Wakako Miura

Changes in clinical features and long-term prognosis in patients with pheochromocytoma

To investigate changes in preoperative clinical features and the long-term outcome of tumor recurrence, mortality, and morbidity in patients with pheochromocytoma, we retrospectively examined changes in the clinical features by comparing 49 patients from 1957 to 1985 (group I) with 46 patients from 1986 to December 1995 (group II). In addition in these 95 patients (excluding 2 who had died before operation), we evaluated long-term postoperative outcome from the initial operation to August 1996 (909 patient-years). The mean age in group II was older than that of group I. The percentage of patients having proteinuria or hypertensive retinopathy in group II was less than that in group I. Of 20 patients with incidentally discovered pheochromocytoma, 7 (35%) were > or =60 years old, 7 asymptomatic, and 11 (55%) normotensive. Plasma and urinary catecholamines in these patients were significantly (P < .01) lower than in patients with pheochromocytoma having typical clinical features. Long-term cohort study showed 14 deaths. Relative survival rates were 91% at 5 years and 83% at 10 years and unchanged thereafter. The Kaplan-Meier estimate of pheochromocytoma-free survival was shorter in patients with a larger-than-median (60 g) tumor weight. Six patients had malignant recurrence 3 to 101 months (median, 45 months) after the initial operation. Of 65 patients confirmed alive at follow-up, 11 were hypertensive. In the Cox model, hypertension-free survival was not associated with age, a family history of hypertension, duration of hypertension, or creatinine clearance. Pheochromocytoma should be diagnosed from a wide spectrum of clinical features including those that are not generally suspected of resulting from excess catecholamines or hypertension, and after surgery, patients with this disease should be followed-up carefully for a long period (at least 10 years) because of the risk of tumor recurrence and the high prevalence of disease.

Ki-67 is an indicator of progression of neuroendocrine tumors

No current histological or cytological indices can distinguish reliably malignant from benign tumors in neuroendocrine tumors, including pheochromocytomas, pancreatic endocrine tumors, and carcinoid tumors. We investigated immunohistochemically the expression of Ki-67 in 52 neuroendocrine tumors, including 17 pheochromocytomas, 9 pancreatic endocrine tumors, 23 carcinoid tumors, 2 neuroendocrine carcinomas (NEC), and 1 neuroblastoma with liver metastasis. Of the 52 tumors, distant metastasis was observed in 4 pheochromocytomas, 2 pancreatic endocrine tumors, 4 carcinoids, 2 NEC, and 1 neuroblastoma. We classified these tumors into 3 groups; Groups A, B, and C, depending on the number of Ki-67-positive cells counted under a 200 x magnified field. Expression of Ki-67 was extremely high in group A (> 50 labeled nuclei/field), moderately high in group B (20–50 labeled nuclei), and very low in group C (< 10 labeled nuclei). There was a significant correlation between expression of Ki-67 and tumor progression. The tumors in group A progressed rapidly with the worst outcome; the tumors in group B progressed slowly but with a bad outcome; and the tumors in group C had no metastasis and a good prognosis. Ki-67 is an excellent indicator to assess progression of neuroendocrine tumors.

Immunohistochemical localization of chromostatin and pancreastatin, chromogranin A-Derived bioactive peptides, in normal and neoplastic neuroendocrine tissues

Despite the widespread distribution of chromogranin A (CgA) in neuroendocrine tissues, the biological function of CgA has not yet been elucidated. The primary amino acid sequence of CgA, elucidated by cDNA analysis, has been revealed to include several pairs of basic amino acid residues that are homologous to the bioactive peptides, such as pancreastatin (PST) and chromostatin (CST). Using antibodies for human PST and CST, the immunohistochemical localization of these peptides was investigated in neuroendocrine tissues, including human pituitary glands, pancreas, adrenal medulla, various types of neuroendocrine neoplasms (13 pheochromocytomas, 10 medullary thyroid carcinomas, 11 pancreatic endocrine tumors, and 19 carcinoid tumors), and the cell line QGP-1N derived from human somatostatin-producing pancreatic endocrine tumor.Variable immunoreactive intensities of PST and CST were seen, but both peptides were detectable in all neuroendocrine tissues and in most of the neoplasms. Immunoreactivity for both PST and CST was observed in 100 and 73%, respectively, of pancreatic endocrine tumors, all pheochromocytomas, and 80 and 40%, respectively, of medullary thyroid carcinomas, as well as all nonrectal carcinoid tumors. In rectal carcinoids, cells immunoreactive for PST and CST were sparse. The distribution of PST and CST was similar to that of CgA, and it is considered that these peptides are simultaneously processed from CgA, and may play roles in autocrine and paracrine regulation on various hormones in addition to their previously known functions.

Expression of stanniocalcin in zona glomerulosa and medulla of normal human adrenal glands, and some adrenal tumors and cell lines

Stanniocalcin (STC) is a calcium (Ca)‐regulating hormone that was originally discovered in the fish Stannius body, which is a unique endocrine organ. Hypercalcemia increases STC secretion, which inhibits Ca uptake by the gills and normalizes serum Ca level. In this study we investigated the STC expression in human normal and abnormal adrenal cells. Immunohistochemistry using monoclonal antibody against STC revealed specific staining in zona glomerulosa and medulla of normal human adrenal glands. STC was also detected in human adrenal tumors, such as pheochromocytoma, differentiated neuroblastoma, and aldosterone‐producing adenoma, and cultured adrenal tumor cells (rat pheochromocytoma PC‐12 cells and human neuroblastoma NB‐1 cells). However, undifferentiated human adrenal neuroblastoma was negative for STC staining. Reverse transcription polymerase chain reaction demonstrated STC mRNA expression in cultured PC‐12 cells and NB‐1 cells. Following several studies indicating that zona glomerulosa cells of adrenal glands express neuroendocrine properties, STC expression in normal and abnormal adrenal cells provides additional evidence to support the neuroendocrine differentiation of these cells. In conclusion, STC may be useful as a new cell marker of adrenal glands under physiological and pathological conditions.

Dna ploidy of pheochromocytoma on cytology specimen by image analysis

Pheochromocytoma usually shows prominent nuclear atypia, but the presence of such atypical cells is known to be an unreliable predictor of malignancy. DNA ploidy of pheochromocytomas has been analyzed by flow cytometry or photospectrometry on paraffinem-bedded tissue, but the results were controversial. We performed DNA analysis on cytology specimens of 11 pheochromocytomas using an image analysis system. All tumors had a mixed pattern of a large population of diploid cells and a small population of polyploid cells. DNA content correlated with nuclear size, and larger cells had more DNA content. Such larger tumor cells had polyploid nuclei, such as 4 C, 8 C, 16 C, and 32 C, in both malignant and benign pheochromocytomas. The larger polyploid nuclei may result from difficulty of duplication at the mitotic phase of the cell cycle.