View clinical trials related to Glioma.
Filter by:Patients will receive a vaccine called SurVaxM on this study. While vaccines are usually thought of as ways to prevent diseases, vaccines can also be used to treat cancer. SurVaxM is designed to tell the body's immune system to look for tumor cells that express a protein called survivin and destroy them. The survivin protein can be found on up to 95% of glioblastomas and other types of cancer but is not found in normal cells. If the body's immune system knows to destroy cells that express survivin, it may help to control tumor growth and recurrence. SurVaxM will be mixed with Montanide ISA 51 before it is given. Montanide ISA 51 is an ingredient that helps create a stronger immune response in people, which helps the vaccine work better. This study has two phases: Priming and Maintenance. During the Priming Phase, patients will get one dose of SurVaxM combined with Montanide ISA 51 through a subcutaneous injection (a shot under the skin) at the start of the study and every 2 weeks for 6 weeks (for a total of 4 doses). At the same time that patients get the SurVaxM/Montanide ISA 51 injection, they will also get a second subcutaneous injection of a medicine called sargramostim. Sargramostim is given close to the SurVaxM//Montanide ISA 51 injection and works to stimulate the immune system to help the SurVaxM/Montanide ISA 51 work more effectively. If a patient completes the Priming Phase without severe side effects and his or her disease stays the same or improves, he or she can continue to the Maintenance Phase. During the Maintenance Phase, the patient will get a SurVaxM/Montanide ISA 51 dose along with a sargramostim dose about every 8 weeks for up to two years. After a patient finishes the study treatment, the doctor and study team will continue to follow his/her condition and watch for side effects up to 3 years following the last dose of SurVaxM/Montanide ISA 51. Patients will be seen in clinic every 3 months during the follow-up period.
Neurocognitive decline after radiation therapy is one of the most concerning complication for brain tumor patients and neuro-oncologists. There are increasing technological advances in evaluating the brain's neural connections responsible for the neurocognitive processes. For example, resting-state functional MRI (RS-fMRI) is an advanced imaging method that can identify the spatiotemporal distribution of the intrinsic functional networks within the brain (also referred to as resting state networks (RSNs) without requiring specific tasks by the imaged participants. Although there is evidence that shows that avoidance of specific neural networks during radiation therapy planning can lead to improved preservation of neurocognitive function afterward, it is important to first identify the most vulnerable and clinically relevant RSNs that correspond to cognitive decline. In this study, the investigators will prospectively perform RS-fMRI and neurocognitive evaluation using the NIH Toolbox Cognitive Battery (NIHTB-CB) on patients with gliomas before and after radiation therapy to generate preliminary data on what RSNs are most vulnerable to radiation injury leading to cognitive decline. A benign brain tumor cohort will also be followed to serve as control. The investigators will also evaluate the feasibility of incorporating RS-fMRI with radiation planning software for treatment optimization.
Patient education plays an essential role in patient-centered care as it enhances patient satisfaction and information comprehension. However, about 40-80% of the information patients receive from healthcare professionals is forgotten and about half of the information patients remember is incorrect. To give informed consent, patients must be able to understand and recall the discussed information correctly. This is especially important in brain tumor patients, in which different treatment options determine outcome and risks. The goal of treatment in brain tumors is resection as completely as possible, without damaging healthy brain tissue. To this end, patients must understand the complex relation of the tumor to healthy brain tissue. This relation is different in each patient and three-dimensional (3D) in nature. Current two-dimensional visual tools lack the ability to properly display these complex 3D relations. In this study, we will investigate the effect of the use of 3D models in patient education, taking into account patient specific factors that might act as confounders. We will conduct a case control, multi-center study in the Radboud University Medical Center (Radboudumc) Maastricht University Medical Center (MUMC). Patients will be enrolled in the control group until inclusion for the control group is completed (n=30), after which patients will be enrolled in the intervention group (n=30). Patients will be cognitively tested using the Amsterdam Cognition Scale (ACS). After the consultation with their neurosurgeon, patients will be asked to fill out two questionnaires, consisting of two parts (patient experiences and information recall), one week apart.
The prognostic value of ANXA2 expression in tumor tissue and PTBE was analyzed, so as to seek new therapies to inhibit glioma invasion and improve the prognosis of glioma patients
Tailored approaches targeting crucial oncogenes and pathways have shown successful results in a number of cancer types and offer exciting perspective in neuro-oncology. IDH (Isocitrate dehydrogenase) wild-type (IDHwt) glioblastoma (GBM) (10%) present a unique and homogenous energetic metabolism which is specifically dependent on the oxidative phosphorylation (OXPHOS) rather than on the aerobic glycolysis. OXPHOS+ IDHwt GBMs overexpress mitochondrial markers and can be specifically inhibited by mitochondrial inhibitors in vitro and in vivo. Metformin is an oral inhibitor of mitochondrial complex I and is a widely used drug in diabetic and non-diabetic patients, safe and well tolerated in association with radiotherapy and chemotherapy. Basing on drastic effect, the investigators have observed in vivo (reduction of >50% of tumor growth) and hypothesize that metformin could be specifically efficient to treat up-front patients affected by OXPHOS+ GBM, in association with the standard first-line treatment with radiotherapy and temozolomide (RT-TMZ). The investigators set up a dedicated molecular analysis including RNA assay and expression of OXPHOS markers for formalin-fixed paraffin-embedded tumors (FFPE), which allows to detect OXPHOS+ GBM at diagnosis. Here a phase II, open label, non-randomized multicenter trial including five French neurooncology centers (H. Foch-Suresnes, Pitié-Salpêtrière-Paris, Saint Louis-Paris, Lyon, Marseille) and one in Italy (Istituto Besta, Milan) is proposed. Newly diagnosed IDH wild-type GBM patients with the OXPHOS+ signature will be eligible for inclusion in this trial. The investigators expect to screen 640 patients and to include 64 patients over a period of 24 months with 24 months of follow-up.
This study is to investigate the safety and efficacy of tumor infiltrating lymphocyte (TIL) therapy in patients with malignant glioma . Autologous TILs are expanded from tumor resections and infused i.v. into the patient after NMA lymphodepletion treatment with hydroxychloroquine(600mg,single-dose) and cyclophosphamide.
This is a phase I, open label, plus expansion clinical trial evaluating the safety and tolerability of rHSC-DIPGVax in combination with BALSTILIMAB and ZALIFRELIMAB. rHSC-DIPGVax is an off-the-shelf neo-antigen heat shock protein containing 16 peptides reflecting neo-epitopes found in the majority of DIPG and DMG tumors. Newly diagnosed patients with DIPG and DMG who have completed radiation six to ten weeks prior to enrollment are eligible.
A single-arm, single-center, open-labeled study will be conducted with an aim to investigate the feasibility, safety, and efficacy of the personalized vaccine for patients with recurrent malignant glioma.
This Phase 0 surgical window of opportunity trial seeks to evaluate the pharmacokinetic (PK) and pharmacodynamic (PD) properties of an FDA-approved proprotein convertase/ kexin type 9 serine protease inhibitor (PCSK9i) in patients with primary and recurrent World Health Organization (WHO) grade IV malignant glioma. The investigators intend to evaluate whether a clinically licensed PCSK9i called evolocumab (also known as Repatha) can be repurposed as a potential immunotherapeutic for high grade glioma by testing its ability to access the intracranial space. The primary objective is to evaluate whether evolocumab crosses the blood brain barrier (BBB) and is measurable in the resected tumor specimens of patients with primary and recurrent high grade glioma or glioblastoma.
Fluorescence-guided resection using 5-ALA induced tumor fluorescence of malignant gliomas allows for better identification of tumor tissue and more radical resection in select patients and improvements in progression-free and overall survival. With new developments in surgical microscopy, the development of digital exoscopes have provided advanced visualization as well as improvements in ergonomics and accessibility of the surgical field. The use of the exoscope in 5-ALA fluorescence-guided tumor surgery has the potential to enhance the ability of the surgeon to remove brain tumors with high efficacy. While algorithms for use of 5-ALA fluorescence have been optimized for use with traditional microscopes, the use of fluorescence techniques in newer digital exoscopes have not been developed. The primary outcome of the study is to obtain parameters to optimize visualization of fluorescence intensity and perform optimization based on the intensities achieved. The operating ORBEYE exoscope will be fitted with a blue light filter. All experiments will be performed in darkened operating rooms. The ORBEYE exoscope will be set up at constant distances from the target and incident light intensities. The focal distance and light intensity settings will be recorded from the data displayed on the microscope. Patients (experimental group) will receive 5ALA treatment before operation, blue light filter imagining will take place after tacking up dura and prior to direct resection. The expected outcomes of image analysis will be to have a set of exoscope parameters optimized for visualization of 5ALA tissue in different tumor types. This 5ALA characterization of visualization parameters has never been completed on an exoscope. Optimizing ORBEYE exoscope parameters will define a standard in glioma resection using 5ALA under a novel exoscopic filter as well as contribute insight into the use of the fluorescent filter for additional tumor types.