Active clinical trials for "Glioblastoma"

This phase II trial studies how well fluorodopa F 18-positron emission tomography/magnetic resonance imaging scan (18F-DOPA-PET/MRI) works in imaging elderly patients with newly diagnosed grade IV malignant glioma or glioblastoma during planning for a short course of proton beam radiation therapy. 18F-DOPA is a chemical tracer that highlights certain cells during imaging. PET scan, is a metabolic imaging technique which takes advantage of how tumor cells take up nutrients differently than normal tissue. MRI scans are used to guide radiation therapy for most brain tumors. Hypofractionated proton beam therapy delivers higher doses of radiation therapy over a shorter period of time and may kill more tumor cells and have fewer side effects. Using 18FDOPA-PET scans along with MRI scans may be able to provide the radiation doctor with information on tumor tissue versus normal, healthy tissue and may help the doctor more accurately plan the radiation treatment.

This randomized phase II trial studies how well cediranib maleate and olaparib work compared to bevacizumab in treating patients with glioblastoma that has come back (recurrent). Cediranib maleate and olaparib may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth. Immunotherapy with monoclonal antibodies, such as bevacizumab, may help the body's immune system attack the cancer, and may interfere with the ability of tumor cells to grow and spread.

The purpose of this Phase 2, open-label, single-arm study is to determine the safety and the maximal tolerated dose (MTD) of VAL-083 in combination with a standard of care radiation regimen when used to treat newly diagnosed GBM in patients with unmethylated promoter of the methylguanine-DNA methyltransferase (uMGMT) gene. Pharmacokinetic (PK) properties will be explored and tumor responses to treatment will be evaluated.

Safety of combination of ibrutinib and radiation at various dose levels in unmethylated o6-methylguanine-DNA-methyltransferase (MGMT) glioblastoma and study of ibrutinib, temozolomide, and radiation combination therapy in methylated MGMT glioblastoma.

This is a phase I trial using EGFR Bi-armed Activated T-cells (BATs) in combination with standard of care temozolomide (TMZ) and radiation (RT) in patients with glioblastoma (GBM). The purpose of the study is to determine a safe dose of EGFR BATs when given with standard of care therapy.

The purpose of this study is to use precision medicine in the form of a vaccine, a mutation-derived tumor antigen vaccine (MTA-based vaccine) in combination with standard care treatment of glioblastoma (GBM) and Tumor Treating Fields (TTFields). The study is designed to determine whether this treatment combination is well tolerated and safe.

This protocol has a 2-part design: This phase 2 study is an open-label, multicenter, dose-escalation and expansion study to assess the safety, tolerability, recommended phase 2 dose (RP2D), pharmacokinetics (PK) and clinical activity of paxalisib in patients with newly-diagnosed glioblastoma (GBM) with unmethylated MGMT promoter status as adjuvant therapy following surgical resection and initial chemoradiation with temozolomide (TMZ).

Approximately 90% of children with malignant brain tumors that have recurred or relapsed after receiving conventional therapy will die of disease. Despite this terrible and frustrating outcome, continued treatment of this population remains fundamental to improving cure rates. Studying this relapsed population will help unearth clues to why conventional therapy fails and how cancers continue to resist modern advances. Moreover, improvements in the treatment of this relapsed population will lead to improvements in upfront therapy and reduce the chance of relapse for all. Novel therapy and, more importantly, novel approaches are sorely needed. This trial proposes a new approach that evaluates rational combination therapies of novel agents based on tumor type and molecular characteristics of these diseases. The investigators hypothesize that the use of two predictably active drugs (a doublet) will increase the chance of clinical efficacy. The purpose of this trial is to perform a limited dose escalation study of multiple doublets to evaluate the safety and tolerability of these combinations followed by a small expansion cohort to detect preliminary efficacy. In addition, a more extensive and robust molecular analysis of all the participant samples will be performed as part of the trial such that we can refine the molecular classification and better inform on potential response to therapy. In this manner the tolerability of combinations can be evaluated on a small but relevant population and the chance of detecting antitumor activity is potentially increased. Furthermore, the goal of the complementary molecular characterization will be to eventually match the therapy with better predictive biomarkers. PRIMARY OBJECTIVES: To determine the safety and tolerability and estimate the maximum tolerated dose/recommended phase 2 dose (MTD/RP2D) of combination treatment by stratum. To characterize the pharmacokinetics of combination treatment by stratum. SECONDARY OBJECTIVE: To estimate the rate and duration of objective response and progression free survival (PFS) by stratum.

In this study, the investigators propose to combine retifanlimab with radiation therapy (RT) and bevacizumab with or without epacadostat in the treatment of recurrent glioblastoma (GBM). The investigators hypothesize that this combination provides a powerful synergy between RT and immune modulators to produce more robust anti-tumor immune response, induce tumor regression and improve overall survival.

The purpose of this study is to test how well the drug works, safety and tolerability of an investigational drug called Ruxolitinib in gliomas and glioblastomas, when combined with standard treatment for brain cancer, temozolomide and radiation. Ruxolitinib is an experimental drug that works by targeting proteins in cells and stops them from growing. Ruxolitinib is experimental because it is not approved by the Food and Drug Administration (FDA) for the treatment of gliomas or glioblastomas Temozolomide works by damaging the DNA of tumor cells so that they cannot divide properly. Some tumor cells can repair that damage and therefore be resistant to temozolomide.