viernes, 19 de abril de 2019

Langerhans Cell Histiocytosis Treatment (PDQ®)—Health Professional Version - National Cancer Institute

Langerhans Cell Histiocytosis Treatment (PDQ®)—Health Professional Version - National Cancer Institute

National Cancer Institute

Langerhans Cell Histiocytosis Treatment (PDQ®)–Health Professional Version

General Information About Langerhans Cell Histiocytosis (LCH)

The histiocytic diseases in children and adults are caused by an abnormal accumulation of cells of the mononuclear phagocytic system. Only Langerhans cell histiocytosis (LCH), a myeloid-derived dendritic cell disorder, is discussed in detail in this summary.
The histiocytic diseases have been reclassified into five categories, and LCH is in the L group.[1] LCH results from the clonal proliferation of immunophenotypically and functionally immature, morphologically rounded LCH cells along with eosinophils, macrophages, lymphocytes, and, occasionally, multinucleated giant cells.[2,3] The term LCH cells is used because there are clear morphologic, phenotypic, and gene expression differences between Langerhans cells of the epidermis (LCs) and those in LCH lesions (LCH cells), despite the pathologic histiocyte having the identical immunophenotypic characteristics of normal epidermal LCs, including the presence of Birbeck granules identified by electron microscopy.
LCH cells, known for many years to be caused by a clonal proliferation, have now been shown to likely derive from a myeloid precursor whose proliferation is uniformly associated with activation of the MAPK/ERK signaling pathway.[4,5] However, the somatic mutation leading to the activation varies and is unknown in 10% to 20% of cases.[6] In the original breakthrough description of the BRAF V600E mutation occurring in approximately 60% of LCH biopsy specimens, the authors also described activation of the RAS-RAF-MEK-ERK pathway in almost all cases, regardless of stage and organ involvement.[7,8] Since then, activating mutations in several other genes in the pathway have been identified in a significant percentage of BRAF V600E–negative LCH specimens, including MAP2K1, in-frame deletions plus another leading to upregulation of BRAF, and, less frequently, the CSF-1 receptor, RAS, and ARAF.[9-11]
In accordance with these findings, the pathologic histiocyte or LCH cell has a gene expression profile closely resembling that of a myeloid dendritic cell. Studies have also demonstrated that the BRAF V600E mutation can be identified in mononuclear cells in peripheral blood and cell-free DNA, usually in patients with disseminated disease.[2,12,13] This shows that multisystem LCH arises from a somatic mutation within a marrow or circulating precursor cell, while localized disease arises from the mutation occurring in a precursor cell at the local site.[2]
The above findings have led all clinicians to agree that LCH is a myeloid neoplasm; however, discussion remains about whether it is a malignant neoplasm with varying clinical behavior. The same BRAF V600E mutation has been found in other cancers, including malignant melanoma; however, V600E-mutated BRAF is also present in benign nevi, possibly indicating the need for additional mutations to render the cell malignant.[7] Nevertheless, these findings have raised the possibility of targeted therapy with inhibitors already used in the treatment of melanoma. Several trials of BRAF inhibitors are open for adults and children with BRAF V600E–mutated tumors, including LCH.
LCH may involve a single organ (single-system LCH), which may be a single site (unifocal) or involve multiple sites (multifocal); or LCH may involve multiple organs (multisystem LCH), which may involve a limited number of organs or be disseminated. Involvement of specific organs such as the liver, spleen, and hematopoietic system separates multisystem LCH into a high-risk group and a low-risk group, where risk indicates the risk of death from disease.
References
  1. Emile JF, Abla O, Fraitag S, et al.: Revised classification of histiocytoses and neoplasms of the macrophage-dendritic cell lineages. Blood 127 (22): 2672-81, 2016. [PUBMED Abstract]
  2. Berres ML, Lim KP, Peters T, et al.: BRAF-V600E expression in precursor versus differentiated dendritic cells defines clinically distinct LCH risk groups. J Exp Med 211 (4): 669-83, 2014. [PUBMED Abstract]
  3. Allen CE, Merad M, McClain KL: Langerhans-Cell Histiocytosis. N Engl J Med 379 (9): 856-868, 2018. [PUBMED Abstract]
  4. Willman CL, Busque L, Griffith BB, et al.: Langerhans'-cell histiocytosis (histiocytosis X)--a clonal proliferative disease. N Engl J Med 331 (3): 154-60, 1994. [PUBMED Abstract]
  5. Yu RC, Chu C, Buluwela L, et al.: Clonal proliferation of Langerhans cells in Langerhans cell histiocytosis. Lancet 343 (8900): 767-8, 1994. [PUBMED Abstract]
  6. Monsereenusorn C, Rodriguez-Galindo C: Clinical Characteristics and Treatment of Langerhans Cell Histiocytosis. Hematol Oncol Clin North Am 29 (5): 853-73, 2015. [PUBMED Abstract]
  7. Badalian-Very G, Vergilio JA, Fleming M, et al.: Pathogenesis of Langerhans cell histiocytosis. Annu Rev Pathol 8: 1-20, 2013. [PUBMED Abstract]
  8. Badalian-Very G, Vergilio JA, Degar BA, et al.: Recurrent BRAF mutations in Langerhans cell histiocytosis. Blood 116 (11): 1919-23, 2010. [PUBMED Abstract]
  9. Chakraborty R, Hampton OA, Shen X, et al.: Mutually exclusive recurrent somatic mutations in MAP2K1 and BRAF support a central role for ERK activation in LCH pathogenesis. Blood 124 (19): 3007-15, 2014. [PUBMED Abstract]
  10. Nelson DS, van Halteren A, Quispel WT, et al.: MAP2K1 and MAP3K1 mutations in Langerhans cell histiocytosis. Genes Chromosomes Cancer 54 (6): 361-8, 2015. [PUBMED Abstract]
  11. Chakraborty R, Burke TM, Hampton OA, et al.: Alternative genetic mechanisms of BRAF activation in Langerhans cell histiocytosis. Blood 128 (21): 2533-2537, 2016. [PUBMED Abstract]
  12. Allen CE, Li L, Peters TL, et al.: Cell-specific gene expression in Langerhans cell histiocytosis lesions reveals a distinct profile compared with epidermal Langerhans cells. J Immunol 184 (8): 4557-67, 2010. [PUBMED Abstract]
  13. Hyman DM, Diamond EL, Vibat CR, et al.: Prospective blinded study of BRAFV600E mutation detection in cell-free DNA of patients with systemic histiocytic disorders. Cancer Discov 5 (1): 64-71, 2015. [PUBMED Abstract]

Histopathologic, Immunologic, and Cytogenetic Characteristics of LCH

Cell of Origin and Biologic Correlates

Modern classification of the histiocytic diseases subdivides them into dendritic cell–related, monocyte/macrophage-related, or true malignancies. Langerhans cell histiocytosis (LCH) is a dendritic cell disease.[1,2] Comprehensive gene expression array data analysis on LCH cells is consistent with the concept that the skin Langerhans cell (LC) is not the cell of origin for LCH.[3] Rather, it is likely to be a hematopoietic progenitor cell before being a committed myeloid dendritic cell, which expresses the same antigens (CD1a and CD207) as the skin LC.[4,5] This concept was further supported by reports that the transcription profile of LCH cells was distinct from myeloid and plasmacytoid dendritic cells, as well as epidermal LCs.[3,4,6,7]

Histopathology

The Langerhans histiocytosis cells in LCH lesions (LCH cells) are immature dendritic cells making up fewer than 10% of the cells present in the lesion.[7,8] These cells are classically large oval cells with abundant pink cytoplasm and a bean-shaped nucleus on hematoxylin and eosin stain. LCH cells stain positively with antibodies to S100, CD1a, and/or anti-Langerin (CD207). Staining with CD1a or Langerin confirm the diagnosis of LCH, but care should be taken to correlate with clinical presentation in organs in which normal LC cells occur.[9]
Because LCH cells activate other immunologic cells, LCH lesions also contain other histiocytes, lymphocytes, macrophages, neutrophils, eosinophils, and fibroblasts, and may contain multinucleated giant cells.
In the brain, the following three types of histopathologic findings have been described in LCH:
  1. Mass lesions in the meninges or choroid plexus with CD1a-positive LCH cells and predominantly CD8-positive lymphocytes.
  2. Mass lesions in connective tissue spaces with CD1a-positive LCH cells and predominantly CD8-positive lymphocytes that cause an inflammatory response and neuronal loss.
  3. Neurodegenerative lesions. Predominantly CD8-positive lymphocyte infiltration with neuronal degeneration, microglial activation, and gliosis.[10]

Immunologic Abnormalities

Normally, the LC is a primary presenter of antigen to naïve T-lymphocytes. However, in LCH, the pathologic dendritic cell does not efficiently stimulate primary T-lymphocyte responses.[11] Antibody staining for the dendritic cell markers, including CD80, CD86, and class II antigens, has been used to show that in LCH, the abnormal cells are immature dendritic cells that present antigen poorly and are proliferating at a low rate.[8,11,12] Transforming growth factor-beta (TGF-beta) and interleukin (IL)-10 may be responsible for preventing LCH cell maturation in LCH.[8] The expansion of regulatory T cells in patients with LCH has been reported.[12] The population of CD4-positive CD25(high) FoxP3(high) cells was reported to comprise 20% of T cells and appeared to be in contact with LCH cells in the lesions. These T cells were present in higher numbers in the peripheral blood of patients with LCH than in the peripheral blood of control patients and returned to a normal level when patients were in remission.[12]

Cytogenetic and Genomic Studies

Studies published in 1994 showed clonality in Langerhans cell histiocytosis (LCH) using polymorphisms of methylation-specific restriction enzyme sites on the X-chromosome regions coding for the human androgen receptor, DXS255, PGK, and HPRT.[13,14] The results of biopsies of lesions with single-system or multisystem disease showed a proliferation of LCH cells from a single clone. The discovery of recurring genomic alterations (primarily BRAF V600E) in LCH (see below) confirmed the clonality of LCH in children.
Pulmonary LCH in adults was initially reported to be nonclonal in approximately 75% of cases,[15] while an analysis of BRAF mutations showed that 25% to 50% of adult lung LCH patients had evidence of BRAF V600E mutations.[15,16] Another study of 26 pulmonary LCH cases found that 50% had BRAF V600E mutations and 40% had NRAS mutations.[17] Approximately the same number of mutations are polyclonal, rather than monoclonal. It has not yet been investigated whether clonality and BRAF pathway mutations are concordant in the same patients, which might suggest a reactive rather than a neoplastic condition in smoker's lung LCH and a clonal neoplasm in other types of LCH.
ENLARGEBRAF-RAS pathway
Figure 1. Courtesy of Rikhia Chakraborty, Ph.D. Permission to reuse the figure in any form must be obtained directly from Dr. Chakraborty.
The genomic basis of LCH was advanced by a 2010 report of an activating mutation of the BRAF oncogene (V600E) that was detected in 35 of 61 cases (57%).[18] Multiple subsequent reports have confirmed the presence of BRAF V600E mutations in 50% or more of LCH cases in children.[19-21] Other BRAF mutations that result in signal activation have been described.[20,22ARAF mutations are infrequent in LCH but, when present, can also lead to RAS-MAPK pathway activation.[23]
The RAS-MAPK signaling pathway (refer to Figure 1) transmits signals from a cell surface receptor (e.g., a growth factor) through the RAS pathway (via one of the RAF proteins [A, B, or C]) to phosphorylate MEK and then the extracellular signal-regulated kinase (ERK), which leads to nuclear signals affecting cell cycle and transcription regulation. The V600E mutation of BRAF leads to continuous phosphorylation, and thus activation, of MEK and ERK without the need for an external signal. Activation of ERK occurs by phosphorylation, and phosphorylated ERK can be detected in virtually all LCH lesions.[18,24]
Because RAS-MAPK pathway activation can be detected in all LCH cases, but not all cases have BRAF mutations, the presence of genomic alterations in other components of the pathway was suspected. The following genomic alterations were identified:
  • Whole-exome sequencing of BRAF-mutated versus BRAF–wild-type LCH biopsy tissue samples revealed that 7 of 21 BRAF–wild-type specimens had MAP2K1 mutations, while no BRAF-mutated specimens had MAP2K1 mutations.[24] The mutations in MAP2K1(which codes for MEK) were activating, as indicated by their induction of ERK phosphorylation.[24]
  • Another study showed MAP2K1 mutations exclusively in 11 of 22 BRAF–wild-type cases.[25]
  • Finally, in-frame BRAF deletions and in-frame FAM73A-BRAF fusions have occurred in the group of BRAF V600E and MAP2K1 mutation–negative cases.[26]
Studies support the universal activation of ERK in LCH, with activation in most cases being explained by BRAF and MAP2K1 alterations.[18,24,26] Altogether, these mutations in the MAP kinase pathway account for nearly 90% of the causes of the universal activation of ERK in LCH.[18,24,26]
The presence of the BRAF V600E mutation in blood and bone marrow was studied in a series of 100 patients, 65% of whom tested positive for the BRAF V600E mutation by a sensitive quantitative polymerase chain reaction technique.[19] Circulating cells with the BRAF V600E mutation could be detected in all high-risk patients and in a subset of low-risk multisystem patients. The presence of circulating cells with the mutation conferred a twofold increased risk of relapse. In a similar study that included 48 patients with BRAFV600E–mutated LCH, the BRAF V600E allele was detected in circulating cell-free DNA in 100% of patients with risk-organ–positive multisystem LCH, 42% of patients with risk-organ–negative LCH, and 14% of patients with single-system LCH.[27]
The myeloid dendritic cell origin of LCH was confirmed by finding CD34-positive stem cells with the mutation in the bone marrow of high-risk patients. In those with low-risk disease, the mutation was found in more mature myeloid dendritic cells, suggesting that the stage of cell development at which the somatic mutation occurs is critical in defining the extent of disease in LCH. LCH is now considered a myeloid neoplasm.
Clinical implications
Clinical implications of the described genomic findings include the following:
  • LCH joins a group of other pediatric entities with activating BRAF mutations, including select nonmalignant conditions (e.g., benign nevi) [28] and low-grade malignancies (e.g., pilocytic astrocytoma).[29,30] All of these conditions have a generally indolent course, with spontaneous resolution occurring in some cases. This distinctive clinical course may be a manifestation of oncogene-induced senescence.[28,31]
  • BRAF V600E mutations can be targeted by BRAF inhibitors (e.g., vemurafenib and dabrafenib) or by the combination of BRAF inhibitors plus MEK inhibitors (e.g., dabrafenib/trametinib and vemurafenib/cobimetinib). These agents and combinations are approved for adults with melanoma. Treatment of melanoma in adults with combinations of a BRAF inhibitor and a MEK inhibitor showed significantly improved progression-free survival outcome compared with treatment using a BRAF inhibitor alone.[32,33]
    Case reports have described activity of BRAF inhibitors against LCH in adult patients [34-38] and pediatric patients,[39] but there are insufficient data to assess the role of these agents in the treatment of children with LCH.
    The most serious side effect of BRAF inhibitor therapies is the induction of cutaneous squamous cell carcinomas,[32,33] with the incidence of these second cancers increasing with age;[40] this effect can be reduced by concurrent treatment with both BRAF and MEK inhibitors.[32,33] In a long-term study of adult patients with Erdheim-Chester disease and LCH who received vemurafenib, 85% of patients had arthralgias; 62% of patients had maculopapular rashes; and more than 40% of patients had other skin issues, including hyperkeratosis, seborrheic keratosis, and pruritus.[41]
  • Circulating BRAF V600E–mutated cells have been found in 59% of patients who developed neurodegenerative-disease LCH, compared with 15% of patients who did not develop neurodegenerative-disease LCH. Detectable mutated circulating cells had a sensitivity of 0.59 and specificity of 0.86 for developing the neurodegenerative disease condition. Even after therapy, some patients with neurodegenerative-disease LCH had circulating BRAF V600E–mutated cells.[42]
  • With additional research, the observation of BRAF V600E (or potentially mutated MAP2K1) in circulating cells or cell-free DNA may become a useful diagnostic tool to define high-risk versus low-risk disease.[19] Additionally, for patients who have a somatic mutation, persistence of circulating cells with the mutation may be useful as a marker of residual disease.[19]

Cytokine Analysis

Immunohistochemical staining has shown upregulation of many different cytokines/chemokines, both in lesional tissue and in serum/plasma.[43,44] In an analysis of gene expression in LCH by gene array techniques, 2,000 differentially expressed genes were identified. Of 65 genes previously reported to be associated with LCH, only 11 were found to be upregulated in the array results. The most highly upregulated gene in both CD207-positive and CD3-positive cells was SPP1 (encodes the osteopontin protein); other genes that activate and recruit T cells to sites of inflammation are also upregulated.[3] The expression profile of the T cells was that of an activated regulatory T-cell phenotype with increased expression of FOXP3CTLA4, and SPP1. These findings support a previous report on the expansion of regulatory T cells in LCH.[3] There was pronounced expression of genes associated with early myeloid progenitors including CD33 and CD44, which is consistent with an earlier report of elevated myeloid dendritic cells in the blood of patients with LCH.[45] A model of Misguided Myeloid Dendritic Cell Precursors has been proposed, whereby myeloid dendritic cell precursors are recruited to sites of LCH by an unknown mechanism, and the dendritic cells, in turn, recruit lymphocytes by excretion of osteopontin, neuropilin-1, and vannin-1.[3]
A study to evaluate possible biomarkers for central nervous system LCH examined 121 unique proteins in the cerebrospinal fluid (CSF) of 40 pediatric patients with LCH and compared them with controls, which included 29 patients with acute lymphoblastic leukemia, 25 patients with brain tumors, 28 patients with neurodegenerative diseases, and 9 patients with hemophagocytic lymphohistiocytosis. Only osteopontin proved to be significantly increased in the CSF of LCH patients with either neurodegeneration or mass lesions (pituitary), compared with all of the control groups. Analysis of osteopontin expression in these tissues confirmed an upregulation of the SPP1 gene.[42]
Several investigators have published studies evaluating the level of various cytokines or growth factors in the blood of patients with LCH that have included many of the genes found not to be upregulated by the gene expression results discussed above.[3] One explanation for elevated levels of these proteins is a systemic inflammatory response, with the cytokines/growth factors being produced by cells outside the LCH lesions. A second possible explanation is that macrophages in the LCH lesions produce the cytokines measured in the blood or are concentrated in lesions.
IL-1 beta and prostaglandin GE2 levels were measured in the saliva of patients with oral LCH lesions or multisystem high-risk patients with and without oral lesions; levels of both were higher in patients with active disease and decreased after successful therapy.[46]

HLA Type and Association With LCH

Specific associations of LCH with distinct HLA types and extent of disease have been reported. In a study of 84 Nordic patients, those with only skin or bone involvement more frequently had HLA-DRB1*03 type than did those with multisystem disease.[47] In 29 patients and 37 family members in the United States, the Cw7 and DR4 types were significantly more prevalent in Caucasians with single-bone lesions.[48]
References
  1. Emile JF, Abla O, Fraitag S, et al.: Revised classification of histiocytoses and neoplasms of the macrophage-dendritic cell lineages. Blood 127 (22): 2672-81, 2016. [PUBMED Abstract]
  2. Picarsic J, Jaffe R: Nosology and Pathology of Langerhans Cell Histiocytosis. Hematol Oncol Clin North Am 29 (5): 799-823, 2015. [PUBMED Abstract]
  3. Allen CE, Li L, Peters TL, et al.: Cell-specific gene expression in Langerhans cell histiocytosis lesions reveals a distinct profile compared with epidermal Langerhans cells. J Immunol 184 (8): 4557-67, 2010. [PUBMED Abstract]
  4. Ginhoux F, Merad M: Ontogeny and homeostasis of Langerhans cells. Immunol Cell Biol 88 (4): 387-92, 2010 May-Jun. [PUBMED Abstract]
  5. Durham BH, Roos-Weil D, Baillou C, et al.: Functional evidence for derivation of systemic histiocytic neoplasms from hematopoietic stem/progenitor cells. Blood 130 (2): 176-180, 2017. [PUBMED Abstract]
  6. Hutter C, Kauer M, Simonitsch-Klupp I, et al.: Notch is active in Langerhans cell histiocytosis and confers pathognomonic features on dendritic cells. Blood 120 (26): 5199-208, 2012. [PUBMED Abstract]
  7. Berres ML, Allen CE, Merad M: Pathological consequence of misguided dendritic cell differentiation in histiocytic diseases. Adv Immunol 120: 127-61, 2013. [PUBMED Abstract]
  8. Geissmann F, Lepelletier Y, Fraitag S, et al.: Differentiation of Langerhans cells in Langerhans cell histiocytosis. Blood 97 (5): 1241-8, 2001. [PUBMED Abstract]
  9. Chikwava K, Jaffe R: Langerin (CD207) staining in normal pediatric tissues, reactive lymph nodes, and childhood histiocytic disorders. Pediatr Dev Pathol 7 (6): 607-14, 2004 Nov-Dec. [PUBMED Abstract]
  10. Grois N, Prayer D, Prosch H, et al.: Neuropathology of CNS disease in Langerhans cell histiocytosis. Brain 128 (Pt 4): 829-38, 2005. [PUBMED Abstract]
  11. Yu RC, Morris JF, Pritchard J, et al.: Defective alloantigen-presenting capacity of 'Langerhans cell histiocytosis cells'. Arch Dis Child 67 (11): 1370-2, 1992. [PUBMED Abstract]
  12. Senechal B, Elain G, Jeziorski E, et al.: Expansion of regulatory T cells in patients with Langerhans cell histiocytosis. PLoS Med 4 (8): e253, 2007. [PUBMED Abstract]
  13. Willman CL, Busque L, Griffith BB, et al.: Langerhans'-cell histiocytosis (histiocytosis X)--a clonal proliferative disease. N Engl J Med 331 (3): 154-60, 1994. [PUBMED Abstract]
  14. Yu RC, Chu C, Buluwela L, et al.: Clonal proliferation of Langerhans cells in Langerhans cell histiocytosis. Lancet 343 (8900): 767-8, 1994. [PUBMED Abstract]
  15. Dacic S, Trusky C, Bakker A, et al.: Genotypic analysis of pulmonary Langerhans cell histiocytosis. Hum Pathol 34 (12): 1345-9, 2003. [PUBMED Abstract]
  16. Roden AC, Hu X, Kip S, et al.: BRAF V600E expression in Langerhans cell histiocytosis: clinical and immunohistochemical study on 25 pulmonary and 54 extrapulmonary cases. Am J Surg Pathol 38 (4): 548-51, 2014. [PUBMED Abstract]
  17. Mourah S, How-Kit A, Meignin V, et al.: Recurrent NRAS mutations in pulmonary Langerhans cell histiocytosis. Eur Respir J 47 (6): 1785-96, 2016. [PUBMED Abstract]
  18. Badalian-Very G, Vergilio JA, Degar BA, et al.: Recurrent BRAF mutations in Langerhans cell histiocytosis. Blood 116 (11): 1919-23, 2010. [PUBMED Abstract]
  19. Berres ML, Lim KP, Peters T, et al.: BRAF-V600E expression in precursor versus differentiated dendritic cells defines clinically distinct LCH risk groups. J Exp Med 211 (4): 669-83, 2014. [PUBMED Abstract]
  20. Satoh T, Smith A, Sarde A, et al.: B-RAF mutant alleles associated with Langerhans cell histiocytosis, a granulomatous pediatric disease. PLoS One 7 (4): e33891, 2012. [PUBMED Abstract]
  21. Sahm F, Capper D, Preusser M, et al.: BRAFV600E mutant protein is expressed in cells of variable maturation in Langerhans cell histiocytosis. Blood 120 (12): e28-34, 2012. [PUBMED Abstract]
  22. Héritier S, Hélias-Rodzewicz Z, Chakraborty R, et al.: New somatic BRAF splicing mutation in Langerhans cell histiocytosis. Mol Cancer 16 (1): 115, 2017. [PUBMED Abstract]
  23. Nelson DS, Quispel W, Badalian-Very G, et al.: Somatic activating ARAF mutations in Langerhans cell histiocytosis. Blood 123 (20): 3152-5, 2014. [PUBMED Abstract]
  24. Chakraborty R, Hampton OA, Shen X, et al.: Mutually exclusive recurrent somatic mutations in MAP2K1 and BRAF support a central role for ERK activation in LCH pathogenesis. Blood 124 (19): 3007-15, 2014. [PUBMED Abstract]
  25. Brown NA, Furtado LV, Betz BL, et al.: High prevalence of somatic MAP2K1 mutations in BRAF V600E-negative Langerhans cell histiocytosis. Blood 124 (10): 1655-8, 2014. [PUBMED Abstract]
  26. Chakraborty R, Burke TM, Hampton OA, et al.: Alternative genetic mechanisms of BRAF activation in Langerhans cell histiocytosis. Blood 128 (21): 2533-2537, 2016. [PUBMED Abstract]
  27. Héritier S, Hélias-Rodzewicz Z, Lapillonne H, et al.: Circulating cell-free BRAF(V600E) as a biomarker in children with Langerhans cell histiocytosis. Br J Haematol 178 (3): 457-467, 2017. [PUBMED Abstract]
  28. Michaloglou C, Vredeveld LC, Soengas MS, et al.: BRAFE600-associated senescence-like cell cycle arrest of human naevi. Nature 436 (7051): 720-4, 2005. [PUBMED Abstract]
  29. Jones DT, Kocialkowski S, Liu L, et al.: Tandem duplication producing a novel oncogenic BRAF fusion gene defines the majority of pilocytic astrocytomas. Cancer Res 68 (21): 8673-7, 2008. [PUBMED Abstract]
  30. Pfister S, Janzarik WG, Remke M, et al.: BRAF gene duplication constitutes a mechanism of MAPK pathway activation in low-grade astrocytomas. J Clin Invest 118 (5): 1739-49, 2008. [PUBMED Abstract]
  31. Jacob K, Quang-Khuong DA, Jones DT, et al.: Genetic aberrations leading to MAPK pathway activation mediate oncogene-induced senescence in sporadic pilocytic astrocytomas. Clin Cancer Res 17 (14): 4650-60, 2011. [PUBMED Abstract]
  32. Larkin J, Ascierto PA, Dréno B, et al.: Combined vemurafenib and cobimetinib in BRAF-mutated melanoma. N Engl J Med 371 (20): 1867-76, 2014. [PUBMED Abstract]
  33. Long GV, Stroyakovskiy D, Gogas H, et al.: Dabrafenib and trametinib versus dabrafenib and placebo for Val600 BRAF-mutant melanoma: a multicentre, double-blind, phase 3 randomised controlled trial. Lancet 386 (9992): 444-51, 2015. [PUBMED Abstract]
  34. Haroche J, Cohen-Aubart F, Emile JF, et al.: Reproducible and sustained efficacy of targeted therapy with vemurafenib in patients with BRAF(V600E)-mutated Erdheim-Chester disease. J Clin Oncol 33 (5): 411-8, 2015. [PUBMED Abstract]
  35. Charles J, Beani JC, Fiandrino G, et al.: Major response to vemurafenib in patient with severe cutaneous Langerhans cell histiocytosis harboring BRAF V600E mutation. J Am Acad Dermatol 71 (3): e97-9, 2014. [PUBMED Abstract]
  36. Gandolfi L, Adamo S, Pileri A, et al.: Multisystemic and Multiresistant Langerhans Cell Histiocytosis: A Case Treated With BRAF Inhibitor. J Natl Compr Canc Netw 13 (6): 715-8, 2015. [PUBMED Abstract]
  37. Euskirchen P, Haroche J, Emile JF, et al.: Complete remission of critical neurohistiocytosis by vemurafenib. Neurol Neuroimmunol Neuroinflamm 2 (2): e78, 2015. [PUBMED Abstract]
  38. Hyman DM, Puzanov I, Subbiah V, et al.: Vemurafenib in Multiple Nonmelanoma Cancers with BRAF V600 Mutations. N Engl J Med 373 (8): 726-36, 2015. [PUBMED Abstract]
  39. Héritier S, Jehanne M, Leverger G, et al.: Vemurafenib Use in an Infant for High-Risk Langerhans Cell Histiocytosis. JAMA Oncol 1 (6): 836-8, 2015. [PUBMED Abstract]
  40. Anforth R, Menzies A, Byth K, et al.: Factors influencing the development of cutaneous squamous cell carcinoma in patients on BRAF inhibitor therapy. J Am Acad Dermatol 72 (5): 809-15.e1, 2015. [PUBMED Abstract]
  41. Diamond EL, Subbiah V, Lockhart AC, et al.: Vemurafenib for BRAF V600-Mutant Erdheim-Chester Disease and Langerhans Cell Histiocytosis: Analysis of Data From the Histology-Independent, Phase 2, Open-label VE-BASKET Study. JAMA Oncol 4 (3): 384-388, 2018. [PUBMED Abstract]
  42. McClain KL, Picarsic J, Chakraborty R, et al.: CNS Langerhans cell histiocytosis: Common hematopoietic origin for LCH-associated neurodegeneration and mass lesions. Cancer 124 (12): 2607-2620, 2018. [PUBMED Abstract]
  43. Fleming MD, Pinkus JL, Fournier MV, et al.: Coincident expression of the chemokine receptors CCR6 and CCR7 by pathologic Langerhans cells in Langerhans cell histiocytosis. Blood 101 (7): 2473-5, 2003. [PUBMED Abstract]
  44. Annels NE, Da Costa CE, Prins FA, et al.: Aberrant chemokine receptor expression and chemokine production by Langerhans cells underlies the pathogenesis of Langerhans cell histiocytosis. J Exp Med 197 (10): 1385-90, 2003. [PUBMED Abstract]
  45. Rolland A, Guyon L, Gill M, et al.: Increased blood myeloid dendritic cells and dendritic cell-poietins in Langerhans cell histiocytosis. J Immunol 174 (5): 3067-71, 2005. [PUBMED Abstract]
  46. Preliasco VF, Benchuya C, Pavan V, et al.: IL-1 beta and PGE2 levels are increased in the saliva of children with Langerhans cell histiocytosis. J Oral Pathol Med 37 (9): 522-7, 2008. [PUBMED Abstract]
  47. Bernstrand C, Carstensen H, Jakobsen B, et al.: Immunogenetic heterogeneity in single-system and multisystem langerhans cell histiocytosis. Pediatr Res 54 (1): 30-6, 2003. [PUBMED Abstract]
  48. McClain KL, Laud P, Wu WS, et al.: Langerhans cell histiocytosis patients have HLA Cw7 and DR4 types associated with specific clinical presentations and no increased frequency in polymorphisms of the tumor necrosis factor alpha promoter. Med Pediatr Oncol 41 (6): 502-7, 2003. [PUBMED Abstract]

Childhood LCH

Incidence

The annual incidence of Langerhans cell histiocytosis (LCH) has been estimated to be between two and ten cases per 1 million children aged 15 years or younger.[1-3] The male-to-female ratio (M:F) is close to one, and the median age of presentation is 30 months.[4] A 4-year survey of 251 new LCH cases in France found an annual incidence of 4.6 cases per 1 million children younger than 15 years (M:F = 1.2).[5] A survey of LCH in northwest England (Manchester) revealed an overall incidence of 2.6 cases per 1 million child-years.[6]
Surveillance, Epidemiology, and End Results registry data from 2000 to 2009 were reviewed to identify high-risk LCH cases and assess demographic variables.[7] On the basis of 145 cases, the age-standardized incidence was 0.7 per 1 million children per year, with lower incidence in black patients (0.41 per 1 million) and higher incidence in Hispanic patients (1.63 per 1 million) younger than 5 years. Crowded living conditions and lower socioeconomic circumstances were associated with a higher risk of LCH, possibly because of the correlation with maternal and neonatal infections.[8]
Identical twins and non-twin siblings with LCH, as well as LCH in multiple generations in one family, have been reported.[9]

Etiology

The etiology of LCH is unknown.

Risk Factors

Although the following risk factors have been identified for LCH, strong and consistent associations have not been confirmed:
  • Parental exposure to solvents.[8]
  • Family history of cancer.[10]
  • Personal or family history of thyroid disease.[8,11]
  • Perinatal infections.[8,10]
  • Parental occupational exposure to metal, granite, or wood dust.[10]
  • Ethnicity and race.[7]
  • Low socioeconomic status.[7]
  • Lack of childhood vaccinations.[10]
Efforts to define a viral cause have not been successful.[12,13] One study has shown that 1% of patients have a positive family history for LCH.[9]

Clinical Presentation

LCH most commonly presents with a painful bone lesion, with skin being the second most commonly involved organ. Systemic symptoms of fever, weight loss, diarrhea, edema, dyspnea, polydipsia, and polyuria relate to specific organ involvement and single-system or multisystem disease presentation, as noted below.
Specific organs are considered high risk or low risk when involved with disease presentation. Risk refers to the risk of mortality in high-risk patients. Chronic recurrent involvement of low-risk organs, while usually not life-threatening, can result in potentially devastating long-term consequences.
  • High-risk organs include the liver, spleen, and hematopoietic system (defined by the presence of pathologic CD1a-positive or CD207-positive cells in the bone marrow, although newer technologies [BRAF V600E detection by polymerase chain reaction or immunostaining] are resulting in more-reliable detection of LCH cells in the bone marrow). High-risk patients are typically younger than 2 years.
  • Low-risk organs include the skin, bone, lung, lymph nodes, gastrointestinal tract, pituitary gland, thyroid, thymus, and central nervous system (CNS). Involvement of every organ except kidney and gonads has been described.
Patients may present with single-organ involvement (single-system LCH), which may involve a single site (unifocal) or multiple sites (multifocal). Bone is the most common single-organ site. Less commonly, LCH may involve multiple organs (multisystem LCH), which may involve a limited number of organs, or it may be disseminated. Patients can have LCH of the skin, bone, lymph nodes, and pituitary gland in any combination and still be considered at low risk of death, although there may be relatively high risk of developing long-term consequences of the disease.
Treatment decisions for patients are based on whether high-risk or low-risk organs are involved and whether LCH presents as unifocal, multifocal, or multisystem disease.

Single-system low-risk disease presentation

In single-system low-risk LCH, as the name implies, the disease presents with involvement of a single site or organ, including skin and nails, oral cavity, bone, lymph nodes and thymus, pituitary gland, and thyroid gland.
Skin and nails
  • Infants: Seborrheic involvement of the scalp may be mistaken for prolonged cradle cap in infants, unless the classic purpuric component is present. The second most common site involves the body creases, such as the antecubital fossa and perineum. Infants with LCH may also present with a generalized skin rash, which may mimic many other skin disorders and may or may not be pruritic. Vesicular LCH skin lesions need to be differentiated from congenital infections.
    Skin LCH in infants may be limited to skin (skin-only disease) or may be part of multisystem LCH. In a report of 61 neonatal cases from 1,069 patients in the Histiocyte Society database, nearly 60% (36 of 61 patients) had multisystem disease, and 72% of the patients with multisystem disease had risk-organ involvement.[14] A retrospective analysis of 71 infants and children with apparent skin-only LCH found that those older than 18 months were more likely to have multisystem involvement and often relapsed after treatment with vinblastine and prednisone.[15] Eight of 11 patients in this category had circulating cells with the BRAF V600E mutation, compared with only 1 of 13 patients in the skin-only group. Patients younger than 1 year with skin-only disease who were completely evaluated to exclude any other site of disease had an 89% 3-year progression-free survival with initial therapy.
    Skin-only LCH may be self-limited because the lesions may disappear without therapy during the first year of life. Therapy is used only for very extensive rashes, pain, ulceration, or bleeding. These patients must be watched closely because skin-only LCH in neonates and very young infants may progress within weeks or months to high-risk multisystem disease, which may be life-threatening.[16-18]
    Hashimoto-Pritzker disease or congenital spontaneous regressing skin histiocytosis is a self-limited disease that has the same immunohistochemical staining as LCH but, on electron microscopy, shows dense bodies thought to be senescent mitochondria.[19] Careful review of the original cases revealed that some patients progressed to multisystem LCH; the distinction between skin-only LCH and Hashimoto-Pritzker disease is felt to be without clinical value because all of these infants should be carefully observed after diagnosis.
    A review of patients presenting in the first 3 months of life with skin-only LCH compared the clinical and histopathologic findings of 21 children whose skin LCH regressed with those of 10 children who did not regress.[17] Patients with regressing disease had distal lesions that appeared in the first 3 months of life and were necrotic papules or hypopigmented macules. Patients with nonregressing disease who required systemic therapy were more often intertriginous. Immunohistochemical studies showed no difference in interleukin (IL)-10, Ki-67, E-cadherin expression, or T-reg number between the two clinical groups.
  • Children and adults: Children and adults may develop a red papular rash in the groin, abdomen, back, or chest that resembles a diffuse candidal rash. Seborrheic involvement of the scalp may be mistaken for a severe case of dandruff in older individuals. Ulcerative lesions behind the ears, involving the scalp, under the breasts, on the genitalia, or in the perianal region are often misdiagnosed as bacterial or fungal infections. Vesicular lesions may be seen and need to be differentiated from herpetic lesions.
    Fingernail involvement is an unusual finding that may present as a single site or with other sites of LCH involvement; there are longitudinal, discolored grooves and loss of nail tissue. This condition often responds to the usual LCH therapies.[20]
Oral cavity
In the mouth, presenting symptoms include gingival hypertrophy and ulcers on the soft or hard palate, buccal mucosa, or tongue and lips. Hypermobile teeth (floating teeth) and tooth loss usually indicate involvement of underlying bone.[21,22] Lesions of the oral cavity may precede evidence of LCH elsewhere.
Bone
Bone is the most commonly affected system, estimated to be affected in 80% of patients with LCH. LCH can occur in any bone of the body, although the hands and feet are often spared.[23]
Sites of LCH bone lesions in children include the following:
  • Lytic lesion of the skull: The most frequent site of LCH in children is a lytic lesion of the skull vault,[24] which may be asymptomatic or painful. It is often surrounded by a soft tissue mass that may extend internally to impinge on the dura.
  • Femur, ribs, humerus, pelvis, and vertebra: Other frequently involved skeletal sites are femur, ribs, humerus, pelvis, and vertebra. Spine lesions may involve any vertebra, although involvement of the cervical vertebrae is most common, and spine lesions are frequently associated with other bone lesions. Spine lesions may result in collapse of the vertebral body (vertebra plana). Vertebral lesions with soft tissue extension often present with pain and may present with significant neurologic deficits,[25] an indication of an urgent need for magnetic resonance imaging (MRI) scan.
  • CNS-risk bones: Proptosis from an LCH mass in the orbit mimics rhabdomyosarcoma, neuroblastoma, and benign fatty tumors of the eye.[26]
    Lesions of the facial bones or anterior or middle cranial fossae (e.g., temporal, orbit, sphenoid, ethmoid, zygomatic) with intracranial tumor extension comprise a CNS-riskgroup. These patients have a threefold increased risk of developing diabetes insipidus and other CNS disease. Because of the increased risk of diabetes insipidus, systemic treatment is recommended for these patients.
Lymph nodes and thymus
The cervical nodes are most frequently involved and may be soft-matted or hard-matted groups with accompanying lymphedema. An enlarged thymus or mediastinal node involvement can mimic an infectious process and may cause asthma-like symptoms. Accordingly, biopsy with culture is indicated for these presentations. Mediastinal involvement is rare (<5%) and usually presents with respiratory distress, superior vena cava syndrome, or cough and tachypnea. The 5-year survival is 87%, with deaths mostly attributable to hematologic involvement.[27]
Pituitary gland
The posterior part of the pituitary gland and pituitary stalk can be affected in patients with LCH, causing central diabetes insipidus. (Refer to the Endocrine system subsection in the Multisystem disease presentation section of this summary for more information.) Anterior pituitary involvement often results in growth failure and delayed or precocious puberty. Rarely, hypothalamic involvement may cause morbid obesity.
Thyroid gland
Thyroid involvement has been reported in LCH. Symptoms include massive thyroid enlargement, hypothyroidism, and respiratory symptoms.[28]

Multisystem disease presentation

In multisystem LCH, the disease presents in multiple organs or body systems, including bone, abdominal/gastrointestinal system (liver and spleen), lung, bone marrow, endocrine system, eye, CNS, skin, and lymph nodes; these are divided into high-risk sites (liver, spleen, bone marrow) and low-risk sites (all other sites).
Multisystem low-risk disease
Bone and other organ systems
Patients with LCH may present with multiple bone lesions as a single site (single-system multifocal bone) or bone lesions with other organ systems involved (multisystem including bone). A review of patients with single-system multifocal bone presentation and patients with multisystem-including-bone presentation who were treated on the Japanese LCH study (JLSG-02) found that patients in the multisystem including bone group were more likely to have lesions in the temporal bone, mastoid/petrous bone, orbit, and zygomatic bone (CNS risk).[29] These patients also had a higher incidence of diabetes insipidus, correlating with the higher frequency of risk-bone lesions. By contrast, a study from members of the Histiocyte Society found decreased mortality in high-risk multisystem LCH patients who had bone involvement, suggesting that those with bone LCH may have more indolent disease.[30]
Abdominal/gastrointestinal system
In LCH, the liver and spleen are considered high-risk organs, and involvement of these organs affects prognosis. Involvement in this context means the liver and spleen are enlarged from direct infiltration of LCH cells or as a secondary phenomenon of excess cytokines, which cause macrophage activation or infiltration of lymphocytes around bile ducts. LCH cells have a portal (bile duct) tropism that may lead to biliary damage and ductal sclerosis. A percutaneous (peripheral) liver biopsy may not be diagnostic of the infiltrate that tends to be more central in the liver, but will show the upstream obstructive effects of distal biliary occlusion. Hepatic enlargement can be accompanied by dysfunction, leading to hypoalbuminemia with ascites, hyperbilirubinemia, and clotting factor deficiencies. Sonography, computed tomography (CT), or MRI of the liver will show hypoechoic or low-signal intensity along the portal veins or biliary tracts when the liver is involved with LCH.[31]
Patients with diarrhea, hematochezia, perianal fistulas, or malabsorption have been reported.[32,33] Diagnosing gastrointestinal involvement with LCH is difficult because of patchy involvement. Careful endoscopic examination that includes multiple biopsies is usually needed.
Lung
In LCH, the lung is less frequently involved in children than in adults because smoking in adults is a key etiologic factor.[34] The cystic/nodular pattern of disease reflects the cytokine-induced destruction of lung tissue. Classically, the disease is symmetrical and predominates in the upper and middle lung fields, sparing the costophrenic angle and giving a very characteristic picture on high-resolution CT scan.[35] Confluence of cysts may lead to bullous formation, and spontaneous pneumothorax can be the first sign of LCH in the lung, although patients may present with tachypnea or dyspnea. Ultimately, widespread fibrosis and destruction of lung tissue may lead to severe pulmonary insufficiency. Declining diffusion capacity may also herald the onset of pulmonary hypertension.[36] Widespread fibrosis and declining diffusion capacity are much less common in children. In young children with diffuse disease, therapy can halt the progress of the tissue destruction, and normal repair mechanisms may restore some function, although scarring or even residual nonactive cysts may continue to be visible on radiologic studies.
Pulmonary involvement is present in approximately 25% of children with multisystem low-risk and high-risk LCH.[37] However, a multivariate analysis of pulmonary disease in multisystem LCH did not show pulmonary disease to be an independent prognostic factor, with 5-year overall survival rates of 94% for those with pulmonary involvement and 96% for those without pulmonary involvement.[38] Isolated pulmonary involvement is rarely seen in children.
Endocrine system
Diabetes insipidus, caused by LCH-induced damage to the antidiuretic hormone-secreting cells of the posterior pituitary, is the most frequent endocrine manifestation in LCH.[39] MRI scans usually show nodularity and/or thickening of the pituitary stalk and loss of the pituitary bright spot on T2-weighted images. Pituitary biopsies are rarely done. A biopsy of the pituitary gland may be indicated when the pituitary gland is the only site of disease and the stalk is greater than 6.5 mm or there is a hypothalamic mass.[40] If the pituitary disease is associated with other sites of involvement, these sites can be biopsied to establish the diagnosis.
Approximately 4% of LCH patients present with an apparently idiopathic form of diabetes insipidus before other lesions of LCH are identified. A review of pediatric patients presenting with idiopathic central diabetes insipidus showed that 19% eventually developed manifestations of LCH, while 18% were diagnosed with craniopharyngioma and 10% with germinoma.[41] A prospective study of the etiology of central diabetes insipidus in children and young adults found that 15% had LCH, 11% had a germinoma, and 7% had a craniopharyngioma.[42] The other diagnoses were related to trauma, familial association, or midline defects, and 50% remained idiopathic. When the pituitary stalk is thickened or is very large, there is a 50% chance the patient will have a germinoma, LCH, or lymphoma.[43] Decisions about when to treat or whether to treat a patient with apparent isolated central diabetes insipidus as LCH without a biopsy remain controversial. These patients should be monitored closely for signs of any of the possible diagnoses.
Approximately 50% of patients who present with isolated diabetes insipidus as the initial manifestation of LCH either have anterior pituitary deficits at the time of diagnosis or develop them within 10 years of diabetes insipidus onset.[44,45] Anterior pituitary deficits include secondary amenorrhea, panhypopituitarism, growth hormone deficiency, hypoadrenalism, and abnormalities of gonadotropins. This incidence appears to be higher in LCH patients than in those with true idiopathic central diabetes insipidus.
Patients with diabetes insipidus caused by LCH have a 50% to 80% chance of developing other lesions that are diagnostic of LCH within 1 year of diabetes insipidus onset, including bone, lung, and skin lesions.[40,44] More commonly, LCH patients present with diabetes insipidus later in the course of the disease, as noted in the following studies:
  • One study compared the incidence of diabetes insipidus in patients who received no systemic therapy with that in patients who received 6 months of vinblastine/prednisone therapy. Patients who received no systemic therapy had a 40% incidence of diabetes insipidus; patients who were treated with chemotherapy had a 20% incidence of diabetes insipidus. This finding strongly supports treatment of CNS-risk bones, even when the disease occurs in a single site.[46]
  • A study of 589 patients with LCH revealed a 24% 10-year risk of pituitary involvement.[39] Diabetes insipidus was seen at a mean of 1 year after LCH diagnosis. Fifty-six percent of LCH patients who developed diabetes insipidus developed anterior pituitary hormone deficiencies (growth, thyroid, or gonadal-stimulating hormones) within 10 years of the onset of diabetes insipidus. No decrease in the incidence of diabetes insipidus was seen in chemotherapy-treated patients, but this may reflect the length of the therapy and/or the number of drugs used.[39]
Using longer therapy and more drugs, the German-Austrian-Dutch (Deutsche Arbeitsgemeinschaft für Leukaemieforschung und -therapie im Kindesalter [DAL]) group found a 12% cumulative incidence of diabetes insipidus.[46] The incidence of diabetes insipidus was also lower in patients treated with more-intensive chemotherapy regimens on the HISTSOC-LCH-III (NCT00276757) and JLSG-96 and JLSG-02 studies in Japan (8.9% for multisystem patients) compared with the HISTSOC-LCH-I and HISTSOC-LCH-II studies (14.2%).[47-51] Overall, diabetes insipidus occurred in 11% of patients treated with multiagent chemotherapy and in up to 50% of patients treated less aggressively.[45,52]
Patients with multisystem disease and craniofacial involvement (particularly of the orbit, mastoid, and temporal bones) at the time of diagnosis carried a significantly increased risk of developing diabetes insipidus during the disease course (relative risk, 4.6), with 75% of patients with diabetes insipidus having these CNS-risk bone lesions.[46] The risk increased when the disease remained active for a longer period of time or reactivated. The risk of diabetes insipidus development in this population was 20% at 15 years after diagnosis.
Ocular
Although rare, ocular LCH, sometimes leading to blindness, has been reported. Other organ systems may be involved, and the ocular LCH may not respond well to conventional chemotherapy.[26]
CNS
CNS disease manifestations
Patients with LCH may develop mass lesions in the hypothalamic-pituitary region, the choroid plexus, the grey matter, or the white matter.[53] These lesions contain CD1a-positive LCH cells and CD8-positive lymphocytes and are, therefore, active LCH lesions.[54]
Patients with large pituitary tumors (>6.5 mm) have a higher risk of anterior pituitary dysfunction and neurodegenerative CNS LCH.[55] A retrospective study of 22 patients found that all had radiologic signs of neurodegenerative CNS LCH detected at a median time of 3 years and 4 months after LCH diagnosis; it worsened in 19 patients. Five patients had neurologic dysfunction. Eighteen of 22 patients had anterior pituitary dysfunction, and 20 had diabetes insipidus. Growth hormone deficiency occurred in 21 patients; luteinizing hormone/follicle-stimulating hormone deficiency occurred in 10 patients; and thyroid hormone deficiency occurred in 10 patients.
LCH CNS neurodegenerative syndrome
A chronic neurodegenerative syndrome that is manifested by dysarthria, ataxia, dysmetria, and sometimes behavior changes develops in 1% to 4% of patients with LCH. These patients may develop severe neuropsychologic dysfunction with tremor, gait disturbances, ataxia, dysarthria, headaches, visual disturbances, cognitive and behavioral problems, and psychosis.
Brain MRI scans from these patients show hyperintensity of the dentate nucleus and white matter of the cerebellum on T2-weighted images or hyperintense lesions of the basal ganglia on T1-weighted images and/or atrophy of the cerebellum.[56] The radiologic findings may precede the onset of symptoms by many years or be found coincidently. A study of 83 patients with LCH who had at least two MRI studies of the brain for evaluation of craniofacial lesions, diabetes insipidus, and/or other endocrine deficiencies of neuropsychological symptoms has been published.[57] Forty-seven of 83 patients (57%) had radiological neurodegenerative changes at a median time of 34 months from diagnosis. Of the 47 patients, 12 (25%) developed clinical neurological deficits that presented 3 to 15 years after the LCH diagnosis. Fourteen of the 47 patients had subtle deficits in short-term auditory memory.
A study of CNS-related permanent consequences (neuropsychologic deficits) in 14 of 25 patients with LCH who were monitored for a median of 10 years has been published.[58] Seven of these patients had diabetes insipidus, and five patients had radiographic evidence of LCH CNS neurodegenerative changes.[58] Patients with craniofacial lesions had lower performance and verbal intelligence quotient scores than did those with other LCH lesions.
The first histological evaluation of neurodegenerative lesions reported prominent T-cell infiltration, usually in the absence of the CD1a-positive dendritic cells along with microglial activation and gliosis.[54] However, in a report from 2018, analysis of brain tissue from patients with neurodegenerative-disease LCH showed perivascular infiltration of CD207-negative cells staining with the BRAF V600E mutant protein in the pons, cerebellum, and basal ganglia. These are areas identified by the characteristic abnormal MRI findings on T2 fluid-attenuated inversion recovery (FLAIR) images. Quantitative polymerase chain reaction analysis of these areas showed increased numbers of BRAF-mutated cells and elevated expression of osteopontin. Brain tissue in these areas showed active demyelination, correlating with the radiologic findings and clinical deficits.[59]
Multisystem high-risk disease
Liver (sclerosing cholangitis)
One of the most serious complications of hepatic LCH is cholestasis and sclerosing cholangitis.[60] This usually occurs months after initial presentation, but on occasion may be present at diagnosis. The median age of children with this form of hepatic LCH is 23 months.
Patients with hepatic LCH present with hepatomegaly or hepatosplenomegaly, and elevated alkaline phosphatase, liver transaminases, and gamma glutamyl transpeptidase levels. While ultrasound and/or MRI-cholangiogram can be helpful in the diagnosis of this complication, liver biopsy is the only definitive way to determine whether active LCH or residual hepatic fibrosis is present. Biopsy results often show lymphocytes and biliary obstructive effects without LCH cells. Peribiliary LCH cells and, rarely, nodular masses of LCH may also be present. It is thought that cytokines such as transforming growth factor-beta (TGF)-beta, elaborated by lymphocytes during the active phase of the disease, lead to fibrosis and sclerosis around the bile ducts.[61]
Seventy-five percent of children with sclerosing cholangitis will not respond to chemotherapy because the LCH is no longer active, but the fibrosis and sclerosis remain. Despite the limitations, liver biopsy may be the only way to distinguish active LCH from end-stage fibrosis. Liver transplantation is the only alternate treatment when hepatic function worsens. In one series of 28 children undergoing liver transplantation, 78% survived and 29% had recurrence of LCH, but only two cases of recurrent LCH occurred in the transplanted liver, although other cases have been reported since publication of the initial data.[62] If possible, active LCH should be under control before transplantation. Patients who undergo liver transplant for LCH may have a higher incidence of posttransplant lymphoproliferative disease.[63]
Spleen
Massive splenomegaly may lead to cytopenias because of hypersplenism and may cause respiratory compromise. Splenectomy typically provides only transient relief of cytopenias, as increased liver size and reticuloendothelial activation result in peripheral blood cell sequestration and destruction. Although rare, LCH infiltration of the pancreas and kidneys has been reported.[64] Splenectomy is performed only as a life-saving measure.
Bone marrow
Most patients with bone marrow involvement are young children who have diffuse disease in the liver, spleen, lymph nodes, and skin and who present with significant thrombocytopenia and anemia with or without neutropenia.[65] Others have only mild cytopenias and are found to have bone marrow involvement with LCH by sensitive immunohistochemical or flow cytometric analysis of the bone marrow.[66] A high content of bone marrow macrophages can obscure LCH cells.[67] Patients with LCH who are considered at very high risk sometimes present with hemophagocytosis involving the bone marrow.[68] The cytokine milieu driving LCH is probably responsible for the epiphenomenon of macrophage activation which, in the most severe cases, presents with typical manifestations of hemophagocytic lymphohistiocytosis such as cytopenias and hyperferritinemia.

Diagnostic Evaluation

The complete evaluation of any patient, presenting with either single-system or multisystem disease, should include the following:[69]
  • History and physical exam: A complete history and physical exam with special attention to the skin, lymph nodes, ears, oral pharynx, gingiva, tongue, teeth, bones, lungs, thyroid, liver and spleen size, bone abnormalities, growth velocity, and history of excessive thirst and urination.
Other tests and procedures include the following:
  • Blood tests: Blood tests include complete blood count with leukocyte differential and platelet count, liver function tests (e.g., bilirubin, albumin, aspartate aminotransferase, alanine aminotransferase, alkaline phosphatase, and prothrombin time/partial thromboplastin time in patients with hepatomegaly, jaundice, elevations of liver enzymes, or low albumin), and serum electrolytes.
    In severe multisystem LCH, additional tests for secondary hemophagocytic lymphohistiocytosis such as ferritin, triglycerides, fibrinogen, d-dimers, and lactate dehydrogenase may be indicated.
  • BRAF V600E assessment: Although BRAF mutation assessment is not a required part of the workup for LCH, the BRAF mutation can be detected by either immunohistochemistry or molecular diagnostic methods in fresh and formalin-fixed tissue.
  • Urine tests: Urine tests include urinalysis and a water-deprivation test if diabetes insipidus is suspected. Water deprivation tests in very young children, especially infants, is performed under medical monitoring.
  • Bone marrow aspirate and biopsy: The bone marrow aspirate and biopsy is indicated for patients with multisystem disease who have unexplained anemia or thrombocytopenia. The biopsy should be stained with anti-CD1a and/or anti-CD207 (langerin) and anti-CD163 immunostains to facilitate the detection of LCH cells.
  • Radiologic and imaging tests: Radiologic tests for the first level of screening include skeletal survey, skull series, bone scans, and chest X-ray. Newer diagnostic imaging modalities, including whole-body MRI scan or somatostatin analog scintigraphy, augment but do not replace the standard tests. Positron emission tomography (PET) scans are becoming more widely used because of superior diagnostic index and evaluation of response to therapy compared with bone scans.[70-74]
    • CT scan: CT scan of the head may be indicated if orbital, mastoid, or other maxillofacial involvement is suspected. Imaging tests may include MRI scan with gadolinium contrast of the brain for patients with diabetes insipidus or suspected brain or vertebral involvement.[75]
      CT scan of the lungs may be indicated for patients with abnormal chest X-rays or pulmonary symptoms. High-resolution CT scans may show evidence of pulmonary LCH when the chest X-ray is normal; thus, in infants and toddlers with normal chest X-rays, a CT scan may be considered. Patients with pulmonary LCH may also have normal chest X-rays and abnormal pulmonary function tests.[76]
      LCH causes fatty changes in the liver or hypodense areas along the portal tract, which can be identified by CT scan, if indicated.[77]
    • Fluorine F 18-fludeoxyglucose (18F-FDG) PET scan: 18F-FDG PET scan abnormalities were reported in the brains of seven patients with LCH who exhibited neurologic and radiographic signs of neurodegenerative disease.[74] There was good correlation with MRI findings in the cerebellar white matter, but less so in the caudate nuclei and frontal cortex. It was suggested that PET scans of patients at high risk of developing neurodegenerative LCH could show abnormalities earlier than MRI.[74] PET scans often demonstrate lesions not found by other modalities and show a decrease of activity after 6 weeks of therapy, thus providing a better assessment of response to therapy than bone scans or plain X-rays.[73]
    • MRI: MRI findings of patients with diabetes insipidus include thickening and nodularity of the pituitary stalk with loss of the posterior pituitary bright spot, reflecting absence of antidiuretic hormone. Later in the course, the stalk generally atrophies, but this should not be used as evidence of response to therapy.
      All patients with vertebral body involvement need careful assessment of associated soft tissue, which may impinge on the spinal cord.
      MRI findings of CNS LCH include T2 FLAIR enhancement in the pons, basal ganglia, white matter of the cerebellum, and mass lesions or meningeal enhancement. In a report of 163 patients,[56] meningeal lesions were found in 29% and choroid plexus involvement in 6%. Paranasal sinus or mastoid lesions were found in 55% of patients versus 20% of controls, and accentuated Virchow-Robin spaces were found in 70% of patients versus 27% of controls.
  • Biopsy: Lytic bone lesions, skin, and lymph nodes are the sites most frequently biopsied for diagnosis of LCH. A liver biopsy is indicated when a child with LCH presents with hypoalbuminemia not caused by gastrointestinal LCH or other etiology. These patients usually have elevated levels of bilirubin or liver enzymes. An open lung biopsy may be necessary for obtaining tissue for diagnosis of pulmonary LCH when bronchoalveolar lavage is nondiagnostic.
    A pathologic diagnosis is always required to make a definitive diagnosis. However, this may sometimes be difficult or contraindicated, such as in isolated pituitary stalk disease or vertebra plana without a soft tissue mass, when the risk outweighs the benefit of a firm diagnosis.

Prognosis

Survival is closely linked to the extent of disease at presentation when high-risk organs (liver, spleen, and/or bone marrow) are involved, as well as the response to initial treatment. Many studies have confirmed the high mortality rate (35%) in high-risk multisystem patients who do not respond well to therapy in the first 6 weeks. For many years, lung was thought to be a high-risk organ, but isolated lung involvement in pediatric LCH is no longer considered to pose a significant risk of death.[38] Because of treatment advances, including early implementation of additional therapy for poor responders, the outcome for children with LCH involving high-risk organs has improved.[48,49] Data from HISTSOC-LCH-III (NCT00276757) showed an 84% overall survival (OS) rate for patients treated for 12 months with systemic chemotherapy.[50]
Patients with single-system disease and low-risk multisystem disease do not usually die from LCH, but recurrent disease may result in considerable morbidity and significant late effects.[78] Overall, recurrences have been found in 10% of patients with single-system unifocal disease, 25% of patients with single-system multifocal bone LCH, and 50% of both low-risk multisystem patients and high-risk multisystem patients who achieve nonactive disease status with chemotherapy. HISTSOC-LCH-III data showed a significant difference in reactivation rate for low-risk organ patients randomly assigned to receive 6 months of treatment (54%) versus 12 months of treatment (37%).[50] Similarly, the nonrandomized high-risk group who were all treated for 12 months had a reactivation rate of 30% compared with more than 50% in previous studies with 6 months of the same therapy.[50]
Most good-responder, high-risk patients who have a reactivation (30%) do so in low-risk organs such as bone and then have the same risk of late effects as the low-risk multisystem patients.[50] The major current treatment challenge is to reduce this overall 20% to 30% incidence of reactivations and the significant incidence of serious permanent consequences in this group of patients.
Apart from disease extent, prognostic factors for children with LCH include the following:
  • Age at diagnosis: Although age younger than 2 years was once thought to portend a worse prognosis, data from the HISTSOC-LCH-II study showed that patients aged 2 years or younger without high-risk organ involvement had the same response to therapy as did older patients.[49] By contrast, the OS was poorer in neonates with risk-organ involvement compared with infants and children with the same extent of disease when patients were treated for only 6 months.[49]
  • Response to treatment: Response to therapy at 6 to 12 weeks has been shown to be a more important prognostic factor than age.[14] The overall response to therapy is influenced by the duration and intensity of treatment.[48,49]
  • Site of involvement: Involvement of craniofacial bones including orbital, mastoid, and temporal bones is associated with an increased risk of diabetes insipidus and an increased frequency of anterior pituitary hormone deficiencies and neurologic problems, although the strength of this correlation is controversial. (Refer to the Endocrine system subsection in the Multisystem disease presentation section of this summary for more information about diabetes insipidus.) Because of the permanent nature of established diabetes insipidus and the risk of progression to even more serious endocrine and CNS consequences, the Histiocyte Society trials suggest chemotherapy for patients with unifocal risk-bone disease until this problem can be clarified in a well-designed prospective study.
  • BRAF mutation: A study of 173 patients with the BRAF V600E mutation and 142 without the mutation revealed that the mutation occurred in 88% of patients with high-risk disease, 69% of patients with multisystem low-risk LCH, and 44% of patients with single-system low-risk LCH.[79] The mutation was also found in 75% of patients with neurodegenerative syndrome and 73% of patients with pituitary involvement. Resistance to initial treatment and relapse were higher in patients with the mutation.[79]
    An earlier study of 100 patients did not find these clinical correlations with the BRAFV600E mutation.[80]

Follow-up Considerations in Childhood LCH

Because of the risk of reactivation (which ranges from 10% in single-system unifocal bone lesions to close to 50% in low-risk and high-risk multisystem LCH) and the risk of permanent long-term effects, LCH patients need to be monitored for many years.
Patients with diabetes insipidus and/or skull lesions in the orbit, mastoid, or temporal bones appear to be at higher risk of LCHCNS involvement and LCH CNS neurodegenerative syndrome. These patients should have MRI scans with gadolinium contrast at the time of LCH diagnosis and every 1 to 2 years thereafter for 10 years to detect evidence of CNS disease.[57] The Histiocyte Society CNS LCH Committee does not recommend any treatment for radiologic CNS LCH of the neurodegenerative type if there is no associated clinical neurodegeneration. However, careful neurologic examinations and appropriate imaging with MRI are suggested at regular intervals. Brain stem auditory evoked responses should also be done at regular intervals to define the onset of clinical CNS LCH as early as possible, as this may affect response to therapy.[81] When clinical signs are present, intervention may be indicated. Available studies of different forms of therapy for CNS neurodegeneration suggest that the neurodegenerative changes may be stabilized or improved, but only if therapy is started early.[81] (Refer to the LCH CNS neurodegenerative syndrome section of this summary for more information.) Careful follow-up of patients at risk is critical.
For children with LCH in the lung, pulmonary function testing and chest CT scans are sensitive methods for detecting disease progression.[36]
A 16-year follow-up study of patients from one institution suggested that children with LCH have an increased risk of developing adult smoker's lung LCH compared with the normal young adult who smokes. Ongoing re-education regarding this risk should be part of the routine follow-up of children with LCH at any site.[36]
In summary, many patients with multisystem disease will experience long-term sequelae caused by their underlying disease and/or treatment. Endocrine and CNS sequelae are the most common. These long-term sequelae significantly affect health quality of life in many of these patients.[82][Level of evidence: 3iiiC] Specific long-term follow-up guidelines after treatment of childhood cancer or in those who have received chemotherapy have been published by the Children's Oncology Group and are available on their website.

Special Considerations for the Treatment of Children With Cancer

Cancer in children and adolescents is rare, although the overall incidence of childhood cancer has been slowly increasing since 1975.[83] Children and adolescents with cancer should be referred to medical centers that have a multidisciplinary team of cancer specialists with experience treating the cancers that occur during childhood and adolescence. This multidisciplinary team approach incorporates the skills of the following health care professionals and others to ensure that children receive treatment, supportive care, and rehabilitation that will achieve optimal survival and quality of life:
  • Primary care physicians.
  • Pediatric surgical subspecialists.
  • Pathologists.
  • Radiation oncologists.
  • Pediatric medical oncologists/hematologists.
  • Rehabilitation specialists.
  • Pediatric nurse specialists.
  • Social workers.
Refer to the PDQ summaries on Supportive and Palliative Care for specific information about supportive care for children and adolescents with cancer.
Guidelines for pediatric cancer centers and their role in the treatment of pediatric patients with cancer have been outlined by the American Academy of Pediatrics.[84] At these pediatric cancer centers, clinical trials are available for most types of cancer that occur in children and adolescents, and the opportunity to participate in these trials is offered to most patients and families. Clinical trials for children and adolescents with cancer are generally designed to compare potentially better therapy with therapy that is currently accepted as standard. Most of the progress made in identifying curative therapies for childhood cancers has been achieved through clinical trials. Information about ongoing clinical trials is available from the NCI website.
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  48. Gadner H, Grois N, Arico M, et al.: A randomized trial of treatment for multisystem Langerhans' cell histiocytosis. J Pediatr 138 (5): 728-34, 2001. [PUBMED Abstract]
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Treatment of Childhood LCH

Over many years, national and international study groups have defined risk groups for allocation of Langerhans cell histiocytosis (LCH) patients to risk-based therapy on the basis of mortality risk and risk of late effects of the disease.
Depending on the site and extent of disease, treatment of LCH may include observation alone (after biopsy or curettage), surgery, radiation therapy, or oral, topical, and intravenous medication. The recommended duration of therapy is 12 months for patients who require chemotherapy for single-system bone, skin, or lymph node involvement.
For patients with both high-risk and low-risk multisystem disease, the reactivation rate after 6 months of therapy was as high as 50% on the HISTSOC-LCH-I and HISTSOC-LCH-II trials.[1,2] Based on data from the German-Austrian-Dutch (Deutsche Arbeitsgemeinschaft für Leukaemieforschung und -therapie im Kindesalter [DAL]) group trials, which treated patients for 1 year and had fewer relapses (29%),[1,3] the HISTSOC-LCH-III trial was designed to administer 12 months of chemotherapy for all high-risk multisystem patients and to randomly assign low-risk multisystem patients to either 6 months or 12 months of therapy. In patients with low-risk or high-risk disease who received 12 months of therapy, the reactivation rate was significantly reduced to approximately 30%.[4]
The standard treatment for LCH is chosen on the basis of data from international trials with large numbers of patients. However, some patients may have LCH involving only the skin, mouth, pituitary gland, or other sites not studied in these international trials. In these cases, therapy recommendations are based on case series that lack the evidence-based strength of the trials.
Clinical trials organized by the Histiocyte Society have been accruing patients on childhood treatment studies since the 1980s. Information about centers enrolling patients on these trials can be found on the ClinicalTrials.gov website.

Treatment of Low-Risk Single-System or Multisystem Disease

Treatment options for patients with low-risk single-system or multisystem disease depend on the site of involvement and include the following:

Isolated skin involvement

Treatment options for patients with asymptomatic isolated skin involvement include the following:
  1. Observation. Observation is recommended for all pediatric patients with skin-only LCH. These patients need to have a complete staging evaluation because 41% of skin-only patients referred to one center had multisystem disease requiring treatment.[5]
Therapy is suggested only for patients with symptomatic disease, which includes extensive rashes, pain, ulceration, or bleeding. Careful clinical (but not radiologic) follow-up of young infants with skin-only LCH is suggested because progression to high-risk multisystem disease is possible. Young children with skin-only LCH should be monitored periodically for many years because 1 of 19 children and 1 of 25 children in two series developed late diabetes insipidus.[6,7]
For patients who require therapy, treatment options for symptomatic isolated skin lesions include the following:
  1. Topical steroids. Medium- to high-potency steroids are effective, but recurrence after discontinuation is common.[8]
  2. Oral methotrexate. Oral methotrexate (20 mg/m2) weekly for 6 to 12 months.[9]
  3. Oral hydroxyurea. Oral hydroxyurea (20 mg/kg) daily for at least 12 months.[10]
  4. Oral thalidomide. Oral thalidomide 50 mg to 200 mg nightly.[11] Oral thalidomide may be effective for both pediatric and adult patients.
  5. Topical nitrogen mustard. Topical application of nitrogen mustard can be effective for cutaneous LCH that is resistant to oral therapies, but not for disease involving large areas of skin.[12,13]
  6. Psoralen and long-wave ultraviolet A radiation (PUVA) or UVB. Psoralen and PUVA or UVB can be effective in skin LCH, but its use is limited by the potential for late skin cancers, especially in patients with light skin tones.[14,15]
  7. Chemotherapy. Systemic chemotherapy may be used in severe and symptomatic cases.

Skeletal involvement

Single skull lesions of the frontal, parietal, or occipital regions, or single lesions of any other bone
Treatment options for patients with single skull lesions of the frontal, parietal, or occipital regions, or single lesions of any other bone, include the following:
  1. Curettage. Curettage only is the recommended therapy, when possible, for isolated bone lesions; curettage plus injection of methylprednisolone may also be used. LCH bone lesions may not need complete excision because this may increase healing time and the risk of long-term complications. Complete excision of skull lesions, which may require grafting, is not necessary.
    Low-dose radiation therapy is effective, but its use is limited in pediatric patients to lesions that threaten organ function.[16,17]; [18][Level of evidence: 3iiiA]
Skull lesions in the mastoid, temporal, or orbital bones
The mastoid, temporal, and orbital bones are referred to as CNS-risk bones. Risk refers to the increased risk of progression to diabetes insipidus followed by brain involvement.
The purpose of treating patients with isolated skull lesions in the mastoid, temporal, or orbital bones is to decrease the chance of developing diabetes insipidus and other long-term problems.[19]
Treatment options for patients with skull lesions in the mastoid, temporal, or orbital bones include the following:
  1. Chemotherapy. The current treatment for CNS-risk bones is 12 months of vinblastine/prednisone therapy, as per the HISTSOC-LCH-III (NCT00276757) study:[4,19]
    • Weekly vinblastine (6 mg/m2) for 7 weeks for good response.
    • Daily prednisone (40 mg/m2) for 4 weeks, then tapered over 2 weeks.
    • Afterward, prednisone is given for 5 days at 40 mg/m2 every 3 weeks with the vinblastine injections.
    There is some controversy about whether systemic therapy is required for the first presentation of unifocal bone LCH, even in the CNS-risk bones. Orbital and ear, nose, and throat surgeons have reported a series of patients with orbital or mastoid lesions who received only surgical curettage.[20] None of these patients developed diabetes insipidus. However, when comparing the incidence rates of diabetes insipidus in patients who received little or no chemotherapy (20%–50% incidence) with the incidence rates reported by the German-Austrian-Dutch group DAL-HX 83 trial (10% incidence in patients treated for LCH), it appears that the weight of evidence from the DAL-HX 83 trial supports chemotherapy treatment to prevent diabetes insipidus in patients with LCH of the mastoid, temporal, or orbital bones.[3,21] It should be noted, however, that the DAL-HX studies administered more drugs and treated patients for 12 months.
Vertebral or femoral bone lesions at risk of collapse
Treatment options for patients with vertebral or femoral bone lesions at risk of collapse include the following:
  1. Observation. A single vertebral body lesion without soft tissue extension to the extradural space may be observed only.
  2. Low-dose radiation therapy. Low-dose radiation therapy may be used to promote resolution in an isolated vertebral body lesion or a large femoral neck lesion at risk of fracture, where chemotherapy is not usually indicated (single bone lesion). Despite the low dose required (7–10 Gy), radiation therapy should be used with caution in the area of the thyroid gland, brain, or any growth plates.[22]
  3. Chemotherapy. Patients with soft tissue extension from vertebral lesions are often treated successfully with chemotherapy,[23][Level of evidence: 3iiDiii] but prolonged therapy does not appear to be needed beyond the period required to reduce the mass and any risk to the spinal cord. The risk of reactivation of a single bone lesion was only 9% in one large retrospective series.[24]
  4. Bracing or spinal fusion. When instability of the cervical vertebrae and/or neurologic symptoms are present, bracing—or rarely, spinal fusion—may be needed.[25] Patients with soft tissue extension from the vertebral lesions are often treated successfully with chemotherapy.[23][Level of evidence: 3iiDiii]
Multiple bone lesions (single-system multifocal bone lesions)
Treatment options for patients with multiple bone lesions (single-system multifocal bone lesions) at risk of collapse include the following:
  1. Chemotherapy. The most commonly used systemic chemotherapy regimen is the combination of vinblastine and prednisone. Based on the results of the HISTSOC-LCH-III (NCT00276757) trial, 12 months of treatment with weekly vinblastine (6 mg/m2) for 7 weeks, then every 3 weeks, is used for good responders.[4] Prednisone (40 mg/m2) is given daily for 4 weeks, then tapered over 2 weeks. Afterward, prednisone is given for 5 days at 40 mg/m2 every 3 weeks with the vinblastine injections. A short treatment course (<6 months) with only a single agent (e.g., prednisone) is not sufficient, and the number of relapses is higher. A reactivation rate of 18% was reported with a multidrug treatment regimen that was used for 6 months versus a historical reactivation rate of 50% to 80% with surgery alone or with a single-drug treatment regimen.[26] A comparison of results from two Japanese trials revealed no improvement in progression-free survival (66% vs. 65%) when additional prednisone and a prolonged maintenance phase were added.[27]
(Refer to the Multiple bone lesions in combination with skin, lymph node, or diabetes insipidus [low-risk multisystem LCH] section of this summary for information about additional agents used to treat multifocal bone LCH.)
Multiple bone lesions in combination with skin, lymph node, or diabetes insipidus (low-risk multisystem LCH)
Treatment options for patients with multiple bone lesions in combination with skin, lymph node, or diabetes insipidus (low-risk multisystem LCH) include the following:
  1. Chemotherapy (vinblastine and prednisone). Vinblastine and prednisone in combination. Based on the results of the randomized HISTSOC-LCH-III (NCT00276757)trial, the same chemotherapy regimen of vinblastine and prednisone, as described above, is used for 12 months. Patients without risk-organ involvement who were randomly assigned to receive 12 months of treatment with vinblastine/prednisone had a lower 5-year reactivation rate (37%) than did patients who received only 6 months of treatment (54%; P = .03) and patients treated with historical 6-month schedules (52% [HISTSOC-LCH-I] and 48% [HISTSOC-LCH-II]; P < .001). Most disease reactivations were in bone, skin, or other nonrisk locations.[4]
    Patients with low-risk multisystem LCH have a survival rate of almost 100%, but reactivations were shown to be major risk factors for significant late effects on the DAL and Histiocyte Society trials.[3,4]
  2. Chemotherapy (other regimens). Other chemotherapy regimens have also been effective, including the following:
    • Vincristine, cytosine arabinoside, and prednisone in combination.[28] This combination has been proven to be an effective frontline or salvage therapy. However, prednisone is now given for a much shorter time than was originally published (52 weeks): 4 weeks at 40 mg/m2 then tapered to 20 mg/m2 by week 6 during the induction phase, and for 5 days every 3 weeks at 20 mg/m2 with a single dose of vincristine and 5 days of cytosine arabinoside during maintenance.
    • Cladribine. Cladribine given at 5 mg/m2 per day for 5 days every 3 weeks for two to six cycles can be an effective salvage therapy for recurrent bone or low-risk multisystem disease.[29] More than six cycles is not recommended because of the risk of cumulative cytopenias.
  3. Bisphosphonate therapy. Bisphosphonate therapy can also be effective for treating LCH bone lesions.[30,31] A nationwide survey from Japan described 16 children treated with bisphosphonates for bone LCH. All of the children had bone disease; none had risk-organ disease. Most patients received six cycles of pamidronate at 1 mg/kg per course given at 4-week intervals. In 12 of 16 patients, all active lesions including skin (n = 3) and soft tissues (n = 3) resolved. Eight patients remained disease free at a median of 3.3 years.[32] Other bisphosphonates such as zoledronate have been used to successfully treat bone LCH.[33]
    Although bisphosphonates are used for bone LCH, some publications report response in other organs, such as skin.[31,32]

CNS disease

CNS lesions
The three types of LCH CNS lesions are as follows:
  • Mass lesions or tumors in the cerebrum, cerebellum, or choroid plexus.
  • Mass lesions of the hypothalamic-pituitary axis that are always associated with diabetes insipidus and are often associated with other endocrinopathies.
  • Neurodegenerative syndrome. T2 fluid-attenuated inversion recovery (FLAIR) hyperintense signals are present, most often in the cerebellar white matter, pons, basal ganglia, and, sometimes, in the cerebrum.
Drugs that cross the blood-brain barrier, such as cladribine, or other nucleoside analogs, such as cytarabine, are used for active CNS LCH lesions.
Treatment options for patients with CNS lesions include the following:
  1. Chemotherapy (cladribine). Treatment of mass lesions with cladribine has been effective in 13 reported cases.[34,35]; [36][Level of evidence: 3iiiDiii] Mass lesions included enlargement of the hypothalamic-pituitary axis, parenchymal mass lesions, and leptomeningeal involvement. Doses of cladribine ranged from 5 mg/m2 to 13 mg/m2, given at varying frequencies.[36][Level of evidence: 3iiiDiii]
  2. Chemotherapy (other regimens). Patients with LCH and mass lesions in the hypothalamic-pituitary region, the choroid plexus, the grey matter, or the white matter may also respond to standard LCH chemotherapy.[37,38] Treatment with vinblastine with or without corticosteroids for patients with CNS mass lesions (20 patients; mainly pituitary) demonstrated an objective response in 15 patients; 5 of 20 patients achieved a complete response, and 10 of 20 patients achieved a partial response.
CNS neurodegenerative syndrome
There is no established optimal therapy for CNS neurodegenerative LCH, and assessment of response can be difficult.[39]
It is not clear whether LCH changes in the cerebellum, pons, and basal ganglia diagnosed by magnetic resonance imaging (MRI) and without clinical neurologic findings should be treated. Early studies suggested that not all LCH-related radiologic changes progressed to clinical neurodegenerative disease. However, treatment in the early stages of clinical disease before permanent damage occurs appears to be important. The current recommendation is ongoing neurologic evaluation both clinically and with MRI scanning; therapy is started as soon as clinical neurodegenerative disease progression is noted. It is unclear whether progressive radiologic changes should be an indication for treatment.[40] In this regard, studies of cerebrospinal fluid (CSF) and serum biomarkers in an attempt to predict and prevent neurodegenerative disease are ongoing.[39]
Drugs used in active LCH, such as dexamethasone and cladribine, along with other agents, such as all-trans retinoic acid (ATRA), intravenous immunoglobulin (IVIG), infliximab, and cytarabine with or without vincristine, have been used in small numbers of patients with mixed results. Many of these agents may result in the complete or partial resolution of radiographic findings, but definitive clinical response rates have not been rigorously defined.[40-44]; [36][Level of evidence: 3iiiDiii]
  • ATRA. ATRA was given at a dose of 45 mg/m2 daily for 6 weeks, then 2 weeks per month for 1 year.[41] Patients were reported to have stable clinical status at 1 year.
  • IVIG. IVIG (400 mg/m2) alone given monthly or in combination with chemotherapy has been reported to result in stabilization of disease and even transient improvements in some patients. The duration of therapy is undefined and may be prolonged or even lifelong.[39,45]
  • Chemotherapy. A study using cytarabine with or without vincristine for up to 24 months reported improvement in the clinical and MRI findings in some patients and stabilization of disease in the others.[40][Level of evidence: 3iiiC] Seven of eight patients were monitored for more than 8 years after stopping therapy and had stable neurologic and radiographic findings.
    In the Japan LCH Study Group-96 Protocol, cytarabine failed to prevent the onset of neurodegenerative syndrome. Patients received cytarabine 100 mg/m2 daily on days 1 to 5 during induction and 150 mg/m2 on day 1 of each maintenance cycle (every 2 weeks for 6 months). Three of 91 patients developed neurodegenerative disease, which is similar to the rate reported for patients on the Histiocyte Society studies.[46]
  • BRAF V600E inhibitor therapy. Very early results confirm the activity of BRAF V600E inhibitor therapy in BRAF V600E–positive LCH. The earliest published results included eight adults with BRAF-mutated Erdheim-Chester disease treated with vemurafenib; four patients also had LCH, and two of these patients had involvement of the cerebellum and pons. All patients had a good response to vemurafenib. One patient developed a cutaneous squamous cell carcinoma that was treated with surgical excision.[47] Three patients with neurodegenerative-disease LCH who had progressive disease 1 to 3 years after cytotoxic chemotherapy were treated with either vemurafenib or dabrafenib and had complete (n = 1) or partial (n = 2) clinical and radiologic responses. Another patient who had neurodegenerative-disease LCH for more than 10 years developed progressive disease but had limited exposure to these agents because of excessive cutaneous and joint toxicities.[48]
Early recognition of clinical neurodegeneration and early institution of therapy appear to be vital for success of therapy. Studies combining MRI findings together with CSF markers of demyelination, to identify patients who require therapy even before onset of clinical symptoms, are underway in several countries.

Treatment of High-Risk Multisystem Disease

Treatment options for patients with high-risk multisystem disease (spleen, liver, and bone marrow involving one or more sites) include the following:
  1. Chemotherapy.
Evidence (chemotherapy):
  1. In the HISTSOC-LCH-II and HISTSOC-LCH-III (NCT00276757) studies, the standard arm consisted of vinblastine and prednisone, as described above, but mercaptopurine was added to the continuation phase of the protocol.[3,19]
    • The standard therapy length recommended for LCH involving the spleen, liver, or bone marrow (high-risk organs) is now 12 months, based on the DAL-HX 83 and HISTSOC-LCH-III studies.
  2. The HISTSOC-LCH-II study was a randomized trial to compare treatment of patients with either vinblastine, prednisone, and mercaptopurine or vinblastine, prednisone, mercaptopurine, and etoposide.[2][Level of evidence: 1iiA]
    • There was no statistically significant difference in outcomes (response at 6 weeks, 5-year probability of survival, relapses, and permanent consequences) between the two treatment groups. Hence, etoposide has not been used in subsequent Histiocyte Society trials.
    • Late review of the results, however, reported reduced mortality of patients with risk-organ involvement in the etoposide arm.[2]
  3. Although controversial, a comparison of patients in the HISTSOC-LCH-I trial with patients in the HISTSOC-LCH-II trial suggested that increased treatment intensity promoted additional early responses and reduced mortality. It is important to note that those studies included lungs as risk organs. However, subsequent analyses have shown that lung involvement lacks prognostic significance.[49]
  4. The HISTSOC-LCH-III (NCT00276757) study randomly assigned risk organ–affected patients to receive either vinblastine/prednisone/mercaptopurine or vinblastine/prednisone/mercaptopurine plus methotrexate (intravenous during the induction phase and oral in the continuation phase).[4]
    1. The response rates at 6 and 12 weeks and overall survival (OS) were not improved; however, there were significantly increased grade 3 and grade 4 toxicities in patients who received methotrexate.
    2. An important finding of the HISTSOC-LCH-III study was that the mortality of patients with high-risk LCH on both arms of the study was significantly reduced compared with that of patients on the earlier HISTSOC-LCH-II study, even though the standard arm utilized the same drugs. Possible explanations for reduced mortality include the following:
      • A second 6-week induction phase of weekly vinblastine with prednisone was administered for 3 days per week. This reinduction phase was given to all patients who did not achieve a status of no active disease by the end of the 6-week induction phase, before going onto the every-3-weeks maintenance courses. The rate of no active disease increased after the second induction phase; this course may have played a significant role in the reduced mortality rate.
      • Better supportive care.
      • Earlier change to an effective salvage strategy for nonresponsive lesions.
    3. It should be noted that although survival was improved in the HISTSOC-LCH-III study, only 60% of patients had no active disease in risk organs after a year of therapy, and 25% to 29% of patients relapsed.
  5. The Japan LCH Study Group (JLSG) reported the following results for patients treated on the JLSG-96 trial. Treatment included a 6-week induction regimen of cytosine arabinoside, vincristine, and prednisolone followed by 6 months of maintenance therapy with cytarabine, vincristine, prednisolone, and low-dose intravenous methotrexate. If patients had a poor response to the initial regimen, they were switched to a salvage regimen of intensive combination doxorubicin, cyclophosphamide, methotrexate, vincristine, and prednisolone.[46]
    • The 5-year response rate was 78%, and the OS rate was 95% for patients with multisystem disease.
    • Diabetes insipidus occurred in 8.9% of patients with multisystem disease.
    • Similar to the HISTSOC-LCH-III (NCT00276757) study, the important finding of this study was the decreased mortality compared with previous JLSG studies and to the HISTSOC-LCH-II study. This was attributed to the early change to a more effective salvage therapy for patients with nonresponsive disease, as well as better supportive care.[46]
    • The study had a high reactivation rate, which prompted several changes, including an increase in the duration of the trial to 12 months and the addition of vinblastine, prednisone, mercaptopurine, and methotrexate.[50]
  6. The JLSG-02 protocol was similar to the JLSG-96 study, except for adding cyclosporine to the reinduction of poor responders and increasing the length of treatment to 54 weeks for good responders and 60 weeks for poor responders.[51]
    • Despite a markedly increased intensity of treatment, the event-free survival (EFS) was only 46% for high-risk patients and 70% for low-risk patients, whereas the rates for the HISTSOC-LCH-III study were 70% and 63%.
Some patients develop a macrophage activation of their marrow. This may be confusing to clinicians, who may think the patient has hemophagocytic lymphohistiocytosis and LCH. The best therapy for this life-threatening manifestation is not clear because it tends not to respond well to standard hemophagocytic lymphohistiocytosis therapy. Clofarabine, anti-CD52 antibody alemtuzumab, or reduced-intensity allogeneic stem cell transplant could be considered.[52]

Treatment Options for Childhood LCH No Longer Considered Effective

Treatments that have been used in the past but are no longer recommended for pediatric patients with LCH in any location include cyclosporine [53] and interferon-alpha.[54] Extensive surgery is also not indicated. Curettage of a circumscribed skull lesion may be sufficient if the lesion is not in the temporal, mastoid, or orbital areas (CNS risk). Patients with disease in these particular sites are recommended to receive 6 months of systemic therapy with vinblastine and prednisone. For lesions of the mandible, extensive surgery may destroy any possibility of secondary tooth development. Surgical resection of groin or genital lesions is contraindicated because these lesions can be healed by chemotherapy.
Radiation therapy use in LCH has been significantly reduced in pediatric patients, and even low-dose radiation therapy should be limited to single-bone vertebral body lesions or other single-bone lesions compressing the spinal cord or optic nerve that do not respond to chemotherapy.[55]

Treatment Options Under Clinical Evaluation

Information about National Cancer Institute (NCI)–supported clinical trials can be found on the NCI website. For information about clinical trials sponsored by other organizations, refer to the ClinicalTrials.gov website.
The following are examples of national and/or institutional clinical trials that are currently being conducted:
  • HISTSOC-LCH-IV (NCT02205762) (LCH-IV, International Collaborative Treatment Protocol for Children and Adolescents With LCH): On the basis of features at presentation and response to treatment, the LCH-IV study tailors treatment to one of the following seven strata:
    • Stratum I: First-line treatment for multisystem LCH patients (group 1) and patients with single-system LCH with multifocal bone or CNS-risk lesions (group 2).
    • Stratum II: Second-line treatment for nonrisk patients (patients without risk-organ involvement who fail first-line therapy or have a reactivation after completion of first-line therapy).
    • Stratum III: Salvage treatment for risk LCH (patients with dysfunction of risk organs who fail first-line therapy).
    • Stratum IV: Stem cell transplantation for risk LCH (patients with dysfunction of risk organs who fail first-line therapy).
    • Stratum V: Monitoring and treatment of isolated tumorous and neurodegenerative CNS LCH.
    • Stratum VI: Natural history and management of other single-system LCH (patients who do not need systemic therapy at the time of diagnosis).
    • Stratum VII (long-term follow up): All patients, regardless of previous therapy, will be monitored for reactivation or permanent consequences once complete disease resolution has been achieved and the respective protocol treatment has been completed.
  • NCT02670707 (Vinblastine/Prednisone Versus Single Therapy With Cytarabine for LCH):The purpose of this trial is to compare previously used vinblastine/prednisone to single therapy with cytarabine for LCH.
It is preferable that patients with LCH be enrolled in a clinical trial whenever possible so that advances in therapy can be achieved more quickly, utilizing evidence-based recommendations and to ensure optimal care. Information about clinical trials for LCH in children is available from the NCI websiteHistiocyte Society website and the North American Consortium for Histiocytosis (NACHO) website.

Current Clinical Trials

Use our advanced clinical trial search to find NCI-supported cancer clinical trials that are now enrolling patients. The search can be narrowed by location of the trial, type of treatment, name of the drug, and other criteria. General information about clinical trials is also available.

Assessment of Response to Treatment

Response assessment remains one of the most difficult areas in LCH therapy unless there is a specific area that can be followed clinically or with sonography, computed tomography (CT), or MRI scans, such as the skin, hepato/splenomegaly, and other mass lesions. Clinical judgment, including evaluation of pain and other symptoms, remains important.
Bone lesions may take many months to heal and are difficult to evaluate on plain radiographs, although sclerosis around the periphery of a bone lesion suggests healing. CT or MRI scans are useful in assessing response of a soft tissue mass associated with a bone lesion, but are not particularly helpful in assessing the response of lytic bone lesions. Technetium Tc 99m bone scans remain positive in healing bone. Positron emission tomography (PET) scans may be helpful in following the response to therapy because the intensity of the PET image diminishes with the response of lesions and healing of bone.[56]
For children or adults with lung LCH, pulmonary function testing and high-resolution CT scans are sensitive methods for detecting disease progression.[57] Residual interstitial changes reflecting residual fibrosis or residual inactive cysts must be distinguished from active disease; somatostatin analogue scintigraphy may be useful in this regard.[58]
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  47. Haroche J, Cohen-Aubart F, Emile JF, et al.: Reproducible and sustained efficacy of targeted therapy with vemurafenib in patients with BRAF(V600E)-mutated Erdheim-Chester disease. J Clin Oncol 33 (5): 411-8, 2015. [PUBMED Abstract]
  48. McClain KL, Picarsic J, Chakraborty R, et al.: CNS Langerhans cell histiocytosis: Common hematopoietic origin for LCH-associated neurodegeneration and mass lesions. Cancer 124 (12): 2607-2620, 2018. [PUBMED Abstract]
  49. Ronceray L, Pötschger U, Janka G, et al.: Pulmonary involvement in pediatric-onset multisystem Langerhans cell histiocytosis: effect on course and outcome. J Pediatr 161 (1): 129-33.e1-3, 2012. [PUBMED Abstract]
  50. Imashuku S, Kinugawa N, Matsuzaki A, et al.: Langerhans cell histiocytosis with multifocal bone lesions: comparative clinical features between single and multi-systems. Int J Hematol 90 (4): 506-12, 2009. [PUBMED Abstract]
  51. Morimoto A, Shioda Y, Imamura T, et al.: Intensified and prolonged therapy comprising cytarabine, vincristine and prednisolone improves outcome in patients with multisystem Langerhans cell histiocytosis: results of the Japan Langerhans Cell Histiocytosis Study Group-02 Protocol Study. Int J Hematol 104 (1): 99-109, 2016. [PUBMED Abstract]
  52. Jordan MB, McClain KL, Yan X, et al.: Anti-CD52 antibody, alemtuzumab, binds to Langerhans cells in Langerhans cell histiocytosis. Pediatr Blood Cancer 44 (3): 251-4, 2005. [PUBMED Abstract]
  53. Minkov M, Grois N, Broadbent V, et al.: Cyclosporine A therapy for multisystem langerhans cell histiocytosis. Med Pediatr Oncol 33 (5): 482-5, 1999. [PUBMED Abstract]
  54. Lukina EA, Kuznetsov VP, Beliaev DL, et al.: [The treatment of histiocytosis X (Langerhans-cell histiocytosis) with alpha-interferon preparations] Ter Arkh 65 (11): 67-70, 1993. [PUBMED Abstract]
  55. Gadner H, Ladisch S: The treatment of Langerhans cell histiocytosis. In: Weitzman S, Egeler R M, eds.: Histiocytic Disorders of Children and Adults. Cambridge, United Kingdom: Cambridge University Press, 2005, pp 229-53.
  56. Phillips M, Allen C, Gerson P, et al.: Comparison of FDG-PET scans to conventional radiography and bone scans in management of Langerhans cell histiocytosis. Pediatr Blood Cancer 52 (1): 97-101, 2009. [PUBMED Abstract]
  57. Ha SY, Helms P, Fletcher M, et al.: Lung involvement in Langerhans' cell histiocytosis: prevalence, clinical features, and outcome. Pediatrics 89 (3): 466-9, 1992. [PUBMED Abstract]
  58. Tazi A, Hiltermann J, Vassallo R: Adult lung histiocytosis. In: Weitzman S, Egeler R M, eds.: Histiocytic Disorders of Children and Adults. Cambridge, United Kingdom: Cambridge University Press, 2005, pp 187-207.

Treatment of Recurrent, Refractory, or Progressive Childhood LCH

Reactivation of Single-System and Multisystem LCH

Reactivation of Langerhans cell histiocytosis (LCH) after complete response is common.[1] In a large study, the percentage of patients with reactivations was 9% to 17.4% for single-site disease; 37% for single-system, multifocal disease; 46% for multisystem (nonrisk organ) disease; and 54% for risk-organ involvement. Forty-three percent of reactivations were in bone, 11% in ears, 9% in skin, and 7% developed diabetes insipidus; a lower percentage of patients had lymph node, bone marrow, or risk-organ relapses.[1] The median time to reactivation was 12 to 15 months in nonrisk patients and 9 months in risk patients. One-third of patients had more than one reactivation varying from 9 to 14 months after the initial reactivation. Patients with reactivations were more likely to have long-term sequelae in the bones, diabetes insipidus, or other endocrine, ear, or lung problems.[1]
A comprehensive review of the German-Austrian-Dutch (Deutsche Arbeitsgemeinschaft für Leukaemieforschung und -therapie im Kindesalter [DAL]) and Histiocyte Society clinical trials revealed a reactivation rate of 46% at 5 years for patients with multisystem LCH, with most reactivations occurring within 2 years of first remission. A second reactivation occurred in 44% of patients, again within 2 years of the second remission. Involvement of the risk organs in these reactivations occurred only in those who were initially in the high-risk group (meaning they had liver, spleen, or bone marrow involvement at the time of original diagnosis).[2][Level of evidence: 3iiiDiii] Most reactivations, even in patients with high-risk disease who initially responded to therapy, were in bone, skin, or other nonrisk locations.
Consistent with these findings, the percentage of reactivations in multisystem disease was 45% in the Japanese trial [3][Level of evidence: 1iiA] and 46% in the HISTSOC-LCH-II trial.[4] There was no statistically significant difference in reactivations between the high-risk and low-risk groups. Both the DAL-HX and Japanese studies concluded that intensified treatment increased the rapidity of response, particularly in young children and infants younger than 2 years, and together with rapid switch to salvage therapy for nonresponders, reduced mortality for patients with high-risk multisystem LCH. Based on the HISTSOC-LCH-III (NCT00276757) randomized trial, prolongation of therapy also significantly reduced the rate of reactivation, although the exact duration of therapy (12 vs. 24 months) is being addressed in the HISTSOC-LCH-IV (NCT02205762) trial.

Treatment of Low-Risk Single-System or Multisystem LCH

The optimal therapy for patients with recurrent, refractory, or progressive LCH has not been determined.
Treatment options for patients with recurrent, refractory, or progressive low-risk single-system or multisystem disease include the following:
  1. Chemotherapy.
  2. Bisphosphonate therapy.
Several chemotherapy regimens exist for the treatment of recurrent, refractory, or progressive low-risk disease.
Evidence (chemotherapy):
  1. Patients with recurrent bone disease that recurs months after vinblastine and prednisone are stopped can benefit from treatment with a reinduction of vinblastine weekly and daily prednisone for 6 weeks. If there is no active disease or very little evidence of active disease, treatment can be changed to every 3 weeks, with the addition of oral mercaptopurine nightly.[5]
  2. An alternative treatment regimen for patients with any combination of low-risk sites employs vincristine, prednisone, and cytosine arabinoside.[6] The prednisone dose is reduced from the dose used in the original publication.
  3. Cladribine at 5 mg/m2 per day for 5 days per course has also been shown to be effective therapy for recurrent low-risk LCH (multifocal bone and low-risk multisystem LCH), with very little toxicity.[7] Cladribine therapy should, if possible, be limited to a maximum of six cycles to avoid cumulative and potentially long-lasting cytopenias.
  4. Clofarabine is a proven effective therapy for patients with multiple relapses of low-risk or high-risk LCH.[8]
  5. Treatment with hydroxyurea, alone or in combination with oral methotrexate, resulted in responses in 12 of 15 of patients with low-risk recurrent LCH.[9]
  6. A phase II trial of thalidomide for patients with LCH (ten low-risk patients; six high-risk patients) who failed primary and at least one secondary regimen demonstrated complete (four of ten) and partial (three of ten) responses for the low-risk patients. Complete remission was defined as healing of bone lesions on plain radiographs (n = 3) or complete resolution of skin rash (n = 4, including 3 with bone lesions that had complete resolution). Partial response was defined as healing of bone lesion, but then worsening of a skin rash that was partially resolved. However, dose-limiting toxicities, such as neuropathy and neutropenia, may limit the overall usefulness of thalidomide.[10] This agent is not used in pediatric patients to a significant degree.
Bisphosphonate therapy is also effective for treating recurrent LCH bone lesions.[11]
Evidence (bisphosphonate therapy):
  1. In a survey from Japan, bisphosphonate therapy successfully treated the bone lesions in 12 of 16 patients. Skin and soft tissue LCH lesions also resolved in the responding patients. None of the patients had risk-organ disease. Most patients received six cycles of pamidronate at 1 mg/kg per course, given at 4-week intervals. Eight of the 12 patients remained disease free at a median of 3.3 years.[12]
  2. Other bisphosphonates, such as zoledronate and oral alendronate, have also been successful in treating bone LCH.[13-15]

Treatment of High-Risk Multisystem LCH

Data from the DAL group studies showed that patients with multisystem high-risk LCH who had progressive disease by week 6 of standard induction treatment or who did not achieve at least a partial response by week 12 had only a 10% chance of survival.[16] These results were consistent with those of the less-intensive HISTSOC-LCH-II trial in which patients treated with vinblastine/prednisone who did not respond well by week 6 had a 27% chance of survival, compared with 52% for good responders.[4][Level of evidence: 1iiA] To improve on these results, patients with poorly responsive disease need to move to salvage strategies by week 6 for progressive disease and no later than week 12 for those without at least a good response.
Treatment options for patients with recurrent, refractory, or progressive high-risk multisystem disease include the following:
  1. Chemotherapy.
  2. Hematopoietic stem cell transplantation (HSCT).
Evidence (chemotherapy):
  1. Cladribine and cytarabine.
    • Ten patients with refractory high-risk organ involvement (liver, spleen, or bone marrow) and resistant multisystem low-risk organ involvement were treated with an intensive acute myeloid leukemia–like protocol consisting of cladribine and cytosine arabinoside.[17][Level of evidence: 3iiiDiv] The follow-up HISTSOC-LCH-S-2005 trial accrued 27 patients and showed a progression-free survival rate of 63% and a 5-year overall survival (OS) rate of 85% in this refractory high-risk patient population. However, all patients developed grade 4 hematologic toxicity, and five of these patients had severe sepsis.[18]
    • For centers that cannot provide the intensive supportive care needed for this protocol, an alternative protocol using lower doses of cladribine (5 mg/m2/day × 5) and cytosine-arabinoside (100 mg/m2/day × 5) was published.[19] Six of nine patients had no active disease, and one patient had improved status after six courses. Some patients had maintenance therapy; ultimately, seven of nine patients remained in complete remission, with a median follow-up of 6.5 years.
  2. Clofarabine. Patients who failed cladribine were reported to respond to treatment with clofarabine.[20]; [21][Level of evidence: 3iiiDii]
    • Eleven patients with recurrent multisystem high-risk and low-risk disease treated with clofarabine had a 90% OS.[8] If confirmed in prospective trials, the reduced toxicity of this regimen compared with the cladribine/cytarabine combination could be advantageous, despite the cost of the drug.
HSCT has been used in patients with multisystem high-risk organ involvement that is refractory to chemotherapy.[11,22-24] Early results showing very high treatment-related mortality in these very ill young infants led to the development of reduced-intensity conditioning.
Evidence (HSCT):
  1. A review from the United Kingdom, however, suggests that in transplant centers with LCH HSCT experience, there was no advantage to reduced-intensity conditioning in their setting. Reduced-intensity conditioning provided no OS advantage over myeloablative conditioning for LCH patients;[25] the relapse rate after reduced-intensity conditioning was significantly higher (28%) than the relapse rate after myeloablative conditioning (8%). However, many of the reduced-intensity conditioning patients who relapsed were successfully re-treated with chemotherapy alone.[25]

Treatment Options Under Clinical Evaluation

Information about National Cancer Institute (NCI)–supported clinical trials can be found on the NCI website. For information about clinical trials sponsored by other organizations, refer to the ClinicalTrials.gov website.
The following are examples of national and/or institutional clinical trials that are currently being conducted:
  • HISTSOC-LCH-IV (NCT02205762) (LCH-IV, International Collaborative Treatment Protocol for Children and Adolescents With LCH): On the basis of features at presentation and response to treatment, the LCH-IV study tailors treatment to one of the following seven strata:
    • Stratum I: First-line treatment for multisystem LCH patients (group 1) and patients with single-system LCH with multifocal bone or CNS-risk lesions (group 2).
    • Stratum II: Second-line treatment for nonrisk patients (patients without risk-organ involvement who fail first-line therapy or have a reactivation after completion of first-line therapy).
    • Stratum III: Salvage treatment for risk LCH (patients with dysfunction of risk organs who fail first-line therapy).
    • Stratum IV: Stem cell transplantation for risk LCH (patients with dysfunction of risk organs who fail first-line therapy).
    • Stratum V: Monitoring and treatment of isolated tumorous and neurodegenerative CNS LCH.
    • Stratum VI: Natural history and management of other single-system LCH (patients who do not need systemic therapy at the time of diagnosis).
    • Stratum VII (long-term follow up): All patients, regardless of previous therapy, will be monitored for reactivation or permanent consequences once complete disease resolution has been achieved and the respective protocol treatment has been completed.
  • APEC1621 (NCT03155620) (Pediatric MATCH: Targeted Therapy Directed by Genetic Testing in Treating Pediatric Patients with Relapsed or Refractory Advanced Solid Tumors, Non-Hodgkin Lymphomas, or Histiocytic Disorders): NCI-COG Pediatric Molecular Analysis for Therapeutic Choice (MATCH), referred to as Pediatric MATCH, will match targeted agents with specific molecular changes identified using a next-generation sequencing targeted assay of more than 3,000 different mutations across more than 160 genes in refractory and recurrent solid tumors. Children and adolescents aged 1 to 21 years are eligible for the trial.
    Tumor tissue from progressive or recurrent disease must be available for molecular characterization. Patients with tumors that have molecular variants addressed by treatment arms included in the trial will be offered treatment on Pediatric MATCH. Additional information can be obtained on the ClinicalTrials.gov website for APEC1621 (NCT03155620).
  • RAS pathway (MAP2K/ERK) inhibitors: The discovery that most patients with LCH have BRAF V600E or other mutations that result in activation of the RAS pathway suggests that new therapies that target molecules within this pathway will become an important part of LCH therapy. Vemurafenib has been shown to induce significant responses in patients with BRAF V600E–positive Erdheim-Chester disease and in multiply relapsed BRAF V600E patients with multisystem LCH.[26]
  • Tyrosine kinase inhibitors: Imatinib has been shown to decrease differentiation of CD34-positive stem cells to dendritic cells; small case reports of its efficacy in patients with LCH have been published.[27,28]
References
  1. Pollono D, Rey G, Latella A, et al.: Reactivation and risk of sequelae in Langerhans cell histiocytosis. Pediatr Blood Cancer 48 (7): 696-9, 2007. [PUBMED Abstract]
  2. Minkov M, Steiner M, Pötschger U, et al.: Reactivations in multisystem Langerhans cell histiocytosis: data of the international LCH registry. J Pediatr 153 (5): 700-5, 705.e1-2, 2008. [PUBMED Abstract]
  3. Morimoto A, Ikushima S, Kinugawa N, et al.: Improved outcome in the treatment of pediatric multifocal Langerhans cell histiocytosis: Results from the Japan Langerhans Cell Histiocytosis Study Group-96 protocol study. Cancer 107 (3): 613-9, 2006. [PUBMED Abstract]
  4. Gadner H, Grois N, Pötschger U, et al.: Improved outcome in multisystem Langerhans cell histiocytosis is associated with therapy intensification. Blood 111 (5): 2556-62, 2008. [PUBMED Abstract]
  5. Titgemeyer C, Grois N, Minkov M, et al.: Pattern and course of single-system disease in Langerhans cell histiocytosis data from the DAL-HX 83- and 90-study. Med Pediatr Oncol 37 (2): 108-14, 2001. [PUBMED Abstract]
  6. Egeler RM, de Kraker J, Voûte PA: Cytosine-arabinoside, vincristine, and prednisolone in the treatment of children with disseminated Langerhans cell histiocytosis with organ dysfunction: experience at a single institution. Med Pediatr Oncol 21 (4): 265-70, 1993. [PUBMED Abstract]
  7. Weitzman S, Braier J, Donadieu J, et al.: 2'-Chlorodeoxyadenosine (2-CdA) as salvage therapy for Langerhans cell histiocytosis (LCH). results of the LCH-S-98 protocol of the Histiocyte Society. Pediatr Blood Cancer 53 (7): 1271-6, 2009. [PUBMED Abstract]
  8. Simko SJ, Tran HD, Jones J, et al.: Clofarabine salvage therapy in refractory multifocal histiocytic disorders, including Langerhans cell histiocytosis, juvenile xanthogranuloma and Rosai-Dorfman disease. Pediatr Blood Cancer 61 (3): 479-87, 2014. [PUBMED Abstract]
  9. Zinn DJ, Grimes AB, Lin H, et al.: Hydroxyurea: a new old therapy for Langerhans cell histiocytosis. Blood 128 (20): 2462-2465, 2016. [PUBMED Abstract]
  10. McClain KL, Kozinetz CA: A phase II trial using thalidomide for Langerhans cell histiocytosis. Pediatr Blood Cancer 48 (1): 44-9, 2007. [PUBMED Abstract]
  11. Kudo K, Ohga S, Morimoto A, et al.: Improved outcome of refractory Langerhans cell histiocytosis in children with hematopoietic stem cell transplantation in Japan. Bone Marrow Transplant 45 (5): 901-6, 2010. [PUBMED Abstract]
  12. Farran RP, Zaretski E, Egeler RM: Treatment of Langerhans cell histiocytosis with pamidronate. J Pediatr Hematol Oncol 23 (1): 54-6, 2001. [PUBMED Abstract]
  13. Morimoto A, Shioda Y, Imamura T, et al.: Nationwide survey of bisphosphonate therapy for children with reactivated Langerhans cell histiocytosis in Japan. Pediatr Blood Cancer 56 (1): 110-5, 2011. [PUBMED Abstract]
  14. Sivendran S, Harvey H, Lipton A, et al.: Treatment of Langerhans cell histiocytosis bone lesions with zoledronic acid: a case series. Int J Hematol 93 (6): 782-6, 2011. [PUBMED Abstract]
  15. Chellapandian D, Makras P, Kaltsas G, et al.: Bisphosphonates in Langerhans Cell Histiocytosis: An International Retrospective Case Series. Mediterr J Hematol Infect Dis 8 (1): e2016033, 2016. [PUBMED Abstract]
  16. Gadner H, Grois N, Arico M, et al.: A randomized trial of treatment for multisystem Langerhans' cell histiocytosis. J Pediatr 138 (5): 728-34, 2001. [PUBMED Abstract]
  17. Imamura T, Sato T, Shiota Y, et al.: Outcome of pediatric patients with Langerhans cell histiocytosis treated with 2 chlorodeoxyadenosine: a nationwide survey in Japan. Int J Hematol 91 (4): 646-51, 2010. [PUBMED Abstract]
  18. Donadieu J, Bernard F, van Noesel M, et al.: Cladribine and cytarabine in refractory multisystem Langerhans cell histiocytosis: results of an international phase 2 study. Blood 126 (12): 1415-23, 2015. [PUBMED Abstract]
  19. Rosso DA, Amaral D, Latella A, et al.: Reduced doses of cladribine and cytarabine regimen was effective and well tolerated in patients with refractory-risk multisystem Langerhans cell histiocytosis. Br J Haematol 172 (2): 287-90, 2016. [PUBMED Abstract]
  20. Rodriguez-Galindo C, Jeng M, Khuu P, et al.: Clofarabine in refractory Langerhans cell histiocytosis. Pediatr Blood Cancer 51 (5): 703-6, 2008. [PUBMED Abstract]
  21. Abraham A, Alsultan A, Jeng M, et al.: Clofarabine salvage therapy for refractory high-risk langerhans cell histiocytosis. Pediatr Blood Cancer 60 (6): E19-22, 2013. [PUBMED Abstract]
  22. Akkari V, Donadieu J, Piguet C, et al.: Hematopoietic stem cell transplantation in patients with severe Langerhans cell histiocytosis and hematological dysfunction: experience of the French Langerhans Cell Study Group. Bone Marrow Transplant 31 (12): 1097-103, 2003. [PUBMED Abstract]
  23. Nagarajan R, Neglia J, Ramsay N, et al.: Successful treatment of refractory Langerhans cell histiocytosis with unrelated cord blood transplantation. J Pediatr Hematol Oncol 23 (9): 629-32, 2001. [PUBMED Abstract]
  24. Caselli D, Aricò M; EBMT Paediatric Working Party: The role of BMT in childhood histiocytoses. Bone Marrow Transplant 41 (Suppl 2): S8-S13, 2008. [PUBMED Abstract]
  25. Veys PA, Nanduri V, Baker KS, et al.: Haematopoietic stem cell transplantation for refractory Langerhans cell histiocytosis: outcome by intensity of conditioning. Br J Haematol 169 (5): 711-8, 2015. [PUBMED Abstract]
  26. Haroche J, Cohen-Aubart F, Emile JF, et al.: Dramatic efficacy of vemurafenib in both multisystemic and refractory Erdheim-Chester disease and Langerhans cell histiocytosis harboring the BRAF V600E mutation. Blood 121 (9): 1495-500, 2013. [PUBMED Abstract]
  27. Janku F, Amin HM, Yang D, et al.: Response of histiocytoses to imatinib mesylate: fire to ashes. J Clin Oncol 28 (31): e633-6, 2010. [PUBMED Abstract]
  28. Wagner C, Mohme H, Krömer-Olbrisch T, et al.: Langerhans cell histiocytosis: treatment failure with imatinib. Arch Dermatol 145 (8): 949-50, 2009. [PUBMED Abstract]

Late Disease and Treatment Effects of Childhood LCH

The reported overall frequency of long-term consequences of Langerhans cell histiocytosis (LCH) has ranged from 20% to 70%. This wide variation in frequency results from case definition, sample size, therapy used, method of data collection, and follow-up duration. Quality-of-life studies have reported the following:
  • In one quality-of-life study of long-term survivors of skeletal LCH, the quality-of-life scores were not significantly different from those of healthy control children and adults.[1] In addition, the quality-of-life scores were very similar between those with and without permanent sequelae.
  • In another study of 40 patients who were carefully screened for late effects, adverse quality-of-life scores were found in more than 50% of patients.[2] Seventy-five percent of patients had detectable long-term sequelae—hypothalamic/pituitary dysfunction (50%), cognitive dysfunction (20%), and cerebellar involvement (17.5%) being the most common.
Children with low-risk organ involvement (skin, bones, lymph nodes, or pituitary gland) have an approximately 20% chance of developing long-term sequelae.[3,4] Patients with multisystem involvement have an approximately 70% incidence of long-term complications.[3,5-7]
The late effects of LCH may occur in the following body systems:
  • Endocrine. Patients with diabetes insipidus are at risk of panhypopituitarism and should be monitored carefully for adequacy of growth and development. In a retrospective review of 141 patients with LCH and diabetes insipidus, 43% developed growth hormone (GH) deficiency. [5-7] The 5-year risk of GH deficiency among children with LCH and diabetes insipidus was 35%, and the 10-year risk was 54%. There was no increased reactivation of LCH in patients who received GH compared with those who did not.[5] Growth and development problems are more frequent because of the young age at presentation and the more toxic effects of long-term prednisone therapy in the very young child.
  • Special senses. Hearing loss has been found in 38% of children who were treated for LCH.[7] Seventy percent of patients with LCH in this study had ear involvement, which included aural discharge, mastoid swelling, and hearing loss. Of those with computed tomography or magnetic resonance imaging (MRI) abnormalities in the mastoid, 59% had hearing loss.[8][Level of evidence: 3iiiC]
  • Neurologic. Neurologic symptoms secondary to vertebral compression of cervical lesions have been reported in 3 of 26 patients with LCH and spinal lesions.[7] Central nervous system (CNS) LCH occurs most often in children with LCH of the pituitary or CNS-risk skull bones (mastoid, orbit, or temporal bone). Significant cognitive defects and MRI abnormalities may develop in some long-term survivors with CNS-risk skull lesions.[9] Some patients have markedly abnormal cerebellar function and behavior abnormalities, while others have subtle deficits in short-term memory and brain stem–evoked potentials.[10]
  • Skeletal. Orthopedic problems from lesions of the spine, femur, tibia, or humerus may be seen in 20% of patients. These problems include vertebral collapse or instability of the spine that may lead to scoliosis and facial or limb asymmetry.
  • Respiratory. Diffuse pulmonary disease may result in poor lung function with higher risk of infections and decreased exercise tolerance. These patients should be monitored with pulmonary function testing, including the diffusing capacity of carbon monoxide and ratio of residual volume to total lung capacity.[11]
  • Digestive. Liver disease may lead to sclerosing cholangitis, which rarely responds to any treatment other than liver transplantation.[12] Dental problems characterized by loss of teeth have been significant for some patients, usually related to overly aggressive dental surgery.[13]
  • Subsequent neoplasms. Bone marrow failure secondary to LCH or from therapy is rare and is associated with a higher risk of malignancy. Patients with LCH have a higher-than-normal risk of developing secondary cancers.[14,15]
    Leukemia (usually acute myeloid leukemia) occurs after treatment, as does lymphoblastic lymphoma. Concurrent LCH and malignancy has been reported in a few patients, and some patients have had their malignancy first, followed by development of LCH. Three patients with T-cell acute lymphoblastic leukemia (ALL) and aggressive LCH were reported and, as with all histiocytic disorders associated with or following lymphoblastic malignancies, the same genetic changes were found in both diseases, suggesting a shared clonal origin.[16-18] One study reported two cases in which clonality with the same T-cell receptor gamma genotype was found.[17] The authors of this study emphasized the plasticity of lymphocytes developing into Langerhans cells. In the second study, one patient with LCH after T-cell ALL who had the same T-cell receptor gene rearrangements and activating mutations of the NOTCH1 gene was described.[18]
    An association between solid tumors and LCH has also been reported. Solid tumors associated with LCH include retinoblastoma, brain tumors, hepatocellular carcinoma, and Ewing sarcoma.
References
  1. Lau LM, Stuurman K, Weitzman S: Skeletal Langerhans cell histiocytosis in children: permanent consequences and health-related quality of life in long-term survivors. Pediatr Blood Cancer 50 (3): 607-12, 2008. [PUBMED Abstract]
  2. Nanduri VR, Pritchard J, Levitt G, et al.: Long term morbidity and health related quality of life after multi-system Langerhans cell histiocytosis. Eur J Cancer 42 (15): 2563-9, 2006. [PUBMED Abstract]
  3. Haupt R, Nanduri V, Calevo MG, et al.: Permanent consequences in Langerhans cell histiocytosis patients: a pilot study from the Histiocyte Society-Late Effects Study Group. Pediatr Blood Cancer 42 (5): 438-44, 2004. [PUBMED Abstract]
  4. Chow TW, Leung WK, Cheng FWT, et al.: Late outcomes in children with Langerhans cell histiocytosis. Arch Dis Child 102 (9): 830-835, 2017. [PUBMED Abstract]
  5. Donadieu J, Rolon MA, Pion I, et al.: Incidence of growth hormone deficiency in pediatric-onset Langerhans cell histiocytosis: efficacy and safety of growth hormone treatment. J Clin Endocrinol Metab 89 (2): 604-9, 2004. [PUBMED Abstract]
  6. Komp DM: Long-term sequelae of histiocytosis X. Am J Pediatr Hematol Oncol 3 (2): 163-8, 1981. [PUBMED Abstract]
  7. Willis B, Ablin A, Weinberg V, et al.: Disease course and late sequelae of Langerhans' cell histiocytosis: 25-year experience at the University of California, San Francisco. J Clin Oncol 14 (7): 2073-82, 1996. [PUBMED Abstract]
  8. Nanduri V, Tatevossian R, Sirimanna T: High incidence of hearing loss in long-term survivors of multisystem Langerhans cell histiocytosis. Pediatr Blood Cancer 54 (3): 449-53, 2010. [PUBMED Abstract]
  9. Nanduri VR, Lillywhite L, Chapman C, et al.: Cognitive outcome of long-term survivors of multisystem langerhans cell histiocytosis: a single-institution, cross-sectional study. J Clin Oncol 21 (15): 2961-7, 2003. [PUBMED Abstract]
  10. Mittheisz E, Seidl R, Prayer D, et al.: Central nervous system-related permanent consequences in patients with Langerhans cell histiocytosis. Pediatr Blood Cancer 48 (1): 50-6, 2007. [PUBMED Abstract]
  11. Bernstrand C, Cederlund K, Henter JI: Pulmonary function testing and pulmonary Langerhans cell histiocytosis. Pediatr Blood Cancer 49 (3): 323-8, 2007. [PUBMED Abstract]
  12. Braier J, Ciocca M, Latella A, et al.: Cholestasis, sclerosing cholangitis, and liver transplantation in Langerhans cell Histiocytosis. Med Pediatr Oncol 38 (3): 178-82, 2002. [PUBMED Abstract]
  13. Guimarães LF, Dias PF, Janini ME, et al.: Langerhans cell histiocytosis: impact on the permanent dentition after an 8-year follow-up. J Dent Child (Chic) 75 (1): 64-8, 2008 Jan-Apr. [PUBMED Abstract]
  14. Egeler RM, Neglia JP, Puccetti DM, et al.: Association of Langerhans cell histiocytosis with malignant neoplasms. Cancer 71 (3): 865-73, 1993. [PUBMED Abstract]
  15. Egeler RM, Neglia JP, Aricò M, et al.: The relation of Langerhans cell histiocytosis to acute leukemia, lymphomas, and other solid tumors. The LCH-Malignancy Study Group of the Histiocyte Society. Hematol Oncol Clin North Am 12 (2): 369-78, 1998. [PUBMED Abstract]
  16. Castro EC, Blazquez C, Boyd J, et al.: Clinicopathologic features of histiocytic lesions following ALL, with a review of the literature. Pediatr Dev Pathol 13 (3): 225-37, 2010 May-Jun. [PUBMED Abstract]
  17. Feldman AL, Berthold F, Arceci RJ, et al.: Clonal relationship between precursor T-lymphoblastic leukaemia/lymphoma and Langerhans-cell histiocytosis. Lancet Oncol 6 (6): 435-7, 2005. [PUBMED Abstract]
  18. Rodig SJ, Payne EG, Degar BA, et al.: Aggressive Langerhans cell histiocytosis following T-ALL: clonally related neoplasms with persistent expression of constitutively active NOTCH1. Am J Hematol 83 (2): 116-21, 2008. [PUBMED Abstract]

Adult LCH

The natural history of disease in adult Langerhans cell histiocytosis (LCH), with the exception of pulmonary LCH, is unknown. It is unclear whether there are significant differences from childhood LCH, although it appears that multisystem high-risk LCH is less aggressive than childhood high-risk disease. The risk of reactivations is unknown, but may be higher than in pediatric LCH patients. A reactivation rate of 62.5% has been reported in adults, compared with 36.8% in pediatric patients.[1]. Sixty-four percent of adults with diabetes insipidus monitored for an average of 6 years developed other endocrine problems.[2,3]
A consensus group reported on the evaluation and treatment of adult patients with LCH.[4] However, discussion continues, particularly regarding optimal first-line therapy.

Incidence

It is estimated that one to two adult cases of LCH occur per 1 million population.[5] The true incidence of this disease is not known, however, because most published studies are not population based, and the disorder is likely to be underdiagnosed. A survey from Germany reported that 66% of the patients with LCH were women, with an average age of 43.5 years for all patients.[6]
More than 90% of adult pulmonary LCH cases occur in young adults who smoke, often more than 20 cigarettes per day.[7,8]

Clinical Presentation

Adult patients may have signs and symptoms of LCH for many months before receiving a definitive diagnosis and treatment. LCH in adults is often similar to that in children and appears to involve the same organs, although the incidence in an organ may be different. There is a predominance of lung disease in adults, usually occurring as single-system disease and closely associated with smoking and some unique biologic characteristics. Most adult isolated lung LCH cases are polyclonal and possibly reactive, while fewer lung LCH cases are monoclonal.[9,10]
A German registry with 121 registrants showed that 62% had single-organ involvement and 38% had multisystem involvement, while 34% of the total had lung involvement. The median age at diagnosis was 44 years ± 12.8 years. The most common organ involved was lung, followed by bone and skin. All organ systems found in childhood LCH were seen, including endocrine and central nervous system, liver, spleen, bone marrow, and gastrointestinal tract. The major difference is the much higher incidence of isolated pulmonary LCH in adults, particularly in young adults who smoke. Other differences appear to be the more frequent involvement of genital and oral mucosa. There may possibly be a difference in the distribution of bone lesions, but both groups suffer reactivations of bone lesions and progression to diabetes insipidus, although the exact incidence in adults is unknown.[5]
Presenting symptoms from published studies are (in order of decreasing frequency) dyspnea or tachypnea, polydipsia and polyuria, bone pain, lymphadenopathy, weight loss, fever, gingival hypertrophy, ataxia, and memory problems. The signs of LCH are skin rash, scalp nodules, soft tissue swelling near bone lesions, lymphadenopathy, gingival hypertrophy, and hepatosplenomegaly. Patients who present with isolated diabetes insipidus should be carefully observed for the onset of other symptoms or signs characteristic of LCH. At least 80% of patients with diabetes insipidus had involvement of other organ systems, including bone (68%), skin (57%), lung (39%), and lymph nodes (18%).[11] However, isolated diabetes insipidus in adults is similar to that in pediatric patients, with progression from posterior to anterior pituitary/hypothalamus and to cerebellar involvement (refer to the Endocrine system subsection in the Childhood LCH section of this summary for more information ).

Skin and oral cavity

Thirty-seven percent of adults with LCH have skin involvement, usually as part of multisystem disease. Skin-only LCH occurs but it is less common in adults than in children. The prognosis for adults with skin-only LCH is excellent, with 100% probability of 5-year survival. The cutaneous involvement is clinically similar to that seen in children and may take many forms.[12] Infra-mammary and vulvar involvement may be seen in adult women with skin LCH.
Many patients have a papular rash with brown, red, or crusted areas ranging from the size of a pinhead to a dime. In the scalp, the rash is similar to that of seborrhea. Skin in the inguinal region, genitalia, or around the anus may have open ulcers that do not heal after antibacterial or antifungal therapy. The lesions are usually asymptomatic but may be pruritic or painful. In the mouth, swollen gums or ulcers along the cheeks, roof of the mouth, or tongue may be signs of LCH.
Diagnosis of LCH is usually made by skin biopsy performed for persistent skin lesions.[12]

Bones

The relative frequency of bone involvement in adults differs from that in children; the frequency of mandible involvement is 30% in adults and 7% in children, and the frequency of skull involvement is 21% in adults and 40% in children.[5,6,11,13] The frequency of vertebrae (13%), pelvis (13%), extremities (17%), and rib (6%) lesions in adults are similar to those found in children.[5]

Lung

Pulmonary LCH in adults is usually single-system disease, but in some patients, other organs may be involved, including bone (18%), skin (13%), and diabetes insipidus (5%).[14]
Pulmonary LCH is more prevalent in smokers than in nonsmokers, and the male-to-female ratio is nearly 1:1, depending on the incidence of smoking in the population studied.[14,15] Patients with pulmonary LCH usually present with a dry cough, dyspnea, or chest pain, although nearly 20% of adults with lung involvement have no symptoms.[16,17] Chest pain may indicate a spontaneous pneumothorax (10%–20% of adult pulmonary LCH cases).
Pulmonary LCH can be diagnosed by bronchoscopy in about 50% of adult patients, as defined by characteristic CD1a immunostaining cells of at least 5% of cells observed.[18] High-resolution lung computed tomography (CT) shows characteristic changes with cysts and nodules, more prevalent at the mid and upper zones. These changes have been characterized as pathognomonic for lung LCH.[16]
The LCH cells in adult lung lesions were shown to be mature dendritic cells expressing high levels of the accessory molecules CD80 and CD86, unlike Langerhans cells (LCs) found in other lung disorders.[17] Pulmonary LCH in adults has been considered a primarily reactive process, rather than a clonal proliferation as seen in childhood LCH.[9] However, ERK pathway mutations have been demonstrated in up to two-thirds of pulmonary LCH lesions in adults, suggesting a clonal process in a significant proportion of patients.[10,19]
The course of pulmonary LCH in adults is variable and unpredictable.[14]
Favorable prognostic factors for adult LCH of the lung include the following:
  • Minimal symptoms. Adults with pulmonary LCH who have minimal symptoms have a good prognosis, although some have steady deterioration over many years.[8]
  • Smoking cessation or treatment. Fifty-nine percent of patients do well with either spontaneous remission with cessation of smoking, or with some form of therapy.[8] However, one study reported that smoking cessation did not increase the longevity of adults with pulmonary LCH, apparently because the tempo of disease is so variable.[20]
  • Lung transplantation. Patients receiving lung transplantation for treatment of pulmonary LCH have a 77% survival rate at 1 year and a 54% survival rate at 10 years, with a 20% chance of LCH recurrence.[21]
Unfavorable prognostic factors for adult LCH of the lung include the following:
  • Altered pulmonary function. Lower forced expiratory volume/forced vital capacity (FEV1/FVC) ratio and higher residual volume/total lung capacity (RV/TLC) ratio are adverse prognostic variables.[20] About 10% to 20% of patients have early severe progression to respiratory failure, severe pulmonary hypertension, and cor pulmonale. Adults who have progression with diffuse bullae formation, multiple pneumothoraces, and fibrosis have a poor prognosis.[22,23]
  • Age. Age older than 26 years is an adverse prognostic variable.[20]
The remaining patients have a variable course, with stable disease in some patients and relapses and progression of respiratory dysfunction in others, some after many years.[24] A natural history study of 58 LCH patients with pulmonary involvement found that 38% of patients had deterioration of lung function after 2 years.[25] The most significant adverse prognostic variables were positive smoking statuses and low PaO2 levels at the time of inclusion.
The following results may be noted on diagnostic tests:
  • Pulmonary function testing. The most frequent pulmonary function abnormality finding in patients with pulmonary LCH is a reduced carbon monoxide diffusing capacity in 70% to 90% of cases.[20,26]
  • CT scan. A high-resolution CT scan, which reveals a reticulonodular pattern classically with cysts and nodules, usually in the upper lobes and sparing the costophrenic angle, is characteristic of LCH. [27] The presence of cystic abnormalities on high-resolution CT scans appears to be a poor predictor of which patients will have progressive disease.[28]
  • Biopsy. Despite the typical CT findings, most pulmonologists agree that a lung biopsy is needed to confirm the diagnosis. A study that correlated lung CT findings and lung biopsy results in 27 patients with pulmonary LCH observed that thin-walled and bizarre cysts had active LCs and eosinophils.[29]

Liver

Liver involvement was reported in 27% of adult patients with LCH and multiorgan disease.[30] Hepatomegaly (48%) and liver enzyme abnormalities (61%) were present. CT and ultrasound imaging abnormalities are often found.
The early histopathologic stage of liver LCH includes infiltration of CD1a-positive cells and periductal fibrosis with inflammatory infiltrates with or without steatosis. The late stage is biliary tree sclerosis; treatment with ursodeoxycholic acid is suggested.[30]

Multisystem disease

In a large series of patients from the Mayo Clinic, 31% had multisystem LCH compared with 69% registered on the Histiocyte Society adult registry; this likely reflects referral bias.[12,31] In the adult multisystem patients, the sites of disease included the following:
  • Skin (50%).
  • Mucocutaneous (40%).
  • Diabetes insipidus (29.6%).
  • Hepatosplenomegaly (16%).
  • Hypothyroidism (6.6%).
  • Lymphadenopathy (6%).
References
  1. Maia RC, de Rezende LM, Robaina M, et al.: Langerhans cell histiocytosis: differences and similarities in long-term outcome of paediatric and adult patients at a single institutional centre. Hematology 20 (2): 83-92, 2015. [PUBMED Abstract]
  2. Malpas JS, Norton AJ: Langerhans cell histiocytosis in the adult. Med Pediatr Oncol 27 (6): 540-6, 1996. [PUBMED Abstract]
  3. Di Iorgi N, Allegri AE, Napoli F, et al.: Central diabetes insipidus in children and young adults: etiological diagnosis and long-term outcome of idiopathic cases. J Clin Endocrinol Metab 99 (4): 1264-72, 2014. [PUBMED Abstract]
  4. Girschikofsky M, Arico M, Castillo D, et al.: Management of adult patients with Langerhans cell histiocytosis: recommendations from an expert panel on behalf of Euro-Histio-Net. Orphanet J Rare Dis 8: 72, 2013. [PUBMED Abstract]
  5. Baumgartner I, von Hochstetter A, Baumert B, et al.: Langerhans'-cell histiocytosis in adults. Med Pediatr Oncol 28 (1): 9-14, 1997. [PUBMED Abstract]
  6. Götz G, Fichter J: Langerhans'-cell histiocytosis in 58 adults. Eur J Med Res 9 (11): 510-4, 2004. [PUBMED Abstract]
  7. Tazi A, Soler P, Hance AJ: Adult pulmonary Langerhans' cell histiocytosis. Thorax 55 (5): 405-16, 2000. [PUBMED Abstract]
  8. Vassallo R, Ryu JH, Colby TV, et al.: Pulmonary Langerhans'-cell histiocytosis. N Engl J Med 342 (26): 1969-78, 2000. [PUBMED Abstract]
  9. Yousem SA, Colby TV, Chen YY, et al.: Pulmonary Langerhans' cell histiocytosis: molecular analysis of clonality. Am J Surg Pathol 25 (5): 630-6, 2001. [PUBMED Abstract]
  10. Roden AC, Hu X, Kip S, et al.: BRAF V600E expression in Langerhans cell histiocytosis: clinical and immunohistochemical study on 25 pulmonary and 54 extrapulmonary cases. Am J Surg Pathol 38 (4): 548-51, 2014. [PUBMED Abstract]
  11. Kaltsas GA, Powles TB, Evanson J, et al.: Hypothalamo-pituitary abnormalities in adult patients with langerhans cell histiocytosis: clinical, endocrinological, and radiological features and response to treatment. J Clin Endocrinol Metab 85 (4): 1370-6, 2000. [PUBMED Abstract]
  12. Aricò M, Girschikofsky M, Généreau T, et al.: Langerhans cell histiocytosis in adults. Report from the International Registry of the Histiocyte Society. Eur J Cancer 39 (16): 2341-8, 2003. [PUBMED Abstract]
  13. Slater JM, Swarm OJ: Eosinophilic granuloma of bone. Med Pediatr Oncol 8 (2): 151-64, 1980. [PUBMED Abstract]
  14. Vassallo R, Ryu JH, Schroeder DR, et al.: Clinical outcomes of pulmonary Langerhans'-cell histiocytosis in adults. N Engl J Med 346 (7): 484-90, 2002. [PUBMED Abstract]
  15. Schönfeld N, Frank W, Wenig S, et al.: Clinical and radiologic features, lung function and therapeutic results in pulmonary histiocytosis X. Respiration 60 (1): 38-44, 1993. [PUBMED Abstract]
  16. Travis WD, Borok Z, Roum JH, et al.: Pulmonary Langerhans cell granulomatosis (histiocytosis X). A clinicopathologic study of 48 cases. Am J Surg Pathol 17 (10): 971-86, 1993. [PUBMED Abstract]
  17. Tazi A, Moreau J, Bergeron A, et al.: Evidence that Langerhans cells in adult pulmonary Langerhans cell histiocytosis are mature dendritic cells: importance of the cytokine microenvironment. J Immunol 163 (6): 3511-5, 1999. [PUBMED Abstract]
  18. Baqir M, Vassallo R, Maldonado F, et al.: Utility of bronchoscopy in pulmonary Langerhans cell histiocytosis. J Bronchology Interv Pulmonol 20 (4): 309-12, 2013. [PUBMED Abstract]
  19. Kamionek M, Ahmadi Moghaddam P, Sakhdari A, et al.: Mutually exclusive extracellular signal-regulated kinase pathway mutations are present in different stages of multi-focal pulmonary Langerhans cell histiocytosis supporting clonal nature of the disease. Histopathology 69 (3): 499-509, 2016. [PUBMED Abstract]
  20. Delobbe A, Durieu J, Duhamel A, et al.: Determinants of survival in pulmonary Langerhans' cell granulomatosis (histiocytosis X). Groupe d'Etude en Pathologie Interstitielle de la Société de Pathologie Thoracique du Nord. Eur Respir J 9 (10): 2002-6, 1996. [PUBMED Abstract]
  21. Dauriat G, Mal H, Thabut G, et al.: Lung transplantation for pulmonary langerhans' cell histiocytosis: a multicenter analysis. Transplantation 81 (5): 746-50, 2006. [PUBMED Abstract]
  22. Chaulagain CP: Pulmonary langerhans' cell histiocytosis. Am J Med 122 (11): e5-6, 2009. [PUBMED Abstract]
  23. Lin MW, Chang YL, Lee YC, et al.: Pulmonary Langerhans cell histiocytosis. Lung 187 (4): 261-2, 2009. [PUBMED Abstract]
  24. Tazi A, Hiltermann J, Vassallo R: Adult lung histiocytosis. In: Weitzman S, Egeler R M, eds.: Histiocytic Disorders of Children and Adults. Cambridge, United Kingdom: Cambridge University Press, 2005, pp 187-207.
  25. Tazi A, de Margerie C, Naccache JM, et al.: The natural history of adult pulmonary Langerhans cell histiocytosis: a prospective multicentre study. Orphanet J Rare Dis 10: 30, 2015. [PUBMED Abstract]
  26. Crausman RS, Jennings CA, Tuder RM, et al.: Pulmonary histiocytosis X: pulmonary function and exercise pathophysiology. Am J Respir Crit Care Med 153 (1): 426-35, 1996. [PUBMED Abstract]
  27. Diette GB, Scatarige JC, Haponik EF, et al.: Do high-resolution CT findings of usual interstitial pneumonitis obviate lung biopsy? Views of pulmonologists. Respiration 72 (2): 134-41, 2005 Mar-Apr. [PUBMED Abstract]
  28. Soler P, Bergeron A, Kambouchner M, et al.: Is high-resolution computed tomography a reliable tool to predict the histopathological activity of pulmonary Langerhans cell histiocytosis? Am J Respir Crit Care Med 162 (1): 264-70, 2000. [PUBMED Abstract]
  29. Kim HJ, Lee KS, Johkoh T, et al.: Pulmonary Langerhans cell histiocytosis in adults: high-resolution CT-pathology comparisons and evolutional changes at CT. Eur Radiol 21 (7): 1406-15, 2011. [PUBMED Abstract]
  30. Abdallah M, Généreau T, Donadieu J, et al.: Langerhans' cell histiocytosis of the liver in adults. Clin Res Hepatol Gastroenterol 35 (6-7): 475-81, 2011. [PUBMED Abstract]
  31. Howarth DM, Gilchrist GS, Mullan BP, et al.: Langerhans cell histiocytosis: diagnosis, natural history, management, and outcome. Cancer 85 (10): 2278-90, 1999. [PUBMED Abstract]

Treatment of Adult LCH

Standard Treatment Options

The lack of clinical trials limits the ability to make evidence-based recommendations for adult patients with Langerhans cell histiocytosis (LCH).
Most investigators have previously recommended treatment according to the guidelines for the treatment of childhood LCH. It is unclear, however, whether adult LCH responds as well as the childhood form of the disease. In addition, the drugs used in the treatment of children are not as well tolerated when used in adults. Excessive neurologic toxicity from vinblastine, for example, prompted closure of the LCH-A1 trial.
A consensus opinion reported on the evaluation and treatment of adult patients with LCH.[1] Discussion continues, particularly with regard to optimal first-line therapy, with some experienced clinicians preferring to start with vinblastine and prednisone and others with alternative therapy, such as single-agent cytosine arabinoside or cladribine.[2][Level of evidence: 3iiiC]

Treatment of pulmonary LCH

It is difficult to judge the effectiveness of various treatments for pulmonary LCH because patients can recover spontaneously or have stable disease without treatment.
Treatment options for adult patients with pulmonary LCH include the following:
  1. Smoking cessation. Smoking cessation is mandatory because of the apparent causal effect of smoking in pulmonary LCH.[3] Most adult patients with LCH have gradual disease progression with continued smoking. The disease may regress or progress with the cessation of smoking.[4] A study of 27 patients with pulmonary LCH observed that 52% of patients improved after a mean follow-up period of 14 months; most patients improved with smoking cessation, and some patients improved with steroid treatment. Four patients (15%) had stable disease at a mean follow-up of 26 months, and nine patients (33%) demonstrated disease progression during the mean follow-up of 22 months.[5]
  2. Steroid therapy. It is not known whether steroid therapy is efficacious in the treatment of adult pulmonary LCH because reported case series did not control for smoking cessation.[3]
  3. Chemotherapy. Some patients have been reported to respond to cladribine therapy.[3,6]
  4. Lung transplantation. Lung transplantation may be necessary for adults with extensive pulmonary destruction from LCH.[7] This multicenter study reported 54% survival at 10 years posttransplant, with 20% of patients having recurrent LCH that did not impact survival; longer follow-up of these patients is needed.[7] Another study confirmed an approximate 50% survival at 10 years and improved hemodynamic changes associated with pulmonary arterial hypertension, but did not alter pulmonary function testing or incidence of pulmonary edema.[8]
The best strategy for follow-up of pulmonary LCH includes physical examination, chest radiographs, lung function tests, and high-resolution computed tomography (CT) scans.[9]

Treatment of bone LCH

Treatment options for adult patients with bone LCH include the following:
  1. Curettage followed by observation, with or without intralesional corticosteroids.As in children, adults with single-bone lesions should undergo curettage of the lesion followed by observation, with or without intralesional corticosteroids. Extensive or radical surgery leading to loss of function and disfigurement is contraindicated at any site, including the teeth or jaw bones.
  2. Systemic chemotherapy. Systemic chemotherapy will cause bone lesions to regress. A variety of chemotherapy regimens, including cladribine, have been published in the treatment of a relatively limited number of patients. (Refer to the Chemotherapy for the treatment of other single-system disease and multisystem disease section of this summary for more information.)
  3. Low-dose radiation therapy. For those failing chemotherapy, low-dose radiation therapy may be indicated and should be tried before any radical surgery that leads to extensive loss of function and disfigurement. Radiation therapy is also indicated for impending neurological deficits from vertebral body lesions or visual problems from orbital lesions. Two series have reported the following:
    • A German cooperative radiation therapy group reported on a series of 98 adult patients with LCH, most of whom (60 of 98) had only bone lesions, and 24 had multisystem disease including bone, treated with radiation therapy.[10][Level of evidence: 3iiiDiv] Of 89 evaluable patients, 77% achieved a complete remission, 9% developed an infield recurrence, and 15.7% (14 of 89) experienced a progression outside the radiation field(s).
    • A retrospective analysis of 80 patients treated with radiation therapy alone reported a 77% complete remission rate and a 12.5% partial remission rate, with 80% long-term control noted in adults. No adverse late effects were reported.[11]
  4. Bisphosphonate therapy. Case reports and case series have described the successful use of bisphosphonates, both intravenous pamidronate and oral zoledronate, in controlling severe bone pain in patients with multiple osteolytic LCH bone lesions.[12-14] A multi-institutional review of bisphosphonate therapy in children and adults with LCH found that most adult patients were given oral zoledronic acid, and most pediatric patients were given pamidronate.[15] Because of the increased toxicity of chemotherapy in adults, bisphosphonate therapy could be used before chemotherapy in multifocal bone disease. Response of other organs, such as skin and soft tissue, to bisphosphonate therapy has been reported.[16]
  5. Anti-inflammatory agents with trofosfamide. Another approach using anti-inflammatory agents (pioglitazone and rofecoxib) coupled with trofosfamide in a specific timed sequence was successful in two patients who had disease resistant to standard chemotherapy treatment.[17]

Treatment of single-system skin disease

Treatment options for adult patients with single-system skin disease include the following:
  1. Surgical excision. Localized lesions can be treated by surgical excision, but as with bone, mutilating surgery, including hemivulvectomy, should be avoided unless the disease is refractory to all available therapy.
  2. Topical therapy. Topical therapies are described in greater detail in the childhood isolated skin involvement section of this summary and include the following:
    • Topical or intralesional corticosteroid.
    • Topical tacrolimus.
    • Topical imiquimod.[18,19]
    • Psoralen and long-wave ultraviolet A radiation (PUVA) and UVB. Therapies such as PUVA/UVB may be more useful in adults because long-term toxicity may be reduced.[20,21]
  3. Systemic therapy. Systemic therapy for severe skin LCH includes oral methotrexate, hydroxyurea, oral thalidomide, oral interferon-alpha, or combinations of interferon and thalidomide.[22-24] Interferon and thalidomide are also used to treat chronic adult skin LCH.[25] Recurrences may occur after treatment is stopped but may respond to re-treatment.
    Oral isotretinoin has induced remission in some refractory cases of skin LCH in adults.[26]
Chemotherapy is generally used for skin LCH associated with multisystem disease in adults.

Chemotherapy for the treatment of other single-system disease and multisystem disease

Evidence (chemotherapy for the treatment of other single-system disease [not mentioned above] and multisystem disease):
  1. A single-center, retrospective review of 58 adult patients with LCH reported on the efficacy and toxicities of treatment with vinblastine/prednisone, cladribine, and cytarabine.[27]
    • Patients treated with vinblastine/prednisone had the worst outcome, with 84% not responding within 6 weeks or relapsing within a year.
    • The no-response/relapse rate was 59% for cladribine and 21% for cytarabine.
    • Grade 3 or 4 neurologic toxic effects occurred in 75% of patients treated with vinblastine.
    • Grade 3 or 4 neutropenia occurred in 37% of patients treated with cladribine and in 20% of patients receiving cytarabine.
  2. A report on the treatment of adult patients with either vindesine and prednisone or cyclophosphamide, etoposide, vindesine, and prednisone showed that more than 70% of patients relapsed with either regimen.[28][Level of evidence: 3iiiDiii]
  3. Etoposide has been used with some success in single-system and multisystem LCH.
    • Minimal toxicity was reported with the use of prolonged oral etoposide in adults with skin LCH, while 3-day courses of intravenous etoposide (100 mg/m2/day) induced complete remission in a small number of patients with resistant single-system and multisystem disease.[29]
    • Another study at the same center found that azathioprine was the most successful drug for localized disease in adults, with the addition of etoposide for refractory and multisystem disease.[30]
  4. For patients who do not respond to front-line therapy with etoposide, cladribine is effective for adults with skin, bone, lymph node, and probably pulmonary and central nervous system (CNS) disease.[31,32]
    • The first study that used cladribine to treat refractory and recurrent skin LCH disease reported on three patients (aged 33, 51, and 57 years) who received two to four courses of cladribine at 0.7 mg/kg intravenously over 2 hours/day for 5 days.[31]
    • In a series of five adults (one untreated and four with refractory LCH treated with cladribine at the same dose noted directly above), three patients achieved a complete remission and two patients achieved a partial remission.[32]
  5. An adult lymphoma treatment regimen of methotrexate, doxorubicin, cyclophosphamide, vincristine, prednisone and bleomycin (MACOP-B) was used in three patients with multisystem LCH and four with single-system multifocal bone LCH from 1995 to 2007. Total duration of therapy was 12 weeks.[33]
    • Response was seen in all patients, two with partial response and five with complete response.
    • Three recurrences were seen after therapy was stopped.
    • Despite the small number of patients and the retrospective nature of the study, MACOP-B may be useful as salvage therapy in adult patients with LCH and deserves further study.[34]
  6. Neurodegenerative CNS disease. A case report suggests some benefit to treating neurodegenerative CNS LCH disease with infliximab, a tumor necrosis factor (TNF)-alpha inhibitor.[35] However, the TNF inhibitors infliximab and etanercept have limited ability to cross the blood-brain barrier. Thalidomide, which also has anti-TNF activity, has been effective in adults with skin and bone LCH.[22,36] One study reported an improvement in ataxia in a patient with LCH who was treated with vemurafenib.[37]
  7. Pituitary LCH. A report of stereotactic radiosurgery for the treatment of pituitary LCH in adults showed efficacy in reducing the masses.[38] However, radiation therapy is not considered the standard of care for children with pituitary involvement. Systemic chemotherapy with cytarabine and cladribine have been the preferred treatments.[39,40]

Targeted therapies for the treatment of single-system and multisystem disease

Early reports on the use of targeted therapies for LCH patients with low-risk or high-risk LCH sites include the following:
  1. Tyrosine kinase inhibitors. Imatinib mesylate was effective in the treatment of four adult patients with LCH who had skin, lung, bone, and/or CNS involvement.[41,42] Another adult patient with LCH did not respond to imatinib mesylate.[43]
  2. MAP2K/ERK pathway inhibitors. The finding that most patients with LCH have BRAFand other RAS pathway mutations led to several reports of good responses to vemurafenib, a BRAF V600E inhibitor, in adult patients with LCH, Erdheim-Chester (ECD) disease, or mixed ECD/LCH, as well as in severe cutaneous LCH.[44,45]
    Of four patients with LCH who were treated with vemurafenib on the VE-BASKET (NCT01524978) trial, one patient had a complete response and three patients had partial responses.[37] Early results of targeted inhibitor therapy are encouraging, but many questions remain, particularly the optimal duration of therapy and the reactivation rate after therapy is discontinued. A BRAF inhibitor in combination with a MEK inhibitor have been shown to be effective in patients with melanoma who have BRAF mutations (with reduced toxicity), and this combination may be effective in patients with LCH.[44] A number of clinical trials of BRAF and other RAS pathway inhibitors in adults and children with LCH are ongoing.

Current Clinical Trials

Use our advanced clinical trial search to find NCI-supported cancer clinical trials that are now enrolling patients. The search can be narrowed by location of the trial, type of treatment, name of the drug, and other criteria. General information about clinical trials is also available.
References
  1. Girschikofsky M, Arico M, Castillo D, et al.: Management of adult patients with Langerhans cell histiocytosis: recommendations from an expert panel on behalf of Euro-Histio-Net. Orphanet J Rare Dis 8: 72, 2013. [PUBMED Abstract]
  2. Grobost V, Khouatra C, Lazor R, et al.: Effectiveness of cladribine therapy in patients with pulmonary Langerhans cell histiocytosis. Orphanet J Rare Dis 9: 191, 2014. [PUBMED Abstract]
  3. Tazi A: Adult pulmonary Langerhans' cell histiocytosis. Eur Respir J 27 (6): 1272-85, 2006. [PUBMED Abstract]
  4. Mogulkoc N, Veral A, Bishop PW, et al.: Pulmonary Langerhans' cell histiocytosis: radiologic resolution following smoking cessation. Chest 115 (5): 1452-5, 1999. [PUBMED Abstract]
  5. Kim HJ, Lee KS, Johkoh T, et al.: Pulmonary Langerhans cell histiocytosis in adults: high-resolution CT-pathology comparisons and evolutional changes at CT. Eur Radiol 21 (7): 1406-15, 2011. [PUBMED Abstract]
  6. Lorillon G, Tazi A: How I manage pulmonary Langerhans cell histiocytosis. Eur Respir Rev 26 (145): , 2017. [PUBMED Abstract]
  7. Dauriat G, Mal H, Thabut G, et al.: Lung transplantation for pulmonary langerhans' cell histiocytosis: a multicenter analysis. Transplantation 81 (5): 746-50, 2006. [PUBMED Abstract]
  8. Le Pavec J, Lorillon G, Jaïs X, et al.: Pulmonary Langerhans cell histiocytosis-associated pulmonary hypertension: clinical characteristics and impact of pulmonary arterial hypertension therapies. Chest 142 (5): 1150-1157, 2012. [PUBMED Abstract]
  9. Abbritti M, Mazzei MA, Bargagli E, et al.: Utility of spiral CAT scan in the follow-up of patients with pulmonary Langerhans cell histiocytosis. Eur J Radiol 81 (8): 1907-12, 2012. [PUBMED Abstract]
  10. Olschewski T, Seegenschmiedt MH: Radiotherapy of Langerhans' Cell Histiocytosis : Results and Implications of a National Patterns-of-Care Study. Strahlenther Onkol 182 (11): 629-34, 2006. [PUBMED Abstract]
  11. Kriz J, Eich HT, Bruns F, et al.: Radiotherapy in langerhans cell histiocytosis - a rare indication in a rare disease. Radiat Oncol 8: 233, 2013. [PUBMED Abstract]
  12. Arzoo K, Sadeghi S, Pullarkat V: Pamidronate for bone pain from osteolytic lesions in Langerhans'-cell histiocytosis. N Engl J Med 345 (3): 225, 2001. [PUBMED Abstract]
  13. Farran RP, Zaretski E, Egeler RM: Treatment of Langerhans cell histiocytosis with pamidronate. J Pediatr Hematol Oncol 23 (1): 54-6, 2001. [PUBMED Abstract]
  14. Brown RE: Bisphosphonates as antialveolar macrophage therapy in pulmonary langerhans cell histiocytosis? Med Pediatr Oncol 36 (6): 641-3, 2001. [PUBMED Abstract]
  15. Chellapandian D, Makras P, Kaltsas G, et al.: Bisphosphonates in Langerhans Cell Histiocytosis: An International Retrospective Case Series. Mediterr J Hematol Infect Dis 8 (1): e2016033, 2016. [PUBMED Abstract]
  16. Morimoto A, Shioda Y, Imamura T, et al.: Nationwide survey of bisphosphonate therapy for children with reactivated Langerhans cell histiocytosis in Japan. Pediatr Blood Cancer 56 (1): 110-5, 2011. [PUBMED Abstract]
  17. Reichle A, Vogt T, Kunz-Schughart L, et al.: Anti-inflammatory and angiostatic therapy in chemorefractory multisystem Langerhans' cell histiocytosis of adults. Br J Haematol 128 (5): 730-2, 2005. [PUBMED Abstract]
  18. O'Kane D, Jenkinson H, Carson J: Langerhans cell histiocytosis associated with breast carcinoma successfully treated with topical imiquimod. Clin Exp Dermatol 34 (8): e829-32, 2009. [PUBMED Abstract]
  19. Taverna JA, Stefanato CM, Wax FD, et al.: Adult cutaneous Langerhans cell histiocytosis responsive to topical imiquimod. J Am Acad Dermatol 54 (5): 911-3, 2006. [PUBMED Abstract]
  20. Rieker J, Hengge U, Ruzicka T, et al.: [Multifocal facial eosinophilic granuloma: successful treatment with topical tacrolimus]. Hautarzt 57 (4): 324-6, 2006. [PUBMED Abstract]
  21. Vogel CA, Aughenbaugh W, Sharata H: Excimer laser as adjuvant therapy for adult cutaneous Langerhans cell histiocytosis. Arch Dermatol 144 (10): 1287-90, 2008. [PUBMED Abstract]
  22. McClain KL, Kozinetz CA: A phase II trial using thalidomide for Langerhans cell histiocytosis. Pediatr Blood Cancer 48 (1): 44-9, 2007. [PUBMED Abstract]
  23. Steen AE, Steen KH, Bauer R, et al.: Successful treatment of cutaneous Langerhans cell histiocytosis with low-dose methotrexate. Br J Dermatol 145 (1): 137-40, 2001. [PUBMED Abstract]
  24. Zinn DJ, Grimes AB, Lin H, et al.: Hydroxyurea: a new old therapy for Langerhans cell histiocytosis. Blood 128 (20): 2462-2465, 2016. [PUBMED Abstract]
  25. Chang SE, Koh GJ, Choi JH, et al.: Widespread skin-limited adult Langerhans cell histiocytosis: long-term follow-up with good response to interferon alpha. Clin Exp Dermatol 27 (2): 135-7, 2002. [PUBMED Abstract]
  26. Tsambaos D, Georgiou S, Kapranos N, et al.: Langerhans' cell histiocytosis: complete remission after oral isotretinoin therapy. Acta Derm Venereol 75 (1): 62-4, 1995. [PUBMED Abstract]
  27. Cantu MA, Lupo PJ, Bilgi M, et al.: Optimal therapy for adults with Langerhans cell histiocytosis bone lesions. PLoS One 7 (8): e43257, 2012. [PUBMED Abstract]
  28. Duan MH, Han X, Li J, et al.: Comparison of vindesine and prednisone and cyclophosphamide, etoposide, vindesine, and prednisone as first-line treatment for adult Langerhans cell histiocytosis: A single-center retrospective study. Leuk Res 42: 43-6, 2016. [PUBMED Abstract]
  29. Tsele E, Thomas DM, Chu AC: Treatment of adult Langerhans cell histiocytosis with etoposide. J Am Acad Dermatol 27 (1): 61-4, 1992. [PUBMED Abstract]
  30. Chu T: Langerhans cell histiocytosis. Australas J Dermatol 42 (4): 237-42, 2001. [PUBMED Abstract]
  31. Saven A, Foon KA, Piro LD: 2-Chlorodeoxyadenosine-induced complete remissions in Langerhans-cell histiocytosis. Ann Intern Med 121 (6): 430-2, 1994. [PUBMED Abstract]
  32. Pardanani A, Phyliky RL, Li CY, et al.: 2-Chlorodeoxyadenosine therapy for disseminated Langerhans cell histiocytosis. Mayo Clin Proc 78 (3): 301-6, 2003. [PUBMED Abstract]
  33. Derenzini E, Fina MP, Stefoni V, et al.: MACOP-B regimen in the treatment of adult Langerhans cell histiocytosis: experience on seven patients. Ann Oncol 21 (6): 1173-8, 2010. [PUBMED Abstract]
  34. Gadner H: Treatment of adult-onset Langerhans cell histiocytosis--is it different from the pediatric approach? Ann Oncol 21 (6): 1141-2, 2010. [PUBMED Abstract]
  35. Chohan G, Barnett Y, Gibson J, et al.: Langerhans cell histiocytosis with refractory central nervous system involvement responsive to infliximab. J Neurol Neurosurg Psychiatry 83 (5): 573-5, 2012. [PUBMED Abstract]
  36. Sander CS, Kaatz M, Elsner P: Successful treatment of cutaneous langerhans cell histiocytosis with thalidomide. Dermatology 208 (2): 149-52, 2004. [PUBMED Abstract]
  37. Diamond EL, Subbiah V, Lockhart AC, et al.: Vemurafenib for BRAF V600-Mutant Erdheim-Chester Disease and Langerhans Cell Histiocytosis: Analysis of Data From the Histology-Independent, Phase 2, Open-label VE-BASKET Study. JAMA Oncol 4 (3): 384-388, 2018. [PUBMED Abstract]
  38. Hong WC, Murovic JA, Gibbs I, et al.: Pituitary stalk Langerhans cell histiocytosis treated with CyberKnife radiosurgery. Clin Neurol Neurosurg 115 (5): 573-7, 2013. [PUBMED Abstract]
  39. Dhall G, Finlay JL, Dunkel IJ, et al.: Analysis of outcome for patients with mass lesions of the central nervous system due to Langerhans cell histiocytosis treated with 2-chlorodeoxyadenosine. Pediatr Blood Cancer 50 (1): 72-9, 2008. [PUBMED Abstract]
  40. Egeler RM, de Kraker J, Voûte PA: Cytosine-arabinoside, vincristine, and prednisolone in the treatment of children with disseminated Langerhans cell histiocytosis with organ dysfunction: experience at a single institution. Med Pediatr Oncol 21 (4): 265-70, 1993. [PUBMED Abstract]
  41. Montella L, Insabato L, Palmieri G: Imatinib mesylate for cerebral Langerhans'-cell histiocytosis. N Engl J Med 351 (10): 1034-5, 2004. [PUBMED Abstract]
  42. Janku F, Amin HM, Yang D, et al.: Response of histiocytoses to imatinib mesylate: fire to ashes. J Clin Oncol 28 (31): e633-6, 2010. [PUBMED Abstract]
  43. Wagner C, Mohme H, Krömer-Olbrisch T, et al.: Langerhans cell histiocytosis: treatment failure with imatinib. Arch Dermatol 145 (8): 949-50, 2009. [PUBMED Abstract]
  44. Haroche J, Cohen-Aubart F, Emile JF, et al.: Dramatic efficacy of vemurafenib in both multisystemic and refractory Erdheim-Chester disease and Langerhans cell histiocytosis harboring the BRAF V600E mutation. Blood 121 (9): 1495-500, 2013. [PUBMED Abstract]
  45. Charles J, Beani JC, Fiandrino G, et al.: Major response to vemurafenib in patient with severe cutaneous Langerhans cell histiocytosis harboring BRAF V600E mutation. J Am Acad Dermatol 71 (3): e97-9, 2014. [PUBMED Abstract]

Changes to This Summary (04/12/2019)

The PDQ cancer information summaries are reviewed regularly and updated as new information becomes available. This section describes the latest changes made to this summary as of the date above.
Added Allen et al. as reference 3.
Added text to state that in a long-term study of adult patients with Erdheim-Chester disease and LCH who received vemurafenib, 85% of patients had arthralgias; 62% of patients had maculopapular rashes; and more than 40% of patients had other skin issues, including hyperkeratosis, seborrheic keratosis, and pruritus (cited Diamond et al. as reference 41).
Added text about circulating BRAF V600E–mutated cells that have been found in patients with LCH (cited McClain et al. as reference 42).
Added text about the results of a study that evaluated possible biomarkers for central nervous system LCH and examined 121 unique proteins in the cerebrospinal fluid of 40 pediatric patients with LCH.
Added Sakamoto et al. as reference 51.
Added text about a report from 2018 that analyzed brain tissue from patients with neurodegenerative-disease LCH, which showed perivascular infiltration of CD207-negative cells staining with the BRAF V600E mutant protein in the pons, cerebellum, and basal ganglia (cited McClain et al. as reference 59).
Added text to state that a comparison of results from two Japanese trials revealed no improvement in progression-free survival when additional prednisone and a prolonged maintenance phase were added (cited Morimoto et al. as reference 27).
Added text to state that three patients with neurodegenerative-disease LCH who had progressive disease 1 to 3 years after cytotoxic chemotherapy were treated with either vemurafenib or dabrafenib and had complete or partial clinical and radiologic responses. Another patient who had neurodegenerative-disease LCH for more than 10 years developed progressive disease, but had limited exposure to these agents because of excessive cutaneous and joint toxicities (cited McClain et al. as reference 48).
Revised text to state that systemic therapy for severe skin LCH includes oral methotrexate, hydroxyurea, oral thalidomide, oral interferon-alpha, or combinations of interferon and thalidomide (cited Zinn et al. as reference 24).
Added text to state that one study reported an improvement in ataxia in a patient with LCH who was treated with vemurafenib (cited Diamond et al. as reference 37).
Added text to state that of four patients with LCH who were treated with vemurafenib on the VE-BASKET trial, one patient had a complete response and three patients had partial responses. Also added text to state that a BRAF inhibitor in combination with a MEK inhibitor have been shown to be effective in patients with melanoma who have BRAFmutations, and this combination may be effective in patients with LCH.
This summary is written and maintained by the PDQ Pediatric Treatment Editorial Board, which is editorially independent of NCI. The summary reflects an independent review of the literature and does not represent a policy statement of NCI or NIH. More information about summary policies and the role of the PDQ Editorial Boards in maintaining the PDQ summaries can be found on the About This PDQ Summary and PDQ® - NCI's Comprehensive Cancer Database pages.

About This PDQ Summary

Purpose of This Summary

This PDQ cancer information summary for health professionals provides comprehensive, peer-reviewed, evidence-based information about the treatment of childhood and adult Langerhans cell histiocytosis. It is intended as a resource to inform and assist clinicians who care for cancer patients. It does not provide formal guidelines or recommendations for making health care decisions.

Reviewers and Updates

This summary is reviewed regularly and updated as necessary by the PDQ Pediatric Treatment Editorial Board, which is editorially independent of the National Cancer Institute (NCI). The summary reflects an independent review of the literature and does not represent a policy statement of NCI or the National Institutes of Health (NIH).
Board members review recently published articles each month to determine whether an article should:
  • be discussed at a meeting,
  • be cited with text, or
  • replace or update an existing article that is already cited.
Changes to the summaries are made through a consensus process in which Board members evaluate the strength of the evidence in the published articles and determine how the article should be included in the summary.
The lead reviewers for Langerhans Cell Histiocytosis Treatment are:
  • Louis S. Constine, MD (James P. Wilmot Cancer Center at University of Rochester Medical Center)
  • Thomas G. Gross, MD, PhD (National Cancer Institute)
  • Kenneth L. McClain, MD, PhD (Texas Children's Cancer Center and Hematology Service at Texas Children's Hospital)
  • Carlos Rodriguez-Galindo, MD (St. Jude Children's Research Hospital)
Any comments or questions about the summary content should be submitted to Cancer.gov through the NCI website's Email Us. Do not contact the individual Board Members with questions or comments about the summaries. Board members will not respond to individual inquiries.

Levels of Evidence

Some of the reference citations in this summary are accompanied by a level-of-evidence designation. These designations are intended to help readers assess the strength of the evidence supporting the use of specific interventions or approaches. The PDQ Pediatric Treatment Editorial Board uses a formal evidence ranking system in developing its level-of-evidence designations.

Permission to Use This Summary

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The preferred citation for this PDQ summary is:
PDQ® Pediatric Treatment Editorial Board. PDQ Langerhans Cell Histiocytosis Treatment. Bethesda, MD: National Cancer Institute. Updated <MM/DD/YYYY>. Available at: https://www.cancer.gov/types/langerhans/hp/langerhans-treatment-pdq. Accessed <MM/DD/YYYY>. [PMID: 26389240]
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  • Updated: April 12, 2019

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