Carcinoid of the ampulla of Vater

Endocrine neoplasms only rarely occur at the ampulla of Vater, comprising mostly carcinoids and malignant carcinoids, as well as few cases of poorly differentiated endocrine carcinomas (small cell carcinomas). Only 105 cases are reported in the literature, most as single case reports. For many years, the neoplasms of the disseminated neuroendocrine cell system of the gastrointestinal tract have been subsumed as 'carcinoids'. Instead, in the latest World Health Organization (WHO) classification published in 2000, it is recommended to distinguish between (i) well-differentiated endocrine tumors (carcinoids); (ii) well-differentiated endocrine carcinomas (malignant carcinoids); and (iii) poorly differentiated endocrine carcinomas (small cell carcinomas). Patients with carcinoid tumors of the ampulla of Vater are very often free of clinical and laboratory findings that belong to the carcinoid syndrome. Approximately 26% of all patients with carcinoid tumor reported in the literature had neurofibromatosis. Besides endoscopic retrograde cholangiopancreatography, endosonography, computed tomography or magnetic resonance imaging may complete the staging approach of this tumor. The Kausch-Whipple procedure or pylorus-preserving pancreaticoduodenectomy is considered the treatment of choice for ampullary, well-differentiated carcinoids >2.0 cm and for ampullary neuroendocrine carcinomas. However, it should be considered that long-term survival of patients with ampullary carcinoids is also reported after local tumor excision (5-year survival rate of 90%). The dilemma is that the differentiation of neuroendocrine tumors cannot be assessed intraoperatively in most cases. Therefore, considering that the 5-year survival rate in patients with neuroendocrine carcinomas of the ampulla of Vater is very low without radical resection, neuroendocrine tumors of the ampulla of Vater without definite histological differentiation should undergo extended surgery.     

Immunohistological localization of growth hormone-releasing hormone in human tumors

Two forms of GH-releasing factor (GHRH), which play a role in the regulation of GH secretion, have been isolated from pancreatic endocrine tumors in two patients with acromegaly. We examined formalin-fixed, paraffin-embedded human tissues from autopsies and surgical specimens for the presence of human pancreatic GHRH-40 using the avidin-biotin-peroxidase complex technique to assess the prevalence of tumors containing GHRH, to define their primary sites and cellular derivations, and to correlate clinical and pathological features. Immunopositivity was demonstrated in 4 of 24 pancreatic endocrine tumors, 1 of 5 bronchial and 2 of 15 gut carcinoids, 1 of 2 thymic carcinoids, 2 of 20 medullary carcinomas of the thyroid, 1 of 12 pheochromocytomas, and 5 of 20 small cell carcinomas of the lung. Of the GHRH-containing tumors, only 2 of the pancreatic endocrine tumors and the bronchial carcinoid were associated with acromegaly. No GHRH was found in 35 tumors derived from cells that are not known to produce peptide hormones. Immunoreactivity was not detected in the nontumorous tissues from which GHRH-containing tumors were derived. It can be concluded that GHRH may be found in a variety of tumors arising from and composed of peptide hormone-producing endocrine cells. The significance of immunoreactive GHRH detected in tumors unassociated with clinical evidence of acromegaly remains to be established.     

Ghrelin-producing endocrine tumors of the stomach and intestine

Ghrelin is a novel gastrointestinal hormone produced by about 20% of the rat and human gastric neuroendocrine cell population, which possesses strong GH-releasing activity, but also plays other central and peripheral roles, including influence on food intake, gastric motility, and acid secretion. The aim of the present study was to determine whether gastrointestinal endocrine hyperplastic and neoplastic lesions produce ghrelin, at both protein (immunohistochemistry) and mRNA (in situ hybridization and/or RT-PCR) levels, and express the GH secretagogue receptor mRNA by RT-PCR. Sixteen gastric and 20 intestinal carcinoids as well as normal gastrointestinal mucosa and atrophic gastritis-associated neuroendocrine cell hyperplasia were studied. The majority (12 of 16, 75%) of gastric carcinoids and only 5 of 18 (27%) of intestinal endocrine tumors were immunoreactive for ghrelin. In situ hybridization confirmed the immunohistochemical data, but also showed ghrelin mRNA in 1 gastric and 8 intestinal additional tumors. RT-PCR showed ghrelin mRNA in 14 of 14 cases, indicating a low level of ghrelin gene expression in all gastrointestinal endocrine tumors tested. Gastric neuroendocrine hyperplastic cells were also strongly positive for ghrelin. GH secretagogue receptor mRNA was absent in 3 gastric, but present in 7 of 11 intestinal carcinoids studied by RT-PCR. These findings demonstrate that most gastric carcinoids (and related neuroendocrine cell hyperplasias) and some intestinal carcinoids produce ghrelin. These hyperplastic/neoplastic conditions could represent the clinical model to clarify the existence and impact of ghrelin hypersecretion on endocrine and nonendocrine functions.     

Multiple carcinoids in the duodenum, pancreas and stomach accompanied with type A gastritis： A case report

We report a case of multiple duodenal, pancreatic, and gastric carcinoids. A 67-year old woman was admitted to our hospital for treatment of a duodenal carcinoid. Laboratory tests revealed that the patient was associated with macrocytic anemia and hypergastrinemia, and type A gastritis was shown by gastrofiberscopy. During surgery, another tumor was incidentally found in the head of the pancreas. The tumors in the duodenum and pancreas were completely excised by pancreatoduodenectomy and immunohistologically diagnosed as gastrin-and serotonin-producing carcinoids, respectively. Pathological examination revealed that in addition to the grossly found carcinoids, there were subclinical carcinoids, one of which was an endocrine cell micronest, located in the stomach and duodenum. The tumors in the duodenum, pancreas, and stomach showed different characteristics from one another morphologically and immunochemically. Although no definitive evidence has been obtained, some sort of genetic anomaly may have been involved in this case, and hypergastrinemia due to duodenal gastrinoma may induce multiple gastric carcinoids.     

Circulating ghrelin levels in patients with pancreatic and gastrointestinal neuroendocrine tumors: identification of one pancreatic ghrelinoma

Ghrelin is a novel gastrointestinal hormone involved in several metabolic functions. Although the expression of ghrelin has been demonstrated in most gastrointestinal carcinoids and pancreatic tumors, the circulating levels of this peptide have been marginally assessed in patients with these disorders. We measured plasma ghrelin levels in 16 patients with gastrointestinal carcinoid (10 with midgut and 6 with gastric carcinoid), 24 patients with pancreatic tumor (8 with gastrinoma, 2 with insulinoma, 2 with vipoma, 1 with glucagonoma, and 11 with nonfunctioning tumor), and 35 healthy controls. Plasma ghrelin levels recorded in patients with gastroenteropancreatic tumors were similar to controls (mean +/- SE, 182.7 +/- 66.5 pM in patients vs. 329 +/- 32 pM in controls, P = not significant), and no significant difference between gastrointestinal and pancreatic, functioning and nonfunctioning, and metastatic and nonmetastatic tumors was observed. One patient with metastatic nonfunctioning pancreatic tumor had circulating ghrelin levels of 12,000 pM that were slightly reduced during chemotherapy and interferon therapy. Immunohistochemistry performed on peritoneal lesions showed an intense, focal cytoplasmic positivity for ghrelin. Despite the 50-fold increase in ghrelin concentrations, the patient had normal serum GH and IGF-I levels. In conclusion, the study showed that carcinoids and pancreatic tumors rarely cause ghrelin hypersecretion. However, in this series, 1 pancreatic ghrelinoma not associated with clinical features of acromegaly was identified.     

Expression of cyclo-oxygenase-2 in gastrointestinal carcinoid tumors

BACKGROUND: Cyclo-oxygenase (COX)-2 overexpression is observed in various neoplasms and COX-2 inhibition has been attempted as prevention and/or therapy in these neoplasms. Carcinoid tumors are thought to arise from neuroendocrine cells and originate mainly in the gastrointestinal tract. Cyclo-oxygenase-2 is reportedly expressed in neuroendocrine cells of normal colorectal mucosa. The role of COX in carcinoids has not previously been investigated. The aim of the present paper was to clarify the expression of COX-1 and -2, and their role in human gastrointestinal carcinoids. METHODS: Expression of COX-1 and -2 was studied immunohistochemically in 38 gastrointestinal carcinoids. Five bronchopulmonary and seven metastatic carcinoids were also examined, for comparison with gastrointestinal carcinoids. The immunohistochemical score (IHS) was calculated from staining intensity and immunoreactive cell population, and ranked according to four grades (negative to strong). RESULTS: Cyclo-oxygenase-2 was expressed in all gastrointestinal carcinoids (weak, 1; moderate, 13; strong, 24) and bronchopulmonary carcinoids (weak, 1; moderate, 4), as well as their metastases (moderate, 3; strong, 4). The IHS of COX-2 in larger tumors was significantly lower than that in smaller tumors. However, the IHS of COX-2 at the advancing tumor edge was significantly higher than that at the centers of tumors >or=10 mm in size. Faint COX-1 expression was detected in only one duodenal, one rectal and four bronchopulmonary carcinoids. CONCLUSIONS: Enhanced COX-2 expression was observed in gastrointestinal as well as bronchopulmonary carcinoids and their metastases, especially at the advancing edges of the tumors. Cyclo-oxygenase-2 may play a role in carcinoid progression.     

Classification of gastric neuroendocrine tumors and its clinicopathologic significance

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Prospective study of thymic carcinoids in patients with multiple endocrine neoplasia type 1

Little is known of the natural history of thymic carcinoids in multiple endocrine neoplasia type 1 (MEN1). This is important because in 1993 they were identified as a frequent cause of death, yet only small retrospective studies and case reports exist. We report results of a prospective study of 85 patients with MEN1 evaluated for pancreatic endocrine tumors and followed over a mean of 8 yr with serial chest computed tomography, magnetic resonance imaging (MRI), chest x-ray, and, since 1994, octreoscans [somatostatin receptor scintigraphy (SRS)]. Seven patients (8%) developed thymic carcinoids. Patients with and without carcinoids did not differ in clinical, laboratory, or MEN1 tumor features, except for male gender and the presence of a gastric carcinoid. All thymic tumors were hormonally inactive. Four thymic carcinoids lacked 11q loss of heterozygosity, although it was found in three pancreatic endocrine tumors. Computed tomography and/or MRI were more sensitive than SRS or chest x-ray in detecting tumors initially or with recurrence. All patients underwent resection of the thymic carcinoid, and in all patients followed more than 1 yr, the tumor recurred. Bone metastases developed in two patients and were detected early only on MRI, not SRS. This study provides information on early thymic carcinoids and allows modifications of existing guidelines to be recommended for their diagnosis, surveillance, and treatment.     

Preliminary results of a Japanese nationwide survey of neuroendocrine gastrointestinal tumors

Background We conducted a nationwide survey to estimate the incidence of neuroendocrine gastrointestinal tumors (NETs) newly diagnosed in Japan from 2002 through 2004. Methods Data on 1541 patients, 514 pancreatic endocrine tumors (PETs) and 1027 gastrointestinal carcinoids (GICs), were collected and analyzed. Results Nonfunctioning tumors (NF-PET) constituted 47.7% of PETs. Next in frequency were insulinoma (31.7%) and gastrinoma (8.6%). Malignancy was frequent in NF-PETs (46.1%) and gastrinomas (45.5%), but only 7.4% of insulinomas were malignant. The incidence of multiple endocrine neoplasia type-1 associated with PETs was 7.4%. The incidence of GICs was 28.8%, 5.2%, and 66.0% in foregut, midgut, and hindgut, respectively. Carcinoid syndrome and metastases were observed in only 1.7% and 5.6% of GICs, respectively. Conclusions The incidence of NETs in Japan was clarified by this preliminary study. Comparatively large differences in GICs between Japan and Western nations were present with regard to the location, symptomatic status, and prevalence of malignancy.     

Pancreastatin: molecular and immunocytochemical characterization of a novel peptide in porcine and human tissues

Pancreastatin, a novel 49-amino acid peptide isolated from porcine pancreas, shows over 70% sequence homology to the central part of bovine and human chromogranin-A. Using an N-terminal and C-terminal synthetic peptide, we developed two sensitive and specific RIAs for the detection of pancreastatin-like immunoreactivity (PLI) in porcine and human tissue extracts. PLI was present throughout the gastrointestinal tract and in most endocrine and neuronal tissues. Highest concentrations were measured in the pituitary, adrenal gland, and pancreas (1200-4000 pmol/g), similar to the distribution of chromogranin-A. PLI was also detected in human endocrine tumors, with large quantities in some carcinoids (up to 14 nmol/g). HPLC revealed that extracts from porcine pituitary and pancreas contained small pancreastatin-like peptides, whereas in adrenal medulla large chromogranin-A-like molecular forms predominated. Human endocrine tumors showed a different pattern, with intermediate forms distinct from chromogranin-A and pancreastatin. Biochemical analysis was confirmed by immunocytochemistry localizing PLI in pancreatic islets, adrenal medulla, pituitary, duodenum, and human endocrine tumors. Pancreastatin is present in a variety of gastrointestinal, endocrine, and neuronal tissues and may represent a novel peptide of unknown physiological function, derived from chromogranin-A by proteolytic cleavage.     

Clinical applications of somatostatin analogs.

The somatostatin analog Sandostatin is successfully used in the treatment of metastatic endocrine pancreatic tumors, carcinoids, and acromegaly. In addition, somatostatin receptors are also present on other tumors in man, therefore making it possible to demonstrate these tumors by the administration of (123)I-coupled to a somatostatin analog.     

Xenin-immunoreactive cells and extractable xenin in neuroendocrine tumors of duodenal origin

BACKGROUND & AIMS: Xenin is a 25-amino acid peptide produced by specific endocrine cells of the duodenal mucosa. We investigated whether xenin is expressed in neuroendocrine tumors. METHODS: Seventy-two foregut and midgut neuroendocrine tumors were examined by means of immunohistochemistry, confocal laser microscopy with an antibody against the C-terminus of xenin, and high-pressure liquid chromatography after acidic extraction, assessed by radioimmunoassay. RESULTS: We found xenin-immunoreactive cells in 23 of 26 duodenal neuroendocrine tumors, including gastrinomas, somatostatinomas, and nonfunctioning and enterochromaffin cell tumors. In these tumors, up to 20% of the endocrine cells were xenin immunoreactive, and xenin immunoreactivity was concentrated in secretory granules. Xenin was coexpressed with chromogranin A. We found no xenin expression in gastrin-, somatostatin-, and serotonin-immunoreactive cells. High-pressure liquid chromatography after acidic extraction revealed 497 +/- 285 pmol of xenin per gram of tissue in 5 duodenal gastrinomas. The other neuroendocrine tumors, such as bronchial carcinoids, gastric enterochromaffin-like cell carcinoids, gastric and ileal enterochromaffin cell carcinoids, insulinomas, and gastrinomas of pancreatic origin, did not contain immunoreactive xenin. CONCLUSIONS: Xenin is a peptide marker specific to neuroendocrine tumors of the duodenum. This finding may be useful in tumor classification and in the differential diagnosis of neuroendocrine tumors of the upper gut.     

The diffuse endocrine system and the carcinoids of the alimentary tract. Part I: Orthological aspects and common morphological features of the carcinoids (author's transl)

Carcinoids arise from the so-called system of diffuse clear cells. Because of common histochemical properties it was proposed in the APUD-concept that these endocrine cells are of neural crest origin. As for the gastrointestinal tract endocrine cells this embryological derivation is disputed. Modern methods have led to the identification of about 18 distinct cell types. - According to the different localization of these cells in the alimentary canal the carcinoids show various histological structures i.e., a solid, trabecular, adenoid, undifferentiated and mixed growth. According to the reactivity to silver salts one can distinguish argentaffin, argyrophil and argyrophobe carcinoids. Biochemically and immunohistochemically some carcinoids are multihormonal, while others show paraendocrine hormone production. Small cell anaplastic carcinomas with endocrine granules are highly malignant variants of the carcinoids. There may be a mixed endo- and exocrine (amphicrine) differentiation in normal cells and in the so-called mucicarcinoids.     

Pathologic pancreatic endocrine cell hyperplasia

Pathologic hyperplasia of various pancreatic endocrine cells is rare but has been long known.β cell hyperplasia contributes to persistent hyperinsulinemic hypoglycemia of infancy,which is commonly caused by mutations in the islet ATP-sensitive potassium channel,and to noninsulinoma pancreatogenous hypoglycemia in adults,which may or may not be associated with bariatric surgery.α cell hyperplasia may cause glucagonoma syndrome or induce pancreatic neuroendocrine tumors.An inactivating mutation of the glucago...     

ECL cell tumor and poorly differentiated endocrine carcinoma of the stomach: prognostic evaluation by pathological analysis

BACKGROUND & AIMS: Gastric endocrine tumors show a wide spectrum of clinical behavior, and prognostic assessement of individual tumors is difficult. The aims of this work were to identify predictors of tumor malignancy and patient outcome and to provide a rationale for treatment guidelines. METHODS: Gastric endocrine tumors (86 enterochromaffin-like cell carcinoids and 16 poorly differentiated carcinomas) were investigated for 15 clinicopathologic variables and for expression of Ki67, P53, and BCL-2 proteins. Data were analyzed by univariate and multivariate statistics for evidence of tumor malignancy and patient survival. RESULTS: Histological grades 2 and 3, size >/=3 cm, 9 or more mitoses, or >/=300 Ki67-positive cells per 10 high-power fields identified 26 of 33 (79%) malignant (metastatic or deeply invasive) tumors, and size <1 cm and/or growth restricted to the mucosa characterized 46 of 69 (67%) tumors with benign behavior during a median follow-up of 39 months. Malignancy-predictive models were developed using angioinvasion, size, clinicopathologic type, mitotic index, and Ki67 index. The same variables, in addition to deep gastric wall invasion and histological grade, predicted patient outcome. CONCLUSIONS: Criteria for the assessment of malignancy risk and patient outcome were developed for the different tumors, providing a basis for treatment guidelines.     

Expression of ghrelin and of the GH secretagogue receptor by pancreatic islet cells and related endocrine tumors

Ghrelin is a novel gastrointestinal hormone produced by rat and human gastric X-like neuroendocrine cells, which strongly stimulates GH secretion and influences energy balance, gastric motility, and acid secretion. Ghrelin is expressed in pituitary and gastrointestinal endocrine tumors. It binds to the GH secretagogue receptor (GHS-R), which is present in a wide variety of central and peripheral human tissues. The aim of the present study was 2-fold: 1) to determine, by immunohistochemistry and mRNA analysis, whether pancreatic islet cells produce ghrelin and express GHS-R; and 2) to investigate ghrelin and GHS-R expression in pancreatic endocrine tumors. Seven cases of nonneoplastic pancreatic tissue and 28 endocrine tumors were studied. In pancreatic islets, ghrelin immunoreactivity was present in all cases and confined to beta-cells. Eleven of the 28 (39%) endocrine tumors were immunoreactive for ghrelin. In situ hybridization and RT-PCR confirmed the immunohistochemical data for both tumors and islets but also revealed ghrelin mRNA in 8 and 11 additional tumors, respectively. GHS-R 1a and 1b mRNAs were present in 7 of 28 and 14 of 28 tumors, respectively, studied by RT-PCR. These findings demonstrate that ghrelin production is not restricted to the stomach but is also present in pancreatic beta-cells and endocrine tumors (regardless of the type of pancreatic hormone produced, if any). Expression of GHS-R in some of the endocrine tumors studied indicates that autocrine/paracrine circuits may be active in neoplastic conditions.     

Ductal and acinar differentiation in pancreatic endocrine tumors

Rare pancreatic endocrine tumors consisting of both exocrine and endocrine components have been reported sporadically. We investigated the ductal and acinar differentiation in pancreatic endocrine tumors. In immunohistochemical studies of 28 pancreatic endocrine tumors, staining with anti-carcinoembryonic antigen (CEA) or CA19-9 antibody indicated ductal differentiation, while staining with anti-amylase or anti-trypsin antibody indicated acinar differentiation. K-ras gene mutations and p53 gene alterations also were studied. Ten tumors were immunoreactive for CEA or CA19-9. Five tumors diffusely immunoreactive for CEA or CA19-9, in addition to endocrine markers, were diagnosed as duct–endocrine cell tumors of the pancreas. Two tumors diffusely immunoreactive for CEA or CA19-9 and also for pancreaticogut hormones as well as endocrine markers were diagnosed as duct–acinar–endocrine cell tumors. These tumors showed uniform histologic features and synchronous ductal, acinar, and endocrine differentiation, distinct from the coexisting different cellular populations seen in collision tumors. All tumors were malignant. These duct–endocrine cell tumors or duct–acinar–endocrine cell tumors of the pancreas may be derived from a stem cell that retains the capability of expressing either an exocrine or endocrine phenotype. Only one K-ras gene mutation and no p53 gene alterations were detected in these tumors, which suggests that they constitute an entity with a different origin than ductal carcinomas.     

Neuroendocrine gastric carcinoma. A case report and review of current management

Neuroendocrine or carcinoid tumors of the gastrointestinal tract considered previously extremely rare, are diagnosed at present with increased frequency due to the better capacity to identify neuroendocrine system cells in normal and pathologic conditions. Occasionally, these tumors secrete a great variety of vasoactive substances, producing the carcinoid syndrome. Gastric carcinoids are classified, according to their degree of differentiation into well differentiated and poorly differentiated tumors, also called neuroendocrine carcinomas. Neuroendocrine gastric carcinomas or poorly differentiated gastric carcinoids are seen in 5-15% of all gastric carcinoids, mainly in older male patients. Generally they are large, very aggressive tumors with extensive local infiltration. Due to poor differentiation, they are not frequently associated with an endocrine syndrome. They can be located in any part of the stomach but are mainly seen in antrum. These tumors have an aggressive behavior and must be treated in a radical manner; recurrences are not uncommon. We report the case of a patient with a neuroendocrine gastric carcinoma treated with an en bloc subtotal gastrectomy and colectomy.     

Coexisting carcinoid tumors in familial adenomatous polyposis-associated upper intestinal adenomas

Upper gastrointestinal polyps and extraintestinal tumors are well recognized in association with familial adenomatous polyposis (FAP). Although carcinoid tumors have been reported in association with sporadic colonic neoplasms and ulcerative colitis, to date, carcinoids have not been reported in association with FAP. We report a patient with FAP who has recurrent carcinoid tumors located at the bases of duodenal adenomas. The genetic basis of carcinoid neoplasms is still uncertain. This report may represent the clinical effect of the APC gene mutation on the enterochromaffin cell line manifesting as recurrent carcinoid tumors in physical association with intestinal adenomas. Future genetic analysis and epidemiological studies may be of value in determining whether a true association exists.