Illustrated Manual of Pediatric Dermatology: Diagnosis and Management - PDF Free Download (2024)

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Illustrated Manual of

Pediatric Dermatology

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Illustrated Manual of

Pediatric Dermatology Diagnosis and Management

Susan Bayliss Mallory MD Professor of Internal Medicine/Division of Dermatology and Department of Pediatrics Washington University School of Medicine Director, Pediatric Dermatology St. Louis Children’s Hospital St. Louis, Missouri, USA Alanna Bree

MD

St. Louis University Director, Pediatric Dermatology Cardinal Glennon Children’s Hospital St. Louis, Missouri, USA

Peggy Chern

MD

Department of Internal Medicine/Division of Dermatology and Department of Pediatrics Washington University School of Medicine St. Louis, Missouri, USA

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© 2005 Taylor & Francis, an imprint of the Taylor & Francis Group First published in the United Kingdom in 2005 by Taylor & Francis, an imprint of the Taylor & Francis Group, 2 Park Square, Milton Park Abingdon, Oxon OX14 4RN, UK Tel: Fax: Website:

+44 (0) 20 7017 6000 +44 (0) 20 7017 6699 www.tandf.co.uk

All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means, electronic, mechanical, photocopying, recording, or otherwise, without the prior permission of the publisher or in accordance with the provisions of the Copyright, Designs and Patents Act 1988 or under the terms of any licence permitting limited copying issued by the Copyright Licensing Agency, 90 Tottenham Court Road, London W1P 0LP. Although every effort has been made to ensure that all owners of copyright material have been acknowledged in this publication, we would be glad to acknowledge in subsequent reprints or editions any omissions brought to our attention. British Library Cataloguing in Publication Data Data available on application Library of Congress Cataloging-in-Publication Data Data available on application ISBN 1-85070-753-7 Distributed in North and South America by Taylor & Francis 2000 NW Corporate Blvd Boca Raton, FL 33431, USA Within Continental USA Tel: 800 272 7737; Fax: 800 374 3401 Outside Continental USA Tel: 561 994 0555; Fax: 561 361 6018 E-mail: [emailprotected] Distributed in the rest of the world by Thomson Publishing Services Cheriton House North Way Andover, Hampshire SP10 5BE, UK Tel: +44 (0) 1264 332424 E-mail: [emailprotected]

Composition by Parthenon Publishing Printed and bound by T.G. Hostench S.A., Spain

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CONTENTS

Preface Dedication Chapter 1. Principles of Clinical Diagnosis 2. Neonatal Dermatology 3. Papular and Papulosquamous Disorders 4. Eczematous Dermatoses 5. Acne and Acneiform Disorders 6. Bullous Disorders 7. Bacterial and Spirochetal Diseases 8. Viral and Rickettsial Diseases 9. Fungal Diseases 10. Infestations and Environmental Hazards 11. Hypersensitivity Disorders/Unclassified Disorders 12. Photodermatoses and Physical Injury and Abuse 13. Drug Eruptions 14. Pigmentary Disorders 15. Collagen Vascular Diseases 16. Vascular and Lymphatic Diseases 17. Tumors, Cysts, and Growths 18. Hair Disorders 19. Nail Disorders 20. Genodermatoses and Syndromes 21. Therapy Index

vii ix 1 9 33 49 71 81 95 119 149 163 177 199 217 229 257 275 297 335 359 369 391 411

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PREFACE

Pediatric dermatology is an exciting area of medicine. When children are young, they cannot give a history. In fact, pediatrics is said to be much like veterinary medicine! The practitioner must use sharp observational skills to assess a problem. For example, rather than asking a 1 year old if they scratch or if a rash itches, merely observing the child scratching in the office or seeing excoriations on the skin will lead a physician to the correct conclusion. Thus, looking for clues further sharpens one’s visual skills. This book is a synopsis of basic pediatric dermatology. The approaches that we use are practical ones which we have found to be simple basic approaches to problems that pediatricians and dermatologists see in their practices. This book is aimed at the common problems seen in medical offices with some added information about unique conditions in pediatric dermatology.

Teaching at a pediatric tertiary care hospital, we find that pediatric and family practice residents ask us frequently which book they might purchase for their library. Mainly, they are interested in a book that has good photographs so that they can visually recognize skin diseases combined with a practical, concise text. Our purpose in writing this book was to produce a manual of high-quality photographs which can easily aid the pediatric house officer and primary care physician in the diagnosis of pediatric skin diseases. In addition, we have tried to provide a pertinent, easy to read outline with easily applied suggestions on treatment. Realistic criteria for referring patients are also outlined and a few pertinent references are given. We hope that you enjoy this text and that it can be of benefit to all who read it. Susan Bayliss Mallory MD Alanna Bree MD Peggy Chern MD

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DEDICATION

We would like to dedicate this book to our children and patients who have been a great source of learning not only about pediatrics but also about pediatric dermatology. For Susan Bayliss Mallory, my children, Elizabeth and Meredith, have been a source of joy and encouragement as well as keeping me grounded. My parents, Milward William Bayliss MD and Jeanette Roedell Bayliss were always encouraging me to study and learn. God has been an ever-loving omniscient presence in my life and has been my source of inspiration. For Alanna Bree, to all of my many teachers, especially my first teachers – my parents, Al and Shirley Flath. Most importantly, to my husband, Doug, and children Sam and Kendyl for their unconditional love and constant support.

For Peggy Chern, to my parents, Henry and Myra Chern, and to Matt Shaw for their support and encouragement. Others who have been a major source of help and inspiration have been: General Elbert DeCoursey MD, Esther DeCoursey, Jere Guin MD, Arthur Eisen MD and Lynn Cornelius MD. Special thanks to the following physicians who helped review the manuscript: Chan-Ho Lai, Pam Weinfeld, Jason Fung, Tony Hsu, Angela Spray, D. Russell Johnson, Alison Klenk, Margaret Mann and Yadira Hurley.

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1 PRINCIPLES OF CLINICAL DIAGNOSIS

GENERAL

• Diagnosis of cutaneous disorders in infants and •

children requires careful inspection of skin, hair and nails Skin disorders of infants are different from skin disorders in adults 1. For example, erythema toxicum neonatorum is only seen in newborns 2. Skin of a young child tends to form blisters more easily (e.g. insect bites or mastocytomas) Determining morphology of skin lesions, their color and distribution will help generate a differential diagnosis

HISTORY

• Take a thorough history of events surrounding the skin disorder (Table 1.1)

Table 1.1

1. This includes the patient’s age, race, sex, details of previous treatments and duration of the problem 2. Focus attention on the particular morphology 3. Physicians should be sensitive to the anxieties that parents might have and address these issues appropriately a. While taking a family history, note whether a family member has a similar but more severe disorder that may cause concern (e.g. psoriasis). Talking about these issues will let the parent know that you understand their concerns 4. Developmental aspects, previous illnesses and previous surgery are important points in the history 5. Newborn history should include the prenatal period, pregnancy and delivery

Interviewing and treating pediatric dermatology patients

1. Children are different from adults. Learn the differences. 2. Approach patients cautiously. Sit across the room and talk to the parents before examining the child. This gives them time to ‘size you up’. 3. Speak directly to the child as if he/she understands what you are saying. Make eye contact with the child. 4. Keep the parent in the room for procedures as much as possible unless it interferes with the procedure or the parent wishes to step out of the room. 5. Conservative management is best. Try to use the lowest effective dose of medication for the shortest time. 6. Avoid new therapies which do not have a proven track record in pediatrics until adequate clinical trials are performed. 7. Do not use treatments which may decrease growth or mental development. 8. Anticipatory guidance and emotional support are helpful especially in chronic disorders (e.g. alopecia areata, atopic dermatitis). Adapted from Honig PJ. Potential clinical management risks in pediatric dermatology. Risk Management in Dermatology, Part II. AM Medica Communications LTS: New York, 1988: 6

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a. Maternal history may quickly lead to a diagnosis in some cases (e.g. maternal HIV or systemic lupus erythematosus) 6. Evaluation of young children requires a modified approach, depending upon the age of the child a. Establish a positive relationship with not only the parent but also the child b. Gain eye contact with the child at his own level. This is less threatening than standing over him in an intimidating manner c. Sit and talk to the parents without making any movements toward the young child. This allows time for him/her to observe your actions (‘size you up’) before speaking with them directly d. Refrain from using a loud voice or touching the child until he feels comfortable. These are techniques which pediatricians know very well e. Allow the child to play with small toys in the room. This is a way to distract him and allows one to observe his interactions, which could help with developmental history f. Obviously, young children cannot always answer specific questions. However, carefully observing the child may reveal answers to questions not even asked (e.g. observing scratch marks on a 6-month-old child obviates the necessity of asking whether the child is scratching) 7. School age children (5–10 years) can answer questions directly and are sometimes very informative a. Engaging them in conversation about school or an interest, such as a pet, may put the child at ease quickly 8. Adolescents can give a history and should be given instructions, giving the adolescent the ability to take care of his own skin, demonstrating his maturity and ability to care for his own health

• •

1. Additional lighting with high-intensity examination lights 2. Side-lighting may demonstrate subtle elevations or depressions A magnifying glass may enlarge tiny variations of the skin Examination of the genitalia should not be overlooked; have an assistant or parent in the room, not only for the comfort of the patient but also for legal purposes Mucous membranes should also be examined, specifically looking for ulcers, white spots or pigmented lesions that may reflect a primary skin disorder Teeth should be examined for evidence of enamel dysplasia (pitting), infection or general hygiene

TERMINOLOGY

• The description of lesions is important to help • • • •

• • •

determine whether lesions are primary (initial) lesions or secondary lesions Primary lesions are de novo lesions which are most representative of the disorder (Table 1.2) Secondary lesions occur with time and demonstrate other changes (Table 1.3) Configuration describes the pattern of lesions on the skin (Table 1.4) Distribution describes where the lesions are found. Examples: localized, generalized, patchy, symmetric, asymmetric, segmental, dermatomal, or following Blaschko lines Number of lesions: single, grouped or multiple Color of lesions: red, pink, blue, brown, black, white, yellow or a variation of these colors (Table 1.5) Regional patterns if lesions are found primarily in a certain distribution (Table 1.6). Examples: photosensitive eruptions are seen on the face and arms with sun exposure; tinea versicolor tends to be on the upper chest and back

PHYSICAL EXAMINATION

• Include the entire skin surface including hair, nails and oral mucosa

• Adequate lighting is important, preferably natural lighting through a window

DISEASES

• In a pediatric dermatological practice, 35 diseases account for more than 90% of the diagnoses seen in patients (Table 1.7)

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Table 1.2

Primary lesions

Primary (initial) lesions Macule Patch Papule Nodule Tumor Plaque Wheal Vesicle Bulla Pustule Cyst Comedone Petechiae Purpura

Table 1.3

Description Flat; any change in color of the skin < 1 cm in size Flat lesion > 1 cm in size Solid elevated lesion < 1 cm diameter; greatest mass above skin surface Solid elevated lesion > 1 cm diameter; greatest mass below skin surface Solid elevated lesion > 2 cm diameter; greatest mass below skin surface Raised, flat, solid lesion > 1 cm; may show epidermal changes Raised, solid, edematous papule or plaque without epidermal change Fluid-filled (clear) < 1 cm diameter, usually < 0.5 cm Fluid-filled (clear) > 1 cm diameter Vesicle or bulla with purulent fluid Cavity lined with epithelium containing fluid, pus, or keratin Plugged sebaceous follicle containing sebum, cellular debris and anaerobic bacteria Extravasated blood into superficial dermis appearing as tiny red macules Extravasated blood into dermis and/or subcutaneous tissues associated with inflammation; may or may not be palpable

Secondary lesions

Secondary lesions Crust Exudate Eschar Scale Lichenification Excoriation Erosion Ulcer Fissure Atrophy

Scar Papillomatous Friable Pedunculated Filiform

Description Collection of dried serum, blood, pus and damaged epithelial cells Moist serum, blood or pus from either an erosion, blister or pustule Dark or black plaque overlying an ulcer; seen in tissue necrosis Dry, flaky surface with normal/abnormal keratin; present in proliferative or retention disorders Accentuation of normal skin lines caused by thickening, primarily of the epidermis, due to scratching or rubbing Localized damage to skin secondary to scratching Superficial depression from loss of surface epidermis Full-thickness loss of epidermis, some dermis and subcutaneous fat, which results in a scar when healed Linear crack in the skin, down to the dermis Thinning or loss of epidermis and/or dermis Epidermal atrophy may be very subtle, showing only fine wrinkling of the skin with increased underlying vascular prominence Dermal atrophy shows little if any epidermal change but shows depressions, reflecting loss of dermis or subcutaneous tissue Healed dermal lesion caused by trauma, surgery, infection Surface with minute finger-like projections Skin bleeds easily after minor trauma Papule or nodule on a stalk with a base usually smaller than the papule or nodule Finger-like, usually associated with warts on the face

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Table 1.4

Configuration of skin lesions

Configuration

Description

Annular Linear Grouped Target

Round lesion with an active margin and a clear center (e.g. granuloma annulare, tinea corporis) Lesion occurring in a line (e.g. poison ivy dermatitis, excoriations) Lesions of any morphology located close together (e.g. molluscum) Dark, dusky center with erythematous border and lighter area in between (e.g. erythema multiforme) Semicircular Lesions which were annular and/or arched and have moved and become joined Snake-like margins (e.g. urticaria, creeping eruption) Appearing like an eruption of herpes simplex virus with tightly grouped vesicles or pustules (e.g. dermatitis herpetiformis) Following a dermatome (e.g. herpes zoster)

Arciform Gyrate/polycyclic Serpiginous Herpetiform Zosteriform/ dermatomal Segmental Reticulated Umbilicated

Table 1.5

Following a body segment (e.g. hemangioma) Net-like pattern (e.g. livedo reticularis) Surface has round depression in center (e.g. molluscum contagiosum)

Other descriptive terms

Characteristic

Examples

Color

Pink – caused by increase in blood flow or interstitial fluid Red – caused by increased blood or dilated blood vessels Purple – caused by increased blood or dilated blood vessels Violaceous – lavender, bluish pink Depigmented – complete loss of pigment Hypopigmented – partial loss of pigment Brown – increase in melanin in epidermis Gray/blue – increase in melanin in dermis or subcutaneous tissue Black – intensely concentrated melanin Yellow – associated with lipids or sebaceous glands

Border

Circumscribed – limited in space by something drawn around or confining an area Diffuse – spreading, scattered

Palpation

Smooth – surface not different from surrounding skin Uneven – felt in scaly or verrucous lesions Rough – feels like sandpaper

• Reaction patterns help group disorders together (Table 1.8) 1. Examples are eczematous eruptions: atopic dermatitis, allergic contact dermatitis 2. Examples are papulosquamous disorders: psoriasis, seborrheic dermatitis

DIAGNOSTIC TESTS Potassium hydroxide examination Potassium hydroxide (KOH) examination is used for suspected fungal infections of skin, hair and nails

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Table 1.6

Table 1.7

Regional patterns and diagnosis

Face Contact dermatitis Perioral dermatitis Pityriasis alba Acne Milia Photosensitivity disorders Trunk Tinea corporis Tinea versicolor Pityriasis rosea Psoriasis Extremities Psoriasis (also scalp and nails) Scabies (also groin and waistline) Granuloma annulare Erythema nodosum Erythema multiforme Dyshidrotic eczema Gianotti–Crosti syndrome Cutis marmorata Nails Psoriasis Alopecia areata Twenty nail dystrophy Lichen planus Ingrown toenail

Genital/groin Lichen sclerosus Condyloma acuminata Acrodermatitis enteropathica Intertrigo

• Scrapings (using a scalpel blade) from a scaly lesion

• Apply a few drops of 10–20% KOH • Apply a cover slip • Heat the slide to facilitate dissolution of the cell • •

are placed on a clean glass slide

• Nail scrapings can be obtained by scraping with a •

scalpel blade or small dermal curette underneath the nail for keratinous subungual debris Place scrapings on a glass slide

Most common dermatoses in children

Acne Alopecia areata Atopic dermatitis (eczema) Café au lait macules Capillary malformation (port wine stain) Condyloma acuminata Contact dermatitis Drug eruption Epidermal cyst Folliculitis Granuloma annulare Hemangioma Herpes simplex Ichthyosis Impetigo Keloid Keratosis pilaris Mastocytosis Milia Molluscum Nevi Pityriasis alba Postinflammatory hyperpigmentation Postinflammatory hypopigmentation Psoriasis Pyogenic granuloma Scabies Seborrhea Telangiectasias Tinea capitis Tinea corporis Tinea versicolor Urticaria Viral exanthem Vitiligo Warts

Scalp Seborrheic dermatitis Tinea capitis Alopecia areata Psoriasis Nevus sebaceus Aplasia cutis congenita

Oral Lichen planus Mucocele Geographic tongue Stevens–Johnson syndrome

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walls or allow the slide to sit for 15–20 min without heating If 20% KOH in dimethylsulfoxide (DMSO) is used, heating is unnecessary KOH can also be formulated in ink-based preparations which darken the hyphae for easier identification (examples: Chlorazole fungal stain from Delasco Dermatologic Lab and Supplies, Inc (www.delasco.com), or Swartz–Lampkin solution) Examine microscopically at 10× or 20× power with the condenser in the lowest position

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Table 1.8

Common dermatologic diagnoses by reaction pattern

Eczematous Atopic dermatitis (eczema) Infantile eczema Nummular eczema Allergic contact dermatitis Dermatophytosis Diaper dermatitis Scabies Papulosquamous Psoriasis Seborrheic dermatitis Pityriasis rosea Syphilis Lichen planus Vesiculobullous Impetigo Herpes simplex virus Varicella-zoster virus Epidermolysis bullosa Miliaria Scabies

Infiltrative pattern Nodular Erythema nodosum Pyogenic granuloma Juvenile xanthogranuloma Cyst Papular Granuloma annulare Mastocytosis Xanthomas Molluscum contagiosum Atrophy and/or sclerosis Scleroderma Morphea Lichen sclerosus Lipoatrophy Aplasia cutis congenita

Acneiform Acne vulgaris Steroid-induced acne Perioral dermatitis Rosacea Verrucous Warts Nevus sebaceus Epidermal nevus Erosive Acrodermatitis enteropathica Epidermolysis bullosa

Vascular reactions/erythema Urticaria Vasculitis Viral exanthem

• Demonstration of hyphae or spores confirms the •

Erythema multiforme Erythema annulare centrifugum

diagnosis of tinea Oral lesions suspected of Candida can be scraped in a similar fashion to demonstrate the typical pseudohyphae or budding yeast forms

Scabies preparation Scrape a burrow or unexcoriated papule, and apply KOH or mineral oil to the slide before microscopic examination • Best areas to find mites: wrists, in between fingers, or along sides of feet of infants • Examine at 4× power to demonstrate mites, eggs or scybala (feces)

Pediculosis This can be confirmed by finding a live louse on the skin or scalp, or by demonstrating nits on the hair shafts • Affected hairs can be cut with scissors, placed on a glass slide and covered with immersion oil or KOH to demonstrate nits

Fungal cultures Fungal cultures confirm a diagnosis of tinea capitis, tinea corporis or onychomycosis • Using appropriate fungal culture media (Sabouraud’s agar, Mycosel agar) allows for identification of fungal species • Dermatophyte Test Media (DTM) can be used in the office for easy identification of dermatophytes, but does not speciate fungi

Tzanck smear This is used for diagnosis of herpes simplex or varicella-zoster virus • Remove vesicle roof with a scalpel blade and place on a glass slide • The base of the lesion is gently scraped and transferred to a slide, then stained with a Giemsa or Wright stain • Multinucleated giant epithelial cells under 40× microscopy are diagnostic for herpes virus or varicella-zoster infections

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Wood’s lamp examination A Wood’s lamp emits long-wave ultraviolet light • Screening for fungal scalp infections caused by Microsporum species shows green fluorescence of affected hair shafts 1. It is important to verify that the actual hair shaft is causing fluorescence, which can easily be seen with a magnifying lens 2. Lint, scales and other debris on the scalp also fluoresce and should not be confused with tinea • Hypopigmentation or depigmentation can be accentuated (e.g. tuberous sclerosis patches) and delineated, particularly in light-skinned patients • Corynebacterium minutissimum, which causes erythrasma, fluoresces a coral red color • Urine of patients with certain types of porphyria fluoresces pink

Bacterial cultures

• Purulent material from representative lesions are swabbed with a soft sterile swab, inserted into the appropriate tube and sent to the laboratory

Viral culture This requires a special transport medium, which is available at most large hospitals • Blister fluid and the base of the lesion should be swabbed or aspirated and then inoculated into the appropriate media

Skin biopsy Skin biopsy is carried out for routine histopathologic or immunofluorescence examination • Topical anesthetic can be applied to the skin prior to biopsy to reduce the pain of the needle stick for local anesthesia • Punch biopsies or elliptical biopsies should demonstrate all three levels of the cutis (epidermis, dermis and subcutaneous fat)

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• Shave biopsies (saucerization) may be indicated for more superficial lesions

• Biopsy is best done by a physician who is trained •

in the knowledge of which areas are best biopsied and what histology is expected Immunofluorescence may be indicated for certain connective tissue disorders or bullous diseases and requires special transport media

Diascopy Diascopy is performed by placing a glass slide over the skin lesions with light pressure • Vascular lesions typically show characteristic blanching with refilling once the slide has been removed • Granulomatous disorders such as sarcoidosis may demonstrate an apple jelly color References Brodkin RH, Janniger CK. Common clinical concerns in pediatric dermatology. Cutis 1997; 60: 279–30 Eichenfield LF, Frieden IJ, Esterly NB, eds. Textbook of Neonatal Dermatology. WB Saunders: Philadelphia, 2001 Eichenfield LF, Funk A, Fallon-Friedlander S, Cunningham BB. A clinical study to evaluate the efficacy of ELA Max (4% liposomal lidocaine) as compared with eutectic mixture of local anesthetics cream for pain reduction of venipuncture in children. Pediatrics 2002; 109: 1093–9 Freedberg IM, Eisen AZ, Wolff K, et al., eds. Fitzpatrick’s Dermatology in General Medicine, 6th edn. McGraw Hill: New York, 2003 Harper J, Oranje A, Prose N, eds. Textbook of Pediatric Dermatology. Blackwell Science Oxford: UK, 2000 Lewis EJ, Dahl MV, Lewis CA. On standard definitions: 33 years hence. Arch Dermatol 1997; 133: 1169 Renzi C, Abeni D, Picardi A, et al. Factors associated with patient satisfaction with care among dermatological outpatients. Br J Dermatol 2001; 145: 617–23 Schachner LA, Hansen RC, eds. Pediatric Dermatology, 3rd edn. Mosby (Elsevier): New York, 2003 Sybert VP. Genetic Skin Disorders. Oxford University Press: New York, 1997

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2 NEONATAL DERMATOLOGY

COMMON CUTANEOUS FINDINGS

ceramide pattern in vernix and fetal skin. Br J Dermatol 2002; 146: 194–201

Vernix caseosa

Joglekar VM. Barrier properties of vernix caseosa. Arch Dis Child 1980; 55: 817

Major points

• Common finding in the neonatal period • Characteristic white to gray, greasy covering on the • • • •

skin surface of the newborn (Figure 2.1) Thickness increases with gestational age Considered a protective covering and mechanical barrier to bacteria Lipid composition is variable depending on gestational age Discoloration and odor can indicate fetal distress and/or intrauterine infection

Pathogenesis • Composed of shed epidermal cells, sebum and lanugo hairs • Variable lipid composition of cholesterol, free fatty acids and ceramide

Cutis marmorata Major points

• Transient mottling of the skin in the newborn period

• Normal physiologic response to ambient • •

temperature changes; accentuates with decreased temperatures and improves with rewarming Symmetrical, blanchable, red–blue reticulated mottling of trunk and extremities. (Figure 2.2) More common in premature infants, but also affects full-term newborns

Diagnosis • Clinical diagnosis Differential diagnosis • Ichthyoses (disorders of keratinization) if atypical Treatment

• None needed Prognosis • Sheds without therapy during the first week of life References Hoeger PH, Schreiner V, Klaassen IA, et al. Epidermal barrier lipids in human vernix caseosa: corresponding

Figure 2.1 newborn

Vernix caseosa – cheesy white material in a

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References Devillers ACA, De Waard-Van der Spek, Oranje AP. Cutis marmarota telangiectatica congenita. Clinical features in 35 cases. Arch Dermatol 1999; 134: 34–8 Ercis M, Balci S, Atakan N. Dermatological manifestations in 71 Down syndrome children admitted to a clinical genetics unit. Clin Genet 1996; 50: 317–20 Treadwell PA. Dermatoses in newborns. Am Fam Physician 1997; 56: 443–50

Sebaceous gland hyperplasia Figure 2.2 Cutis marmorata – reticulated vascular normal pattern in an infant

Major points

• Prominent sebaceous glands present in the • Improves with increasing age; typically resolves by 1 year

Pathogenesis

• Physiologic vascular reaction based on immature

autonomic control of the vascular plexus in response to temperature changes Postulated to be caused by increased sympathetic tone with delayed vasodilatation in response to a flux in temperature resulting in dilatation of capillaries and small venules Persistent cases associated with Down syndrome, trisomy 18, hypothyroidism, Cornelia de Lange syndrome, congenital heart disease

newborn period Affects up to 50% of term infants; less common in premature infants Characteristic pinpoint yellow papules with no surrounding erythema (Figure 2.3) Location: nose, cheeks, upper lip and forehead

Diagnosis

• Clinical findings Differential diagnosis

• Cutis marmorata telangiectatica congenita • Livedo reticularis caused by collagen vascular disorder Treatment

• Maintain even temperature of infant and surroundings Prognosis

• Generally resolves spontaneously as vasomotor responses mature

• May require further evaluation for underlying disorder if persistent beyond 6 months of age and does not respond to warming (e.g. thyroid disorder, heart disease)

Figure 2.3 newborn

Sebaceous gland hyperplasia seen in a

Pathogenesis

• Caused by maternal androgen stimulation of sebaceous glands that occurs in the final month of gestation Diagnosis

• Clinical findings • Histology: enlarged sebaceous gland with a widened sebaceous duct

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Neonatal dermatology

Differential diagnosis

Prognosis

• •

• Typically resolves within weeks to months • Can be associated with syndromes: type I

Milia Neonatal acne

Treatment

• None required or recommended Prognosis

• Spontaneous resolution during the first few months of life

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oral–facial–digital syndrome, hereditary trichodysplasia, pachyonychia congenita References Akinduro OM, Burge SM. Congenital milia in the nasal groove. Br J Dermatol 1994; 130: 800

Reference

Bridges AG, Lucky AW, Haney G, Mutasim DF. Milia en plaque of the eyelids in childhood: case report and review of the literature. Pediatr Dermatol 1998; 15: 282–4

Rivers JK, Friederikesn PC, Dibin C. A prevalence survey of dermatoses in the Australian neonate. J Am Acad Dermatol 1990; 23: 77–81

Langley RG, Walsh NM, Ross JB. Multiple eruptive milia: report of a case, review of the literature, and a classification. J Am Acad Dermatol 1997; 37: 353–6

Milia Major points

• Occurs in up to 40% of infants, most commonly • • •

on the face Known as Epstein’s pearls when they occur in the oral cavity; affect up to 85% of newborns 1–2 mm white, firm papules on the face, but can also occur on the trunk, extremities, genitalia and oral mucosa (Figure 2.4) Can occur at sites of scars

Larralde de Luna M, Paspa ML, Ibargoyen J. Oral–facial–digital type I syndrome of Papillon-Leage and Psaume. Pediatr Dermatol 1992; 9: 52–6 Stefanidou MP, Panayotides JG, Tosca AD. Milia en plaque: a case report and review of the literature. Dermatol Surg 2002; 28: 291–5

Erythema toxicum neonatorum Synonym: toxic erythema of the newborn Major points

• Occurs in 40–70% of full-term infants

Pathogenesis

• Keratinous cyst originating from vellus hair follicle • Results from retention of keratin within the lowest portion of the infundibulum of the pilosebaceous unit at the level of the sebaceous duct Diagnosis

• Clinical findings • Histology: identical to epidermal cysts except for smaller size; lined by stratified epithelium; contains laminated keratin Differential diagnosis

• Neonatal acne • Sebaceous hyperplasia • Molluscum contagiosum Treatment

• No intervention required • Incision and expression rarely required

Figure 2.4

Milia – multiple white papules on the face

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• Rarely affects preterm infants or infants weighing • • • • •

4 times maternal titer indicates true neonatal infection; treponemal serologies are more specific, especially IgM FTAABS or VDRL on CSF Long-bone radiologic evaluation for osteochondritis Histology: swelling of vascular endothelium and lymphoplasmocytic perivascular inflammation

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Neonatal dermatology

Differential diagnosis

• • • •

Congenital candidiasis Scabies Psoriasis Epidermolysis bullosa

• Majority are external; 30% can be intranasal or with oropharyngeal extension Pathogenesis

• Evagination of neuroectodermal tissue via a

Treatment

• Establish status of CNS involvement by examining •

CSF Aqueous crystalline penicillin G 50 000 units/kg per dose intravenously every 12 h for first 7 days of life, then every 8 h thereafter to complete a 10-day course; infants and children are dosed at 200 000–300 000 units/kg per day divided every 4–6 h for 10 days

sequelae Skin lesions typically resolve with postinflammatory hypo- and hyperpigmentation

References Evans HE, Frenkel LD. Congenital syphilis. Clin Perinatol 1994; 21: 149–62 Hollier LM, Cox SM. Syphilis. Semin Perinatol 1998; 22: 323–31 Parish JL. Treponemal infections in the pediatric population. Clin Dermatol 2000; 18: 687–700 van Voorst Vader PC. Syphilis management and treatment. Dermatol Clin 1998; 16: 699–711 Wicher V, Wicher K. Pathogenesis of maternal–fetal syphilis revisited. Clin Infect Dis 2001; 33: 354–63

developmental abnormality of the nasofrontal fontanelle Failure of complete retraction during formation of dura leads to isolation of this tissue upon suture closure; a stalk may connect to the underlying brain through the foramen caecum

Diagnosis

• Imaging: CT or MRI recommended prior to biopsy • Histology: collections of astrocytes embedded in dense connective tissue trabeculae with occasional striated muscle

Prognosis

• 25–40% intrauterine fetal death • High risk for preterm birth and neurologic

27

Differential diagnosis

• • • • • •

Encephalocele Hemangioma Nasal dermoid cyst Lacrimal duct cyst Neuroblastoma Rhabdomyosarcoma

Treatment

• Evaluate with MRI • Treatment is surgical by experienced pediatric surgeons in collaboration with neurosurgeons as needed

NEONATAL DEFECTS Nasal glioma Major points

• Typically presents at birth • Firm bluish or red swelling on the nasal root with overlying telangiectasias (Figure 2.21)

• Composed of ectopic neural tissue • Regarded as a variant of encephalocele; intracranial connection not always present

• Does not increase in size with crying or Valsalva maneuver

Figure 2.21 Nasal glioma resembling a hemangioma but with a connection through the cranium in a newborn

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Prognosis

Prognosis

• Excellent with appropriate resection • Recurrences occasional

• Lesions persist if not surgically corrected and may

References

References

El Shabrawi-Caelen L, White WL, Soyer HP, et al. Rudimentary meningocele: remnant of a neural tube defect? Arch Dermatol 2001; 137: 45–50

Brown MS, Sheridan-Pereira M. Outlook for the child with a cephalocele. Pediatrics 1992; 90: 914–19 Davis DA, Cohen PR, George RE. Cutaneous stigmata of occult spinal dysraphism. J Am Acad Dermatol 1994; 31: 892–6 El Shabrawi-Caelen L, White WL, Soyer HP, et al. Rudimentary meningocele: remnant of a neural tube defect? Arch Dermatol 2001; 137: 45–50 Hoving EW. Nasal encephaloceles. Childs Nerv Syst 2000; 16: 702–6 Hunt JA, Hobar PC. Common craniofacial anomalies: facial clefts and encephaloceles. Plast Reconstruct Surg 2003; 112: 606–15 Paller AS, Pensler JM, Tomita T. Nasal midline masses in infants and children. Arch Dermatol 1991; 127: 362–6

Paller AS, Pensler JM, Tomita T. Nasal midline masses in infants and children. Arch Dermatol 1991; 127: 362–6 Rahbar R, Resto VA, Robson CD, et al. Nasal glioma and encephalocele: diagnosis and management. Laryngoscope 2003; 113: 2069–77

Encephalocele Major points

• Cystic structure on the midline face • Presents in the neonatal period with nasal • •

broadening (67%) or as a soft, blue pulsatile mass that transilluminates on the nasal bridge Increases in size with crying, Valsalva maneuver, or external compression of the jugular veins Associated with facial clefting and other midline defects

Pathogenesis

• Herniation of brain tissue through the skull with connection to the underlying brain Diagnosis

• Image with MRI • Biopsy of the skin lesion not recommended,

owing to the connection with the subarachnoid space which could lead to CSF rhinorrhea and infection Histology: similar to nasal glioma

Differential diagnosis

• • • •

Hemangioma Nasal glioma Dermoid cyst Hypertelorism

become infected

Congenital dermal sinus Major points

• Cutaneous sign of potential spinal dysraphism • Midline epithelium-lined tract most common in • • • •

occipital or lumbar area Typically associated with a dermoid or epidermal cyst Presents as a dimple with an opening visible on the skin Tuft of hair may arise from the sinus tract A cord may be extend from the dimple to the bony defect

Pathogenesis

• Occurs as a result of a developmental abnormality in the separation of the neuroectoderm and the cutaneous ectoderm Diagnosis

• Characteristic skin findings • Imaging studies: MRI Differential diagnosis

Treatment

• Pilonidal sinus

• Evaluation with MRI or CT scan is essential • Surgical excision is recommended by a skilled

Treatment

pediatric neurosurgeon and otolaryngologist

• Excision of area only after appropriate imaging

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Prognosis

Pathogenesis

• 30% of patients are asymptomatic • Complications: repeated meningitis or

• Branchial cysts are epithelial cysts arising from

space-occupying symptoms In the absence of complications, surgical removal leads to resolution of symptoms and minimizes the risk of meningitis

incomplete closure of the branchial clefts in embryologic development, most commonly the second or third branchial clefts Branchial sinuses are remnants of branchial clefts with depressions

References

Diagnosis

Pacheco-Jacome E, Ballesteros MC, Jayakar P, et al. Occult spinal dysraphism: evidence-based diagnosis and treatment. Neuroimag Clin North Am 2003; 13: 327–34, xii

• Histology: cyst lined by stratified squamous

Saito H, Ogonuki R, Yanadori A, et al. Congenital dermal sinus with intracranial dermoid cyst. Br J Dermatol 1994; 130: 235–7 Schijman E. Split spinal cord malformations: report of 22 cases and review of the literature. Childs Nerv Syst 2003; 19: 96–103

29

epithelium and ciliated columnar epithelium on deeper portions; wall of cyst can be surrounded by heavy lymphoid infiltrate Differential diagnosis See Table 17.2 Treatment

• Preoperative imaging to assess for a fistulous connection to the posterior pharynx Surgical excision

Branchial cleft cyst/sinus

Major points

Prognosis

• Cysts or sinus tracts on the lateral aspect of the

• If untreated, cyst may have persistent mucoid

• • • •

neck which are deep to sternocleidomastoid muscle (Figure 2.22) May be unilateral or bilateral Usually present at birth or become obvious in early childhood Can be apparent on the cutaneous surface or drain into the pharynx Most cases are sporadic, but familial cases have been reported

discharge or become infected References Eastlack JP, Howard RM, Frieden IJ. Congenital midline cervical cleft: case report and review of the English language literature. Pediatr Dermatol 2000; 17: 118–22 Glosser JW, Pires CA, Feinberg SE. Branchial cleft or cervical lymphoepithelial cysts: etiology and management. J Am Dent Assoc 2003; 134: 81–6 Mukherji SK, Fatterpekar G, Castillo M, et al. Imaging of congenital anomalies of the branchial apparatus. Neuroimag Clin North Am 2000; 10: 75–93, viii Vaughan TK, Sperling LC. Diagnosis and surgical treatment of congenital cartilaginous rests of the neck. Arch Dermatol 1991; 127: 1309–10

Preauricular cyst/sinus Synonyms: ear pits, congenital auricular fistula Major points

• An epithelial cyst, sinus, or swelling in preauricular region Figure 2.22

Branchial cleft with skin tag

• Common, occurs in 1% of the population • Autosomal dominant or sporadic

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References Leung AK, Robson WL. Association of preauricular sinuses and renal anomalies. Urology 1992; 40: 259–61 Marres HA, Cremers CW. Congenital conductive or mixed deafness, preauricular sinus, external ear anomaly, and commissural lip pits: an autosomal dominant inherited syndrome. Ann Otol Rhinol Laryngol 1991; 100: 928–32 Moreland RF, Elston DM. Photo quiz. Preauricular pit. Cutis 2001; 68: 324, 353–4 O’Mara W, Guarisco L. Management of the preauricular sinus. J LA State Med Soc 1999; 151: 447–50

Accessory tragus Major points

• Presents with round, pedunculated, skin-colored Figure 2.23

Accessory tragus

• Most cases are bilateral and asymptomatic • May become infected and drain purulent material • Associated defects include deafness and renal abnormalities Pathogenesis

• Due to incomplete fusion of the first two branchial arches with epithelial entrapment Diagnosis

• Imaging, preferably CT, defines the lesion • Histology: cysts and sinus tracts are lined by stratified squamous epithelium

• •

papule, occurring anywhere along the line from the tragus to the lateral commissure of the mouth (Figure 2.23) Can be unilateral or bilateral; single or multiple Familial cases have been reported

Pathogenesis

• Anomalous migration of the dorsal portion of the first branchial arch Diagnosis

• Clinical findings • Histology: polypoid lesion with numerous hair follicles, small sebaceous glands and often cartilaginous core; eccrine glands, nerve fibers and Pacinian corpuscles may also be present Differential diagnosis

Differential diagnosis

• Epidermal cyst See Table 17.2 Treatment

• Most lesions are asymptomatic and do not require treatment

• Secondarily infected cysts can be treated with •

antibiotics Excision is indicated if there is chronic inflammation, drainage or infection

• Skin tag • Preauricular cyst/sinus • Goldenhar syndrome (oculoauriculovertebral syndrome) Treatment

• Surgical excision Prognosis

• Usually asymptomatic, may need surgery References

Prognosis

• Lesion persists throughout life

Ban M, Kamiya H, Yamada T, Kitajima Y. Hair follicle nevi and accessory tragi: variable quantity of adipose tissue in

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connective tissue framework. Pediatr Dermatol 1997; 14: 433–6 Jansen T. Romiti R. Altmeyer P. Accessory tragus: report of two cases and review of the literature. Pediatr Dermatol 2000; 17: 391–4 Resnick KI, Soltani K, Berstein JE, Fathizadeh A. Accessory tragus and associated syndromes involving the first branchial arch. J Dermatol Surg Oncol 1981; 7: 39–41

Tadini G, Cambiaghi S, Scarabelli G, et al. Familial occurrence of isolated accessory tragi. Pediatr Dermatol 1993; 10: 26

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3 PAPULAR AND PAPULOSQUAMOUS DISORDERS

Psoriasis

• Infantile psoriasis

Major points

• Affects approximately 1–3% of the population • 2 years) BID

• • • •

1. Antistaphylococcal drugs a. Topical agents (e.g. mupirocin) may be helpful for the short term, but some topical antibiotics (e.g. neomycin, bacitracin) can sensitize the skin and cause further allergic contact dermatitis b. Oral antibiotics may be given in short courses to reduce staphylococcal infections of the skin c. Frequent use of antibiotics can lead to resistant bacteria Systemic corticosteroids 1. Short courses for acute, severe exacerbations may be indicated 2. Long-term oral steroids are not recommended Referral to a dermatologist is recommended for severe and moderately severe cases uncontrolled by standard measures Hospitalization is indicated only if not controlled by methods at home Consider psychological stresses and counseling if unresponsive to treatment For severe, recalcitrant cases consider phototherapy (PUVA, UVB), IFN-γ, or immunosuppressive drugs (e.g. cyclosporine, methotrexate)

Prognosis

• Half of the cases of typical atopic dermatitis improve by 2 years of age

• Most improve by teenage years • Patients tend to have dry, sensitive skin throughout life

• 10 times normal) b. Eosinophilia c. Neutrophil chemotaxis abnormal d. Sinopulmonary infections

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e. Coarse facial features in some patients f. Recurrent staphylococcal infections of skin, lungs, joints, etc. 3. Severe combined immunodeficiency syndrome a. Decreased levels of IgG, IgM, IgD, IgA, IgE b. Lymphopenia c. Defects in cell-mediated immunity d. Adenosine deaminase deficiency, and others Treatment

• Usual treatment for atopic dermatitis with topical steroids, emollients, etc

Rosen FS, Cooper MD, Wedgwood RJP. The primary immunodeficiencies. N Engl J Med 1995; 333: 431–40 Schurman SH, Candotti F. Autoimmunity in Wiskott–Aldrich syndrome. Curr Opin Rheumatol 2003; 15: 446–53 Stewart DM, Tian L, Nelson DL. Linking cellular activation to cytoskeletal reorganization: Wiskott–Aldrich syndrome as a model. Curr Opin Allergy Clin Immunol 2001; 1: 525–33 Thrasher AJ, Burns S, Lorenzi R, Jones GE. The Wiskott–Aldrich syndrome: disordered actin dynamics in haematopoietic cells. Immunol Rev 2000; 178: 118–28

• Infections should be treated with appropriate antibiotics

• Fresh frozen plasma or whole blood for severe lifethreatening illnesses

• Bone marrow transplantation when indicated

ALLERGIC CONTACT DERMATITIS

References

Major points

Arbiser JL. Genetic immunodeficiencies: cutaneous manifestations and recent progress. J Am Acad Dermatol 1995; 33: 82–9

• Characteristics

Badour K, Zhang J, Siminovitch KA. The Wiskott–Aldrich syndrome protein: forging the link between actin and cell activation. Immunol Rev 2003; 192: 98–112 Berron-Ruiz A, Berron-Perex R, Ruiz-Maldonado R. Cutaneous markers of primary immunodeficiency diseases in children. Pediatr Dermatol 2000; 17: 91–6

Bonilla FA, Geha RS. 12. Primary immunodeficiency diseases. J Allergy Clin Immunol 2003; 111(Suppl 2): S571–81 Buckley RH. The hyper-IgE syndrome. Clin Rev Allergy Immunol 2001; 20: 139–54 Dave S, Thappa DM, Karthikeyan K. Disseminated and disfiguring molluscum contagiosum in a child. Pediatr Dermatol 2003; 20: 436–9 Erlewyn-Lajeunesse MD. Hyperimmunoglobulin-E syndrome with recurrent infection: a review of current opinion and treatment. Pediatr Allergy Immunol 2000; 11: 133–41 Lindegren ML, Kobrynski L, Rasmussen SA, et al. Applying public health strategies to primary immunodeficiency diseases: a potential approach to genetic disorders. Morbid Mortal Weekly Rep 2004; 53: 1–29 Mueller BJ, Pizzo PA. Cancer in children with primary or secondary imunodeficiencies. J Pediatr 1995; 126: 1–10 Paller AS. Immunodeficiency syndromes. Dermatol Clin 1995; 13: 65–71 Ratko TA, Cummings JP, Blebea J, Matuszewski KA. Clinical gene therapy for nonmalignant disease. Am J Med 2003; 115: 560–9

1. First exposure does not cause a reaction 2. Reaction begins 12–96 h after subsequent exposure if already allergic 3. Lesions can persist up to 3 weeks 4. Pruritus may vary from mild to severe Clinical pattern and shape give clues to offending antigen (Table 4.2) 1. Linear configuration with sharp borders (Figure 4.18) 2. Individual lesions are pruritic, erythematous papules or papulovesicles which may become vesicular with oozing, weeping and crusting 3. Erythema with scaling in chronic cases 4. Edema may be prominent especially around the face and groin 5. Urticaria-like eruption can occur 6. Heat, sweating and friction accentuate the reaction Major causes in childhood 1. Toxicodendron – poison ivy/oak/sumac (Figure 4.19) a. Most common allergic contact dermatitis in the USA b. Sensitizing substance is an oleoresin called urushiol c. Typical lesions in spring, summer, fall d. Pruritic, erythematous streaks with vesicles are typical e. Erythematous patches, papules can occur

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Table 4.2

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Contact dermatitis history

1. Determine the onset – exact time and location of appearance of lesions 2. Course of dermatitis – progression, recurrence, remission 3. Topical medicines used 4. Previous therapy and response 5. Work exposure – relation to work, days off, vacation, duties 6. Other persons having similar dermatitis 7. Hobbies – chemical exposure 8. Topical cosmetics – perfumes, soaps, sunscreens, toothpaste, nail polish, hair dyes, etc.

Figure 4.19 be

9. Plant exposure – poison ivy, chrysanthemums, weeds, etc. 10. Chemical exposure – work and home 11. Water exposure – hand washing, job-related 12. Clothing history – underwear, jewelry, watches, earrings, belts, snaps

3.

13. Atopic history – asthma, eczema, personal and/or family history 14. Immune status

4.

5.

6.

Figure 4.18 Poison ivy dermatitis – linear streaks of vesicles and erythema

2. Nickel a. Common in children who wear earrings for pierced ears, metal belt buckles, metal zippers, metal snaps, or metal buttons b. Erythema, scaling, crusting and pruritus on earlobes from earrings or around umbilicus

Poison ivy plant – leaves of three, let them

from snaps or belt buckles (Figure 4.20 and 4.21) c. Infants may have involvement from snaps on undershirts Rubber/adhesives, causes: a. Antioxidants: paraphenylenediamine, hydroquinone b. Accelerators: mercaptobenzathiazole, thiuram, carbamate Shoe dermatitis – acute or subacute dermatitis on dorsal feet (Figure 4.22); toewebs spared, causes: a. Rubber (most common) b. Chromates (in leather) c. Glutaraldehyde (in leather) d. Adhesives e. Dyes Adhesive tape dermatitis caused by rubber or colophony: well-demarcated area where adhesive tape is applied Cosmetics a. Acute or subacute (may require detective work) b. Parabens c. Perfumes – can be generalized or localized d. Deodorants – in axillae e. Nail lacquers – may see reaction around the eyes from zlacquer which was not completely dried and patient rubbed the eyelids f. Eye products g. Lipstick – rim of erythema around lips

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Figure 4.20 Nickel dermatitis – typical distribution from a snap on the pants or belt buckle

Figure 4.22 dorsal feet

Shoe dermatitis – typical distribution on

Pathogenesis

• Delayed-type hypersensitivity reaction (type IV)

Figure 4.21 Autoeczematous dermatitis ‘id reaction’ – generalized eczematous changes from nickel dermatitis

7. Formaldehyde – used in clothing (permanentpress fabric finishes); periaxillary area 8. Benzocaine – over-the-counter (OTC) topical anesthetics 9. Caines/diphenhydramine (e.g. Benadryl®) – topical anesthetics 10. Neomycin – topical antibiotics; increased sensitivity if applied to broken skin 11. Mercury – e.g. Merthiolate®, Mercurochrome®

1. Afferent (induction) phase (5–25 days) 2. First contact; allergen penetrates skin and acts as hapten, binding to skin proteins 3. Helper T cells activated 4. Langerhans cells recognize antigen as nonself and present it to T lymphocytes 5. Langerhans cells with hapten move from epidermis to lymph nodes 6. Naïve T cells differentiate into clones of effector cells directed at foreign antigen 7. Results in committed sensitized T cells reactive to specific antigen Elicitation reaction (24–48 hours) 1. Re-exposure results in accumulation of effector cells which produce numerous cytokines (e.g. IFN-γ, TNF, etc.) and mediators which result in dermatitis in areas limited to skin contact

Diagnosis

• Laboratory – not indicated. Refer to dermatologist •

for evaluation if diagnosis unclear Skin patch tests (T.R.U.E. tests) (Tables 4.3 and 4.4) 1. Helpful for difficult cases 2. Patches applied to normal nonhairy skin (back or upper arms) for 48 h; read at 72 h and 5 days 3. False-positive reactions often seen in atopic patients

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Table 4.3

Patch testing T.R.U.E. Test (Glaxo Dermatology)

Standard allergens

Found in:

1. Nickel sulfate

Jewelry, belt buckles, eyeglass frames, alloys, orthopedic appliances, money, scissors, eating utensils

2. Wool alcohols

Cosmetics, creams, lotions, ointments, soaps (cross-reacts with lanolin)

3. Neomycin sulfate

Topical antibiotics, first-aid creams, eardrops, nosedrops

4. Potassium dichromate

Tanning solutions for leather, cement, photography solutions, paints, glues, pigments and some detergents

5. Caine mix

Topical anesthetics

6. Fragrance mix

Toiletries, soaps, perfumes, shampoo, scented products, industrial cutting fluids

7. Colophony (rosin)

Used by violinists, ball players, bowlers; in cosmetics, adhesives, lacquers, varnishes, paper and industrial products

8. Epoxy resin

Uncured epoxy resin, nail products

9. Quinolone mix

Topical antimicrobial medicated creams, medicated bandages and veterinary products

10. Balsam of Peru

Perfumes, flavoring in drinks, tobacco, topical medications, dental agents

11. Ethylenediamine dihydrochloride

Stabilizer for some creams; found in rubber, color photography solutions, epoxy catalyst systems and some antifreeze solutions (cross-reacts with hydroxyzine, aminophylline)

12. Cobalt dichloride

Some paints, cement, metal, metal-plated objects

13. Para-tert butylphenol formaldehyde resin

Leather finishes (shoes), paper fabrics, furniture, glues

14. Paraben mix

Preservative in numerous creams, cosmetics, industrial oils, glues

15. Carba mix

Rubber, rubber glues, vinyl, pesticides

16. Black rubber mix

Rubber antioxidant, hair dyes

17. Cl+Me– Isothiazolinone

Preservative found in cosmetics, medications, household cleaning products, industrial fluids and greases

18. Quaternium 15

Stabilizer, formaldehyde releaser found in cosmetics, creams, lotions

19. Mercaptobenzothiazole

Shoes, rubber accelerator, antifreeze, cutting oils, flea and mosquito repellants

20. Paraphenylenediamine

Hair dyes, inks, photodevelopers, textile dyes

21. Formaldehyde

Clothes, textiles, preservatives, disinfectants, dental plastics, glues, nail polishes, adhesives, shampoo Formaldehyde releasers: Quaternium 15, imiadiazoyl urea, Bronopol

22. Mercapto mix

Rubber, glues, coolants, industrial products

23. Thimerosal

Preservative in vaccines, contact lens solutions, eye cosmetics, nose and ear drops

24. Thiuram mix

Rubber, disinfectant, lubricating oils, fungicide

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Table 4.4 Patch test materials/nickel detection kits can be ordered

Glaxo Dermatology (T.R.U.E. Test) 5 Moore Drive Research Triangle Park, NC 27709, USA www.truetest.com/ Hermal Pharmaceutical Laboratories, Inc. Route 145 Oak Hill, NY 12460, USA (518) 475-0175 www.hermal.de/english/index.html Allerderm Labs Inc. 28 Glen Drive Mill Valley, CA 94941, USA (415) 381-0106 www.allerderm.com

• Histology:

1. Multilocular intraepidermal spongiotic vesicles 2. Eosinophils in dermis and epidermis 3. Langerhans cells in the epidermis associated with lymphocytes 4. Immunohistochemical studies show primarily memory T-helper lymphocytes, although Tsuppressor cells can be noted Nickel detection kit: dimethylglyoxime in a 10% aqueous solution of ammonia – turns pink on contact with nickel (see Table 4.4)

Differential diagnosis

• Atopic dermatitis • Irritant contact dermatitis • Autoeczematization Treatment

• Avoidance of contactant

1. Education 2. Give patients a list of objects or products which contain allergens 3. Wash skin with plain water if known allergen is contacted Acute dermatitis with oozing and weeping, vesicles or bullae 1. Compresses with Burrow’s solution (e.g. Domeboro®, Blurobor®) for 15 min 2. Apply shaken lotion of calamine three times a day for drying effect

3. Avoid topical diphenhydramine or caines which are added to some products 4. Topical corticosteroids a. Medium to ultra-potent steroids (class 1–4) for about 5–7 days used two or three times a day then taper to lowest strength to keep erythema and itching under control 5. Oral antipruritics (see doses in Chapter 21), diphenhydramine (Benadryl), hydroxyzine (Atarax®), cetirizine (Zyrtec®), fexofenadine (Allegra®) 6. Systemic corticosteroids a. Oral prednisone 0.5–2 mg/kg per day tapered over 10–21 days for widespread or severe involvement b. Barrier creams: Stokogard® (OTC)–linoleic acid dimer, Hollister Moisture Barrier Ointment® (OTC by Hollister Inc., Libertyville® IL) and Theraseal® Prognosis • Most patients recover from acute hypersensitivity in 14–21 days • Hyposensitization injections not effective and may be unsafe • Oral hyposensitization used mainly for workers in forest industry who cannot avoid contact with toxicodendrons (of questionable value) • Wash skin and clothes with water and soap immediately after contact • Most contact allergens bind to the epidermis and set up response within 0.5–2 h of contact • Chronic exposure to allergens such as rubber, perfumes, preservatives which are not obvious, would benefit from patch testing by a dermatologist skilled in this technique References Bourke J, Coulson I, English J. Guidelines for care of contact dermatitis. Br J Dermatol 2001; 145: 877–85 Drake LA, Dorner W, Goltz RW, et al. Guidelines of care for contact dermatitis. J Am Acad Dermatol 1995: 32: 109–13 Mallory SB. The pediatric patient. In Practical Contact Dermatitis. Guin JD, ed. McGraw-Hill, 1995: 603–21 Maouad M, Fleischer AB, Sherertz EF, Feldman SR. Significance–prevalence index number: a reinterpretation and enhancement of data from the North American Contact Dermatitis Group. J Am Acad Dermatol 1999; 41: 573–6

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Sharma V, Beyer DJ, Paruthi S, Nopper AJ. Prominent pruritic periumbilical papules: allergic contact dermatitis to nickel. Pediatr Dermatol 2002; 19: 106–9 Silverberg NB, Licht J, Friedler S, et al. Nickel contact hypersensitivity in children. Pediatr Dermatol 2002; 19: 110–13 Wildemore JK, Junkins-Hopkins JM, James WD. Evaluation of the histologic characteristics of patch test confirmed allergic contact dermatitis. J Am Acad Dermatol 2003; 49: 243–8

IRRITANT CONTACT DERMATITIS Major points

Figure 4.23 Irritant contact dermatitis – caused by excessive hand washing

• In general, all people will react to an irritant if

• •

• •

applied in a high enough concentration 1. People with atopic dermatitis are more susceptible to irritant dermatitis, especially in dry climates 2. Skin of infants can redden quickly when irritated Characteristic erythematous, pruritic patches and plaques with ill-defined borders Common causes: 1. Hands repeatedly exposed to water, cleansers, or soaps show fissuring or a ‘glazed’ appearance (Figure 4.23) 2. Bubble baths, bleaches, detergents, solvents, acids, alkalis 3. Lip-licking habit – wetting and drying caused by saliva 4. Thumb-suckers in toddlers 5. Perioral area in babies – foods, dribbling saliva and rubbing the area 6. Diaper area secondary to multiple factors such as wetting, maceration, urine, feces Severe forms: chemical burns (alkalis, acids) with vesiculation, necrosis, or ulceration Chronic irritant dermatitis usually lacks vesicles and is characterized by dryness and chapping

• Histology: mild to moderate epidermal spongiosis; epidermal necrosis; usually does not contain eosinophils (as in allergic causes); perivascular lymphocytes and neutrophils Differential diagnosis

• Atopic dermatitis • Allergic contact dermatitis Treatment

• Avoid offending agents • Occlusive pastes (zinc oxide paste) or barrier • •

creams (e.g. Desitin®) Emollients (e.g. petrolatum) Steroids of low to moderate potency

Prognosis

• Benign condition but usually reappears if same circumstances occur References Weedon D. Skin Pathology. Churchill Livingstone: New York, 1997: 88–9

Pathogenesis

• Wetting and drying causes decreased lipids in the •

epidermis with a resultant break in the epidermal barrier Occurs more commonly in atopic patients

Diagnosis

• Clinical findings

DIAPER DERMATITIS Major points

• Irritant diaper dermatitis (chafing dermatitis) 1. Involves convex surfaces of buttocks, upper thighs, abdomen (Figure 4.24)

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3. Satellite red papules or pustules at the periphery are common 4. Frequently occurs after diaper dermatitis has lasted >72 h 5. KOH: budding yeast and pseudohyphae 6. Commonly seen with thrush (oral candidiasis) Seborrheic dermatitis 1. Involves inguinal folds (Figure 4.26) 2. Yellowish-pink scale 3. Cradle cap can be prominent on scalp and a clue to correct diagnosis (Figure 4.27) 4. Typical lesions present elsewhere

Figure 4.24 Diaper dermatitis (irritant) – caused by infrequent diaper changes

a. Spares inguinal folds b. Common between 7 and 12 months of age 2. Ulcerative form a. Marked erythema b. Shallow or deep ulcers (Jacquet ulcers) (Figure 4.25) c. Most frequent around perianal area d. Commonly follows diarrhea Candida albicans dermatitis 1. Beefy-red, confluent erythema (Figure 4.28) 2. Involves inguinal creases

Figure 4.26 Seborrheic dermatitis – erythematous scaling in the diaper area

Figure 4.25 Jacquet ulcers – caused by chronic moisture in an incontinent child

Figure 4.27 on the face

Seborrheic dermatitis – erythematous scaling

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• Minimize irritants

• Figure 4.28 Candidal diaper dermatitis – satellite erythematous papules

1. Use water with or without mild soap 2. Avoid diaper wipes which may contain alcohol, propylene glycol or perfumes 3. Use soft washcloth or soft paper towel for cleaning Candidal infections 1. Topical antifungal therapy (e.g. nystatin, miconazole, ketoconazole, clotrimazole) with every diaper change until clear Erythema 1. Hydrocortisone cream or ointment 1%, 3–4 times a day until clear (usually adults) Erythema and tenderness begin 30 minutes to 4 hours after sun exposure; peaks at 24 hours; may last for 72 hours (Figures 12.1 and 12.2) Most prominent on areas which receive direct light (e.g. nose, cheeks, shoulders) with less reaction in shielded areas (e.g. under nose and chin, and on upper eyelids) With intense exposure: blistering, edema and later desquamation 1. Sleep often disturbed 2. Tenderness of skin 3. Reduced sweating

Skin phototypes

Skin type

Reactivity to sun

Examples

I

Always burns; never tans

Light skin, blond or red hair, blue or brown eyes, and freckles (e.g. Celts)

II

Always burns; tans minimally or lightly

Light skin; red, blond, or brown hair; blue, hazel or brown eyes (e.g. Northern Europeans)

III

Sometimes burns; tans gradually and uniformly

Brown hair, blue or brown eyes (e.g. Southern Europeans)

IV

Burns minimally or never; always tans

Dark brown hair, dark eyes, light brown skin (e.g. Latinos, Asians)

V

Moderately pigmented skin; never burns, always tans well

Medium brown skin, dark brown hair (e.g. Middle Easterners, Latinos)

VI

Deeply pigmented; never burns, always tans well

Dark skin, dark hair (e.g. Black Africans)

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Figure 12.1

Phototoxicity – from excessive sun exposure

Figure 12.2

Phototoxicity from doxycycline

4. In severe burns, collapse from heat stroke, fever, headache and fatigue Ultraviolet light 1. UV light consists of UVA, UVB, UVC 2. UVB does not generate a perception of warmth unless skin is already burned (i.e. a person does not realize the damage until it is too late) 3. On cloudy days, visible light and infrared rays (both cause a sensation of warmth) are filtered out; however, 80% of UVB can get through 4. Much of lifetime sun exposure occurs before 18 years

Pathogenesis

• Acute ultraviolet injury is caused by radiation damage

1. First change is vasodilatation, probably caused by prostaglandins as mediators 2. Metabolic changes occur within epidermal cells, which demonstrate clumping of tonofilaments and abnormalities of cytoplasm and nucleus which produce dyskeratotic ‘sunburn cells’, recognizable by light microscopy. These cells lose their epidermal cell attachments, and produce intraepidermal blisters 3. By 48 hours, damage throughout epidermis 4. By 72 hours, regeneration begins 5. At 96 hours, great increase in number of melanocytes that have arborized their dendrites, beginning the tanning process Tanning response occurs in two distinct phases: 1. Immediate response caused by photo-oxidation of melanin chromoproteins 2. Delayed tanning develops with increased melanosome formation and increased transfer of melanosomes to keratinocytes; starts at 2 days and peaks at 19 days 3. Melanin absorbs UVB and also acts as a ‘sponge’ by mopping up free radicals which damage the epidermis UV radiation effects are cumulative 1. Long-term effects: fine, deep wrinkling, actinic keratoses, skin cancer (especially basal cell carcinoma and squamous cell carcinoma), laxity, mottled pigmentation and telangiectasias 2. Malignant melanoma: more common in patients with a history of several severe sunburns

Diagnosis

• Clinical symptoms and history • Histology: epidermal spongiosis, ‘sunburn cells’

(dyskeratotic damaged epidermal cells), dermal vasodilatation, edema, neutrophils, monocytes, reduced number of Langerhans cells Photosensitizing agents can induce a reaction with short exposure (5–30 minutes) (Table 12.2)

Differential diagnosis

• • • •

Porphyria Lupus erythematosus Viral eruptions (e.g. fifth disease) Xeroderma pigmentosum

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Table 12.2

4. Topical anesthetics (e.g. benzocaine) can be sensitizing and only bring temporary relief. Not recommended 5. Efficacies of topical aloe vera, jojoba oil and vitamin E have not been well studied

Exogenous photosensitizers

Examples Drugs

Antibiotics (sulfonamides, tetracyclines, griseofulvin), phenothiazines, diuretics (furosemide, thiazides), quinine, isoniazid, tranquilizers, antidepressants, antiinflammatory agents (naproxen), antiarrhythmics, antihypertensives

Plants

Furocoumarins

Dyes

Methylene blue, toluidine blue, xanthenes, fluorescein, eosin, erythrosine, acridine

Polycyclic hydrocarbons

Pitch, coal tars, anthracene, acridine, fluoranthrene

Perfumes/ cosmetics

Bergamot oil, musk ambrette, 6-methylcoumarin, halogenated salicylanilides

Sunscreens

PABA, benzophenones, cinnamates

Tatoos

Cadmium sulfide

Treatment

• Prevention

1. Good sun protection habits should be stressed at an early age 2. Infants 1 h. Some improvement or resolution with time 2. Actinic prurigo (Hutchinson summer prurigo) a. Most commonly seen in school-aged children b. More common in Native Americans c. Dermatitis starts in the early spring with acute itchy facial and forearm dermatitis with edematous papules and vesicles d. With time, crusting, thickening and lichenification e. Eruption clears, only to recur the next spring; however, some children have the eruption all year f. Chronic cheilitis, especially of the lower lip g. Autosomal dominant in some families 3. Juvenile spring eruption (hydroa aestivale) a. Primarily seen in northern European boys, aged 5–12 years b. Discrete papules of 2–3 mm or vesicles on ears and cheeks lasting about a week (Figure 12.5) c. Tends to recur each spring d. Some patients develop more typical papular PMLE

Figure 12.5

Juvenile spring eruption – limited to the ears

4. Hydroa vacciniforme a. Discrete, deep-seated vesicles on ears, nose and face which lead to hemorrhage and scarring b. Lesions last up to 4 weeks c. Occasional keratitis and uveitis d. Begins before age 10 years e. Male/female ratio >1 f. Rare Pathogenesis

• Considered to be caused by delayed-type • •

hypersensitivity response to a UV radiationinduced antigen One-quarter of affected individuals sensitive to UVB alone, one-quarter to UVB and UVA together, and one-half to UVA only Probably genetic, with incomplete expression and penetrance

Diagnosis

• Suspect diagnosis on clinical basis. Biopsy or phototesting may be needed

• Histology shows: 1. Superficial and deep lymphocytic infiltrate 2. Papillary dermal edema and hemorrhage 3. Variable epidermal changes

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4. Spongiotic dermatitis resembling eczema 5. Late lesions demonstrate chronic infiltration of lymphocytes and spongiosis Differential diagnosis

• • • • • • • • •

Atopic dermatitis Contact dermatitis Systemic lupus erythematosus Erythropoietic protoporphyria Sunburn/phototoxicity Photoallergic reactions Tinea corporis Drug-induced photosensitivity Solar urticaria

Treatment

• Sun avoidance • Restriction of daily activities outdoors between 10.00 and 16.00 (peak UV times)

Hann SK, Im S, Park Y-K, Lee S. Hydroa vacciniforme with unusually severe scar formation: diagnosis by repetitive UVA phototesting. J Am Acad Dermatol 1991; 25: 401–3 Hasan T, Ranki A, Jansen CT, Karvonen J. Disease associations in polymorphous light eruption. Arch Dermatol 1998; 134: 1081–5 Leenutaphong V. Hydroa vacciniforme: an unusual clinical manifestation. J Am Acad Dermatol 1991; 25: 892–5 Patel DC, Bellaney GJ, Seed PT, et al. Efficacy of short-course oral prednisolone in polymorphic light eruption: a randomized controlled trial. Br J Dermatol 2000; 143: 828–31 Rhodes LE. Polymorphic light eruption reassessed. Arch Dermatol 2004; 140: 351–2 van de Pas CB, Hawk JL, Young AR, Walker SL. An optimal method for experimental provocation of polymorphic light eruption. Arch Dermatol 2004; 140: 286–92 Van Praag MCG, Boom BW, Vermeer BJ. Diagnosis and treatment of polymorphous light eruption. Int J Dermatol 1994; 33: 233–8

• Clothing: wide-brimmed hat, long-sleeved shirt and sunscreens

• Topical corticosteroids in an ointment vehicle 2–3 times a day

• Wet dressings for acute weeping lesions • Treatment of secondary bacterial infection if • • • •

present β-carotene (Solatene) 60–180 mg/day for an adult For severe cases, oral psoralen plus UVA (PUVA) under controlled conditions may help induce hardening Frequent follow-up visits if dermatitis is not under control; less frequent as child improves Hydroxychloroquine (Plaquenil®) 100–200 mg BID (adult dose) for severe cases

Prognosis

• Variable; some patients may improve with time or with chronic sun exposure; however, many patients continue to have symptoms

Solar urticaria Major points

• Pruritic wheals occur within minutes of sun exposure and last 10 years of age • Tolerance (i.e. ‘hardening’) can occur after repeated exposure

• Onset usually between 10 and 50 years of age • Slight female predominance Pathogenesis

• Allergic response to photo-induced allergen • Mast cells play a major role • Types of solar urticaria based on action spectra: usually visible light, but UVA and UVB or combinations may be responsible

References

Diagnosis

Boonstra HE, van Weelden H, Toonstra J, van Vloten WA. Polymorphous light eruption: a clinical, photobiologic, and follow-up study of 110 patients. J Am Acad Dermatol 2000; 42: 199–207

• Clinical characteristics • Histology: similar to urticaria with dermal edema,

Fusaro RM, Johnson JA. Hereditary polymorphic light eruption of American Indians: occurrence in non-Indians with polymorphic light eruption. J Am Acad Dermatol 1996; 34: 612–17

Differential diagnosis

perivascular neutrophilic and eosinophilic infiltrates

• Urticaria • Polymorphous light eruption

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• Porphyria • Drug reactions Treatment • Sun avoidance with clothing and sunscreens • Nonsedating antihistamines • Systemic steroids (short course for 5–10 days) initially may be helpful • PUVA may induce tolerance

Beattie PE, Dawe RS, Ibbotson SH, Ferguson J. Characteristics and prognosis of idiopathic solar urticaria: a cohort of 87 cases. Arch Dermatol 2003; 139: 1149–54 Grabbe J. Pathomechanisms in physical urticaria. Symposium Proceedings. J Invest Dermatol 2001; 6: 135–6 Roelandts R. Diagnosis and treatment of solar urticaria. Dermatol Ther 2003; 16: 52–6

GENODERMATOSES WITH SUN SENSITIVITY Porphyria Major points

• Group of disorders of porphyrin metabolism •

which can have sun sensitivity as a primary feature (Table 12.3) Erythropoietic protoporphyria (EPP) 1. Most common type in children 2. Usually presents in preschool child with burning, itching or stinging of skin after short exposure to sun, even through window glass 3. Younger children may be irritable but may not have typical skin lesions 4. Intense sun exposure may result in severe facial edema, urticaria, vesiculation and crusting 5. Chronic changes: thickened skin-colored papules on the dorsal hands, and pitted scarring on nose and face (Figures 12.6 and 12.7) 6. Perioral linear papules may result from previous vesicular damage

Pathogenesis • Caused by enzyme defects in heme biosynthesis which lead to blockade of porphyrin

pathway and accumulation of porphyrins and precursors Porphyrin molecules absorb visible light and generate molecular level excited states leading to free radical formation with subsequent cell membrane damage and cell death

Diagnosis

• Histology: thickening of superficial blood vessels

Prognosis • May be chronic and intermittent References

205

and a perivascular deposit of periodic acid-Schiff (PAS)-positive material which, on direct immunofluorescence, contains IgG Blood, urine and stool porphyrin levels have characteristic patterns

Differential diagnosis • Phototoxicity • Photoallergic reactions • Polymorphous light eruption • Solar urticaria • Contact dermatitis Treatment • Sun avoidance with clothing and sunscreens blocking UVA (physical sunscreens with titanium dioxide are best) • β-carotene (Solatene) 60–180 mg/day may be helpful • Because of potential chronic liver changes, liver function tests should be followed every 6–12 months • Genetic counseling advised. Family members should be screened and liver functions followed • Low-dose hydroxychloroquine Prognosis • Chronic, life-long sun sensitivity, skin damage and possible liver disease References Ahmed I. Childhood porphyrias. Mayo Clin Proc 2002; 77: 825–36 Bruce AJ, Ahmed I. Childhood-onset porphyria cutanea tarda: successful therapy with low-dose hydroxychloroquine (Plaquenil). J Am Acad Dermatol 1998; 38: 810–14 Cummins R, Wagner-Weiner L, Paller A. Pseudoporphyria induced by celecoxib in a patient with juvenile rheumatoid arthritis. J Rheumatol 2000; 27: 2938–40 De Silva B, Banney L, Uttley W, et al. Pseudoporphyria and nonsteroidal antiinflammatory agents in children with juvenile idiopathic arthritis. Pediatr Dermatol 2000; 17: 480–3

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Table 12.3

Porphyrias

Type

Characteristics

Erythropoietic porphyria (EP)

Begins in infancy Uroporphyrinogen III Marked photosensitivity with pain synthetase (UROS) Vesicles, bullae Gene locus: 10q25.2-q26.3 Hypertrichosis Autosomal recessive Mutilating scars Hemolytic anemia Splenomegaly Erythrodontia

Gene

Laboratory investigations Urine: elevated URO I, COPRO I Urine: fluorescent Stool: elevated COPRO I Blood: fluorescent RBCs

Erythropoietic protoporphyria (EPP)

Onset in first decade Ferrochelatase (FECH) Mild to severe Gene locus: 18q21.3 photosensitivity Autosomal dominant Burning, stinging after sun exposure Edematous plaques with erythema, purpura Waxy or depressed scars on nose, dorsal hands Liver: cholelithiasis, hepatic failure

Blood: elevated FEP Blood: elevated RBC & plasma PROTO Blood: fluorescent RBCs Urine: normal porphyrins Stool: elevated PROTO

Acute intermittent Onset 2nd to 4th decade porphyria (AIP) No photosensitivity Recurrent attacks of abdominal pain, weakness, neuropathy, behavioral changes Attacks precipitated by drugs, events

PBG deaminase Gene locus: 11q23.3 Autosomal dominant

Urine: elevated ALA, PBG during attacks Stool: ALA, PBG during attacks Blood: plasma neg, RBC neg

Porphyria cutanea tarda (PCT)

Onset in 3rd to 4th decade Moderate photosensitivity Bullae, fragility, scars, milia, hyperpigmentation, facial hypertrichosis Precipitated by alcohol, estrogens, iron, hydrocarbons Liver iron overload

Uroporphyrinogen decarboxylase (UROD) Gene locus: 1p34 Autosomal dominant or sporadic

Urine: URO I>III, ISOCOPRO Stool: ISOCOPRO>PROTO Plasma + RBC neg

Variegate porphyria (VP)

Onset 2nd to 3rd decade Photosensitivity similar to PCT Acute attacks simlar to AIP Common in South Africa

Protoporphyrinogen oxidase Gene locus: 1q22, 6p21.3 Autosomal dominant

Urine: ALA and PBG elevated during attacks Urine: elevated URO & COPRO between attacks Stool: PROTO>COPRO both elevated during and between attacks

Hereditary coproporphyria (HCP)

Onset any age Skin lesions resemble PCT but milder Attacks like AIP but milder

Coproporphyrinogen oxidase Gene locus: 3q12 Autosomal dominant

Stool: COPRO III elevated during and between attacks Urine: COPRO III elevated during and between attacks Elevated ALA, PBG only during attacks

ALA, delta-aminolevulinic acid; PBG, porphobilinogen; URO, uroporphyrin; COPRO, coproporphyrin; PROTO, protoporphyrin; ISOCOPRO, isocoproporphyrin; RBCs, red blood cells; FEP, free erytrocyte protoporphyria

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Paller AS, Eramo LR, Farrell EE, et al. Purpuric phototherapy-induced eruption in transfused neonates: relation to transient porphyrinemia. Pediatrics 1997; 100: 360–4 Pandhi D, Suman M, Khurana N, Reddy BSN. Congenital erythropoietic porphyria complicated by squamous cell carcinoma. Pediatr Dermatol 2003; 20: 498–501 Poh-Fitzpatrick MB, Wang X, Anderson KE, et al. Erythropoietic protoporphyria: altered phenotype after bone marrow transplantation for myelogenous leukemia in a patient heteroallelic for ferrochelatase gene mutations. J Am Acad Dermatol 2002; 46: 861–6 Figure 12.6 hands

Erythropoietic protoporphyria – scars on

Xeroderma pigmentosum Major points

• Presents in infancy with extreme sun sensitivity • By 18 months of age, early sunburn reactions and • • • • • • • Figure 12.7 the face

Porphyria cutanea tarda – hypertrichosis on

freckling are evident after minimal sun exposure (Figure 12.8) Sunburn reactions persist for weeks Telangiectasias and atrophy of skin Actinic keratoses develop as red, scaly persistent macules and papules on sun-exposed areas In darker skinned patients, findings may be more subtle By 6–8 years, multiple basal cell carcinomas, squamous cell carcinomas and malignant melanoma are common Ocular findings, particularly photophobia and decreased vision, occur in ~20% Mild to severe mental retardation, especially evident in De Sanctis–Cacchione syndrome

Pathogenesis Fritsch C, Bolsen K, Ruzicka T, Goerz G. Congenital erythropoietic porphyria. J Am Acad Dermatol 1997; 36: 594–610 Gross U, Hoffmann GF, Doss MO. Erythropoietic and hepatic porphyrias. J Inherit Metab Dis 2000; 23: 641–61 Huang J-L, Zaider E, Roth P, et al. Congenital erythropoietic porphyria: clinical, biochemical, and enzymatic profile of a severely affected infant. J Am Acad Dermatol 1996; 34: 924–7 LaDuca JR, Bouman PH, Gaspari AA. Nonsteroidal antiinflammatory drug-induced pseudoporphyria: a case series. J Cutan Med Surg 2002; 6: 320–6

• Defective repair of ultraviolet radiation damage to

• •

pyrimidine dimers in DNA in many cell types (e.g. epidermal cells, fibroblasts, lymphocytes, corneal cells, liver cells) Group A: most severe form; exhibits skin and central nervous system disorders (severe or mild) (DeSanctis–Cacchione syndrome); gene locus/gene: 9q22.3/ XPA Group B: gene locus/gene: 2q21/ ERCC3, XPB Group C: usually have only skin disorders; most common in USA, Europe, Egypt; gene locus/gene: 3p25/ XPC

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• Prevention with complete sun avoidance: sun • •

protective clothing, sunscreens, and night time habits of outdoor activities Should ideally be followed at a center which is familiar with this condition and treatment of skin cancers Frequent visits are important to evaluate incipient tumors

Prognosis

• Prognosis is poor. Morbidity from chronic skin cancers requiring surgery. Early death from metastatic skin cancer or melanoma. Some types have a better prognosis References Bootsma D, Hoeijmakers JHJ. The genetic basis of xeroderma pigmentosum. Ann Genet 1991; 34: 143–50 Figure 12.8 Xeroderma pigmentosum – multiple lentigines and scarring from previous skin cancer removal

• Group D: skin cancer, CNS disorders; may have • • •

Cockayne syndrome or trichothiodystrophy; gene locus/gene: 19q13.2-q13.3/ ERCC2, EM9 Group E: few skin cancers, excision repair 40–50% of normal, gene locus: 11p12-p11 Group F: mild skin symptoms, excision repair 10–20% of normal; gene locus: 16p13.3-p13.13; gene: ERCC4 Group G: mental retardation, neurological abnormalities, photosensitivity, excision repair 1 Gene locus: 15q26.1 Gene: BLM, RECQ3 helicase; protein product is member of DNA helicase

References Chisholm CA, Bray MJ, Karns LB. Successful pregnancy in a woman with Bloom syndrome. Am J Med Genet 2001; 102: 136–8

• • • •

209

edematous plaques sometimes accompanied by blistering Photosensitivity Ocular abnormalities Hyperkeratoses of palms, soles, hands, wrists, ankles and elsewhere (squamous cell carcinoma may develop) Scalp hair sparse and fine, may progress to partial or total alopecia Short stature (2 million children abused in USA per • •

year; 55% neglect, 27% physical, 16% sexual, 8% emotional Many teens run away from home 1200–1300 fatalities per year; 50% are 50%) 2. Trimethoprim–sulfamethoxazole (incidence >60% in HIV patients) 3. Penicillin derivatives 4. Antiepileptic drugs

Urticaria

• Red wheals occur which are very pruritic, ranging • Figure 13.2 Morbilliform drug eruption from trimethoprim–sulfamethoxazole

• •

• Usual time period between ingestion and drug • • • •

eruption is 1–2 weeks Rash usually lasts 1–2 weeks Low-grade fever common Rash may not recur with rechallenge Main causes: Table 13.2

• • •

in size from pinpoint to >20 cm and last 40°C Arthralgias/arthritis Pulmonary symptoms (shortness of breath, wheezing) Hypotension Laboratory abnormalities Abnormal liver function tests Elevated eosinophil count Atypical lymphocytosis Drugs implicated Allopurinol Amoxicillin Ampicillin Carbamazepine Lamotrigine Phenobarbital Phenylbutazone Phenytoin Piroxicam Sulfadiazine Sulfadoxime Sulfamethoxazole–trimethoprim Sulfasalazine Valproic acid Adapted from: Stern RS, Wintroub BU. Cutaneous reactions to drugs. In Fitzpatrick’s Dermatology in General Medicine, 5th edn. Freedberg IM, Eisen AZ, Wolff K, et al. McGraw Hill: New York, 1999: 1633–42

4. Mucous membrane findings subtle (erythema, petechiae) Systemic involvement 1. Liver (61%) 2. Hematologic (48%) – eosinophilia, leukocytosis, reactive lymphocytosis, leukopenia, anemia

Figure 13.5 Toxic epidermal necrolysis – with sheets of denuded epidermis

• •

3. Renal (15%) 4. Pulmonary (14%) 5. Spleen 6. Myositis 7. Pancreatitis Can be associated with recent viral or bacterial infection (e.g. EBV, hepatitis B, parvovirus, Streptococcus, Mycoplasma) Treatment 1. Oral prednisone 0.5–2.0 mg/kg per day 2. Topical steroids 3. Supportive care 4. May need hospitalization Pathogenesis 1. Possible defect in epoxide hydrolase enzymatic pathway which normally degrades toxic arene oxide metabolites formed during oxidation of antiepileptics; arene oxide metabolites may be directly cytotoxic or act as haptens, leading to hypersensitivity reaction 2. Sulfonamides – possible defect in glutathione transferase-mediated enzymatic breakdown

Serum sickness

• Type III immune complex disease caused by deposition of circulating immune complexes in

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Table 13.4 Drugs associated with hypersensitivity syndrome

Aromatic anticonvulsants Carbamazepine Phenobarbital Phenytoin Primidone Nonaromatic anticonvulsants Lamotrigine Valproic acid Ethosuxidimide Sulfa drugs Dapsone Sulfasalazine Sulfonamides Sulfamethoxazole Others Allopurinol Diltiazem Minocycline Terbinafine

Figure 13.6 phenytoin

Drug-induced hypersensitivity from

blood vessels and other tissues, activating the complement cascade Characterized by urticaria, morbilliform eruption, vasculitis, fever, arthralgia, lymphadenopathy, gastrointestinal disturbance, renal disease

Serum sickness-like reaction

• Characterized by rash (urticarial, maculopapular,

• • •

erythema multiforme-like angioedema), fever, arthralgias, lymphadenopathy, eosinophilia (Figure 13.8) No circulating immune complexes, vasculitis or renal disease Usually starts 1–3 weeks after administration of offending drug Common drugs: cefaclor, amoxicillin, ampicillin, β-blockers, cefprozil, cephalexin, doxycycline, minocycline, penicillin, sulfonamide

Figure 13.7 Drug-induced hypersensitivity from phenytoin with erythematous plaques

• Common drugs: 1. Oral contraceptives 2. Sulfonamides 3. Sulfonylureas

Erythema nodosum

• Red, tender subcutaneous nodules, usually located on the anterior lower legs

• May be caused by drugs, infection, inflammatory bowel disease or other causes

Photosensitivity eruptions See Table 13.5 • Action spectrum is long-wave ultraviolet light (UVA)

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Table 13.5 Drugs and chemicals that cause photosensitivity reactions

Antidepressants Amitriptyline Doxepin Nortriptyline

Figure 13.8 Serum sickness-like eruption from a cephalosporin

Antihistamines Cyproheptadine

Diphenhydramine

Antimetabolic drugs Actinomycin Doxorubicin 5-fluorouracil

Methotrexate Vinblastine Hydroxyurea

Antimicrobials Ciprofloxacin Doxycycline Enoxacin Griseofulvin Minocycline Nalidixic acid Sulfasalazine Tetracycline Sulfamethoxazole–trimethoprim

• Phototoxic reactions are characterized by an

Desipramine Imipramine

exaggerated sunburn reaction 1. Does not involve immunologic mechanisms 2 Severity is dose-related 3. Phototoxic agents generally have a resonating chemical structure capable of absorbing photons of ultraviolet light and moving to an excited state, thus producing damage to cells 4. Examples: psoralen, tetracyclines Photoallergic responses involve primarily type IV reactions 1. Not dose-related 2. Occurs in a sensitized individual 3. Examples: chlorpromazine, sulfanilamide, thiazides, sulfonylureas Topical photosensitizers 1. Drug applied to the skin and exposed to light causing an eczematous eruption 2. Examples: para-amino benzoic acid (PABA), phenothiazines, coal tar, oil of bergamot, psoralens

Antiparasitic drugs Chloroquine

Quinine

Diuretics Acetazolamide Furosemide

Chlorothiazide Hydrochlorothiazide

Nonsteroidal anti-inflammatory drugs Ketoprofen Naproxen Piroxicam Sulindac Psychiatric drugs Chlorpromazine Haloperidol Tricylic antidepressants Other agents Acetretin Captopril Gold salts Oral contraceptives Psoralen

Amiodarone Carbamazepine Isotretinoin Promethazine Quinidine

Lichenoid drug eruption

• Purple-red, flat-topped, pruritic papules, similar to • •

lichen planus Often photo-distributed Examples: gold, antimalarials, phenothiazines, captopril, β-blockers and thiazide diuretics

Fixed drug eruption

• Well-demarcated, red to brown plaque with dusky center

• Lesions appear at the same sites after each administration of the medication

• May become vesicular or bullous periodically with

introduction of the offending medicine; chronically becomes a hyperpigmented patch (Figure 13.9) Location is usually hands, feet, face and genitalia, but can occur anywhere, including mucosal surfaces

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Figure 13.9 Fixed drug eruption – with typical dark center and erythematous halo

• Lesions are solitary or multiple • Common offenders: 1. 2. 3. 4. 5. 6. 7. 8.

Trimethoprim–sulfamethoxazole Ampicillin Amoxicillin Erythromycin Phenolphthalein Tetracycline Barbiturates Ibuprofen

Figure 13.10 minocycline

3. 4. 5. 6.

Gray pigmentation of the skin – caused by

Antimalarials Cytotoxic agents (bleomycin) Hydantoin Tetracyclines

Lupus-like reactions

Vasculitis

• Difficult to tell the difference between lupus and

• Palpable purpura with concentration on the lower

• • • •

drug-induced lupus reaction Erythema in the butterfly malar distribution and V of the neck Usually: antinuclear antibody-positive, antihistone antibody-positive, antidouble-stranded DNA antibody-negative Renal involvement less common in drug-induced lupus Examples: minocycline, procainamide, hydralazine (in patients who are slow acetylators), isoniazid, phenytoin, penicillamine

• •

extremities May involve other organs (e.g. liver, kidney, brain and joints) Examples: penicillin, phenytoin, thiazides

Acneiform eruptions

• Follicular papules and pustules in an acne •

distribution, often sudden in onset Causes: corticosteroids, oral contraceptives, halogens, hydantoin, lithium

Pigmentary changes

Alopecia

• Mechanisms: drugs stimulate melanocytic activity

• Anagen arrest caused by cytotoxic agents • Telogen effluvium caused by anticoagulants, oral

or deposit drug in tissues (Figure 13.10) Examples: 1. Heavy metals (gold, silver, mercury) 2. Phenothiazines

contraceptives and β-blockers

• Androgenetic alopecia caused by oral contraceptives

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SPECIFIC DRUGS CAUSING REACTIONS Penicillin

• Reactions range from 16 to 52 per 1000 recipients or 5–10% of the population

• Increased use of penicillin increases the risk of developing allergy

• Route of administration: parenterally administered • •

• •

drugs cause more reactions than those administered orally Certain diseases (e.g. infection with EBV, HIV, cytomegalovirus (CMV), etc.) may cause an increased risk of reaction Manifestations: 1. Maculopapular and/or papulosquamous reactions most common (associated with IgM antibodies) 2. Urticarial reactions – risk of developing anaphylaxis on subsequent exposure Penicillin can cause any of the four types of immunologic reactions Testing available to diagnose allergy to certain components of penicillin

Cephalosporins

Figure 13.11

Antiepileptic drugs

• Characteristic syndrome of maculopapular rash,

• • •

• Erythema which progresses to ‘purple urticaria’ • • •

(not true erythema multiforme), with cutaneous swelling (especially feet), migratory pruritic lesions No adenopathy Serum-sickness-like picture Hypersensitivity occurs in ~3% of patients

Corticosteroids

• Occurs from oral, parenteral, or topical application •

of corticosteroids Manifestations: 1. Acneiform eruptions 2. Striae (Figure 13.11) 3. ‘Moon facies’ caused by fat deposition in the cheeks 4. ‘Buffalo hump’ caused by fat deposition on the upper back 5. Telangiectasias 6. Atrophy 7. Masking of other dermatoses (e.g. tinea, scabies)

Striae caused by corticosteroids

fever, facial edema, lymphadenopathy, leukocytosis, hepatitis, nephritis, pneumonitis (see Drug-induced hypersensitivity) Most patients develop this syndrome within 2 months of starting the drug Cross-sensitivity with phenytoin, carbamazepine and phenobarbital Lamotrigine, which is structurally dissimilar, can also cause this reaction

Tetracyclines

• • • • • • • • •

Phototoxic reactions Onycholysis Fixed drug eruptions Staining of teeth Hyperpigmentation Serum sickness-like reactions Drug-induced lupus (e.g. minocycline) Urticaria Morbilliform eruptions

Gold

• Reactions occur in about one-third to one-half of patients

• Clinical manifestations: 1. Lichenoid reactions 2. Papulosquamous reactions (resembling pityriasis rosea) 3. Exfoliative dermatitis

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Drug eruptions

4. Morbilliform eruptions 5. Erythema nodosum Chrysiasis can occur after prolonged use, resulting from deposition of gold salts in the skin, causing blue pigmentation of the skin and ocular conjunctiva

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• Vasculitis • Pseudoporphyria – blistering, erosions and scarring on dorsa of hands, and bridge of nose

Coumadin

• Sharply – demarcated, erythematous, purpuric Antimetabolites (chemotherapy)

• Anagen effluvium (alopecia) caused by the sudden • • • •

weakening of hair and subsequent breakage Stomatitis caused by toxic effect on mucosal cells which have a high mitotic rate Acneiform eruptions (e.g. actinomycin-D) Onychodystrophy (e.g. bleomycin, hydroxyurea, 5-fluorouracil) Chemical cellulitis/phlebitis/ulceration from intravenous extravasation

Lithium

plaques which become necrotic and form an eschar

• Lesions occur between days 3 and 10 of anticoagulant therapy

• Thrombosis due to a relative drop in circulating protein C levels Pathogenesis

• Molecular characteristics

• Aggravation of acne and psoriasis Iodides and bromides

• Acneiform eruptions • Granulomatous fungating lesions (halogenodermas)

Antimalarials

• Increased pigmentation (black or yellow) of skin • •

and mucous membranes Lichenoid eruptions Erythema annulare centrifugum

Sulfonamides and thiazides

• Thiazides are substituted sulfonamides and may • • • • •

cross-react with sulfonamide antibiotics Urticaria Morbilliform eruptions Erythema multiforme Vasculitis Toxic epidermal necrolysis

Nonsteroidal anti-inflammatory drugs

• Morbilliform eruptions • Bullous fixed drug eruptions

1. Increases in molecular size and complexity are associated with increased immunologic reactions 2. Small molecules form stable bonds with tissue macromolecules forming haptens Environmental/other factors 1. Viral infections can alter the host response, increasing the frequency of reactions (e.g. mononucleosis or HIV plus ampicillin-induced morbilliform eruptions) 2. Light exposure with photoallergic reactions (e.g. tetracyclines) 3. Associated diseases: systemic lupus erythematosus predisposes to developing reactions 4. Genetic factors: deficiency in epoxide hydrolase, an enzyme required for metabolism of a toxic epoxide derived from aromatic anticonvulsants such as phenytoin, carbamazepine and phenobarbital Nonimmunologic methods 1. Drugs may release mast cell mediators directly, causing urticaria (e.g. opiates, curare, radiocontrast media) 2. Drugs may activate complement in the absence of antibody 3. Drugs may alter the pathway of arachidonic acid metabolism (e.g. aspirin) 4. Individual metabolic variation (e.g. defect in clearing reactive intermediate metabolites with thiazides and sulfonamides) Type 1 immunologic reactions: 1. Mediated by IgE 2. Result in varying degrees of urticaria, pruritus, bronchospasm and anaphylaxis

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3. Immediate reactions occur within minutes after exposure 4. Accelerated reactions occur hours or days after drug exposure 5. Production of IgE directed against the drug or drug–hapten complex 6. Drug molecules in general are usually small enough so that they cannot initiate an immune reaction by themselves but require a carrier protein 7. Re-exposure to drug plus antibodies of IgE cause mast cells to release histamine, slow reacting substance of anaphylaxis (SRS-A), eosinophil chemotactic factor of anaphylaxis, neutrophil chemotactic factors and platelet activating factor 8. Examples: penicilloyl polylysin Type 2 immunologic reactions (cytotoxic antibody reaction): 1. Mediated by cytotoxic antibodies 2. Specific antigens combine with endogenous tissue components which, when combined, act as an antigen, stimulating the formation of antibodies 3. Antibodies coat the target tissue and stimulate complement activation and tissue destruction Type 3 immunologic reactions (immune complex reaction): 1. Most drug reactions are caused by this type of reaction: serum sickness, possibly erythema multiforme and erythema nodosum 2. Classic reaction pattern is serum sickness with fever, arthritis, nephritis, neuritis, edema and urticarial or morbilliform eruptions 3. Symptoms develop >6 days after exposure 4. Drug or drug–protein complex acts as an antigen, which stimulates antibody production 5. Sensitization occurs during first exposure with subsequent antibody formation, usually IgG or IgM 6. When the concentration of antibodies is high enough, there is formation of large immune complexes 7. Various sizes of immune complex result; size depends upon the rate of antibody production and immune complex clearance rates 8. Some immune complexes deposit in the peripheral circulation, where they stimulate inflammation and destroy local tissues

9. Products of the complement cascade, especially C5a and C3a, can degranulate mast cells causing urticaria Type 4 immunologic reactions (cell-mediated type): 1. Keratinocytes are activated and express various cytokines 2. Associated with morbilliform reactions to some oral drugs (e.g. amoxicillin) 3. Common as the cause of contact dermatitis (e.g. neomycin) Fixed drug eruption: 1. Histology: superficial and deep perivascular infiltrate with lymphocytes, eosinophils, some neutrophils and necrotic keratinocytes in the epidermis 2. Hypothesis that intercellular adhesion molecule1 (ICAM-1) plays a role in site restriction

Diagnosis

• Clinical evaluation:

1. History of taking drug 2. Alternative explanations for the rash (e.g. viral causes, contact history) 3. Timing of drug exposure with flow chart 4. Removal of the offending agent 5. Response to rechallenge Laboratory tests: 1. Drug levels 2. Complete blood count with differential 3. Liver function tests 4. Specific drug evaluations: a. Penicillin: skin tests b. Radioallergosorbent test (RAST) measures specific serum IgE against specific drug Histology: 1. Sparse mixed inflammatory cell infiltrate with eosinophils 2. Slight vacuolar alteration 3. Scattered dyskeratotic keratinocytes 4. Lichenoid drug eruption resembles lichen planus with eosinophils and a deep infiltrate 5. Fixed drug eruption shows keratinocyte necrosis, melanophages in the papillary dermis and a superficial and deep infiltrate

Differential diagnosis

• Morbilliform drug eruptions 1. Viral eruption 2. Miliaria rubra

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Drug eruptions

• • • •

3. Graft-versus-host disease 4. Kawasaki syndrome Urticaria 1. Insect bites 2. Vasculitis Erythema multiforme 1. Urticaria 2. Kawasaki syndrome Erythema nodosum 1. Ecchymoses 2. Vasculitis Photosensitive eruptions 1. Sunburn 2. Contact dermatitis 3. Eczema Lupus-like reactions 1. Systemic lupus erythematosus

Treatment • Discontinue offending drug • Supportive therapy as indicated by clinical picture • Corticosteroids early (prednisone 1–2 mg/kg per day) • Antihistamines • Topical antipruritic agents • Baths, with or without additives (e.g. oatmeal) • Intravenous immunoglobulins for toxic epidermal necrolysis • If patient is at risk for anaphylaxis or severe reaction, a medical alert bracelet is warranted • Consider desensitization if drug is necessary Prognosis

• Resolution with cessation of drug • Some pigmentation or scarring can be permanent References Barbaud AM, Bene M-C, Schmutz J-L, et al. Role of delayed cellular hypersensitivity and adhesion molecules in amoxicillin-induced morbilliform rashes. Arch Dermatol 1997; 133: 481–6 Callot V, Roujeau J-C, Bagot M, et al. Drug-induced pseudolymphoma and hypersensitivity syndrome. Arch Dermatol 1996; 132: 1315–21 Carroll MC, Yueng-Yue KA, Esterly NB, Drolet BA. Druginduced hypersensitivity syndrome in pediatric patients. Pediatrics 2001; 108: 485–93 Caumes E, Guermonprez G, Lecomte C, et al. Efficacy and safety of desensitization with sulfmethoxazole and trimethoprim in 48 previously hypersensitive patients infected with human immunodeficiency virus. Arch Dermatol 1997; 133: 465–9

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Chosidow O, Bourgault I, Roujeau J-C. Drug rashes. What are the targets of cell-mediated cytotoxicity? Arch Dermatol 1994; 130: 627–9 Gonzalez E, Gonzalez S. Drug photosensitivity, idiopathic photodermatoses, and sunscreens. J Am Acad Dermatol 1996; 35: 871–85 Halevy S, Shai A. Lichenoid drug eruptions. J Am Acad Dermatol 1993; 29: 249–55 Hawfield W, Goodrich R, Warren S, Morrell D. Traumainduced cutaneous pigmentation from tetracycline: a case report. Pediatr Dermatol 2004; 21: 164–6 Hebert AA, Sigman ES, Levy ML. Serum sickness-like reactions from cefaclor in children. J Am Acad Dermatol 1991; 25: 805–8 Huang Y-L, Hong H-S, Wang Z-W, Kuo T-T. Fatal sodium valproate-induced hypersensitivity syndrome with lichenoid dermatitis and fulminant hepatitis. J Am Acad Dermatol 2003; 49: 316–19 Kaur S, Sarkar R, Thami G, Kanwar AJ. Anticonvulsant hypersensitivity syndrome. Pediatr Dermatol 2002; 19: 142–5 Lee WM. Drug-induced hepatotoxicity. N Engl J Med 1995; 333: 1118–27 Levy ML, Barron KS, Eichenfield L, Honig PJ. Naproxeninduced pseudoporphyria: a distinctive photodermatitis. J Pediatr 1990; 117: 660–4 Litt JZ. Drug Eruption Reference Manual, 9th edn. Parthenon Publishing: New York, 2003 Ming ME, Bhawan J, Stefanato CM, et al. Imipramineinduced hyperpigmentation: four cases and a review of the literature. J Am Acad Dermatol 1999; 40: 159–66 Morelli JG, Tay Y-K, Rogers M, et al. Fixed drug eruptions in children. J Pediatr 1999; 134: 365–7 Nigen S, Knowles SR, Shear NH. Drug eruptions – approaching the diagnosis of drug-induced skin diseases. J Drugs Dermatol 2003; 3: 278–99 Sehgal VN, Srivastava G, Sardana K. Erythroderma/exfoliative dermatitis: a synopsis. Int J Dermatol 2004; 43: 39–47 Shapiro LE, Shear NH. Drug interactions: proteins, pumps, and p-450s. J Am Acad Dermatol 2002; 47: 467–84 Shapiro LE, Knowles SR, Shear NH. Comparative safety of tetracycline, minocycline and doxycycline. Arch Dermatol 1997; 133: 1224–30 Stern RS, Wintroub BU. Cutaneous reactions to drugs. In Fitzpatrick’s Dermatology in General Medicine, 5th edn. Freedberg IM, Eisen AZ, Wolff K, et al., eds. McGraw Hill: New York, 1999: 1633–42 Tristani-Firouzi P, Petersen MJ, Saffle JR, et al. Treatment of toxic epidermal necrolysis with intravenous immunoglobulin in children. J Am Acad Dermatol 2002; 47: 548–52

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14 PIGMENTARY DISORDERS

LINES OF BLASCHKO

HYPERPIGMENTED DISORDERS

• A form of mosaicism with two or more genetically

Postinflammatory hyperpigmentation

• • •

distinct cell lines arising from a postzygotic somatic mutation (see Table 17.1) Follow segmental and linear skin lines which are V-shaped or a circling pattern on the chest and a linear distribution on the extremities Should not be confused with dermatomes, which are areas of the skin innervated by sensory nerves Can be hypopigmented (e.g. hypomelanosis of Ito), hyperpigmented (e.g. linear and whorled hypermelanosis), or verrucous (e.g. epidermal nevus), depending upon the type of defect

Major points

• Most common cause of increased pigmentation in childhood

• Follows an inflammatory process or traumatic

• •

injury to the epidermis, especially following atopic dermatitis, contact dermatitis, or lichen planus (Figure 14.1) Lesions usually localized and follow the distribution of the resolving skin disorder More common in dark skin types

References Bolognia JL, Orlow SJ, Glick SA. Lines of Blaschko. J Am Acad Dermatol 1994; 31: 157–90 Danarti R, Bittar M, Happle R, Konig A. Linear atrophoderma of Moulin: postulation of mosaicism for a predisposing gene. J Am Acad Dermatol 2003; 49: 492–8 Duran-McKinster C, Moises C, Rodriguez-Jurado R, et al. Streptococcal exanthem in a Blaschkolinear pattern: clinical evidence for genetic mosaicism in hypomelanosis of Ito. Pediatr Dermatol 2002; 19: 423–5 Happle R, Assim A. The lines of Blaschko on the head and neck. J Am Acad Dermatol 2001; 44: 612–15 Kabbash C, Laude TA, Weinberg JM, Silverberg NB. Lichen planus in the lines of Blaschko. Pediatr Dermatol 2002; 19: 541–5 Nehal KS, DeBenito R, Orlow SJ. Analysis of 54 cases of hypopigmentation and hyperpigmentation along the lines of Blaschko. Arch Dermatol 1996; 132: 1167–70 Rott HD. Extracutaneous analogies of Blaschko lines. Am J Med Genet 1999; 85: 338–41

Figure 14.1 Postinflammatory hyperpigmentation following insect bites

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Pathogenesis

• Histology: aberrant delivery of melanin to the surrounding keratinocytes and deposition of pigment in the dermal melanophages Diagnosis

• Clinical presentation Differential diagnosis

• Café au lait macule • Becker nevus • Nevus spilus Treatment

• No treatment is very effective • Hydroquinone 2-4% BID may decrease epidermal hyperpigmentation slowly Prognosis

• After inflammation is resolved, hyperpigmentation fades slowly over many months References

Figure 14.2 Generalized hyperpigmentation caused by Addison disease with accentuation of palmar creases

Pathogenesis

Ruiz-Maldonado R, Orozco-Covarrubias ML. Postinflammatory hypopigmentation and hyperpigmentation. Semin Cutan Med Surg 1997; 16: 36–43

• Etiology depends upon cause of pigmentation • Melanogenic action of increased pituitary peptides

Generalized hyperpigmentation

Diagnosis

Major points

• Clinical presentation • Histology: increased melanin in melanocytes and

• Widespread accentuation of normal areas of

• •

melanin pigmentation all over the body with marked increases in skin creases of palms and soles and mucous membranes Generalized hyperpigmentation should be differentiated from normal variation or from sun exposure Causes: 1. Endocrine abnormalities (e.g. Addison disease, Cushing syndrome, acromegaly, melanotropinstimulating hormone (MSH) excess) (Figure 14.2) 2. Certain drugs (e.g. heavy metals, phenothiazines, antimalarials) 3. Hemochromatosis 4. Chronic renal disease 5. Chronic hepatic disease 6. Scleroderma 7. AIDS

(e.g. MSH in Addison disease)

some melanophages in the dermis Differential diagnosis

• See Causes (above) Treatment

• Depends upon the cause of hyperpigmentation • Discontinuance of medication or treatment of disease does not always improve hyperpigmentation Prognosis

• Generally permanent, unless caused by a medicine which can be discontinued References Fulk CS. Primary disorders of hyperpigmentation. J Am Acad Dermatol 1984; 10: 1–16 Oelkers W. Adrenal insufficiency. N Engl J Med 1996; 335: 1206–12

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Pigmentary disorders

Congenital nevocellular nevi

• Other tumors developing in CNN: schwannoma, neuroid tumor, lipoma, rhabdomyosarcoma, neurofibroma and others

Synonym: congenital nevomelanocytic nevi, congenital melanocytic nevi Major points

Pathogenesis

• Lesions are apparent at birth or within 1 year of

• CNN form in utero between 8 weeks and 6

• •

• • • • •

birth (Figure 14.3) Surface can be smooth, pebbly, verrucous or lobular Pigmentation is usually uniform, medium or dark brown but may have dark brown speckles or black areas. In dark skin, congential nevocellular nevi (CNN) tend to be more heavily pigmented Size ranges from small (2 mm to 1.5 cm) to medium (1.5–19.9 cm) to large (>20 cm) and can cover a large portion of the skin surface Except for size, the overall appearance is similar to that of acquired nevi Some have coarse long hairs Familial tendency has been reported CNN of the head or neck (usually large in size) may be associated with leptomeningeal melanocytosis, manifesting as hydrocephalus, seizures, mental retardation, or melanoma, and carries a poor prognosis Melanoma arises in ~5–15% in the reported literature

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months Histology: nests, sheets or single nevus cells in the dermis, epidermis and sometimes into subcutaneous tissues with features of neuroid appearance, epithelioid cells and/or spindle cells; involvement around appendageal and neurovascular structures is common

Diagnosis

• Usually clinical, but biopsy might be indicated to confirm the diagnosis in unusual cases Differential diagnosis

• • • • • • •

Mongolian spot Café au lait macule Lentigo Acquired nevocellular nevus Nevus sebaceus Smooth muscle hamartoma Becker nevus

Treatment

• Ulceration, nodules or markedly varied •

• • •

pigmentation suggests the possibility of melanoma and should be biopsied Treatment is dependent on perceived risk of melanoma, cosmetic and functional considerations. There is some controversy amongst experts whether excision versus watching is advised Excision if indicated; goal is to remove as much of the CNN as possible while preserving function and cosmesis Management of extensive CNN should be individualized on a case-by-case basis Dermabrasion and other destructive methods may be cosmetically helpful but are controversial

Prognosis

• CNN usually expand in direct proportion to Figure 14.3 Large congenital nevocellular nevus – with variation in color

growth of the anatomic site and can actually enlarge. They often darken with time and develop hair; rarely they may become lighter in color

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• Incidence of melanoma in CNN is unknown, but •

ranges from 5 to 15%. In large CNN, half of the cases of melanoma arise before age 5 years Prognosis for patients who develop melanoma in a giant CNN is poor, because of early metastasis or late diagnosis

• Lesions slowly enlarge and become papular with age

• Nevi increase in darkening, size and number at puberty

• Most acquired nevi are 6 mm in diameter 7. Light skin color 8. Marked freckling 9. Sun sensitivity 10. Excessive sun exposure Associations: 1. Family history of melanoma 2. Presence of multiple atypical nevi (atypical mole syndrome) 3. Xeroderma pigmentosum 4. Transplacental spread of maternal melanoma

Figure 14.10

Melanoma – arising in a congenital nevus

Pathogenesis

• Genetic factors with resultant progressive changes in DNA and inability to repair DNA

• Familial cutaneous malignant melanoma (OMIM no. 15560) can be caused by germline mutations in CDKN2A on chromosome 9p21 and CDK4 on 12q14 and 1p36 Diagnosis

Figure 14.11 Melanoma – changes in color brought this patient to the doctor; it was melanoma in situ

• Clinical features • Histology: increased numbers of atypical

Differential diagnosis

basal melanocytes with atypical nuclei of different sizes, epidermotropism, nest of melanocytes with variation in size and shape, asymmetrical no maturation of melanocytes, signs of regression

• • • •

Spitz nevus Congenital nevocellular nevus Acquired melanocytic nevus Blue nevus

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• Traumatic hemorrhage (especially under the nails, on the heels, or on the mucous membranes)

• Pyogenic granuloma Treatment

• Excision with wide margins based on microscopic

depth of melanoma cells: 1. In situ: 2–5 mm excision margin 2. 4 mm: 2–3 cm excision margin Adjunctive treatments: α-interferon, chemotherapy

Prognosis

• Influenced by depth of the lesion and involvement of lymph nodes

uncommon variant, pigment-synthesizing melanoma. J Am Acad Dermatol 2002; 47: 77–90 Saenz NC, Saenz-Badillos J, Busam K, et al. Childhood melanoma survival. Cancer 1999; 85: 750–4 Sahin S, Levin L, Kopf AW, et al. Risk of melanoma in medium-sized congenital melanocytic nevi: a follow-up study. J Am Acad Dermatol 1998; 39: 428–33 Schmid-Wendtner MH, Berking C, Baumert J, et al. Cutaneous melanoma in childhood and adolescence: an analysis of 36 patients. J Am Acad Dermatol 2002; 46: 874–9 Sober AJ, et al. (Task Force). Guidelines of care for primary cutaneous melanoma. J Am Acad Dermatol 2001; 45: 579–86 Wechsler J, Bastuji-Garin S, Spatz A, et al. Reliability of the histopathologic diagnosis of malignant melanoma in childhood. Arch Dermatol 2002; 138: 625–8

• Five year survival (in general; many factors influence staging): stages I–II: 79%; stage III: 13–69%; stage IV: 6% References Arbiser JL. Melanoma. Lessons from metastases. Arch Dermatol 1998; 134: 1027–8 Bevona C, Goggins W, Quinn T, et al. Cutaneous melanomas associated with nevi. Arch Dermatol 2003; 139: 1620–4

Becker nevus Synonyms: Becker’s melanosis, hairy epidermal nevus Major points

• Male/female ratio >1 • Clinical:

de Braud F, Khayat D, Kroon BB, et al. Malignant melanoma. Crit Rev Oncol Hematol 2003; 47: 35–63 Eedy DJ. Surgical treatment of melanoma. Br J Dermatol 2003; 149: 2–12 Handfield-Jones SE, Smith NP. Malignant melanoma in childhood. Br J Dermatol 1996; 134: 607–16 Johnson TM, Hamilton T, Lowe L. Multiple primary melanomas. J Am Acad Dermatol 1998; 39: 422–7 Johnson TM, Yahanda AM, Chang AE, et al. Advances in melanoma therapy. J Am Acad Dermatol 1998; 38: 731–41 Kanzler MH, Swetter SM. Malignant melanoma. Periodic synopsis. J Am Acad Dermatol 2003; 48: 780–3 Monzon J, Liu L, Brill H, et al. CDKN2A mutations in multiple primary melanomas. N Engl J Med 1998; 338: 879–87 Queirolo P, Taveggia P, Gipponi M, Sertoli MR. Sentinel lymph node biopsy in melanoma patients: the medical oncologist’s perspective. J Surg Oncol 2004; 85: 162–5 Richardson SK, Tannous ZS, Mihm MC. Congenital and infantile melanoma: review of the literature and report of an

1. May be present at birth or childhood as a brown patch with smudged borders 2. Sharply demarcated irregular hyperpigmented patch with or without coarse dark hair (Figure 14.12) 3. Location characteristically over the shoulder, anterior chest, or scapula, but can be anywhere 4. Enlarges slowly over ~2 years, then stabilizes 5. Usual size: 2–20 cm 6. Asymptomatic Rare association: hypoplasia of underlying structures (e.g. hypoplasia of the breast)

Pathogenesis

• Organoid hamartoma of ectoderm and mesoderm • Increase in expression of testosterone receptors and increased sensitivity to androgens may account for expression of lesion around puberty Diagnosis

• Clinical presentation • Histology: slight acanthosis, papillomatosis, hyperpigmented basal cell layer and variable increase in smooth muscle fibers

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Pigmentary disorders

Differential diagnosis

Freckles (ephelides)

• Congenital nevocellular nevus • Smooth muscle hamartoma

Major points

Treatment

• • • • •

No treatment needed Pigmented lesion lasers (Q-switched ruby, neodymium : YAG lasers) may improve hyperpigmentation Photoprotection decreases darkening from sun exposure Bleaching agents with hydroquinone may be helpful For hair removal: shaving, depilatories, electrolysis, laser

239

• 2–3-mm tan-brown macules appearing in sun• •

exposed areas, particularly on face, upper torso and arms (Figure 14.13) Lightly pigmented individuals usually affected Tend to fade in winter and increase in summer

Figure 14.13

Freckles – this young adult has type 1 skin

Pathogenesis

• Caused by sun exposure in light-skinned person with a genetic predispostion Histology: hyperpigmentation of basal cell layer Melanocytes are large and have more numerous and prominent dendritic processes

Figure 14.12 Becker nevus – unilateral mottled brown patch with increased hair

• •

Prognosis

Diagnosis

• Lesion persists indefinitely • Benign

• Clinical presentation

References

• Lentigines • Nevocellular nevi

Chima KN, Janniger CK, Schwartz RA. Becker’s melanosis. Cutis 1996; 57: 311–13 Formigon M, Alsina MM, Mascaro JN, Rivera F. Becker’s nevus and ipsilateral breast hypoplasia androgen-receptor study in two patients. Arch Dermatol 1992; 128: 992–3 Happle R, Koopman RJ. Becker nevus syndrome. Am J Med Genet 1997; 68: 357–61 Nirde P, Dereure O, Belon C, et al. The association of Becker nevus with hypersensitivity to androgens. Arch Dermatol 1999; 135: 212–14

Differential diagnosis

Treatment

• No treatment needed • Sunscreens and protective clothing can decrease the appearance of new freckles Prognosis

• Usually permanent but tend to fade with less sun exposure

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References Levine N, Fulk CS, Rubenzik R. Ephelides (freckles). In The Pigmentary System. Nordlund JJ, Boissy RE, Hearing VJ, et al. eds. Oxford University Press: New York, 1998: 849–51 Zhang XJ, He PP, Liang YH, et al. A gene for freckles maps to chromosome 4q32-q34. J Invest Dermatol 2004; 122: 286–90

Lentigo simplex

Arnsmeier SL, Paller AS. Pigmentary anomalies in the multiple lentigines syndrome: is it distinct from LEOPARD syndrome? Pediatr Deramtol 1996; 13: 100–4 Chamlin SL, Williams ML. Pigmented lesions in adolescents. Adolesc Med State Art Rev 2001; 12: 195–212 Chong W-S, Klanwarin W, Giam Y-C. Generalized lentiginosis in two children lacking systemic associations: case report and review of the literature. Pediatr Dermatol 2004; 21: 139–45

Plural: lentigines

Cognetta AB Jr, Stolz W, Katz B, et al. Dermatoscopy of lentigo maligna. Dermatol Clin 2001; 19: 307–18

Major points

Fulk CS. Primary disorders of hyperpigmentation. J Am Acad Dermatol 1984; 10: 1–16

• Hyperpigmented macule similar to a freckle, but is • • •

darker and does not necessarily show predilection for sun-exposed areas Size 2–15 mm in diameter Color ranges from brown to black Solar lentigines: irregularly shaped, darkly pigmented macules which appear after a severe sunburn; often seen with increased freckles in the same area

O’Neill JF, James WD. Inherited patterned lentiginosis in blacks. Arch Dermatol 1989; 125: 1231–5 Rahman SB, Bhawan J. Lentigo. Intern J Dermatol 1996; 35: 229–38 Smith SR, O’Grady TC. Reticulated ephelides: ‘inkspots’ revisited. Arch Dermatol 1996; 132: 353–4 Tanzi EL, Lupton JR, Alster TS. Lasers in dermatology: four decades of progress. J Am Acad Dermatol 2003; 49:1–31

Pathogenesis

• Histology: elongation of rete ridges, increase in numbers of melanocytes in basal layer and increased melanin in melanocytes and keratinocytes

Café au lait macules Major points

Diagnosis

• Clinical presentation Differential diagnosis

• Junctional nevocellular nevus • LEOPARD syndrome (multiple lentigines

• • • • •

syndrome)

• Peutz–Jeghers syndrome Treatment

Laser ablation: carbon dioxide, Q-switched ruby, neodymium : yttrium–aluminum–garnet, and alexandrite

Discrete brown macules (Figure 14.14) Appear at birth or during childhood Size 1 mm to >20 cm May involve any skin surface Neurofibromatosis: >6 macules greater than 0.5 cm in diameter if 15 years (Figure 14.15)

Pathogenesis

• Histology: increased numbers of melanocytes and increased melanin in melanocytes and keratinocytes Diagnosis

Prognosis

• Clinical presentation

• Persists unless treated

Differential diagnosis

References Abdelmalek NF, Gerber TL, Menter A. Cardiocutaneous syndromes and associations. J Am Acad Dermatol 2002; 46: 161–83

• • • •

Neurofibromatosis McCune–Albright syndrome LEOPARD syndrome Epidermal nevus

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Figure 14.14 Café au lait macule – associated with neurofibromatosis

Figure 14.15 Café au lait macules in a linear distribution, not associated with neurofibromatosis

• Nevocellular nevus • Lentigo/lentigines

McCune–Albright syndrome

Treatment

• None usually needed • On the face, treatment with a pigmented laser may

Major points

• Triad of findings:

be temporarily helpful but may need multiple treatments Prognosis

• Lesions tend to be stable in size and distribution

References Goldberg Y, Dibbern K, Klein J, et al. Neurofibromatosis type 1 – an update and review for the primary pediatrician. Clin Pediatr 1996; 35: 545–61 Karabiber H, Sasmaz S, Turanli G, Yakinci C. Prevalence of hypopigmented maculae and café-au-lait spots in idiopathic epileptic and healthy children. J Child Neurol 2002; 17: 57–9 Landau M, Krafchik BR. The diagnostic value of café au lait macules. J Am Acad Dermatol 1999; 40: 877–90 Okazaki M, Yoshimura K, Suzuki Y, et al. The mechanism of epidermal hyperpigmentation in cafe-au-lait macules of neurofibromatosis type 1 (von Recklinghausen’s disease) may be associated with dermal fibroblast-derived stem cell factor and hepatocyte growth factor. Br J Dermatol 2003; 148: 689–97

1. Large irregularly shaped café au lait macules, usually on trunk; may be present at birth, usually evident in infancy 2. Precocious puberty (especially females) 3. Polyostotic fibrous dysplasia – usually onset at 1 • More common in Latinos and Asians Pathogenesis

• Increase in number and activity of melanocytes • Histology: increase in epidermal and/or dermal melanin Diagnosis

• Clinical presentation Differential diagnosis

• Postinflammatory hyperpigmentation • Phytophotocontact dermatitis Treatment

Melasma Major points

• Common acquired hypermelanosis in teenage and adult women

• Discontinuation of oral contraceptives • Topical sunscreens • Bleaching creams with hydroquinone 2–4% BID for 20 cm. 5. Can be multiple or single

• Natural course of lumbosacral macules is to fade in childhood

• Aberrant lesions stay indefinitely and tend not to fade References Bashiti HM, Blair JD, Triska RA, Keller L. Generalized dermal melanocytosis. Arch Dermatol 1981; 117: 791–3 Cordova A. The mongolian spot. Clin Pediatr 1981; 20: 714–22 Fulk CS. Primary disorders of hyperpigmentation. J Am Acad Dermatol 1984; 10: 1–16 Hori Y, Takayama O. Circumscribed dermal melanoses. Classification and histologic features. Dermatol Clin 1988; 6: 315–26 Leung AK, Kao CP. Extensive mongolian spots with involvement of the scalp. Pediatr Dermatol 1999; 16: 371–2 Smalek JE. Significance of mongolian spots. J Pediatr 1980; 97: 504–5 Stanford DG, Georgouras KE. Dermal melanocytosis: a clinical spectrum. Aust J Dermatol 1996; 37: 19–25 Van Gysel D, Oranje AP, Stroink H, Simonsz HJ. Phakomatosis pigmentovascularis. Pediatr Dermatol 1996; 13: 33–5

Nevus of Ota/nevus of Ito Figure 14.17 Mongolian spot in the typical location on the lumbar back

Synonyms for nevus of Ota: oculodermal melanocytosis, nevus fuscoceruleus ophthalmomaxillaris

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Synonym for nevus of Ito: nevus fuscoceruleus acromiodeltoideus Major points

• Clinical 1. 2. 3. 4.

Sporadic inheritance More common in Asians and Blacks Female/male ratio >1 Characterized by unilateral, blue-black macules intermingled with small brown macules, giving a mottled appearance (Figure 14.18) 5. Location of nevus of Ota: skin innervated by V1 and V2; mucosa, conjunctiva, tympanic membrane may be involved 6. Location of nevus of Ito: unilateral pigmentation over supraclavicular, deltoid and scapular regions 7. Half the lesions present at birth; remainder appear at puberty Pathogenesis

• Histology: melanocytes widely scattered in reticular dermis with melanosomes singly dispersed and fully melanized Diagnosis

• Clinical presentation Differential diagnosis

• Congenital nevocellular nevus • Mongolian spot

Treatment

• Q-switched ruby laser – may require multiple treatments

• Cosmetic camouflage Prognosis

• Tends to enlarge and darken with time • Very rarely, melanoma arises within the lesion • Glaucoma arises in 10% References Fulk CS. Primary disorders of hyperpigmentation. J Am Acad Dermatol 1984; 10: 1–16 Hirayama T, Suzuki T. A new classification of Ota’s nevus based on histopathological features. Dermatologica 1991; 183: 169–72 Kono T, Chan HH, Ercocen AR, et al. Use of Q-switched ruby laser in the treatment of nevus of Ota in different age groups. Lasers Surg Med 2003; 32: 391–5 Lee CS, Lim HW. Cutaneous diseases in Asians. Dermatol Clin 2003; 21: 669–77 Leung AK, Kao CP, Lee TK. Mongolian spots with involvement of the temporal area. Int J Dermatol 2001; 40: 288–9 Liesegang TJ. Pigmented conjunctival and scleral lesions. Mayo Clin Proc 1994; 69: 151–61 Watanabe S, Takahashi H. Treatment of nevus of Ota with the Q-switched ruby laser. N J Engl J Med 1994; 331: 1745–50

Incontinentia pigmenti Synonym: Block–Sulzberger syndrome Major points

• X-linked dominant disorder characterized by linear

Figure 14.18 Nevus of Ota – dark gray patch around the eye (published in An Illustrated Dictionary of Dermatologic Syndromes by SB Mallory and S Leal-Khouri)

rows of blisters in first year of life, followed by swirling hyperpigmentation which follow Blaschko lines Four stages which can overlap: 1. Bullous stage (age birth to ~1 year) – linear rows of blisters following Blaschko lines on extremities and occasionally trunk; lesions can recur or new lesions can develop 2. Verrucous stage (~3 months to 3 years) – linear, verrucous lesions develop usually on extremities 3. Hyperpigmented stage (1 year to 20 years) – whorls of dirty-brown to slate-gray

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hyperpigmentation mainly on the trunk following Blaschko lines; fades in adolescence (Figure 14.19) 4. Hypopigmented stages (adulthood) – streaks of hairless atrophic hypopigmentation on the extremities; often subtle

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• Gene locus Xq28. Gene: NEMO (nuclear factor κB essential modulator IKK-gamma)

Diagnosis

• Clinical diagnosis but confirmed with biopsy of skin in early life

• Histology: 1. Bullous stage: numerous eosinophils with spongiosis in the epidermis 2. Verrucous stage: eosinophilic dyskeratosis, hyperkeratosis, acanthosis, papillomatosis 3. Pigmented stage: melanin in dermis or in dermal macrophages 4. Hypopigmented stage: absence of skin appendages; mild epidermal atrophy; melanocytes decreased or normal Differential diagnosis

• Bullous stage:

• • Figure 14.19 Incontinentia pigmenti (stage 3) – whorling pigmentation following Blaschko lines

• • Associated manifestations: 1. Dental (65–80%) – anodontia, hypodontia and others 2. Hair (38–50%) – thin or sparse hair, patches of alopecia (especially vertex), woolly hair nevus 3. CNS (10–31%) – seizures, mental retardation, hemiplegia and others 4. Eye (35–40%) – strabismus, abnormalities of developing retinal vessels 5. Skeletal (14%) – chondrodystrophy, cleft lip and/or palate, clubfoot, contractures, hemiatrophy and others 6. Nails (7–40%) – onychogryphosis, pitting, ridging, subungual keratotic tumors and others 7. Breast – unilateral aplasia 8. Eosinophilia (up to 65%) in infancy Pathogenesis

• X-linked dominant disorder, usually lethal in male

1. Herpes simplex 2. Bullous impetigo 3. Other bullous disorders (see Chapter 6) Verrucous stage: 1. Linear epidermal nevus 2. Warts Pigmented stage: 1. Epidermal nevus 2. Linear and whorled hypermelanosis Hypopigmented stage: 1. Anetoderma 2. Goltz syndrome

Treatment

• Symptomatic treatment • Skin in neonatal period – topical care and topical antibiotics

• Other organ systems should be examined as indicated by specialists: ophthalmology, audiology, neurology, dental, genetics Prognosis

• Watch for seizures early in life (which often

• •

improve with time) with referral to neurologist if indicated; magnetic resonance imaging (MRI) or computerized tomography (CT) scan do not need to be routinely ordered Birth defects (e.g. alopecia, eye abnormalities) are permanent Pigmentary changes improve with age

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References Hadj-Rabia S, Froidevaux D, Bodak N, et al. Clinical study of 40 cases of incontinentia pigmenti. Arch Dermatol 2003; 139: 1163–70 Happle R. A fresh look at incontinentia pigmenti. Arch Dermatol 2003; 139: 1206–8 Hennel SJ, Ekert PG, Volpe JJ, Inder TE. Insights into the pathogenesis of cerebral lesions in incontinentia pigmenti. Pediatr Neurol 2003; 29: 148–50 Shah SN, Gibbs S, Upton CJ, et al. Incontinentia pigmenti associated with cerebral palsy and cerebral leukomalacia: a case report and literature review. Pediatr Dermatol 2003; 20: 491–4 Zvulunov A, Esterly NB. Neurocutaneous syndromes associated with pigmentary skin lesions. J Am Acad Dermatol 1995; 32: 915–35

Figure 14.20 Erythema dyschromicum perstans – slate-gray macules with indistinct borders

Prognosis

Erythema dyschromicum perstans

• Usually static once process stops

Synonym: ashy dermatosis

References

Major points

Meffert JJ. Erythema dyschromicum perstans: a case report and review. Cutis 2002; 70: 62

• Idiopathic, acquired, generalized, macular, blue•

gray hyperpigmentation Clinical features 1. Common in Latin Americans 2. Sporadic 3. Healthy individuals from childhood to adolescence 4. May begin as erythematous macules which fade and becomes slate-gray or ashy or may begin de novo as gray macules (Figure 14.20) 5. Lesions slowly enlarge and coalesce

Metin A, Calka O, Ugras S. Lichen planopilaris coexisting with erythema dyschromicum perstans. Br J Dermatol 2001; 145: 522–3 Osswald SS, Proffer LH, Sartori CR. Erythema dyschromicum perstans: a case report and review. Cutis 2001; 68: 25–8 Pandya AG, Guevara IL. Disorders of hyperpigmentation. Dermatol Clin 2000; 18: 91–8 Silverberg NB, Herz J, Wagner A, Paller AS. Erythema dyschromicum perstans in prepubertal children. Pediatr Dermatol 2003; 20: 529–30

Pathogenesis

• Pathogenesis unknown • Histology: increased melanin in dermis and epidermis with vacuolization of basal cell layer Diagnosis

• Clinical presentation Differential diagnosis

• Mongolian spots • Postinflammatory hyperpigmentation • Lichen planus Treatment

• None very effective

Acanthosis nigricans Major points

• Clinical manifestations: 1. Brownish-black, velvety thickening of the skin with increased skin markings (Figure 14.21) 2. Prominent in axillae, posterior neck, sides of the neck, groin, antecubital, popliteal surfaces and the umbilical area 3. May have soft papillomas (skin tags) or warty nodules on the affected skin 4. Rarely may affect mucocutaneous skin: eyelids, conjunctivae, lips, oral cavity, vulva

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• Malignancy-associated AN

1. Rare in children 2. Sudden onset and rapid spread of skin involvement 3. Associated with internal malignancy (e.g. gastric cancer, Wilms tumor) Medication-induced AN – e.g. nicotinic acid, diethylstilbestrol (DES), corticosteroids, estrogens, oral contraceptives

Pathogenesis

• Hyperinsulinemia is implicated in pathogenesis

• Figure 14.21 Acanthosis nigricans – typical velvety, dark appearance on the neck

• Epidemiology:

• •

1. Male/female ratio =1 2. Occurs most commonly during puberty, or in early adulthood 3. Peak prevalence in childhood is age ~12 years 4. Strong association with obesity: 66% prevalence in adolescents weighing >200% of their ideal body weight Benign acanthosis nigricans (AN) 1. Rare autosomal dominant genodermatosis 2. Associated with multiple melanocytic nevi 3. Presents at birth or early childhood Obesity-associated AN 1. Most common form 2. Clinical course of skin lesions follows weight gain and loss Acral AN 1. Occurs in healthy individuals 2. Distribution over dorsal hands and feet Syndromic AN – syndromes with associated insulin resistance 1. Lawrence–Seip syndrome (lipodystrophy and AN) 2. Leprechaunism 3. Polycystic ovary disease 4. Crouzon syndrome 5. Others

1. Usually caused by underlying insulin resistance in obesity or syndromes 2. Excess insulin binds to receptors on keratinocytes and fibroblasts, leading to increased proliferation of epidermal cells Tumor product with insulin-like activity or transforming growth factor (TGF-α) activity is implicated in malignant AN Histology: hyperkeratosis and epidermal papillomatosis; areas of acanthosis alternating with atrophy

Diagnosis

• Clinical features • Evaluate for underlying endocrine abnormality or malignancy if indicated Differential diagnosis

• Confluent and reticulate papillomatosis • Retained keratin Treatment

• Directed at correcting underlying disease

• •

1. Weight loss 2. Correction of underlying endocrine dysfunction 3. Discontinue offending drug 4. Treat underlying malignancy If mild AN, may not require treatment Topical emollients, keratolytics, topical retinoid (e.g. tretinoin 0.1% cream once daily for 2 weeks) or low-dose systemic retinoids

Prognosis

• Clinical course tends to follow exacerbation or resolution of underlying disorder

• Obesity-associated AN may improve with weight loss

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References Brockow K, Steinkraus V, Rinninger F, et al. Acanthosis nigricans: a marker for hyperinsulinemia. Pediatr Dermatol 1995; 12: 323–6 Hermanns-Le T, Hermanns JF, Pierard GE. Juvenile acanthosis nigricans and insulin resistance. Pediatr Dermatol 2002; 19: 12–14 Panidis D, Skiadopoulos S, Rousso D, et al. Association of acanthosis nigricans with insulin resistance in patients with polycystic ovar`y syndrome. Br J Dermatol 1995; 132: 936–41 Schroeder B. Early diagnosis, presenting complaints, and management of hyperandrogenism in adolescents. Curr Wom Health Rep 2001; 1: 124–30 Schwartz RA, Janniger CK. Childhood acanthosis nigricans. Cutis 1995; 55: 337–9

Figure 14.22 Confluent and reticulated papillomatosis – lesions can resemble tinea versicolor but a scraping for hyphae is negative, and it does not respond to antifungal therapy

Torley D, Bellus GA, Munro CS. Genes, growth factors and acanthosis nigricans. Br J Dermatol 2002; 147: 1096–101 Uyttendaele H, Koss T, Bagheri B, et al. Generalized acanthosis nigricans in an otherwise healthy young child. Pediatr Dermatol 2003; 20: 254–6

Confluent and reticulated papillomatosis Synonym: Gougerot and Carteaud syndrome

Differential diagnosis

• Tinea versicolor • Acanthosis nigricans Treatment

• Oral minocycline 100 mg BID • Variable success with topical therapy: salicylic acid,

Major points

• Distinctive clinical disorder of adolescents and • • • •

young adults Female/male ratio >1 Blacks/Whites ratio >1 Presents with brown hyperkeratotic papules coalescing into plaques with reticulate periphery (Figure 14.22) Location: chest, inframammary area, neck, shoulders, interscapular back and epigastric area

Pathogenesis

• Unknown etiology • Considered a variant of acanthosis nigricans or a disorder of keratinization

• May be related to endocrine abnormalities or host reponse to Pityrosporum orbiculare Diagnosis

• Clinical findings • Histology: similar to acanthosis nigricans with undulating hyperkeratosis, papillomatosis and mild acanthosis with basal hyperpigmentation

selenium sulfide, antifungals, 5-fluorouracil, calcipotriene, retinoids Oral retinoids if minocycline is ineffective

Prognosis

• Benign persistent course with recurrences References Bowman PH, Davis LS. Confluent and reticulated papillomatosis: response to tazarotene. J Am Acad Dermatol 2003; 48(5 Suppl): S80–1 Hirokawa M, Matsumoto M, Iizuka H. Confluent and reticulated papillomatosis: a case with concurrent acanthosis nigricans associated with obesity and insulin resistance. Dermatology 1994; 188: 148–51 Jang HS, Oh CK, Cha JH, et al. Six cases of confluent and reticulated papillomatosis alleviated by various antibiotics. J Am Acad Dermatol 2001; 44: 652–5 Mutasim DF. Confluent and reticulated papillomatosis without papillomatosis. J Am Acad Dermatol 2003; 49: 1182–4 Shimizu S, Han-Yaku H. Confluent and reticulated papillomatosis responsive to minocycline. Dermatology 1997; 194: 59–61

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HYPOPIGMENTED DISORDERS Vitiligo Major points

• Common, sometimes heritable, acquired loss of pigment in interfollicular melanocytes

• Affects ~1–2% of all races • Types

• •

1. Generalized – most common type; macules are symmetrical involving extensor surfaces of distal digits, knees, elbows and periorificial areas; mucosal involvement common (Figure 14.23) 2. Segmental – unilateral macules with dermatomal or segmental configuration which remains stable and is unlikely to be associated with autoimmune diseases; trigeminal area most common (Figure 14.24) 3. Focal – an isolated macule or a few scattered macules 4. Universal – widespread vitiligo; often associated with multiple endocrinopathy syndrome Clinical: 1. Onset at any age from birth to 81 years, with majority of cases beginning in childhood 2. Macules are chalky white, round or oval, with fairly distinct often scalloped margins measuring several millimeters to many centimeters without any epidermal changes 3. Trichrome vitiligo: presence of a band of lighter skin which interfaces between white and normal color displaying three colors: white, light tan and normal skin color (Figure 14.25) 4. Lesions begin as small areas and enlarge over time with coalescence, which can be extensive 5. Can exhibit Koebner phenomenon with involvement after injury 6. Associated with poliosis, prematurely gray hair, halo nevi and alopecia areata Generalized vitiligo can be associated with various autoimmune disorders: thyroid disease, diabetes mellitus, Addison disease, pernicious anemia, multiple autoantibodies, hypoparathyroidism Ocular involvement: iritis, retinal pigmentary abnormalities, chorioretinitis; visual acuity usually normal Rare syndromes: 1. Vogt–Koyanagi–Harada syndrome: rare multisystem disease characterized by aseptic

Figure 14.23 and elbows

Vitiligo classically on the fingertips, knees

Figure 14.24 Vitiligo – acquired depigmented patches in a segmental distribution

meningoencephalitis, vitiligo, poliosis, uveitis, dysacousia 2. Alezzandrini syndrome: characterized by unilateral facial vitiligo, poliosis (white patches of hair), ipsilateral pigmentary retinitis with gradual visual loss, and deafness

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• Repigmentation (slow and requires commitment

• • Figure 14.25

Vitiligo – trichrome color change

Pathogenesis

• Generalized vitiligo is a polygenic disorder; up to 30% have a family member affected

• Segmental vitiligo is not inherited • Theories for mechanism of destruction of melanocytes: autoimmune, neurochemical, or selfdestruction (toxic)

• •

Prognosis

• Natural course of generalized vitiligo is

Diagnosis

• Clinical presentation. Wood’s lamp examination •

may be helpful to identify lesions in light-skinned individuals Histology: loss of melanocytes; lymphocytes may be present in upper dermis in evolving macules

Differential diagnosis

• • • • • • • • • • •

Postinflammatory hypopigmentation Pityriasis alba Tinea versicolor Tuberous sclerosis Nevus depigmentosus Chemical leukoderma (phenolic compounds) Lupus erythematosus Melanoma-associated leukoderma Piebaldism Waardenburg syndrome Leprosy

Treatment

• Education about disease is most helpful • Sunscreens to vitiliginous areas to avoid sunburn

from patient and parents): 1. Topical corticosteroids (mid-strength to ultra-potent) 1–2 times a day 2. Psoralen (oral or topical) plus UVA light (PUVA) 3. UVB light, 2–3 times per week 4. Success depends upon presence of follicular melanocytes Surgical techniques with micrografts from uninvolved skin can be used only if patches are stable (non-progressive) Depigmentation with monobenzylether of hydroquinone 20% should be reserved for only those patients who have lost a large percentage of color and have no hope of repigmenting naturally Psychosocial factors should be addressed Cover-up cosmetics (e.g. Dermablend®) or temporary dyes

unpredictable, but most vitiligo is slowly progressive. Spontaneous regression rare. Treatment can repigment some areas (face responds best) Segmental vitiligo is usually stable but can respond to treatment

References Drake LA, Dinehart SM, Farmer ER, et al. Guidelines of care of vitiligo. J Am Acad Dermatol 1996; 35: 620–6 Gauthier Y, Cario Andre M, Taieb A. A critical appraisal of vitiligo etiologic theories. Is melanocyte loss a melanocytorrhagy? Pigment Cell Res 2003; 16: 322–32 Herane MI. Vitiligo and leukoderma in children. Clin Dermatol 2003; 21: 283–95 Hoffman MD, Dudley C. Suspected Alezzandrini’s syndrome in a diabetic patient with unilateral retinal detachment and ipsilateral vitiligo and poliosis. J Am Acad Dermatol 1992; 26: 496–8 Majumder PP, Nordlund JJ, Nath SK. Pattern of familial aggregation of vitiligo. Arch Dermatol 1993; 129: 994–8 Ongenae K, Van Geel N, Naeyaert JM. Evidence for an autoimmune pathogenesis of vitiligo. Pigment Cell Res 2003; 16: 90–100 Schaffer JV, Bolognia JL. The treatment of hypopigmentation in children. Clin Dermatol 2003; 21: 296–310

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Tsukamoto K, Osada A, Kitamura R, et al. Approaches to repigmentation of vitiligo skin: new treatment with ultrasonic abrasion, seed-grafting and psoralen plus ultraviolet A therapy. Pigment Cell Res 2002; 15: 331–4

b. c. d. e.

Irides progressively darken Skin can tan minimally Nevi and freckles may develop Temperature-sensitive variant: darkly pigmented hair on the arms and legs, and lightly pigmented hair centrally 3. OCA 2 (tyrosinase-positive OCA) a. Dilution of pigment of hair and iris but not complete loss b. Skin color paler than in relatives c. Hair white or light blonde d. With maturity, pigment increases and nevi and freckles can develop e. Photophobia and nystagmus are present, but not as severe as in OCA 1A f. More common in African-Americans 4. OCA 3 (rufous OCA) a. Red hair and lighter skin

Albinism Synonym: oculocutaneous albinism Major points

• General

1. Albinism includes a group of genetic disorders with dilution or absence of ocular and cutaneous pigmentation 2. All races affected 3. Lack of pigment is caused by an abnormal maturation of melanosomes Types of oculocutaneous albinism (OCA): 1. OCA 1A (tyrosinase-negative OCA) a. Marked hypopigmentation of the skin and eyes (Figure 14.26) b. Skin varies from pink to milky white c. Hair white d. Eyes are pale blue with a pink or red reflex which can be seen through the iris e. Severe photophobia caused by lack of pigment f. Associated ocular abnormalities: decreased visual acuity, nystagmus and strabismus 2. OCA 1B (minimal pigment OCA, yellow OCA) a. Hair begins white but may progress to dark blonde or brown in adolescence

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Pathogenesis

• OCA 1: mutation of the tyrosinase gene

• •

(chromosome 11p1) 1. Complete loss with phenotype OCA 1A; reduced activity (5–10% of normal) results in OCA 1B OCA 2: mutation of the P gene (chromosome 15q11.2-12), membrane transporter gene OCA 3: mutation of TYRP1 gene affecting melanin synthesis; chromosome 9p23

Diagnosis

• Clinical presentation • Genetic testing • Electron microscopy can determine the stages of melanosomes Differential diagnosis

• • • • • •

Prader–Willi syndrome Angelman syndrome Homocystinuria Apert syndrome Vitiligo (generalized) Phenylketonuria

Treatment

• Photoprotection is most important to reduce risk Figure 14.26

Albinism – type 1 oculocutaneous albinism

of cutaneous malignancies Ophthalmological evaluation and follow-up

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Prognosis

• Cutaneous squamous cell carcinoma and basal cell carcinoma along with other signs of photoaging are common in unprotected skin References King RA. Albinism. In The Pigmentary System. Nordlund JJ, Boissy RE, Hearing VJ, et al. eds). Oxford University Press: New York, 1998: 553–75 Oetting WS, Fryer JP, Shriram S, King RA. Oculocutaneous albinism type 1: the last 100 years. Pigment Cell Res 2003; 16: 307–11 Oetting WS. The tyrosinase gene and oculocutaneous albinism type 1 (OCA1): a model for understanding the molecular biology of melanin formation. Pigment Cell Res 2000; 13: 320–5 Orlow SJ. Albinism: an update. Semin Cutan Med Surg 1997; 16: 24–9 Sarangarajan R, Boissy RE. Tyrp1 and oculocutaneous albinism type 3. Pigment Cell Res 2001; 14: 437–44

1. Similar to type I with limb abnormalities 2. Gene/gene locus: PAX 3 gene/2q35 3. Autosomal dominant Waardenburg syndrome type IV 1. Similar to type I with Hirschsprung disease 2. Gene/gene locus: endothelin B receptor gene/20q13.2-q13.3 3. Autosomal recessive

References da Silva EO. Waardenburg I syndrome: a clinical and genetic study of two large Brazilian kindreds and literature review. Am J Med Genet 1991; 40: 65–74 Mollaaghababa R, Pavan WJ. The importance of having your SOX on: role of SOX10 in the development of neural crest-derived melanocytes and glia. Oncogene 2003; 22: 3024–34 Read AP, Newton VE. Waardenburg syndrome. J Med Genet 1997; 34: 656–65

Tomita Y. The molecular genetics of albinism and piebaldism. Arch Dermatol 1994; 130: 355–8

Shanske A, Ferreira JC, Leonard JC, et al. Hirschsprung disease in an infant with a contiguous gene syndrome of chromosome 13. Am J Med Genet 2001; 102: 231–6

Waardenburg syndrome

Shibahara S, Takeda K, Yasumoto K, et al. Microphthalmiaassociated transcription factor (MITF): multiplicity in structure, function, and regulation. Symposium Proceedings. J Invest Dermatol 2001; 6: 99–104

Major points

• Waardenburg syndrome type I 1. 2. 3. 4. 5. 6. 7. 8.

Depigmented patches of the skin and hair Heterochromia irides Deafness Dystopia canthorum Broad nasal root Synophrys (confluence of the medial eyebrows) Hypoplasia of the nasal alae Gene/gene locus: PAX 3 gene (transcription factor for melanocyte proliferation and migration from the neural crest)/2q35 9. Autosomal dominant Waardenburg syndrome type II 1. Similar to type I except without dystopia canthorum 2. Gene/gene locus: MITF gene (microphthalmia-associated transcription factor)/3p14.1-12.3 and others 3. Autosomal dominant Waardenburg syndrome type III (Klein–Waardenburg syndrome)

Piebaldism Major points

• Clinical features 1. Symmetrical well-demarcated patches of depigmented skin and hair with V-shape on forehead and frontal scalp, patches on anterior chest and abdomen, and extremities around elbows and knees with sparing of hands and feet (Figure 14.27) 2. No progressive loss of pigment 3. No extracutaneous findings except in a few families with deafness 4. 80–90% of patients have a white forelock Pathogenesis

• Defective cell proliferation and migration of melanocytes during embryogenesis caused by mutation in c-KIT gene which is responsible for melanocytic proliferation; chromosome 14q12

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Spritz RA. Molecular basis of human piebaldism. J Invest Dermatol 1994; 103: 137S–140S Spritz RA. Piebaldism, Waardenburg syndrome, and related disorders of melanocyte development. Semin Cutan Med Surg 1997; 16: 15–23 Syrris P Malik NM, Murday VA, et al. Three novel mutations of the proto-oncogene KIT cause human piebaldism. Am J Med Genet 2000; 95: 79–81 Tomita Y. The molecular genetics of albinism and piebaldism. Arch Dermatol 1994; 130: 355–8

Hermansky–Pudlak syndrome Major points

• Tyrosinase-positive albinism • Bleeding diathesis with epistaxis, gingival bleeding or bleeding after surgical procedures Figure 14.27 Piebaldism – symmetrical congenital depigmentation with thumbprint hypermelanotic macules within the depigmented patches

Diagnosis

• Clinical diagnosis • Confirmed by genetic analysis with mutations on •

c-KIT gene Histology: melanocytes are absent from white patches

Differential diagnosis

• Waardenburg syndrome • Vitiligo Treatment

• Cosmetic covering • Sun protection of the white patches Prognosis

• White patches stable and may develop actinic keratoses

• Autosomal recessive; more common in Puerto Ricans and Dutch

• Ceroid storage disease affecting lungs, gut, platelets • Gene/gene locus: HPS1 (transmembrane protein)/chromosome 10q2 and others References Gahl WA, Brantly M, Kaiser-Kupfer MI, et al. Genetic defects and clinical characteristics of patients with a form of oculocutaneous albinism (Hermansky–Pudlak syndrome). N Engl J Med 1998; 338: 1258–64 Huizing M, Boissy RE, Gahl WA. Hermansky-Pudlak syndrome: vesicle formation from yeast to man. Pigment Cell Res 2002; 15: 405–19 Huizing M, Gahl WA. Disorders of vesicles of lysosomal lineage: the Hermansky–Pudlak syndromes. Curr Mol Med 2002; 2: 451–67 Starcevic M, Nazarian R, Dell’Angelica EC. The molecular machinery for the biogenesis of lysosome-related organelles: lessons from Hermansky–Pudlak syndrome. Semin Cell Dev Biol 2002; 13: 271–8 Vanhooteghem O, Courtens W, Andre J, et al. Hermansky–Pudlak syndrome: a case report and discussion. Pediatr Dermatol 1998; 15: 374–7

References Boissy RE, Nordlund JJ. Molecular basis of congenital hypopigmentary disorders in humans: a review. Pigment Cell Res 1997; 10: 12–24 Richards KA, Fukai K, Oiso N, Paller AS. A novel KIT mutation results in piebaldism with progressive depigmentation. J Am Acad Dermatol 2001; 44: 288–92

Phenylketonuria Major points

• Caused by absence of hepatic phenylalanine hydroxylase (PAH) with build-up of phenylalanine

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• If untreated, phenylketonuria results in mental retardation and pigment dilution

• Most patients have blonde hair, blue eyes, fair skin, • • •

photosensitivity, mousy body odor and neurologic disturbances When treated, skin coloration reverts to normal Autosomal recessive Gene/gene locus: phenylalanine hydroxylase/12q24.1 and others

References Beasley MG, Costello PM, Smith I. Outcome of treatment in young adults with phenylketonuria detected by routine neonatal screening between 1964 and 1971. Q J Med 1994; 87: 155–60 Erlandsen H, Patch MG, Gamez A, et al. Structural studies on phenylalanine hydroxylase and implications toward understanding and treating phenylketonuria. Pediatrics 2003; 112: 1557–65 Mineroff AD. Phenylketonuria. In The Pigmentary System. Nordlund JJ, Boissy RE, Hearing VJ, King RA, Ortonne JP, eds. Oxford University Press: New York, 1998: 590–1

Figure 14.28 Hypomelanosis of Ito – hypopigmented streaks following Blaschko lines

Zschocke J. Focus on the molecular genetics of phenylketonuria. Hum Mutat 2003; 21: 331–2

Pathogenesis

• Mosaicism caused by two distinct germ lines formed during embryogenesis

Hypomelanosis of Ito Synonym: incontinentia pigmenti achromians Major points

Diagnosis

• Clinical presentation • Histology: hypopigmented areas show normal or reduced number of melanocytes with reduction in number of melanosomes

• Hypopigmented streaks and whorls, mainly on the • • • • •

• •

trunk, following the lines of Blaschko (Figure 14.28) Present at birth or becomes apparent during early life Macular pigmentation tends to be stable over time or may fade Inheritance sporadic or autosomal dominant Female/male ratio: 2.5–1 Other cutaneous findings: aplasia cutis, fibromas, follicular keratosis, angiomas, generalized or focal hypertrichosis, and abnormalities in the teeth, hair, nails and sweat glands Extracutaneous findings (30%): mainly CNS, musculoskeletal and ocular system involvement Other findings: limb-length discrepancies, facial hemiatrophy, scoliosis, abnormal facies, genitourinary abnormalities, cardiac abnormalities

Differential diagnosis

• • • • • • •

Goltz syndrome Vitiligo Nevus depigmentosus Incontinentia pigmenti (stage 4) Epidermal nevi Lichen striatus Segmental vitiligo

Treatment

• Cosmetic cover-up is rarely needed Prognosis

• Majority of children are normal, but in the first 2 years of life children should be observed for developmental delay and CNS abnormalities

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• Neurologic and ocular examinations may be indicated

• Hypopigmentation may fade or be stable References Duran-McKinster C, Moises C, Rodriguez-Jurado R, et al. Streptococcal exanthem in a blaschkolinear pattern: clinical evidence for genetic mosaicism in hypomelanosis of Ito. Pediatr Dermatol 2002; 19: 423–5 Kuster W, Ehrig T, Happle R. In The Pigmentary System. Nordlund JJ, Boissy RE, Hearing VJ, et al. eds. Oxford University Press: . New York, 1998: 594–601 Kuster W, Konig A. Hypomelanosis of Ito: no entity, but a cutaneous sign of mosaicism. Am J Med Genet 1999; 85: 346–50 Nehal KS, DeBenito R, Orlow SJ. Analysis of 54 cases of hypopigmentation and hyperpigmentation along the lines of Blaschko. Arch Dermatol 1996; 132: 1167–70 Ruggieri M, Pavone L. Hypomelanosis of Ito: clinical syndrome or just phenotype? J Child Neurol 2000; 15: 635–44 Ruiz-Maldonado R, Roussaint S, Tamayo L, et al. Hypomelanosis of Ito: diagnostic criteria and report of 41 cases. Pediatr Dermatol 1992; 9: 1–10

Nevus depigmentosus (nevus achromicus) Major points

• • • • • •

Single, well-circumscribed, hypopigmented patch, sometimes following the lines of Blaschko or in a segmental unilateral distribution (Figure 14.29) Border of lesion may be serrated or jagged Lesions present at birth or within the first years of life Usual locations: trunk and proximal extremities Male/female ratio = 1 Rare associated findings: hemihypertrophy, seizures and mental retardation

Figure 14.29 Nevus depigmentosus – congenital hypopigmented well-defined patch

• Electron microscopy: defect in transfer of pigment between the melanocyte and keratinocyte with a decreased number of melanosomes in the keratinocytes; number of melanocytes normal Differential diagnosis

• • • • • •

Nevus anemicus Segmental vitiligo Hypopigmented macules of tuberous sclerosis Hypomelanosis of Ito Pityriasis alba Postinflammatory hypopigmentation

Treatment

• Usually none needed • Camouflage makeup such as Dermablend® or Covermark®

Pathogenesis

Prognosis

• Hypothesis: functional defect of melanocytes and

• Stable in size and distribution throughout life

morphologic abnormalities of melanosomes Diagnosis

• Clinical examination • Under Wood’s light examination, lesions show off-white accentuation, in contrast to vitiligo, which is bright white

References Alkemade H, Juhlin L. Unilateral lentiginosis with nevus depigmentosus on the other side. J Am Acad Dermatol 2000; 43: 361–3 Dippel E, Utikal J, Feller G, et al. Nevi flammei affecting two contralateral quadrants and nevus depigmentosus: a new

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type of phacomatosis pigmentovascularis? Am J Med Genet 2003; 119A: 228–30 Lee HS, Chun YS, Hann SK. Nevus depigmentosus: clinical features and histopathologic characteristics in 67 patients. J Am Acad Dermatol 1999; 40: 21–6

Postinflammatory hypopigmentation Major points

• Partial loss of cutaneous melanin in affected area of •

skin resulting from an inflammatory process (Figures 14.30 and 14.31) Appears as a hypochromic macule or patch in distribution of previous inflammation

Figure 14.31 Postinflammatory hypopigmentation caused by a steroid injection for a cyst

Diagnosis

• Clinical presentation with history of inflammation Differential diagnosis

• Tinea corporis • Tinea versicolor • Seborrheic dermatitis Figure 14.30 Postinflammatory hypopigmentation from eczema in a baby. The color reverted to normal after therapy

Treatment

• Treat underlying cause of inflammation Prognosis

• More easily seen in dark skin • Trauma and inflammation are thought to cause •

dysfunction of melanocytes Wood’s lamp examination enhances hypopigmented areas in light skin and helps distinguish between depigmentation and hypopigmentation

Pathogenesis

• Histology can help to establish the cause of hypopigmentation

• Can improve with treatment or remain static References Herane MI. Vitiligo and leukoderma in children. Clin Dermatol 2003; 21: 283–95 Ruiz-Maldonado R, Orozco-Covarrubias ML. Postinflammatory hypopigmentation and hyperpigmentation. Semin Cutan Med Surg 1997; 16: 36–43

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DERMATOMYOSITIS Major points

• Affects three children per million per year in the • • •

USA Bimodal distribution: peaks at 5–9 years of age and again in teenage years Equal gender distribution at 5–9 years of age; 10 : 1 female predominance in early teenage years Skin manifestations: 1. Heliotrope rash – violaceous, periorbital erythema with swelling 2. Gottron papules – scaly, erythematous papules overlying metacarpal–phalangeal joints or interphalangeal joints (Figure 15.1) 3. Erythematous malar rash and over neck, upper back and arms (shawl sign) 4. Scaly, erythematous patches of the elbows, knees and cheeks 5. Nails: periungual telangiectasias and cuticular overgrowth 6. Poikiloderma 7. Calcinosis cutis – usually occurs late in the course of disease, occurs much more frequently in children than adults; incidence can be reduced with aggressive treatment Noncutaneous manifestations: 1. Symmetric, progressive, proximal muscle weakness (Gower sign) 2. Muscle pain 3. Constitutional symptoms: fever, weight loss, fatigue 4. Dysphagia 5. Nasal speech, hoarseness

Figure 15.1 Dermatomyositis – typical Gottron papules over the knuckles

6. Abdominal pain 7. Arthritis and tenosynovitis 8. Pulmonary disease (diffuse interstitial fibrosis, secondary aspiration and infection) 9. Cardiac disease: heart block, arrythmias, pericarditis 10. Gastrointestinal disease (mucosal ulceration) 11. Calcinosis around joints and in intermuscular fascial planes Differs from adult dermatomyositis in that malignancy is extremely rare (work-up for malignancy is unnecessary)

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Pathogenesis

• Etiology unknown • Presumed autoimmune disorder • May be multifactorial: infectious, genetic and environmental etiologies have been implicated Diagnosis

• Criteria (Bohan and Peter)

1. Characteristic rash, plus three of the four following: a. Symmetric proximal muscle weakness b. Elevated muscle enzymes (aldolase, creatine kinase, lactate dehydrogenase, transaminases (AST/ALT) c. Muscle biopsy (chronic inflammation with or without necrosis) d. Abnormal electromyogram (EMG) Magnetic resonance imaging (MRI) is useful in determining areas of muscle involvement: 1. Identifies areas of edema and inflammation 2. Used to identify appropriate muscle biopsy site 3. Used to follow disease course

Differential diagnosis

• Systemic lupus erythematosus • Photosensitive eruption (e.g. drug-induced dermatitis)

• Postinfectious myositis • Other myopathies Treatment

• Systemic corticosteroids – most cases respond to

• •

• • •

corticosteroid therapy 1. Oral prednisone taper over several months 2. High-dose intravenous pulse methylprednisolone (IVMP) Methotrexate is second-line agent of choice with recalcitrant disease If no response or there are intolerable adverse effects, other therapies to consider: cytoxan, hydroxychloroquine, azathioprine, cyclosporine, intravenous immunoglobulins (IVIG) and plasmapheresis Sun protection and sun avoidance Physical therapy to prevent contractures Early aggressive therapy is successful in minimizing long-term sequelae, including calcinosis

Prognosis • With successful treatment, prognosis is good – overall mortality 4 plaque lesions in ≥2 body sites) 2. Lesions similar to plaque morphea with generalized involvement

Figure 15.8 Morphea (en coup de sabre) – hyperpigmented, sclerotic indentation on the forehead and cheek

Pathogenesis

• Thought to be an autoimmune disorder • Early inflammation with edema and increased • •

vascularity; progressing to sclerosis and abnormal collagen formation; ultimately resulting in atrophy Trauma and Borrelia burgdorferi infection have been implicated as triggers Histology: 1. Early: dermal edema with swelling and degeneration of collagen fibrils, lymphocytic infiltrate around dermal vessels and appendages 2. Late: progressive dermal thickening and condensation of collagen – with bundles densely packed and aligned parallel to the dermal – epidermal junction with loss of appendages

Diagnosis • Clinical findings • Skin biopsy may be performed to aid in diagnosis but not always necessary • Laboratory studies: none specific but may be helpful in following the course; ANA, complete blood count (CBC) with differential, immunoglobulins, rheumatoid arthritis factor • Consider work-up for other collagen vascular diseases as indicated by history and physical

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examination; extensive disease may be more likely to have immunologic abnormalities MRI/ultrasound – useful if there is CNS or eye involvement or to determine depth of lesions

Differential diagnosis • Postinflammatory hyperpigmentation • Erythema dyschromicum perstans • Lichen sclerosus • Traumatic scars • Eosinophilic fasciitis • Scleredema of Buschke Treatment • Systemic therapy: 1. Low-dose methotrexate 2. Systemic corticosteroids (oral or IV pulse) 3. Oral calcitriol (vitamin D analog) 4. PUVA (not recommended for 10cm (Figure 17.1) b. Usually solitary

Table 17.1 Disorders which follow Blaschko lines/segmental disorders

Nevoid/hamartomas Epidermal nevus/ILVEN Nevus sebaceus Nevus comedonicus Porokeratotic eccrine ostial and dermal duct nevus Nevus lipomatosus CHILD syndrome Pigmented lesions Incontinentia pigmenti Hypomelanosis of Ito Nevus depigmentosus Linear and whorled nevoid hypermelanosis Segmental vitiligo Tuberous sclerosis with leukodermic macules Café au lait macules (McCune–Albright syndrome) Congenital nevus Vascular lesions Angiokeratoma circumscriptum Verrucous hemangioma Glomuvenous malformations Venous malformations Angioma serpiginosum Lymphangioma circumscriptum Unilateral nevoid telangiectasia

Figure 17.1 Epidermal nevus – on the body following Blaschko lines (published in An Illustrated Dictionary of Dermatologic Syndromes by SB Mallory and S Leal-Khouri)

Other Lichen striatus Linear lichen planus Focal dermal hypoplasia (Goltz syndrome) Conradi–Hünermann syndrome (X-linked dominant) Menkes syndrome (female carriers) X-linked hypohidrotic ectodermal dysplasia (female carriers) Oral–facial–digital syndrome, type 1 Linear porokeratosis Linear keratosis follicularis

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Figure 17.2 Epidermal nevus – on the legs following Blaschko lines

c. Linear or oval in shape d. Most common on extremities, but can be anywhere e. Does not continue to grow after age 7 years except in proportion to the child 2. Nevus unius lateris (systematized epidermal nevus) a. Extensive lesions which can be unilateral or bilateral (Figure 17.2) b. Can continue to expand into adolescence, following Blaschko lines c. Associated with underlying systemic deformities in 30% of patients (called ‘epidermal nevus syndrome’ with CNS, skeletal, cardiovascular, ocular abnormalities) 3. Ichthyosis hystrix a. Extensive lesions following Blaschko lines b. Histology: epidermolytic hyperkeratosis 4. Inflammatory linear verrucous epidermal nevus (ILVEN) a. Erythematous scaly linear plaque/plaques (Figure 17.3) b. Small or large c. Intensely pruritic d. Often in groin e. More common in females (4 : 1)

Figure 17.3 Inflammatory linear verrucous epidermal nevus – scaly, erythematous streaks following Blaschko lines on the leg

Pathogenesis

• Mosaicism arising from somatic mutations early in

embryogenesis. Two distinct cell lines result and migrate along developmental lines (Blaschko lines) producing patchy and linear abnormalities If epidermal nevus has histology of epidermolytic hyperkeratosis and if the gonads are involved in the somatic mutation, offspring may be affected with widespread epidermolytic hyperkeratosis

Diagnosis • Histology: 1. Papillomatous hyperplasia of the epidermis with or without epidermolytic hyperkeratosis 2. Inflammation in the dermis may be seen in the inflammatory types Differential diagnosis • Nevus verrucosus 1. Nevus sebaceus 2. Seborrheic keratosis 3. Verrucae • Inflammatory linear verrucous epidermal nevus 1. Psoriasis 2. Linear lichen planus 3. Lichen simplex chronicus 4. Darier disease

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Treatment

• Solitary epidermal nevi usually require no treatment

• Surgery must include upper levels of dermis in • •

order to prevent recurrences Other techniques which may be effective for removal: CO2 laser, dermabrasion, chemical peels, liquid nitrogen Pruritus in ILVEN may be improved with potent topical or intralesional steroids, pulsed dye laser or short contact dithranol

299

• Sporadic in occurrence; familial cases have been reported

• No racial or sexual predilection • Incidence 0.3% of the population • Solitary oval or linear hairless plaque on the scalp, head or neck (Figure 17.4)

Prognosis

• Lesions persist unless fully removed References Alam, M, Arndt KA. A method for pulsed carbon dioxide laser treatment of epidermal nevi. J Am Acad Dermatol 2002; 46; 554–6 Boyce S, Alster TS. CO2 laser treatment of epidermal nevi: long-term success. Dermatol Surg 2002; 28: 611–14 Grebe TA, Rimsza ME, Richter SF, et al. Further delineation of the epidermal nevus syndrome: two cases with new findings and literature review. Am J Med Genetics 1993; 47: 24–30 Happle R, Rogers M. Epidermal nevi. Adv Dermatol 2002; 18: 175–201 Ivker R, Resnick SD, Skidmore RA. Hypophosphatemic vitamin D-resistant rickets, precocious puberty, and the epidermal nevus syndrome. Arch Dermatol 1997; 133: 1557–61 Paller AS, Syder AJ, Chan Y-M, et al. Genetic and clinical mosaicism in a type of epidermal nevus. N Engl J Med 1994; 331: 1408–15

Figure 17.4 Nevus sebaceus – extensive, yellowish plaque on the face following Blaschko lines

• Surface smooth, velvety or wart-like with a yellowish color

• Size ranges from 0.5 to >6 cm; can be extensive • In childhood, the lesions flatten and become

• •

Prayson RA, Kotagal P, Wyllie E, Bingaman W. Linear epidermal nevus and nevus sebaceus syndrome. Arch Pathol Lab Med 1999; 123: 301–5 Rogers M, McCrossin I, Commens C. Epidermal nevi and the epidermal nevus syndrome. J Am Acad Dermatol 1989; 20: 476–88

Nevus sebaceus Synonym: nevus sebaceus of Jadassohn, organoid nevus Major points

• Congenital hamartoma of skin and adnexae, predominantly sebaceous glands, abortive hair follicles and ectopic apocrine glands

less apparent; thought to be caused by the reduction of maternal hormones and sebaceous glands At puberty, most plaques thicken and become verrucous (Figure 17.5) Development of hamartomatous tumors within the lesion usually after puberty 1. Tumors: syringocystadenoma papilliferum, trichoblastoma, hidradenoma, basal cell carcinoma, others 2. Malignant tumors such as squamous cell carcinoma, apocrine carcinoma and other adnexal carcinomas are rare before age 40 years 3. Detected by development of a papule with ulceration within the lesion Extensive lesions may be associated with multiple systemic manifestations in the nevus sebaceus syndrome (Schimmelpenning syndrome): seizures, mental retardation, arteriovenous malformations of the brain, skeletal abnormalities, ophthalmologic abnormalities

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Prognosis

• Lesions persist throughout life • Potential in adulthood to develop nodules or skin tumors References Cribier B, Scrivener Y, Grosshans E. Tumors arising in nevus sebaceus: a study of 596 cases. J Am Acad Dermatol 2000; 42: 263–8 LeSueur BW, Silvis NG, Hansen RC. Basal cell carcinoma in children: report of 3 cases. Arch Dermatol 2000; 136: 370–2

Figure 17.5 Nevus sebaceus – verrucous plaque on the forehead of an 11-year-old

Pathogenesis

• Complex hamartoma of pilosebaceous follicles, epidermis and adenexal structures that are under hormonal control Diagnosis

• Histology: 1. Early: small underdeveloped sebaceous glands and hair follicles 2. Childhood: small, immature ectopic appendageal structures 3. Puberty: hyperplasia and maturation of the sebaceous glands. Hair follicles remain rudimentary; fully developed apocrine glands occur Differential diagnosis

• • • •

Epidermal nevus Aplasia cutis Congenital triangular alopecia Cutaneous infection (e.g. staphylococcal, streptococcal, herpes simplex)

Oranje AP, Przyrembel H, Meradji M, et al. Solomon’s epidermal nevus syndrome (type: linear nevus sebaceus) and hypophosphatemic vitamin D-resistant rickets. Arch Dermatol 1994; 130: 1167–71 Rogers M, McCrossin I, Commens C. Epidermal nevi and the epidermal nevus syndrome. J Am Acad Dermatol 1989; 20: 476–88 Santibanez-Gallerani A, Marshall D, Duarte AM, et al. Should nevus sebaceus of Jadassohn in children be excised? A study of 757 cases, and literature review. J Craniofac Surg 2003; 14: 658–60 Turner CD, Shea CR, Rosoff PM. Basal cell carcinoma originating from a nevus sebaceus on the scalp of a 7-year-old boy. J Pediatr Hematol Oncol 2001; 23: 247–9

Nevus comedonicus Major points

• Presents at birth or early childhood • Dilated follicular orifices on top of papules, closely set and usually linear (Figure 17.6)

• Site: face, neck, upper arms and chest • Usually solitary • If systematized (rare), developmental defects of the CNS, eyes, bone and skin can be associated

• Usually asymptomatic, but individual papules and cysts within plaques may become inflamed, resembling acne vulgaris

Treatment

Pathogenesis

• Full-thickness surgical excision around the time of

• Considered to be a variant of epidermal nevus, a

puberty is recommended If excision will result in a worse cosmetic defect, then observation may be reasonable CO2 laser is a second choice for destruction of the lesion in a difficult area; however, recurrences may occur

hamartoma of abnormal hair follicle infundibula

• •

Diagnosis

• Clinical diagnosis • Histology: multiple dilated follicles filled with keratinous plugs

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Differential diagnosis

• Acne vulgaris • Nevus sebaceus Treatment • Topical retinoids • Keratolytic agents: 12% ammonium lactate lotion (LacHydrin), tretinoin • Surgical excision Prognosis • Persistent References Beck MH, Dave VK. Extensive nevus comedonicus. Arch Dermatol 1980; 116: 1048–50 Cestari TF, Rubim M, Valentini BC. Nevus comedonicus: case report and brief review of the literature. Pediatr Dermatol 1991; 8: 300–5 Patrizi A, Neri I, Fiorentini C, Marzaduri S. Nevus comedonicus syndrome: a new pediatric case. Pediatr Dermatol 1998; 15: 304–6 Seo YJ, Piao YJ, Suhr KB, et al. A case of nevus comedonicus syndrome associated with neurologic and skeletal abnormalities. Int J Dermatol 2001; 40: 648–50 Vasiloudes PE, Morelli JG, Weston WL. Inflammatory nevus comedonicus in children. J Am Acad Dermatol 1998; 38: 834–6

Figure 17.6 Nevus comedonicus – note the inflamed open and closed comedones

CYSTS Epidermal cyst Major points

• Slow-growing, firm, ballotable round dermal nodule (Figure 17.7)

• Range in size from 0.5 to 15 cm • Neonates:

1. Can be seen anywhere 2. If present in the midline (face, nose) and associated with pits or cysts, may indicate intracranial connection Adolescents: 1. Solitary cysts with acne vulgaris 2. Multiple cysts in childhood or adolescents might suggest Gardner syndrome Ruptured epidermal cysts become markedly inflamed; caused by keratin inciting a foreign body reaction

Figure 17.7 Epidermal cyst – inflamed tender ruptured cyst on the cheek

Pathogenesis

• Epidermal cysts result from the proliferation of surface epidermal cells within the dermis producing keratin. They arise from cells of the follicular infundibulum, or from implantation of epidermal cells into the dermis through trauma, or from trapping of epidermal cells along embryonal fusion planes

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Diagnosis

• Easy to diagnose if there is a central punctum from •

which keratinous material can be expressed Clinically difficult to distinguish between epidermal and dermoid cysts without a biopsy

Vasiloudes PE, Morelli JG, Weston WL. Plantar epidermal cysts in children. Arch Dermatol 1997; 133: 1465 Zuber TJ. Minimal excision technique for epidermoid (sebaceous) cysts. Am Fam Physician 2002; 65: 1409–12, 1417–18, 1420

Differential diagnosis See Table 17.2

Milia

Treatment

Major points

• Surgical excision with removal of the entire cyst wall

• A milium (plural, milia) is a 1–2 mm superficial

Prognosis

• Cysts persist and slowly enlarge over time • If traumatized, the cyst wall can break, extruding keratinous material into the surrounding dermis, causing marked inflammation References Knight PJ, Reiner CB. Superficial lumps in children. Pediatrics 1983; 72: 147–53 Pariser RJ. Benign neoplasms of the skin. Med Clin North Am 1998; 82: 1285–307

• • •

white globoid papule within the epidermis or upper dermis Consists of a tiny ball of keratin with a thin cyst wall Common on the face of newborns, and within scars (especially in epidermolysis bullosa) Milia on the palate of newborns called Epstein pearls

Pathogenesis

• Etiology unknown • Milia are thought to be derived from pilosebaceous follicles Diagnosis

Table 17.2 Benign skin papules, nodules and cysts in infants and children

Epidermal cyst Dermoid cyst Pilomatrixoma Nasal glioma Encephalocele Branchial cleft cyst Milia Eruptive vellus hair cysts Fibroma Neurofibroma Lipoma Panniculitis Juvenile xanthogranuloma Mastocytoma Lymphangioma Granuloma annulare Syringoma Trichoepithelioma Dermatofibroma Keloid Calcinosis cutis Osteoma cutis Foreign body granuloma

• Clinical diagnosis • Histology: identical to an epidermal cyst, differing only in size Differential diagnosis

• Molluscum contagiosum • Keratosis pilaris Treatment

• Lesions can be easily expressed with a comedone extractor after incision with a surgical blade or needle Prognosis

• Superficial milia can spontaneously extrude; deeper ones may be persistent References Bridges AG, Lucky AW, Haney G, Mutasim DF. Milia en plaque of the eyelids in childhood: case report and review of the literature. Pediatr Dermatol 1998; 15: 282–4 Cairns ML, Knable AL. Multiple eruptive milia in a 15year-old boy. Pediatr Dermatol 1999; 16: 108–10

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Girardi M, Federman GL, McNiff JM. Familial multiple basaloid follicular hamartomas: a report of two affected sisters. Pediatr Dermatol 1999; 16: 281–4 Langley RGB, Walsh NMG, Ross JB. Multiple eruptive milia: report of a case, review of the literature, and a classification. J Am Acad Dermatol 1997; 37: 353–6 Stefanidou MP, Panayotides JG, Tosca AD. Milia en plaque: a case report and review of the literature. Dermatol Surg 2002; 28: 291–5

Pathogenesis

• Caused by the sequestration of epithelium along the planes of closure of embryonic clefts Diagnosis

• Biopsy should not be performed unless it is certain there is no intracranial connection

• Histology: an encapsulated cyst with a wall composed of keratinizing, stratified squamous epithelium with hair follicles, sebaceous glands, eccrine and aprocrine glands; within the cyst are lipids, keratin and hair

Dermoid cyst Major points

• Manifest at birth (40%) or before age 5 years • • • •

• •

(70%) Solitary, soft round subcutaneous cyst which is freely moveable within the dermis (Figure 17.8) Sinus opening or hairs may be associated Size usually 1–4 cm Location usually on the forehead, most common in the lateral third of the eyebrow or midline nasal bridge. Also seen on the anterior or lateral neck, sternum, scrotum, perineal raphe and sacral areas In the periorbital area, may cause proptosis or eyelid displacement Most dermoid cysts are superficial, but up to 45% may have intracranial connections to extradural or intradural compartments often indicated by a sinus pit Usually asymptomatic; rarely recurrent infections with cellulitis or abscess; pressure erosion of the bone may occur

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Differential diagnosis See Table 17.2 Treatment

• Simple excision • Midline lesions of the face should be evaluated with an MRI looking for intracranial connections

• Surgery by a pediatric neurosurgeon is essential for •

lesions with intracranial connections in order to avoid ascending infection Dermoid cysts located along the lateral eyebrows rarely have intracranial connections and do not require MRI

Prognosis

• Excellent if completely excised References Ackerman LL, Menezes AH, Follett KA. Cervical and thoracic dermal sinus tracts. A case series and review of the literature. Pediatr Neurosurg 2002; 37: 137–47 Brownstein MH, Helwig EB. Subcutaneous dermoid cysts. Arch Dermatol 1973; 107: 237–9 Drolet BA. Cutaneous signs of neural tube dysraphism. PediatrClin North Am 2000; 47: 813–23 Paller AS, Pensler JM, Tomita T. Nasal midline masses in infants and children. Arch Dermatol 1991; 127: 362–6

Pilomatrixoma Synonym: calcifying epithelioma of Malherbe Major points

• Firm, freely movable slowly growing papule/nodule Figure 17.8

Dermoid cyst – above the eyebrow of an infant

usually 15 cm • If a lesion compresses a nerve, it may be painful • Location often on neck and trunk but can be anywhere

• Usually solitary but may be multiple

Diagnosis

Pathogenesis

• Clinical diagnosis • Biopsy may be necessary to confirm the diagnosis • Histology: small mid-dermal cysts lined by

• Benign mesenchymal tumor of unknown etiology

squamous epithelium; cysts contain lamellar keratin and tiny nonpigmented vellus hair shafts Differential diagnosis

• • • • • •

Epidermoid cysts Syringomas Steatocystoma multiplex Acne Viral exanthems Molluscum contagiosum

Treatment

• Topical keratolytics (e.g. lactic acid, tretinoin cream) may hasten resolution

• Excision or other destructive measures may be needed for larger lesions Prognosis

• Lesions may spontaneously resolve over months to years

• New lesions can continue to form

Diagnosis

• Histology: well-circumscribed sheets of mature, uniform adipocytes with thin strands of fibrous tissue intersecting the sheets of adipocytes Differential diagnosis See Table 17.2 Treatment

• Surgical excision if indicated Prognosis

• Most lipomas are asymptomatic and stable • Trauma or ischemia can cause necrosis of lipomas with pain, and later dystrophic calcification References McAtee-Smith J, Hebert AA, Rapini RP, Goldberg NS. Skin lesions of the spinal axis and spinal dysraphism. Arch Pediatr Adolesc Med 1994; 148: 740–8 Salam GA. Lipoma excision. Am Fam Physician 2002; 65: 901–4

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Sanchez MR, Colomb FM, Moy JA, Petozkin JR. Giant lipoma: case report and review of the literature. J Am Acad Dermatol 1993; 28: 266–8 Trapp CF, Baker EJ. Mobile encapsulated lipomas. Cutis 1992; 49: 63–4 Zvijac JE, Sheldon DA, Schurhoff MR. Extensive lipoma causing suprascapular nerve entrapment. Am J Orthop 2003; 32: 141–3

Knuttel R, Silver EA. A cerebriform mass on the right buttock. Dermatol Surg 2003; 29: 780–1 Lane JE, Clark E, Marzec T. Nevus lipomatosus cutaneus superficialis. Pediatr Dermatol 2003; 20: 313–14

Anetoderma Synonym: macular atrophy Major points

Nevus lipomatosus

• Multiple oval depressions or slightly bulging

Major points

• Herniates inward with fingertip pressure • Location: mainly upper trunk and upper arms, but

papules with wrinkled surface (Figure 17.11)

• Presents at birth or childhood • Multiloculated yellowish or skin-colored plaque of • • • •

rubbery papules and nodules Location usually in lumbosacral area or thighs but may be anywhere Size usually several centimeters or larger Asymptomatic No underlying associations

Pathogenesis

• Rare, benign hamartoma of mature fat cells Diagnosis

• Histology: mature, polypoid fat with the appearance of an acrochordon (skin tag) Differential diagnosis

• Goltz syndrome (focal dermal hypoplasia) • Encephalocraniocutaneous lipomatosis

can be anywhere

• May or may not be preceded by inflammation • Secondary anetoderma may develop after certain cutaneous processes such as syphilis, leprosy, lupus and others Pathogenesis

• Results from increased degradation or reduced synthesis of elastic tissue

• Histology: 1. Perivascular infiltrate of lymphocytes (predominantly helper T cells) 2. Scattered macrophages, giant cells with some elastophagocytosis 3. In established lesion, elastic fibers are sparse in superficial dermis and almost completely absent in mid-dermis

Treatment

• None usually needed • Surgical excision • Liposuction Prognosis

• Benign with no malignant potential References Bergonse FN, Cymbalista NC, Nico MM, et al. Giant nevus lipomatosus cutaneus superficiails: case report and review of the literature. J Dermatol 2000; 27: 16–19 Inoue M, Ueda K, Hashimoto T. Nevus lipomatosus cutaneus superficialis with follicular papules and hypertrophic pilo-sebaceous units. Int J Dermatol 2002; 41: 241–3

Figure 17.11 Anetoderma – note wrinkly skin overlying slightly raised plaques

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Diagnosis

• Clinical diagnosis Differential diagnosis

• Connective tissue nevus • Nevus lipomatosis Treatment

• None known to help Prognosis

• Stable or may increase in number References Colditz PB, Dunster KR, Joy GJ, et al. Anetoderma of prematurity in association with electrocardiographic electrodes. J Am Acad Dermatol 1999; 41: 479–81 Ghomrasseni S, Dridi M, Gogly B, et al. Anetoderma: an altered balance between metalloproteinases and tissue inhibitors of metalloproteinases. Am J Dermatopathol 2002; 24: 118–29 Karrer S, Szeimies R-M, Stolz W, Landthaler M. Primary anetoderma in children: report of two cases and literature review. Pediatr Dermatol 1996; 13: 382–5 Prizant TL, Lucky AW, Frieden IJ, et al. Spontaneous atrophic patches in extremely premature infants. Arch Dermatol 1996; 132: 671–4 Sparsa A, Piette JC, Wechsler B, et al. Anetoderma and its prothrombotic abnormalities. J Am Acad Dermatol 2003; 49: 1008–12 Thomas JE, Mehregan DR, Holland J, Mehregan DA. Familial anetoderma. Int J Dermatol 2003; 42: 75–7

Figure 17.12 Piezogenic pedal papules – herniations of fat which are more pronounced when standing

• Histology: thickened dermis, loss of normal small fat compartments in the lower dermis and subcutis with many protrusions of enlarged fat lobules into the dermis caused by degeneration of the thin fibrous septa Diagnosis

• Clinical diagnosis Differential diagnosis

• Lipomas • Connective tissue nevus • Plexiform neurofibroma Treatment

• Special orthotic heel cups for severely painful Piezogenic pedal papules

lesions Prognosis

Major points

• Common entity found in 10–20% of the general • • • •

population More common in women Asymptomatic skin-colored papules seen along the sides of the plantar surface only when weightbearing (Figure 17.12) Occasionally painful Often seen in runners

Pathogenesis

• Caused by herniations of subcutaneous fat into the dermis on the sides of the feet caused by weight bearing

• Usually stable unless there is chronic stress on the feet, in which case it may progress References Boni R, Dummer R. Compression therapy in painful piezogenic pedal papules. Arch Dermatol 1996; 132: 127–8 Van Straaten EA, Van Langen IM, Oorthuys JWE, Oosting J. Piezogenic papules of the feet in healthy children and their possible relation with connective tissue disorders. Pediatr Dermatol 1991; 8: 277–9 Woodrow SL, Brereton-Smith G, Handfield-Jones S. Painful piezogenic pedal papules: response to local electroacupuncture. Br J Dermatol 1997; 136: 628–30

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Panniculitis

Table 17.3

Types of panniculitis

Major points

• Panniculitis is a term used to describe a group of • • • • • • •

diseases with inflammation in the subcutaneous fat (see Table 17.3) Presents with erythematous or violaceous, painful, subcutaneous nodules (Figures 17.13 and 17.14) Size usually 1–4 cm Common location: lower legs, symmetrical, but nodules may be anywhere Usually do not ulcerate Recurrent crops Lesions involute over a few weeks, and erythema is replaced with hyperpigmentation Erythema nodosum – most common type of panniculitis (see Table 17.4)

Pathogenesis

• Inflammation of fat; etiology depends upon type of panniculitis Diagnosis

• Histology: degeneration and necrosis of lipocytes with an infiltrate of polymorphonuclear leukocytes and lymphocytes within the lobules of fat or in the septae Differential diagnosis

• Epidermal cyst (ruptured) • Cellulitis

Neonatal panniculitis Sclerema neonatorum Subcutaneous fat necrosis of the neonate Physical panniculitis Cold-induced (popsicle panniculitis) Traumatic Chemical-induced Factitial Post-steroid injection Systemic diseases with panniculitis Systemic lupus erythematosus Pancreatitis Sarcoidosis Renal failure Lymphoma Leukemia Infections α1-antitrypsin deficiency Vasculitis Nodular vasculitis Polyarteritis nodosa Cutaneous polyarteritis nodosa Superficial migratory thrombophlebitis Septal panniculitis without vasculitis Erythema nodosum Scleroderma panniculitis Eosinophilic fasciitis Eosinophilic myalgia syndrome Idiopathic lobular panniculitis (Weber–Christian disease)

Treatment

• • • •

Bed rest if lesions occur on legs Withdrawal of offending agent (e.g. drugs) Nonsteroidal anti-inflammatory agents Oral steroids may be indicated, particularly in cases of vasculitis

Prognosis

• Course variable, depending upon the type of panniculitis

• May spontaneously resolve or persist with new lesions occurring in crops References Aronson IK, Zeitz HJ, Variakojis D. Panniculitis in childhood. Pediatr Dermatol 1988; 5: 216–30

Figure 17.13

Panniculitis associated with Crohn disease

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309

Major etiologies of erythema

Drug-induced Sulfonamides Bromides Oral contraceptives Bacterial infections Streptococcal infections Yersinia enterocolitica Mycoplasma pneumoniae Leprosy Leptospirosis Tularemia Bartonella henselae (cat scratch disease) Fungal infections Coccidioidomycosis Blastomycosis Histoplasmosis Dermatophytosis

Figure 17.14 Popsicle panniculitis – caused by sucking on a cold popsicle

Viral infections/other infections Paravaccinia Infectious mononucleosis Hepatitis B Psittacosis Tuberculosis

Eberhard BA, Ilowite NT. Panniculitis and lipodystrophy. Curr Opin Rheumatol 2002; 14: 566–70 McBean J, Sable A, Maude J, Robinson-Bostom L. Alpha1antitrypsin deficiency panniculitis. Cutis 2003; 71: 205–9 Ruiz-Maldonado R, Parrilla FM, Luz Orozco-Covarrubias M, et al. Edematous, scarring vasculitic panniculitis: a new multisystemic disease with malignant potential. J Am Acad Dermatol 1995; 32: 37–44 Sutra-Loubet C, Carlotti A, Guillemette J, Wallach D. Neutrophilic panniculitis. J Am Acad Dermatol 2004; 50: 280–5

Other diseases Sarcoidosis Ulcerative colitis Crohn disease Lymphoma Leukemia Behçet syndrome

CONNECTIVE TISSUE

3. 4. 5. 6. 7. 8.

Fibromatoses General

• Two broad groups: superficial (fascial) fibromatoses, and deep (musculoaponeurotic) fibromatoses

• Benign proliferations of myofibroblasts Major points

• Infantile digital fibromatosis 1. Most common fibrous proliferation in the first year of life 2. Solitary, smooth, dome-shaped nodule on the distal digital phalanx, which is either skincolored or red (Figure 17.15)

Size reaches 1–3 cm Multiple tumors common Fingers affected commonly (86%) No sex predilection Can spontaneously involute May need to be surgically excised, but there is a high recurrence rate Infantile myofibromatosis 1. Seen at birth or early life 2. Multiple cutaneous nodules with underlying tumors in the muscle, bone and visceral organs 3. Lesions are firm, skin-colored to red-purple nodules ranging in size from 0.5 to 7 cm 4. If limited to skin and bones, does not require treatment unless there is functional

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• Fibrous hamartoma of infancy

1. Solitary (or multiple) nodules usually located on the shoulder, arm or axilla 2. Present at birth or shortly after 3. Treat with excision; recurrence is uncommon Juvenile hyaline fibromatosis 1. Very rare triad of fibrous growths on the head and neck, flexion contractures and gingival hyperplasia 2. Skull and encephalic abnormalities 3. Autosomal recessive 4. Relentless progression

Pathogenesis • Etiology is unknown, but fibromatoses are characterized by a proliferation of fibrous/myofibrous tissue Figure 17.15 Infantile digital fibromatosis – painless, firm papules on an infant’s fingers

impairment. More aggressive types may require chemotherapy or radiation and may be fatal Plantar fibromatosis 1. Firm, nontender nodule on mid-plantar surface of foot present at birth 2. Uncomfortable when child walks 3. Requires excision when symptomatic; recurrence is uncommon if completely excised Knuckle pads 1. Solitary or multiple thickenings over the metacarpophalangeal or proximal interphalangeal joints (Figure 17.16) 2. Require no treatment

Diagnosis • Histology is essential 1. Infantile digital fibromatosis: perinuclear cytoplasmic inclusions seen with trichrome stain (may represent actin microfilaments) within a proliferation of fibrous tissue 2. Infantile myofibromatosis: spindle-shaped fibroblasts in whorls and interlacing bundles 3. Fibrous hamartoma of infancy: distinctive tracts of fibroblasts, fat and small blue cells within the lesion 4. Juvenile hyaline fibromatosis: hyalinized collagen with fibroblast proliferation Differential diagnosis • Knuckle pads: Gottron papules (dermatomyositis), acanthosis nigricans • Infantile myofibromatosis: soft tissue sarcomas, hemangioendotheliomas, fibrosarcomas, lipomas, fibrous histiocytomas, lipoblastomas, neurofibromas, rhabdomyosarcomas • Infantile digital fibroma/fibrous hamartoma of infancy: sarcoma Prognosis • Deeper variants can behave aggressively and become infiltrative but do not metastasize References

Figure 17.16

Knuckle pads on all the fingers

Bellman B, Wooming G, Landsman L, et al. Infantile myofibromatosis: a case report. Pediatr Dermatol 1991; 8: 306–9

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Caylakli F, Cakmak O, Seckin D, et al. Juvenile hyaline fibromatosis: a case report. Int J Pediatr Otorhinolaryngol 2003; 67: 557–61 Counsell SJ, Devile C, Mercuri E, et al. Magnetic resonance imaging assessment of infantile myofibromatosis. Clin Radiol 2002; 57: 67–70 Dickey GE, Sotelo-Avila C. Fibrous hamartoma of infancy: current review. Pediatr Dev Pathol 1999; 2: 236–43 Eich GF, Hoeffel JC, Tschappeler H, et al. Fibrous tumours in children: imaging features of a heterogeneous group of disorders. Pediatr Radiol 1998; 28: 500–9 Gandhi MM, Nathan PC, Weitzman S, Levitt GA. Successful treatment of life-threatening generalized infantile myofibromatosis using low-dose chemotherapy. J Pediatr Hematol Oncol 2003; 25: 750–4 Goldberg NS, Bauer BS, Kraus H, et al. Infantile myofibromatosis: a review of clinicopathology with perspectives on new treatment choices. Pediatr Dermatol 1988; 5: 37–46 Haleem A, Al-Hindi HN, Juboury MA, et al. Juvenile hyaline fibromatosis: morphologic, immunohistochemical, and ultrastructural study of three siblings. Am J Dermatopathol 2002; 24: 218–24 Ikediobi NI, Iyengar V, Hwang L, et al. Infantile myofibromatosis: support for autosomal dominant inheritance. J Am Acad Dermatol 2003; 49 (2 Suppl): S148–50 Kang SK, Chang SE, Choi JH, et al. A case of congenital infantile digital fibromatosis. Pediatr Dermatol 2002; 19: 462–3 Kanwar AJ, Kaur S, Thami GP, Mohan H. Congenital infantile digital fibromatosis. Pediatr Dermatol 2002; 19: 370–1

Figure 17.17

• • • •

Keloids Major points

• Caused by unchecked proliferation of fibrous tissue and collagen following an injury to the dermis which invades the surrounding skin Diagnosis

• Histology: whorls of young fibrous tissue and fibroblasts arranged in a haphazard manner with thick, eosinophilic, acellular bands of collagen and thickening of dermis; mast cells and plasma cells increased in number; elastin usually absent Differential diagnosis

• Hypertrophic scar • Fibrosarcoma Treatment

• Intralesional steroids (e.g. triamcinolone

• Mildly tender, firm papule or nodule arising in site

of previous injury (e.g. surgery, ear piercing, cystic acne, burns) and extends beyond the border of the original injury (Figure 17.17) Lesions are skin-colored, pink or hyperpigmented

Can be disfiguring May be painful, especially when growing Common locations are shoulders, chest and earlobes More common in dark-skinned teenagers

Pathogenesis

Keltz M, DiCostanzo D, Desai P, Cohen SR. Infantile (desmoid-type) fibromatosis. Pediatr Dermatol 1995; 12: 149–51 Rahman N, Dunstan M, Teare MD, et al. The gene for juvenile hyaline fibromatosis maps to chromosome 4q21. Am J Hum Genet 2002; 71: 975–80

Keloid – firm plaque in a scar

10–40 mg/ml) given every 2–4 weeks until flattened and not growing Larger lesions should be excised with subsequent steroid injections until growth of the lesion has stopped

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Prognosis

Diagnosis

• Keloids tend to persist and enlarge slowly over

• Clinical diagnosis

time and can recur even when treated References Berman B, Bieley HC. Keloids. J Am Acad Dermatol 1995; 33: 117–23 Gold MH. A controlled clinical trial of topical silicone gel sheeting in the treatment of hypertrophic scars and keloids. J Am Acad Dermatol 1994; 30: 506–7 Kelly AP. Pseudofolliculitis barbae and acne keloidalis nuchae. Dermatol Clin 2003; 21: 645–53 Marneros AG, Norris JEC, Olsen JR, Reichenberger E. Clinical genetics of familial keloids. Arch Dermatol 2001; 137: 1429–34 Poochareon VN, Berman B. New therapies for the management of keloids. J Craniofac Surg 2003; 14: 654–7 Rahban SR, Garner WL. Fibroproliferative scars. Clin Plast Surg 2003; 30: 77–89 Sahl WJ, Clever J. Cutaneous scars: part II. Int J Dermatol 1994; 33: 763–9

Acne keloidalis nuchae Major points:

• Chronic scarring folliculitis located on posterior • • • •

neck in young Black men Characteristic follicular papules that coalesce into firm plaques and nodules (Figure 17.18) Begins with a chronic folliculitis which heals with keloid-like papules Can form small to large plaques Lesions usually pruritic or painful

Differential diagnosis

• Folliculitis • Hypertrophic scars • Pseudofolliculitis barbae Treatment

• Early treatment essential • Intralesional steroids or short course of oral • •

steroids for acute inflammation Surgical excision followed by intralesional steroids if extensive Oral antibiotics (e.g. minocycline, doxycycline) and topical retinoids

Prognosis

• Chronic unless treated References Dinehart SM, Herzberg AJ, Kerns BJ, Pollack SV. Acne keloidalis: a review. J Dermatol Surg Oncol 1989; 15: 642–7 Giovannini UM. Treatment of scars by steroid injections. Wound Repair Regeneration 2002; 10: 116–17 Glenn MJ, Bennett RG, Kelly AP. Acne keloidalis nuchae: treatment with excision and second-intention healing. J Am Acad Dermatol 1995; 33: 243–6 Tsao SS, Dover JS, Arndt KA, Kaminer MS. Scar management: keloid, hypertrophic, atrophic, and acne scars. Semin Cutan Med Surg 2002; 21: 46–75

Pathogenesis

• Etiology uncertain • Aggravated by shaving tightly curled hair at the

nape of the neck and having the new hair curve back into the skin, causing inflammation at the deep infundibular and isthmic levels of the hair follicle Histology: 1. Early: inflammatory cells in the upper onethird of hair follicle; sebaceous glands diminished 2. Later: dermal fibrosis and scar formation

Figure 17.18 Acne keloidalis nuchae – typically seen at the nape of the neck

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Hypertrophic scars

Striae distensae

Major points

Major points

• Firm, slightly raised, flat, pink or red nodule or

• Visible scars with linear, smooth bands of atrophic

plaque in the area of previous injury or inflammation but stays within the site of original injury

skin (Figure 17.19) Begin as reddish streaks, then turn purple, and finally white

Pathogenesis

• Caused by unchecked proliferation of fibrous tissue following an injury to the dermis Diagnosis

• Histology: whorls of young fibrous tissue and fibroblasts arranged in a haphazard manner with marked thickening of the dermis Differential diagnosis

• • • •

Keloid Basal cell carcinoma Skin appendage tumors Dermatofibroma

Treatment

Figure 17.19 Striae distensae (‘stretch marks’) occur commonly in teens on the lower back, inner thighs and breasts

• Intralesional steroids (e.g. triamcinolone •

10–40 mg/ml) given every 2–4 weeks until flattened Silicone gel sheeting worn continuously for several months

Prognosis

• Most common sites: thighs, buttocks, breasts in girls, lower back in boys Pathogenesis

• Histology: thin overlying epidermis, fine dermal

• Hypertrophic scars can flatten with time, but are usually stable after 1 year References Brissett AE, Sherris DA. Scar contractures, hypertrophic scars, and keloids. Fac Plast Surg 2001; 17: 263–72 Gold MH. A controlled clinical trial of topical silicone gel sheeting in the treatment of hypertrophic scars and keloids. J Am Acad Dermatol 1994; 30: 506–7 Nemeth AJ. Keloids and hypertrophic scars. J Dermatol Surg Oncol 1993; 19: 738–46

• •

collagen bundles arranged in straight parallel lines, some inflammation, and elastolysis; late stages show dermal collagen in thin eosinophilic bundles, oriented in straight lines Pathogenesis unknown, probably relates to changes in extracellular matrix components Causes: puberty, obesity, corticosteroids, pregnancy, increased adrenocortical function, genetic factors

Diagnosis

• Clinical inspection

Sahl WJ, Clever J. Cutaneous scars: part II. Intern J Dermatol 1994; 33: 763–9

Differential diagnosis

Shaffer JJ, Taylor SC, Cook-Bolden F. Keloidal scars: a review with a critical look at therapeutic options. J Am Acad Dermatol 2002; 46 (2 Suppl): S63–97

• Ehlers–Danlos syndrome • Marfan syndrome • Child abuse

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Treatment

• Usually no treatment is necessary • Pulsed dye laser can improve redness in early • •

lesions Discontinuance of steroids, if this is a precipitating factor Emollients (e.g. petrolatum, cocoa butter)

Prognosis

• Lesions are permanent References Di Lernia V, Bonci A, Cattania M, Bisighini G. Striae distensae (rubrae) in monozygotic twins. Pediatr Dermatol 2001; 18: 261–2 Garcia Hidalgo L. Dermatological complications of obesity. Am J Clin Dermatol 2002; 3: 497–506 Jabbour SA. Cutaneous manifestations of endocrine disorders: a guide for dermatologists. Am J Clin Dermatol 2003; 4: 315–31 McDaniel DH. Laser therapy of stretch marks. Dermatol Clin 2002; 20: 67–76

Dermatofibroma Synonym: fibrous histiocytoma Major points

• Common, benign, asymptomatic papule or papules ranging from 0.5 mm to 1 cm, commonly found on the lower legs, but may occur anywhere (Figure 17.20)

• Usually solitary but may be multiple • Color varies: yellow, red, purple or dark brown with rim of brown pigment and variation in color

• Palpation: firm or hard; feels like a pea which is •

fixed to the skin surface and freely movable over the subcutis Lateral pressure produces a ‘dimple sign’ with an overlying depression in the center of the papule

Pathogenesis • Cause unknown but thought to be the result of trauma, insect bites, or viral infection Diagnosis • Clinical features characteristic • Histology: whorling fascicles of spindle cells; edges are poorly defined. A Grenz zone of normal tissue lies above the lesion in the papillary dermis; epidermis is acanthotic Differential diagnosis • Nevocellular nevus • Melanoma • Xanthoma • Prurigo nodularis • Seborrheic keratosis • Dermatofibrosarcoma protuberans Treatment • None usually needed • Excision if painful or large Prognosis

• Lesions are benign and usually stable • Can resolve, leaving hypo- or hyperpigmentation References Bouyssou-Gauthier M-L, Labrousse F, Longis B, et al. Dermatofibrosarcoma protuberans in childhood. Pediatr Dermatol 1997; 14: 463–5 Curco N, Jucgla A, Bordas X, Moreno A. Dermatofibroma with spreading satellitosis. J Am Acad Dermatol 1992; 27: 1017–18 Holst VA, Junkins-Hopkins JM, Elenitsas R. Cutaneous smooth muscle neoplasms: clinical features, histologic findings, and treatment options. J Am Acad Dermatol 2002; 46: 477–90 Figure 17.20 Dermatofibroma – firm brown papule commonly seen on the lower legs

Kutzner H. Expression of the human progenitor cell antigen CD34 (HPCA-1) distinguishes dermatofibrosarcoma protuberans from fibrous histiocytoma in formalin-fixed,

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paraffin-embedded tissue. J Am Acad Dermatol 1993; 28: 613–17

• Those associated with neurofibromatosis tend to

Lew W, Lim HS, Kim YC. Cutaneous metastatic malignant fibrous histiocytoma. J Am Acad Dermatol 2003; 48 (2 Suppl): S39–40

References

Niiyama S, Katsuoka K, Happle R, Hoffmann R. Multiple eruptive dermatofibromas: a review of the literature. Acta Derm Venereol 2002; 82: 241–4

Neurofibroma Major points

• Presents as a skin-colored papule or nodule, soft to palpation ranging in size from 0.5 to >3 cm

• Upon pressure to the lesion, the neurofibroma • • •

pushes into the skin giving the sensation that one is pushing a button through a buttonhole Some lesions are pedunculated Usually solitary unless seen in the context of neurofibromatosis (see Chapter 20) Variants such as plexiform neurofibroma can be seen in neurofibromatosis

Pathogenesis • Hyperplasia of nerve elements arising in nerves, composed of Schwann cells, fibroblasts and endothelial cells Diagnosis • Biopsy often needed for confirmation • Histology: Schwann cells, fibroblasts, endothelial cells, mast cells, perineural fibroblasts and axons arranged haphazardly in a matrix containing collagen and myxoid ground substance; circumscribed but not encapsulated Differential diagnosis • Dermal nevus • Skin tag (acrochordon) • Dermatofibroma Treatment

• Usually no treatment needed • Simple excision if indicated Prognosis • Small neurofibromas not associated with neurofibromatosis tend to remain stable or slowly enlarge with time

enlarge slowly

DeBella K, Szudek J, Friedman JM. Use of the National Institutes of Health criteria for diagnosis of neurofibromatosis 1 in children. Pediatrics 2000; 105: 608–14 Johnson NS, Saal HM, Lovell AM, Schorry EK. Social and emotional problems in children with neurofibromatosis type 1: evidence and proposed interventions. J Pediatr 1999; 134: 767–72 Kandt RS. Tuberous sclerosis complex and neurofibromatosis type 1: the two most common neurocutaneous diseases. Neurol Clin 2003; 21: 983–1004 Riccardi VM. Of mass and men. Neurofibromas and histogenesis [Editorial]. Arch Dermatol 2000; 136: 1257–8 Viskochil DH. It takes two to tango: mast cell and Schwann cell interactions in neurofibromas. J Clin Invest 2003; 112: 1791–3

Corns and calluses Synonym: clavus (multiple: clavi) Major points

• Hyperkeratotic plaque seen over pressure or frictional areas typically on the feet

• When pared with a blade, there is a central • •

translucent core, without thrombosed capillaries (as seen in warts) Corns can be hard, soft, vascular, or neurovascular Hard corns are usually over the dorsal interphalangeal joints, on the plantar surface underlying the metatarsal heads, or on the great toe Soft corns arise interdigitally, typically in the fourth web space

Pathogenesis

• Corns are caused by ill-fitting footwear with pointed toes causing crowding in the shoe toe box, or from the digits pressing on each other Diagnosis

• Clinical features Differential diagnosis

• Verruca vulgaris • Verruca plantaris

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• Glomus tumors • Eccrine poroma

(termed peau d’orange, ‘skin of an orange’)

• Solitary lesions usually measure 2–10 cm, whereas

Treatment

clustered lesions usually are 4–5 mm

• Pare with scalpel blade • Salicylic acid plasters and other keratolytics used in •

• Surface of plaque has a pebbled appearance

• Associations: 1. Tuberous sclerosis: shagreen plaques 2. Buschke–Ollendorff syndrome (dermatofibrosis lenticularis disseminata) shows multiple small CTN and osteopoikilosis (bony dysplasia of the long bones, pelvis, hands and feet)

combination with paring Obtain shoes that fit better

Prognosis

• Lesions are stable or progressive unless underlying cause is addressed

Pathogenesis

References

• Hamartoma with various amounts of collagen,

Smith M. Environmental and sports-related skin diseases. In Dermatology. Bolognia JL, Jorizzo JL, Rapini R, eds. Mosby: London, 2003: 1399

Diagnosis

Connective tissue nevus

• Often requires biopsy for confirmation • Biopsy should be a small wedge biopsy including

elastin and adipose tissue without increase in fibroblasts

lesional and nonlesional skin in order to compare normal and abnormal dermal tissues

Major points

• Connective tissue nevi (CTN) are hamartomas of

• • • • •

either collagen or elastin or an abnormality in ground substance plus structural components of connective tissue Male/female ratio = 1 Sporadic or autosomal dominant inheritance Usually present at birth or in early childhood Characteristic firm, nontender, irregularly shaped, or oval skin-colored plaque (Figure 17.21) Common locations: trunk, buttocks, or extremities

Differential diagnosis

• • • • • •

Smooth muscle hamartoma Plexiform neurofibroma Neurofibroma Amyloidosis Colloid millium Nevus lipomatosus

Treatment

• Reassurance to parents of benign nature • Surgical excision Prognosis

• Most solitary CTN are benign and not associated with other syndromes References Chang SE, Kang SK, Kim ES, et al. A case of congenital mucinous nevus: a connective tissue nevus of the proteoglycan type. Pediatr Dermatol 2003; 20: 229–31 Crivellato E. Disseminated nevus anelasticus. Int J Dermatol 1986; 25: 171–3 DePadova-Elder S, Mols-Kowalczewski BL, Lambert WC. Multiple connective tissue nevi. Cutis 1988; 42: 222–4 Figure 17.21 plaque

Connective tissue nevus – skin-colored

Uitto J, Santa Cruz DJ, Eisen AZ. Connective tissue nevi of the skin. J Am Acad Dermatol 1980; 3: 441–61

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Yeh SW, Magalhaes AM, Vasconcellos MR, et al. Zosteriform connective tissue nevus: a case report. Int J Dermatol 2003; 42: 720–2

Smooth muscle hamartoma

spectrum, with varying increases of epidermis, smooth muscle and hair appendages Diagnosis • Histology: numerous smooth muscle fibers oriented haphazardly within the dermis

Major points

Differential diagnosis

• Lesions are solitary, skin-colored or

• • • • •

hyperpigmented, infiltrative patches or plaques with accentuation of hair follicles (Figure 17.22)

317

Mastocytoma Connective tissue nevus Plexiform neurofibroma Congenital nevus Becker nevus

Treatment • None needed • Seldom requires excision Prognosis

• Lesion is benign and stable References D’Addario SF, Morgan M, Talley L, Smoller BR. h-Caldesmon as a specific marker of smooth muscle cell differentiation in some soft tissue tumors of the skin. J Cutan Pathol 2002; 29: 426–9 Grau-Massanes M, Raimer SS, Colome-Grimmer M, et al. Congenital smooth muscle hamartoma presenting as a linear atrophic plaque: case report and review of the literature. Pediatr Dermatol 1996; 13: 222–5 Figure 17.22 Smooth muscle hamartoma – with overlying hypertrichosis

• • • • • • •

Size usually 1–5 cm Hypertrichosis develops in two-thirds of lesions Often overlooked in infancy Rarely acquired in later life Common location in lumbosacral area (67%) No associated systemic abnormalities When firmly stroked, fasciculation of the skin causes the appearance of goosebumps or cobblestones (pseudo-Darier sign) from the stimulation of aberrant arrector pili muscles Slight male predominance

Pathogenesis

• Some authors think smooth muscle hamartoma and Becker nevus are hamartomas of a single

Gualandri L, Cambiaghi S, Ermacora E, et al. Multiple familial smooth muscle hamartomas. Pediatr Dermatol 2001; 18: 17–20 Holst VA, Junkins-Hopkins JM, Elenitsas R. Cutaneous smooth muscle neoplasms: clinical features, histologic findings, and treatment options. J Am Acad Dermatol 2002; 46: 477–90

INFILTRATIONS Juvenile xanthogranuloma Major points

• Most common non-Langerhans cell histiocytosis of childhood

• Sporadic in occurrence • No sexual or racial predilection • Usually appear in early infancy, between 1 and 4 years

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• One lesion (25% of cases) to hundreds of firm, • • • •

• •

reddish-yellow papules/nodules; size 1–10 mm (Figure 17.23) Continues to develop lesions over 2 years Telangiectasias on surface are common Occasional superficial erosions Types: 1. Disseminated micronodular juvenile xanthogranuloma (JXG): small papular lesions (95% of cases of mastocytosis: solitary mastocytoma, urticaria pigmentosa and diffuse mastocytosis

1. Usually solitary, but occasionally several lesions 2. New lesions develop for several months after the first lesion appears, but tend not to continue to develop past 1 year 3. Most common on neck, arms and trunk, but can be anywhere 4. Typical oval to round 1–5 cm slightly brownish yellow nodule which feels thickened or rubbery with a pebbly surface 5. Darier sign: urtication can be demonstrated by stroking the lesion with a typical wheal and flare 6. History of bulla formation, generalized pruritus, flushing, colicky abdominal pain, diarrhea 7. Symptoms often resolve within 2 years, even when the lesion persists 8. Most plaques have flattened or disappeared by age 10 years Urticaria pigmentosa (UP) 1. Most common form of mastocytosis 2. Predominantly a disease of infants and young children 3. Symptoms begin between 3 and 9 months 4. Numerous 5 mm to 2 cm reddish brown to yellowish brown slightly elevated nodules, predominantly on the trunk, but can be anywhere; generally has fewer lesions (Figure 17.25) 5. Darier sign is positive in most lesions (Figure 17.26) 6. May be associated with dermatographism 7. New lesions may continue to develop for many years 8. Bullae may develop within the lesions 9. Pruritus is often the only symptom 10. History of bulla formation, generalized pruritus, flushing, colicky abdominal pain, diarrhea Diffuse cutaneous mastocytosis (DCM) 1. Rare in childhood 2. Neonates born with erythematous, thickened doughy feeling skin which appears lichenified 3. Severe widespread bullae may occur 4. Systemic involvement is prominent with flushing, diarrhea, vomiting, abdominal pain, respiratory distress, shock; can be fatal

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• Malignant mast cell disease

Figure 17.25 Mastocytosis – typical urticaria pigmentosa with numerous brown-yellow papules

1. Involvement of hematopoietic and reticuloendothelial systems 2. Occurs in 30% of adults with mastocytosis; very rare in children 3. One reported case of acute lymphoblastic leukemia associated with UP in a child Mastocytosis syndrome 1. Results from massive release of vasoactive mediators from mast cells 2. Can be caused by any mast cell degranulator (see Table 17.5) 3. Symptoms: flushing, tachycardia, diarrhea, projectile vomiting, abdominal pain, respiratory distress (wheezing), hypotension, severe pruritus and potential shock 4. Should be treated immediately

Pathogenesis

• Thought to represent a reactive hyperplasia of normal mast cells, rather than a neoplasia

Table 17.5

Figure 17.26 Mastocytosis – Darier sign can be elicited by rubbing a lesion of mastocytosis

• Telangiectasia eruptiva macularis perstans (TMEP)

1. Seen in 11 years for extensive disease Symptoms of mastocytosis syndrome (e.g. hypotension, wheezing, shock) should be treated aggressively with intravenous fluids, antihistamines, epinephrine, corticosteroids and vasopressors Parents of children should always carry a list of potential drugs which can degranulate mast cells to avoid complications (Table 17.5) Some children with extensive disease would benefit from an identification bracelet and a syringe of epinephrine kept nearby (e.g. EpiPen®)

Differential diagnosis

Prognosis

• Solitary mastocytoma/urticaria pigmentosa

• Solitary mastocytoma resolves with few sequelae;

1. Juvenile xanthogranuloma 2. Spitz nevus 3. Nodular scabies

bullae rarely scar

• Urticaria pigmentosa in childhood spontaneously resolves. A small number of patients with more

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systemic manifestations will continue into adulthood, and have a more guarded prognosis Diffuse cutaneous mastocytosis with early onset of blisters has a poor prognosis. Without blisters, the prognosis is better. Eventually, the skin improves in symptoms and texture Malignant mast cell disease with infiltration of bone marrow and other organs has a very poor prognosis Severe symptoms should be treated in the emergency room

References Almahroos M, Kurban AK. Management of mastocytosis. Clin Dermatol 2003; 21: 274–7

Figure 17.27 on an elbow

Caken H, Ciftci A, Kisaarslan AF, et al. A child with systemic mastocytosis who had a facial appearance resembling an aged man. Pediatr Dermatol 2002; 19: 184–5

• May be tender and ulcerate, discharging gritty

Golkar L, Bernhard JD. Mastocytosis. Lancet 1997; 349: 1379–85

• Distribution can be anywhere, but most common

Heide R, Tank B, Oranje AP. Mastocytosis in childhood. Pediatr Dermatol 2002; 19: 375–81

• With extensive calcinosis, complications of

Longley J, Duffy TP, Kohn S. The mast cell and mast cell disease. J Am Acad Dermatol 1995; 32: 545–61

material on the extremities, face and scrotum

Murphy M, Walsh D, Drumm B, Watson R. Bullous mastocytosis: a fatal outcome. Pediatr Dermatol 1999; 16: 452–5 Shah PY, Sharma V, Worobec AS, et al. Congenital bullous mastocytosis with myeloproliferative disorder and c-kit mutation. J Am Acad Dermatol 1998; 39: 119–21 Tharp MD. Understanding mast cells and mastocytosis. J Invest Dermatol 1997; 108: 698–9 Tharp MD, Chan IJ. Mastocytosis. Adv Dermatol 2003; 19: 207–36 Valent P, Akin C, Sperr WR, et al. Diagnosis and treatment of systemic mastocytosis: state of the art. Br J Haematol 2003; 122: 695–717 Valent P, Akin C, Sperr WR, et al. Mast cell proliferative disorders: current view on variants recognized by the World Health Organization. Hematol Oncol Clin North Am 2003; 17: 1227–41

Calcinosis cutis Major points

• Presents with firm, stony 1–30-mm papules or plaques which may have an erythematous border (Figure 17.27)

Calcinosis cutis – rock-hard, white papules

contractures, pain and suppuration with or without superinfection may occur Dystrophic calcinosis cutis 1. Most common form of calcinosis cutis 2. Caused by deposition of calcium salts within previously damaged tissues with no metabolic abnormalities 3. Localized forms arise in acne scars, ulcers, foreign body granulomas, subcutaneous fat necrosis of the newborn, neonatal heel sticks, cysts, lipomas and pilomatrixomas 4. Widespread calcification is seen in systemic sclerosis, CREST syndrome, dermatomyositis, pseudoxanthoma elasticum, systemic lupus erythematosus and Ehlers–Danlos syndrome 5. Iatrogenic causes: extravasation of intravenous calcium salts, electroencephalogram leads and electromyogram leads Idiopathic calcinosis cutis 1. No evidence of local tissue injury or systemic metabolic disorder 2. Localized a. Idiopathic calcinosis circumscripta b. Solitary congenital calcified nodule of the ear c. Idiopathic calcinosis of the scrotum or vulva

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3. Generalized a. Milia-like idiopathic calcinosis cutis, seen in Down syndrome Metastatic calcinosis cutis 1. Occurs with abnormal metabolism of calcium and/or phosphorous: chronic renal failure, vitamin D intoxication, sarcoidosis, parathyroid neoplasms, tumors 2. Calcinosis is rarely seen in the skin, but more commonly in kidney, lung, gastric mucosa, eyes and arteries

Pathogenesis

• Precipitation or deposition of hydroxyapatite • •

crystals of calcium phosphate within cutaneous tissues Etiology not understood, but unidentified local factors may promote calcification within tissues Calcium deposits tend to occur in areas of damaged tissue or elastic fibers

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Evans MJ, Blessing K, Gray ES. Subepidermal calcified nodule in children: a clinicopathologic study of 21 cases. Pediatr Dermatol 1995; 12: 307–10 Kotsuji T, Imakado S, Iwasaki N, et al. Milia-like idiopathic calcinosis cutis in a patient with translocation Down syndrome. J Am Acad Dermatol 2001; 45: 152–3 Lai CH, Farah R, Mallory SB. Congenital calcinosis cutis of the ear. J Am Acad Dermatol 2003; 49: 122–4 Ostrov BE, Goldsmith DP, Eichenfield AH, Athreya BH. Hypercalcemia during the resolution of calcinosis universalis in juvenile dermatomyositis. J Rheumatol 1991; 18: 1730–4 Rodriguez-Cano L, Garcia-Patos V, Creus M, et al. Childhood calcinosis cutis. Pediatr Dermatol 1996; 13: 114–17 Touart DM, Sau P. Cutaneous deposition diseases. Part II. J Am Acad Dermatol 1998; 39: 527–44 Walsh JS, Fairley JA. Calcifying disorders of the skin. J Am Acad Dermatol 1995; 33: 693–706

Osteoma cutis

Diagnosis

Major points

• Radiographs reveal radio-opaque densities in areas

• Present as multiple or solitary, hard, raised 1–5-cm

• •

of calcification Laboratory abnormalities are found only in metastatic form Histology: calcium deposits in the dermis or subcutaneous tissues with or without a foreign body reaction

Differential diagnosis

• Osteoma cutis • Myositis ossificans • Pilomatrixoma Treatment

• Excision of isolated lesions may be indicated • Correcting a metabolic disorder usually does not resolve the calcinosis, but may stop progression Prognosis

• Lesions rarely resolve spontaneously • Superficial lesions may self-extrude through the skin References Ahn SK, Kim KT, Lee SH, et al. The efficacy of treatment with triamcinolone acetonide in calcinosis cutis following extravasation of calcium gluconate: a preliminary study. Pediatr Dermatol 1997; 14: 103–9

• • • •

nodules with surrounding normal or erythematous skin Lesions commonly seen on the face Usually asymptomatic; may be painful or tender Superficial lesions may become inflamed and extrude bony particles Primary ossification: 1. Albright hereditary osteodystrophy (AHO) a. Includes: pseudohypoparathyroidism and pseudopseudohypoparathyroidism b. Heterogeneous disorder with multiple areas of subcutaneous ossification which are present at birth or may occur later c. Lesions may occur anywhere and range in size from pinpoint to 5 cm d. Other associated abnormalities: short stature, round facies, multiple skeletal abnormalities (curvature of the radius and shortened metacarpals and metatarsals), short broad nails, basal ganglia calcification, hypothyroidism, mental retardatiion, defective teeth and cataracts e. Dimpling sign seen over knuckles caused by the shortened metacarpals f. Inherited disorder: autosomal dominant or X-linked dominant

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g. Pseudohypoparathyroidism is characterized by a low serum calcium, hyperphosphatemia, and no response to parathyroid hormone (PTH), no renal diseases or other cause h. Pseudopseudohypoparathyoidism has normal calcium and phosphorus levels and no response to PTH i. Progression to pseudohypoparathyroidism with hypocalcemia and seizures may occur, and patients need to be monitored closely 2. Other forms of primary osteoma cutis: a. Widespread osteomas present since birth or early life without AHO b. Single, large, plaque-like osteomas present since birth on the scalp or extremities c. Single, small osteomas arising in later life with or without epidermal elimination d. Multiple miliary osteomas of the face: multiple 0.1–0.4-cm bluish white papules on the face. Most common in women with longstanding acne who have taken tetracycline or minocycline Secondary ossification (also called metaplastic osteoma cutis) 1. Associated with neoplasms, cysts, inflammatory processes (e.g. dermatomyositis, scleroderma), scarring, metabolic conditions, trauma and pre-existing cutaneous mineralization

Pathogenesis

• AHO: gene locus: 20q13.2

1. Gene: GNAS1; partial deficiency of the protein which couples hormone receptors to stimulate adenylate cyclase, which causes multiple hormone resistance Secondary forms: hypothesized to follow inflammatory process or other insult

Diagnosis

• Histology: proliferation of bony tissue with spicules of bone within the dermis and subcutaneous tissue, calcification, lamellae, lacunae, osteoblasts, osteocytes and rarely bone marrow formation Differential diagnosis

• Calcinosis cutis • Subungual exostosis of the finger or toe (Figure 17.28)

Figure 17.28 Exostosis – bony nodule on the tip of the toe requiring surgical excision

• Calcifying epithelioma • Pilomatrixoma Treatment

• Surgical excision of larger or painful lesions • Isotretinoin may aggravate osteoma formation • Close follow-up of patients with AHO is important, with routine checking of calcium, phosphorous and thyroid hormone Prognosis

• Persists indefinitely, but occasionally extrudes spontaneously References Altman JF, Nehal KS, Busam KJ, Halpern AC. Treatment of primary miliary osteoma cutis with incision, curettage, and primary closure. J Am Acad Dermatol 2001; 44: 96–9 Bergonse FN, Nico MM, Kavamura MI, Sotto MN. Miliary osteoma of the face: a report of 4 cases and review of the literature. Cutis 2002; 69: 383–6 Chan I, Hamada T, Hardman C, et al. Progressive osseous heteroplasia resulting from a new mutation in the GNAS1 gene. Clin Exp Dermatol 2004; 29: 77–80 Izraeli S, Metzker A, Horev G, et al. Albright hereditary osteodystrophy with hypothyroidism, normocalcemia, and normal Gs protein activity: a family presenting with congenital osteoma cutis. Am J Med Genet 1992; 43: 764–7 Miller ES, Esterly NB, Fairley JA. Progressive osseous heteroplasia. Arch Dermatol 1996; 132: 787–91 Moritz DL, Elewski B. Pigmented postacne osteoma cutis in a patient treated with minocycline: report and review of the literature. J Am Acad Dermatol 1991; 24: 851–3

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Prendiville JS, Lucky W, Mallory SB, et al. Osteoma cutis as a presenting sign of pseudohypoparathyroidism. Pediatr Dermatol 1992; 9: 11–18

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Diagnosis

• Histology: flattened sebaceous gland lobules and folded cyst walls within the cyst Differential diagnosis

GROWTHS

See Table 17.2

Steatocystoma multiplex

Treatment

Major points

• Because lesions are usually numerous, surgical

• Uncommon cause of cysts in childhood • Appears as asymptomatic, multiple, firm,

• Inflamed lesions can be excised or treated with

skin-colored or yellowish papules several millimeters to 1–3 cm in size (Figure 17.29)

excision is difficult incision and drainage Prognosis

• Lesions persist indefinitely References Ahn SK, Swang SM, Lee SH, Lee WS. Steatocystoma multiplex localized only in the face. Int J Dermatol 1997; 36: 372 Cho S, Chang SE, Choi JH, et al. Clinical and histologic features of 64 cases of steatocystoma multiplex. J Dermatology 2002; 29: 152–6 Kaur T, Kanwar AJ. Steatocystoma multiplex in four successive generations. J Dermatol 2003; 30: 559–61 Kaya TI, Ikizoglu G, Kokturk A, Tursen U. A simple surgical technique for the treatment of steatocystoma multiplex. Int J Dermatol 2001; 40: 785–8 Ohtake N, Kubota Y, Takayama O, et al. Relationship between steatocystoma multiplex and eruptive vellus hair cysts. J Am Acad Dermatol 1992; 26: 876–8 Sato K, Shibuya K, Taguchi H, et al. Aspiration therapy in steatocystoma multiplex. Arch Dermatol 1993; 129: 35–7 Figure 17.29 Steatocystoma multiplex – numerous yellowish papules on the neck

Syringomas

• When punctured, a characteristic oily or creamy • • • • •

fluid is discharged Common areas are axillae, chest and arms, but may appear anywhere Usually begins in adolescence or early adulthood Male/female ratio = 1 Autosomal dominant or sporadic Can be associated with pachyonychia congenita type 2

Pathogenesis

• Etiology unknown

Major points

• Appear at puberty as 1–2-mm skin-colored to • • •

yellowish papules (Figure 17.30) Location: most common around eyes, lids, upper cheeks, axillae and abdomen Female/male ratio >1 May be autosomal dominant

Pathogenesis

• Thought to be a benign hyperplasia of the cells of the eccrine sweat ducts

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Pruzan DL, Esterly NB, Prose NS. Eruptive syringoma. Arch Dermatol 1989; 125: 1119–20

Trichoepithelioma Major points

• Presents in late childhood and adolescence • Appears as solitary or numerous 2–8-mm • • •

Figure 17.30 Syringomas – multiple, familial skin-colored papules around the eyes, a typical location

skin-colored papules on the face, usually around the nose and mid-face (Figure 17.31) Fine telangiectasias on the surface May be seen on other parts of the body, especially the scalp, neck and upper trunk Multiple lesions are seen in Spiegler-Brooke syndrome (OMIM no. 605041), an autosomal dominant disorder; gene map locus 16q12-q13; gene CYLD Solitary lesions are not inherited

Pathogenesis

• Benign tumor with follicular germinative Diagnosis

• Histology: numerous small eccrine ducts in the dermis with surrounding fibrosis; some ducts bulge out to form small comma-like excrescences (tadpole appearance)

differentiation Diagnosis

• Histology: multiple horn cysts and basophilic tumor islands in mid-dermis; can be difficult to distinguish from basal cell carcinoma

Differential diagnosis See Table 17.2 Treatment

• Difficult to treat • Electrocautery somewhat helpful Prognosis

• Lesions persist and may become numerous References Goyal S, Martins CR. Multiple syringomas on the abdomen, thighs, and groin. Cutis 2000; 66: 259–62 Guitart J, Rosenbaum MM, Requena L. ‘Eruptive syringoma’: a misnomer for a reactive eccrine gland ductal proliferation? J Cutan Pathol 2003; 30: 202–5 Karma P, Benedetto AV. Intralesional electrodesiccation of syringomas. Dermatol Surg 1997; 23: 921–4 Nguyen DB, Patterson JW, Wilson BB. Syringoma of the moustache area. J Am Acad Dermatol 2003; 49: 337–9

Figure 17.31 Trichoepithelioma – multiple, skin-colored, asymptomatic, slow-growing papules on the face

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Differential diagnosis

• • • • •

Basal cell carcinoma Pilomatricoma Nevocellular nevus Syringoma Acne vulgaris

• If left untreated, basal cell carcinoma is slow growing and may ulcerate

• Rare in childhood and should suggest a syndrome: basal cell nevus syndrome (see Chapter 20), xeroderma pigmentosum (see Chapter 12), or Bazex syndrome

Treatment

Pathogenesis

• Surgical excision; recurrence common unless

• Malignant growth arising from basal cells in

completely removed Prognosis

• Gradually increase in number and size, then •

stabilize Lesions do not resolve spontaneously

References Centurion SA, Schwartz RA, Lambert WC. Trichoepithelioma papulosum multiplex. J Dermatol 2000; 27: 137–43 Johnson SC, Bennett RG. Occurrence of basal cell carcinoma among multiple trichoepitheliomas. J Am Acad Dermatol 1993; 28: 322–6 Matt D, Xin H, Vortmeyer AO, et al. Sporadic trichoepithelioma demonstrates deletions at 9q22.3. Arch Dermatol 2000; 136: 657–60 Puig L, Nadal C, Fernandez-Figueras MT, et al. BrookeSpiegler syndrome variant: segregation of tumor types with mixed differentiation in two generations. Am J Dermatopathol 1998; 20: 56–60 Requena L, Farina MC, Robledo M, et al. Multiple hereditary infundibulocystic basal cell carcinomas: a genodermatosis different from nevoid basal cell carcinoma syndrome. Arch Dermatol 1999; 135: 1227–35 Shaffelburg M, Miller R. Treatment of multiple trichoepithelioma with electrosurgery. Dermatol Surg 1998; 24: 1154–6

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patient with chronic sun exposure and genetic susceptibility For basal cell nevus syndrome: gene locus/gene: 9q22/PTCH1 gene

Diagnosis

• Biopsy necessary • Histology: solid masses of basal cells with a large nucleus and little cytoplasm Differential diagnosis

• • • • • •

Pilomatricoma Nevocellular nevus Trichoepithelioma Syringoma Acne vulgaris Tuberous sclerosis (angiofibromas)

Treatment

• Excision • Radiation should be avoided in childhood • Prophylactic avoidance of sun, use of sunscreens Prognosis

• Chronic slow progression of individual lesions • Rarely metastasize, but may be disfiguring if orbit or nasal area invaded References

TUMORS/MALIGNANCIES

Comstock J, Hansen RC, Korc A. Basal cell carcinoma in a 12-year-old boy. Pediatrics 1990; 86: 460–2

Basal cell carcinoma

Drake LA, Ceilley RI, Comelison RL, et al. (Committee on Guidelines of Care) Guidelines of care for basal cell carcinoma. J Am Acad Dermaol 1992; 26: 117–20

Major points

• Appear on the face or upper body as a •

skin-colored papule with telangiectasias on the surface Seen in light-skinned individuals (skin types 1–3) with increased sun exposure

Gaspari AA, Sauder DN. Immunotherapy of basal cell carcinoma: evolving approaches. Dermatol Surg 2003; 29: 1027–34 Ledwig PA, Paller AS. Congenital basal cell carcinoma. Arch Dermatol 1991; 127: 1066–7

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Orozco-Covarrubias M, Tamayo-Sanchez L, DuranMcKinster C, et al. Malignant cutaneous tumors in children: twenty years of experience at a large pediatric hospital. J Am Acad Dermatol 1994; 30: 243–9 Strayer SM, Reynolds PL. Diagnosing skin malignancy: assessment of predictive clinical criteria and risk factors. J Fam Pract 2003; 52: 210–18 Tsao H. Update on familial cancer syndromes and the skin. J Am Acad Dermatol 2000; 42: 939–69

Wong CS, Strange RC, Lear JT. Basal cell carcinoma. Br Med J 2003; 327: 794–8

Leukemia cutis Major points

• Primary (specific) lesions are caused by direct •

invasion of leukemic cells; appear as multiple, brownred or violaceous papules and nodules (Figure 17.32) Acute lymphocytic leukemia (ALL) is the most common form of childhood leukemia 1. Peak incidence is 4 years of age 2. Petechiae are seen in 50% of cases at the time of presentation Acute nonlymphocytic leukemia has myelocytic or monocytic differentiation 1. Leukemia cutis is more common in acute monoblastic leukemia and congenital leukemias (50%) 2. Congenital leukemia often presents with ‘blueberry muffin lesions’ which show on histology dermal erythropoiesis

3. Other presentations: a. Gingival hypertrophy b. Soft tissue mass, most common in the deep soft tissues of the head and neck 4. More common in children with Fanconi anemia, Down syndrome, Bloom syndrome, ataxia telangiectasia, Wiscott–Aldrich syndrome and neurofibromatosis Chronic lymphocytic leukemia is rare in childhood Chronic nonlymphocytic leukemia 1. Accounts for 1 4. Skin manifestations rare (e.g. papules, tumors, ulcerated nodules), but seen in advanced disease which has failed aggressive chemotherapy and radiation

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5. Secondary signs: pruritus, acquired ichthyosis and herpes zoster B-cell lymphomas: 1. Painless enlarging lymphadenoathy most common 2. Rapidly growing and poorly differentiated 3. Cutaneous lesions: papules or nodules which may ulcerate and form arcuate lesions 4. Common location: scalp

Pathogenesis

• Anaplasia of B or T cells Diagnosis

• Biopsy of tissue confirms and differentiates the diagnosis Differential diagnosis

• • • • •

Pseudolymphoma Persistent insect bite reaction Granuloma annulare Lymphomatoid papulosis Follicular mucinosis

Treatment

• Depends upon type of lymphoma • CTCL is treated with psoralen plus ultraviolet light A (PUVA) or topical nitrogen mustard or, for a single plaque, ultrapotent steroids Prognosis

• Depends upon the type of lymphoma • CTCL has a good prognosis, but requires life-long observation and therapy References Burg G, Kempf W, Haeffner AC, et al. Cutaneous lymphomas. Curr Prob Dermatol 1997; 9: 137–204 Jones D, Duvic M. The current state and future of clonality studies in mycosis fungoides. J Invest Dermatol 2003; 121: ix–x Maher-Wiese VL, Wenner NP, Grant-Kels JM. Metastatic cutaneous lesions in children and adolescents with a case report of metastatic neuroblastoma. J Am Acad Dermatol 1992; 26: 620–8 Orozco-Covarrubias ML, Tamayo-Sanchez L, DuranMcKinster C, et al. Malignant cutaneous tumors in children. J Am Acad Dermatol 1994; 30: 243–9

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Querfeld C, Rosen ST, Kuzel TM, Guitart J. Cutaneous Tcell lymphomas: a review with emphasis on new treatment approaches. Semin Cutan Med Surg 2003; 22: 150–61 Sandlund JT, Downing JR, Crist WM. Non-Hodgkin’s lymphoma in childhood. N Engl J Med 1996; 334: 1238–48 Shani-Adir A, Lucky AW, Prendiville J, et al. Subcutaneous panniculitic T-cell lymphoma in children: response to combination therapy with cyclosporine and chemotherapy. J Am Acad Dermatol 2004; 50 (2 Suppl): S18–22 Thorley-Lawson DA, Gross A. Persistence of the Epstein–Barr virus and the origins of associated lymphomas. N Engl J Med 2004; 350: 1328–37 Zackheim HS, Vonderheid EC, Ramsay DL, et al. Relative frequency of various forms of primary cutaneous lymphomas. J Am Acad Dermatol 2000; 43: 793–6

Figure 17.33 Langerhans cell histiocytosis – keratotic hemorrhagic papules resembling seborrheic dermatitis

e. f. g. h. i.

Histiocytosis Major points

• Histiocytoses includes a group of benign and fatal •

disorders which may be manifested in a variety of ways Langerhans cell histiocytosis (LCH) was traditionally separated into the following groups, but these are now included under the heading of LCH: 1. Eosinophilic granuloma (localized bony lesions) 2. Hand–Schuller–Christian disease (multiple organ involvement with skull defects, diabetes insipidus and exophthalmos) 3. Letterer–Siwe disease (visceral lesions in lungs, lymph nodes, liver, spleen, bone marrow and skin) Letterer–Siwe disease is most common 1. Peak incidence occurs between 1 and 4 years, but can occur at any age 2. Discrete yellow-brown scaly papules which coalesce in the seborrheic areas (e.g. diaper area, postauricular area, scalp, etc.) and may show petechiae (Figure 17.33) 3. Other involvement a. Bone lesions: lytic lesions (typical in skull), proptosis, mastoid involvement and others b. Lymph nodes c. Bone marrow (pancytopenia) d. Liver enlargement

Spleen enlargement Lungs GI tract Thymic enlargement Endocrine glands (diabetes insipidus, anterior pituitary involvement with growth hormone deficiency) j. CNS involvement rare (intracranial hypertension, seizures) Other forms of histiocytosis: 1. Self-healing reticulohistiocytosis presents with papules and nodules that frequently ulcerate at birth (Figure 17.34) 2. Benign cephalic histiocytosis: 2–5-mm yellowred papules on the face and neck in a child 6 hairs extracted considered abnormal Hair pluck: forcefully extracting ~50 hairs from the scalp by clamping hairs about 1 cm from skin surface with a rubber coated hemostat and pulling Microscopic examination: anagen versus telogen hairs KOH preparation Fungal, bacterial cultures Scalp biopsy Laboratory evaluation: complete blood count, thyroxine, thyroid stimulating hormone, rapid plasma reagin, serum iron, dehydroepiandrosterone sulfate, free testosterone

Figure 18.1 Occipital alopecia – this common patchy hair loss occurs in infants in the first year of life

Pathogenesis

• Lanugo hairs on posterior scalp shed at ~8–12 weeks of age, then replaced with normal anagen hairs Diagnosis

• Clinical diagnosis Differential diagnosis

• Alopecia areata • Hair shaft disorders Treatment

• None needed Prognosis

• Excellent References Olsen EA. Hair loss in childhood. In Disorders of Hair Growth. Olsen EA, ed. McGraw-Hill: New York, 1994: 139–88

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Patchy alopecia Major points

• Aplasia cutis congenita: irregularly shaped erosion • • • • •

• • •

which leads to scarring or oval patch covered by membrane (see Chapter 2) Melanocytic nevus: associated with hyper- or hypotrichosis Hemangioma of infancy: after resolution, may have localized alopecia Nevus sebaceus: linear or oval patch of alopecia with yellowish papules (see Chapter 17) Epidermal or organoid nevi: linear, grouped, verrucous papules Temporal triangular alopecia (Figure 18.2) 1. Well-circumscribed triangular or lance-shaped area of alopecia at the temple 2. Appears at 2–5 years of age; unilateral (80%) or bilateral 3. Vellus hairs present; occasionally a few terminal hairs 4. Erroneously thought to be from forceps delivery Cranial meningoceles, encephaloceles, heterotopic brain tissue: can be surrounded by collar of thick hair (called ‘hair collar sign’) Birth trauma (forceps) from pressure on hair follicles Rare syndromes with patchy hair loss 1. Conradi–Hünermann syndrome 2. Goltz syndrome

Figure 18.3 This type of hair loss resembles triangular alopecia but is caused by styling practices where the hair is pulled tightly into braids

3. Hallerman–streiff syndrome 4. CHILD syndrome Causes of scarring alopecia (Table 18.4)

References Armstrong DKB, Burrows D. Congenital triangular alopecia. Pediatr Dermatol 1996; 13: 394–6 Elmer KB, George RM. Congenital triangular alopecia: a case report and review. Cutis 2002; 69: 255–6 Garcia-Hernandez MJ, Rodriguez-Pichardo A, Camacho F. Congenital triangular alopecia (Brauer nevus). Pediatr Dermatol 1995; 12: 301–3 Trakimas C, Sperling LC, Skelton HG, et al. Clinical and histologic findings in temporal triangular alopecia. J Am Acad Dermatol 1994; 31: 205–9

CONGENITAL ALOPECIA: DIFFUSE Early-onset diffuse alopecia Major points

• Causes: Figure 18.2 Triangular alopecia – congenital and familial patch of alopecia usually over one or both temples

1. Metabolic disorders/nutritional deficiencies a. Acrodermatitis enteropathica (zinc deficiency)

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2. 3. 4. 5.

b. Biotin deficiency c. Essential fatty acid deficiency d. Amino acid disorders Congenital alopecia universalis Loose anagen syndrome Hair shaft defects Genetic syndromes a. KID syndrome b. Trichorhinophalangeal syndrome

References Ahmad W, Panteleyev AA, Christiano AM. The molecular basis of congenital atrichia in humans and mice: mutations in the hairless gene. Invest Dermatol Symp Proc 1999; 4: 240–3 Cambiaghi S, Barbareschi M. A sporadic case of congenital hypotrichosis simplex of the scalp: difficulties in diagnosis and classification. Pediatr Dermatol 1999; 16: 301–4 Carrington PR, Chen H, Altick JA. Trichorhinophalangeal syndrome, type I. J Am Acad Dermatol 1994; 31: 331–6 Ludecke H-J, Wagner MJ, Nardmann J, et al. Molecular dissection of a contiguous gene syndrome: localization of the genes involved in the Langer–Giedion syndrome. Hum Mol Genet 1995; 4: 31–6 Nardmann J, Tranebjaerg L, Horsthembke B, Ludecke H-J. The tricho-rhino-phalangeal syndromes: frequency and parental origin of 8q deletions. Hum Genet 1997; 99: 638–43 Roberts JL, Whiting DA, Henry D, et al. Marie Unna congenital hypotrichosis: clinical description, histopathology, scanning electron microscopy of a previously unreported large pedigree. Invest Dermatol Symp Proc 1999; 4: 261–7 Zlotogorski A, Hochberg Z, Mirmirani P, et al. Clinical and pathologic correlations in genetically distinct forms of atrichia. Arch Dermatol 2003; 139: 1591–6

Ectodermal dysplasia (hypohidrotic/anhidrotic) Synonym: anhidrotic ectodermal dysplasia, Christ–Siemens–Touraine syndrome Major points

• Presents at birth • Hair-fine, sparse, light and twisted terminal hairs •

and eyebrows; may thicken at puberty (Figure 18.4) Sweat glands – partial or complete absence with heat intolerance; sweat pores absent on visual inspection of fingertips

Figure 18.4 Hypohidrotic ectodermal dysplasia – newborn with absence of hair

• Teeth – hypodontia, anodontia, and conical incisors

• Nails – normal or brittle, thin, ridged • Characteristc facies

1. Thick, everted lips 2. Frontal bossing 3. Large, pointed ears 4. Saddle nose 5. Maxillary hypoplasia Other findings 1. Frequent bronchitis and pneumonia 2. Recurrent otitis media, impacted cerumen 3. Hoarse voice 4. Failure to thrive (20%) 5. Unexplained fever in infancy and childhood 6. Poorly developed mucous glands in respiratory and gastrointestinal tract 7. Periorbital hyperpigmentation 8. Skin – soft, dry, finely wrinkled 9. X-linked recessive 10. Increased frequency of atopic dermatitis

Pathogenesis

• Gene locus: Xq12-q13.1 • Gene: ectodysplasin-A (ED1) Diagnosis

• Clinical presentation Differential diagnosis

• Other (Figure 18.5)

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Wisniewski SA, Kobielak A, Trzeciak WH, Kobielak K. Recent advances in understanding of the molecular basis of anhidrotic ectodermal dysplasia: discovery of a ligand, ectodysplasin A and its two receptors. J Appl Genet 2002; 43: 97–107

Ectodermal dysplasia (hidrotic) Synonym: Clouston syndrome Major points

• Generalized hypotrichosis (sparse, fine, blond, wiry, brittle hair); hair loss may be progressive

• Nail dystrophy: nails may be white in early Figure 18.5 Isolated scalp hypotrichosis – with no other ectodermal defects

• Treatment

• Environmental control for temperature stability: • • • •

air conditioning or specialized cooling units Dental consultation for abnormal teeth, with dentures and dental implants Hair appliances (wigs) if necessary Treatment of infections as needed National Foundation for Ectodermal Dysplasias (www.nfed.org)

Prognosis

• Good with close supervision • Increased mortality in infancy References

• • • • • • •

childhood; thickened nails; slow growth; paronychial infections (Figure 18.6) Hyperkeratosis of the palms and soles with pebbling on the fingertips, which increases with age Teeth – normal Mild mental retardation or normal mentation Sweating normal Conjunctivitis Blepharitis possible secondary to absence of protection from eyelashes More common in French Canadian families Autosomal dominant

Pathogenesis

• Gene locus: 13q12 • Gene: GJB6 (gap junction protein) which encodes CX30 (connexin-30)

Aswegan AL, Josephson KD, Mowbray R, et al. Autosomal dominant hypohidrotic ectodermal dysplasia in a large family. Am J Med Genet 1997; 72: 462–7 Azon-Masoliver A, Ferrando J. Loose anagen hair in hypohidrotic ectodermal dysplasia. Pediatr Dermatol 1996; 13: 29–32 Cambiaghi S, Restano L, Paakkonen K, et al. Clinical findings in mosaic carriers of hypohidrotic ectodermal dysplasia. Arch Dermatol 2000; 136: 217–24 Dahan D, Fenichel GM, El-Said R. Neurocutaneous syndromes. Adolesc Med State Art Rev 2002; 13: 495–509 Hummel P, Guddack S. Psychosocial stress and adaptive functioning in children and adolescents suffering from hypohidrotic ectodermal dysplasia. Pediatr Dermatol 1997; 14: 180–5 Lamartine J. Towards a new classification of ectodermal dysplasias. Clin Exp Dermatol 2003; 28: 351–5

Figure 18.6 Hidrotic ectodermal dysplasia – small nails with pebbling of fingertips in a patient with hypotrichosis

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Diagnosis • Clinical presentation • Histology: orthohyperkeratosis of palms and soles with normal granular layer • Abnormal hair with nonspecific narrowing and fraying Differential diagnosis

• Other ectodermal dysplasias • Ankyloblepharon ectodermal dysplasia clefting •

(AEC) syndrome Pachyonychia congenita

Treatment • Hair appliance (wig) if necessary

Figure 18.7 Alopecia areata – sudden loss of hair with exclamation point hairs appearing as broken-off hairs along the periphery

Prognosis

• Hair and nail abnormalities permanent References Chitty LS, Dennis N, Baraitser M. Hidrotic ectodermal dysplasia of hair, teeth, and nails: case reports and review. J Med Genet 1996; 33: 707–10 Hayflick SJ, Taylor T, McKinnon W, et al. Clouston syndrome (hidrotic ectodermal dysplasia) is not linked to keratin gene clusters on chromosomes 12 and 17. J Invest Dermatol 1996; 107: 11–14 Lamartine J, Essenfelder GM, Kibar Z, et al. Mutations in GJB6 cause hidrotic ectodermal dysplasia. Nature Genet 2000; 26: 142–4 Priolo M, Silengo M, Lerone M, Ravazzolo R. Ectodermal dysplasias: not only ‘skin’ deep. Clin Genet 2000; 58: 415–30

Figure 18.8 Alopecia areata – patchy, smooth hair loss of sudden onset

ACQUIRED NON-SCARRING ALOPECIA Alopecia areata Major points

• • • • • • •

Common disorder Incidence: 17 per 100 000 population per year 24–50% begins at age 30% of older women Common complaint: thinning Inheritance probably polygenic

Pathogenesis

• Gradual transformation of thick scalp hair follicles • •

to smaller follicles over many cycles, resulting in progressively shorter, finer, miniaturized hairs Regulated by dihydrotestosterone, which is formed by conversion of testosterone by 5α-reductase Histology shows miniaturized follicle with streamer of collapsed connective tissue sheath; increase ratio of telogen to anagen hairs and increase of vellus hairs; mild perifollicular lymphohistiocytic inflammation (nonspecific)

Diagnosis

• • •

Clinical diagnosis Family history Hair pull test negative

Differential diagnosis

• Virilizing tumors of adrenal or ovary • Telogen effluvium

References Ellis JA, Sinclair R, Harrap SB. Androgenetic alopecia: pathogenesis and potential for therapy. Expert Rev Mol Med 2002; 4: 1–11 Kaufman KD. Androgens and alopecia. Mol Cell Endocrinol 2002; 198: 89–95 Price VH. Androgenetic alopecia in adolescents. Cutis 2003; 71: 115–21 Price VH. Androgenetic alopecia in women. J Invest Dermatol Symp Proc 2003; 8: 24–7 Price VH. Treatment of hair loss. N Engl J Med 1999; 341: 964–73

Trichotillomania Major points

• Location often frontal or frontoparietal scalp; can • • • •

occur in scalp, eyebrows, eyelashes, pubic hair Irregularly shaped, angular patches with stubbly, broken-off hairs; area is never completely bald (Figures 18.11 and 18.12) Begins insidiously as irregular linear or rectangular area of partial hair loss Nonscarring Occurs in 8 million Americans

Treatment

• Evaluation in teenage girls: free testosterone,

• • •

dehydroepiandrosterone sulfate, luteinizing hormone, follicle stimulating hormone, prolactin Aim of treatment is to retard further thinning Topical minoxidil 2 or 5% BID, used for at least 1 year to assess efficacy; must maintain treatment to avoid shedding new growth Males: finasteride 1 mg PO daily; response seen as early as 3 months; needs continued treatment (contraindicated in women who may potentially become pregnant) Girls: 1. Oral spironolactone (aldosterone antagonist), 50–200 mg/day 2. Estrogen

Prognosis

• Slowly progressive

Figure 18.11 Trichotillomania – angular patches of broken-off hairs with areas of normal hair

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Pathogenesis

• Caused by plucking, pulling, breaking, or twisting •

one’s own hair either consciously or subconsciously Histology: 1. Marked increase in catagen and telogen hairs 2. Presence of pigment casts 3. Trichomalacia with abnormally small, distorted, bizarre-shaped hairs 4. Dilated ostia with empty follicles 5. Absence of bulbar inflammation

Diagnosis

• Clinical diagnosis • Confirmed by finding wads of hair or observation •

of habit Histology helpful

Differential diagnosis Figure 18.12 Trichotillomania – hair breakage in an unusual pattern on the posterior scalp

• Alopecia areata • Trichorrhexis nodosa Treatment

• Occurs in all ages >2 years; two-thirds are children, adolescents and young adults

• Two types:

• • •

1. Temporary localized childhood pattern: a. Ages 2–6 years b. Harmless habit, tends to occur before child falls asleep or when reading, writing, or watching television c. No necessary treatment d. Good prognosis 2. Teenage/adult pattern: a. Obsessive compulsive disorder b. Irresistible urge to pluck hair, either unconscious or semi-conscious c. More severe form d. Prognosis worse e. Most deny doing it f. Female/male ratio >1 g. Often refractory to treatment h. Occurs frequently during psychosocial stress Other clinical features: focal perifollicular erythema, hemorrhage, excoriations Examination of hairs: blunt hair tips Concomitant occurrence with alopecia areata has been described

• • • • •

Supportive Psychological evaluation and treatment Behavior modification Oral anti-obsessive compulsive agents: selective serotonin uptake inhibitors: paroxetine (Paxil®), sertraline (Zoloft®), fluoxetine (Prozac®) Topical mild steroid to reduce any inflammation or sense of itching

Prognosis

• Good in childhood type, poor in teenage type if no treatment is given or if problem has been prolonged References Hautmann G, Hercogova J, Lotti T. Trichotillomania. J Am Acad Dermatol 2002; 46: 807–21 Khouzam HR, Battista MA, Byers PE. An overview of trichotillomania and its response to treatment with quetiapine. Psychiatry 2002; 65: 261–70 Oranje AP, Peereboom-Wynia JDR, De Raeymaecher DMJ. Trichotillomania in childhood. J Am Acad Dermatol 1986; 15: 614–19 Papadopoulos AJ, Janniger CK, Chodynicki MP, Schwartx RA. Trichotillomania. Int J Dermatol 2003; 42: 330–4 Trueb RM, Cavegn B. Trichotillomania in connection with alopecia areata. Cutis 1996; 58: 67–70

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Traction alopecia

Prognosis

Major points

• Early disease (few months) – hair will recover • Late disease (years) can cause permanent loss of

• Common in females with tightly pulled hairstyles, • • • •

especially Black girls Outermost hairs are subject to most tension, so margin of scalp usually affected (Figure 18.3 and 18.13) Commonly involves temporal region and frontal scalp Scalp surface appears normal, with no scarring Insidious onset

hair follicles References Wilborn WS. Disorders of hair growth in African Americans. In Disorders of Hair Growth. Olsen EA, ed. McGraw-Hill: New York, 1994: 389–407

Traumatic alopecia

Pathogenesis

Major points

• Chronic traction of ponytails or braids, with

• Sudden onset caused by forceful extraction of hairs

tension on hair shafts or friction from headgear, rubber bands with hair breakage Diagnosis

• Clinical diagnosis Differential diagnosis

• • •

or prolonged pressure on scalp during surgery, resulting in focal tissue ischemia Clinical features: pain, inflammation, edema, followed by ulceration Forcible removal: consider child abuse Hair loss usually not permanent

• Alopecia areata • Trichotillomania

Syndromes with late-onset hypotrichosis

Treatment

• • • • • •

• Gentle hair care (Table 18.3) • Change hairstyle which includes loose braids, parting hair at different site

• Discontinue rubber bands and manipulation of hair

Ectodermal dysplasias Dyskeratosis congenita Werner syndrome Progeria (Hutchinson–Gilford syndrome) Cockayne syndrome Rothmund–Thomson syndrome

Table 18.3

Handout for hair care

1. Be gentle 2. Take time with brushing and combing. Brush and comb as little and as gently as possible 3. Use a soft bristle brush or wide-toothed plastic brush 4. Comb: use a wide-toothed, round-tipped comb, bone or plastic; never metal 5. Cream rinse or condition the hair after shampooing, especially if the hair is long. Choose one with protein added

Figure 18.13 Traction alopecia – caused by over-processing extremely curly hair

6. If your lifestyle does not include time for gentle combing and brushing, then keeping the hair short might be an option

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HAIR SHAFT ABNORMALITIES Trichorrhexis nodosa Major points

• Fracture of hair shaft with splaying out and release • • • •

of individual cortical cells, suggesting the appearance of two brushes being pushed together Hairs very fragile and break with trauma Common in Black females, whose hairstyles include routine straightening Hairs along scalp edge are subject to most tension Can be seen with argininosuccinic aciduria (congenital trichorrhexis nodosa), citrullinemia and hypothyroidism

Pathogenesis

• Results from chronic trauma (mechanical or chemical) to hair shafts: traction, twisting, brushing, hot combing, drying, straightening and other chemical treatments Diagnosis

• Clinical features • Microscopy of hair shaft

• Variability of clinical picture • Hair fragile, short, dull; may affect eyebrows, eyelashes and body hair

• Other features 1. 2. 3. 4.

Ichthyosis linearis circumflexa Atopic dermatitis Erythroderma Secondary colonization with Staphylococcus aureus 5. Increased absorption of topical agents (e.g. tacrolimus) Pathogenesis

• Microscopy of hair shaft: ball and socket configuration or shallow invagination of distal into proximal shaft, resembling bamboo (Figure 18.14) Diagnosis

• Clinical features with characteristic microscopy of hair shaft

• Gene locus/gene: chromosome 5q32/ SPINK5 gene encoding the serine protease inhibitor LEKTI Differential diagnosis

• Other hair shaft abnormalities

• Atopic dermatitis • Erythroderma • Immune deficiencies

Treatment

Treatment

• Avoid manipulating hair as much as possible

• Gentle hair care • Wigs

Differential diagnosis

(Table 18.3) Prognosis

• Slow recovery if trauma avoided References Lurie R, Hodak E, Ginzburg A, David M. Trichorrhexis nodosa: a manifestation of hypothyroidism. Cutis 1996; 57: 358–9 Quinn CR, Quinn TM, Kelly AP. Hair care practices in African American women. Cutis 2003; 72: 280–9

Trichorrhexis invaginata Synonym: bamboo hair Major points

• Characteristic of Netherton syndrome

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Figure 18.14 Netherton syndrome – bamboo hair (courtesy of Dr Dongshi Li)

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• Intermittent topical corticosteroids for atopic dermatitis and scaling

• Emollients Prognosis

• As hair becomes thicker, it may become slightly less fragile References Allen A, Siegfried E, Silverman R, et al. Significant absorption of topical tacrolimus in 3 patients with Netherton syndrome. Arch Dermatol 2001; 137: 747–50 Chavanas S, Bodemer C, Rochat A, et al. Mutations in SPINK5, encoding a serine protease inhibitor, cause Netherton syndrome. Nature Genet 2000; 25: 141–2 Hausser I, Anton-Lamprecht I. Severe congenital generalized exfoliative erythroderma in newborns and infants: a possible sign of Netherton syndrome. Pediatr Dermatol 1996; 13: 183–99

Figure 18.15 Pili torti – twisted hairs involving the scalp and eyebrows

c. Hair twisted, coarse, sparse, hypopigmented or silvery; fragile, especially in areas of trauma d. Untreated disease usually lethal in early years e. Gene mutation in copper transporting P type ATPase protein (ATP7A) on chromosome X 13.3; blocks export of dietary copper from GI tract, leading to decreased bioavailability of copper with functional deficiencies of copper-dependent enzymes

Muller FB, Hausser I, Berg D, et al. Genetic analysis of a severe case of Netherton syndrome and application for prenatal testing. Br J Dermatol 2002; 146: 495–9 Siegel DH. Howard R. Molecular advances in genetic skin diseases. Curr Opin Pediatr 2002; 14: 419–25

Pili torti Major points

• Twisting of hair shaft on its own axis, usually • • • • •

through an angle of 180° Location: scalp, eyebrows, eyelashes Onset at birth or early months Hair: light in color, spangled, dry, brittle, breaks at different lengths and tends to stand out from scalp (Figure 18.15) Autosomal dominant, recessive or sporadic Syndromes that show pili torti: 1. Classic pili torti a. May be isolated finding b. Can be seen with teeth, nail, eye defects, keratosis pilaris 2. Björnstad syndrome a. Associated with sensorineural deafness b. Autosomal dominant 3. Menkes ‘kinky hair’ syndrome a. Progressive neurodegeneration b. Connective tissue abnormalities

Pathogenesis

• Histology of hair shaft: three or four regularly •

spaced twists, each 0.4–0.9 mm in width, occurring at irregular intervals along the shaft Twists almost always through 180° but can be less or more

Diagnosis

• Clinical features with microscopy of hair shaft Differential diagnosis

• Uncombable hair syndrome • Other hair shaft abnormalities Treatment

• Gentle hair care Prognosis

• Stable; may improve slightly with age

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References Richards KA, Mancini AJ. Three members of a family with pili torti and sensorineural hearing loss: the Bjornstad syndrome. J Am Acad Dermatol 2002; 46: 301–3 Selvaag E. Pili torti and sensorineural hearing loss. A follow-up of Bjornstad’s original patients and a review of the literature. Eur J Dermatol 2000; 10: 91–7 Whiting DA. Hair shaft defects. In Disorders of Hair Growth. Olsen EA, ed. McGraw-Hill: New York, 1994: 91–137

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• Hairs fracture at internodal spaces • Mutations in human basic hair keratins: hHb1 and hHb6

• Gene map locus 12q13 Diagnosis

• Clinical features with microscopy of hair shaft Differential diagnosis

• Pseudomonilethrix: artifact caused by hairs pressed between two glass slides

Monilethrix

• Other hair shaft anomalies

Synonym: beaded hair

Treatment

Major points

• Gentle hair care

• Beaded hairs on microscopy; nodes have diameter

Prognosis

• • • •

of normal hair, whereas internodes are narrow and are sites of fracture Hair usually normal at birth, but replaced by dry, dull, brittle hair which breaks spontaneously Scalp has stubbly appearance of hairs (Figure 18.16) Follicular keratosis often associated (scalp, face, limbs can have severe involvement) Autosomal dominant with high penetrance, but expressivity variable

Pathogenesis

• Characteristic elliptic nodes, 0.7–1 mm apart, with intervening tapered constrictions that are nonmedullated

• May improve slightly as hair becomes thicker with age References DeBerker DAR, Ferguson DJP, Dawber RPR. Monilethrix: a clinicopathological illustration of a cortical defect. Br J Dermatol 1993; 128: 327–31 Korge BP, Hamm H, Jury CS, et al. Identification of novel mutations in basic hair keratins hHb1 and hHb6 in monilethrix: implications for protein structure and clinical phenotype. J Invest Dermatol 1999; 113: 607–12 Landau M, Brenner S, Metzker A. Medical pearl: an easy way to diagnose severe neonatal monilethrix. J Am Acad Dermatol 2002; 46: 111–12 Smith F. The molecular genetics of keratin disorders. Am J Clin Dermatol 2003; 4: 347–64

Uncombable hair syndrome Synonyms: spun glass hair, pili trianguli et canaliculi

Figure 18.16 papules

Monilethrix – very short hairs with keratotic

Major points • Onset early in childhood • Hair light silvery-blond, pale, frizzy; stands away from the scalp, cannot be combed flat; often spangled in appearance (Figure 18.17) • Hair usually normal in length, quantity and strength • Eyebrows, lashes and body hair normal • Autosomal dominant, recessive or sporadic

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Itin PH, Buhler U, Buchner SA, Guggenheim R. Pili trianguli et canaliculi: a distinctive hair shaft defect leading to uncombable hair. Dermatology 1993; 187: 296–8

Loose anagen syndrome Major points

• Characterized by actively growing anagen hairs

Figure 18.17 Uncombable hair syndrome – spangled hair which is difficult to style

• • •

Pathogenesis • Microscopy of hairs: longitudinal grooving along the shaft or flattened surface with intact cuticle; areas discontinuous and change orientation many times along the shaft • Cross-sectional microscopy: triangular, or other unusual shapes with longitudinal grooving Diagnosis

• Clinical diagnosis with characteristic microscopy of hair shaft Differential diagnosis

• Pili torti • Loose anagen syndrome Treatment

• Gentle hair care • Conditioners helpful • Hair not particularly fragile Prognosis

• Good; tends to improve with age, but is always difficult to manage References Ang P, Tay YK. What syndrome is this? Uncombable hair syndrome (Pili trianguli et canaliculi). Pediatr Dermatol 1998; 15: 475–6 Hicks J, Metry DW, Barrish J, Levy M. Uncombable hair (cheveux incoiffables, pili trianguli et canaliculi) syndrome: brief review and role of scanning electron microscopy in diagnosis. Ultrastruct Pathol 2001; 25: 99–103

• •

which are loosely anchored and can be easily and painlessly pulled from the scalp Mainly blond healthy girls aged 1–9 years Parents complain that hair will not grow and seldom needs cutting Subtle diffuse or patchy thinning with uneven length of hairs Hair appears limp and matted Sporadic inheritance; occasionally autosomal dominant

Pathogenesis

• Normal tenacious bond between lower hair shaft and inner root sheath is weak, allowing trivial traction to cause disruption and extraction of hairs Diagnosis

• Hair pull test (diagnostic) – numerous hair shafts painlessly extracted from scalp

• Microscopy of proximal ends of hairs pulled: anagen hairs without outer root sheaths, with ruffling of hair shaft (‘crumpled sock’ appearance) Differential diagnosis

• Uncombable hair syndrome • Pili torti • Congenital hypotrichosis Treatment

• Gentle hair care • Reassurance Prognosis

• Can improve with time References Boyer JD, Cobb MW, Sperling LC, Rushin JM. Loose anagen hair syndrome mimicking the uncombable hair syndrome. Cutis 1996; 57: 111–12

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Chapalain V, Winter H, Langbein L, et al. Is the loose anagen hair syndrome a keratin disorder? A clinical and molecular study. Arch Dermatol 2002; 138: 501–6 Olsen EA, Bettencourt MS, Cote NL. The presence of loose anagen hairs obtained by hair pull in the normal population. Invest Dermatol Symp Proc 1999; 4: 258–60 Tosti A, Piraccini BM. Loose anagen hair syndrome and loose anagen hair. Arch Dermatol 2002; 138: 521–2

Trichothiodystrophy Synonyms: BIDS, IBIDS, PIBIDS Major points

• Sulfur-deficient, brittle hair (scalp, eyebrows, • • • • • • •

eyelashes) Neuroectodermal disorder Intellectual impairment Short stature Decreased fertility Photosensitivity with impaired DNA repair Ichthyosis Autosomal recessive

Pathogenesis

• Microscopy of hair shaft: flattened, twisted hair

• • •

shaft, wavy, irregular, trichoschisis (clean, transverse fractures where there is localized absence of cuticle cells) Polarized microscopy: alternating bright and dark bands, resembling a tiger tail Sulfur content of hair reduced by 50% Gene locus/gene: chromosome 19q13/ mutation in at least two separate genes: ERCC2/XPD, and ERCC3/XPB, which encode the two helicase subunits of transcription/repair vector TFIIH

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Prognosis

• Depends upon status of mental capabilities References Bergmann E, Egly JM. Trichothiodystrophy, a transcription syndrome. Trends Genet 2001; 17: 279–86 Itin PH, Pittelkow MR. Trichothiodystrophy: review of sulfur-deficient brittle hair syndromes and association with the ectodermal dysplasias. J Am Acad Dermatol 1990; 22: 705–17 Itin PH, Sarasin A, Pittelkow MR. Trichothiodystrophy: update on the sulfur-deficient brittle hair syndromes. J Am Acad Dermatol 2001; 44: 891–920 McCuaig C, Marcoux D, Rasmussen JE, et al. Trichothiodystrophy associated with photosensitivity, gonadal failure, and striking osteosclerosis. J Am Acad Dermatol 1993; 28: 820–6 Sperling LC, DiGiovanna JJ. ‘Curly’ wood and tiger tails: an explanation for light and dark banding with polarization in trichothiodystrophy. Arch Dermatol 2003; 139: 1189–92 van Brabant AJ, Stan R, Ellis NA. DNA helicases, genomic instability, and human genetic disease. Annu Rev Genomics Hum Genet 2000; 1: 409–59

ACQUIRED SCARRING ALOPECIA Major points

• End result of inflammatory process affecting pilosebaceous unit, resulting in destruction of tissue and permanent hair loss (See Table 18.4) (Figure 18.18–20) References Tan E, Marinka M, Ball N, Shapiro J. Primary cicatricial alopecias: clinicopathology of 112 cases. J Am Acad Dermatol 2004; 50: 25–32

Diagnosis

• Clinical features with characteristic microscopy of hair shaft Differential diagnosis

• Other hair shaft abnormalities Treatment

• Gentle hair care

ABNORMALITIES OF INCREASED HAIR Hypertrichosis Major points

• Diffuse congential hypertrichosis 1. Hypertrichosis lanuginosa a. Very rare

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Table 18.4

Causes of scarring alopecia

Developmental defects/syndrome Aplasia cutis congenita Conradi–Hünermann chondrodysplasia punctata Incontinentia pigmenti Ankyloblepharon, ectodermal dysplasia, cleft lip or palate (AEC) syndrome Epidermolysis bullosa Hallermann-Streiff syndrome KID syndrome Goltz syndrome Ichthyoses Infections Fungal, bacterial, viral (herpes zoster), syphilis Trauma Traction Trichotillomania Hot-comb alopecia Radiation Burns Inflammatory disorders Lichen planopilaris: lichen planus localized to follicles; progressive; mild itching; hyperkeratotic follicular papules with erythema and scaling; histology shows lichenoid infiltrate around follicle Morphea: discrete nontender sclerotic patches with ivory-colored shiny center and violaceous border; can see en coup de sabre pattern on frontal scalp Scleroderma: generalized progressive systemic sclerosis Lupus erythematosus: patchy erythema with telangiectases, follicular plugging and central hypo- or depigmentation with peripheral hyperpigmentation; or diffuse Keratosis pilaris atrophicans: follicular keratinous plugging with erythema Folliculitis decalvans: recurrent patchy painful folliculitis, mainly of scalp, often associated with Staphylococcus aureus Dissecting cellulitis of scalp: chronic inflammatory disease; painful fluctuant nodules and abscesses interconnected by deep sinus tracts (Figure 18.18) Alopecia mucinosa: grouped follicular papules and plaques with hair loss: histology shows accumulation of mucin in sebaceous glands with dissolution of cellular attachments; perifollicular and perivascular inflammatory cell infiltrate of lymphocytes, histiocytes and a few eosinophils. (Figure 18.19)

Figure 18.18 Dissecting folliculitis with cysts and tracts which are sterile abscesses

Figure 18.19 teenager

Neoplastic disorders Acne keloidalis: grouped, small papules typically on nape of neck: caused by shaving of hair and re-entry of curved hairs into skin causing inflammation and keloid formation Benign tumors: adenexal tumors, hemangiomas Malignant tumors: leukemias, lymphomas, sarcomas

Alopecia mucinosa – benign type seen in a

b. Characterized by retention of lanugo hair c. At birth: coat of profuse silky hair up to 10 cm long with accentuation over the spine and ears d. Autosomal recessive or dominant Prepubertal hypertrichosis

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Table 18.5

Causes of hypertrichosis

Types of congenital circumscribed hypertrichosis Congenital nevocellular nevus Congenital Becker nevus Smooth muscle hamartoma Nevoid hypertrichosis Underlying neurofibroma Hypertrichosis cubiti Hemihypertrophy Spinal dysraphism Anterior cervical hypertrichosis

Figure 18.20 planopilaris

Figure 18.21

1. 2. 3. 4.

• •

Acquired scarring alopecia – lichen

Hypertrichosis – familial type on lower back

Common Generalized; can present from birth Severity in early childhood varies Profuse terminal hair growth on back and limbs, and also temples, forehead and eyebrows (Figure 18.21) 5. Not clear whether this represents an abnormality or normal range of hair growth seen in some racial groups (e.g. Mediterranean peoples, Indians) Drug-induced hypertrichosis (Table 18.5) Localized hypertrichosis (see Table 18.5) 1. Hypertrichosis with spinal fusion abnormalities a. Tuft of long hair overlying defect (dimple, sinus tract, lipoma, spinal bifida, occult spinal dysraphism) b. Lumbosacral area usually

Congenital syndromes with secondary hypertrichosis Brachmann-de Lange syndrome Fetal exposures Fetal hydantoin syndrome Fetal alcohol syndrome Lipoatrophic diabetes Mucopolysaccharidoses Congenital porphyrias Rubinstein–Taybi syndrome Hypomelanosis of Ito Causes of acquired localized hypertrichosis Becker nevus Orthopedic casts and splints Friction Lichen simplex chronicus Habitual biting Insect bites Atopic eczema Venous malformations, thrombosis Trichomegaly HIV Systemic lupus erythematosus Linear scleroderma Causes of acquired generalized hypertrichosis Infection Malnutrition Dermatomyositis Thyroid abnormalities Cerebral disturbances Acrodynia Pharmacologic causes of hypertrichosis Phenytoin Acetazolamide Streptomycin Cyclosporin A Diazoxide Minoxidil

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2. Hypertrichosis with cranial abnormalities (‘hair collar’ sign) a. Peripheral collar of thick dark tuft of hair with an underlying form fruste of a neural tube closure defect and heterotopic brain tissue Pathogenesis

• Increase in hair growth by conversion of vellus to terminal hairs, or changes in the hair-growth cycle Diagnosis

• Clinical diagnosis • Rule out causes of hirsutism, if appropriate Differential diagnosis (See Table 18.5) Treatment

• Depends upon cause of hypertrichosis • Removal of excess hair: shaving, epilation, chemical depilatories, threading, waxing, electrolysis, laser hair removal Prognosis

• Depends upon cause of hypertrichosis; usually

Figure 18.22 Hirsutism caused by polycystic ovary disease in a teenage girl

Diagnosis

• History • Physical examination • Laboratory tests: serum testosterone and free testosterone, dehydroepiandrosterone sulfate, cortisol levels, urinary 17-ketosteroids, luteinizing hormone, follicle stimulating hormone, prolactin levels and pelvic ultrasound examination

permanent References Miller ML, Yeager JK. Hairy elbows. Arch Dermatol 1995; 131: 858–9 Wendelin DS, Pope DN, Mallory SB. Hypertrichosis. J Am Acad Dermatol 2003; 48: 161–79

Hirsutism

Differential diagnosis

• • • • •

Genetic predisposition in some ethnic groups Congenital adrenal hyperplasia Cushing syndrome Hyperprolactinemia Ovarian and adrenal tumors

Major points

• Hair in masculine pattern in females on face, chest, upper back, abdomen

Treatment

• Removal of excess hair: shaving, epilation,

• Often associated with other signs of virilization or polycystic ovary syndrome in teens (Figure 18.22)

chemical depilatories, threading, waxing, electrolysis, laser hair removal Oral contraceptives

Pathogenesis

Prognosis

• Abnormality of pituitary, adrenal glands or ovary

• Depends upon etiology of hirsutism, usually

with increase in male hormones

permanent

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References Shum KW, Cullen DR, Messenger AG. Hair loss in women with hyperandrogenism: four cases responding to finasteride. J Am Acad Dermatol 2002; 47: 733–9 Sperling LC, Heimer WL. Androgen biology as a basis for the diagnosis and treatment of androgenic disorders in women. II. J Am Acad Dermatol 1993; 28: 901–16 Whiting DA. Diagnostic and predictive value of horizontal sections of scalp biopsy specimens in male pattern androgenetic alopecia. J Am Acad Dermatol 1993; 28: 755–63

ABNORMALITIES OF HAIR COLOR See Table 18.6

Menkes kinky hair syndrome Major points • Hair appears lightly pigmented, twisted, sparse • Microscopic hair examination: pili torti, trichorrhexis nodosa • General decrease in skin pigmentation • Progressive severe mental retardation and neurologic defects • Bony changes resembling scurvy • Tortuosities of cerebral and systemic vasculature • Diverticuli of the bladder Pathogenesis • Gene/gene locus: ATP7A (copper transporting ATPase enzyme)/Xp 13.3 • Abnormality of a copper binding protein important in cytoplasmic copper transport, causing an inappropriate copper distribution within the cells • Copper accumulates in fibroblasts and macrophages • Kinky hair results from a surplus of free sulfhydryl groups and a decrease in copper-dependent disulfide bonds • Hypopigmentation results from a decrease in tyrosinase, a copper-containing enzyme Diagnosis • Clinical presentation • Low serum copper and ceruloplasm levels • Genetic testing

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Abnormalities of hair color

Disorders associated with primary reduction of hair color Oculocutaneous albinism Chediak–Higashi syndrome Elejalde syndrome Griscelli syndrome Pili torti Menkes syndrome Uncombable hair Phenylketonuria Homocystinuria Prader–Willi syndrome Disorders associated with premature canities (graying) Autoimmune disease Vitiligo Alopecia areata Pernicious anemia Addison disease Hypothyroidism Hyperthyroidism Syndromes Progeria Werner syndrome Rothmund–Thomson syndrome Dyskeratosis congenita Down syndrome Cri du chat syndrome Böök syndrome Localized hypopigmentation (poliosis) Piebaldism Waardenburg syndrome Vitiligo Vogt–Koyanagi–Harada syndrome Alezzandrini syndrome Alopecia areata Tuberous sclerosis Halo nevus

Differential diagnosis • Child abuse • Congenital lipodystrophic diabetes • Trichothiodystrophy Treatment • No effective treatment is available Prognosis • Death usually before 1 year of age

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• Mildly affected patients can survive to adolescence or adulthood References

Chelly J, Tumer Z, Tonnesen T, et al. Isolation of a candidate gene for Menkes disease that encodes a potential heavy metal binding protein. Nature Genet 1993; 3: 14–19 Kodama H, Sato E, Yanagawa Y, et al. Biochemical indicator for evaluation of connective tissue abnormalities in Menkes’ disease. J Pediatr 2003; 142: 726–8

3. Visual acuity normal, but strabismus and nystagmus common Infections: children usually present with infection and fever in early childhood 1. Infections of the skin, lungs, and upper respiratory tract with Staphylococcus aureus, Streptococcus species 2. Natural killer cell function decreased Neurological deterioration is progressive: clumsiness, abnormal gait, paresthesias and other findings Accelerated phase: fever, hepatosplenomegaly, lymphadenopathy, pancytopenia; Epstein–Barr virus has been implicated Autosomal recessive

Menkes JH. Kinky hair disease; twenty five years later. Brain Dev 1988; 10: 77–9

Poulsen L, Horn N, Heilstrup H, et al. X-linked recessive Menkes disease: identification of partial gene deletions in affected males. Clin Genet 2002; 62: 449–57

Shim H, Harris ZL. Genetic defects in copper metabolism. J Nutr 2003; 133 (5 Suppl 1): 1527S–31S

Pathogenesis

• Caused by a mutation in the LYST gene on chromosome 1q

Chediak–Higashi syndrome

Diagnosis

Major points

• Clinical presentation • Giant lysosomal granules are seen in

• Hypopigmentation of skin and hair 1. Hair has a silvery tint because of large melanosome granules in the hair (Figure 18.23) 2. Loss of iris pigmentation with photophobia

polymorphnuclear leukocytes, melanosomes, and other cells Genetic testing

Differential diagnosis

• • • •

Elejalde syndrome Griscelli syndrome Menkes kinky hair syndrome Other immunodeficiencies

Treatment

• Supportive treatments with antibiotics • Bone marrow transplantation early Prognosis

• Usually fatal before age 10 years, unless patient undergoes successful bone marrow transplant References Haddad E, Le Deist F, Blanche S, et al. Treatment of Chediak–Higashi syndrome by allogeneic bone marrow transplantation: report of ten cases. Blood 1995; 85: 3328–33 Figure 18.23 Chediak–Higashi syndrome with silvery hair, mental retardation and numerous infections

Shiflett SL, Kaplan J, Ward DM. Chediak–Higashi syndrome: a rare disorder of lysosomes and lysosome related organelles. Pigment Cell Res 2002; 15: 251–7

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Ward DM, Shiflett SL, Kaplan J. Chediak–Higashi syndrome: a clinical and molecular view of a rare lysosomal storage disorder. Curr Mol Med 2002; 2: 469–77

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review of the literature. J Am Acad Dermatol 1998; 38: 295–300

Elejalde syndrome Griscelli syndrome Major points Major points

• Characterized by pigment dilution, • • • • • • • •

hepatosplenomegaly, lymphohistiocytosis, and T and B cell immunodeficiencies Immunodeficiency with frequent pyogenic infections, fever, neutropenia, thrombocytopenia Hair has a silvery gray tint secondary to the dispersal and clumping of melanin in the hair shaft Skin is lighter in color than in siblings and parents Neurologic dysfunction with cerebellar and bulbar signs, encephalopathy, seizures, retardation Accelerated phase in childhood is usually fatal Autosomal recessive Gene locus: 15q 21 Gene: Myosin VA (Type 1), RAB27A (Type 2)

• Characterized by silvery hair, severe CNS • • • •

dysfunction, abnormal inclusions in cells of all tissues Neurologic abnormalities No immunologic dysfunctions Autosomal recessive Elejalde syndrome and Griscelli syndrome Type 1 may be the same entity

References Bahadoran P, Ortonne JP, Ballotti R, de Saint-Basile G. Comment on Elejalde syndrome and relationship with Griscelli syndrome. Am J Med Genet 2003; 116A: 408–9

References

Duran-McKinster C, Rodriguez-Jurado R, Ridaura C, et al. Elejalde syndrome – a melanolysosomal neurocutaneous syndrome: clinical and morphological findings in 7 patients. Arch Dermatol 1999; 135: 182–6

Griscelli C, Durandy A, Guy-Grand D, et al. A syndrome associating partial albinism and immunodeficiency. Am J Med 1978; 65: 691–702

Elejalde BR, Holguin J, Valencia A, et al. Mutations affecting pigmentation in man: I. Neuroectodermal melanolysosomal disease. Am J Med Genet 1979; 3: 65–80

Kumar M, Sackey K, Schmalstieg F, et al. Griscelli syndrome: rare neonatal syndrome of recurrent hemophagocytosis. J Pediatr Hematol Oncol 2001; 23: 464–8

Ivanovich J, Mallory S, Storer T, et al. 12-year-old male with Elejalde syndrome (neuroectodermal melanolysosomal disease). Am J Med Genet 2001; 98: 313–16

Mancini AJ, Chan LS, Paller AS. Partial albinism with immunodeficiency: Griscelli syndrome: report of a case and

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19 NAIL DISORDERS

Agnail

Beau’s lines

• Hang nail; hard spicules at edge of nail

• Uniform transverse grooves across the nail plate

Alopecia areata

• Shallow pits on surface of nail plate; geometric arrangement giving the appearance of a grid or screen; 60% of patients with alopecia areata have pitting which is reversible (Figure 19.1)

• • • •

usually affecting all nails (Figure 19.2) Thumbnails and great toenails more prominent than others Grooves move distally with nail growth Caused by an arrest in nail plate formation by systemic illness or toxins No treatment is needed

Anonychia

Blue nails

• Absence of nail from birth; associated with nail

• Associated with antimalarial drugs, argyria,

patella syndrome, ectodermal dysplasias, maternal hydantoin ingestion, Coffin–Siris syndrome and others

Figure 19.1 Pitting – commonly occurs in alopecia areata and psoriasis

bleomycin, congenital pernicious anemia, minocycline and Wilson disease (Figure 19.3)

Figure 19.2 Beau’s lines – horizontal ridge of all 20 nails following a severe illness

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• Clinical presentations

Figure 19.3

Nail pigmentation caused by minocycline

1. Congenital hypertrophic lateral nail folds a. Presents as a firm red swelling of lateral nail fold with tenderness (Figure 19.5) b. Usually disappears spontaneously after several months, but may require surgical intervention 2. Distal-lateral nail embedding a. Caused by uneven cutting of the nail plate with subsequent growth of the plate into an injured lateral nail fold b. Painful with exuberant granulation tissue around the edge of the embedded plate c. Complications: secondary infection (often Pseudomonas) and paronychia

Brachyonychia

• Short nails with width greater than length; associated with Rubinstein–Taybi syndrome, Down syndrome

Clubbing

• Bulbous, fusiform enlargement of distal portion of fingers and toes

• Lovibond’s angle >180° • Associated with cystic fibrosis, cyanotic cardiovascular diseases

Dystrophy

• General term describing nail changes. Examples: trauma, epidermal nevus, lichen striatus, psoriasis, twenty-nail dystrophy and others

Figure 19.4 Half-and-half nails – proximal nail is white and distal nail is pink; associated with renal disease

Half-and-half nails (Lindsay nails)

• Proximal nail is white (Figure 19.4) • Distal 20–50% of nail is red, pink, or brown • Seen in renal failure Hutchinson sign

• Periungual spread of pigmentation into the proximal and lateral nail folds

• An important indicator of subungual melanoma but not pathognomonic for it

Ingrown nails

• Common problem in infancy, childhood and teens

Figure 19.5 Congenital ingrown toenails – erythema and swelling of the lateral nail folds, often bilateral

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d. Treatment: subungual packing with sterile cotton in uncomplicated cases with silver nitrate cauterization, oral antibiotics, topical steroid solutions. In complicated cases, surgical removal of the trapped nail plate e. Rarely, total ungual avulsion may be needed

Koilonychia

• Spoon-shaped or flat nails (Figure 19.6) • Associated with iron deficiency anemia • Can be idiopathic or familial

Figure 19.6 Koilonychia – congenital curving of toenails, a common finding in infants and young children

Leukonychia

• • • •

White nails (Figure 19.7) May be congenital or acquired May be totally white, or striped May be associated with multiple causes: alopecia areata, hypoalbuminemia, exfoliative dermatitis, Darier disease, pellagra, zinc deficiency

Macronychia

• Large but otherwise normal nail • Associated with neurofibromatosis, tuberous sclerosis

Malalignment of the great toenails

Figure 19.7 Leukonychia – banded type of unknown etiology. This had been present for many years

• Characterized by lateral deviation of the nail plate relative to the axis of the hallux (Figure 19.8)

• Transverse ridging, thickening and gradual • • • • • •

tapering towards the distal free edge with dicoloration May be discolored from intermittent hemorrhage or microbes May be unilateral or bilateral Surgical correction may be needed Predisposes to paronychia and ingrown nails Spontaneous improvement can be seen Autosomal dominant

Median nail dystrophy

• Split or canal in nail plate usually just off center from cuticle to free edge (Figure 19.9)

Figure 19.8 discomfort

Malalignment of the great toenails, causing

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• Elbow dysplasia, subluxation of the radial heads • Iliac horns (calcifications from the posterior aspect of the ilium)

• Other findings

• Figure 19.9 tic

Median nail dystrophy – caused by a habit

1. Renal abnormalities: glomerulonephritis, renal dysplasia, Goodpasture syndrome 2. Hypoplasia of scapulae 3. Scoliosis 4. Cloverleaf pigmentation of irides (Lester iris) 5. Laxity of skin 6. Hyperhidrosis 7. Autosomal dominant Gene: LMX1B (LIM-homeobox transcription factor 1β) Gene locus: 9q34.1

References

• Caused by trauma or idiopathic; most common on thumb

Mee’s lines

• White bands in nail plate which move with plate as it grows

• Associated with arsenic ingestion, cardiac insufficiency, pellagra, renal failure, sickle cell anemia

Micronychia

• Small but otherwise normal nail or nails • Associated with ectodermal dysplasia, dyskeratosis congenita, nail–patella syndrome

Bongers EM, Gubler MC, Knoers NV. Nail–patella syndrome. Overview on clinical and molecular findings. Pediatr Nephrol 2002; 17: 703–12 Bongers EM, Van Bokhoven H, Van Thienen MN, et al. The small patella syndrome: description of five cases from three families and examination of possible allelism with familial patella aplasia–hypoplasia and nail–patella syndrome. J Med Genet 2001; 38: 209–14 Dreyer SD, Zhou G, Baldini A, et al. Mutations in LMX1B cause abnormal skeletal patterning and renal dysplasia in nail patella syndrome. Nature Genet 1998; 19: 47–50 Ogden JA, Cross GL, Guidera KJ, Ganey TM. Nail patella syndrome. A 55-year follow-up of the original description. J Pediatr Orthop 2002; 11: 333–8 Stratigos AJ, Baden HP. Unraveling the molecular mechanisms of hair and nail genodermatoses. Arch Dermatol 2001; 137: 1465–71

Muehrcke’s nails

• Paired white parallel bands seen with hypoalbuminemia

• Bands do not move

Nevi

• Characterized by longitudinal pigmented bands (Figure 19.10)

• Usually solitary Nail–patella syndrome Synonym: congenital iliac horns syndrome, hereditary osteo-onychodysplasia syndrome • Onychodystrophy (medial thumbnails most involved) with hypoplasia and splitting with usual sparing of the toenails • Triangular lunulae • Absent or rudimentary patellae, with unstable knees

Onychogryphosis

• Acquired thickening (Figure 19.11) • Caused by trauma, aging or unknown etiology Onychoheteropia

• Misplaced nails

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Onychomycosis

• Fungal infection of the nail (See Chapter 9) (Figures 19.14 and 19.15)

Onychophagia

• Nail biting Onychoschizia

• Splitting of nails into parallel layers, with a lamellar surface so that small pieces flake off Figure 19.10 Nevus of the nail matrix with linear dark band of pigmentation; because there is no pigment on the proximal nail fold, this is not Hutchinson sign; however, a biopsy of the nail matrix is suggested to rule out malignant melanoma

Onychorrhexis

• Excess longitudinal ridging Pachyonychia congenita

• Type I: Jadassohn–Lewandowsky syndrome

Figure 19.11 Onychogryphosis of the third toenail with onchomycosis of the great toenail

Onycholysis

• Separation of nail plate from nail bed at distal and lateral attachments (Figure 19.12)

• Caused by hypo- or hyperthyroidism, trauma, psoriasis, candidal infections, diabetes, phototoxic reactions to drugs (tetracycline, thorazine), or idiopathic

Onychomadesis

• Separation of entire nail plate (Figure 19.13)

1. Marked thickening of nails (subungual hyperkeratosis) (Figure 19.16) 2. Recurrent nail shedding 3. Plantar and palmar keratoses 4. Acral bullae 5. Follicular keratoses on buttocks and extremities 6. Hyperhidrosis of the palms and soles 7. Leukoplakia that histologically resembles a white sponge nevus and shows no tendency toward malignant degeneration 8. Mutation of keratin gene: KRT6A, KRT16 (keratin 6a, keratin 16), gene locus: 17q12q21, 12q13 Type II: Jackson-Lawler syndrome 1. Clinical findings of Type I plus 2 Bullae of palms and soles 3. Palmar/plantar hyperhidrosis 4. Steatocystoma multiplex 5. Epidermal cysts 6. Natal teeth 7. No mucosal lesions 8. Mutation of gene: KRT6B, KRT17 (keratin 6b, keratin 17) 9. Gene locus: 17q17-q21, 12q13

Differential diagnosis

• Mucocutaneous candidiasis • Onychomycosis

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Figure 19.12 Onycholysis – lifting off of the nail plate from the nail bed

Figure 19.15 Onychomycosis – thickened distal nails with keratotic debris

Figure 19.13 Onychomadesis – complete shedding of nails after a severe illness

Figure 19.16 nails

Pachyonychia congenita – markedly thick

Treatment

• Surgical removal of nails if severe infections around the nails; keratolytic agents may be helpful Prognosis

• Chronic thickening of nails with chronic paronychia References

Figure 19.14 Onychomycosis – superficial white discoloration associated with Trichophyton rubrum in a child

Feinstein A, Friedman J, Schewach-Millet M. Pachyonychia congenita. J Am Acad Dermatol 1988; 19: 705–11 Paller AS, Moore JA, Scher R. Pachyonychia congenita tarda: a late-onset form of pachyonychia congenita. Arch Dermatol 1991; 127: 701–3 Su WPD, Chun SI, Hammond DE, Gordon H. Pachyonychia congenita: clinical study of 12 cases and review of the literature. Pediatr Dermatol 1990; 7: 33–8

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Paronychia

2. Topical clindamycin solution 3. Drying agents: 4% thymol in chloroform one or two times a day (should not be used in children who put their hands in their mouth)

• Infection of periungual tissues • Common causes: sucking thumb or fingers • Characterized by painful erythematous induration • • • • • •

of proximal or lateral nail folds with fissuring (Figure 19.17) Cuticle is obliterated; nail folds round and replaced with granulation tissue Pus may be expressed Nail dystrophy with wavy undulation may result from inflammation in the proximal nail fold affecting the matrix Common organisms: Staphylococcus, Streptococcus and Candida Trauma to the proximal nail fold disrupts the cuticle, and in moist environment, organisms invade If multiple fingers and toes are involved, consider predisposing diseases: acrodermatitis enteropathica, mucocutaneous candidiasis, or immunodeficiency syndromes Treatment is difficult if predisposing factors are not addressed 1. Topical combination of steroid and antifungal agents (Mycolog®) used two or three times per day for 4–6 months

Pincer nail

• Overcurvature of the nails causing pain and partial strangulation dystrophy of the soft tissues (Figure 19.18)

Polyonychia

• Two or more separate nails on one digit Pseudomonas nail

• Greenish discoloration under the nail plate with onycholysis (Figure 19.19)

Psoriasis

• Occurs in 15–79% of children with cutaneous • • •

Figure 19.17 Paronychia – inflammation around the nail caused by Candida albicans

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signs of psoriasis Pitting of the nail plate is most common; rarely can involve all 20 nails (Figure 19.20) Other findings: discoloration, onycholysis, distal subungual debris and oil spotting Periungual psoriasis can lead to marked nail dystrophy with hyperkeratosis and crumbling of the nail plate

Figure 19.18

Pincer nail causing pain in this teenager

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Racquet nail

• Congenital abnormality of the nail, causing the •

nail to be broader and shorter Most common on the thumb

Red lunulae

• Seen in collagen vascular disease, alopecia areata, congestive heart failure

Splinter hemorrhages

• Associated with subacute bacterial endocarditis, trauma, vasculitis, cirrhosis, trichinosis, scurvy, psoriasis, chronic glomerulonephritis, Darier disease

Terry’s nails Figure 19.19 Pseudomonas infection of the nail bed causing yellow–green discoloration of the nail and the nail bed

• Distal 1–2 mm pink, proximal nail white • Seen with hypoalbuminemia or hepatic cirrhosis Trachyonychia

• Uniform roughness of surface of nail plate • Associated with ichthyosis vulgaris, ectodermal dysplasia, 20-nail dystrophy, others

Traumatic nail injury

• Injury to the nail, nail matrix, nail plate (Figures • •

19.21 and 19.22) Common in childhood Can cause permanent dystrophy

Twenty-nail dystrophy Figure 19.20 Psoriasis – hyperkeratotic plaques under nails with pitting

• Acquired dystrophy involving all 20 nails • Characterized by marked roughness of the nail

Pterygium

• Associated with dyskeratosis congenita, graft-

• • • •

versus-host disease, Raynaud disease, systemic sclerosis

• Wing-shaped destruction of nail matrix • Overgrowth of cuticle onto nail eventually destroying the nail, causing scarring

plates (trachyonychia) with longitudinal grooves, striations, onychorrhexis, distal chipping (Figure 19.23) Nails can be either thin or thick May be associated with lichen planus Cause unknown Course variable with improvement in 6 months to 16 years Treatment:

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Figure 19.21 Trauma – residual damage to nail caused by slamming the finger in a car door

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Figure 19.23 Twenty-nail dystrophy – all nails simultaneously developed trachyonychia

• Painful recurrent vesicles around the distal finger or nails

Yellow nails

• Thickened yellow nails • Associated with chronic lymphedema, pleural effusion, bronchiectasis, chronic bronchitis, rheumatoid arthritis, sinusitis, thyroid disease, psoriasis, pachyonychia congenita, drugs (e.g. tetracycline, penicillamine) References Adams BB. Jogger’s toenail. J Am Acad Dermatol 2003; 48: S58–9 Carroll LA, Laumann AD. Doxycycline-induced photoonycholysis. J Drugs Dermatol 2003; 2: 662–3 Cohen PR. Red lunulae: case report and literature review. J Am Acad Dermatol 1992; 26: 292–4 Figure 19.22 Trauma – hemorrhage under the nail from dropping a heavy object on the toe in a patient with hemophilia

1. Potent topical steroids may be of some benefit over 6 months 2. Clear nail lacquers

Whitlow

• Caused by herpes inoculation into finger tip or around nail

Daniel CR, Piraccini BM, Tosti A. The nail and hair in forensic science. J Am Acad Dermatol 2004; 50: 258–61 Feldman SR, Gammon WR. Unilateral Muehrcke’s lines following trauma. Arch Dermatol 1989; 125: 133–4 Jerasutus S, Suvanprakorn P, Kitchawengkul O. Twenty nail dystrophy. Arch Dermatol 1990; 126: 1068–70 Rich P, Scher RK. Nail psoriasis severity index: a useful tool for evaluation of nail psoriasis. J Am Acad Dermatol 2003; 49: 206–12 Saray Y, Seckin D, Gulec AT, et al. Nail disorders in hemodialysis patients and renal transplant recipients: a case–control study. J Am Acad Dermatol 2004; 50: 197–202

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20 GENODERMATOSES AND SYNDROMES

ICHTHYOSES

• Heterogeneous group of inherited disorders • •

characterized by the accumulation of scale on the skin surface The word ichthyosis comes from the Greek word for fish, referring to the scaliness of the skin National organization: www.scalyskin.org (F.I.R.S.T.)

Collodion baby Major points

• Not specific for any particular ichthyosis • At birth: taut shiny membrane of skin that resembles plastic wrap (Figure 20.1)

• Membrane often becomes fissured and cracked • Ectropion

• • • • •

Eclabium Pinnae crumpled Tips of fingers often tapered Resolves with shedding of membrane Hair and nails usually normal

Pathogenesis • Seen in various types of ichthyosis: 1. Lamellar ichthyosis 2. Ichthyosis vulgaris 3. Congenital ichthyosiform erythroderma (CIE) 4. Netherton syndrome 5. Conradi–Hünermann syndrome 6. Ectodermal dysplasia 7. Ankyloblepharon ectodermal dysplasia clefting (AEC) syndrome 8. Gaucher disease type 2 • Caused by retention of or abnormal stratum corneum in utero Diagnosis • Histology: stratum corneum thickened with orthokeratosis Differential diagnosis • Postmaturity desquamation • Staphylococcal scalded skin syndrome

Figure 20.1

Collodion membrane in a neonate

Treatment • Emollients (e.g. ointments) • Increase ambient humidity • Maintain hygiene to prevent secondary infection • Surveillance of skin cultures • Artificial tears for ectropion • Stabilization of temperature

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Prognosis

• Membrane usually shed in 7–10 days • Outcome depends upon type of ichthyosis References Akcakus M, Gunes T, Kurtoglu S, Ozturk A. Collodion baby associated with asymmetric crying facies: a case report. Pediatr Dermatol 2003; 20: 134–6 Buyse L, Graves C, Marks R, et al. Collodion baby dehydration: the danger of high transepidermal water loss. Br J Dermatol 1993; 129: 86–8 DiGiovanna JJ, Robinson-Bostom L. Ichthyosis: etiology, diagnosis, and management. Am J Clin Dermatol 2003; 4: 81–95 Matsumoto K, Muto M, Seki S, et al. Loricrin keratoderma: a cause of congenital ichthyosiform erythroderma and collodion baby. Br J Dermatol 2001; 145: 657–60 Raghunath M, Hennies HC, Ahvazi B, et al. Self-healing collodion baby: a dynamic phenotype explained by a particular transglutaminase-1 mutation. J Invest Dermatol 2003; 120: 224–8 Richard G, Ringpfeil F. Ichthyoses, erythrokeratodermas and related disorders. In Dermatology. Bolognia JL, Jorizzo JL, Rapini RP, eds. Mosby: London, 2003: 775–808

Ichthyosis vulgaris Major points

• • • • • • • • • •

Most common form of ichthyosis Incidence: 1 per 300–2000 persons Onset 3–12 months of age Personal or family history of dry skin or atopy Fine white scales, can be dark Location: extensor surfaces of the extremities and trunk, with extremities more severely affected (Figure 20.2) Margin of scale tends to turn up Flexural areas spared Hyperlinearity of the palms and keratosis pilaris is common Autosomal dominant

Pathogenesis

• Increased adhesiveness of the stratum corneum cells and failure to separate

• Gene locus: 1q21 • Gene: profilaggrin, FLG (filaggrin)

Figure 20.2 Ichthyosis vulgaris associated with hyperlinearity of the palms

Diagnosis

• Clinical presentation • Histology: absent granular layer and retention hyperkeratosis

• Electron microscopy: abnormally small and crumbly appearing keratohyaline granules Differential diagnosis

• X-linked ichthyosis in a male • Sjögren–Larssen syndrome • Xerosis Treatment

• Topical keratolytic agents • α-hydroxyacids • Moisturize skin with emollients immediately after bathing and frequently through the day Prognosis

• Life-long disorder with exacerbations in dry (winter) weather References Okulicz JF, Schwartz RA. Hereditary and acquired ichthyosis vulgaris. Int J Dermatol 2003; 42: 95–8 Presland RB, Boggess D, Lewis SP, et al. Loss of normal profilaggrin and filaggrin in flaky tail (ft/ft) mice: an animal model for the filaggrin-deficient skin disease ichthyosis vulgaris. J Invest Dermatol 2000; 115: 1072–81 Smack DP, Korge BP, James WD. Keratin and keratinization. J Am Acad Dermatol 1994; 30: 85–102

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Williams ML, Elias PM. From basket weave to barrier. Arch Dermatol 1993; 129: 626–9

• Increased adhesiveness of the stratum corneum

Zhong W, Cui B, Zhang Y, et al. Linkage analysis suggests a locus of ichthyosis vulgaris on 1q22. J Hum Genet 2003; 48: 390–2

• Gene locus: Xp22.32 • Gene: STS (steroid sulfatase)

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cells and failure of these cells to separate

Diagnosis

X-linked ichthyosis

• Clinical presentation in a male, often with a

Synonym: steroid sulfatase deficiency

• Enzyme assay of scale, cultured fibroblasts,

Major points

• Lipoprotein electrophoresis: rapid mobility of

• Incidence: 1 per 2000–6000 males • Placental steroid sulfatase deficiency syndrome with failure to initiate or progress in labor

• Begins in the first year of life • Scales large, thick, adherent and dark (dirty • • • • • •

appearance) (Figure 20.3) Generalized involvement, milder on face May involve flexures and neck Slightly thickened, scaly palms and soles Asymptomatic corneal opacities (50% adult males, some female carriers) Cryptorchidism (20%) X-linked recessive inheritance (males only)

positive family history keratinocytes or blood leukocytes low-density lipoproteins

• Demonstration of gene mutation • Histology: nondiagnostic; shows retention hyperkeratosis Differential diagnosis

• Ichthyosis vulgaris • Sjögren–Larssen syndrome Treatment

• Topical keratolytic agents: α-hydroxyacids • Emollients immediately after bathing and frequently through the day

Pathogenesis

• Increase ambient humidity

• Cholesterol sulfate in epidermis is built up

Prognosis

• Persistent; worsens in dry weather and may resolve in humid environments

• Risk for testicular carcinoma and hypogonadism References Cuevas-Covarrubias SA, Jimenez-Vaca AL, Gonzalez-Huerta LM, et al. Somatic and germinal mosaicism for the steroid sulfatase gene deletion in a steroid sulfatase deficiency carrier. J Invest Dermatol 2002; 119: 972–5 Hernandez-Martin A, Gonzalez-Sarmiento R, De Unamuno P. X-linked ichthyosis: an update. Br J Dermatol 1999; 141: 617–27 Kashork CD, Sutton VR, Fonda Allen JS, et al. Low or absent unconjugated estriol in pregnancy: an indicator for steroid sulfatase deficiency detectable by fluorescence in situ hybridization and biochemical analysis. Prenat Diagn 2002; 22: 1028–32

Figure 20.3 the arms

X-linked ichthyosis – dark brown scaling on

Zettersten E, Man M-Q, Sato J, et al. Recessive X-linked ichthyosis: role of cholesterol-sulfate accumulation in the barrier abnormality. J Invest Dermatol 1998; 111: 784–90

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Lamellar ichthyosis

Diagnosis

Major points

• Clinical diagnosis • Histology: massive orthohyperkeratosis and

• Incidence: 1 per 300 000 persons • Collodion membrane at birth • Large, dark, plate-like scales (generalized) with • • • • • • • •

fissuring between scales (Figure 20.4) Mild erythroderma Ectropion Eclabium Dystrophic nails Alopecia No abnormality of mucosa or teeth Decreased sweating Autosomal recessive

Pathogenesis

• Increased cell hyperplasia of the basal cells and • • • •

increased transit rate through the epidermis Decreased transit time of epidermal cells with increased mitotic activity Alteration of scale lipids Gene defect in transglutaminase 1 (TGM1) that catalyzes cross-linking of proteins in the upper layers of the epidermis Gene locus: 14q11.2, 2q33-35, 19p12-q12

mild/moderate acanthosis

• Genetic testing Differential diagnosis

• Congenital ichthyosiform erythroderma • • •

(nonbullous) Sjögren–Larssen syndrome Netherton syndrome Other ichthyoses

Treatment

• Topical keratolytic agents • Moisturize skin with emollients immediately after • •

bathing and frequently through the day Oral retinoids (isotretinoin, acetretin) Increase ambient humidity

Prognosis

• Persistent life-long hyperkeratosis and peeling • Secondary infection common References Akiyama M, Sawamura D, Shimizu H. The clinical spectrum of nonbullous congenital ichthyosiform erythroderma and lamellar ichthyosis. Clin Exp Dermatol 2003; 28: 235–40 Allen DM, Esterly NB. Significant systemic absorption of tacrolimus after topical application in a patient with lamellar ichthyosis. Arch Dermatol 2002; 138: 1259–60 DiGiovanna JJ, Robinson-Bostom L. Ichthyosis: etiology, diagnosis, and management. Am J Clin Dermatol 2003; 4: 81–95 Hennies HC, Kuster W, Wiebe V, et al. Genotype/phenotype correlation in autosomal recessive lamellar ichthyosis. Am J Hum Genet 1998; 62: 1052–61 Huber M, Rettler I, Bernasconi K, et al. Mutations of keratinocyte transglutaminase in lamellar ichthyosis. Science 1995; 267: 525–8

Congenital ichthyosiform erythroderma (nonbullous) (CIE) Major points Figure 20.4 Lamellar ichthyosis – thick, dark brown, plate-like scales in an adult

• Born with collodion membrane • Generalized scaling and erythroderma, not as severe as lamellar ichthyosis (Figure 20.5)

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• • • • • • • •

Scales fine and white on face, trunk and scalp Scales large, plate-like and dark on legs Ectropion Corneal dystrophy Sparse hair Nail dystrophy Small stature (occasional) Mental retardation (occasional)

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Prognosis

• Persistent, life-long scaling and erythema (can be mild to severe) References Akiyama M, Sawamura D, Shimizu H. The clinical spectrum of nonbullous congenital ichthyosiform erythroderma and lamellar ichthyosis. Clin Exp Dermatol 2003; 28: 235–40 Laiho E, Ignatius J, Mikkola H, et al. Transglutaminase 1 mutations in autosomal recessive congenital ichthyosis: private and recurrent mutations in an isolated population. Am J Hum Genet 1997; 61: 529–38 Porter RM, Lane EB. Phenotypes, genotypes and their contribution to understanding keratin function. Trends Genet 2003; 19: 278–85 Williams ML, Elias PM. Enlightened therapy of the disorders of cornification. Clin Dermatol 2003; 21: 269–73

Epidermolytic hyperkeratosis Synonym: bullous congenital ichthyosiform erythroderma Figure 20.5 Congenital ichthyosiform erythroderma – with erythema and fine scales

Pathogenesis

• Epidermal cell turnover markedly increased; • • •

decrease in transit time of epidermal cells Autosomal recessive or dominant Gene locus: 14q11.2 Gene: TGM1 (transglutaminase-1)

Major points

• • • • •

Incidence is 1 per 300 000 births Blisters, erosions or erythema at birth Generalized scaling develops in later infancy Scales are warty, ridged and columnar (Figure 20.6) Spontaneous erosions throughout life where scales come off

Diagnosis

• Clinical diagnosis • Histology: nondiagnostic; focal or extensive parakeratosis and acanthosis Differential diagnosis

• Lamellar ichthyosis • Other ichthyoses Treatment

• Topical keratolytic agents • Moisturize skin with emollients immediately after •

bathing and frequently through the day Increase ambient humidity

Figure 20.6 Epidermolytic hyperkeratosis with columnar thick odiferous scales

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Prominent keratoderma on the palms and soles No ectropion Heat intolerance Secondary infection common, resulting in malodor Autosomal dominant or sporadic

Pathogenesis

• Chromosomes 12q and 17q • Gene: keratin 1 and 10 • Increased germinative cell hyperplasia of the basal •

cells and increased transit rate through the epidermis Increased transepidermal water loss

Diagnosis

• Clinical presentation • Histology: characteristic intracellular vacuolar •

degeneration of upper spinous/granular cell layers and large clumped keratohyalin granules Prenatal diagnosis by fetal skin biopsy at 20–22 weeks’ gestation

Differential diagnosis

• Lamellar ichthyosis • Congenital ichthyosiform erythroderma • • • • • •

(nonbullous) Epidermolysis bullosa at birth Incontinentia pigmenti at birth Staphylococcal scalded skin syndrome Ichthyosis hystrix Conradi–Hünermann syndrome Other ichthyoses

References Nazzaro V, Ermacora E, Santucci B, Caputo R. Epidermolytic hyperkeratosis: generalized form in children from parents with systematized linear form. Br J Dermatol 1990; 122: 417–22 Porter RM, Lane EB. Phenotypes, genotypes and their contribution to understanding keratin function. Trends Genet 2003; 19: 278–85 Schmuth M, Yosipovitch G, Williams ML, et al. Pathogenesis of the permeability barrier abnormality in epidermolytic hyperkeratosis. J Invest Dermatol 2001; 117: 837–47 Siegel DH, Howard R. Molecular advances in genetic skin diseases. Curr Opin Pediatr 2002; 14: 419–25 Smith F. The molecular genetics of keratin disorders. Am J Clin Dermatol 2003; 4: 347–64 Virtanen M, Smith SK, Gedde-Dahl T Jr, et al. Splice site and deletion mutations in keratin (KRT1 and KRT10) genes: unusual phenotypic alterations in Scandinavian patients with epidermolytic hyperkeratosis. J Invest Dermatol 2003; 121: 1013–20

Harlequin ichthyosis Major points

• Born with massive hyperkeratotic plates resembling • • • •

the diamond pattern on a harlequin’s costume (Figure 20.7) Distorted facial features with severe ectropion, eclabium, and rudimentary ears and nose Deformities of fingers/toes Premature delivery Autosomal recessive

Treatment

• Increase ambient humidity • Topical keratolytic agents • Bathing, add antimicrobial agents to water (e.g. • • •

dilute sodium hypochlorite dilution to reduce odor) (See Chapter 21) Moisturize skin with emollients immediately after bathing Low-dose retinoids (e.g. isotretinoin) Support group

Prognosis

• Persistent, life-long scaling • Malodor is a persistent problem • Secondary infection is common

Figure 20.7

Harlequin fetus – massive plate-like scales

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Pathogenesis

• Gene locus: 18q21.3 • Genetic heterogeneity and division into three subtypes: in types 1 and 2 profilaggrin is expressed but not processed to filaggrin; type 3 lacks profilaggrin; types 2 and 3 both have keratins 6 and 16 in addition to normal keratins 5/14 and 1/10 seen in all three subtypes Diagnosis

• • • •

Clinical appearance Histology: compact orthohyperkeratosis Electron microscopy: absence of lamellar bodies Prenatal diagnosis by fetal skin biopsy at 20–22 weeks’ gestation

Differential diagnosis • Collodion membrane Treatment • Oral retinoids (e.g. isotretinoin, acetretin) within a few days of birth has increased survival in a few patients • Topical keratolytic agents • Moisturize skin with emollients immediately after bathing and frequently through the day • Ophthalmology consultation – important to open eyes to prevent blindness • Management of fluid and electrolytes

Gunes T, Akcakus M, Kurtoglu S, et al. Harlequin baby with ecthyma gangrenosum. Pediatr Dermatol 2003; 20: 529–30 Prasad RS, Pejaver RK, Hassan A, et al. Management and follow-up of harlequin siblings. Br J Derm 1994: 130; 650–3 Singh S, Bhura M, Maheshwari A, et al. Successful treatment of harlequin ichthyosis with acetretin. Int J Dermatol 2001; 40: 472–3 Zeeuwen PL, Dale BA, de Jongh GJ, et al. The human cystatin M/E gene (CST6): exclusion candidate gene for harlequin ichthyosis. J Invest Dermatol 2003; 121: 65–8

Conradi–Hünermann–Happle syndrome Synonym: X-linked dominant chondrodysplasia punctata Major points • Thick scaling in whorl-like pattern (early) following Blaschko lines which clears in 3–6 months, followed by follicular atrophoderma (Figure 20.8) • Asymmetrical, calcific, epiphyseal stippling by X-ray in newborn • Unusual facies: flat facies with depressed nasal bridge • Joint contractures • Kyphoscoliosis • Patchy, scarring alopecia • Dry, lusterless hair

Prognosis • Very poor, despite treatment • Most die perinatally from sepsis or massive hyperkeratotic plaques interfering with respiration and feeding • Survivors shed restrictive scale and develop severe congenital ichthyosiform erythroderma (CIE) phenotype References Chan Y-C, Tay Y-K, Tan L K-S, et al. Harlequin ichthyosis in association with hypothyroidism and juvenile rheumatoid arthritis. Pediatr Dermatol 2003; 20: 421–6 Culican SM, Custer PL. Repair of cicatricial ectropion in an infant with harlequin ichthyosis using engineered human skin. Am J Ophthalmol 2002; 134: 442–3 Fleckman P, Hager B, Dale BA. Harlequin ichthyosis keratinocytes in lifted culture differentiate poorly by morphologic and biochemical criteria. J Invest Dermatol 1997; 109: 36–8

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Figure 20.8 Conradi–Hünermann syndrome – hyperkeratotic streaks following Blaschko lines

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Shortening of humeri and femurs Asymmetrical skeletal deformities Lens opacities, other eye problems Normal mentation X-linked dominant (seen in girls), or autosomal dominant

Pathogenesis

• Gene locus: Xp11.22-p11.23 • Gene: delta (8)–delta (7) sterol isomerase (emopamil-binding protein)

• Mosaic disorder Diagnosis

• Clinical presentation • Genetic testing Differential diagnosis

• Epidermolytic hyperkeratosis • Goltz syndrome • Other ichthyoses Treatment

• Topical keratolytic agents • Moisturize skin with emollients immediately after bathing and frequently through the day

• Increase ambient humidity Prognosis

• Scaling resolves by 12 months, but other features persist References Braverman N, Lin P, Moebius FF, et al. Mutations in the gene encoding 3-beta-hydroxysteroid-delta(8),delta(7)isomerase cause X-linked dominant Conradi–Hunermann syndrome. Nature Genet 1999; 22: 291–4 Bruch D, Megahed M, Majewski F, Ruzicka T. Ichthyotic and psoriasiform skin lesions along Blaschko’s lines in a woman with X-linked dominant chondrodysplasia punctata. J Am Acad Dermatol 1995; 33: 356–60 Corbí MR, Conejo-Mir JS, Linares M, et al. Conradi–Hünermann syndrome with unilateral distribution. Pediatr Dermatol 1998; 15: 299–303 Milunsky JM, Maher TA, Metzenberg AB. Molecular, biochemical, and phenotypic analysis of a hemizygous male with a severe atypical phenotype for X-linked dominant Conradi–Hunermann–Happle syndrome and a mutation in EBP. Am J Med Genet 2003; 116A: 249–54

Offiah AC, Mansour S, Jeffrey I, et al. Greenberg dysplasia (HEM) and lethal X linked dominant Conradi–Hunermann chondrodysplasia punctata (CDPX2): presentation of two cases with overlapping phenotype. J Med Genet 2003; 40: 129 Wessels MW, Den Hollander NJ, De Krijger RR, et al. Fetus with an unusual form of nonrhizomelic chondrodysplasia punctata: case report and review. Am J Med Genet 2003; 120A: 97–104 Yanagihara M, Ueda K, Asano N, et al. Usefulness of histopathologic examination of thick scales in the diagnosis of X-linked dominant chondrodysplasia punctata (Happle). Pediatr Dermatol 1996; 13: 1–4

PALMOPLANTAR KERATODERMAS Major points • Characteristic thickening of the palms and soles (Figure 20.9) • Three major patterns: diffuse, focal or punctuate (Figure 20.10) • Can be inherited (autosomal or recessive) or acquired • Can be associated with ichthyoses or other abnormalities • Associated syndromes: Unna–Thost syndrome, Vohwinkel syndrome, pachyonychia congenita, tyrosinemia type II, epidermolytic hyperkeratosis, hidrotic ectodermal dysplasia, and other dermatoses such as psoriasis, atopic dermatitis, etc. Pathogenesis • Abnormalities of keratin 1, 9, 16, connexin 26, loricrin, desmoplakin, others Diagnosis • Clinical features Treatment • Salicylic acid 4–6% in petrolatum (watch for salicylism) • Mechanical debridement • Oral retinoids have variable effect Prognosis • Persistent, can be progressive References Kimyai-Asadi A, Kotcher LB, Jih MH. The molecular basis of hereditary palmoplantar keratodermas. J Am Acad Dermatol 2002; 47: 327–43

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Whittock NV, Ashton GHS, Dopping-Hepenstal PJC, Gratian MJ. Striate palmoplantar keratoderma resulting from desmoplakin haploinsufficiency. J Invest Deramtol 1999; 113: 940–6 Yan AC, Aasi SZ, Alms WJ, et al. Aquagenic palmoplantar keratoderma. J Am Acad Dermatol 2001; 44: 696–9

OTHER GENODERMATOSES Neurofibromatosis Major points Figure 20.9 Palmoplantar keratoderma with yellow thickened plaques

Figure 20.10

• Neurofibromatosis type 1 (von Recklinghausen disease) 1. Incidence 1 : 3500 of the general population 2. Characterized by multiple café au lait macules and neurofibromas in the skin, CNS, bones, muscles and endocrine system 3. Diagnostic criteria (must have two for diagnosis) a. ≥6 café au lait macules which are >5 mm (before puberty) and >1.5 cm (after puberty) (Figure 20.11) b. Axillary freckling (Crowe sign) (Figure 20.12) c. ≥2 Lisch nodules (iris hamartomas) d. Distinctive osseous lesion such as sphenoid dysplasia or thinning of long bone cortex with or without pseudarthrosis e. Optic glioma f. ≥2 neurofibromas or a plexiform neurofibroma (large doughy mass with or without underlying limb hypertrophy which may be present at birth) (Figures 20.13 and 20.14)

Punctate palmoplantar keratoderma

McGrath JA, Eady RA. Recent advances in the molecular basis of inherited skin diseases. Adv Genet 2001; 43: 1–32 McLean WH. Epithelial Genetics Group. Genetic disorders of palm skin and nail. J Anat 2003; 202: 133–41 Paller AS. The molecular basis for the palmoplantar keratodermas. Pediatr Dermatol 1999; 16: 483–5 Richard G. Connexin disorders of the skin. Adv Dermatol 2001; 17: 243–77 Smith F. The molecular genetics of keratin disorders. Am J Clin Dermatol 2003; 4: 347–64

Figure 20.11

Neurofibromatosis – café au lait macules

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Figure 20.12 Neurofibromatosis – Crowe sign with freckling on neck or axillae

g. First-degree relative with neurofibromatosis type 1 4. Neurologic: learning disorders, mental retardation, seizures, intracranial tumors 5. Ophthalmic: Lisch nodules, proptosis, ptosis, optic gliomas, congenital glaucoma 6. Skeletal: scoliosis, kyphosis, pseudarthrosis, macrocephaly, scalloping of vertebrae, short stature 7. Endocrine abnormalities: sexual precocity 8. Other associations: pheochromocytoma, Wilms tumor, leukemia and other malignancies 9. Autosomal dominant with 50% spontaneous mutations Neurofibromatosis type 2 1. Acoustic neuromas of the eighth cranial nerve (90% bilateral) 2. Multiple CNS tumors (various types) 3. Few café au lait macules or neurofibromas 4. No axillary freckling 5. No iris hamartomas (Lisch nodules) 6. Autosomal dominant

Pathogenesis • Neurofibromas are caused by loss of a tumor suppressor gene with uncontrolled growth of tissues • Neurofibromatosis type 1 1. Gene locus: chromosome 17q11.2 2. Gene: neurofibromin, a protein that acts as a negative feedback control for the ras protooncogene (tumor suppressor gene) • Neurofibromatosis type 2 1. Gene locus: 22q12.2

Figure 20.13 Neurofibromatosis – plexiform neurofibroma on chin; also note the café au lait macules on the neck

Figure 20.14 Neurofibromatosis – numerous neurofibromas in an adult

2. Gene: NF2, merlin (Moesin, Ezrin, RadixinLike proteIN) Diagnosis

• See Major points

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Differential diagnosis

• Neurofibromas:

1. Lipomas 2. Epidermal cysts 3. Intradermal nevi 4. Anetoderma Café au lait macules: 1. McCune–Albright syndrome 2. Watson syndrome 3. Bannayan–Riley–Ruvalcaba syndrome 4. Epidermal nevus syndrome 5. Proteus syndrome

Treatment

• Annual visits (more frequent, as indicated) with a clinician familiar with neurofibromatosis type 1

• Patients should be followed for complications:

• • •

optic glioma, neural tumors, developmental disabilities, vascular problems, elevated blood pressure, orthopedic problems, malignancy, psychological problems Surgical excision of neurofibromas that are rapidly growing or painful Genetic testing is not routine or necessary in the majority of patients Specific treatment geared to specific complications

Prognosis

• Type 1: progressive and variable; may be an •

increase in complications around puberty or pregnancy Type 2: deafness usually in adulthood

References Ablon J. Parents’ responses to their child’s diagnosis of neurofibromatosis 1. Am J Med Genet 2000; 93: 136–42 Dasgupta B, Gutmann DH. Neurofibromatosis 1: closing the GAP between mice and men. Curr Opin Genet Dev 2003; 13: 20–7 DeBella K, Szudek J, Friedman JM. Use of the National Institutes of Health criteria for diagnosis of neurofibromatosis 1 in children. Pediatrics 2000; 105: 608–14 Dugoff L, Sujansky E. Neurofibromatosis type 1 and pregnancy. Am J Med Genet 1996; 66: 7–10 Drappier J-C, Khosrotehrani K, Zeller J, et al. Medical management of neurofibromatosis 1: a cross-sectional study of 383 patients. J Am Acad Dermatol 2003; 49: 440–4

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Gutmann D, Aylsworth A, Carley J, et al. The diagnostic evaluation and multidisciplinary management of neurofibromatosis 1 and neurofibromatosis 2. J Am Med Assoc 1997; 278: 51–7 Evans DGR, Trueman L, Wallace A, et al. Genotype/phototype correlations in type 2 neurofibromatosis (NF2): evidence for more severe disease associated with truncating mutations. J Med Genet 1998; 35: 450–5 Goldberg Y, Dibbern K, Klein J, et al. Neurofibromatosis type 1 – an update and review for the primary pediatrician. Clin Pediatr 1996; 35: 545–61 Johnson NS, Saal HM, Lovell AM, Schorry EK. Social and emotional problems in children with neurofibromatosis type 1: evidence and proposed interventions. J Pediatr 1999; 134: 767–72 Kandt RS. Tuberous sclerosis complex and neurofibromatosis type 1: the two most common neurocutaneous diseases. Neurol Clin 2003; 21: 983–1004 McLaughlin ME, Jacks T. Neurofibromatosis type 1. Methods Mol Biol 2003; 222: 223–37 Task Force: Eichenfield LF, Levy ML, Paller AS, Riccardi VM. Guidelines of care for neurofibromatosis type 1. Academy guidelines. J Am Acad Dermatol 1997; 37: 625–30 Van Es S, North KN, McHugh K, De Silva M. MRI findings in children with neurofibromatosis type 1: a prospective study. Pediatr Radiol 1996; 26: 478–87

Tuberous sclerosis complex Synonym: Bourneville disease Major points

• Incidence: 5 per 100 000 • Characterized by a triad of features (commonly, only one or two of these classic features is present): 1. Adenoma sebaceum (angiofibromas) (>50%) a. Begins at ages 2–5 years as pink/red small papules on the cheeks and nasolabial folds and they enlarge slowly over time 2. Mental retardation in 30–65%; ranges from mild to severe 3. Seizures or infantile spasms (80%) Pathogenesis

• Gene locus/gene: 1. TSC-1, 9q34/ hamartin (tumor suppressor gene)

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2. TSC-2, 16p.13.3/ tuberin (GAP protein)

• 50–75% of cases are sporadic Diagnosis • Diagnostic criteria (see Table 20.1) • Examination with a Wood’s light can aid in the visualization of the hypopigmented macules in light-skinned individuals • Examination of family members • Histology (angiofibroma): dermal fibrosis and vasodilatation • Histology (shagreen patch): increased collagen and elastin • MRI can demonstrate CNS hamartomas Differential diagnosis • Facial lesions 1. Acne 2. Milia 3. Trichoepitheliomas 4. Molluscum contagiosum 5. Seborrheic dermatitis • Hypopigmented macules 1. Vitiligo 2. Nevus depigmentosus 3. Pityriasis alba 4. Hypomelanosis of Ito 5. Nevus anemicus 6. Postinflammatory hypopigmentation 7. Tinea versicolor • Periungual fibromas 1. Warts 2. Infantile digital fibromatosis Treatment • Hypopigmented macules – none needed • Adenoma sebaceum: CO2 laser or other destructive therapy • Close follow-up by pediatrician and specialists as indicated Prognosis • Variable • Some patients have severe CNS difficulties, some have severe development of angiofibromas, others have only minor stigmata of the disease and are only diagnosed when a family member is diagnosed • Hypopigmented lesions are static, or become less obvious with time

Table 20.1 Diagnostic criteria for tuberous sclerosis (TSC)

Definite TSC: either one primary feature, two secondary features or one secondary plus two tertiary features Probable TSC: either one secondary plus one tertiary feature or three tertiary features Suspect TSC: either one secondary feature or two tertiary features Primary features Facial angiofibromas (adenoma sebaceum) Multiple ungual fibromas Cortical tuber (histologically confirmed) Subependymal nodule or giant cell astrocytoma (histologically confirmed) Multiple calcified subependymal nodules protruding into the ventricle (radiographic evidence) Multiple retinal astrocytomas Secondary features Affected first-degree relative Cardiac rhabdomyomas (histologic or radiographic confirmation), often multiple Retinal hamartoma or achromic patch Cerebral tubers (radiographic confirmation) Noncalcified subependymal nodules (radiographic confirmation) Shagreen patch (connective tissue nevus) – most common in lumbar area (Figure 20.15) Forehead plaque (angiofibromas) Renal angiomyolipoma (radiographic or histologic confirmation) Renal cysts (histologic confirmation) Pulmonary lymphangioleiomyomatosis (histology required) Tertiary features Hypomelanotic macules/poliosis (white patches of hair) (Figure 20.16) Confetti skin lesions Renal cysts (radiographic evidence) Randomly distributed enamel pits in teeth Hamartomatous rectal polyps (histologic confirmation) Bone cysts (radiographic evidence) Pulmonary lymphangioleiomyomatosis (radiographic evidence) Cerebral white matter ‘migration tracts’ o heterotopias (radiographic evidence) Gingival fibroma Hamartoma of the other organs (histologic confirmation) Infantile spasms Continued...

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Table 20.1

Continued

Other findings Pneumothorax Diffuse bronzing Retinal gliomas Optic atrophy Mental retardation Seizures

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References Dahan D, Fenichel GM, El-Said R. Neurocutaneous syndromes. Adolesc Med State Art Rev 2002; 13: 495–509 Kandt RS. Tuberous sclerosis complex and neurofibromatosis type 1: the two most common neurocutaneous diseases. Neurol Clin 2002; 20: 941–64 Kwiatkowski DJ. Tuberous sclerosis: from tubers to mTOR. Ann Hum Genet 2003; 67: 87–96 Narayanan V. Tuberous sclerosis complex: genetics to pathogenesis. Pediatr Neurol 2003; 29: 404–9 Tsao H. Update on familial cancer syndromes and the skin. J Am Acad Dermatol 2000; 42: 939–69 Vanderhooft SL, Francis JS, Pagon RA, et al. Prevalence of hypopigmented macules in a healthy population. J Pediatr 1996; 129: 355–61 Zuvlunov A, Esterly NB. Neurocutaneous syndromes associated with pigmentary skin lesions. J Am Acad Dermatol 1995; 32: 915–35

Basal cell nevus syndrome

Figure 20.15 lower back

Tuberous sclerosis – shagreen patch on

Synonyms: nevoid basal cell carcinoma syndrome, Gorlin syndrome Major points

• Multiple basal cell carcinomas at an early age (Figure 20.17)

• Palmoplantar pits • Multiple jaw cysts (odontogenic keratocysts) with malignant potential

• Skeletal abnormalities

Figure 20.16 macules

Tuberous sclerosis – hypopigmented

• • • • • • •

1. Spina bifida occulta 2. Rib anomalies (splayed, bifid, fused, missing, etc.) 3. Scoliosis 4. Short fourth metacarpals 5. Mandibular prognathism 6. Vertebral anomalies 7. Pectus excavatum Hypertelorism Medulloblastoma Mental retardation Calcification of the falx cerebri Agenesis of the corpus callosum Frontal bossing Autosomal dominant

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References Barbagallo JS, Kolodzieh MS, Silverberg NB, Weinberg JM. Neurocutaneous disorders. Dermatol Clin 2002; 20: 547–60, viii Boutet N, Bignon Y-J, Drouin-Garraud V, et al. Spectrum of PTCH1 mutations in French patients with Gorlin syndrome. J Invest Dermatol 2003; 121: 478–81 Kulkarni P, Brashear R, Chuang TY. Nevoid basal cell carcinoma syndrome in a person with dark skin. J Am Acad Dermatol 2003; 49: 332–5 LeSueur BW, Silvis NG, Hansen RC. Basal cell carcinoma in children: report of 3 cases. Arch Dermatol 2000; 136: 370–2 Turner MB, Mallory SB. Nevoid basal cell carcinoma syndrome. Curr Opin Dermatol 1997; 4: 162–7

Figure 20.17 Basal cell nevus syndrome – with basal cell carcinoma resembling a nevus

EHLERS–DANLOS SYNDROME Synonym: cutis hyperelastica

Pathogenesis

Major points

• Gene locus: 9q22.3, 9q31 • Gene: PTC1 (patched gene) (PTC protein binds

• Ehlers–Danlos syndrome I. Gravis type (classic,

and inhibits transmembrane protein SMOOTHENED (SMO) Histology: similar to ordinary basal cell carcinomas

Diagnosis • Clinical features • X-rays looking for skeletal abnormalities and odontogenic keratocysts • Biopsy of suspicious lesion

Differential diagnosis • Melanocytic nevus • See Table 17.2 Therapy • Careful periodic evaluation to assess development of basal cell carcinoma and other abnormalities • Radiotherapy should be avoided • Removal of growing lesions • Sun avoidance, sunscreens • Genetic counseling Prognosis • Slow progression of basal cell carcinomas, jaw cysts • Depends upon behavior of tumors

severe): skin fragility and hyperextensibility; soft, velvety skin; joint hypermobility; easily bruised skin; atrophic scars; varicose veins (Figure 20.18) 1. Autosomal dominant 2. Biochemical defect: COL5A1, or COL5A2, or COL1A1 3. Gene locus: 2q31, 17q21.31-q22, 9q34.2-q34.3 Ehlers–Danlos syndrome II. Mitis type (classic, mild): similar to type I, but less severe; easily bruised skin; floppy mitral valve; absence of inferior labial frenulum and lingual frenulum 1. Autosomal dominant 2. Biochemical defect: COL5A1, COL5A2 3. Gene locus: 9q34.2-q34.3 Ehlers–Danlos syndrome III. Hypermobile type: large and small joint hypermobility (marked) and dislocations; soft skin 1. Autosomal dominant 2. Biochemical defect: COL3A1 and tenascin-XB 3. Gene locus: 2q31 Ehlers–Danlos syndrome IV. Vascular type: arterial, bowel and uterine rupture; marked skin fragility with thin, translucent skin; easily bruised skin; absence of skin and joint extensibility; tendency to form keloids; characteristic facial

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1. Autosomal dominant 2. Biochemical defect unknown Ehlers–Danlos syndrome X. Fibronectin type: similar to EDS type II; striae distensae; prominent bruising; abnormal clotting studies; normal skin texture 1. Autosomal recessive 2. Biochemical defect: fibronectin-1 3. Gene locus: 2q34

Diagnosis • Clinical presentation • Genetic testing • Histology: large, irregular collagen fibrils in Ehlers–Danlos syndrome types I, II, III

Figure 20.18 from scars

Ehlers–Danlos syndrome – pseudotumors

appearance with parchment-like skin and very thin nose; reduced life expectancy 1. Autosomal dominant or autosomal recessive 2. Biochemical defect: abnormal type III collagen (COL 3A1) 3. Gene locus: 2q31 Ehlers–Danlos syndrome V. X-linked type: similar to EDS type II 1. X-linked recessive 2. Biochemical defect unknown Ehlers–Danlos syndrome VI. Ocular-scoliotic type: marked joint and skin involvement; scleral and corneal fragility; keratoconus; intraocular hemorrhage; scoliosis; hypotonia; arterial rupture 1. Autosomal recessive 2. Biochemical defect: lysyl hydroxylase 3. Gene locus: 1p36.3-p36.2 Ehlers–Danlos syndrome VII. Arthrochalsis multiplex congenita type: extreme joint hypermobility with congenital hip dislocation; short stature; excessive, soft skin particularly on the limbs; normal scarring; micrognathia 1. Autosomal recessive 2. Biochemical defect: COL1A1, COL1A2 3. Gene locus: 17q21.31-q22, 7q22.1 Ehlers–Danlos syndrome VIII. Periodontal type; moderate joint and skin involvement; periodontitis, gingival regression, tooth loss

Differential diagnosis • Cutis laxa • Normal hypermobility Treatment • Protection against injury to skin and joints • Orthopedic management with physical therapy and braces if needed Prognosis • Depends upon type • Stable or worsens with injury • Vascular type (Ehlers–Danlos syndrome type IV) has a guarded prognosis, because of vascular or bowel rupture References Beighton P. The Ehlers–Danlos syndrome. McKusick’s Heritable Disorders of Connective Tissue. Mosby–Year Book: St Louis. MO 1993: 189–251 Byers PH. Ehlers–Danlos syndrome: recent advances and current understanding of the clinical and genetic heterogeneity. J Invest Dermatol 1994; 103: 47S–52S Byers PH. Ehlers–Danlos syndrome type IV: a genetic disorder in many guises. J Invest Dermatol 1995; 105: 311–13 Dahan D, Fenichel GM, El-Said R. Neurocutaneous syndromes. Adolesc Med State Art Rev 2002; 13: 495–509 Germain DP. Clinical and genetic features of vascular Ehlers–Danlos syndrome. Ann Vasc Surg 2002; 16: 391–7 Henry F, Goffin V, Piérard-Franchimont C, Piérard GE. Mechanical properties of skin in Ehlers–Danlos syndrome, types I, II, and III. Pediatr Dermatol 1996; 13: 464–7 Mao JR, Bristow J. The Ehlers–Danlos syndrome: on beyond collagens. J Clin Invest 2001; 107: 1063–9

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Myllyharju J, Kivirikko KI. Collagens and collagen-related diseases. Ann Med 2001; 33: 7–21 Sidhu-Malik NK, Wenstrup RJ. The Ehlers–Danlos syndromes and Marfan syndrome: inherited diseases of connective tissue with overlapping clinical features. Semin Dermatol 1995; 14: 40–6

Prognosis

Cutis laxa

Baldwin L, Kumrah L, Thoppuram P, Bhattacharji S. Congenital cutis laxa (dermatochalasia) with cardiac valvular disease. Pediatr Dermatol 2001; 18: 365–6

Major points

• Skin hangs in loose folds from birth or may

develop during childhood or adolescence and becomes inelastic giving a ‘hound dog’ appearance Generalized elastic tissue abnormality predisposing to: 1. Inguinal hernias 2. Lax joints 3. Bronchiectasis with pulmonary emphysema 4. Mitral valve prolapse 5. Aortic aneurysm 6. Gastrointestinal diverticula 7. Prolapse of the rectum or uterus 8. Bladder or urinary tract diverticula

Pathogenesis • Autosomal dominant (milder) – usually involves skin only • Mutations in elastin (ELN) or fibulin-5 (FBLN5) • Gene 14q32.1, 5q23.3-q31.2 • Autosomal recessive (severe): mutation in fibulin-5 (FBLN5) gene Diagnosis • Clinical presentation • Histology: marked fragmentation or diminution of elastic fibers Differential diagnosis • Ehlers–Danlos syndrome • Beare–Stevenson syndrome • Costello syndrome • Michelin tire baby syndrome • Marfan syndrome • Menkes kinky hair syndrome Treatment

• None specific • Surgery for cosmesis

• Slowly progressive References Andiran N, Sarikayalar F, Saraclar M, Caglar M. Autosomal recessive form of congenital cutis laxa: more than the clinical appearance. Pediatr Dermatol 2002; 19: 412–14

Banks ND, Redett RJ, Mofid MZ, Manson PN. Cutis laxa: clinical experience and outcomes. Plast Reconstruct Surg 2003; 111: 2434–42 Hwang ST, Williams ML, McCalmont TH, Frieden IJ. Sweet’s syndrome leading to acquired cutis laxa (Marshall’s syndrome) in an infant with a1-antitrypsin deficiency. Arch Dermatol 1995; 131: 1175–7 Orlow SJ. Cutaneous findings in craniofacial malformation syndromes. Arch Dermatol 1992; 128: 1379–86 Sarkar R, Kaur C, Kanwar AJ, Basu S. Cutis laxa in seven members of a north-Indian family. Pediatr Dermatol 2002; 19: 229–31

Pseudoxanthoma elasticum Major points

• Xanthoma-like papules (‘plucked chicken’

• • • • • • • • • • • •

appearance) found in flexural areas and neck which thicken with age; other areas periumbilical, antecubital fossae, wrists, popliteal fossae Small (1–3 mm) yellowish papules in a linear or reticular pattern, may be in confluent plaques (Figure 20.19) Perforating lesions with hyperkeratosis (e.g. elastosis perforans serpiginosa) Abnormal elastic tissue in arteries Hyperextensible skin and joints Marfanoid features Hypertension Cerebrovascular accidents Gastrointestinal hemorrhages caused by cracking of calcified vessels Cardiovascular disease Arteriosclerosis Myocardial infarction (can be seen in teenagers) Ocular abnormalities: 1. Angioid streaks in retina (breaks in Bruch membrane)

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Prognosis • Depends upon type of psudeoxanthoma elasticum; some have more severe internal involvement than others References

Figure 20.19 Pseudoxanthoma elasticum – firm, yellow papules on the sides of the neck as a presenting sign

2. Loss of vision, drusen, peau d’orange or maculopathy Autosomal dominant or recessive

Pathogenesis • Aberrant calcification of elastic fibers • Gene locus: 16p13.1 • Gene: ABCC6 (ATP-binding cassette) Diagnosis

• Major criteria

1. Characteristic skin involvement 2. Histology: fragmented elastic tissue, clumped with calcium deposits demonstrated by von Kossa stain; calcification in vessels involving elastic media and intima 3. Characteristic ocular disease Minor criteria 1. Characteristic histologic features of nonlesional skin 2. Family history of pseudoxanthoma elasticum in first-degree relative

Differential diagnosis • Xanthomas • Connective tissue nevus • D-Penicillamine-induced skin lesions Treatment • Close observation for gastrointestinal hemorrhage and cardiovascular abnormalities • Surgical excision of abnormal skin rarely indicated • Possible restriction of calcium in childhood and adolescence

Balus L, Amantea A, Donati P, et al. Fibroelastolytic papulosis of the neck: a report of 20 cases. Br J Dermatol 1997; 137: 461–6 Hacker SM, Ramos-Caro FA, Beers BB, Flowers FP. Juvenile pseudoxanthoma elasticum: recognition and management. Pediatr Dermatol 1993; 10: 19–25 Lebwohl M, Halperin J, Phelps RG. Brief report: occult pseudoxanthoma elasticum in patients with premature cardiovascular disease. N Engl J Med 1993; 329: 1237–9 Lebwohl M, Neldner K, Pope M, et al. Classification of pseudoxanthoma elasticum: report of a consensus conference. J Am Acad Dermatol 1994; 30: 103–7 Le Saux O, Urban Z, Tschuch C, et al. Mutations in a gene encoding an ABC transporter cause pseudoxanthoma elasticum. Nature Genet 2000; 25: 223–7 Ohtani T, Furukawa F. Pseudoxanthoma elasticum. J Dermatol 2002; 29: 615–20 Uitto J, Pulkkinen L, Ringpfeil F. Progress in molecular genetics of heritable skin diseases: the paradigms of epidermolysis bullosa and pseudoxanthoma elasticum. J Invest Dermatol Symp Proc 2002; 7: 6–16

Gardner syndrome Major points • Multiple gastrointestinal polyps (mainly colon) with 100% risk for adenocarcinoma (adolescence to adulthood) • Osteomas - especially of mandible, maxilla and facial bones • Epidermal cysts – typical, multiple or large • Desmoid tumors – most often occur at sites of scars (25%) • Fibromas (skin, subcutaneous tissues, mesentery) • Congenital hypertrophy of retinal pigment epithelium – bilateral dark brown patches on fundoscopy • Autosomal dominant with 100% penetrance Pathogenesis • Gene locus: chromosome 5q21-q22 • Gene: APC gene (adenomatous polyposis coli) – a tumor suppressor gene

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Diagnosis

Major points

• Histology of polyps – adenomatous type • Histology of epithelial cysts: lined with epithelial

• Can present in childhood with craniomegaly • Multiple hamartomas of ectodermal, endodermal,

cells Differential diagnosis

• • • • •

Familial polyposis Peutz–Jeghers syndrome Cowden syndrome Common epidermal cysts Bannayan–Riley–Ruvalcaba syndrome

• • • • •

Treatment

• Screening should begin at age 5 years for polyps in • • •

family members Prophylactic colectomy in teens is recommended Surveillance for secondary findings by physician familiar with the disorder Desmoid tumors – suggest excision; 50% recurrence rate; sulindac has been reported to result in regression in some patients

Prognosis 1. Poor if colon not removed before cancer begins References Armstrong JG, Davies DR, Guy SP, et al. APC mutations in familial adenomatous polyposis families in the northwest of England. Hum Mutat 1997; 10: 376–80 Gregory B, Ho VC. Cutaneous manifestations of gastrointestinal disorders. Part I. J Am Acad Dermatol 1992; 26: 153–66 Herrmann SM, Adler YD, Schmidt-Petersen K, et al. The concomitant occurrence of multiple epidermal cysts, osteomas and thyroid gland nodules is not diagnostic for Gardner syndrome in the absence of intestinal polyposis: a clinical and genetic report. Br J Dermatol 2003; 149: 877–83 Parks ET, Caldemeyer KS, Mirowski GW. Gardner syndrome. J Am Acad Dermatol 2001; 45: 940–2 Quesnel S, Malkin D. Genetic predisposition to cancer and familial cancer syndromes. Pediatr Clin N Amer 1997; 44: 791–808 Rustigi AK. Hereditary gastrointestinal polyposis and nonpolyposis syndromes. N Engl J Med 1994; 331: 1694–702

and mesodermal origin Trichilemmomas (especially facial) Facial papules, often grouped around the mouth, nose or ears, usually evident by age 20 years Oral papillomatosis (cobblestoning); can be seen in esophagus and duodenum Palmoplantar keratoses Other findings (seen in teens/adults) 1. Strong association with malignancy of breast (33%) and thyroid (5%) 2. Fibrocystic disease of the breast and follicular adenocarcinoma of the breast in women (75%) 3. Thyroid adenoma or goiter (65%) 4. Gastrointestinal polyps in both large and small bowel 5. Ovarian, cervical and uterine cancer Autosomal dominant

Pathogenesis • Gene locus: 10q23.3 • Gene: PTEN – a tumor suppressor gene Diagnosis • Clinical findings • Histology: trichilemmomas which arise from outer root sheath; multiple biopsies may be necessary; keratoses show hyperkeratotic papillomas Differential diagnosis • Basal cell nevus syndrome • Neurofibromatosis • Gardner syndrome • Tuberous sclerosis Treatment

• Close observation for thyroid,breast and • •

gynecologic cancer in females; bladder cancer in males Surgical removal of facial papules Close follow-up with physician familiar with disorder

Cowden disease

Prognosis

Synonym: multiple hamartoma syndrome

• Depends upon complications

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References Eng C. PTEN: one gene, many syndromes. Hum Mutat 2003; 22: 183–98 Hanssen AMN, Fryns JP. Cowden syndrome. J Med Genet 1995; 32: 117–19 Hanssen AMN, Werquin H, Suys E, Fryns JP. Cowden syndrome: report of a large family with macrocephaly and increased severity of signs in subsequent generations. Clin Genet 1993; 44: 281–6 Lynch ED, Ostermeyer EA, Lee MK, et al. Inherited mutations in PTEN that are associated with breast cancer, Cowden disease, and juvenile polyposis. Am J Hum Genet 1997; 61: 1254–60 Marsh DJ, Kum JB, Lunetta KL, et al. PTEN mutation spectrum and genotype-phenotype correlations in Bannayan– Riley–Ruvalcaba syndrome suggest a single entity with Cowden syndrome. Hum Mol Genet 1999; 8: 1461–72 Marsh D, Zori R. Genetic insights into familial cancers– update and recent discoveries. Cancer Lett 2002; 181: 125–64 Tsao H. Update on familial cancer syndromes and the skin. J Am Acad Dermatol 2000; 42: 939–69 Waite KA, Eng C. From developmental disorder to heritable cancer: it’s all in the BMP/TGF-beta family. Nature Rev Genet 2003; 4: 763–73 Waite KA, Eng C. Protean PTEN: form and function. Am J Hum Genet 2002; 70: 829–44

387

• Frequent sinopulmonary infections: bronchitis,

• • • • • •

rhinitis, pneumonia, bronchiectasis 1. Defective cell-mediated: lymphopenia, impaired lymphocyte transformation 2. Humoral immunity: IgA and IgE deficiency Ocular findings 1. Telangiectasias beginning about age 2–6 years on bulbar conjunctiva 2. Nystagmus 3. Strabismus 4. Blepharitis Structural anomalies of thymus and lymph nodes Elevated α-fetoprotein Progressive mental and neurological deterioration Breaks and rearrangements of chromosomes particularly 7, 14 High incidence of neoplastic disorders (e.g. lymphoma, leukemia, breast carcinomas, etc.) in patients and carriers Autosomal recessive; male/female ratio = 1

Pathogenesis

• Caused by a mutation in ATM gene which repairs chromosomal strand breakage

• Gene locus: 11q22 • Gene: ATM

Ataxia–telangiectasia Synomyn: Louis–Bar syndrome Major points

• Progressive cerebellar ataxia beginning at age ~2 years

• Skin findings 1. Telangiectasias begin on ears, conjunctiva and flexural folds of extremities usually at about 3–5 years, and progress to malar areas and the V of the chest (Figure 20.20) 2. Granulomatous plaques (sterile) 3. Vitiligo 4. Poliosis 5. Premature graying of hair 6. Hypo- or hyperpigmentation 7. Atrophy of the skin 8. Chronic skin infections 9. Acanthosis nigricans

Figure 20.20 Ataxia–telangiectasia – telangiectasias on the conjunctivae

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Diagnosis

• Clinical diagnosis with gene verification • Histology: nonspecific; dilated blood vessels of subpapillary plexus Differential diagnosis

• Hereditary hemorrhagic telangiectasia • Angioma serpiginosum • Generalized essential telangiectasia Treatment

• Supportive, with antibiotics, respiratory therapy, •

physical therapy Genetic counseling

Prognosis

Figure 20.21 Darier disease – scaling on the face resembling seborrheic dermatitis

• Usually fatal in second decade from secondary infections, respiratory failure, or malignancies

• Mucous membranes: white cobblestoning which

References Barbagallo JS, Kolodzieh MS, Silverberg NB, Weinberg JM. Neurocutaneous disorders. Dermatol Clin 2002; 20: 547–60, viii De la Torre C, Pincheira J, Lopez-Saez JF. Human syndromes with genomic instability and multiprotein machines that repair DNA double-strand breaks. Histol Histopathol 2003; 18: 225–43 Koenig M. Rare forms of autosomal recessive neurodegenerative ataxia. Semin Pediatr Neurol 2003; 10: 183–92 Perlman S, Becker-Catania S, Gatti RA. Ataxia–telangiectasia: diagnosis and treatment. Semin Pediatr Neurol 2003; 10: 173–82 Swift M, Morrell D, Massey RB, Chase CL. Incidence of cancer in 161 families affected by ataxia – telangiectasia. N Engl J Med 1991; 325:1831–6

• • • • •

Pathogenesis

• Gene locus: 12q23-24.1 • Gene: SERCA 2 (ATP 2A2) – plays a role in cell adhesion Diagnosis

• Clinical findings with classic histology of skin • Histology: suprabasal acantholysis and dyskeratosis; characteristic corps ronds and corps grains in stratum corneum

Darier disease Synomyn: keratosis follicularis, Darier–White disease Major points

• Firm greasy, yellow-brown, crusted papules which coalesce into plaques (Figure 20.21)

• Distribution: scalp, face, seborrheic and flexural areas, dorsa of hands and feet

• Palm and sole keratoses or minute pits • Malodorous • Onset usually between 8 and 15 years

coalesces into plaques; oropharynx, larynx and anorectal mucosa may be involved Nail changes: white or red longitudinal bands, V-shaped nicks at distal margin, subungual hyperkeratoses T-cell abnormalities in some patients Increased susceptibility to infections Mental disturbances or mild retardation Autosomal dominant, with male/female ratio >1

Differential diagnosis

• • • •

Seborrhea Transient acantholytic dermatosis Pemphigus foliaceus Hailey–Hailey disease

Treatment

• Emollients • Keratolytic agents

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• Intermittent topical steroids for erythema or irritation

• Topical retinoids • Systemic retinoids • Antibiotics for secondary infection Prognosis

• Persistent, chronic dermatosis with exacerbations and partial remissions

• Aggravated by sunlight and heat • Responds to oral retinoids References Burge SM, Wilkinson JD. Darier–White disease: a review of the clinical features in 163 patients. J Am Acad Dermatol 1992; 27: 40–50

389

Cooper SM, Burge SM. Darier’s disease: epidemiology, pathophysiology, and management. Am J Clin Dermatol 2003; 4: 97–105 Devries DT, Warren SJ. Recent advances in intraepidermal blistering diseases. Adv Dermatol 2002; 18: 203–45 Kennedy JL, Berg D, Bassett AS, et al. Genetic linkage for Darier disease (keratosis follicularis). Am J Med Genet 1995; 55: 307–10 Munro CS. The phenotype of Darier’s disease: penetrance and expressivity in adults and children. Br J Dermatol 1992; 127: 126–30 O’Malley MP, Haake A, Goldsmith L, Berg D. Localized Darier disease. Implications for genetic studies. Arch Dermatol 1997; 133: 1134–8 Peacocke M, Christiano AM. Bumps and pumps, SERCA 1999. Nature Genet 1999; 21: 252–3

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21 THERAPY

TOPICAL THERAPY Major points

• Treatment should be simple • Teach patients how to apply medications • Write prescriptions for steroids in sizes of tubes

• • •

• •

(e.g. 15, 30, 45, 60, 90, 120 g), not just ‘trade size’ 1. Patient may receive too little or too much medicine if not written correctly 2. Include the diagnosis in addition to instructions so that there is no confusion (e.g. ‘Apply at bedtime for acne’) Thin application is desirable for most medicines except emollients, where thick application is preferred Apply moisturizers to damp skin to retain hydration Estimates of coverage of the skin can be made by using the ‘Rule of Nines’, in which the body surface is divided into 11 equal parts, each constituting ~9% of the total body surface area 1. Head 2. Arm (one) 3. Chest (anterior) 4. Back 5. Abdomen 6. Buttocks, lumbar area 7. Leg (half each) Each area can be covered by ~2 g of cream or ointment (See Table 21.1) Factors which increase percutaneous absorption of a medication: 1. Inflammation 2. Hydration (after a bath)

3. Occlusion with plastic wraps, or diapers 4. Epidermal breakage or injury 5. Heat 6. Type of vehicle Topical agents are composed of: active medication and vehicle

VEHICLES

• Vehicles have a profound impact on the medication’s delivery and stability

Table 21.1

Amount of medicine to dispense

Area

One application in grams

BID application for 2 weeks in grams

Face

2

60

Hands

2

60

Head

2

60

Groin

2

60

One arm

3

80

Anterior chest

3

80

Back

3

80

One leg

4

120

30–60

840–1680

Whole body

Adapted from Weston WL, Lane AT, Morelli JG. Color Textbook of Pediatric Dermatology. Mosby: St Louis, 1996: 358

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Ointments

• Indications:

• Simplest lubricating vehicle • Ointments are oleaginous pure greases (e.g. • •

• • •

petrolatum, lanolin) or greases with a small amount of water suspended in them Leave a greasy film on the skin, causing heat retention and water retention Indications: 1. Dry, cracked skin (atopic dermatitis) 2. Scaling (psoriasis) 3. Lubrication Do not use (as a general rule of thumb): 1. Moist skin areas (axillae, groin) 2. Hot humid environments Disadvantages: messy, stains clothing (e.g. petrolatum) Advantages: fewest inactive ingredients (i.e. fewer sensitizing agents)

1. Scalp 2. Hairy areas 3. Moist areas (toewebs) Do not use: 1. Broken skin (causes stinging) 2. Very dry skin

Lotions

• Lotions are mainly water with some lipids added • Indications: •

1. Mild dry skin 2. Moist folds Examples: Keri Lotion, Lubriderm, Eucerin Lotion, numerous others

Aerosols, sprays, and foams

• These products are solutions with a propellant Creams

• Emulsion of water and oil plus chemical • • • •

emulsifiers, preservatives and fragrances Creams require preservatives and stabilizers because of the addition of water Easier to use than ointments and cosmetically more acceptable Less occlusive than an ointment Indications: 1. Dry skin in humid climates 2. Semifold areas (antecubital area and neck) 3. Face Do not use: 1. Hairy scalp (in general) 2. If allergic or sensitive to preservatives in a specific product

Emollient creams

• Generally more oily than nonemollient types • Smooth application • More moisturizing than creams

• •

system Indications: 1. Scalp: with a small tubular applicator nozzle, aerosols are easy to use on the scalp 2. Body: can cover large areas with a very fine coat of medication (e.g. insect repellents) Advantages 1. Cosmetically elegant 2. Convenient, easy to use Disadvantages: may be drying and irritating

Gels

• Gelled propylene glycol solutions which liquify on • • • •

contact with skin Advantages: 1. Permit good penetration of medications 2. Leave little residue Disadvantage: very drying Indications: 1. Facial dermatoses 2. Scalp dermatoses Do not use on irritated or broken skin (causes stinging) Examples: tretinoin gel, steroid gels

Solutions

• Solutions contain alcohol and propylene glycol

Tape/plasters

with the active ingredient Completely evaporate, leaving the active medication on the skin

• Tape impregnated with medicament • Advantage

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Therapy

1. Stays in place

• Indications:

1. Thickened, pruritic plaques of lichen simplex chronicus 2. Warts Examples: Cordran tape, salicylic acid plasters

Shake lotions

• Liquid preparation to which powder has been • • • •

added Must be shaken to suspend the powder in solution Antipruritics (menthol, camphor) often added Examples: calamine lotion Indications: 1. Mild cooling and soothing effect 2. Weeping, oozing dermatitis (e.g. poison ivy dermatitis)

• Borderline oil-free products, although not technically oils or fats, can contain oil-like emollient esters which may be comedogenic

PRODUCTS AND TREATMENT Wet dressings

• Indications

• •

Pastes

• • • •

Creams or ointments with powder added Disadvantages: thick and stiff in consistency Indications: barrier cream Example: zinc oxide paste

393

1. Useful for first 24–72 hours of an acute weeping dermatitis 2. Evaporation of water is cooling, causing vasoconstriction 3. Relief of pruritus by increasing humidity 4. Helps remove crusts Examples: water, saline Examples: 1. Burow’s solution (aluminum acetate) for a more drying effect (e.g. Bluboro powder, Boropak powder, Domeboro powder or tablets) 2. Dakin’s solution (sodium hypochlorite) for antisepsis (strengths: 0.25%, 0.5%) 3. Oatmeal bathing products (e.g. Aveeno)

Topical corticosteroids

Powders

• Potency of topical steroids (Table 21.2) based on

• Consist of fine particles of talc • Indications:

• •

1. Increased surface area with a drying effect 2. Moist sweaty areas (axillae, groin, feet) 3. Reduce friction Examples: nystatin powder, Zeasorb AF Disadvantage: delivery of medication relatively poor

Oils

• Oily monophasic solution • Examples: mineral oil, Dermasmoothe Oil Oil-free products

• All avoid ingredients with the word ‘oil’; however, • •

may contain oils or fats which do not contain the word ‘oil’ (e.g. lanolin) May contain waxes or oily hydrocarbons Disadvantage: can be drying

vasocontriction assay, roughly corresponds to antiinflammatory properties Indications: inflammatory skin disorders (steroids cause vasoconstriction and prevent inflammation) 1. Low potency a. Ideal in infants b. Adults/teens – face, intertriginous, genitals 2. Mid-potency a. Atopic dermatitis b. Psoriasis 3. High potency/ultrapotency a. Palms and soles b. Psoriasis if thickened plaques c. Lichen simplex chronicus d. Acute contact dermatitis (e.g. poison ivy dermatitis) 4. High-potency and ultrapotency topical steroids should not be used in children except in short courses for specific conditions Dose: 1. Use a mid-strength steroid twice daily for 3–10 days until symptoms have subsided, then

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Table 21.2

Potency of topical steroids

Brand name Group I (ultrapotent) Cormax Ointment 0.05% Cormax Scalp Solution 0.05% Cordran Tape 4 µg/cm2 Diprolene Cream, Ointment, Gel 0.05% Olux Foam 0.05% Psorcon Ointment 0.05% Temovate Cream, Ointment, Gel, E Emollient Cream 0.05% Ultravate Cream, Ointment 0.05%

Generic name Clobetasol propionate Clobetasol propionate Flurandrenolide Betamethasone dipropionate Clobetasol propionate Diflorasone diacetate Clobetasol propionate Halobetasol propionate

Group II (potent) Cyclocort Ointment 0.1% Diprolene AF Cream 0.05% Diprosone Ointment 0.05% Elocon Ointment 0.1% Florone Ointment 0.05% Halog Cream, Oint., Sol., Emollient Cream 0.1% Kenalog Ointment 0.5% Lidex Cream, Gel, Ointment, Gel 0.05% Topicort Ointment, Cream 0.25% Topicort Gel 0.05%

Amcinonide Betamethasone dipropionate Betamethasone dipropionate Mometasone furoate Diflorasone diacetate Halcinonide Triamcinolone acetonide Fluocinonide Desoximetasone Desoximetasone

Group III (high mid-strength) Aristocort A Ointment 0.1% Aristocort-HP Ointment Cutivate Ointment 0.05% Cyclocort Cream and Lotion 0.1% Florone Cream 0.05% Halog Ointment 0.1% Lidex E Cream 0.05% Topicort LP Cream 0.05% Valisone Ointment 0.1%

Triamcinolone acetonide Triamcinolone acetonide Fluticasone propionate Amcinonide Diflorasone diacetate Halcinonide Fluocinonide Desoximetasone Betamethasone valerate

Group IV (middle mid-strength) Aristocort 0.1% Cream Cordran Ointment 0.05% Dermatop Ointment 0.1% Elocon Cream, Lotion 0.1% Kenalog Cream, Ointment 0.1% Luxiq Foam 0.12% Synalar Ointment 0.025% Westcort Ointment 0.2%

Triamcinolone acetonide Flurandrenolide Prednicarbate Mometasone furoate Triamcinolone acetonide Betamethasone valerate Fluocinolone acetonide Hydrocortisone valerate Continued...

reduce to once daily, eventually weaning off medication; emollients are often helpful 2. Face and groin: a. Only use low-potency steroids, class VI, VII (e.g. hydrocortisone 1–2.5%)

b. Prone to atrophy, striae and telangiectasias 3. Tachyphylaxis can occur with high-potency/ultrapotent steroids a. Caused by intense vasoconstriction, followed by rebound vasodilatation

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Table 21.2

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Continued

Brand name

Generic name

Group V (low mid-strength) Aclovate Cream, Ointment 0.05% Cordran Cream, Lotion 0.05% Cutivate Cream 0.05% Dermatop Cream 0.1% Kenolog Cream, Lotion 0.1% Locoid Cream, Ointment, Solution 0.1% Synalar Cream 0.025% Westcort Cream 0.2% Dermatop Cream 0.1%

Alclometasone dipropionate Flurandrenolide Fluticasone propionate Prednicarbate Triamcinolone acetonide Hydrocortisone butyrate Fluocinolone acetonide Hydrocortisone valerate Prednicarbate

Group VI (low strength) Aclovate Cream, Ointment 0.05% DesOwen Cream, Lotion, Ointment 0.05% Synalar Cream, Solution 0.01% Tridesilon Cream 0.05%

Alclometasone dipropionate Desonide Fluocinolone acetonide Desonide

Group VII (lowest strength) Hytone 0.5%, 1%, 2.5%, dexamethasone

Hydrocortisone 0.5%, 1%, 2.5%

b. Most commonly occurs on the face (causing perioral dermatitis or steroid rosacea) Monitor: 1. Adrenal axis suppression can occur with long-term or overuse of mid- or high-potency, or ultrapotent topical steroids 2. Limit total dosage to 30 is advised 2. Vehicle: determines whether sunscreen is waterproof, or water resistant 3. Reapply sunscreen especially after swimming or sweating 4. With the regular use of an SPF 15 sunscreen during the first 18 years of life, the lifetime incidence of nonmelanoma skin cancers has been estimated to be reduced by 78% 5. Contact dermatitis to sunscreens can be caused by either the chemical or the vehicle. Treat with topical steroids, or if severe, a short course of oral steroids (5–7 days) Ingredients in sunscreens: 1. Para-aminobenzoic acid (PABA) and PABA esters – partial UVB and no UVA protection

COMMONLY USED DRUGS IN DERMATOLOGY (Some of the indications are off-label – refer to Physician Desk Reference for indications)

Antihistamines

• Cetirizine (Zyrtec)

• •

1. Dose: 2–6 years: 2.5 mg daily; maximum 5 mg daily; >6 years: 5–10 mg daily 2. Supplied: 5 mg/5ml; 5 mg, 10 mg Clemastine (Tavist-1) 1. Dose: >6 years: 1–3 tsp BID 2. Supplied: 0.67 mg/5 ml, 1.34 mg (OTC), 2.68 mg (Rx) Cyproheptadine (Periactin) 1. Dose: 2–5 years: 2 mg BID–TID; 6–12 years: 4 mg BID–TID 2. Supplied: 4 mg, 2 mg/5 ml Desloratadine (Clarinex) 1. Dose: ≥12 years: 5 mg daily 2. Supplied: 5 mg Diphenhydramine (Benadryl) 1. Dose: 5 mg/kg per 24 hours PO, IV, IM given every 6–8 hours maximum 300 mg/24 hours 2. Supplied: 12.5 mg/5 ml, 25 mg, 50 mg Fexofenadine (Allegra) 1. Dose: 6–11 years: 30 mg BID; >12 years: 60 mg BID or 180 mg daily 2. Supplied: 30 mg, 60 mg, 180 mg Hydroxyzine (Atarax, Vistaril)

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1. Dose: 6 years 10–100 mg every 6 hours 2. Supplied: 10 mg/5 ml, 10 mg, 25 mg, 50 mg Loratadine (Claritin) 1. Dose: >5 years: 5–10 mg daily 2 Supplied: 5 mg/5 ml, 10 mg

Antibiotics

• Amoxicillin (Amoxil)

1. Dose: child: 20–40 mg/kg per 24 hours divided TID; Adult 250 mg TID 2. Supplied: 125 mg/5 ml, 250 mg/5 ml, 250 mg, 500 mg, 875 mg Ampicillin (Omnipen, Principen, Totacillin) 1. Dose: child: 50–100 mg/kg per 24 hours, given every 6 hours; adult 250–500 mg PO, IM, IV given every 6 hours 2. Supplied: 125 mg/5 ml, 250 mg/5 ml Augmentin (amoxicillin plus clavulanic acid) 1. Dose: child: 20–40 mg/kg per 24 hours, divided TID; adult: 250–500 mg BID–TID 2. Supplied: 200 mg/5 ml, 400 mg/5 ml, 250 mg, 500 mg Azithromycin (Zithromax) 1. Dose: child (6 months–12 years) 5–12 mg/kg per 24 hours; adult 500 mg daily once; then 250 mg daily for 4 days 2. Supplied: 100 mg/5 ml, 200 mg/5 ml, 100 mg, 250 mg; Z–Pak: 500 mg for 1 day, then 250 mg daily for 4 days; Tri-Pak: 500 mg daily for 3 days 3. Comments: take on empty stomach; hepatic excretion Cefaclor (Ceclor) 1. Dose: 20–40 mg/kg per 24 hours given TID, adult: 250–500 mg TID 2. Supplied: 125 mg/5 ml, 250 mg/5 ml, 250 mg, 500 mg Cefadroxil (Duricef ) 1. Dose: child: 30 mg/kg per 24 hours; give BID; adult: 500 mg BID 2. Supplied: 125 mg/5 ml, 250 mg/5 ml, 500 mg/5 ml, 500 mg, 1000 mg Cephalexin (Keflex) 1. Dose: child: 25–50 mg/kg per 24 hours; adult: 250–500 mg every 6 hours or QID 2. Supplied: 125 mg/5 ml, 250 mg/5 ml, 250 mg, 500 mg Ciprofloxacin (Cipro)

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1. Dose: 250–750 mg every 12 hours 2. Supplied: 250 mg/5 ml, 500 mg/5 ml, 100 mg, 250 mg, 500 mg, 750 mg 3. Interactions: antacids, sucralfate, Fe, Zn, theophylline, warfarin, cyclosporine Clarithromycin (Biaxin) 1. Dose: child: 7.5–15 mg/kg every 12 hours; adult: 250–500 mg BID 2. Supplied: 125mg/5 ml, 250 mg/5 ml, 250 mg, 500 mg Clindamycin 1. Dose: child: 8–25 mg/kg per 24 hours divided TID–QID; adult: 150–450 mg QID 2. Supplied: 75 mg, 150 mg, 300 mg, 75 mg/5 ml Cloxacillin (Cloxapen) 1. Dose: 50 mg/kg per 24 hours (given every 6 hours); adult: 250–500 mg every 6 hours 2. Supplied: 125 mg/5 ml, 250 mg, 500 mg Diaminodiphenylsulfone (Dapsone) 1. Dose: child:1–2 mg/kg per 24 hours given 1–2 times a day; adult: 25–150 mg per 24 hours 2. Supplied: 25 mg, 100 mg 3. Side-effects: methemoglobinemia, peripheral neuropathy, drug interactions, agranulocytosis 4. Monitor: a. Baseline CBC, glucose-6-phosphate dehydrogenase (G6PD), complete metabolic panel, neurologic evaluation; b. CBC every week for 4 weeks, then once a month for 6 months, then every 6 months c. Complete metabolic panel and neurologic examination every 3–4 months Dicloxacillin (Dynapen) 1. Dose:child: 12.5–50 mg/kg per 24 hours, given QID; adult: 125–500 mg QID 2. Supplied: 62.5 mg/5 ml, 250 mg, 500 mg Doxycycline (Doryx, Monodox, Vibramycin, Vibr-Tabs) 1. Dose: child: 3–5 mg/kg per 24 hours; given BID; adult: 50–200 mg/24 hours, given BID 2. Supplied: 25 mg/5 ml, 50 mg/5 ml, 50 mg, 100 mg 3. Side-effects: phototoxicity, dizziness, esophagitis Erythromycin 1. Dose: child: 50 mg/kg per 24 hours divided QID; adult: 250–500 mg QID 2. Supplied: Eryped (EES) 200 mg/5 ml, 400 mg/5 ml, 400 mg; E-mycin 250 mg, 333 mg, 500 mg

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2. Supplied: liquid: 200 mg/5 ml of sulfa, 40 mg/5 ml of TMP; tablet: 400 mg of sulfa, 80 mg of TMP; double strength: 800 mg of sulfa, 160 mg of TMP 3. Warnings: white blood cell suppression, allergy

3. Side-effects: nausea

• Minocycline (Dynacin, Minocin, Vectrin)

1. Dose: 2–4 mg/kg per 24 hours; 50–100 mg BID 2. Supplied: 50 mg/5 ml, 50 mg, 100 mg 3. Side-effects: discoloration of skin, teeth, pseudotumor cerebri Nafcillin (Unipen) 1. Dose: 250–1000 mg every 4–6 hours IV or IM 2. Supplied: 500 mg, 1000 mg powder for injection 3. Side-effects: nephrotoxicity Oxacillin (Bactocill) 1. Dose: child: 50–100 mg/kg per 24 hours divided 4–6 hours; adult: 500 mg every 4–6 hours 2. Supplied: 250 mg/5 ml, 250 mg, 500 mg Penicillin V 1. Dose: child: 25–50 mg/kg per 24 hours given every 6–8 hours; adult: 250–500 mg PO QID 2. Supplied: 125 mg/5 ml, 250 mg/5 ml, 250 mg, 500 mg Rifampin 1. Dose: 10–20 mg/kg per 24 hours, max 600 mg 2. Supplied: 150 mg, 300 mg 3. Warnings: interacts with antacids, Ca channel blockers, steroids, cyclosporine, digoxin, dapsone, quinolones, warfarin, L-thyroxine Sulfasalazine (Azulfidine) 1. Dose: child: 30–60 mg/kg per 24 hours given every 4–6 hours; adult: 500 mg/24 hours for 1 week, then increase by 500 mg/24 hours for 1 week 2. Max: 1–4 g/24 hours given QID 3. Supplied: 500 mg/5 ml, 500 mg 4. Monitor: CBC, liver enzymes every 2 weeks, monthly for 3 months, then every 3–6 months 5. Warning: take with food Tetracycline (Panmycin, Sumycin) 1. Dose: child: 25–50 mg/kg per 24 hours given QID; adult: 250–500 mg BID–QID, maximum 3 g/24hours 2. Supplied: 250 mg, 500 mg 3. Warning: do not use 50 kg: 2 caps BID b. Hair (tinea capitis): 3–5 mg/kg per 24 hours for 30 days, given once daily or BID; >60 lb: 100 mg/24 hours for 1 month; 2-year-old: 100 mg every other day in apple sauce or Jello for 1 month c. Tinea versicolor: 200 mg once, repeat in 1 week 3. Supplied: 10 mg/ml, 100 mg 4. Monitor: liver enzymes, drug interactions Ketoconazole (Nizoral) 1. Dose: child ≥2 years: 3.3–6.6 mg/kg per 24 hours given once daily; adult: 200–400 mg/24 hours given once daily; max dose: 800 mg/24 hours given BID 2. Tinea versicolor: 400 mg once a week twice, week apart; or 200 mg daily for 5–10 days 3. Supplied: 100 mg/5 ml compounded, 200 mg 4. Monitor: liver enzymes in long-term use, drug interactions Nystatin 1. Dose: child/adult: 4–6 ml swish and swallow QID 2. Supplied: suspension 100 000 units/ml Terbinafine (Lamisil) 1. Dose: a. Hair: 3–6 mg/kg per 24 hours for one month; 40 kg: 1 tab/24 hours b. Nails: 250 mg daily for 3 months or pulsed: 250 mg BID for 1 week each month for 3 months c. Adult: 250–500 mg/24 hours 2. Supplied: 250 mg 3. Monitor: CBC and liver enzymes before and monthly during continuous therapy, drug interactions

• RID (pyrethrin 0.3% plus pipermylbutoxide) • •

1. Apply for 10 minutes to dry hair then wash out Sulfur (precipitated) (5–10% ointment) 1. Must compound in cream or petrolatum; apply daily for 3 days Ivermectin (0.2 mg/kg given in a single dose). 15–24 kg: half tab (3 mg); 25–35 kg: 1 tab (6 mg); 36–50 kg: 1 half tab (9 mg); 51–65 kg: 2 tab (12 mg); 66–79 kg: 2 half tab (15 mg); ≥80 kg: 0.2 mg/kg 1. Supplied: 6 mg tab

Acne medicines (topicals) Benzoyl peroxide (BP)

• Antibacterial/keratolytic • Do not apply at same time with topical retinoid • Water-based gels less irritating and less drying than acetone- or alcohol-based gels

• Concentrations of 2.5–5% are as effective as 10% gels and less irritating

• See Table 21.5 Topical antibiotics for acne

• Come as solutions, lotions, gels, creams and pads

• Kill Propionibacterium acnes • Anti-inflammatory effects • See Table 21.6 Keratolytics for acne

• See Table 21.7 Topical retinoids

• Available by prescription only • Creams are less irritating than gels or solutions • See Table 21.8

Antiparasitic agents

Sulfur products

• Elimite cream (permethrin 5%)

• • • •

• •

1. Apply for 8–14 hours (overnight); repeat in 1 week Kwell (lotion, cream, shampoo) (lindane 1%) 1. Apply for 8–14 hours; repeat in 1 week Nix Cream Rinse (permethrin 1%) 1. Apply for 10 minutes to dry hair then wash out

Broad-spectrum antimicrobial, keratolytic Treat: acne, rosacea, seborrheic dermatitis Do not use in sulfa-sensitive patients See Table 21.9

Other

• See Table 21.10

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Table 21.5

Topical acne medicines

Medication

Prescription/OTC

Benzac AC (water emollient base) 2.5%, 5%, 10% Benzac W (water) 2.5%, 5%, 10% BenzaClin (BP 5% + 1% clindamycin) Brevoxyl (water) 4%, 8% Clear By Design 2.5% Duac gel (clindamycin 1% + BP 5%) Neutrogena Acne Mask 5% Oxy 10% gel Pan Oxyl 5%, 10% gel Sulfoxyl (regular) 5% BP + 2% sulfur lotion Sulfoxyl (strong) 10% BP + 2% sulfur lotion Triaz 3%, 6%, 10% gel Benzagel 5%, 10% Desquam X 2.5%, 5%, 10% gel

Rx Rx Rx Rx OTC Rx OTC OTC Rx Rx Rx Rx Rx Rx

Benzoyl peroxide wash Benzac AC Wash 2.5%, 5%, 10% Brevoxyl Cleanser 4%, 8% Brevoxyl Creamy Wash 4%, 8%

Rx Rx Rx

Table 21.6

Topical antibiotics for acne

Medication

Generic

Akne-Mycin (ointment or solution) A/T/S (gel, solution) Benzamycin BenzaClin (gel) Cleocin T (solution, gel, lotion, pledgets) Clindets (pads) Duac Emgel (gel) Erycette (swabs) EryDerm (solution) Erygel (gel) Staticin solution Theramycin Z (solution) Topicycline (solution) T-Stat (solution, pads)

2% erythromycin 2% erythromycin 3% erythromycin + BP 5% 1% clindamycin + BP 5% 1% clindamycin 1% clindamycin 1% clindamycin + BP 5% 2% erythromycin 2% erythromycin 2% erythromycin 2% erythromycin 1.5% erythromycin 2% erythromycin + zinc acetate tetracycline 2.2 mg/ml 2% erythromycin

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Table 21.7

Rosacea medicines

Keratolytics for acne

Medication

Generic

Supplied

Clean & Clear

salicylic acid 0.5% or 2% salicylic acid 1% or 2% salicylic gel 2%

OTC

Oxy Night Watch Stridex Clear Gel

OTC

• Anti-inflammatory • Prescription only • See Table 21.11 Antiviral agents

OTC

Topical Table 21.8

• Suppressive, not for primary treatment • Prescription only • See Table 21.12

Topical retinoids for acne

Medication

Generic

Avita 0.025% cream, gel Differin 0.1% cream, gel Retin-A Micro 0.1% gel Retin A 0.025%, 0.05%, 0.1% cream Retin A 0.01%, 0.025% gel Tazorac 0.05%, 0.1% (cream, gel)

tretinoin adapalene tretinoin tretinoin

Table 21.9

Medication

tretinoin tazarotene

Sulfur products for acne

Generic

Clearasil

8% sulfur + 1% resorcinol Fostril 2% sulfur Klaron 10 % sodium sulfacetamide Liquimat 5% sulfur Novacet 5% sulfur + 10% sodium sulfacetamide Sulfacet-R 5% sulfur +10% sodium sulfacetamide Sulfoxyl (regular) 5% BP + 2% sulfur lotion Sulfoxyl (strong) 10% BP + 2% sulfur lotion

Table 21.10

Table 21.11

Rosacea medicines

Medication

Generic

Noritate (cream) MetroGel MetroCream MetroLotion Klaron (lotion) Novacet Lotion sodium Sulfacet-R sodium

metronidazole 1% metronidazole 0.75% metronidazole 0.75% metronidazole 0.75% sodium sulfacetamide 10% sulfacetamide 10%/5% sulfur sulfacetamide 10%/5% sulfur

Supplied OTC Table 21.12

OTC Rx OTC Rx

Antiviral agents

Medication

Generic

Zovirax ointment Viroptic solution Cidofovir gel Denavir cream

acyclovir 5% trifluridine 1% 0.3, 1, 3% gel penciclovir 1% cream

Rx

Rx Rx

Topical genital wart treatment

• Podocon-25 (podophyllin 25%) •

Other products for acne

Medication

Generic

Azelex cream Finacea gel

20% azelaic acid Rx 15% azelaic acid Rx

Supplied

1. Apply in office; leave on 1–6 hours; then wash off Condylox (podofilox 0.5%) 1. Dose: use BID for 3 days each week; reassess at 4 weeks Aldara (imiquimod 5%) 1. Apply once daily 3 times per week at bedtime; wash in morning

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Opioid analgesics

a. Child (6 months to 5 years): 0.05–0.1 mg/kg per dose; can repeat in 2–3 minute intervals; max: 6 mg; 6–12 years: 0.025–0.05 mg/kg per dose; max: 10 mg; 12–16 years: 0.5–2 mg/dose; max: 10 mg; can repeat b. Adult: 5 mg or 0.07 mg/kg IM or 1 mg IV or 0.15 mg/kg IM 2. Supplied: 2 mg/ml, 3 mg/ml

• Codeine

1. Starting oral doses and intervals a. Child (50 kg) 15–60 mg every 4–6 hours 2. Supplied: 15 mg, 30 mg, 60 mg; 15 mg/ml, 60 mg/5 ml a. Acetaminophen with codeine: no. 2: 300 mg acetaminophen + 15 mg codeine; no. 3: 300 mg acetaminophen + 30 mg codeine; no. 4: 300 mg acetaminophen + 60 mg codeine Diazepam (Valium) 1. Dose: child: 0.1–0.8 mg/kg per 24 hours given every 6–8 hours; adult: 2–10 mg/24 hours given every 6–12 hours 2. Supplied: 5 mg/ml, 5 mg/5 ml, 1 mg, 2 mg, 5 mg, 10 mg Oxycodone (Oxycontin, Roxicodone) 1. Starting oral doses and intervals a. Child (50 kg) 5–10 mg every 4–6 hours 2. Supplied: 1 mg/ml, 20 mg/ml, 5 mg a. Oxycontin controlled-release tabs: 10 mg, 20 mg, 40 mg; adults: 10–40 mg PO every 12 hours b. Percocet (oxycodone + acetaminophen); adult 1–2 tab every 4–6 hours c. Supplied: 500 mg acetaminophen + oxycodone 5 mg; 325 mg acetaminophen + oxycodone 5 mg; 325 mg acetaminophen + oxycodone 5 mg/5 ml Morphine 1. Starting oral doses and intervals: a. Child (50 kg) 10–30 mg every 4–6 hours 2. Supplied: 10 mg/5 ml, 20 mg/5 ml, 100 mg/5 ml; 15 mg, 30 mg 3. Controlled release tabs (given every 12 hours): 30 mg, 60 mg, 100 mg Midazolam (Versed) 1. Dose (sedation/anxiolysis)

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Nonopioid analgesics

• Acetaminophen (Tylenol)

1. Dose: a. Child: 10–15 mg/kg per dose every 4–6 hours; 6 months to 5 years: 0.25–1 mg/kg per dose; 6–12 years: 0.25–0.5 mg/kg per dose b. Max daily dose: 75 mg/kg per 24 hours (not to exceed 4 g/24 hours) c. Adult: 325–650 mg every 4–6 hours d. Max daily dose (adults): 4 g/24 hours 2. Supplied: 160, 325, 500, 650 mg a. Chewable tabs: 80, 160 mg b. Infant drops: 80 mg/ 0.8 ml c. Liquid: 80 mg/5 ml, 120 mg/5 ml, 160 mg/5 ml, 325 mg/5 ml Aspirin 1. Dose: a. Child: 10–15 mg/kg per dose every 4–6 hours b. Adult dose 650–1000 mg every 4–6 hours c. Max daily dose: 4 g/24 hours 2. Supplied: 325, 500 mg, others a. Chewable tabs: 81 mg Ibuprofen (Advil, Motrin) 1. Dose: a. Child: 5–10 mg/kg per dose every 6–8 hours b. Max dose (child): 40 mg/kg per 24 hours c. Adult: 400–800 mg every 6–8 hours d. Max daily dose (adult): 3200 mg/24 hours 2. Supplied: 100 mg/5 ml, 40 mg/ml a. Chewable tabs: 50 mg, 100 mg b. Tabs: 100, 200, 300, 400, 600, 800 mg Naproxen (Naprosyn, Aleve) 1. Dose: a. Child >2 years: 5–7 mg/kg per dose every 8–12 hours b. Adult dose 250–500 mg every 12 hours c. Max daily dose (adult): 1000 mg

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2. Supplied: 125 mg/5 ml, 220 mg, 250 mg, 375 mg, 500 mg

Topical anesthetics

• See Table 21.13 Table 21.13

Topical anesthetics

Medication

Generic

EMLA ELA-MAX LMX Pramosone

2.5% lidocaine + 2.5% prilocaine 4% lidocaine 4% lidocaine Pramoxine + 1% or 2.5% hydrocortisone 3% Lidocaine + 0.13% benzalkonium Cl + 0.5% hydrocortisone

Lida-Mantle

Local anesthetics

• Lidocaine (Xylocaine) 1. Dose: a. Adults: max 4.5 mg/kg per dose without epinephrine; max 7 mg/kg per dose with epinephrine; max topical 3 mg/kg per dose, no more frequently than every 2 hours 2. Supplied: a. Injection: 0.5%, 1%, 1.5%, 2%, 4%, 10%, 20% b. Injection with 1 : 50 000 epinephrine – 2% lidocaine c. Injection with 1 : 100 000 epinephrine – 1%, 2% lidocaine d. Injection with 1 : 200 000 epinephrine – 0.5%, 1%, 1.5%, 2% lidocaine; jelly: 2% lidocaine ; liquid (viscous): 2% lidocaine; solution: 2% lidocaine

Other medicines

• Acitretin (Soriatane) 1. Indications: psoriasis, ichthyosis (off label) 2. Dose: 0.5 mg/kg per 24 hours; adult: 25–50 mg/24 hours 3. Supplied: 10 mg, 25 mg 4. Monitor: CBC, electrolytes, blood urea nitrogen (BUN), creatinine, liver enzymes,

lipids, urinalysis, fasting glucose, albumin, pregnancy tests a. Check baseline, then every 2 weeks for 2 weeks, then every month for 6 months, then every 3 months 5. Contraindications: pregnancy, alcohol ingestion 6. Warnings: see Physician’s Desk Reference, avoid pregnancy for >3 years after cessation 7. Side-effects: fetal abnormalities, pseudotumor cerebri, hepatotoxicity, decreased night vision, hyperostosis, lipid abnormalities Acyclovir (Zovirax) 1. Dose: a. Primary herpes: child: 15–30 mg/kg per 24 hours every 8 hours; max dose in child: 80 mg/kg per 24 hours; adult: 400 mg TID or 200 mg 5 times daily for 7–10 days b. Recurrence: adult: 400 mg TID for 5 days, or 200 mg 5 times a day for 5 days c. Chronic suppression: adult: 800–1000 mg/24 hours given 2–5 times a day d. Varicella: child: 80 mg/kg per 24 hours given QID for 5 days; max dose: 3200 mg/24 hours e. Herpes zoster: 800 mg 5 times a day for 5–7 days 2. Supplied: 200 mg/5 ml, 200 mg, 400 mg, 800 mg Chloral hydrate 1. Indications: sedation for procedures, sedative 2. Dose: a. Child: for anxiety: 5–15 mg/kg per dose (maximum 500 mg); for conscious sedation: 50–75 mg/kg per dose given every 6–8 hours; max: 1 g/dose b. Adult: 250–1000 mg/dose given TID; max: 2 g/24 hours 3. Supplied: 250 mg/5 ml, 500 mg/5 ml, 250 mg, 500 mg 4. Contraindications: hepatic or renal disease Cimetidine (Tagamet) 1. Indications: histamine-2-antagonist 2. Dose: a. Child: 20–40 mg/kg per 24 hours, given 3–4 times per day b. Adult 300 mg QID c. Max: 2400 mg/24 hours

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3. Supplied: 100 mg (OTC), 200 mg tabs, 300 mg/5 ml, 300 mg, 400 mg, 800 mg 4. Warning: drug interactions Cyclosporine (Neoral) 1. Indications: immunosuppressant, potent T-cell inhibitor, psoriasis 2. Dose: 2.5–4 mg/kg per 24 hours divided BID for 4 weeks; increase every 2 weeks by 0.5 mg/kg per 24 hours a. Max: 5 mg/kg per 24 hours 3. Monitor: CBC, liver enzymes, BUN, creatinine, Mg, K, uric acid, lipids, cyclosporine trough levels if >5 mg/kg per day a. Check blood pressure every 2 weeks for 3 months, decrease dose if creatinine is elevated >30% b. Check creatinine clearance every 6 months 4. Contraindications: renal insufficiency, hypertension, infection 5. Relative contraindications: malignancy, immunodeficiency, nephrotoxic drugs, hepatic disease, gout 6. Side-effects: nephrotoxicity, hepatotoxicity, hypertension, tremor, gingival hyperplasia, long-term malignancy, hyperlipidemia, hypertrichosis, hyperkalemia, uricemia, hypomagnesemia 7. Supplied: 100 mg/ml, 25 mg, 100 mg Doxepin 1. Dose: a. Child: 1–3 mg/kg per 24 hours, given in single dose at bedtime b. Adult 25–100 mg PO at bedtime; start low and increase slowly; max 300 mg/24 hours 2. Supplied: 10 mg/ml; 10 mg, 25 mg 3. Topical - use in teens and adults only; use only in small areas; consider toxicity (drowsiness) if overused Epinephrine 1. Indications: sympathomimetic, hypersensitivity reactions 2. Dose: a. Child: 0.01 mg/kg per dose (maximum 0.3 mg) b. Adult: usually 0.1–0.25 mg of 1 : 1,000 solution subcutaneously 3. Supplied: Epi Pen Jr 0.15 mg dose, Epi Pen 0.3 mg autoinjection

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a. For injection: 1 mg/ml, 5 mg/ml, 0.1 mg/ml, 0.01 mg/ml 4. Warning: may produce arrhythmia, hypertension, nervousness, vomiting Famciclovir (Famvir) 1. Dose: ages >18 years a. Primary herpes: 250 mg TID for 7–10 days b. Recurrence: 125–250 mg BID for 5 days c. Suppression: 250 mg BID d. Herpes zoster: 500 mg TID for 7 days e. Supplied: 125 mg, 250 mg, 500 mg f. Warning: do not give to HIV patients Folic acid 1. Dose: a. Initial: child (1–10 years): 1 mg/24 hours or 5 mg per week; >11 years: 1–3 mg/dose divided daily to TID b. Maintenance: 0.1–0.5 mg/24 hours given QD; pregnant women 0.8 mg/24 hours 2. Supplied: 0.4 mg, 0.8 mg, 1 mg; 1 mg/ml compounded Hydroquinone (HQ) 1. Indications: bleaching agent 2. Supplied: 1.5–2% OTC a. 4% by prescription b. Lustra (HQ, glycolic acid, no sunscreen) c. Lustra AF (HQ, sunscreen) d. Alustra (HQ, retinal, sunscreen) 3. Warnings: do not use for prolonged periods (>3 months) because of risk of hyperpigmentation Hydroxychloroquine (Plaquenil) 1. Dose: 200–400 mg/24 hours, given BID–TID 2. Supplied: 200 mg 3. Monitor: a. Initial G6PD (avoid if deficient), CBC, liver enzymes, eye examination b. Every 3 months: CBC, liver enzymes c. Every 6 months: eye examination 4. Side-effects: retinal damage, myopathy, liver abnormalities, hemolysis, cutaneous eruptions or discoloration Isotretinoin (Accutane) 1. Indications: severe recalcitrant or cystic acne, ichthyosis (off label) 2. Dosage: a. Initial 0.5–2 mg/kg per 24 hours given BID for 15–20 weeks b. Max dose: 2 mg/kg per 24 hours

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c. Adjust for side-effects and disease response d. Repeat only if necessary after 2 months off drug e. Take with food 3. Supplied: 10 mg, 20 mg, 30 mg, 40 mg 4. Contraindications: pregnancy, paraben sensitivity, concomitant vitamin A 5. Monitor: initial CBC; baseline and every month: liver enzymes, lipids, pregnancy tests 6. Warnings: see PDR; need special labels to prescribe Methotrexate (Rheumatrex) 1. Indications: psoriasis, morphea, cutaneous T-cell lymphoma 2. Dose: 2.5–25 mg given once a week either PO or IM 3. Supplied: 2.5 mg 4. Monitor: liver enzymes, creatinine, CBC, urinalysis every week for 4 weeks then once a month; chest X-ray as indicated; liver biopsy after 1–1.5 g total dose 5. Contraindications: pregnancy, liver disease, alcohol ingestion, significant hematological abnormalities, active infectious disease, immunodeficiency 6. Warning: multiple drug interactions, hepatoxicity, bone marrow depression, carcinogenesis, pulmonary fibrosis Minoxidil (Rogaine) 1. Indications: androgenetic alopecia 2. Dose: 2%, 5% solution, apply 1 ml to dry scalp BID 3. Side-effects: hypertrichosis Mycophenolate mofetil (CellCept) 1. Indications: immunosuppressive agent 2. Dose: 2–4 g/24 hours given BID i. Child: 600 mg/m2 per dose PO, BID 3. Supplied: 250 mg, 500 mg 4. Monitor: CBC (neutrophils) and liver enzymes once a week for 1 month, then once monthly 5. Warning: drug interactions Oral contraceptive pills (with low androgenetic activity) 1. Indications: acne, hirsutism 2. Supplied: Ortho-Tricyclen (ethinyl estradiol–norgestimate), OrthoCyclen, Desogestrel, Ovulen, Demulen, Enovid, Orthocept, Desogen, OrthoCyclen, Desogen, Orthocept

3. Contraindications: pregnancy

• Pimecrolimus (Elidel)

1. Ages >2 years: 1% pimecrolimus cream BID 2. Supplied: 15 g, 30 g, 100 g 3. Warnings: burning, stinging Robinul (glycopyrrolate) 1. Indications: hyperhidrosis (anticholinergic) 2. Dose: a. Child: 0.04–0.1 mg/kg per dose every 4–8 hours b. Adult: 1–2 mg BID–TID 3. Supplied: 1 mg, 2 mg 4. Warning: caution in liver or kidney disease; atropine-like side-effects SSKI (potassium iodide) 1. Indications: larva migrans, erythema nodosum (off label), sporotrichosis 2. Dose: 3–10 drops TID a. Adult: 300–650 mg TID–QID b. Child: 60–250 mg TID–QID c. Max: 4.5–9 g/24 hours 3. Supplied: 1000 mg/ml, 325 mg/5 ml, 65 mg, 130 mg 4. Monitor: thyroid tests 5. Contraindications: pregnancy 6. Warning: metallic taste, give with milk or meals Tacrolimus (Protopic) 1. Ages 2–15 years: 0.03% tacrolimus ointment BID 2. Ages >15 years: 0.1% tacrolimus ointment BID 3. Supplied: 30 g, 60 g 4. Warnings: burning, stinging Thalidomide 1. Dose: a. Adult: 50–300 mg/24 hours given at night 2. Supplied: 50 mg 3. Side-effects: birth defects, peripheral neuropathy (sensory), sedation 4. Monitor: a. Baseline human chorionic gonadotropin (hCG), neurological examination, sensory nerve action potential (SNAP) b. hCG every week for 4 weeks, then every 4 weeks c. Neurological examination every 3 months, and SNAP as indicated Valacyclovir (Valtrex)

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Therapy

1. Dose: ages: >18 years a. Primary herpes: 1–2 g BID for 7–10 days b. Recurrence: 500 mg BID for 5 days c. Suppression: 500 mg once daily d. Herpes zoster: 1 g TID for 7 days 2. Supplied: 500 mg, 1000 mg 3. Warning: do not prescribe to HIV patients Zinc 1. Indications: zinc deficiency 2. Dose: a. Child: 0.5–1 mg elemental zinc/kg per 24 hours, given daily to TID b. Adult: 25–50 mg elemental zinc/dose TID 3. Supplied: 2 mg/ml a. Children >4 years: Centrum Jr + Fe (15 mg), Polyvisol + Fe Zn b. Tabs as sulfate with 23% elemental Zn: 110 mg (25 mg elemental Zn), 220 mg (50 mg elemental Zn) c. Tabs as gluconate with 14.3% elemental Zn d. Liquid as acetate: 5 mg, 10 mg elemental Zn/ml (compounded) 4. Warning: GI upset

409

References Archer JSM, Archer DF. Oral contraceptive efficacy and antibiotic interaction: a myth debunked. J Am Acad Dermatol 2002; 46: 917–23 Berde CB, Sethna NF. Analgesics for the treatment of pain in children. N Engl J Med 2002; 347: 1094–103 Brecher AR, Orlow SJ. Oral retinoid therapy for dermatologic conditions in children and adolescents. J Am Acad Dermatol 2003; 49: 171–82 Drake LA, Dinehart SM, Farmer ER, et al. Guidelines of care for the use of topical glucocorticosteroids. J Am Acad Dermatol 1996; 35: 615–19 Litt JZ. Pocketbook of Drug Eruptions. Parthenon Publishing: New York, 2001 Parker JF, Vats A, Bauer G. EMLA toxicity after application for allergy skin testing. Pediatrics 2004; 113: 410–11 Shapiro LE, Shear NH. Drug interactions: proteins, pumps, and P-450s. J Am Acad Dermatol 2002; 47: 467–84 Scheman AJ, Severson DL. Pocket Guide to Medication Used in Dermatology, 6th edn. Williams & Wilkins: Baltimore, 1999

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INDEX

abuse 211–16 acanthosis nigricans 246–8 acetaminophen 405 acitretin 406 acne 71–80 acne vulgaris 72–74 drug-induced acne 74–75, 223 early-onset 71–72 infantile 71 keloidalis nuchae 312 neonatal 71 prepubertal 71 acne medications 402–4 keratolytics 404 retinoids 404 sulfur products 404 topical antibiotics 401, 403 acneiform disorders drug-induced 74–75, 223 hidradenitis suppurativa 77 hyperhidrosis 79–80 miliaria 78–79 perioral dermatitis 75–76 rosacea 76–77 acquired lesions 291–5 acrodermatitis enteropathica 197–8, 337 acropustulosis of infancy 68–69 actinic porokeratosis, disseminated superficial (DSAP) 46–7 actinic prurigo 203 acute febrile neutropenic dermatosis 191–3 acyclovir 406 Adams–Oliver syndrome 18 adapalene 55 Addison disease, hyperpigmentation

230 adhesives, contact dermatitis 59 aerosols 392 AIDS and HIV infection 142–4 albinism 251–2 Albright hereditary osteodystrophy 323 Alezzandrini syndrome 249 allergens, skin patch tests 61–62 allergic contact dermatitis 58–63 alopecia 335–7 acquired non-scarring 340–6 alopecia areata 340–2 alopecia areata, nail disorders 359 alopecia mucinosa 352 anagen effluvium 343 androgenetic alopecia 343–4 syndromes with late-onset hypotrichosis 346 telogen effluvium 342–3 traction alopecia 346 traumatic alopecia 346 triangular alopecia 337 trichotillomania 344–5 acquired scarring 351–353 congenital, diffuse 337–40 early-onset 337–8 ectodermal dysplasia (hidrotic) 339–40 ectodermal dysplasia (hypohidrotic/anhidrotic) 338–9 congenital, localized 336–7 occipital alopecia 336 patchy alopecia 337 drug-induced 223

Amblyomma americanum 171 anagen effluvium 343 analgesics 405 anaphylaxis 177–178 Ancylostoma braziliensis 172–3 Ancylostoma caninum 172–3 androgenetic alopecia 343–4 anesthetics, local 406 anetoderma 306–7 angiokeratoma 287–8 anhidrotic ectodermal dysplasia 338–9 animal bites 169–74 annular, defined 4 annular erythema 183–5 anogenital warts 137–9 anonychia 359 anorexia nervosa-associated skin disorders 194–5 ant bites 168 anthralin 396 antibiotics 399–400 endocarditis prophylaxis 400 topical 401 topical, for acne 403 antiepileptics, drug reactions 224 antifungals 400–1 antihistamines 398–9 antimalarials, drug reactions 225 antimetabolites (chemotherapy), drug reactions 225 antiparasitic agents 402 antiperspirants 398 antipruritics 54, 62 antiviral agents 404 aplasia cutis congenita, 17–19 arciform, defined 4

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artefactual dermatitis 214–16 ashy dermatosis 246 aspirin 405 asteatotic (winter) eczema 56 ataxia–telangiectasia 387–8 athlete’s foot fungus 153 atopic dermatitis 49–55 atrophy, defined 3 Auspitz sign 33 avobenzone 398 bacterial culture 7 bacterial diseases 95–115 baldness see alopecia bamboo hair 347 Bartonella henselae 109 basal cell carcinoma 327–8 basal cell nevus syndrome 381–2 Bazex syndrome 327 Bazin disease 113 beaded hair (monilethrix) 349 Beau’s lines 359 bee/wasp/hornet stings 168 benzoyl peroxide 402 BIDS 351 biopsy 7 bites 169–74 Blaschko lines 46–7, 229, 297–301 Conradi–Hunermann syndrome 375–6 definition 229 disorders following 297 epidermal nevus 297–9 hypomelanosis of Ito 254 nevus comedonicus 300–1 nevus sebaceus 299–300 blastomycosis 159, 160–1 blepharitis 66 blistering distal dactylitis 103–4 Block–Sulzberger syndrome 244 Bloom syndrome 209 blue nails 359–60 blue rubber bleb syndrome 281 blueberry muffin baby 21 body lice 165–7 borreliosis 146, 170–2 Bourneville disease 379 brachyonychia 360 branchial cleft cyst/sinus 29 bromides, drug reactions 225 bulimia nervosa-associated skin disorders 194–5 bulla, defined 3 bullous congenital ichthyosiform

erythroderma 373 bullous disorders 81–94 bullous impetigo 96 bullous pemphigoid 85–86 chronic bullous disease of childhood 84, 87–89 drug-induced erythema multiforme 219 epidermolysis bullosa 89–94 immunobullous disorders 81–89 see also pemphigus Burow’s solution 393 café au lait macules 240–1, 377 calcifying epithelioma of Malherbe 303–4 calcinosis cutis 257, 322–3 metastatic 323 calcipotriene 396 calluses 315–16 candidal diaper dermatitis 65, 149 candidiasis 149–51 neonatal infections 24–6 capillaritis, primary 272 capillary malformations 280–2 Caspary–Joseph spaces 44 cat hookworm 172–3 cat scratch disease 109–10 caterpillar dermatitis (lepidopterism) 169 cellulitis 99–101 cephalic pustulosis, neonates 13–14 cephalosporins, drug reactions 224 cercarial dermatitis (swimmer’s itch) 174–5 cetirizine 398 Chediak–Higashi syndrome 356–7 chemotherapy, drug reactions 225 chickenpox 132–5 chiggers 167 chilblains 210 child abuse 211–16 CHILD syndrome 337 chloral hydrate 406 chondrodysplasia punctata, X-linked 375 Christian–Siemens–Touraine syndrome 338 cimetidine 406 Civatte bodies 44 clavus/i 315 cleansers 54, 397 clemastine 398 clinical diagnosis 1–7

configuration of lesions 4 dermatoses, common 8 diagnostic tests 4–7 history 1–2 primary lesions 3 reaction patterns 6 regional patterns 5 secondary lesions 3 terminology 2–4 Clouston syndrome 339 Cockayne syndrome 208–9 Cockayne–Touraine epidermolysis bullosa 92 codeine 405 cold injuries 210–11 collagen type-7 84 collagen vascular diseases 257–74 collodion baby 369–70 coloration 4 comedonal nevi 300–1 comedones 3, 72 condylomata acuminata 137, 139 configuration of lesions 4 confluent and reticulated papillomatosis 248 congenital dermal sinus 28–9 congenital ichthyosiform erythroderma (CIE) 372–3 congenital lymphedema 290–1 congenital nevocellular nevi 231–2 connective tissue 309–17 nevus 316 Conradi–Hunermann–Happle syndrome 337, 375–6 contact dermatitis 58–63 allergic 58–63 history 59 irritant 63 corns 315–16 corticosteroids drug reactions 224 mid-strength and high-potency 54 systemic/oral 54, 62, 395–6 topical 54, 62, 393–5 types and strengths 394 Corynebacterium minutissimum, Wood’s lamp examination 7 cosmetics, contact dermatitis 59 coumadin, drug reactions 225 coup de sabre 264 Cowden disease 386–7 coxsackieviruses 136–7 crab lice 165–7 creams 392

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creeping eruption 172–3 Crowe sign 378 crust, defined 3 cutaneous larva migrans 172–3 cutaneous T-cell lymphoma 41–3 cutis hyperelastica 382 cutis laxa 384 cutis marmorata 9–10 telangiectatica congenita 284–5 cyclosporine 407 cyproheptadine 398 Cyrano nose 277 cystic fibrosis 197–8 cystic hygroma 290 cysts 301–5 benign 302 branchial cleft cyst/sinus 29 defined 3 dermoid cyst 303 epidermal cyst 301–2 eruptive vellus hair cysts 304–5 macrocystic malformations 289–90 preauricular cyst/sinus 29–30 steatocystoma multiplex 325 dactylitis, blistering distal 103–4 Dakin’s solution 393, 400 Dandy–Walker syndrome 277–8 Darier disease 388–9 Darier sign 320 definitions 3–4 delayed-type hypersensitivity reactions 60 Dennie’s lines 64 Dermacentor variabilis 171 dermal erythropoiesis, neonates 21 dermal sinus, congenital 28–9 dermatitis allergic contact 58–63 artefactual 214–16 caterpillar 169 cercarial 174–5 defined 49 diaper 63–65 eczematous, with immunodeficiencies 57–58 factitial 214–16 frictional lichenoid 51–52 irritant contact 63 juvenile plantar 51–52 marine 175–6 perianal streptococcal 102–3 perioral 75–76

photoallergic 201–2 photodermatoses 201–2 phytophotodermatitis 202 seborrheic 66–67 dermatitis herpetiformis 84, 86–87 dermatofibroma 314–15 dermatographism 52, 177 dermatomyositis 257–8 dermatoses acute febrile neutropenic 191–3 common 8 eczematous 49–69 genodermatoses 205–10 IgA 87–89 neutropenic 191–3 photodermatoses 199–205 dermoid cyst 303 DeSanctis–Cacchione syndrome 207 desloratadine 398 desmoglein 84 desmoplakin 84 diabetes, necrobiosis lipoidica 186–7 diagnosis see clinical diagnosis diagnostic tests 4–7 diaper candidiasis 65, 149 diaper dermatitis 63–65 diaper psoriasis 33–6 diascopy 7 diazepam 405 diffuse cutaneous mastocytosis 319–20 diphenhydramine 398 discoid lupus erythematosus 260–1 dispensing topical therapy 391 see also therapies disseminated superficial actinic porokeratosis 46–7 dog bites 173 dog hookworm 172–3 Dowling–Meara epidermolysis bullosa 89, 90, 91 Down syndrome 360 doxepin 407 doxycycline, phototoxicity 199–201 drug eruptions 217–27 acne 74–75 acneiform eruptions 223 alopecia 223 common causative drugs 218 diagnosis 226 drugs with low incidence 217 environmental factors 225 erythema multiforme 219

413

erythema nodosum 221 fixed 222–3, 226 hypersensitivity 219–21 immunologic reactions (types 1–4) 225–6 lichenoid 222 lupus-like reactions 223 maculopapular/morbilliform 217–18 pathogenesis 225–7 photosensitivity eruptions 221–2 pigmentary changes 223 reaction types 217–27 serum sickness 220–1 serum sickness-like reactions 221 toxic epidermal necrolysis 219 treatment 227 urticaria 218–19 vasculitis 223 drug eruptions, specific drugs 224–7 antiepileptics 224 antimalarials 225 antimetabolites (chemotherapy) 225 bromides 225 cephalosporins 224 corticosteroids 224 coumadin 225–7 gold 224–5 iodides 225 lithium 225 nonsteroidal anti-inflammatory agents 225 penicillin 224 sulfonamides 225 tetracyclines 224 thiazides 225 drug-induced hypersensitivity 219–21 echovirus 126–7 ecthyma 98–99 ecthyma contagiosum 141 ectodermal dysplasia hidrotic 339–40 hypohidrotic/anhidrotic 338–9 eczema defined 49 dermatitis with immunodeficiencies 57–58 infantile eczema 49–69 Ehlers–Danlos syndrome 382–4 Ehrlichia 171 elastosis perforans serpiginosa 45–6 Elejalde syndrome 357

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elicitation reactions 60 EMLA 406 emollients 392 en coup de sabre 264 enanthems 119 encephalocele 28 endocarditis, prophylaxis 400 envoplakin 84 ephelides 239–40 epidermal cyst 301–2 epidermal growths 325–7 steatocystoma multiplex 325 syringomas 325–6 trichoepithelioma 326–7 epidermal nevus 297–9 epidermolysis bullosa 89–94 acquisita 84 Cockayne–Touraine type 92 Dowling–Meara type 89, 90, 91 dystrophica 19, 92 Herlitz type 89, 91 junctional 91 of Pasini 92 simplex 90–91 Weber–Cockayne type 89, 90 epidermolytic hyperkeratosis 373–4 Epidermophyton floccosum 153 epinephrine 407 epithelioma of Malherbe 303–4 Epstein–Barr virus disease 127 erosion, defined 3 eruptive vellus hair cysts 304–5 eruptive xanthoma 319 erysipelas 101–2 erythema annulare 183–5 erythema chronicum migrans 145, 170–1 erythema craquele 56 erythema dyschromicum perstans 246 erythema induratum 113 erythema infectiosum (fifth disease) 123–4 erythema multiforme drug-induced 219 major 180–2 minor 179–80 erythema nodosum 182–3 drug-induced 221 etiologies 309 erythema toxicum neonatorum 11–12 erythematous psoriasis 34 erythroderma, congenital ichthyosiform (CIE) 372–3 eschar, defined 3

exanthems 119 asymmetric periflexural 125 subitum (roseola) 122–3 unilateral laterothoracic 125–6 excoriation, defined 3 exostoses 324 exudate, defined 3 Fabry disease 288 famciclovir 407 fat, associated disorders 305–9 subcutaneous necrosis 16–17 favus 154 fetus papyraceus 18 fexofenadine 398 fibromatoses 309–11 dermatofibroma 314–15 fibrous histiocytoma 314–15 fifth disease 123–4 finger clubbing 360 fish tank granuloma 111–12 fissure, defined 3 fluconazole 401 foams 392 fogo selvagem 82 folic acid 407 folic acid deficiency 196 folliculitis 96–98 dissecting 352 keratotic 388 Pityrosporum 97 pseudomonal 97–98 Fordyce, angiokeratoma 288 Forschheimer spots 104 freckles (ephelides) 239–40 frictional lichenoid dermatitis 51–52 frostbite 210–11 fungal cultures 6 fungal infections 149–62 fungal infections, deep 159–62 blastomycosis 160–1 mucormycosis 161–2 sporotrichosis 159–60 fungal infections, superficial 149–59 candida 149–51 onychomycosis 156–7, 363–4 potassium hydroxide examination 4–5 tinea capitis 154–6 tinea corporis 151–3 tinea pedis 153–4 tinea versicolor 157–9 furunculosis 97

Gardner syndrome 301, 385–6 gels 392 generalized hyperpigmentation 230 genital warts 137–9 topical treatment 404 genodermatoses sun sensitivity 205–10 syndromes 369–89 Gianotti–Crosti syndrome 124–5 Gilchrist disease 160 gliadin 84 glioma 27–8 glomuvenous malformations 285–6 glycopyrrolate 408 gold, drug reactions 224–5 Goltz syndrome 337 Gorlin syndrome 381 Gottron papules 257 Gougerot and Carteaud syndrome 248 Gower sign 257 granulomas annulare 185–6 fish tank 111–12 juvenile xanthogranuloma 317–19 Majocchi 152 pyogenic granuloma 291–2 sarcoidosis 193–4 umbilical granuloma 14 granulomatosis, Wegener 267 Griscelli syndrome 357 griseofulvin 400–1 gyrate, defined 4 Haemophilus influenzae 270 hair disorders 335–57 abnormalities of hair color 355–7 abnormalities of increased hair 351–5 acquired non-scarring alopecia 340–6 acquired scarring alopecia 351, 352, 353 congenital alopecia, diffuse 337–40 congenital alopecia, localized 336–7 see also alopecia hair growth, normal cycle 335 hair shaft abnormalities 347–51 loose anagen syndrome 350–1 monilethrix 349 pili torti 348–9

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Index

trichorrhexis invaginata 347–8 trichorrhexis nodosa 347 trichothiodystrophy 351 uncombable hair syndrome 349–50 Hallopeau, continua 34 hamartoma connective tissue nevi 316 fibrous of infancy 310 multiple hamartoma syndrome 386 smooth muscle hamartoma 317 hand, foot and mouth disease 136–7 Hansen disease 113–14 harlequin ichthyosis 374–5 harvest mites 167 head lice 165–7 heliotrope rash 257 hemangioma of infancy 275–80 hematopoiesis, extramedullary 21 Henoch–Schönlein purpura 268–70 hepatitis 128–9 Herlitz type junctional epidermolysis bullosa 89 Hermansky–Pudlak syndrome 253 herpes simplex 130–2 erythema multiforme 179–80 infantile 23–4, 130–2 neonates 21–3, 130–2 Tzanck smear 6 whitlow 131, 367 herpes zoster 135–6 infantile 23–4 herpetiform, defined 4 hidradenitis suppurativa 77 hidrotic ectodermal dysplasia 339–40 hirsutism 354–5 histiocytoma 314–15 histiocytosis 330–1 HIV infection 142–4 hookworm 172–3 hot tub (pseudomonal) folliculitis 97–98 human immunodeficiency virus (HIV) 142–4 Hutchinson sign, nail disorders 360 Hutchinson summer prurigo 203 Hutchinson triad 26 hydroa aestivale 203 hydroa vacciniforme 203 hydroquinone 407 hydroxychloroquine 407 hydroxyzine 398 hymenoptera stings 168–9

hypercalcaemia, subcutaneous fat necrosis 16–17 hyperhidrosis 79–80 hyperimmunoglobulin E syndrome 57–58 hyperkeratosis, epidermolytic 373–4 hyperpigmentation disorders 229–48 hypersensitivity disorders 177–94 annular erythemas 183–5 drug-induced 219–20 erythema multiforme 179–80 erythema nodosum 182–3 granuloma annulare 185–6 Kawasaki disease 187–9 necrobiosis lipoidica diabeticorum 186–7 pyoderma gangrenosum 189–91 rheumatoid nodules 186 sarcoidosis 193–4 Stevens–Johnson syndrome (SJS) 180–2 Sweet syndrome 191–3 toxic epidermal necrolysis (TEN) 180–2 urticaria 177–79 hypersensitivity reactions acute 58–60 delayed-type 60 hypertrichosis 351–4 causes 353 hypertrophic scars 313 hypohidrotic ectodermal dysplasia 338–9 hypomelanosis of Ito 254–5 hypopigmented disorders 249–56 hypotrichosis 339, 346 late-onset 346 IBIDS 351 ibuprofen 405 ichthyosiform erythroderma, congenital (CIE) 372–3 ichthyosis 369–76 collodion baby 369–70 congenital ichthyosiform erythroderma (CIE) 372–3 Conradi–Hunermann–Happle syndrome 375–6 epidermolytic hyperkeratosis 373–4 harlequin 374–5 ichthyosis vulgaris 370–1 lamellar 372 steroid sulfatase deficiency 371

415

X-linked 371 id reaction 60, 152 IgA dermatosis 87–89 imiquimod 404 immunobullous disorders 81–89 bullous pemphigoid 85–86 dermatitis herpetiformis 86–87 pemphigus 81–84 immunodeficiencies with eczematous dermatitis 57–58 HIV infection 142–4 severe combined syndrome 57–58 immunologic reactions (types 1–4) 225–6 impetigo 95–96 incontinentia pigmenti 244–6 infantile eczema 49–69 infantile fibromatoses 309–11 infectious mononucleosis 127–8 infestations 163–76 infiltrations 317–25 calcinosis cutis 322–3 juvenile xanthogranuloma 317–19 mastocytosis 319–22 osteoma cutis 323–5 inflammatory linear verrucous epidermal nevus (ILVEN) 298 insect bites, urticarial reactions 167–8 insect stings 168–9 intertrigo 66–67 iodides, drug reactions 225 isotretinoin 407 Ito hypomelanosis 254–5 nevus 243–4 itroconazole 401 ivermectin 165, 402 Ixodes spp. 171 Jackson–Lawler syndrome 364 Jacquet ulcers 64 Jadassohn–Lewandowsky syndrome 364 Job syndrome 57–58 juvenile plantar dermatitis 51–52 juvenile rheumatoid arthritis 186 juvenile spring eruption 203 juvenile xanthogranuloma 317–19 Kasabach–Merrittt syndrome 277 Kawasaki disease 187–9 keloids 311–12 keratodermas, palmoplantar 376–82 keratolysis, pitted 108–9

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keratolysis exfoliativa 47–8 keratolytics 55, 397 with moisturizers 396–7 keratosis follicularis 388 keratosis pilaris 55–56 kerion 154 ketoconazole 402 KID syndrome 338 kinky hair syndrome 355–6 Klein–Waardenburg syndrome 252 Klippel–Trenaunay syndrome 283–4 knuckle pads 310 Koebner epidermolysis bullosa 89 Koebner phenomenon 33, 44 koilonychia 361 Koplik spots 119 kwashiorkor 195 Lactrodectus mactans 169–70 Langerhans cell histiocytosis 330–1 laser therapy 279 lentiginous nevus 236 lentigo simplex 240 Leopard syndrome 208 lepidopterism 169 leprosy 113–15 Letterer–Siwe disease 330 leukemia cutis 328–9 leukoderma acquisitum centrifugum 235 leukonychia 361 lichen aureus 273–4 lichen nitidus 44–5 lichen planus 43–4 lichen purpuricus 273–4 lichen sclerosus 265–6 lichen scrofulosorum 113 lichen simplex chronicus 51 lichen striatus 67–68 lichenification, defined 3 lichenoid dermatitis 51–52 drug-induced 222 lidocaine 406 Lindsay nails 360 linear IgA dermatosis 87–89 lipoma 305–6 lithium, drug reactions 225 livedo reticularis 292–3 local anesthetics 406 loose anagen syndrome 350–1 loratadine 399 lotions 392 Louis–Bar syndrome 387 louse infestations 165–7

Loxosceles reclusa 169–70 lues 115–17 lupus erythematosus discoid 260–1 neonatal 14–16 systemic lupus erythematosus 258–60 lupus vulgaris 112 lupus-like drug-induced reactions 223 Lyme disease 145–7, 171 lymphangioma circumscriptum 289 lymphatic malformations 288–91 lymphedema 290–91 lymphoma 329–30 McCune–Albright syndrome 241–2 macrocystic (lymphatic) malformations 289–90 macronychia 361 macular atrophy 306 macule, defined 3 Mafucci syndrome 281 Majocchi granuloma 152 malar rash 257 malignancies/tumors 327–33 basal cell carcinoma 327–8 defined 3 glomus tumor 285–6 histiocytosis 330–1 leukemia cutis 328–9 lymphoma 329–30 mast cell disease 320 melanoma 236–8 neuroblastoma 332–3 neurofibroma 315 neurofibromatosis 377–9 rhabdomyosarcoma 331–2 marasmus 195 marine dermatitis 175–6 mast cells 321 degranulators 320 malignant disease 320 mastocytoma, solitary 319–22 mastocytosis 319–22 syndrome 320 systemic 320 measles (rubeola) 119–20 Mee’s lines, nail disorders 362 melanocytic nevi 231–3, 243–4 congenital/acquired 231–3 melanoma 236–8 benign juvenile 233 melanosis, transient neonatal pustular 12–13

melanosis of Ito/Ota 243–4 melasma 242–3 meningococcemia 107–8 Menkes kinky hair syndrome 355–6 methotrexate 408 Mibelli angiokeratoma 288 porokeratosis 46–7 micronychia 362 Microsporum spp. 155–6 Wood’s lamp examination 7 midazolam 405 milia 11, 302–3 miliaria 78–79 minoxidil 408 moisturizers, with/without keratolytics 396–7 molluscum contagiosum 139–41 Mongolian spot 243 monilethrix 349 morbilliform eruptions drug-induced 217–18 viral 121 morphea 263–5 morphine 405 Mucha–Habermann disease 39 mucocutaneous candidiasis 149–50 mucormycosis 161–2 Muehrcke’s nails 362 multiple hamartoma syndrome 386 Munchausen syndrome by proxy 214 mycobacterial disease atypical 110–12 classification 110 leprosy 113–15 tuberculosis 112–13 mycophenolate mofetil 408 Mycoplasma pneumoniae 180 mycosis fungoides 41–3 nail disorders 359–68 alopecia areata 359 anonychia 359 Beau’s lines 359 blue nails 359–60 brachyonychia 360 clubbing 360 dystrophy 360 ectodermal dysplasia (hidrotic) 339 half-and-half (Lindsay) nails 360 hangnail 359 Hutchinson sign 360 ingrown toenails 360

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koilonychia 361 leukonychia 361 macronychia 361 malalignment of great toenails 361–2 median nail dystrophy 362 Mee’s lines 362 micronychia 362 Muehrcke’s nails 362 nail–patella syndrome 362 nevi 362–3 onychogryphosis 363 onychoheteropia 363 onycholysis 363 onychomadesis 363 onychomycosis 363–4 onychophagia 363 onychorrhexis 364 onychoschizia 364 pachyonychia congenita 364–5 paronychia 365 pincer nail 365 polyonychia 365 Pseudomonas nail 365–6 psoriasis 35, 365 pterygium 366 racquet nail 366 red lunulae 366 splinter hemorrhages 366 Terry’s nails 366 trachyonychia 366 traumatic nail injury 366–7 twenty-nail dystrophy 366–7 whitlow 367 yellow nails 367 nail–patella syndrome 362 naproxen 405 nasal glioma 27–8 necrobiosis lipoidica diabeticorum 186–7 Neisseria meningitidis 107, 270 neonatal defects 27–31 accessory tragus 30–1 aplasia cutis congenita 17–19 branchial cleft cyst/sinus 29 cephalic pustulosis 13–14 congenital dermal sinus 28–9 dermal erythropoiesis 21 encephalocele 28 lupus erythematosis 14–16 nasal glioma 27–8 neonatal scars 20–1 nevus sebaceus (of Jadassohn) 19–20

preauricular cyst/sinus 29–30 sclerema neonatorum 17 see also ichthyosis neonatal infections 21–7 candidiasis 24–6 congenital syphilis 26–7 congenital varicella 23–4 herpes neonatorum 21–3 infantile herpes 23–4 neonates 9–31 neuroblastoma 332–3 neurofibroma 315 neurofibromatosis 377–9 neutropenic dermatosis, acute febrile 191–3 nevoid basal cell carcinoma syndrome 381 nevus/i 316–17 acquired melanocytic nevi 232–3 araneus 293 basal cell nevus syndrome 381–2 Becker nevus 238–9 blue nevus 234–5 comedonicus 300–1 congenital melanocytic nevi 231 connective tissue 316 epidermal nevus 297–9 epithelioid nevus 297–9 flammeus 280–2 halo nevus 235–6 inflammatory linear verrucous epidermal (ILVEN) 298 lentiginous 236 lipomatosus 306 nail matrix 362–3 nevocellular congenital 231 nevus achromicus 255–6 nevus anemicus 286–7 nevus depigmentosus 255–6 nevus fuscoceruleus ophthalmomaxillaris 243–4 nevus of Ito 243–4 nevus of Ota 243–4 nevus sebaceus (of Jadassohn) 19–20, 299–300 nevus simplex (salmon patch) 287 nevus spilus 236 organoid 299 speckled lentiginous 236 Spitz/spindle nevus 233–4 Sutton (halo) nevus 235–6 niacin deficiency 195–7, 209–10 nickel contact dermatitis 59

417

detection kit 62 Nikolsky sign 181 nits (pediculosis), potassium hydroxide examination 6 nodules benign 302 defined 3 non-opioid analgesics 405–6 nonsteroidal anti-inflammatories, drug reactions 225 nutritional disorders 194–8 acrodermatitis enteropathica 197–8 anorexia and bulimia nervosaassociated skin disorders 194–5 kwashiorkor 195 marasmus 195 vitamin deficiencies 195–7, 209–10 nystatin 402 oculocutaneous albinism 251–2 oculodermal melanocytosis 243–4 oils and oil-free products 393 ointments 392 onychogryphosis 363 onychoheteropia 363 onycholysis 363 onychomadesis 363 onychomycosis 156–7, 363–4 onychophagia 363 onychorrhexis 364 onychoschizia 364 opioid analgesics 405 oral contraceptive pills 408 orf 141 Osler–Weber–Rendu syndrome 295 osteoma cutis 323–5 Ota, nevus 243–4 oxycodone 405 PABA/PABA esters 398 pachyonychia congenita 364–5 Pasini epidermolysis bullosa 92 palmoplantar keratodermas 376–82 basal cell nevus syndrome 381–2 neurofibromatosis 377–9 tuberous sclerosis complex 379–81 palms, hyperlinearity 370 panniculitis 308–9 papillomatosis confluent and reticulated 248 defined 3

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papillomaviruses 137–9 papular acrodermatitis 124 papular polymorphous light eruption 202–4 papular urticaria 167–8 papular/papulosquamatous disorders 33–48 papules benign 302 defined 3 Gottron 257 piezogenic pedal 307 papulovesical acrolated syndrome 124 paraneoplastic pemphigus 83, 84 parasites, antiparasitic agents 402 paronychia 365 candidal 149 Parry–Romberg syndrome 264 pastes 393 Pasteurella multocida 173 Pastia’s lines 104 patch defined 3 shagreen 381 patch tests (TRUE) 60–62 pedal papules 307 pediculosis 165–7 potassium hydroxide examination 6 pellagra, vitamin B3 deficiency 209–10 pemphigoid gestationis 84, 85 pemphigus 81–84 pemphigus erythematosus 84 pemphigus foliaceus 82, 84 penicillin drug reactions 224 see also antibiotics perforating elastosis 45–6 perianal streptococcal dermatitis 102–3 perioral dermatitis 75–76 periplakin 84 permethrin cream 164 pernio 210 petechiae, defined 3 PHACES syndrome 277–8 phenylketonuria 253–4 photodermatoses 199–205 causative drugs 222 drug-induced eruptions 221–2 photoallergic dermatitis 201–2 phototoxicity 199–201 phytophotodermatitis 202

polymorphous light eruption 202–4 solar urticaria 204–5 sunburn 199–201 photosensitizers 201 Phthirus pubis 165–6 physical abuse 211–16 PIBIDS 351 piebaldism 252–3, 253 piezogenic pedal papules 307 pigmentary disorders 229–56 Blaschko lines 46–7, 229, 297–301 confluent and reticulated papillomatosis 248 drug-induced 223 hyperpigmented disorders 229–48 postinflammatory 229–30 hypopigmented disorders 249–56 whorling 245 pigmented purpura 272–4 lichen aureus 273–4 Schamberg disease 273 pili torti 348–9 pili triangulari et canaliculi 349 pilomatrixoma 303–4 pimecrolimus 408 pitted keratolysis 108–9 pityriasis alba 53 pityriasis lichenoides chronica (PLC) 39–40 pityriasis lichenoides et varioliformis acuta (PLEVA) 39–40 pityriasis rosea 38 pityriasis rubra pilaris 36–7 pityriasis versicolor 157–9 Pityrosporum folliculitis 97 plantar warts 137 plaque, defined 3 plasters 392 podophyllin 404 poison ivy Toxicodendron 58–59 polyarteritis nodosa 267 polyonychia 365 porokeratosis 46–7 porphyrias 205–7 port wine stains 280–2 postinflammatory hypopigmentation 256 potassium hydroxide examination 4–5 potassium iodide 408 drug reactions 225 powders 393 preauricular cyst/sinus 29–30

primary lesions, definitions 3 Propionibacterium acnes 73 protein C or S deficiency 270 protein deficiency 195 prurigo, actinic 203 pseudomonal infections folliculitis 97–98 nails 365–6 pseudopseudohypoparathyroidism 324 pseudoxanthoma elasticum 384–5 psoriasis 33–6 nail disorders 35, 365 variant forms 34–5 psoriatic arthritis 35 pterygium 366 purpura anaphylactoid 268–70 defined 3 eczematoid 272 fulminans 270 Henoch–Schonlein purpura 268–70 lichen aureus 273–4 pigmented purpura 272–4 Schamberg disease 273 purpura fulminans 270–2 pustular melanosis, transient neonatal 12–13 pustular psoriasis 34 pustule, defined 3 pustulosis, neonatal cephalic 13–14 pyoderma gangrenosum 189–91 pyogenic granuloma 291–2 Ramsay Hunt syndrome 135 Raynaud phenomenon 262–3 reaction patterns 6 reaction types, drug-induced 217–27 regional patterns, and diagnosis 5 renal disease, half-and-half (Lindsay) nails 360 reticulated, defined 4 rhabdomyosarcoma 331–2 rheumatoid nodules 186 rickettsial diseases 144–7 Lyme disease 145–7 Rocky Mountain spotted fever 144–5, 171 ringworm 151 Ritter disease 105 rosacea 76–77, 404 roseola (exanthem subitum 122–3 Rothmund–Thomson syndrome 209

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rubber/adhesives, contact dermatitis 59 rubella 120–2 rubeola 119–20 Rubinstein–Taybi syndrome 360 salicylates, UVB screen 398 salicylic acid 397 salmon patch 287 sarcoidosis 193–4 Sarcoptes scabiei 163–5 scabies 163–5 potassium hydroxide examination 6 scale, defined 3 scalp preparations 397 scalp ringworm 154 scarlet fever 104–5 scars hypertrophic scars 313 neonatal scars 20–1 Schamberg disease 273 Schistosoma cercariae 174 sclerema neonatorum 17 scleroderma 262–3 localized 263–4 scrofuloderma 112 seabather’s eruption 175–6 sebaceous gland hyperplasia 10–11 seborrheic dermatitis 66–67 secondary lesions, definitions 3, 142 segmental, defined 4 serpiginous, defined 4 serum sickness, drug-induced 220–1 severe combined immunodeficiency syndrome 57–58 sexual abuse 139, 212–16 shagreen patch 381 shake lotions 393 shampoos 66, 397–8 shawl sign 257 shoe contact dermatitis 59 signs Auspitz 33 Crowe 378 Darier 320 Gower 257 Hutchinson 360 Nikolsky 181 shawl 257 sixth disease 122–3 skin area, rule of nines 391 skin biopsy 7 skin lesions, configuration 4

skin patch tests (TRUE) 60–62 skin phototypes 199 smooth muscle hamartoma 317 snake bites 173–4 soapless cleansers 54, 397 soaps 397 solar urticaria 204–5 see also photodermatoses solitary mastocytoma 319 solutions (treatment) 392 speckled lentiginous nevus 236 spider angioma 293–4 spider bites 169–70 Spiegler–Brooke syndrome 326 spirochetal disease 115–17 Spitz nevus 233–4 Sporothrix schenkii 159–60 sporotrichosis 159–60 sprays 392 staphylococcal disease 95–108 and HIV infection 142 scalded skin syndrome 105–7 secondary infection 50–51, 142 Staphylococcus aureus 50–51 steatocystoma multiplex 325 steroids see corticosteroids Stevens–Johnson syndrome (SJS) 180–2 stings, insect 168–9 strawberry hemangioma 275–80 streptococcal disease 95–108 erythema nodosum 182–3 perianal dermatitis 102–3 purpura 270 striae, corticosteroid drug reactions 224 striae distensae 313–14 Sturge–Weber syndrome 282–3 subcutaneous fat necrosis 16–17 sulfonamides, drug reactions 225 sun sensitivity genodermatoses 205–10 photodermatoses 199–205 sunburn 199–201 sunscreens 398 ‘sweaty sock syndrome’ 51 Sweet syndrome 191–3 swimmer’s eruption 175–6 swimmer’s itch 174–5 swimming-pool diseases 110–12 syphilis 115–17 neonatal 26–7 syringomas 325–6 systemic corticosteroids 54, 62,

419

395–6 systemic lupus erythematosus 258–60 systemic mastocytosis 320 systemic sclerosis 262–3 T-cell lymphoma 41–3 tacrolimus 408 Takayasu arteritis 267 tape/plasters 392 tar 396 target lesions defined 4 telangietasias 294 eruptiva macularis perstans 320 generalized essential 294–5 hereditary hemorrhagic 295 spider angioma 293 telogen effluvium 342–3 terbinafine 402 terminology of lesions 3 Terry’s nails 366 tetracyclines, drug reactions 224 thalidomide 408 therapies 391–409 thiazides, drug reactions 225 thrush 149 tick bites 170–2 tick-borne (rickettsial) diseases 144–7 tinea capitis 154–6 tinea corporis 151–3 tinea pedis 153–4 tinea unguium 156–7 tinea versicolor 157–9 tissue transglutaminase 84 titanium oxide 398 topical therapy 391 anesthetics 406 corticosteroids 62, 393–5 keratolytics 397 toxic epidermal necrolysis 180–2 drug-induced 219 toxic erythema of newborn 11–12 Toxicodendron (poison ivy) 58–59 trachyonychia 366 tragus, accessory 30–31 transient neonatal pustular melanosis 12–13 treatments 391–409 Treponema pallidum 116 trichoepithelioma 326–7 Trichophyton mentagrophytes 153 Trichophyton rubrum 153–7 trichorhinophalangeal syndrome 338 trichorrhexis invaginata 347–8 trichorrhexis nodosa 347

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trichothiodystrophy 351 trichotillomania 344–5 TRUE skin patch tests 60–62 tuberculids 113 tuberculosis 112–13 tuberous sclerosis complex 379–81 tumors see malignancies/tumors twenty-nail dystrophy 366–7 Tzanck smear 6 ulcer, defined 3 umbilical granuloma 14 umbilicated, defined 4 uncombable hair syndrome 349–50 urticaria 177–9 drug-induced 218–19 insect bite reactions 167–8 pigmentosa 319 solar 204–5 valacyclovir 408–9 varicella 132–5 neonatal 23–4 vascular disorders 275–88 angiokeratoma 287–8 blue rubber bleb syndrome 281 capillary malformations 280–2 cutis marmorata telangiectatica congenita 284–5 drug-induced vasculitis 223 glomuvenous malformations 285–6 hemangioma of infancy 275–80 Klippel–Trenaunay syndrome 283–4

leukocytoclastic vasculitis 268 nevus anemicus 286–7 nevus simplex (salmon patch) 287 Sturge–Weber syndrome 282–3 vascular malformations 280–2 vasculitis 223, 266–8 vehicles 391–3 vellus hair cysts 304–5 venereal warts 137–9 venous malformations 281 vernix caseosa 9 verrucae 137–9 vesicle, defined 3 viral culture 7 viral diseases 119–44 echovirus 126–7 erythema infectiosum (fifth disease) 123–4 Gianotti–Crosti syndrome 124–5 hand foot and mouth disease 136–7 hepatitis 128–9 herpes simplex 130–2 herpes zoster 135–6 human immunodeficiency virus (HIV) 142–4 infectious mononucleosis 127–8 measles (rubeola) 119–20 molluscum contagiosum 139–41 orf 141 roseola (exanthem subitum, sixth disease) 122–3 rubella 120–2 unilateral laterothoracic exanthem 125–6

varicella 132–5 verrucae 137–9 vitamin deficiencies 195–7, 209–10 vitiligo 249–51 Vogt–Koyanagi–Harada syndrome 249 Waardenburg syndrome 252 Weber–Cockayne epidermolysis bullosa 89, 90 Wegener granulomatosis 267 wet dressings 393 wheal, defined 3 whitlow 131, 367 Wickham striae 43 winter eczema 56 Wiskott-Aldrich syndrome 57 Wood’s lamp examination 7 X-linked ichthyosis 371 xanthogranuloma, juvenile 317–19 xanthoma eruptive 319 pseudoxanthoma elasticum 384 xeroderma pigmentosum 207–8 xerosis 56–57 zinc 409 zinc deficiency 197–8, 337 zosteriform, defined 4

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