Understanding the Burden of Atopic Dermatitis in Africa and the Middle East

This article reviews the epidemiology and disease burden of atopic dermatitis, an inflammatory skin disease, in Africa and the Middle East, and outlines appropriate treatment options for patients in these regions. Defining unmet needs in atopic dermatitis (AD), analyzing current treatment options, and exploring factors that contribute to AD burden in these understudied regions are important as AD is frequently encountered and difficult to manage.

We aim to (1) provide an overview of the burden of AD in Africa and the Middle East, (2) outline the unmet need for novel therapeutic options for AD in this part of the world, and (3) offer clinical recommendations for improving the management of atopic disease in Africa and the Middle East.

A literature search was conducted using PubMed and Web of Science for articles published in English within the previous 10 years. Search terms included “atopic dermatitis,” “Middle East,” “Africa,” “prevalence,” and “treatment.” Articles were manually reviewed for relevance, and additional searches were conducted to supplement the narrative where appropriate. Articles referenced throughout the current review include primary articles, clinical guidelines documents, and reviews, with primary articles preferentially referenced where possible. This article is based on previously conducted studies and does not contain any studies with human participants or animals performed by any of the authors.

The prevalence of AD varies significantly throughout the world [29]. Historically, the prevalence of AD in Africa and Middle Eastern countries has generally been lower than in Europe and North America, but recent time trends show increasing AD prevalence in the developing world [1, 31]. The most comprehensive global epidemiological data can be sourced from the International Study of Asthma and Allergies in Childhood (ISAAC) [32, 33]. Investigators from ISAAC phase 3, which surveyed more than 1 million schoolchildren throughout the world between 1999 and 2004, estimated the lifetime prevalence of AD in 6- to 7-year-old children to be relatively low in the eastern Mediterranean (7.2%) and high in Africa (23.3%) [32, 33]. The global prevalence for 6- to 7-year-old children was 14.2%. The investigators from ISAAC phase 3 estimated the lifetime prevalence of AD in 13- to 14-year-old children to be moderate in the eastern Mediterranean (10.8%) and in Africa (15.2%). The global prevalence for 13- to 14-year-old children was 12.8%. Prevalence differed between and within countries in the Middle East and Africa.

According to a 2012 systematic review, the prevalence of AD in Africa was increasing [29]. The lifetime prevalence of AD symptoms in 13- to 14-year-old children approximately doubled in Morocco, South Africa, and Kenya over an approximate 7-year period (1995–2001/2002). In contrast, the prevalence of AD symptoms in 13- to 14-year-old Nigerian children decreased during this period, although this trend may have been impacted by extremely high baseline prevalence. The same review did not find a clear time trend of change in Middle Eastern prevalence, citing studies that indicated increasing (Israel) and decreasing (Kuwait) lifetime prevalence. A 2008 comparison of ISAAC phases 1 (1992–1997) and 3 (1999–2004) found large increases in prevalence (at least two standard errors [SE]) in 13- to 14-year-old children in Kenya and Algeria [30]. Of nine African regions/countries surveyed in both phases, seven had higher lifetime prevalence in phase 3 than in phase 1 among 13–14 year olds. Of the six eastern Mediterranean regions/countries surveyed in both phases, four had higher phase 3 than phase 1 lifetime prevalence in this age group. All four eastern Mediterranean regions/countries surveyed for 6–7 year olds reported higher phase 3 than phase 1 lifetime prevalence.

Regional and ethnic diversity may play a significant role in variable rates of prevalence in the Middle East. For instance, prevalence differs between countries of Semitic (Qatar, Oman, Saudi Arabia) and Persian (Iran) origin, and between urban and rural or desert regions in Iran [34].

Many environmental, social, and economic factors relevant to Africa and the Middle East contribute to increasing prevalence and burden of AD (Table 2) [12, 19, 35‐49]. Dwelling in urban environments compared with rural environments has been linked to AD in both the Middle East and Africa [34, 37]. In Iran, prevalence of AD is higher in Tehran (17.6%) and Kerman (9.1%) than in Shahr-e-Kord (2.1%), a western city where a greater proportion of citizens have rural lifestyles [34]. A similar pattern has been observed in Africa, with higher income and more urban countries such as South Africa showing large recent increases in AD prevalence [50]. Within individual African countries, AD risk often follows an urban–rural gradient, with a higher rate of AD in city dwellers than in rural dwellers [37]. Effects of increased socioeconomic status and urbanization on prevalence of AD are thought to stem from factors that include increased air pollution, sedentary lifestyle and diet, and smaller family size [12, 31, 50].

Findings in Africa support the “hygiene hypothesis,” which argues that increased prevalence of AD stems, at least in part, from decreased exposure to infection and microorganisms in early childhood [12]. In rural Ethiopia, higher rates of AD have been reported in children with access to piped drinking water than in children who drink river water, an effect attributed to reduced exposure to enteric infections [51]. Helminth (parasitic) infections, which are highly prevalent in Africa, have been shown to promote protection from atopic illness [31]. Results of an analysis of more than 2000 children in Uganda showed that maternal hookworm infection during pregnancy and early childhood infection with Trichuris trichiura or hookworm both were negatively associated with AD [37]. Protection may be mediated by regulatory T and B cells, parasite-induced expression of the anti-inflammatory cytokine IL-10, and reduced expression of atopy-associated genes in infected individuals [31]. However, a study in Ethiopian children showed a positive association between intestinal infection with the Trichuris parasite and risk for AD [51]. This study also showed a history of malaria to be a predictor of risk for AD [51]. Taken together, this underscores the need for additional research. Other hygiene-related factors associated with increased AD prevalence and burden include reduced pre- and postnatal exposure to farm animals and to dogs, antibiotic exposure, and reduced diversity of gut flora [12].

Climate conditions in Africa and the Middle East are also likely contributors to the burden of AD. In Iran and Saudi Arabia, desert conditions are associated with higher burden of AD because high temperatures and low humidity exacerbate dry skin [34, 52]. In Africa, high humidity and temperature promote growth of allergens, including mold [31].

Most available data regarding the impact of AD on patient quality of life (QoL) in the Middle East is from Saudi Arabia. Numerous studies have reported that QoL is significantly affected in Saudi Arabian patients with dermatologic diseases, including AD [53‐56]. Abolfotouh et al. reported data from 283 adult Saudi Arabian patients with skin disease who completed the Skindex-16 scale, which assesses QoL across symptom, emotional, and functional domains [53]. They used an Arabic version of Skindex-16 adapted for and validated in Saudi Arabian individuals. The authors found that, of the eight diagnoses represented among patients, eczematous dermatitis was associated with the highest mean symptom domain score, indicating a high physical burden of disease in patients with AD [53]. Another study by Ibrahim Al-Hoqail [54] of adult patients in outpatient dermatology treatment in Saudi Arabia used an Arabic version of the Dermatology Life Quality Index (DLQI), which has shown adequate validity and reliability in Moroccan patients with psoriasis but has not yet been validated for AD [57, 58]. The DLQI measures the effect of dermatologic disease on numerous aspects of daily life, including physical symptoms, feelings such as embarrassment, activities (social, recreational, work), and personal relationships. Higher scores are associated with poorer QoL. The author found that patients with eczematous dermatitis had the third highest mean DLQI score of eight skin diseases, with only patients who have papulosquamous disorders (not otherwise specified by the authors) and connective tissue/immunological disorders showing poorer QoL [54]. In another study of Saudi Arabian adult and teenaged dermatology outpatients, Ahmed et al. found that most patients with dermatologic disease (79%) experienced low QoL, as measured by the DLQI [56]. The most common dermatologic diagnoses among study patients were acne vulgaris (29.5%), AD (22.3%), vitiligo (20.7%), and psoriasis (6.4%).

Additional data indicate that family QoL is significantly affected when an infant or child has AD in Saudi Arabia [55, 59, 60]. A study of the families of 447 Saudi Arabian infants and children with AD found that only 15 families (3.4%) had normal QoL; most families (66.4%) experienced a moderate impact on QoL [60]. The authors measured QoL with an Arabic version of the Dermatitis Family Impact Questionnaire, which they tested for clarity and feasibility. Results of numerous studies have shown that degree of impairment in QoL of Saudi Arabian families is directly proportional to severity of child disease [55, 59, 60].

QoL data from the remainder of the Middle East are limited. A study conducted in the Sanandaj, Kurdistan province of Iran found that 1- to 6-year-old children with severe AD had significantly lower QoL than the same-age children with moderate AD [61]. The authors reported itching/scratching and sleep problems as the greatest contributors to poor QoL in patients with severe AD.

QoL data from Africa are limited but have been reported for South Africa and Uganda. A 2015 South African qualitative study involving interviews with ten parents of children aged 0–12 years who have AD helped identify detrimental physical, emotional, and social effects of AD to children and families [62]. Consistently reported factors with prominent impact on child QoL included physical discomfort from persistent itching and scratching, low self-esteem, and social isolation. Parents reported fatigue owing to care-related loss of sleep and change in daily routine, as well as emotional burden, including feelings of frustration, stress, and confusion. In another study, 81 Ugandan patients 1.5–75 years of age with pruritus owing to dermatoses, including AD, were surveyed, and the QoL of Ugandan patients was compared with that of German dermatology patients [63]. QoL was measured using a study-specific questionnaire translated by a physician. Ugandan patients were more likely than German patients to experience normal emotional reactions and were less likely to experience adverse emotional reactions in the form of aggressive behavior and loss of drive. The authors reported a trend toward higher frequency of pruritus affecting QoL and self-assessment in German patients than in Ugandan patients. Although this study did not account for disease severity, results suggest that the burden of AD on QoL may be lower in African patients than in European patients. However, additional research is necessary to make informed comparisons between African and European or North American patients.

In the study measuring QoL of Saudi Arabian patients with skin diseases, Abolfotouh et al. found that 31.4% of patients had comorbidities, the most common being diabetes (43.8%) and hypertension (47.2%) [53]. About 20% of patients reported a comorbid psychiatric condition. Numerous additional studies support a relationship between dermatologic and psychiatric conditions in the Middle East. A 2016 study of 254 teenage and adult Saudi Arabian outpatients with dermatologic conditions, including AD, reported overall prevalence rates for depression, anxiety, and stress of 12.6%, 22.1%, and 7.5%, respectively [56]. The prevalence rates among the 56 patients with AD were similar: 10.7% (depression), 21.4% (anxiety), and 7.1% (stress). Dermatology patients with poor QoL were 3.5 times more likely to report depression, anxiety, or stress. Women were nearly three times more likely to report at least one negative emotional condition than men, although this was not statistically significant. Another study of 875 Saudi Arabian dermatology patients estimated high overall prevalence of anxiety (29%) and depression (14%) [64]. A cross-sectional study of Iranian dermatology patients reported psychiatric comorbidities in more than 50% of patients and showed higher rates of psychiatric comorbidities in patients with recurrent disease [65]. Collectively, these statistics suggest a potentially alarming pattern of psychological distress in Middle Eastern patients with dermatological conditions, including AD.

Although data are limited, comorbidities have also been noted in African patients. In the study in which QoL of Ugandan and German patients with pruritic conditions owing to dermatoses was compared, depressed mood was reported in 41% of Ugandan patients (vs 49% of German patients) [63]. Results of a survey of Senegalese infants and children with AD showed that AD significantly increased the risk for malarial infection in children older than 3.5 years of age and delayed development of clinical immunity [66].

Although AD treatment guidelines are similar globally, in managing AD, Africa and the Middle East face challenges that contribute to disease burden. In Saudi Arabia, numerous AD medications are available over the counter, and medical consultation and treatment are free for citizens at government hospitals [67]. However, patients often prefer to see a specialist rather than a general practitioner, resulting in long wait lists and potentially delayed diagnosis. A case report from Saudi Arabia cites use of traditional medicine, general practitioner nonadherence to clinical guidelines, and lack of access to systemic therapies as contributing factors to disease severity and burden in a pediatric patient [52]. The author recommended numerous steps to improve local care for AD in Saudi Arabia, including adequate refresher training in dermatology for general practitioners; use of specialized nurses in dermatology; and enhanced coordination of primary, secondary, and tertiary care. The report also emphasized the need for further research into traditional Middle Eastern medicine and enhanced regulation of long-term prescription of potent topical steroids.

A qualitative report of parent impressions of AD management in the Gauteng district of South Africa identified dispensation of inappropriate medication or insufficient amounts of medication, inadequate primary care, financial obstacles, and lack of disease education for parents and health care providers as unmet needs in AD treatment [68]. The authors describe barriers of care general to South Africa. These include inadequate knowledge of allergic conditions among primary care providers and unavailability of treatment. Issues are amplified in rural settings, where lack of drugs and equipment, ill-informed health care providers, and financial obstacles add to the burden of AD. As in Saudi Arabia, a high proportion of South African patients report using alternative and traditional medicine.

AD research and care in Africa might also be affected by underreporting of the disease, stemming from limited access to health care and prioritization of infectious, highly virulent diseases such as malaria and tuberculosis [31]. Furthermore, many diagnostic tests were developed for use in European and North American individuals, and allergens inherent to tools such as the skin prick test for IgE immunoreactivity may not be relevant to African local environments. In regions with severe shortages of physicians such as sub-Saharan Africa, innovative tools to promote access to AD care such as the African Teledermatology Project, which connects sub-Saharan medical facilities to dermatologists in the USA, Europe, and Australia, are emerging [69]. However, the effectiveness of such tools in alleviating AD burden in Africa requires further research.

Taking into consideration the unmet needs of AD patients in Africa and the Middle East, we outlined treatment recommendations for management of AD in these patient populations in Table 3 based on literature [16, 20, 70‐93] and our clinical experience. The goal of treatment should be threefold: to break the itch–rash cycle by controlling pruritus, to suppress inflammation, and to restore skin barrier function. When colonization or infection occurs, antiseptics, antibiotics, or antivirals are necessary [16‐18, 20, 21]. The merits and drawbacks of therapeutic options should be weighed when developing a treatment plan. Furthermore, regional differences with respect to affordability and availability of AD therapies should be considered as these obstacles have been reported in Africa [68] and the Middle East [52].

Despite some deviations, our recommendations largely align with established international guidelines and comprise a multifaceted approach to treatment [16‐21]. Emollients and moisturizers should be treatment mainstays. Topical corticosteroids are first-line therapies, but strength and treatment duration should be considered to avoid adverse events. Calcineurin inhibitors for AD are an important option, especially in children and for certain areas such as the face, neck, and intertriginous areas. Systemic therapies and phototherapy are useful for moderate to severe cases that remain uncontrolled by topical treatments. Behavioral interventions and disease state education should also be provided because these interventions can improve self-management and QoL, promote optimal sleep and dietary habits, and reduce physician visits and costs [21, 23].

As new treatments such as topical crisaborole and the biologic dupilumab become available in Africa and the Middle East, they should be added to AD management plans where indicated. However, there is a need for real-world efficacy, safety, and tolerability data for novel therapies in Africa and the Middle East because racial and ethnic differences in genetic and immune profiles relevant to AD pathophysiology have been documented [94, 95] and may impact treatment response. Furthermore, studies of the cost-effectiveness of these therapies will be especially important for regions of low socioeconomic status.

Available information is very limited regarding the effect of treatment on QoL of patients with AD in the Middle East and Africa. Results of an Iranian study showed that 6 weeks of dermatologic treatment with ultraviolet light, TCSs, and topical ointments produced a statistically significant improvement in QoL (57% change) as measured by a Persian version of the DLQI in patients with chronic dermatitis [96]. Statistically significant improvement after treatment was observed for all DLQI subdomains, but the greatest improvement was seen in the symptoms and feelings domain. Results of a study in Pretoria, South Africa, of 20 infants and children with severe AD showed a 33% improvement in mean Parent Index QoL (PIQoL) score following treatment with pimecrolimus [97]. The PIQoL questionnaire was translated from English as needed.