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Browse 1,242 clinical trials for brain cancer. Find studies that match your criteria and connect with research centers.
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NCT05635734
This is an open label study to determine the safety and preliminary evidence of a therapeutic effect of azeliragon in patients with newly diagnosed glioblastoma receiving concurrent radiation and temozolomide.
NCT07390539
The purpose of this research study is to test the safety and effectiveness of a cell therapy at different doses for children and young adults with recurrent or progressive brain tumors. Recurrent/recurred means a tumor that has gone away and then came back. This cell therapy is called B7- H3.CD28Z.CART, referred to as B7-H3 CAR T cells. B7-H3 is a protein that is over-expressed on many tumor cells, making it a good target for cancer cell therapy. The names of the study investigational therapies involved in this study are: * Fludarabine (a type of chemotherapy) * Cyclophosphamide (a type of chemotherapy) * B7-H3 CAR T cells (a type of cellular therapy)
NCT01535911
This study will look at the effects, good and/or bad, of treating primary brain cancers with diet therapy using an energy restricted ketogenic diet (ERKD) that uses food. An energy restricted ketogenic diet is a diet designed to keep blood sugars in the low range of normal while at the same time increasing the blood concentration of metabolic break down products called ketones. This diet is currently used to treat children with uncontrollable seizures. This diet is well tolerated by the children with minimal side effects reported after using the diet for years. * The main purpose of this study is to find out whether or not the energy restricted ketogenic diet will help patients with primary brain cancer by either decreasing the size of the cancer or by keeping the cancer from growing. * Another reason for doing this study is to learn about the side effects associated with the energy restricted ketogenic diet in patients with primary brain cancer.
NCT07391215
The purpose of this clinical trial is to evaluate the safety and tolerability of paxalisib in combination with temozolomide and to determine the preliminary antitumour activity of the combination therapy. In the Phase 1b of this study parallel biomarker defined arms will be opened in the front-line unmethylated MGMT setting, enrolling 10 patients onto each arm. These patients will be treated with paxalisib in combination with temozolomide (TMZ). The starting dose of paxalisib will be 45mg once a day (OD) with the option of increasing to 60 mg (30 mg BD) in Cycle 2. TMZ will be administered once daily by mouth on days 1 to 5 in a 28-day cycle, with a starting dose of 150mg/m2 during cycles 1 and 2, and subsequent dose escalation to 200mg/m2 at the start of cycle 3 if cycles 1 and 2 have been well tolerated with no significant toxicity.
NCT07050836
This study plans to learn more about using contrast enhanced ultrasound (CEUS) in brain tumor surgery. The goal of glioma brain tumor surgery is to remove as much of the glioma as possible. Tumor tissue that is close to normal brain tissue can look very similar. This can make it difficult for the surgeon to remove all the tumor. In this study, we hope to learn if using CEUS during brain tumor surgery will allow the brain surgeon to better see and remove all the tumor tissue.
NCT04923126
This is an open-label, multi-center, Phase 1/2 study of the brain-penetrant MEK inhibitor, mirdametinib (PD-0325901), in patients with pediatric low-grade glioma (pLGG).
NCT05756985
To collect and preserve glioblastoma tissue during standard of care tumor resection surgery and blood for future molecular and genetic testing. Tissue for research will be collected from three different regions within the same tumor to study how these regions differ in their structure, DNA, and RNA and also to compare the data obtained from this testing to imaging data found in the medical record. The goal of this study is to help us better understand what the glioblastoma tumor tissue looks like and how it functions. This understanding can lead to new therapies for the treatment of glioblastoma in the future.
NCT05733312
This study seeks to determine the impact of focused ultrasound (FUS) on the composition of the tumor extracellular microenvironment. Researchers will evaluate regions that are very abnormal, as well as regions that have less evidence of disease. A sub-portion of each of these areas will be targeted by focused ultrasound. Microdialysis catheters will then be placd into each region that has and has not been exposed to FUS (total of 4 catheters) to determine how FUS impacts the the brain and tumor extracellular metabolome, including concentration of routine drugs systemically administered prior to, and during surgery. Researchers hope that this information will help reveal the relative contribution of blood-derived compounds to the tumor microenvironment. If successful, microdialysis could be leveraged in the future to simultaneously evaluate pharmacokinetic and pharmacodynamic impacts of future candidate therapies, including those delivered with the aid of FUS.
NCT07338526
Children diagnosed with benign or low-grade brain tumors often require radiation therapy to control their disease. While radiation can be effective, traditional techniques using X-rays (photon-based radiotherapy) expose healthy brain tissue to radiation, potentially leading to long-term side effects like memory loss, learning difficulties, hormone imbalances, hearing problems, and a higher risk of secondary cancers. This study, called the IMPORT Trial, aims to compare two types of radiation therapy-Intensity-Modulated Proton Therapy (IMPT) and Intensity-Modulated Radiation Therapy (IMRT)-to determine which is safer and more effective for children. IMPT, a newer technique, uses protons instead of X-rays to deliver radiation, reducing exposure to healthy brain tissue. Researchers believe this could help minimize long-term damage while maintaining effective tumor control. What is the goal of the study? The primary goal is to see if IMPT leads to better survival with fewer side effects compared to IMRT. The study will track how well children function over five years, looking at: * Cognitive abilities (memory, attention, learning) * Hormonal balance (pituitary gland function) * Hearing ability * Overall survival without significant decline in quality of life How will the study work? * Who can join? Children aged 6 to 16 years diagnosed with certain types of benign or low-grade brain tumors. * How are patients treated? Patients will be randomly assigned to receive either IMRT or IMPT. * What is analysed? Doctors will track survival, tumor control, cognitive function, endocrine health, and quality of life over time. * How long will it take? The study will last 10 years (5 years to enroll patients, 5 years to follow up). Proton therapy is more expensive and not widely available, so strong scientific evidence is needed to justify its use in routine treatment. If IMPT significantly improves quality of life and survival, it could become the preferred treatment, shaping future policies and making proton therapy more accessible for children who need it.
NCT04702581
Because of their prolonged survival, patients with 1p/19q-codeleted low-grade oligodendrogliomas treated with RT + PCV are at risk of neurocognitive deterioration. We make the hypothesis that withholding radiotherapy until tumor progression could reduce the risk of neurocognitive deterioration without impairing overall survival.
NCT02721732
This phase II trial studies how well pembrolizumab works in treating patients with rare tumors that cannot be removed by surgery or have spread to other parts of the body. Monoclonal antibodies, such as pembrolizumab, may block specific proteins found on white blood cells which may strengthen the immune system and control tumor growth.
NCT06057168
This trial aimed to study the performance of Elucirem (gadopiclenol) in Dynamic Susceptibility Contrast Magnetic Resonance Imaging (DSC-MRI) perfusion of brain gliomas.
NCT05762419
The blood brain barrier (BBB) prevents some drugs from successfully reaching the target tumor. Focused Ultrasound (FUS) using microbubbles and neuro-navigator controlled sonication is a non-invasive method of temporarily opening up the blood brain barrier to allow a greater concentration of the drug to reach into the brain tumor. This may improve response and may also reduce system side effects in the patient. The primary purpose of this study is to evaluate the feasibility of safely opening the blood brain barrier in children with progressive diffuse midline gliomas (DMG) treated with oral etoposide using focused ultrasound with microbubbles and neuro-navigator-controlled sonication. For the purpose of the study, the investigators will be opening up the blood brain barrier temporarily in one or two locations around the tumor using the non-invasive focused ultrasound technology, and administrating oral etoposide in children with progressive diffuse midline glioma.
NCT07087002
This is a single-site, open-label Phase 1 clinical trial evaluating the feasibility, safety, and preliminary activity of autologous GPC2-targeted chimeric antigen receptor (CAR) T cells administered via intracerebroventricular (ICV) infusion in children and young adults with relapsed or refractory medulloblastoma or other eligible Central Nervous System (CNS) embryonal tumors.
NCT03251027
This phase II trial studies how well intensity-modulated stereotactic radiation therapy works in treating patients with grade II-IV glioma. Stereotactic radiosurgery is a specialized radiation therapy that delivers a single, high dose of radiation directly to the tumor and may cause less damage to normal tissue.
NCT04196413
The primary purpose of this study is to test whether CAR T cells targeting GD2 (GD2CART) can be successfully made and safely given to children and adults with H3K27M-mutant diffuse midline glioma (DMG). Eligible subjects may have DMG arising in the pons (called difuse intrinisic pontine glioma, DIPG), the spinal cord, or other areas of the brain such as a thalamus
NCT07025226
This early phase I trial tests the safety, side effects and how well medication combinations of dasatinib, quercetin, fisetin and temozolomide work in treating patients with glioma for which the patient has received treatment in the past (previously treated) and for tumor cells that remain after attempts to treat the tumor have been made (residual disease). Dasatinib is in a class of medications called tyrosine kinase inhibitors. It works by blocking the action of an abnormal protein that signals tumor cells to multiply, which may help keep tumor cells from growing. Quercetin and fisetin are compounds found in plants. They have antioxidant and anti-inflammatory properties and help remove senescent cells, older or damaged cells that have stopped dividing but don't die off as they should and build up in tissues over time. Senescent cells may cause inflammation or damage to nearby healthy cells. Temozolomide is in a class of medications called alkylating agents. It works by damaging the cell's deoxyribonucleic acid (DNA) and may kill tumor cells and slow down or stop tumor growth. Giving medication combinations of dasatinib, quercetin, fisetin and temozolomide may be safe, tolerable and/or effective in treating patients with previously treated glioma with residual disease.
NCT07365280
This is a multicenter, open-label, randomized Phase II clinical study designed to evaluate the efficacy and safety of a personalized dendritic cell (DC) vaccine, ZSNeo-DC1.1, in combination with temozolomide (TMZ) as adjuvant therapy in patients with newly diagnosed glioblastoma (GBM). Eligible patients with histologically confirmed, IDH1/IDH2 wild-type newly diagnosed glioblastoma who have undergone tumor debulking surgery followed by standard concurrent chemoradiotherapy will be enrolled. After confirmation of tumor neoantigens and eligibility, patients will be randomized in a 1:1 ratio to receive either ZSNeo-DC1.1 in combination with TMZ or TMZ alone. The primary objective is to evaluate progression-free survival (PFS) as assessed by an Independent Radiological Review Committee (IRRC) according to RANO 2.0 criteria. Secondary objectives include overall survival (OS), survival rates, tumor response outcomes, and safety. Exploratory objectives include assessment of antigen-specific T-cell immune responses induced by ZSNeo-DC1.1.
NCT05556473
Imaging procedures such as 1-(2-\[18F\]FLUOROETHYL)-L-Tryptophan PET/CT in patients with cancers may help doctors assess a patient's response to treatment and help plan the best treatment in the future. The purpose is to see if there can be a better differentiation of tumor and non-tumor tissue where the tumor tissue has a higher uptake of Tryptophan.
NCT04216329
Background: Glioblastoma is a type of brain cancer. Treatments include radiation, chemotherapy, and surgery. But survival rates are poor. Researchers think that the drug selinexor, when combined with chemotherapy and radiation, might help. Objective: To learn the highest dose of selinexor that people with brain cancer can tolerate when given with temozolomide and radiation therapy. Eligibility: People ages 18 and older with brain cancer that has not been treated with chemotherapy or radiation. Design: Participants will be screened under another protocol. Before participants start treatment, they will have tests: Neurological and physical evaluations Blood and urine tests Possible computed tomography (CT) scan or magnetic resonance imaging (MRI) of the brain if they have not had one in 3 weeks. Participants will lie in a machine that takes pictures of the body. They may have a dye injected into a vein. Surveys about their well-being Participants will have radiation to the brain for up to 6 weeks. This will usually be given once a day, Monday through Friday. Starting the second day of radiation, participants will take selinexor by mouth once a week. They will take it in weeks 1, 2, 4, and 5. The timing may be changed. Starting the first day of radiation, participants will take temozolomide by mouth once a day until they complete radiation. Participants will have blood tests once per week during treatment. Participants will have a follow-up visit 1 month after they complete treatment. Then they will have visits at least every 2 months for the first 2 years, then at least every 3 months for another year. Visits will include MRIs and blood tests.
