View clinical trials related to Glioma.
Filter by:Glioblastoma is recognized as the most common and aggressive form of primary malignant brain tumor, with treatment options that are limited and prognosis that is extremely poor, showing median progression-free survival of 12 months and median overall survival of less than 18 months. Surgical resection plays a critical role in the treatment, with the extent of resection significantly impacting patient outcomes. Historical approaches to surgical resection have evolved, moving from radical strategies to more conservative ones that aim to preserve normal brain function while removing the tumor as completely as possible. Recent studies have suggested that increasing the extent of surgical resection, particularly along the T2 FLAIR border rather than the traditional T1-enhanced border, can significantly improve patient prognosis. There is, however, a lack of consensus on the optimal surgical approach, and the heterogeneity of tumors presents challenges in standardizing surgical strategies. Extended resection has been shown to prolong survival, and novel intraoperative molecular diagnostics have emerged to improve accuracy in tumor classification and prognosis. Building on these advancements, a multicenter, prospective, randomized controlled trial is proposed to evaluate the efficacy of sub-lobectomy in treating IDH wild-type/TERTp-mutant glioblastoma, aiming to improve evidence levels and establish standardized surgical practices for this devastating disease.
The goal of this clinical investigation of a medical device is to test the safety of graphene based electrodes when used during surgery for resection of brain tumors. The main questions that it aims to answer are: - To understand the safety of these new electrodes when used during brain tumor surgery (primary objective); - To assess the quality of the brain signals recorded with the new electrodes, their ability to stimulate the brain, how stable their function is over the duration of an operation, and their suitability for use in the operating theatre (secondary objectives). Participants will undergo tumor surgery as usual with the study electrodes being tested alongside a standard monitoring system. If they are awake for part of their surgery they may be asked to complete specific tasks such as naming objects from a list modified for the study. They will be monitored subsequently for any complications including undergoing an additional MRI scan 6 weeks after their surgery.
This is an open label, Phase 1b safety, dose-finding, brain tumor delivery, and pharmacokinetics study of intranasal NEO100 in patients with pediatric-type diffuse high grade gliomas. Patients will receive IN NEO100 that will follow a dose titration design, followed by a standard dose escalation design to establish safety. Brain tumor delivery of NEO100 will be confirmed in each disease sub-type by surgical resection/needle biopsy only if clinically indicated and scheduled for clinical purposes and testing with residual tissue for NEO100 and the major metabolite of NEO100 (Perillic Acid).
Background: Glioblastoma (GBM) is a cancer of the brain. Current survival rates for people with GBM are poor; survival ranges from 5.2 months to 39 months. Most tumors come back within months or years after treatment, and when they do, they are worse: Overall survival drops to less than 10 months. No standard treatment exists for people whose GBM has returned after radiation therapy. Objective: To find a safe schedule for using radiation to treat GBM tumors that returned after initial radiation treatment. Eligibility: People aged 18 years and older with grade 4 GBM that returned after initial radiation treatment. Design: Participants will be screened. They will have a physical exam with blood tests. A sample of tumor tissue may be collected. Participants will undergo re-irradiation planning: They will wear a plastic mask over their head during imaging scans. These scans will pinpoint the exact location of the tumor. This spot will be the target of the radiation treatments. Participants will undergo radiation treatment 4 times per week. Some people will have this treatment for 3 weeks, some for 2 weeks, and some for 1 week. Blood tests and other exams will be repeated at each visit. Participants will complete questionnaires about their physical and mental health. They will answer these questions before starting radiation treatment; once a week during treatment; and at intervals for up to 3 years after treatment ends. Participants will have follow-up visits 1 month after treatment and then every 2 months for 6 months. Follow-up clinic visits will continue up to 3 years. Follow-ups by phone or email will continue an additional 2 years.
This phase I trial tests the safety and side effects, and best dose of a vaccine (neoantigen-target ppDC) in treating patients with H3 G34-mutant diffuse hemispheric glioma. Vaccines made from the patient's own white blood cells and peptide-pulsed dendritic cells may help the body build an effective immune response to kill tumor cells. Giving neoantigen-targeted ppDC may be safe, tolerable and/or effective in treating patients with diffuse hemispheric glioma with a H3 G34 mutation.
The goal of this study is to determine the response of the study drug loratinib in treating children who are newly diagnosed high-grade glioma with a fusion in ALK or ROS1. It will also evaluate the safety of lorlatinib when given with chemotherapy or after radiation therapy.
This will be a prospective, open-label, single-arm pilot study to investigate the safety and efficacy of Bevacizumab (BEV) in combination with microbubble (MB)-mediated FUS in patients with recurrent GBM. BEV represents the physician's best choice for the standard of care (SoC) in rGBM after previous treatment with surgery (if appropriate), standard radiotherapy with temozolomide chemotherapy, and with adjuvant temozolomide.
The treatment of adolescents and young adults (AYA, 15 to 39 years) with malignant intra-axial CNS parenchymal tumors such as IDH-mutated gliomas, medulloblastomas and ependymomas is still not curative in all cases. The tumor biology and clinical needs to diagnose and treat these tumors are comparable across all age groups, so an integrated treatment environment overseen by adult and pediatric neuro-oncology specialists seems promising to leverage synergisms and advance diagnostic and therapeutic development in these tumors. A comprehensive, prospective and integrated biomaterial and imaging-based pipeline for the multi-faceted evaluation of AYAs has not yet been established for AYA patients with brain tumors in Germany. Current diagnostic platforms neglect the integrative processing of data from MRI and FET-PET imaging, radiotherapy plans, tumor tissue, liquid biopsies and clinical data as well as prognostic markers. A prospective AYA pipeline can therefore enable a better understanding of the aforementioned high-risk CNS malignancies and promises clinical advances for AYA patients and the clinical and scientific research landscape.
The study evaluates safety, tolerability, pharmacokinetics at recommended phase II dose (RP2D) and preliminary antitumor activity of Niraparib + dd-TMZ "one week on, one week off" in patients affected by recurrent GBM IDH wild-type and recurrent IDH mutant (WHO grade 2-4) gliomas. The treatment will be administered until progressive disease, unacceptable toxicity, consent withdrawal, lost to follow-up or death. The entire study is expected to last approximately 40 months.
As a part of molecular imaging, many PET tracers have been investigated in this regard. Those include 18F-FDG being glucose analogue, 18F-FLT representing nucleoside metabolism, and 18F-FDOPA, 18F-FET, 11C-MET as amino acids analogues. Among these, 18F-FDG is the most commonly used tracer due to its broader use and easy availability. However, high physiological uptake in the brain is a significant limitation. The main limitation of other tracers is the need for onsite cyclotrons for their production, making their availability difficult. So, the search for an ideal modality is still ongoing, and the latest addition to this search is a radio ligand labeled Prostate Specific Membrane Antigen (PSMA). It is a new but potentially promising radiotracer, currently showing its utility in different malignancies. Investigators, therefore, aim to identify whether Ga-68 PSMA PET-CT has better diagnostic accuracy in the detection of recurrent gliomas than conventional imaging modalities.