Pediatric sarcoidosis is a rare disease. A recent review done in Danish children with sarcoidosis showed that the incidence in children younger than or equal to 15 years was 0.29 per 100,000 person-years, with the incidence rates gradually increasing with age. The median age at diagnosis was 13 years. The male/female ratio in this cohort was 1.18 [2]. The prevalence of sarcoidosis varies according to the geographic area and racial distribution. It is more prevalent in US blacks, Swedes, and Danes and is relatively less frequent in South America, Spain, Portugal, India, Saudi Arabia, and Japan [1, 3]. The disease is thought to be more severe in the blacks than in whites [1].

The etiology of sarcoidosis remains essentially unknown. It probably occurs due to an environmental or infectious trigger in a genetically susceptible host. Organisms like Mycobacteria, Propionibacterium acnes, and Borrelia burgdorferi have been implicated in the etiopathogenesis, but there is no definite proof of direct causation [4–6]. There is also a genetic component to the pathophysiology of sarcoidosis, which is evidenced by familial clustering of cases. Certain manifestations of sarcoidosis are associated with HLA-AI, HLA-B8, and HLA-DR3, whereas negative association is seen with HLA-B12 and HLA-DR4. HLA-DR3 has been associated with a good outcome [7]. A recent study found three independent association signals in the HLA region, peaking in the BTNL2 promoter region, at HLA-B*0801, and at HLA-DPB1, and another novel independent signal near IL23R [8].

The hallmark of the disease is the formation of the sarcoid granuloma, in response to a persistent, poorly degradable antigenic stimulus [1]. Macrophages from patients with sarcoidosis have an increased expression of MHC II molecules and other co-stimulatory molecules on their cell surface. The antigen is presented by these highly efficient macrophages to T-helper cells, expressing the Th1 phenotype. This leads to proliferation and activation of the T cells [9]. The sarcoid granuloma has activated T cells abundantly present in the internal areas of the granuloma with a layer-like distribution. T-helper cells are present in the internal areas of the granuloma, whereas the periphery comprises of cytotoxic T cells and suppressor/inducer T cells [10]. These cells secrete a variety of cytokines and chemokines including interferon gamma; interleukin (IL)-2, IL-12, and IL-15; tumor necrosis factor-alpha (TNF-α); and growth factors. Two mechanisms are involved in the accumulation of inflammatory cells in tissues affected by sarcoidosis. First, chemoattractant cytokines such as IL-8, IL-16, and RANTES contribute to expand the local pool of CD4 memory cells within the inflamed tissue. The second mechanism is in situ IL-2-mediated proliferation of CD4 T cells [1]. IL-18 has been recently recognized as an IFN γ-inducing factor. It plays an important role in Th1 response induction and may be responsible for disease progression. IL-18 has also been described as a good prognostic marker [11].

A sustained inflammatory response leads to granuloma formation, common sites for which are the lymph nodes, lungs, liver, spleen, and skin. These granulomas resolve or they heal by fibrosis [1].

There are two forms of pediatric sarcoidosis. The early-onset form is associated with a sporadic genetic mutation in the nucleotide binding oligomerization domain 2/caspase activation recruitment domain 15 (NOD2/CARD15) gene that causes accelerated nuclear factor (NF)-κB activation [12]. The second type is seen in older children and adolescents and is similar to the adult disease with pulmonary manifestations, lymphadenopathy, panniculitis, arthritis, hepatosplenomegaly, parotid swelling, and other systemic features such as weight loss and fever.

There is no definite confirmatory laboratory test for the diagnosis of sarcoidosis. Laboratory evaluation may reveal elevated acute phase reactants, anemia, leukopenia, and eosinophilia. Hypergammaglobulinemia is common. Depression of delayed-type hypersensitivity on skin testing is seen [1]. Hypercalcemia and hypercalciuria are also observed due to specific metabolic dysregulation [21].

The levels of serum angiotensin-converting enzyme (ACE) are elevated in over 50 % of children with late-onset sarcoidosis [2]. ACE is produced by the epithelioid cells in granulomas. ACE levels, in children less than 15 years of age, are 40–50 % higher than in adults. The mean ± SD ACE values in children less than 18 years are 118 ± 30 as compared to 100 ± 35 in adults. Adolescent children have higher serum ACE, with boys showing a higher level than girls [33]. The test is not specific for sarcoidosis, and levels may be also elevated in other conditions like primary biliary cirrhosis, tuberculosis, diabetes mellitus, hyperthyroidism, Gaucher disease, myeloma, pulmonary neoplasm, and lymphomas [1, 23]. Angiotensin-converting enzyme (ACE) polymorphism (insertion/deletion) has been associated with susceptibility to sarcoidosis in European and East Asian populations [34].

A recent study has shown that serum adenosine deaminase is useful in detecting sarcoidosis activity, and soluble interleukin-2 receptor (sIL2R) serum levels are useful in exploring the extrapulmonary organ involvement [35].

Chest radiograph should be done to screen for pulmonary involvement. High-resolution chest computed tomography (CT) is a better modality to delineate the extent of parenchymal disease. Bronchoalveolar lavage (BAL) typically demonstrates an increased number of lymphocytes, with around 55 % of the patients showing a high CD4/CD8 ratio. A CD4/CD8 ratio greater than 3.5 is highly specific for sarcoidosis, although the sensitivity is low. Endobronchial ultrasonography-guided transbronchial needle aspiration (EBUS-TBNA) has been shown to be highly specific [36].