View clinical trials related to Glioblastoma.
Filter by:In the proposed trial, patients will be administered ribociclib prior to surgical resection of their tumor. Patients will be enrolled in time-intervals sequentially (non-randomized). All patients will be orally-administered 5 doses of LEE011 (900 mg/d) with the final dose occurring at one of 3 intervals before brain tumor resection.
The purpose of this study is to determine whether a combination of Sunitinib, Temozolomide and Radiation Therapy would be effective in the treatment of newly diagnosed Glioblastoma patients harboring tumors with unmethylated MGMT promoter.
This study aims to evaluate the role of Regorafenib in prolonging the overall survival of glioblastoma multiforme patients who progressed after surgery and Stupp regimen with or without bevacizumab.
This clinical trial studies how well delayed fludeoxyglucose F-18 (18F-FDG) positron emission tomography (PET)/computed tomography (CT) works in improving visualization of brain tumors in patients with glioblastoma. Radiotracers such as 18F-FDG are highly taken up by tumors in the brain and are visualized using PET/CT. Increasing the interval of time between 18F-FDG administration and PET/CT scan may improve the visualization of brain tumors in patients with glioblastoma.
This is an open-label positron emission tomography/near infrared (PET/NIRF) study to investigate the imaging navigation performance and evaluation efficacy of dual modality imaging probe 68Ga-BBN-IRDye800CW in glioblastoma (GBM) patients. A single dose of 40μg/111-148 Mega-Becquerel (MBq) and 1.0 mg/ml 68Ga-BBN-IRDye800CW will be injected intravenously before the operation and intraoperative respectively. Visual and semiquantitative method will be used to assess the PET images and real-time margins localization for surgical navigation.
One-third of all primary brain tumors are astrocytomas, the most common type of glioma. Grade 4 astrocytomas, more commonly known as glioblastomas (GBMs), represent about 50% of all gliomas (annual incidence of over 3 per 100,000) and are associated with high mortality rates and median patient survival of just 12-15 months post-diagnosis. Treatment response is assessed by measuring post-treatment tumor size on contrast-enhanced magnetic resonance images (MRI). However, radiation and chemotherapy cause inflammatory and necrotic changes which, like actual tumor progression itself, demonstrate contrast enhancement on the first post-treatment MRI scan. This enhancement eventually subsides (typically within 6 months of treatment) and is known as pseudoprogression (PsP). Currently, there is no gold standard noninvasive tool for distinguishing between pseudoprogression and progressive disease. Dynamic susceptibility-weighted contrast-enhanced perfusion MRI (DSC perfusion MRI) permits measurement of hemodynamic imaging variables. Previous literature reports attempted to use some or all of these metrics to assess their utility in distinguishing PsP from true cancer progression. These studies showed mixed results, likely due to a number of factors, including poor statistical power, poorly defined PsP, analysis of multiple cancer grades and types, and varied analysis methodologies. The investigators aim to address these issues in this study.
Despite maximal safe surgery followed by combined chemo-radiation therapy, the outcome of patients suffering from glioblastoma (GBM) remains extremely poor with a median survival of 15 months. Hence, new avenues have to be taken to improve outcome in this devastating disease. Given their intracerebral localization and their highly invasive features, GBM pose some specific challenges for the development of adequate tumor models. Orthotopic xenograft models directly derived from the tumor of a patient might represent an attractive perspective to develop patient-specific targeted therapies. This approach remains however to be validated for GBM as it offers specific challenges, including the demonstration that the properties of xenograft models validly represent treatment relevant features of the respective human tumors. In this innovative project the investigators aim to compare and validate an approach of paired human GBM and respective derived orthotopic xenografts in the mouse brain on the levels of radiological behavior and metabolism of the tumors, as determined by high resolution MRI of the patients (7T MRI) and the respective orthotopic mouse xenografts (14.1T MRI), as well as on the level of the transcriptome, genome, and methylome of the original GBM tissue and respective derived xenografts/glioma sphere lines. The data will be integrated in multidimensional analyses and interrogated for similarities and associations with molecular GBM subtype. This pilot project will provide the basis for the crucial next steps, which will include drug intervention studies. New promising drugs, tested pre-clinically in the mouse orthotopic xenograft models established here using the radiologic/metabolic/molecular procedures described for this project, will be taken into patients in phase 0 studies. GBM patients will receive radiologic/metabolic follow-up using high resolution MRI under drug treatment, followed by resection of the tumor and subsequent acquisition of molecular data.
This study is for newly diagnosed WHO Grade IV malignant glioma patients to determine whether an investigational drug known as marizomib (MRZ) will improve the treatment of newly diagnosed glioblastoma patients by delaying the growth of the cancer, reducing the size of the tumor, and/or improving survival. Marizomib (MRZ) is being added to standard-of-care treatments of radiotherapy (RT), temozolomide (TMZ), and Optune.
This pilot clinical trial studies fluordeoxyglucose (fludeoxyglucose) F-18 (FDG) positron emission tomography (PET)/computed tomography (CT) in monitoring very early therapy response in patients with glioblastoma. Diagnostic procedures, such as FDG PET/CT, may help measure a patient's response to earlier treatment. Chemotherapy can induce very rapid changes to the tumor's glucose consumption which can be measured with imaging. FDG PET/CT shortly after the start of therapy may help identify very early therapy response in patients with glioblastoma.
Systematic retrospective medical chart and medical imaging file review of all patients receiving brain MRI for the follow-up of glioblastoma.