UMLS:C0017636 - FACTA Search

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Query: UMLS:C0017636 (glioblastoma)
18,345 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Reduced glutathione (gamma-glutamylcysteinylglycine, GSH) plays an important role in the protection of cells against damage from free radicals and other electrophils and also influences cellular radiosensitivity, cellular response to hyperthermia, and cytotoxicity to some kinds of chemotherapeutic agents. The concentrations of GSH in 40 primary and metastatic brain tumors were quantitatively analyzed, and GSH was localized in these tumors by a novel o-phthalaldehyde histofluorescence method. The level of GSH was 195.2 +/- 57.1 micrograms/gm (mean +/- standard deviation) in glioblastomas multiforme, 444.1 +/- 105.1 micrograms/gm in normal brain tissues, and 614.4 +/- 237.4 micrograms/gm in meningiomas. The differences in GSH levels between glioblastomas and normal brain tissues and between glioblastomas and meningiomas were statistically significant (p less than 0.01). The mean GSH level in astrocytoma grades II and III was 321.9 +/- 11.8 micrograms/gm. The difference in the GSH level between glioblastomas and astrocytomas was statistically significant (p less than 0.05). Radiosensitive tumors, such as multiple myeloma, germinoma, and small-cell carcinoma, showed low GSH levels. These data suggest the possibility that the GSH may be a predictor for the efficacy of radiation therapy. The cytochemical study showed GSH localized in the cytoplasm; although it stained well in meningioma tissue, GSH was not well stained in sections of multiple myeloma. The endothelial proliferation did not stain well in glioblastoma, which seems to imply that this area is vulnerable to attack by free radicals from irradiation and/or chemotherapy.
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PMID:Quantitative analysis of glutathione in human brain tumors. 169 Jul 92

The immunohistochemical distribution of alpha and beta subunits of S-100 protein (S-100 alpha, S-100 beta, respectively) in 138 cases of human brain tumors was investigated by the avidin-biotin immunoperoxidase method. Brain tumors can be divided into four groups: group 1 [S-100 alpha (+) and/or S-100 beta (+)]; astrocytoma, glioblastoma, ependymoma, subependymoma, oligodendroglioma, choroid plexus papilloma, gangliocytoma, meningioma, chordoma, malignant melanoma. Group 2 [S-100 alpha (+) and S-100 beta (-)]; pineoblastoma, pituitary adenoma, craniopharyngioma, rhabdomyosarcoma. Group 3 [S-100 alpha (-) and S-100 beta (+)]; acoustic Schwannoma. Group 4 [S-100 alpha (-) and S-100 beta (-)]; medulloblastoma malignant lymphoma, germinoma. The S-100 beta immunoreactivity pattern in brain tumors was similar to those obtained using conventional anti-S-100 protein sera. In the first group of brain tumors both the number of positively stained tumor cells and the staining intensity were generally greater for S-100 beta than for S-100 alpha with a few exceptions including one gemistocytic astrocytoma, one subependymoma, one malignant melanoma, and some cases of glioblastomas. As to the relationship between malignancy and S-100 protein in glioma, S-100 beta immunoreactivity decreased according to degree of malignancy, while that of S-100 alpha varied, suggesting a heterogeneity of tumor cells in glioblastomas. Immunostaining for S-100 alpha and S-100 beta might become a useful diagnostic procedure in brain tumors and may give us more detailed and precise data of S-100 protein in brain tumors.
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PMID:Immunohistochemical study on the distribution of alpha and beta subunits of S-100 protein in brain tumors. 188 40

A cooperative clinical trial of human fibroblast interferon (BM532) (HuIFN-beta with a specific activity of greater than 1 X 10(7) IU/mg protein; Toray Industries, Inc.) in the treatment of malignant brain tumors was conducted by the neurosurgical departments of 34 medical institutions. The patients admitted to the study had measurable lesions with an established histopathologic diagnosis, and desirably, a favorable performance status. The interferon therapy was instituted after a minimum 4-week interval following termination or completion of previous therapy so that the effect of interferon alone was able to assess. HuIFN-beta was administered either locally (intrathecally or intratumorally) or intravenously in doses of 1 X to 6 X 10(6)IU/body, daily for a period of 8 weeks or longer as a rule. Evaluation of the clinical responses was based primarily upon the findings of CT scans and conformed to Koyama-Saito's criteria. There were a total of 65 patients, 49 males and 16 females, whose clinical responses were amenable to assessment in the study. They were 64 cases of gliomas (neuroectodermal tumors other than glioblastoma) and one case of germinoma. The treatment was effective in 26.2% of all cases and 26.6% of the glioma cases. The efficacy rate was 24.5% (12/49) in the cases administered intravenously at dose of 1 X to 6 X 10(6)IU/body of HuIFN-beta. The efficacy did not vary appreciably with the route of administration of interferon. The response rates for new cases and recurrent cases did not show any significant differences. Side effects occurred in 61.1% of the patients with transient fever being the most common.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Clinical effect of human fibroblast interferon (BM532) on malignant brain tumors--with special reference to gliomas]. 267 Dec 5

Neocarzinostatin as previously reported, appeared to exhibit an intense cytotoxicity to the glioblastoma cells and some other malignant brain tumor cells, such as pineal germinoma or medulloblastoma, which are notoriously known to disseminate into the cerebrospinal fluid space. In vitro study, the minimum susceptibility of glioblastoma cells to neocarzinostatin was found to be below 0.005 microgram/ml, whereas normal glia cells were not affected at 0.3 microgram/ml. This study indicated that neocarzinostatin was extremely effective in the treatment of malignant brain tumor without affecting normal neural tissue. Pharmacokinetic study was performed in order to establish intermittent intrathecal perfusion therapy and to prevent subarachnoid dissemination of the brain tumor cells. Experimental results were applied to the treatment of 12 patients with brain tumor, who had shown positive cytology of the cerebrospinal fluid. Follow-up investigation showed quite a favorable result and it was considered that prophylactic irradiation to the entire spinal column could be replaced with intrathecal administration of neocarzinostatin. During clinical application no noticeable side effect was encountered and active stimulation of macrophages, which were mobilized into the CSF space, was another unexpected advantage of this treatment.
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PMID:[Pharmacokinetic one-compartment model using neocarzinostain as a prototype drug and its clinical application to chemotherapy for brain tumor. Part II. A clinical trial with selected protocol]. 622 89

An analysis of more than 18,000 primary central nervous system (CNS) tumors revealed only 18 cases (0.01%) in which dropped spinal metastases had caused the presenting symptoms. This group included 11 males and 7 females in whom there was no history of surgical intervention or irradiation. Primitive neuroectodermal tumors ( PNET , medulloblastoma), comprised the largest group (11 patients) followed by high-grade astrocytomas (anaplastic and glioblastoma) (5 patients). One case each of germinoma and ependymoma were also identified. The clinicopathologic data of these cases, and a brief review of the literature are presented.
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PMID:Spinal metastases. A rare mode of presentation of brain tumors. 632 8

Of 8000 consecutive patients studied with computed tomography, 10 patients with primary intracranial tumors (germinoma, medulloblastoma, malignant teratoma and glioblastoma) showed ventricular or leptomeningeal spread of the tumor cells. In patients with leptomeningeal spread, computed tomography showed obliteration of basal cisterns and sulci with isodense or slightly hyperdense mass, which was markedly enhanced following administration of the contrast medium. In cases of ventricular spread, a narrow zone of high density was noted on the ependymal surface, and it was also markedly enhanced with the contrast medium. Similar CT scan appearance of contrast enhancement in the subarachnoid space or in the ventricular surface was, however, noted also in the infectious processes such as basal arachnoiditis or ependymitis, and the differentiation of the neoplastic process from the infectious lesions seemed impossible based on the CT scan appearance alone.
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PMID:[Computed tomography in leptomeningeal and ventricular spread of primary brain tumors (author's transl)]. 697 May 84

In 1955, Collins made the observation that tumor recurrence in children with Wilms' tumor was correlated with the child's age plus 9 months. This concept of a period of risk for recurrence was later applied to a variety of tumors in children and became known as Collins' Law (CL). The law has been a successful predictor of survival for some children with neural tumors within the central nervous system and a poor predictor for others. We tested Collins' concept of a period of risk for recurrence and extended it to survival for 14 childhood neural tumors described in the Childhood Brain Tumor Consortium (CBTC) database. The CBTC data describe clinical, surgical, and histological details (over a 49-year period in 10 institutions) from 3921 patients under the age of 21 years at the time of their first surgical procedure for a brain tumor. CL was considered to be a good predictor of survival if fewer than 10% of patients who die survive beyond the expiration of the period of risk for that child. We found that CL applied to tumors such as anaplastic astrocytoma, glioblastoma, pineoblastoma, medulloblastoma or "primitive neuroectodermal tumor," teratoma, and germinoma, as well as ependymoma, papilloma, and tumors that could not be classified; it had no predictive value in craniopharyngioma, oligodendroglioma, or plain, fibrillary, pilocytic, or protoplasmic astrocytoma. We had sufficient follow-up data to determine adherence to CL when the child's age at diagnosis was less than 8 years; it is likely that CL applies to older children with these tumors, but we did not have the data to show this unequivocally.
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PMID:The applicability of Collins' Law to childhood brain tumors and its usefulness as a predictor of survival. 764 86

Despite its usefulness in adults with cerebral gliomas, indications for thallium-201 single-photon emission computed tomography (SPECT) in pediatric brain tumor patients are not well defined. We prospectively compared thallium SPECT with gadolinium-enhanced MR (Gd-MR) to determine if thallium SPECT provides clinically useful information that cannot be derived from Gd-MR. We studied 24 pediatric brain tumor patients, 7 at presentation and 17 during therapy. MR imaging included T2 and pre- and postgadolinium T1 images. Thallium SPECT was done within 48 h of MR imaging; thallium indices were calculated for 12 of 14 lesions which showed thallium uptake. Surgery and/or clinical follow-up are available in all patients. The tumors included pilocytic astrocytoma (7), medulloblastoma (5), brainstem glioma or glioblastoma (4), germinoma (3), optic glioma (2), mixed glioma (1), primitive neuroectodermal tumor (1), and choroid plexus carcinoma (1). Among the primary tumors, compared to MR, thallium SPECT was false-negative for tumor in 1 patient and true-positive in 6 patients. Among the patients studied while on therapy, compared to MR, thallium SPECT was true-negative for tumor in 7, true-positive in 5, false-negative in 3, and false-positive in 2. In both groups of patients, thallium SPECT underestimated tumor burden as nonenhancing regions of the tumors were not thallium-avid. Thallium indices did not correlate with histologic grade, biologic aggressiveness, or tumor type. We were unable to establish indications for the use of thallium SPECT in this setting as there was little clinically useful information derived from thallium SPECT that was not provided by Gd-MR.
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PMID:Comparison of gadolinium-enhanced MR and thallium-201 single photon emission computed tomography in pediatric brain tumors. 788 93

The role of inflammatory reactions in brain tumors is still unclear. In particular, there is little information about the participation of the microglia/macrophage cell system. We therefore investigated 72 surgical biopsy samples of brain tumors (astrocytoma, glioblastoma, oligodendroglioma, ependymoma, medulloblastoma, cerebral lymphoma, gangliocytoma, neurocytoma and germinoma) and the brains of eight cases with malignant gliomas that came to autopsy, using immunohistochemical markers for the monocyte/macrophage lineage (Ki-M1P, HLA-DR, KP1, My4, My7, Ki-M1, Ki-M6, EBM 11). These markers allowed us to characterize four subtypes of the microglia/macrophage cell system: ramified microglia, ameboid microglia, perivascular microglia and brain macrophages. Among the different tumors, glioblastomas and anaplastic gliomas showed the largest number of mixed cell populations, which consisted of macro-phages and ramified and ameboid microglia. In glial tumors of low malignancy fewer, predominantly ameboid, microglia were found. Neuronal tumors showed only a mild increase of microglia. Cerebral lymphomas contained macrophages diffusely distributed within the tumor center, while activated microglia were prominent at the border zone and in the adjacent brain tissue. The autopsy cases were used to study the morphometric distribution of microglia/macrophages. There was a significant increase of microglia/macrophages within the tumor, but no differences were seen between central and peripheral tumor areas. The non-neoplastic gray and white matter contained more microglial cells than controls. We conclude that the distribution pattern of ameboid and ramified microglial cells and macrophages is distinct in most of the investigated tumor types, underlining the complex immunological function of the microglia/macrophage cell system.
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PMID:Distribution and characterization of microglia/macrophages in human brain tumors. 887 Aug 31

Mass lesions of the central nervous system (CNS) that may assume a clear cell appearance are diverse in nature. Primary conditions in this category include oligodendroglioma, hemangioblastoma, germinoma (seminoma), clear cell and chordoid meningioma, pleomorphic xanthoastrocytoma, and lipid-rich glioblastoma. These proliferations usually can be identified by attention to clinical presentation, topographic location, radiographic details, and histological nuances. Occasionally, however, electron microscopy or immunohistological analysis may be necessary. A recommended panel of reagents for the evaluation of clear cell primary CNS lesions include antibodies to glial fibrillary acidic proteins, S-100 protein, epithelial membrane antigen, vimentin, keratins, placental-like alkaline phosphatase, and synaptophysin. This article reviews the salient clinicopathologic attributes of such proliferations, elaborates a practical approach to their diagnosis, and discusses important differential diagnostic considerations. The latter include malformative lesions, infarcts, inflammatory conditions, and secondary lymphomas, carcinomas, and melanomas.
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PMID:Clear cell neoplasms and pseudoneoplastic lesions of the central nervous system. 938 25

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