Eczematous eruptions in childhood


Eczematous eruptions are characterized as inflamed papules and plaques, often in association with pruritus and serous discharge. The specific subtype of eczematous dermatitis is based on the clinical morphology, distribution of lesions, and, in many cases, history of exposure. Biopsy of the skin in these conditions is usually not helpful, except to consider alternative diagnoses with distinct histopathologic features.

Atopic dermatitis

Atopic dermatitis (AD) is one of the most common skin disorders seen in infants and children, and the most common eczematous disorder. Although the term eczema is commonly used, atopic dermatitis (or, less commonly, atopic eczema) is a more precise term to describe this subset of dermatitis or inflammation of skin. AD begins during the first 6 months of life in 45% of children, the first year of life in 60% of affected individuals, and before 5 years of age in at least 85% of affected individuals. , The prevalence of AD in American children is 10% to 13%, , which is consistent with the prevalence in Scandinavia , and Japan and represents a marked increase during the past several decades. Of these, 67% have mild disease, 26% have moderate disease, and 7% have severe AD. AD severity is increased in older children, in the eldest child in a family, and in Black and Hispanic children. AD occurs more often in urban areas than in rural areas, in smaller families, and in higher socioeconomic classes, which may suggest that exposure to antigenic pollutants and lack of exposure to infectious agents or other antigenic triggers early in life may play a role in the development of the dermatitis.

The 1-year prevalence of AD in adults is up to 10.2%. Despite its early onset for most patients, a meta-analysis of 7 birth cohort studies with follow-up of up to 26 years revealed no difference in AD prevalence before and after childhood (up to 14.6%), suggesting that the percentage of patients with persistence of AD into adulthood or with relapse after an interval without manifestation is relatively high, although the numbers from studies are variable. In one study, more than 80% of children with mild to moderate AD had recurrent symptoms or required medication use at least into the second decade of life. In another meta-analysis of 45 studies, children with AD of greater severity and that had been persistent already for more than 10 years had the lowest chance for clearance.

Pathogenesis of atopic dermatitis

Our improved understanding of the basis for AD has led to new therapeutic interventions (see the Management section). AD involves genetic factors dictating immune response and skin barrier integrity, as well as environmental influences, including one’s microbiome. The “inside-out” concept of AD pathogenesis focuses on immune abnormalities as being primary, and the “outside-in” theory considers the epidermal barrier dysfunction (a form of innate immunity) as primary, but it is the interplay of these factors that leads to disease.

A role for genetic alterations is suggested by the concordance of 77% in monozygotic twins and the greater probability of having AD if one or, even more so, both parents have AD. By far the most common and influential genetic change is having uniallelic or biallelic loss-of-function mutations in profilaggrin (FLG). FLG mutations occur overall in approximately 10% of the population and are the cause of ichthyosis vulgaris, a genetic disorder characterized by climate-dependent dry, scaling skin and hyperlinear palms (see Chapter 5 ). Mutations in FLG occur in 10% to 30% of AD patients. In addition to the tight linkage of AD with genes of the epidermal differentiation complex (particularly encoding profilaggrin), genome-wide association (GWA) studies have shown numerous other associated loci, primarily related to epidermal barrier function and innate-adaptive immunity.

Heterozygous loss-of-function mutations in CARD11 (encoding caspase recruitment domain-containing protein 11) have also been associated , with moderate to severe AD. Many but not all patients have concurrently been affected by other forms of atopy, pneumonia, bronchiectasis, cutaneous viral infections, oral ulcerations, autoimmunity, neutropenia, hypogammaglobulinemia, or lymphoma. Affected individuals may have reduced T-cell responsiveness in vitro with increases in B lymphocytes and abnormal B-cell differentiation. Interestingly, homozygous null mutations in CARD11 cause a form of severe combined immunodeficiency (SCID), whereas heterozygous gain-of-function mutations lead to a form of B-cell lymphoproliferative disease. Loss-of-function mutations in CARD14 (vs. the gain-of-function mutations associated with the psoriasis–pityriasis rubra pilaris spectrum) may also underlie a severe variant of AD. Heterozygous gain-of-function mutations in JAK1 have recently been associated with severe AD with hypereosinophilia but not high levels of immunoglobulin E (IgE). Eosinophilic infiltration of the liver and gastrointestinal tract with hepatosplenomegaly, autoimmune disease, and failure to thrive or short stature are other features, and patients respond to Janus kinase (JAK) inhibition.

In the acute phase of AD, environmental triggers such as irritants, allergens, and microbes and mechanical injury (scratching or rubbing) activate the skin’s innate immune system, which includes epidermal Langerhans cells and keratinocytes. , Expression of cytokines, particularly alarmins interleukin-25 (IL-25), IL-33, and thymic stromal lymphopoietin (TSLP) activate group 2 innate lymphoid cells (ILC2s), leading to T helper 2 (Th2) cell activation. Th2 cells express IL-4, -5, and -13, which promote eosinophilia and IgE production but suppress the expression of epidermal barrier proteins as well as antimicrobial peptides such as β-defensins and cathelicidin. This reduction in antimicrobial peptide production may contribute to the propensity toward development of skin infection in AD patients. TSLP, IL-4/-13, and IL-31 are thought to mediate AD pruritus. ,

Recent studies show that AD T cells also differentiate into Th22 cells, which produce IL-22 and thereby stimulate expression of keratinocyte S100As. , IL-22 has been implicated in the thickening of skin with lichenification. The role of Th17 cells in AD is not well understood, but increased levels of IL-17 are found in some patients (although not to the extent of Th2 cytokines and IL-22), particularly in young children with recent onset, patients with intrinsic (vs. extrinsic) AD, and people of Asian descent. Although adults with chronic AD also may have increases in Th1 cytokines, Th1 immunity and the Th1/Th2 ratio are very low in children with AD. The immune profile of AD is age dependent, with older children and adolescents having an intermediate profile between those of recent-onset AD in young children and in adults.

The intact epidermis itself also plays a role in the skin’s innate immune system because it functions as a barrier against water loss (preventing dry skin) and activation of the innate immune system by high-molecular-weight allergens such as dust mite antigens, foods, and microbes. This barrier primarily is composed of tight junction proteins (particularly claudins, middle of the stratum granulosum) and stratum corneum structural proteins and lipids. Filaggrin is the major component of the stratum granulosum of epidermis and binds to keratin. , Its precursor, profilaggrin, contains 10 to 12 monomers of filaggrin, and fewer monomers within the profilaggrin gene (e.g., 10 vs. 12) have been linked to an increased risk of developing AD, which complements the known increased risk of developing AD with filaggrin insufficiency. , Filaggrin is also broken down into natural moisturizing factor (NMF), particularly urocanic acid, which promotes skin hydration, providing another explanation for the dry skin of AD and ichthyosis vulgaris. NMF has been shown to be low during the first year of life, especially on the cheeks. AD in association with mutations in FLG has been shown to be more severe and more persistent. ,

The stratum corneum lipid matrix predominantly is composed of cholesterol, free fatty acids, and ceramides, densely stacked into a highly ordered, three-dimensional structure of lipid lamellae, which depends on lipid composition. These lipids are secreted by the lamellar bodies into the intercellular space of the stratum corneum. AD skin has a decreased content of very long chain ceramides , and free fatty acids, related to a deficiency of elongases that synthesize very long-chain fatty acids. The barrier can also be altered by the increased activity of proteases (especially kallikreins 5 and 7), which degrade barrier proteins and are more active at increased pH, as occurs in association with deficiency of filaggrin products (e.g., urocanic acid).

The skin (and perhaps gut) microbiome is another environmental influence on both the barrier and skin immunity. A meta-analysis of 95 studies showed that Staphylococcus aureus is found on lesional skin of 70% and nonlesional skin of 39% of patients with AD. Most of the S. aureus is methicillin-sensitive S. aureus (MSSA), although 7% of patients have methicillin-resistant S. aureus (MRSA). Flares of AD are associated with a shift in the microbiome toward a greater percentage of S. aureus (and S. epidermidis ) and reduced bacterial diversity, and the shift is greater in patients with MRSA than MSSA. Commensal organisms are recognized to play a key role in killing S. aureus and modulating immune responses. A recent birth cohort suggested that having commensal Staphylococcus spp. at day 2 could protect infants against the development of AD. Patients with AD not only have fewer commensals with active disease but also have fewer commensals that are able to kill S. aureus . Topical application of commensal organisms (e.g., Staphylococcus hominis or Roseomonas mucosa ) as treatment for AD is a new direction that in early studies appears to reduce AD severity and the use of topical corticosteroid.

Clinical features

The cardinal features of AD are pruritus, chronicity, and the age-specific morphology and distribution of lesions ( Box 3.1 ). Extent of involvement may range from mild and limited—for example, to flexural areas—to generalized and severe. The tremendous itch of AD can translate into issues with sleep, especially with wake after sleep onset, but also difficulty in falling asleep, because the pruritus tends to be worst at bedtime. Skin pain can also be a feature.

Box 3.1
American Academy of Dermatology Clinical Criteria for Atopic Dermatitis

Essential features

  • Pruritus (or parental reporting of itching or rubbing) in past 12 months

  • Eczena (acute, subacute, chronic)

    • Typical morphology and age-specific patterns (infants and young children: face, neck, extensors; spares diaper area; any age group: flexural lesions

    • Chronic or relapsing history

Important features (seen in most cases and support diagnosis)

  • Early age of onset

  • Personal and/or family history of atopy

  • IgE reactivity

  • Xerosis

Associated features (can help with diagnosis but too nonspecific for diagnosis)

  • Atypical vascular responses (e.g., delayed blanch response, facial pallor, white dermographism)

  • Keratosis pilaris/pityriasis alba/hyperlinear palms/ichthyosis

  • Ocular/periorbital changes

  • Other regional changes (perioral, periauricular)

  • Perifollicular accentuation/lichenification/prurigo lesions

Exclusionary conditions in children

  • Contact dermatitis (irritant or allergic; can be concurrent)

  • Immunodeficiency (and other causes of erythroderma)

  • Psoriasis

  • Seborrheic dermatitis

  • Ichthyoses

  • Scabies

  • Cutaneous T-cell lymphoma

  • Photosensitivity disorders

IgE, Immunoglobulin E.

The morphology of AD and distribution of lesions is often age dependent, although there is considerable overlap (e.g., infants may show the typical distribution of adult AD). Infants with AD typically have intense itching, erythema, papules, vesicles, oozing, and crusting. In infants, AD often begins on the cheeks, forehead, or scalp ( Figs. 3.1 , 3.2 , and 3.3 ) and then may extend to the trunk ( Fig. 3.4 ) or particularly the extensor aspects of the extremities in scattered, ill-defined, often symmetric patches. Generalized xerosis is common. Exacerbation of facial dermatitis on the medial cheeks and chin is often seen concomitant with teething and initiating foods. This localization likely reflects exposure to irritating saliva and foods, although contact dermatitis or urticaria may contribute. By 8 to 10 months of age the extensor surfaces of the arms and legs often show dermatitis ( Fig. 3.5 ), perhaps because of the role of friction associated with crawling and the exposure of these sites to irritant and allergenic triggers such as those found in carpets. Although dermatitis of the antecubital and popliteal fossae, periorbital areas, and neck are more commonly involved in older children and adolescents, these sites may be affected in infants and young children as well ( Fig. 3.6 ). Typically, lesions of AD spare the groin and diaper area during infancy ( Fig. 3.7 ), which aids in the diagnosis. This sparing likely reflects the combination of increased hydration in the diaper area, protection from triggers by the diaper, and inaccessibility to scratching and rubbing. The “headlight sign” has been used to describe the typical sparing of the nose and medial cheeks in AD, even when there is extensive facial involvement elsewhere (see Fig. 3.1 ).

Fig. 3.1, Acute atopic dermatitis (AD) on the cheek of an infant. This boy shows the headlight sign, with relative sparing of the midface and immediate perioral area. The edema and exudation is typical of infantile AD and should not be confused with secondary bacterial infection.

Fig. 3.2, Acute atopic dermatitis in an infant. Despite extensive perioral and nasal tip involvement, the immediate perinasal and infralabial areas are spared.

Fig. 3.4, Atopic dermatitis on the trunk and extremities of an infant. In this baby, note the accentuation at the nipple and relative sparing of the antecubital fold.

Fig. 3.5, Involvement of the extensor surfaces of the legs and arms is commonly seen during the infantile phase of atopic dermatitis beginning at about 8 months of age, concomitant with crawling and exposure to irritant and allergenic triggers.

Fig. 3.6, Although antecubital and popliteal fossa involvement is typical of the childhood and adult phases of atopic dermatitis, infants not uncommonly will show involvement at these fold areas. This infant is demonstrating his response to the pruritus.

Fig. 3.7, Relative sparing of the diaper area is typical in infants with atopic dermatitis, likely because of the occlusion of this site and protection from scratching and rubbing, as well as from allergenic triggers.

Not uncommonly, infants initially show signs of seborrheic dermatitis, particularly during the first month or two of life. The associated pruritus and the dry (rather than greasier) scale suggest the combination of both disorders (see Fig. 3.3 ); the seborrheic component usually clears by 6 to 12 months, whereas the AD features persist. Alopecia may accompany the scalp involvement because of inflammation and chronic rubbing.

Fig. 3.3, Atopic dermatitis (AD) and seborrheic dermatitis. Seborrheic dermatitis and AD often occur concurrently, especially in infants with early atopic dermatitis. In addition to the presence of AD on the face, head rubbing or excoriations (suggesting scalp pruritus) and recalcitrance to traditional management for seborrheic dermatitis are clues to the combination.

By about 2 years of age, children with AD are less likely to have exudative and crusted lesions and have a greater tendency toward chronicity and lichenification ( Fig. 3.8 ). Eruptions are characteristically drier and more papular and often occur as circumscribed scaly patches. The classic areas of involvement in this group are the wrists, ankles, hands, feet, neck, and antecubital and popliteal regions ( Figs. 3.9 and 3.10 ). Facial involvement switches from cheeks and chin to periorbital ( Figs. 3.11 and 3.12 ) and perioral, the latter sometimes manifesting as “lip-licker’s dermatitis” (see Fig. 3.56 ). Dermatitis of the nipples ( Fig. 3.13 ) occurs in some infants and children and can be exacerbated by rubbing on clothing. Pruritus is often severe. Some children with AD show nummular or coin-shaped lesions with sharply defined oval scaly plaques on the face, trunk, and extremities (see Nummular Dermatitis section). In Black children, the lesions of AD are often more papular and follicular ( Fig. 3.14 ). Although localization at flexural areas is more common, some children show an inverse pattern with involvement primarily of extensor areas. Lymphadenopathy may be a prominent feature in affected children ( Fig. 3.15 ), reflecting the role of lymph nodes in handling local infection and inflammation. Nail dystrophy may be seen when fingers are affected, indicating involvement of the nail matrix; children may show secondary staphylococcal or pseudomonal paronychia.

Fig. 3.8, Extensive lichenification on the legs of this affected toddler. Note the follicular accentuation and relative sparing of the popliteal areas.

Fig. 3.9, Xerosis with erythema, fissuring, and crusting on the neck and face in this 10-year-old boy.

Fig. 3.10, Atopic dermatitis on the ankle and dorsal aspect of the foot. Note the lichenification and crusting.

Fig. 3.11, Facial atopic dermatitis in children and adolescents typically affects the periorbital and perioral areas.

Fig. 3.56, Lip-licker’s dermatitis. Chronic contact dermatitis with lichenification and hyperpigmentation in the shape of licking from the tongue and sometimes beyond.

Fig. 3.13, Nipple eczema may occur in infants and children with atopic dermatitis, even without much truncal involvement elsewhere, and is exacerbated by the rubbing of clothes on the affected nipples.

Fig. 3.14, Follicular (or papular) atopic dermatitis (AD) is more commonly seen in Black children with AD and can be difficult to distinguish from lichen nitidus (see Fig. 4.61 ) and, if on the elbows or knees, juvenile frictional lichenoid dermatosis (see Fig. 3.50 ).

Fig. 3.15, Lymphadenopathy is a common accompanying feature of severe atopic dermatitis (AD), especially when the AD is associated with infection.

By later childhood and adolescence, predominant areas of involvement include the flexural folds ( Fig. 3.16 ), the face and neck, the upper arms and back, and the dorsal aspect of the hands, feet, fingers, and toes. The eruption is characterized by dry, scaling erythematous papules and plaques and by the formation of large lichenified plaques from lesional chronicity. Weeping, crusting, and exudation may occur from the AD itself but usually is the result of superimposed staphylococcal infection or allergic contact dermatitis. Prurigo nodularis, characterized by well-circumscribed, usually hyperpigmented thickened papules, most commonly on the lower extremities, is most often seen during adolescence ( Fig. 3.17 ).

Fig. 3.16, Involvement of antecubital and popliteal areas is characteristic in children and adolescents with atopic dermatitis. Note the associated crusting and postinflammatory hypopigmentation.

Fig. 3.17, Prurigo nodularis. Well-circumscribed, usually hyperpigmented lichenified papules appear most commonly on the lower extremities. Recurrent gouging of these intensely pruritic papules results in scarring.

Postinflammatory reduction of pigmentation may occur at any age, especially in individuals with darker skin. Although postinflammatory hypopigmentation is more common (see Figs. 3.16 and 3.18 ), pigment reduction may be severe enough to be depigmented, resembling vitiligo ( Fig. 3.19 ), especially on distal extremities. The pigmentary changes are transient and are reversible when the underlying inflammation is controlled; however, 6 months or more may be required for repigmentation (and years if vitiliginous), and sun exposure may accentuate the differences between uninvolved and hypopigmented skin areas. In contrast, hyperpigmentation is predominantly noted at sites of lichenification ( Figs. 3.12 , 3.15 , 3.17 , and 3.20 .), because the thickened epidermis accumulates epidermal melanin pigment, especially in darker skinned individuals. Children with lichenification show accentuation of skin ( Fig. 3.21 ). Parents may mistake the postinflammatory pigment change seen in some children for scarring or a toxicity of topically applied medications and need reassurance. AD lesions are not usually scarring, but secondary infection and deep gouging of lesions can leave residual scarring and long-term pigmentary change.

Fig. 3.18, Postinflammatory hypopigmentation of atopic dermatitis (AD). Postinflammatory hypopigmentation is a sequela of AD inflammation, is not related to use of topical steroids, and is not scarring. The postinflammatory hypopigmentation is particularly prominent during summer months, when the surrounding unaffected skin tans after exposure to ultraviolet light, and tends to clear spontaneously after several months if further flares of dermatitis at the site are prevented.

Fig. 3.19, Depigmentation resembling vitiligo occasionally occurs in severely affected children, particularly at sites of chronic atopic dermatitis (AD) on the dorsal aspect of the hands and feet, wrists, and ankles. Repigmentation can occur slowly with improved AD control at these sites.

Fig. 3.12, The periorbital areas can be severely lichenified with chronic eyelid dermatitis. Consideration should be given to patch testing with chronic involvement at this site.

Fig. 3.20, Lichenification. Accentuation of skin markings are notable in thickened, lichenified skin of chronic atopic dermatitis. In darker-skinned individuals, hyperpigmentation tends to be associated with the lichenification.

Fig. 3.21, Lichenification appears hyperpigmented in darker skin types (in contrast, see Fig. 3.10 with lichenification at the same site of a child with light skin).

Other clinical signs

Several other clinical signs are seen with increased incidence in children with AD, although they may appear in children without AD as well. Dermographism, a manifestation of the triple response of Lewis that occurs in approximately 5% of the normal population, is characterized by a red line, flare, and wheal reaction. A red line develops within 15 seconds at the exact site of stroking, followed within 15 to 45 seconds by an erythematous flare (because of an axon-reflex vasodilation of arterioles). The response finally eventuates in a wheal (because of transudation of fluid from the injured capillaries in the original stroke line) 1 to 3 minutes later. Individuals with AD often demonstrate a paradoxical blanching of the skin termed white dermographism ( Fig. 3.22 ). The initial red line is replaced, generally within 10 seconds, by a white line without an associated wheal. Patients with AD may also show circumoral pallor, thought to relate to local edema and vasoconstriction.

Fig. 3.22, White dermographism is the paradoxical blanching of skin after stroking.

Follicular hyperkeratosis, or chicken-skin appearance, particularly on the lateral aspects of the face, buttocks, and outer aspects of the upper arms and thighs, is termed keratosis pilaris (see Figs. 7.24 and 7.25 ). Keratosis pilaris is not seen at birth but is common from early childhood onward and often persists into adulthood. Each lesion represents a large cornified plug in the upper part of the hair follicles, often with surrounding inflammation and vasodilation. Keratosis pilaris is more commonly associated with AD in children who have ichthyosis vulgaris. Moisturizers alone tend to be insufficient as therapy for keratosis pilaris. Keratolytic agents such as urea or α-hydroxy acids may be helpful. Their use is limited, however, by the increased potential for irritation in children with AD. Treatment should be discouraged unless of significant cosmetic importance, because keratosis pilaris is almost always asymptomatic.

Lichen spinulosus manifests as round collections of numerous tiny, skin-colored to hypopigmented dry spiny papules ( Fig. 3.23 ). More common in Black children, lichen spinulosus usually occurs on the trunk or extremities. Lesions tend to be asymptomatic and may respond to application of emollients and mild topical corticosteroids. Children with AD also show an increased incidence of pityriasis alba, nummular dermatitis, dyshidrotic eczema, and juvenile plantar dermatosis (see related sections).

Fig. 3.23, Lichen spinulosus is commonly seen in children with dry skin and sometimes with atopic dermatitis. The characteristic collections of tiny, discrete flat-topped papules are usually asymptomatic.

Individuals with atopic disorders have a distinct tendency toward an extra line or groove of the lower eyelid, the so-called “atopic pleat” ( Fig. 3.24 ). Seen just below the lower lid of both eyes, the atopic pleat may be present at birth or shortly thereafter and is often retained throughout life. This groove (commonly referred to as a Dennie–Morgan fold ) may result from edema of the lower eyelids and skin thickening; it represents a feature of the atopic diathesis rather than a pathognomonic marker of AD. The atopic pleat has been found with increased incidence in Black children. Slate-gray to violaceous infraorbital discolorations (“allergic shiners”), with or without swelling, are also seen in patients with allergies and in patients with AD. Allergic shiners are thought to be a manifestation of vascular stasis induced by pressure on underlying venous plexuses by edema of the nasal and paranasal cavities; the swelling and discoloration become more prominent as a result of repeated rubbing of the eyes and postinflammatory pigment darkening. Another clinical feature, an exaggerated linear nasal crease, is caused by rubbing of the nasal tip (the so-called “allergic salute”) and occurs in 7% of schoolchildren. Milia (tiny inclusion cysts; see Chapter 9 ) of the periorbital area are common in preadolescents ( Fig. 3.25 ), may resemble acne, and are thought to result from the recurrent rubbing. Milia tend to resolve spontaneously, although years may be required; extraction may be performed but is rarely necessary.

Fig. 3.24, Atopic pleats. Accentuated lines or grooves (Dennie–Morgan folds) are seen below the margin of the lower eyelids. This is a sign of the allergic diathesis and is not specific to atopic dermatitis. Note the mild periorbital dermatitis with hyperpigmentation.

Fig. 3.25, Milia. Note that this child has numerous milia of the periorbital area, small inclusion cysts that are often a sign of chronic rubbing of the skin from periorbital dermatitis and/or allergic conjunctivitis. Milia clear spontaneously but after months to years.

Many patients with atopic conditions exhibit an increased number of fine lines and accentuated markings of the palms ( Fig. 3.26 ). These accentuated palmar markings often are a clue to the concurrent diagnosis of ichthyosis vulgaris (see the previous discussion of the pathomechanism and also Chapter 5 ), a relatively common condition seen with increased incidence in children with AD. Ichthyosis vulgaris is considered a “semi-dominant” disorder because heterozygotes show manifestations (especially in drier, colder climates), but homozygotes tend to have greater severity. Most individuals with ichthyosis vulgaris merely think they have dry skin until the diagnosis is made when they are seen for AD. Diagnosis is based on the accentuated markings on the palms and soles, the characteristic generalized scaling with larger and more severe scaling on the lower extremities, worsening during winter months, and often positive family history.

Fig. 3.26, Accentuated palmar creases. Hyperlinearity of the palms is a sign of concurrent ichthyosis vulgaris (see Chapter 5 ), a genetic disorder of skin associated with an increased risk of atopic dermatitis.

Allergic keratoconjunctivitis (AKC) is a chronic noninfectious inflammatory condition and is one of the most severe ophthalmic complications associated with atopic dermatitis. AKC has been described in up to 30% of children with AD. It typically begins during late teenage years but has been described as early as 7 years of age. Patients experience chronic itching and pain of the eyes, as well as tearing, redness, and blurred vision. It requires prompt and effective treatment to prevent permanent vision loss; moderate to severe eye irritation, increased redness, discharge, and any visual symptoms are features that require more urgent referral to an ophthalmologist. Complications of AKC include cataracts, keratoconus, infectious keratitis, blepharitis, tear dysfunction, and steroid-induced glaucoma. Treatment options include a combination of mast cell inhibitors, antihistamines, corticosteroids, and calcineurin inhibitors.

Posterior subcapsular cataracts have been described in up to 13% of adult patients with severe AD. Rarely seen in children, these cataracts are usually asymptomatic. Keratoconus (elongation and thinning of the corneal surface) has been reported in about 1% of patients with AD and seems to develop independently of cataracts. Keratoconus is exacerbated by continuous rubbing of the eyes and may require corneal transplantation.

Effect on quality of life

The quality of life in infants, children, and adolescents with moderate to severe dermatitis is significantly reduced, and having severe AD during childhood can have a great impact on psychosocial development. Infants with AD have been shown to be excessively dependent and fearful. Sleep disturbance affects up to 60% of children with AD overall and 83% of children during flares. Impaired sleep quality occurs in children with mild AD and even inactive AD but is particularly problematic in children with more severe disease, especially wake after sleep onset. Neurocognitive function is impaired in children with sleep problems. Even in clinical remission, children with AD show more sleep disturbance than healthy children, including increased nocturnal wakefulness and a longer latency to rapid-eye-movement (REM) sleep.

Disfigurement associated with moderate to severe AD, coupled with the reduction in sleep, restlessness, and fatigue at school, as well as limitations in participation in sports, isolates the affected child and strains relationships with peers and with teachers.

As a chronic disorder that requires frequent attention, the family of a child with AD carries a high financial burden of parental missed days from work for doctor visits and home care; lost wages owing to interruption of employment; expensive medications; and the costs of special or additional bedding, clothes, and food. The socioeconomic impact of AD in the United States alone is estimated to be $364 million to $3.8 billion annually. The demonstrated average reduction by 1 to 2 hours of parental sleep nightly also translates into increased parental stress and the tendency of affected children to cosleep with parents affects family dynamics. These stressful psychological factors often exacerbate the AD, as may concurrent infectious illness or the stress of assignments at school.

Comorbidities of atopic dermatitis

Allergic disorders

AD is often associated with other forms of atopy, with 70% to 80% of affected children having an associated increase in IgE levels (“extrinsic” AD). Children with AD overall have a two- to threefold increased risk of developing asthma by 6 years of age and a threefold increased risk of developing allergic rhinitis (AR) compared with children without AD. Greater severity, earlier onset, persistence of the AD, polysensitization, having at least one variant in FLG , and parental history of allergic disease further increase the odds of developing these other atopic disorders. Overall, asthma occurs by 6 years of age in approximately 30% of children with AD; AR develops in 43% to 80% of children with AD.

The risk of food allergy is also increased with AD. In one study of almost 1100 infants with predominantly mild to moderate AD who enrolled at 3 to 18 months without a history of food allergy at baseline and were followed prospectively for 36 months, allergy to at least one food developed in 15.9% overall. The most common triggers were peanut (6.6%), cow’s milk (4.3%), and egg white (3.9%). The percentage with food allergies increases with greater AD severity, earlier onset, and AD persistence.

Negative predictive values are high for antigen-specific IgE (sIgE), but positive predictive values for sIgE testing tend to be much lower, especially if the cutoff values are low. True food allergy (based on clinical manifestations or food challenge) must be differentiated from the positive sIgE, which is common in infants and children with AD (including in 64% of those with AD beginning before 3 months of age). In one study, 89% of food challenges based on positive sIgE testing were negative, consistent with a false-positive rate for true food allergy. Food allergies to cow’s milk and egg usually resolve during childhood, whereas peanut allergy tends to persist.

The approach to prevention of peanut allergy has dramatically changed during the past few years, based on the 2015 Learning Early About Peanut Allergy study, which showed that early introduction (4 to 11 months) of peanut reduced the risk of developing peanut allergy at 60 months of age (1.9%) compared with delayed introduction (13.7%). A panel of the National Institutes of Allergy and Infectious Diseases amended early guidelines to recommend that children with severe AD, egg allergy, or both be exposed to peanut as early as 4 to 6 months of life, but only after evaluation by an allergy specialist (by skin prick testing [SPT], sIgE, or both). Severe AD has been defined as having persistent or frequently recurrent AD with typical morphology and distribution and requiring frequent application of prescription-strength topical antiinflammatory medications despite appropriate use of emollients. Having a low peanut sIgE (<0.35; 6 to 7 g over three or more feedings) or minimal skin prick test reaction (0 to 2 mm) translates into an option to introduce the peanut at home or with supervision in the office setting; having an sIgE of 0.35 or greater should lead to referral to a specialist (given the poor predictive value for a positive sIgE). Having a SPT of 3 to 7 mm allows supervised administration in the office or oral food challenge, whereas having a reaction of more than 8 mm suggests a high likelihood of existent peanut allergy and requires appropriate management with strict peanut avoidance. For those with mild to moderate AD, peanut can be introduced at 4 to 6 months without further assessment (and as desired in those without AD, but ideally well before 1 year of age). Instructions for home feeding, including foods, amounts, subsequent observation, and signs of reaction have been published in the dermatology literature. The expert panel did not recommend a broader panel of food allergen testing, given the poor positive predictive value and in an effort to avoid unnecessary dietary restriction.

The parallel increase in the prevalence of these various atopic disorders, including AD, suggests a shared mechanism or triggers. In fact, AD is often the first atopic feature in children who later develop asthma or AR, although food allergy not uncommonly precedes AD. The atopic march refers to the earlier occurrence of AD and later occurrence of one or more of these allergic disorders. Having both AD and allergic sensitization greatly increases the risk of developing asthma and AR.

The concurrence of allergic disorders with AD implicates the AD skin barrier abnormality in increasing the risk through promoting early local and systemic immune reactivity to antigens, with later development of food and environmental allergies, asthma, and allergic rhinitis. The importance of barrier integrity is supported by the association of FLG mutations with increased risk of asthma, allergic rhinitis, and food allergies, but only in children with prior development of AD. However, latent class analyses have suggested that AD occurs before asthma or AR less often than previously noted, and studies have suggested the concept of multimorbidity with a shared underlying basis (e.g., genetic and/or environmental) driving these disorders.

Biomarker and cluster analyses have begun to further subclassify patients according to phenotype (clinical features) or endotype (biologic/laboratory features that are associated with clinical phenotypes). The ability to study biomarkers derived noninvasively through tape strips is likely to help subphenotype pediatric patients in the future, allowing prediction of AD course, risk of comorbidities, and therapeutic responses.

Infectious complications

In contrast to a prevalence of a carrier state in 5% to 20% of individuals who have no atopic condition, S. aureus is recovered in up to 90% of patients from lesions of AD—up to 76% from uninvolved (normal) skin and 50% to 60% from the anterior nares. The increased adherence of S. aureus to the epidermal cells of individuals with AD and a failure to produce endogenous antimicrobial peptides in the inflamed skin of patients with AD may account for the high rate of S. aureus colonization and infection. Although secondary infection in AD is usually from S. aureus (72%), 16% of cultures in infected patients with AD yield S. pyogenes, and 14% are mixed cultures. Patients infected with group A Streptococcus were more likely to be febrile, have facial and periorbital involvement, have bacteremia and cellulitis, and be hospitalized compared with those infected with S. aureus alone.

The pyoderma associated with AD is usually manifested by erythema with exudation and crusting ( Fig. 3.27 , A and B ), particularly at sites of scratching, and occasionally by small pustules at sites of dermatitis ( Fig. 3.28 ). This complication must be considered whenever a flare of chronic AD develops or fails to respond to appropriate therapy. S. aureus exacerbates the AD through (1) release of super-antigen toxins, which enhance T-cell activation; (2) activation of superantigen-specific and allergen-specific T cells ; (3) expression of IgE antistaphylococcal antibodies , ; and (4) increased expression of Th2 cytokines (including IL-31 and TSLP, which are known to cause pruritus directly) and increased expression of IL-22, which is associated with epidermal thickening. Superantigen production also increases the expression of an alternative glucocorticoid receptor that does not bind to topical corticosteroids, leading to resistance. Other factors produced by S. aureus are likely to exacerbate AD as well. These observations emphasize the role of S. aureus as an important trigger of AD and endorse therapies that decrease the numbers of bacteria on the skin.

Fig. 3.27, Staphylococcal infection in atopic dermatitis. Sites of excoriation on the dorsal aspects of the hands (A) and upper back (B) are oozing and crusted. Note the erythema and mild associated edema. The dermatitis and the infection improved with oral administration of cephalexin, and the use of daily baths with sodium hypochlorite helped to maintain control while minimizing crusting.

Fig. 3.28, Staphylococcal infection with pustules in atopic dermatitis (AD). Discrete nongrouped pustules and crusting overlying erythema and swelling of the periorbital area of a child with severe AD.

Although MRSA colonization and superinfection of AD is increasing, the majority of children with AD harbor MSSA. , MRSA infection may manifest as pustules ( Fig. 3.29 , A ), abscesses (see Fig. 3.29 , B ), or crusting that is indistinguishable clinically from MSSA infection but much more difficult to eradicate; suppression of MRSA often requires that the entire family (including pets, who can harbor MRSA) be treated initially or even on an intermittent basis to reduce colonization, such as with intranasal mupirocin ointment and once to twice weekly bleach baths or use of sodium hypochlorite–containing cleansers.

Fig. 3.29, Methicillin-resistant Staphylococcus aureus (MRSA) infection in atopic dermatitis (AD). (A) Staphylococcal pustulosis on the knees in a girl with severe AD and recurrent MRSA infections. (B) Her father has an MRSA abscess on the arm. Decolonization of the entire family is important.

Greater cutaneous dissemination of certain viral infections has also been noted in children with AD and has been attributed to defects in the generation of antimicrobial peptide and the relative deficiency of Thl cytokine generation and cytotoxic T-cell function. Molluscum contagiosum is a cutaneous viral infection of childhood that most commonly affects the trunk, axillae, antecubital, popliteal fossae, and crural areas (see Chapter 15 ). Lesions are usually small, dome-shaped papules that often show central umbilication. The often-extensive molluscum lesions tend to be most numerous at sites of active dermatitis and can induce pruritus as well as dermatitis around the molluscum papules (“molluscum dermatitis”).

Eczema herpeticum (EH, also termed Kaposi varicelliform eruption ) describes the explosive development of a vesiculopustular eruption caused by herpes simplex virus (HSV) in an individual with an atopic condition. Children with more severe AD and other atopic conditions are at greatest risk. The tendency toward eczema herpeticum is associated with an elevated Th2 and reduced Th1 T-cell immune response to HSV1. , The clustering and often umbilication of the vesicles is characteristic ( Figs. 3.30 and 3.31 ; see Fig. 8.15 ), with sites of the dermatitis most commonly affected. Nevertheless, with a confluence of vesicles and crusting, eczema herpeticum can be mistaken for bacterial infection ( Fig. 3.32 ). The diagnosis can be verified by polymerase chain reaction (PCR) and viral culture. If these tests are not available, a Tzanck test can be performed by scraping the floor of vesicles and, after staining the smear with Giemsa or Wright stain, searching for multinuclear virus “giant cells” or balloon cells.

Fig. 3.30, Eczema herpeticum (Kaposi varicelliform eruption). Grouped vesiculopustular lesions on the face, retroauricular, and neck areas. Several of the pustules are beginning to show umbilication. The intense erythema is harder to appreciate in dark skin.

Fig. 3.31, Eczema herpeticum. These small, round umbilicated vesicles and punched out erosions are typical lesions of herpes simplex infection.

Fig. 3.32, Eczema herpeticum. Infection tends to occur at sites of atopic dermatitis, in this case the periorbital and perioral areas. Although eczema herpeticum with confluence of vesicles and extensive crusting can be confused with bacterial infection, some children also have secondary bacterial infection and need treatment with both acyclovir and antibiotic, such as cephalexin.

Hospitalization may be necessary, especially in infants younger than 1 year and in association with fever or other systemic symptoms. Early administration of acyclovir has been shown to lead to better outcomes for EH, and use of topical corticosteroids or calcineurin inhibitors has not been associated with poorer outcomes in children hospitalized with EH. Systemic antibiotics should be administered if secondary bacterial infection is strongly suspected but should not be used empirically.

Eczema vaccinatum was a problem when smallpox vaccinations were compulsory, most commonly contracted by accidental contact with a recently vaccinated individual. The global threat of bioterrorism and consideration of smallpox vaccinations has again brought to attention the risk of eczema vaccinatum for patients, particularly children, with AD. Eczema vaccinatum is characterized by the widespread cutaneous dissemination of vaccinia viral lesions that manifest as firm, deep-seated vesicles or pustules that are all in the same stage of development (see Chapter 15 ). Lesions may become umbilicated or confluent.

Eczema coxsackium (see Chapter 16 ) is a recently coined term to describe the unusual cutaneous concentration in sites of previous or current AD of vesicles and erosions from coxsackievirus A6 and, less commonly, coxsackievirus A16 infection, which could be confused with EH ( Fig. 3.33 ). , Fever, oral erosions or ulcerations, and sore throat or mouth are among the most common associated symptoms. Lesions clear spontaneously in an average of 12 days but may persist for a month.

Fig. 3.33, Eczema coxsackium. Children with atopic dermatitis (AD) are at increased risk of widespread cutaneous lesions from coxsackie infection, especially coxsackie A6, which can cluster at sites of AD and be confused with eczema herpeticum.

Reactivity to Malassezia has been blamed for recalcitrant AD of the head and neck in adolescents. Although there are no documented differences in Malassezia species colonization, patients with head and neck AD are more likely to have positive skin prick test results and Malassezia -specific IgE compared with healthy control subjects and patients with atopy without head and neck dermatitis. These patients may benefit from a 1- to 2-month course of daily itraconazole or fluconazole followed by long-term weekly treatment.

Other comorbidities

AD is also associated with several neuropsychiatric disorders, including anxiety, depression, attention-deficit/hyperactivity disorder (ADHD), conduct disorder, and autism. In preschool children with AD, there is also a higher risk of enuresis, encopresis, and attachment disorder. The risk of ADHD is highest in children with more severe disease and greater sleep deprivation, reinforcing the impact of these factors on neurocognitive function. One provocative study suggested that use of sedating antihistamines increased the risk of developing ADHD, but further study is needed. Although restlessness and inattention at school, common in sleep-deprived, itchy AD children, may be features that resemble those of ADHD, these are not sufficient to meet screening criteria for ADHD for the majority of AD children. Families are also affected, with higher risks of anxiety and depression in caregivers. Children with AD have a higher risk of injury requiring medical attention, related both to comorbid psychiatric and behavioral disorders and their atopy. Additional emerging comorbidities are autoimmune disorders (alopecia areata, vitiligo, rheumatoid arthritis, and inflammatory bowel disease ) and obesity, especially during infancy and including central obesity. ,

Differential diagnosis

AD is a chronic fluctuating disease. The distribution and morphology of lesions vary with age, but itching is the cardinal symptom of this disorder. Although many skin conditions may occasionally resemble AD, certain characteristics assist in their differentiation. Three common forms of dermatitis that are seen often with AD are contact dermatitis (both irritant and allergic), seborrheic dermatitis, and nummular dermatitis. Each of these disorders is discussed in detail later in the chapters and, as such, is mentioned only briefly here as relevant to AD.

Seborrheic dermatitis is characterized by a greasy yellow or salmon-colored scaly eruption that may involve the scalp, cheeks, trunk, extremities, and diaper area. The major differentiating features include a tendency toward earlier onset, characteristic greasy yellowish or salmon-colored lesions with a predisposition for intertriginous areas, a generally well-circumscribed eruption, and a relative absence of pruritus (see later). Infants may show both atopic and seborrheic dermatitis (see Fig. 3.3 ), with progression or persistence of the atopic lesions as the seborrheic dermatitis subsides.

Irritant and allergic forms of contact dermatitis are common comorbidities of AD (see related section). Primary irritant dermatitis is commonly seen in infants and young children on the cheeks and the chin (owing in part to the irritation of saliva), the extensor surfaces of the extremities (as a result of harsh soaps, detergents, or rough fabrics), and the diaper area (usually spared in AD; primarily from feces and vigorous cleansing). Irritant dermatitis may also result from bubble baths, personal care products, and handled materials such as modeling clays. Primary irritant dermatitis is generally milder, less pruritic to asymptomatic, and not as eczematous and oozing as the eruptions seen in association with AD. Irritant contact dermatitis to saliva and to exposure to harsh soaps and fabrics occurs more often in children with concomitant AD.

Allergic contact dermatitis (ACD), although relatively uncommon in the first few months of life, can mimic almost any type of eczematous eruption and is characterized by a well-circumscribed pruritic, erythematous, papular, and vesicular eruption. Although such eruptions involute spontaneously on identification and removal of the cause, this disorder often requires a carefully detailed history and prolonged observation before the true causative agent is identified. ACD to nickel occurs often in children with AD and may be misdiagnosed as recalcitrant periumbilical AD. Patients with recalcitrant AD may have concomitant allergic contact reactions, particularly to nickel and less often to topically applied medications and emollients, suggesting the role for patch testing. Positive patch tests for potential allergens other than nickel have been described in up to 45% of children with AD, , , and more than half of these are reactions to components in their emollients (lanolin, neomycin, formaldehyde, sesquiterpene lactone mix [including parthenolide], compositae mix, and fragrances) or foaming products (cocamidopropyl betaine). Topical corticosteroids are unusual contact allergens but can be tested based on structural class with tixocortol-21-pivalate, budesonide, and hydrocortisone 17-butyrate. , ,

Nummular dermatitis is a distinctive disorder characterized by coin-shaped lesions. Measuring 1 cm or more in diameter, lesions of nummular dermatitis develop on dry skin and are more often seen during dry winter months. The eruption is characterized by discrete erythematous round plaques formed by the confluence of papules and vesicles ( Figs. 3.34 and 3.35 ). Nummular lesions tend to be secondarily infected and often more recalcitrant to topical therapy. If the combination of medium-strength to potent topical steroid plus topical antibiotic does not suffice, a course of systemic antibiotic may be required. Dilute sodium hypochlorite baths should also be considered.

Fig. 3.34, Nummular dermatitis. Characterized by well-defined, round (coin-shaped or nummular) plaques of vesiculopapules overlying erythema and edema. Oozing and secondary infection are common.

Fig. 3.35, Nummular dermatitis. Some patients show multiple nummular plaques.

The lesions of psoriasis, another common skin disease of children, are bright red and topped with loosely adherent silvery micaceous scale (see Chapter 4 ). Psoriatic lesions usually show a sharply delineated edge and have a predilection for the extensor surfaces (particularly the elbows and knees), the scalp, the buttock, and the genital regions. Approximately 5% of children with psoriasis also show dermatitis, either as typical psoriasis and AD lesions or a psoriasiform dermatitis; these children often have a family history of both atopy and psoriasis.

Scabies in infants and children is commonly complicated by eczematous changes because of scratching and rubbing of involved areas or the application of harsh topical therapeutic agents. The diagnosis of scabies is best made by the history of itching, a characteristic distribution of lesions, the recognition of primary lesions (particularly the pathognomonic burrow when present), positive identification of the mite on microscopic examination of skin scrapings, and the presence of infestation among the patient’s family or associates (see Chapter 18 ).

Langerhans cell histiocytosis (LCH) most commonly occurs before 3 years of age (see Chapter 10 ). In affected neonates, reddish-brown, purpuric, crusted papules or vesiculopapules are typically present. In infants this skin eruption is often characterized as a scaly, erythematous seborrheic eruption on the scalp, behind the ears, and in the intertriginous regions. On close inspection the presence of reddish-brown, petechial or purpuric lichenoid papules or vesicular or crusted papules in infants is typical. Cutaneous biopsy and identification of CD1a + Langerhans cells by immunostaining confirms the diagnosis of LCH.

Acrodermatitis enteropathica is an autosomal recessive disorder characterized by vesiculobullous eczematoid lesions of the acral and periorificial areas, failure to thrive, diarrhea, alopecia, nail dystrophy, and frequent secondary bacterial or candidal infection (see Chapters 2 and 24 ). The characteristic distribution of lesions accompanied by listlessness, diarrhea, failure to thrive, and low serum zinc levels differentiate lesions of acrodermatitis enteropathica from those of AD. Usually a disorder in formula-fed babies with the hereditary form, acrodermatitis enteropathica may also occur in breastfed babies as a result of deficient zinc secretion into maternal breast milk.

Dermatitis during the neonatal or infantile periods is also seen in immune dysregulation, polyendocrinopathy, enteropathy, X-linked (IPEX) syndrome, which manifests with early onset intractable diarrhea and type 1 diabetes mellitus. The disorder is often fatal during the first year of life. The cutaneous manifestations are seen in 70% of affected babies and tend to be the first sign. Although an atopic-like dermatitis is most common, the eruption has also been described as psoriasiform or resembling ichthyosiform erythroderma. Lesions are often pruritic, secondarily infected by S. aureus , and resistant to treatment with topical corticosteroids. Other common cutaneous manifestations include severe cheilitis, onychodystrophy, and alopecia. Infections of the upper and lower airways and gastrointestinal (GI) tract are common, and affected patients may succumb to sepsis. Food allergies and high levels of IgE and eosinophils are also associated. The autoimmune enteropathy is characterized by persistent, watery, and sometime mucoid or bloody diarrhea during the neonatal period, resulting in malabsorption and failure to thrive. Type 1 diabetes is difficult to control and results from lymphocytic infiltration of the pancreas. Other autoimmune symptoms, such as hypothyroidism, cytopenia, hepatitis, nephropathy, and arthritis can develop in patients who survive the initial acute phase. IPEX syndrome results from mutations in FOXP3, leading to absent or dysfunctional regulatory T cells and self-reactive T-cell activation and proliferation. Detection of enterocyte autoantibodies helps make the diagnosis. Treatment generally includes supportive care and systemic immunosuppressive therapy (steroids, methotrexate, tacrolimus), although rapamycin has shown promise. Stem-cell transplantation is the curative treatment if a suitable donor can be found.

Generalized erythroderma in association with atopic features can be seen in other disorders with barrier abnormalities, notably Netherton syndrome (biallelic mutations in SPINK5 ) and SAM syndrome ( s evere skin dermatitis, multiple a llergies and m etabolic wasting; biallelic mutations in DSG1 ) ; failure to thrive, recurrent infections, and hypotrichosis are associated with both of these ichthyotic disorders (see Chapter 5 ).

Typical AD may be a feature of several forms of immunodeficiency, most notably in Wiskott–Aldrich syndrome (WAS) and the hyperimmunoglobulinemia E syndrome (HIES) (see related sections). These disorders are distinguished from AD by their recurrent noncutaneous infections and other characteristic features (e.g., thrombocytopenic purpura, bloody diarrhea, and purpuric lesions in WAS and facial and intertriginous staphylococcal abscesses in HIES).

Management

The overall goals of therapy are to reduce itch and maintain sufficient control to minimize any adverse effects of the AD on quality of life. In general, a multistep approach is taken toward management that includes patient and parent education, avoidance of irritants and allergic triggers, good moisturization, normalization of dysbiosis, and use of antiinflammatory medications ( Table 3.1 ). Patient compliance is the main reason for poor outcome and is fueled by concerns about the use of topical corticosteroids and calcineurin inhibitors (see later). Aggressively but safely managing AD flares is important in preventing the exacerbation of disease by delayed or inadequate treatment. The National Eczema Association (NEA) offers a website for education and patient support ( www.nationaleczema.org ). Age-specific structured educational programs have improved objective and subjective severity scores, and educational videos may improve severity beyond direct education. Written action plans have been shown to improve adherence to therapy. , , , Several guidelines for AD management in children have been published.

Table 3.1
Management of Mild, Moderate, and Severe Forms of Atopic Dermatitis
Mild Moderate Severe
Bathing and barrier repair *
Avoidance of irritant and allergic triggers
Intermittent, short-term use of class VI or VII topical steroids (see Table 3.2 ) ± topical calcineurin inhibitors ± phosphodiesterase 4 (PDE4) inhibitor
Treat superinfection
Bathing and barrier repair *
Avoidance of irritant and allergic triggers
Intermittent, short-term use of class III–V topical steroids (see Table 3.2 ) ± topical calcineurin inhibitors ± PDE4 inhibitor
Treat superinfection
Oral antihistamines for sleep
Bathing and barrier repair *
Avoidance of irritant and allergic triggers
Class II topical steroids for flares (see Table 3.2 ); class III–V topical steroids ± tacrolimus ointment for maintenance
Treat superinfection
Oral antihistamines for sleep
Consider systemic immunosuppressants, immunomodulatory biologics (e.g., dupilumab), ultraviolet light therapy

* Barrier repair may be accomplished by application of effective emollients and/or barrier-repair agents.

Preventing the development of atopic dermatitis

Infants in at-risk families (i.e., with at least one parent or sibling who has AD) have a 30% to 50% chance of developing AD by 2 years of age. Limiting the use of skin cleansers is advised. Applying an oil-in-water emollient at least once daily appeared to lower the risk and severity of AD, but larger studies have not confirmed this effect. ,

Water hardness has been shown to be associated with an increased prevalence of AD , and may relate to increased sodium lauryl sulfate residue from washing, leading to greater impairment in barrier function and skin irritation. Although ion-exchange water softeners do not lower the prevalence of AD, they may mitigate the residue deposition seen with hard water.

Despite the fact that maternal dietary antigens are known to cross the placenta, most studies have provided no evidence that avoidance of maternal dietary antigens during pregnancy or lactation has a protective effect during the first 18 months of life on the development of AD or on food sensitization by 7 years of age. In fact, there is increasing evidence that early exposure to food antigens may reduce the risk of developing food allergies. As a result, breastfeeding without restricting maternal diet as a strategy to prevent food allergy is recommended until 4 to 6 months unless contraindicated for medical reasons. Although there is no evidence that breastfeeding protects against the development of pediatric AD at any age, , peanut, milk, and wheat intake during pregnancy may be associated with reduced allergy and asthma in children. , As a result, if available and affordable, hydrolyzed infant formulas, rather than cow’s-milk or soy-milk formulas, can be given to at-risk infants who are not exclusively breastfed, although they may not affect the risk of AD. Solid foods, including potentially allergenic foods, should not be delayed beyond 4 to 6 months of age in at-risk infants. ,

Probiotics have recently received considerable attention as a means of prevention of AD. Evidence that reduced diversity in the gut microbiota is a risk factor in the development of AD provides further rationale for probiotic use. Although there is some evidence of benefit prenatally in prevention (for reviews ) there is insufficient evidence to recommend probiotics as part of standard management of infantile AD. , Of note, however, mixtures of probiotics appear to be more helpful than use of a single probiotic, and a recent trial of a mixture of different probiotic strains led to a significantly greater reduction in SCORAD during 12 weeks of therapy than placebo, with a greater use of topical steroids in the placebo arm.

Although early studies suggest some benefit of prebiotics (fiber compounds that stimulate the growth of advantageous organisms) and fatty acids (such as the γ-linolenic acid alone or in combination with omega-3 fatty acids), there is insufficient evidence to recommend these approaches for either reducing the risk of developing AD or treating AD.

Avoidance of irritant triggers

Certain climatic factors, such as temperature, air pollution/urban environment, and psychological stress, are linked to AD and difficult to control. Many patients have problems with eccrine sweating and sweat retention during the summer months, leading to increased pruritus, especially in the face of lichenification. The increased vasodilation of already inflamed skin from increased summer heat further contributes to pruritus and cutaneous erythema. Nevertheless, children with AD should be encouraged to participate as actively in sports as possible. Swimming is an excellent sport for children with AD if exposure to chlorinated pool water is tolerated. Children should be coated with an emollient (after sunscreen application) as a protectant against pool chemicals; rinsing immediately after swimming followed by application of emollient may decrease the risk of irritation. Children should also be kept cool after application of the thick emollient, or, if sweating is anticipated, a less occlusive moisturizer should be applied. Air-conditioning is important during hot weather to decrease pruritus. The pruritus and erythematous papules of miliaria rubra, which can develop when sweating and using an occlusive moisturizer, can be confused by parents with exacerbation of the dermatitis, setting up a cycle of worsening involvement from repeated application of the occlusive emollient. Recognition and education in decreasing the frequency of emollient application are vital in this situation.

Overdressing children during winter months should also be avoided to prevent overheating. The low humidity of winter months and use of indoor heating also increases skin xerosis and may promote dermatitis; humidifiers may be useful but may increase the exposure to mold allergens if they are not cleaned often. Saliva is a major irritant for infants with AD, and exposure to large amounts of saliva with teething and eating, including saliva mixed with food, exacerbates the facial dermatitis. Protecting the face before meals or naptime with a thick, protective emollient may be helpful. Similarly, older children with AD are at risk for lip-licker’s dermatitis because of the irritant effects of saliva.

Attention to clothing is also important. Soft cotton clothing is recommended over traditional wool or other harsh materials, which tend to precipitate itching and scratching, and in one study fabric softener decreased skin dryness. There is only low-quality evidence regarding AD improvement or decrease in bacterial colonization from use of special textiles, particularly silk and silver-coated cotton. Affected children should avoid use of harsh soaps and detergents, fabric softener sheets, products with fragrance, and bubble baths. Cigarette smoking in homes of children with AD should be avoided, because it can lead to an increase in irritation and pruritus and may also increase the tendency toward subsequent development of asthma.

Avoidance of triggering allergens

It may be possible to identify potential allergen triggers by taking a careful history and doing selective allergy tests. However, triggers that can easily be avoided are difficult to find for most affected individuals, and without a documented or proven food allergy, avoiding potentially allergenic foods as a means of managing AD is not recommended. Food allergy leading to dermatitis is unusual. Testing for allergy to milk, egg, peanut, wheat, and soy is only recommended in children younger than 5 years of age with moderate to severe AD who have persistent AD despite optimized management with topical therapy or who have a reliable history of an immediate reaction after ingestion of a specific food. , Food antigen–specific IgE levels correlate better than a radioallergosorbent test and prick tests, but the level of sIgE is not clinically useful for predicting the development of clinically relevant food allergy. Negative skin prick tests or serum allergen-specific IgE levels are highly predictive at eliminating potential allergens. However, at 6 months of age, 83% of patients with severe AD show IgE food sensitization to milk, eggs, and/or peanuts, and 65% of these children retain food sensitivity by 12 months of age. In comparison, 5% of 6-month-old infants and 11% of 12-month-old infants without atopy show IgE food sensitization. Fewer than 40% of children with moderate to severe AD with food sensitization show reactivity during food challenges, and many of these eruptions are urticarial. In a longitudinal study, 16% of more than 1000 infants with AD (all severities) developed food allergies, particularly to peanut (7%), milk (4%), and egg (4%), with the highest risk in infants with greater AD severity. , Foods may also induce extracutaneous manifestations in pediatric patients with AD, particularly involving the GI tract. Foods may also act as irritants, especially citrus foods, and reactions to chemicals in foods, such as tartrazine or other colorings, may occur. For children in whom food allergies are suspected to be relevant, comanagement with a pediatric allergist is recommended.

The most common food allergens often contaminate other foods and are difficult to avoid entirely. Restrictions in diet should not worsen the quality of the patient’s and family’s life more than the AD itself. Challenges of agents that may trigger IgE reactivity are best conducted under medical observation, because anaphylaxis has occasionally been reported. It should be remembered that excessively restrictive diets in atopic children may lead to weight loss, calcium deficiency, hypovitaminosis, and kwashiorkor. Proper nutritional counseling and supplementation should be included in management, including warning against the use of protein-poor rice and almond milk for cow’s milk, hydrolyzed, and elemental formulas. After the first few years of life, the risk of significant reactivity to food diminishes (particularly with eggs, milk, soy, and wheat). Unless a careful dietary history suggests food sensitivity as a trigger, improvement through dietary manipulation in children older than 5 years is rarely noted.

In contrast to potential reactivity to foods, reactivity of children and adolescents with AD to aeroallergens increases with age. The most common aeroallergen triggers are house-dust mites (Dermatophagoides pteronyssinus), grass pollens, animal dander, and molds, particularly Alternaria . Plant pollens, particularly ragweed, also contain an oleoresin capable of producing sensitization and eczematous contact dermatitis. Airborne dermatitis may involve the exposed surfaces of the face, neck, arms, legs, and V area of the chest but can be distinguished from photosensitivity, which results in sharper lines of demarcation between normal skin and eczematous skin. Exacerbation of facial dermatitis during pollen season or after children contact a pet should alert parents to the possibility of allergy to an aeroallergen or contact allergen (see Allergic Contact Dermatitis section). Cat exposure during infancy can increase the risk of developing AD, especially in infants with an FLG mutation. Cat exposure in children with AD has been shown to increase the risk of developing asthma, although dog exposure may be protective. Epicutaneous application of aeroallergens by atopy patch test on unaffected atopic skin shows reactivity as an eczematoid patch in 30% to 50% of patients with AD but tends to be negative in patients with only respiratory allergy to these triggers or in healthy volunteers. However, patch tests have not been standardized, and their performance and interpretation vary widely.

The value toward AD control of mite-allergen avoidance measures (encasing mattresses and pillows, washing bedding in hot water weekly, vacuuming living areas and bedrooms frequently, keeping only soft nonfurry toys, cleaning carpets regularly or removing them, and eliminating pets) is controversial, and a meta-analysis found no value in encasing mattresses to prevent allergic diseases or symptoms. Immunotherapy for food allergies or aeroallergens has long been controversial as treatment for AD, unlike its efficacy for treating AR and extrinsic asthma; recent double-blind, placebo-controlled studies, however, suggest some value of specific oral and sublingual immunotherapy, including to peanuts. ,

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