View clinical trials related to Glioblastoma.
Filter by:Glioblastomas represent 40% of all tumors of the central nervous system (CNS) and are among the most lethal tumors. Temozolomide (TMZ) combined with radiotherapy was the first substance to significantly improve the overall survival (to 14.6 months) as compared to surgery and radiotherapy alone and increased the proportion of patients surviving more than 2 years to 26%. TMZ showed the best efficacy in patients with a methylated O6-methylguanine-DNA methyltransferase (MGMT) promoter in part by eliminating stem cell-like tumor cells. Among patients with a methylated MGMT promoter, the median survival after treatment with combined radio-chemotherapy was 21.7 months, as compared to 15.3 months among those who were assigned to radiotherapy only. In the absence of methylation of the MGMT promoter, there was a smaller and statistically insignificant difference in survival between the treatment groups. Doxorubicin is one of the most effective substances in vitro against cells derived from glioblastoma. However, it has no significant effect in vivo due to poor blood-brain-barrier penetration. In a tumor model, tissue and CSF-concentrations of doxorubicin were substantially increased when sterically stabilized liposomes were used resulting in a comparable clinical response using approximately half of the dose of stabilized liposomes compared to conventional doxorubicin. A pegylated formulation (PEG-liposomal Doxorubicin) even further improved the penetration of the blood-brain barrier. Case series and two phase II-studies in patients with recurrent glioblastoma have shown modestly promising results for PEG-Dox. In this study, the investigators treated patients with recurrent glioblastoma with 20 mg/m2 PEG-Dox on days 1 and 15 of each 28-day cycle. To determine the dose limiting toxicity of PEG-Dox combined with prolonged administration of TMZ, the investigators performed a phase I part ahead of the phase II study. To investigate, by means of a historical control analysis, if the addition of PEG-Dox to TMZ and radiotherapy improves the survival of patients, the investigators chose similar inclusion criteria and identical TMZ and radiotherapeutic regimes as in the EORTC26981/NCIC-CE.3 study.
This 2 arm study investigated the efficacy and safety of the addition of bevacizumab to the current standard of care (multimodality therapy of concurrent radiotherapy plus temozolomide followed by adjuvant temozolomide) as compared to the current standard of care alone. Participants were randomly assigned to either the bevacizumab (10 milligrams per kilogram (mg/kg) intravenously [IV] once every 2 week [q2w]) or the placebo arm, in combination with radiation therapy (total dose 60 Gray [Gy], administered as 2 Gy fractions, 5 days/week) plus temozolomide (75 milligrams per meter squared [mg/m^2] oral administration [po] daily) for 6 weeks. After a 4 week treatment break, participants continued to receive bevacizumab (10 mg/kg IV q2w) or placebo, plus temozolomide (150-200 mg/m^2 po daily on days 1-5 of each 4 week cycle) for 6 cycles of maintenance treatment or until disease progression or unacceptable toxicity, whichever occured first. Following the maintenance phase, bevacizumab (15 mg/kg iv every 3 weeks [q3w]) or placebo monotherapy continued. The time on study treatment was until disease progression.
The treatment of a specific subtype of highly malignant brain tumor (called "glioblastoma" or "glioblastoma multiforme") consists of neurosurgical resection, followed by radiotherapy and mostly chemotherapy as well. Increased extent of tumor resection is associated with prolonged survival. The standard treatment uses conventional neuronavigation systems to increase extent of tumor resection. However, the quality of this form of neuronavigation decreases throughout surgery because of "brain shift". This is caused by edema, loss of cerebrospinal fluid and tumor resection. A new form of neuronavigation uses intraoperative MRI to compensate for brain shift, and to check for the presence of residual tumor that can be removed. This study aims to compare the extent of glioblastoma resection between the standard treatment and intraoperative MRI.
For patients with progressive or recurrent glioblastoma there is no standard therapy. One strategy is re-exposure to temozolomide in a higher dose. This increase in dosing can be done by 2 regimens. Aim of this study is to compare these 2 dosing regimens concerning toxicity. In study arm A patients receive temozolomide for one week, followed by a week without temozolomide. In study arm B patients receive temozolomide for three weeks, followed by a week without temozolomide. The regimen that is less toxic will be selected for further evaluations.
This is a Phase I/II open-label, single-arm study among recurrent malignant glioma patients. Patients will be treated with Vorinostat in combination with Bevacizumab (BV) (10 mg/kg) and Temozolomide (T) (50 mg/m2/day) BV is administered every 2 weeks. Temozolomide will be taken orally once every day. Vorinostat will be taken orally on days 1-7 and 15-21 of each 28-day cycle. In the phase I portion of this study, the dose of Vorinostat will be escalated in successive cohorts of patients to determine the maximum tolerated dose (MTD) based on dose-limiting toxicities (DLTs). In the phase II portion of this study, the dose of Vorinostat will be the MTD determined in the phase I portion. The primary endpoint of the phase II study is 6-month progression-free survival (PFS) for recurrent GBM (Glioblastoma) patients. This study will be conducted at The Preston Robert Tisch Brain Tumor Center at Duke.
To assess the efficacy and safety of bevacizumab plus irinotecan for the patients with recurrent anaplastic astrocytoma or with recurrent glioblastoma multiforme
The purpose of this study is to evaluate whether NPC-08 is safety and efficacy in the treatment of newly-diagnosed malignant glioma and recurrent glioblastoma multiforme.
The study is a prospective, randomly controlled pivotal trial, designed to test the efficacy and safety of a medical device, the NovoTTF-100A, as an adjuvant to the best standard of care in the treatment of newly diagnosed GBM patients. The device is an experimental, portable, battery operated device for chronic administration of alternating electric fields (termed TTFields or TTF) to the region of the malignant tumor, by means of surface, insulated electrode arrays.
Hypoxia is recognized to be an independent predictor of clinical outcome in oncology. PET using [18F]-FMISO has been described to be useful for the non invasive assessment of hypoxia in cancer. The use of this radiotracer for brain tumours is very limited and there is no standard to acquire and quantify [18F]-FMISO uptake. So there is a need for a methodological evaluation of this PET tracer The purpose of this research is to define optimal parameters for acquisition and data exploitation to quantify [18F]-FMISO uptake and so predict clinical outcome in glioblastomas. Low sensitivity to radiation of glioblastoma is partly caused by hypoxia. Hypoxia in tumours is not predicted by tumour size. Detecting and monitoring tissue oxygenation are of great interest to modify therapeutic strategies, including local dose escalation for radiotherapy or select chemotherapeutic agents with better impact in glioblastomas. PET with appropriate radiotracers, especially [18F]-FMISO, enables non-invasive assessment of hypoxia. [18F]-FMISO only accumulates in viable hypoxic cells. So, it has been demonstrated that PET using 18F-FMISO is suitable to localize and quantify hypoxia. But there isn't any optimal acquisition protocol or standardized images quantification treatment. Thus, the interpretation of [18F]-FMISO PET images and the predictive value of [18F]-FMISO SUV (Standardized Uptake Value) remain unclear explaining the need of methodological approaches.
This phase II trial is studying how well positron emission tomography (PET) scan using 18F-fluoromisonidazole works when given together with magnetic resonance imaging (MRI) ) in assessing tumor hypoxia in patients with newly diagnosed glioblastoma multiforme (GBM). Diagnostic procedures, such as MRI and PET scan using 18F-fluoromisonidazole (FMISO), may help predict the response of the tumor to the treatment and allow doctors to plan better treatment.