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. 2022 Jun 21;22:302. doi: 10.1186/s12876-022-02378-8

Pancreatic involvement in Erdheim-Chester disease: a case report and review of the literature

Jia-wen Dai 2, Tian-hua He 2, Ming-hui Duan 2, Yue Li 3, Xin-xin Cao 1,2,
PMCID: PMC9210604  PMID: 35729495

Abstract

Background

Erdheim-Chester disease (ECD) is a rare form of non-Langerhans cell histiocytosis characterized by infiltration of lipid-laden foamy macrophages within different tissues. Clinical manifestations of ECD are highly heterogeneous. Bone lesions are found in 80%-95% of patients, while extraosseous lesions usually involve the cardiovascular system, retroperitoneum, central nervous system (CNS), and skin. Pancreatic involvement in ECD has barely been reported.

Case presentation

A 29-year-old female initially presented with menoxenia, diabetes insipidus and diabetes mellitus. 18F-fluorodeoxyglucose positron emission tomography-computed tomography (18F-FDG-PET/CT) revealed hypermetabolic foci in the bilateral frontal lobe, saddle area, and pancreas. A 99mTc-MDP bone scrintigraphy scan revealed symmetrical increased uptake in distal femoral and proximal tibial metaphysis, which was confirmed to be osteosclerosis by high-resolution peripheral quantitative computed tomography. The patient underwent incomplete resection of the sellar mass. Histological examination of biopsies showed histiocytic aggregates, which were positive for S100 and negative for CD1a and CD207 on immunohistochemistry. Enhanced abdominal CT scan showed hypointense nodules within the body and tail of the pancreas. Endoscopic ultrasonography guided fine-needle aspiration (EUS-FNA) found no evidence of malignancy. She was diagnosed with ECD and treated with high-dose IFN-α. Repeated examinations at three-and eight-months post treatment revealed markedly reduction of both intracranial and pancreatic lesions.

Conclusions

ECD is a rare histiocytic neoplasm that can involve almost every organ, whereas pancreatic involvement has barely been reported to date. Here, we present the rare case of pancreatic lesions in ECD that responded well to interferon-α. We further reviewed reports of pancreatic involvement in histiocytic disorders and concluded the characteristics of such lesions to help diagnosis and treatment, in which these lesions mimicked pancreatic adenocarcinoma and caused unnecessary invasive surgeries.

Keywords: Pancreas, Histiocytosis, Erdheim-Chester disease, Treatment, Interferon, Case report

Background

Erdheim-Chester disease (ECD) is an inflammatory myeloproliferative neoplasm characterized by infiltration of tissues by foamy CD68+CD1a histiocytes [1]. Theoretically, ECD can affect every tissue and organ, while so far pancreatic involvement has been reported only in one case. The main sites of involvement in ECD patients include bone (95%), lung (91%) [2], cardiovascular region (50%), retroperitoneum (40–50%), central nervous system (40%), and skin (25%) [3]. Iconic radiographic signs of ECD include the ‘hairy kidney’, sheath around the aorta, long-bone sclerosis, and right atrial pseudo tumors. Clinical manifestations can be of great heterogeneity. Any of the clinical signs, such as bone pain, diabetes insipidus, xanthelasma, exophthalmos, ataxia, or sinusitis, may herald the disease [4]. The mean time from symptom onset to diagnosis was 2.7 years [5]. Mutations activating the MAPK pathway are found in more than 80% of patients with ECD, mainly the BRAFV600E mutation in 57% to 70% of cases, followed by MAP2K1 in close to 30% [1, 69]. Untreated multisystemic ECD can be severe and fatal. Patients with life-threatening cardiac or neurologic involvement with or without BRAF-V600-mutation should receive MEK inhibitors. For BRAF-wild-type patients without end-organ dysfunction, IFN-α is still the first line therapy, especially in developing countries. A retrospective cohort study reported a response rate of 80%, and 3-year progression-free survival and overall survival of 64.1 and 84.5%, respectively [10] . BRAF and MEK inhibitors have shown robust efficacy in BRAFV600E patients, yet most patients relapsed after BRAF inhibitor interruption [11]. ECD involving the pancreas has barely been reported. Our case highlights a rare location, the pancreas, for a rare disorder, Erdheim-Chester disease. We also reviewed reported cases of pancreatic involvement in relatively common histiocytic disorders for better diagnosis and management, including Langerhans cell histiocytosis (LCH), Juvenile xanthogranuloma (JXG), and Rosai-Dorfman disease (RDD).

Case presentation

A 29-year-old female presented to our hospital with a complaint of menoxenia for 5 years and polyuria, polydipsia, hyperglycemia and lethargy for 1 year, with no previous medical, family, and psycho-social history. She was diagnosed with menoxenia in 2013 and treated with hormone replacement therapy. In 2017, when she gradually developed symptoms of diabetes insipidus and lethargy, a brain MRI was arranged which showed a mass in sellar area. Incomplete resection was performed, and histological examination of the mass showed histiocytic aggregates, which were CD1a-negative, Langerin-negative, and S100-positive on immunohistochemistry. (Fig. 1a, b. Microscope: OLYMPUS BX53; acquisition software: pylon Viewer; measured resolution: 1390*1038px; scale bar: 50 µM). DNA extracted from the patient’s biopsy sample was obtained and subjected to NGS of 183 genes, including BRAF, MAP2K1, PIK3CA, NRAS, KRAS, ARAF, ALK [9], yet no BRAFV600E and other meaningful mutations downstream the MAPK or in related pathways was found.

Fig. 1.

Fig. 1

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Imaging and pathological data at the time of diagnosis. a Histological examination of the sellar mass showed histiocytic aggregates(× 200, scale bar: 50 µM), which were CD1a-negative, Langerin-negative, and b S100-positive on immunohistochemistry (× 200, scale bar: 50 µM). c Enhanced brain MRI showed multiple lesions affecting sellar, suprasellar area, pons, and part of hypothalamus. d 99mTc-MDP bone scrintigraphy scan showed symmetrical increased uptake in the frontal bone and distal femoral and proximal tibial metaphysis. e HR-pQCT confirmed osteosclerosis by revealing increased trabecular volumetric bone mineral density and localized structural alteration of trabeculae network in tibia. f PET/CT revealed hypermetabolic foci in the bilateral frontal lobe, saddle area, and pancreas. g Enhanced abdominal CT scan showed nodules of hypointense lesions within the body and tail of the slightly enlarged pancreas. h EUS-FNA of pancreas found no evidence of malignancy but only normal pancreatic ductal cells (× 400, scale bar: 25 µM)

2 years later, the patient was admitted to our hospital due to progression of the intracranial mass. We performed further examinations to confirm the diagnosis. On physical examination, no remarkable abnormity was found. Blood test and tumor markers were normal. Liver enzymes were abnormal with a mild to moderate elevation of alkaline phosphatase (178 U/L) and γ-Glutamyltransferase (72 IU/L). C-reactive protein, erythrocyte sedimentation rate, and Tumor necrosis factor-α elevated slightly. Enhanced MRI of the brain showed multiple lesions affecting sella, suprasellar area, pons, and part of hypothalamus (Fig. 1c). The patient’s 99mTc-MDP bone scrintigraphy scan revealed symmetrical increased uptake in the frontal bone and distal femoral and proximal tibial metaphysis (Fig. 1d). Further investigation with high-resolution peripheral quantitative computed tomography (HR-pQCT) confirmed long-bone osteosclerosis by revealing increased trabecular volumetric bone mineral density and localized structural alteration of trabeculae network in tibia (Fig. 1e) [12]. FDG-PET/CT revealed hypermetabolic foci in the bilateral frontal lobe, nasal septum, sella, gallbladder, and the body and tail of the pancreas (Fig. 1f). Further examination on the pancreas with enhanced CT scan showed nodules of hypointense lesions within the body and tail of the slightly enlarged pancreas. During the arterial phase and portal phase, such lesions showed reduced enhancement (Fig. 1g). No dilation of pancreatic duct was identified. Endoscopic ultrasound found multiple hypoechoic, obscure circumstanced lesions with a diameter of about two centimeters. EUS-FNA of pancreas found no evidence of malignancy but only normal pancreatic ductal cells (Fig. 1h. Microscope: OLYMPUS BX53; acquisition software: pylon Viewer; measured resolution: 1920*1200px; scale bar: 25 µM).

Based on typical meta-diaphyseal osteosclerosis and pathological findings of histiocytes aggregates, the patient was diagnosed with ECD, involving the brain, bones and the pancreas. She was treated with IFN-α at 900 million international units, three times a week. Hormone replacement therapy included euthyrox and minirin. Metformin was also applied to control blood glucose. She tolerated the treatment well with no unanticipated events. Repeated MRI of the brain at three- and eight-months post treatment showed alleviation of all intracranial lesions (Fig. 2b, c). Repeated abdominal CT scans revealed markedly reduction of size of the pancreatic lesions, and their enhancement features were closer to normal pancreatic tissue (Fig. 2e, f). The patient still relied on hormone replacement therapy but her lethargy largely resolved, and her blood glucose level was easier to control.

Fig. 2.

Fig. 2

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Imaging changes of the brain and pancreas during treatment. Enhanced brain MRI scans at a pre-treatment, b three months, and c eight months post treatment. Enhanced abdominal CT scans of pancreas at d pre-treatment, e three months, and f eight months post treatment

Discussion and conclusion

In this case, though EUS-FNA of pancreas found no evidence of infiltration of histiocytes, those nodular, obscure circumstanced, hypermetabolic lesions, with rather a rapid response to IFN treatment, were suggested as ECD involvements. We should consider pancreatic tumor, chronic pancreatitis, and autoimmune pancreatitis in those space-occupying lesions, of which we are most concerned about pancreatic tumor. However, the lesions were not accompanied by indirect signs of malignancy such as ductal dilation and vascular invasion, tumor markers are normal, and no tumor cells were found by pathological biopsy, thus we excluded this diagnosis.

The histiocytoses are rare disorders characterized by the accumulation of macrophage, dendritic cell, or monocyte-derived cells in various tissues and organs. Histiocytic disorders were traditionally divided into Langerhans cell histiocytosis (LCH) and non-Langerhans cell histiocytosis, among which Erdheim-Chester disease (ECD), Juvenile xanthogranuloma (JXG), and Rosai–Dorfman disease (RDD) were the most common types. Since pancreatic involvement is rare in histiocytoses, we know little about the characteristics of such lesions. Thus, we searched case reports of histiocytoses involving pancreas in the English literature in the PubMed database. Thus far, only one pancreatic ECD has been reported, while 5 cases of LCH (Table 1), 19 cases of JXG (Table 2), and 11 cases of RDD (Table 3) have been reported. In the following tables, we summarized the key information of these cases.

Table 1.

Summary of 5 cases with ECD and LCH involving the Pancreas

No. References Sex/age Symptoms Site Treatment Outcome Other organs involved
1. Poehling et al. [13] F/57y Cramping Autopsy Prednisone Death Bone, kidney
2.Hara et al. [16] M/10y Fever, jaundice Diffuse swelling Chemo (EP) Death Lung, liver, spleen, BM, kidney
3.Yu et al. [17] M/8mo Belly pain, distension, diarrhea Autopsy Chemo (VP,C) Death Skin, liver, spleen, BM, lung, GI
4.Muwakkit et al. [18] M/4w Frequent stools Body (cyst) Chemo (VP) Resolution Skin, lung, spleen
5.Goyal et al. [19] M/18mo Loose stools Autopsy Chemo (VP) Death LN, liver, kidney
6.Hou et al. [20] M/44y / Diffuse swelling Chemo (CAVP) Resolution Lung, liver, LN, bone
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BM bone marrow, GI gastrointestinal tract, LN lymph node, Chemo chemotherapy, E etoposide, V vinblastine, P prednisone/prednisolone, C cyclosporin A, A adriamycin

Table 2.

Summary of 19 cases with JXG involving the Pancreas

No. References Sex/age Symptoms Site Treatment Outcome Other organs involved
1. Dehner [21] M/2mo Jaundice Head Unknown Resolution Lung
2. Heintz et al. [22] F/5mo Jaundice Head Whipple Resolution Liver
3. Prasil et al. [23] NA/9mo Jaundice Head Mass excision Resolution
4. Ueno et al. [24] M/42y Belly pain Body (cyst) Distal pancreatectomy Resolution
5. Iyer et al. [25] M/50y Jaundice Head Whipple Unknown Unknown
6. Iyer et al. [25] M/36y Pancreatitis Tail Mass excision Unknown Unknown
7. Kamitani et al. [26] M/82y Belly pain Body (cyst) Whipple Unknown Stomach
8. Kang 2007 F/22y Belly pain Head PPPD Unknown Unknown
9. Okabayashi et al. [27] M/60y Belly pain Tail Distal pancreatectomy Unknown Unknown
10. Okabayashi et al. 2007 M/69y Belly pain Tail Distal pancreatectomy Unknown Unknown
11. Shima et al. [28] M/66y Belly pain Body Distal pancreatectomy Unknown
12. Iso et al. [29] M/82y Weight loss Head and tail Distal pancreatectomy Resolution Spleen
13. Ikeura et al. [30] M/73y Body (cyst) PPPD Unknown
14. Uguz et al. [31] M/30y Belly pain Head PPPD Unknown Unknown
15. Uguz et al. [31] M/34y Belly pain Head PPPD Unknown Unknown
16. Kim et al. [32] F/72y Weight loss Body (cyst) PPPD Resolution
17. Kim et al. [33] F/70y Belly pain, dyspepsia Uncinate Whipple Resolution
18. Atreyapurapu et al. [34] M/60y Belly pain, vomit Uncinate Whipple Resolution
19. Antary et al. [35] F/13mo Jaundice Head and uncinate Whipple Resolution
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PPPD pylorus preserving pancreatoduodenectomy

Table 3.

Summary of 11 cases with RDD involving the Pancreas

No. References Sex/age Symptoms Site Treatment Outcome Other organs involved
1. Esquivel et al. [36] F/48y Belly pain Body and tail Distal pancreatectomy Unknown Spleen
2. Zivin et al. [37] F/63y Jaundice Body Whipple Resolution Lung
3. Podberezin et al. [38] F/35y Belly pain Tail Mass excision Progression (steroids, chemo, imatinib, excision) Spine, perinephric, perisplenic
4. Romero et al. [39] F/74y Belly pain Head PPPD Unknown
5. Shaikh et al. [40] F/59y Belly pain Body and tail Whipple, steroids Progression (imatinib) Liver
6. Mantilla et al. [41] F/54y Belly pain, weight loss Tail Distal pancreatectomy Resolution
7. Karajgikar et al. [42] F/65y Belly pain Head, body, and tail Consider clofarabine Unknown Presacral soft tissue, skin
8. Smith et al. [43] F/75y Weight loss Body Steroids Resolution
9. Brown et al. [44] F/65y Granulomatous uveitis, skin rash Tail Distal pancreatectomy Resolution Skin
10. Liu et al. [45] F/71y Fullness Tail Distal pancreatectomy Resolution
11. Emily et al. [46] F/40y Belly pain Tail Distal pancreatectomy Resolution Colon
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Pancreatic involvement in ECD was reported in a 57y woman with pancreatic induration, which was confirmed of ECD involvement by biopsy. The patient died of acute respiratory failure of unknown cause 5 months later [13]. All of 5 cases of LCH were high risk, with involvement in the liver, spleen, or bone marrow. All patients received chemotherapy, but the condition was resolved in only 2 patients. The third patient showed an exact size reduction of the pancreatic lesion, similar to what we reported in our case. It is reasonable to believe the pancreas is involved more often in high-risk LCH. The 19th case of JXG was a baby with a lesion in the head of the pancreas and largely elevated cancer antigen 19-9 (1954 U/mL). She underwent Whipple surgery as a diagnostic and therapeutic method and resolved well, with normalization of CA 19-9 within 1 month. Such lesions, especially those with elevated tumor markers, are difficult to differentiate with malignancies. From these cases, we can conclude that the symptoms of the over 30 cases mentioned are quite atypical, ranging from obstructive jaundice to no discomfort. The pancreas can be affected in different forms, with solid or cystic masses in the head/body/tail or diffuse swelling of the whole pancreas. It can be involved in the disease alone or with any possible organ. Due to the similarity in clinical presentation and imaging with pancreatic malignancies, these lesions mostly lead to distal pancreatectomy or even Whipple surgery, with only one patient among all 30 cases of JXG and RDD receiving medical treatment.

However, considering the spontaneous remission trend of JXG and RDD and the good response of these two diseases as well as LCH and ECD to chemotherapy or targeted BRAF inhibitors, we believe that surgery is sometimes overprescribed to a certain extent. Therefore, histiocytoses may be considered as a differential diagnosis for patients presenting with a pancreatic mass.

Recently, two recent publications have explained the cause of the hyperinflammatory state in ECD and other histiocytic diseases. Molteni, R. and his colleagues found that BRAFV600E in macrophages induce hallmark immunometabolic features of trained immunity, causing activation of the AKT/mTOR signaling axis, increased glycolysis, epigenetic changes on promoters of genes encoding cytokines, and enhanced cytokine production leading to hyper-inflammatory responses [14]. Biavasco, R. and his colleagues discovered that the activation of BRAFV600E impairs HSPC function, features myeloid restricted hematopoiesis, and leads to a widespread inflammatory condition [15]. These findings reveal the cause of high inflammatory condition in ECD patient, explain the rationale for pancreatic involvement and the robust response to IFN in our case.

In conclusion, we report the second case of pancreatic ECD with a good response to interferon-α therapy, with a literature review of pancreatic involvement in other histiocytoses, including LCH, JXG, and RDD. These lesions often simulate pancreatic malignancies, causing unnecessary invasive surgery in some cases. Thus we recommend histiocytoses as a differential diagnosis in pancreatic lesions.

Acknowledgements

The authors thank the patients and their families for their trust, respect and support. They also acknowledge all clinicians for their help in accomplishing this work.

Abbreviations

ECD

Erdheim-Chester disease

CNS

Central nervous system

18F-FDG-PET/CT

18F-fluorodeoxyglucose positron emission tomography-computed tomography

HR-pQCT

High-resolution peripheral quantitative computed tomography

EUS-FNA

Endoscopic ultrasonography guided fine-needle aspiration

LCH

Langerhans cell histiocytosis

JXG

Juvenile xanthogranuloma

RDD

Rosai-Dorfman disease

NGS

Next Generation Sequencing

BM

Bone marrow

GI

Gastrointestinal tract

LN

Lymph node

Chemo

Chemotherapy

E

Etoposide

V

Vinblastine

P

Prednisone/prednisolone

C

Cyclosporin A

A

Adriamycin

PPPD

Pylorus preserving pancreatoduodenectomy

Author contributions

XXC and MHD designed the report and approved the final submission; JWD, THH, and YL analyzed relevant information; JWD performed literature review and wrote the manuscript; MHD, YL, and XXC clinically managed the patient. All Authors read and approved the final manuscript.

Funding

Institutional research funding was provided by the Innovation Training Program for College Students of Peking Union Medical College [XE1000000110090]. The funding body played no role in the design of the study and collection, analysis, and interpretation of data and in writing the manuscript.

Availability of data and materials

The data used and analyzed during the current study are included in this article.

Declarations

Ethics approval and consent to participate

Not applicable.

Consent for publication

Written informed consent was obtained from the patient for publication of this case report and any accompanying images. A copy of the written consent is available for review by the editor of this journal.

Competing interests

The authors declare that they have no competing interests.

Footnotes

Publisher's Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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Data Availability Statement

The data used and analyzed during the current study are included in this article.

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