Active clinical trials for "Glioma"

Gliomas are the most common malignant primary central nervous system (CNS) tumours. When high-grade gliomas (HGG) recur, subsequent magnetic resonance (MRI) imaging, with additional sequences is required.The Positron Emission Tomography (PET) radiotracer [18F]-fluorodeoxyglucose (FDG) will be used in this study to distinguish between changes seen on MRI which can be a reflection of pseudoprogression, radiation necrosis, or recurrence.

Study on glioma patients treated with brain surgery is focusing on the analysis of their transcriptome expression profile measured in two immune cell populations, CD4+ T cells and CD56+ NK cells. The results of analysis will be compared to the reference data of healthy population. Furthermore, the metabolomic and immunological status will also be monitored and compared to healthy group reference data, before and after the surgery*. With comparative crossomics analysis the investigators intend to possibly identify new diagnostic and prognostic biological markers for the relapse of the disease. The results are expected to convey a deeper insight into pathophysiology of the glioma as well as into the mechanisms of the current surgical therapy. * The healthy reference data have been published in collaborative efforts of BTC, UMC and NIB (Gruden et al. 2012).

Malignant gliomas are the most common and deadly primary brain tumors in adults. The clinical outcome of patients with glioblastoma depends on key molecular genetic alteration. Specifically, Isocitrate Dehydrogenase Gene Mutation, an independent favorable prognostic factor, serve as diagnostic and prognostic markers of glioma. Thus, accurate grading of a glioma is fundamental in order to determine the treatment strategy. Amide proton transfer (APT) imaging is a noninvasive molecular MRI technique based on chemical exchange saturation transfer mechanism that detects endogenous mobile proteins and peptides in biological tissues. Preliminary studies have shown that APT-weighted (APTw) signal intensity could serve as a new imaging biomarker, by revealing significantly higher signal intensities in the high-grade gliomas compared with the low-grade gliomas. The purpose of this study was to investigate the value of amide proton transfer imaging (APT) in the noninvasive evaluation of isocitrate dehydrogenase (IDH) gene status in glioma.

ATRX (X-linked mental retardation and alpha-thalassaemia syndrome protein) loss and pTERT (Telomerase reverse transcriptase) mutation are diagnostic markers of gliomas. However, 4 to 28% of gliomas shows none of these alterations. The aim of this project is to propose a new test able to detect the telomeric status for every glioma. Based on this test and other markers (such as mutation of IDH1 (isocitrate dehydrogenase 1) and IDH2 (isocitrate dehydrogenase 2)), investigators propose an algorithm, able to classify the main subtypes of gliomas (astrocytoma, oligodendroglioma and glioblastoma).

From the medical records of a series of patients operated on for incident grade II and III glioma, the primary objective is to evaluate the correlation between the molecular profile of tumours and preoperative imaging data (by FDG and FDOPA PET-scan and multimodal MRI).

Low-grade diffuse glioma (GDBG) are rare tumors of young adults, whose ontogenesis is poorly understood. Patient management is based on the molecular profile defined by two molecular markers : mutations of the IDH genes and chromosomal 1p19q co-deletion. To date, the IDH and 1p19q statuses are determined on a single fragment collected from the tumor. In the case of GDBGs infiltrating several brain lobes, the sampling is done randomly on only one of the infiltrated lobes. An intra-tumoral heterogeneity of genetic alterations has been suggested and would impact management. Phylogenetic analysis of genetic alterations found, by high throughput sequencing, in each lobe invaded by the same GDBG will make it possible to assess intra-tumoral heterogeneity and to discuss, at a fundamental level, the hypothesis of a single tumor site with secondary diffusion or that of the convergent progression of two or three distinct tumor sites. Clinically, understanding the ontogenesis of GDBGs will improve their management because of the known link between brain location, dominant molecular profile, and prognosis.

This prospective study aims to collect clinical, radiological, pathological, molecular and genetic data including detailed clinical parameters, MR and histopathology images, molecular pathology and genetic sequencing data. By leveraging artificial intelligence, this registry seeks to construct and refine algorithms that able to predict molecular pathology or clinical outcomes of glioma patients based on MR images and histopathology images, as well as revealing related mechanisms from genetic perspective.

The goal of this project is to get more insight into the (neuro)ophthalmological characteristics of children with neurofibromatosis type 1. This way investigators would like to update the current guidelines for follow up and treatment of optic pathway gliomas. Clinical findings will be compared with the results of Optical coherence tomography (OCT) and MRI (magnetic resonance imaging).

Prospective, observational study aimed to investigate the specific hemostatic alterations in patients undergoing glial tumor resection.