View clinical trials related to Glioblastoma Multiforme.
Filter by:A Phase 1/2a Open Label Multicenter, Non-Randomized, Trial to Assess the Safety and Efficacy of CYNK-001 in Combination with Recombinant Human Interleukin-2 in Adults with Recurrent Resection Eligible IDH1 wild-type Glioblastoma. For phase I portion, the study objectives to assess the safety and feasibility CYNK-001 in combination with rhIL2 of Intravenous (IV) infusion and Intracavitary (IC) administrations following tumor resection and to establish a maximum tolerated dose (MTD) and a Recommended Phase 2a Dose (RP2D) for IV and IC CYNK-001 administration. For Phase IIa, to evaluate efficacy and safety of CYNK-001 administrations in recurrent GBM as measured by Progression Free Survival at 6 months (PFS6M)
Patients with a new diagnosis of high-grade glioma based on MRI, who are considered surgical candidates determined by neurosurgeons or patients with recurrent glioblastoma with the initial diagnosis of glioblastoma (histologic or molecular proof) and recommended for clinically surgical resection may be eligible for this study. Subjects may participate in this study if they are at least 18 years of age. Ferumoxytol-enhanced MRI will be used to quantify tumor-associated macrophages. This is a non-therapeutic trial in that imaging will not be used to direct treatment decisions. The blood draw is being completed to evaluate cell-free circulating tumor DNA (cfDNA) and cell-free tumor DNA (ctDNA).
The purpose of this pilot study is to evaluate the addition of carvedilol with standard of care treatment to determine if it will improve progression-free survival in the front line setting in patients with glioblastoma multiforme (GBM). In addition, monitoring of circulating tumor cells (CTCs) by a real-time reverse transcriptase polymerase chain reaction (qRT-PCR) assay to correlate with the clinical findings.
This clinical trial increases radiation to areas of the brain considered to be at risk for cancer. The at-risk areas are identified by a biological MRI scan. The study will look at side effects of the radiation and overall survival.
This pilot study aims to evaluate the feasibility of close glucose monitoring and management of patients (targeting fasting and pre-meal glucose of 4-7 mmol/L) using state-of-the-art flash glucose monitoring (FGM) technology. The glycemic intervention will be personalized based on individual blood glucose levels. Although the glycemic interventions used in this study include standard medications and methods of glucose monitoring used for patients with diabetes, this pilot study will specifically evaluate the feasibility of using these approaches in patients with GBM, appreciating their additional medical, functional and social challenges.
This study plans to learn more about if fluorescein with intraoperative Magnetic Resonance Imaging (MRI) is as good as intraoperative MRI (iMRI) alone in detecting the presence of tumor tissue during surgery. Both fluorescein and intraoperative MRI have been studied and routinely used to aid the neurosurgeon in distinguishing normal brain from tumor, helping the neurosurgeon to safely resect more tumor tissue during surgery. This study will enroll patients with malignant high grade glioma who are going to have a surgery to remove their brain tumor. For half of the patients, fluorescein and intraoperative MRI will be used together during surgery. For half of the patients, only intraoperative MRI will be used during surgery. iMRI is used as final verification of complete, safe resection in both arms.
Patients with a high grade glioma have an increasing overall survival and progression free survival after initial treatment. Because of a better performance status these patients are more often eligible for re-treatment with for example radiotherapy. However, to date only a few prospective studies on re-irradiation of gliomas exist and very little is known about the effects of re-irradiation on quality of life and cognition. This trial is designed to longitudinally establish the effects of re-irradiation on quality of life, cognition and physical performance in patients with a high grade glioma. Based on the currently available information the investigators hypothesize that quality of life after re-irradiation can be kept stable until further tumour progression.
High-grade gliomas are the commonest primary malignant brain tumours in adults, affecting approximately 5000 people per year in the UK. Standard treatment comprises a combination of surgery, radiotherapy and chemotherapy; however this condition remains incurable and the average survival is approximately 18 months from diagnosis. There are a number of reasons for this. Firstly these tumours are highly invasive and involve important areas of brain making it impossible to remove them surgically or cure them with radiotherapy. In the majority of cases the tumour recurs within 2 to 3cm of the original site of tumour removal. Secondly, due to the presence of a barrier between the bloodstream and the brain, when drugs designed to kill tumour cells (chemotherapy) are given intravenously or orally, they frequently do not reach the tumour at a sufficient dose to have a beneficial effect. As the chemotherapy dose has to be very high for a sufficient dose to reach the tumour, drug-related side-effects are common. Laboratory studies demonstrate that glioma tumour cells are sensitive to a number of different chemotherapies, including carboplatin. When given intravenously however, carboplatin does not reach a sufficient concentration in the tumour to have a beneficial effect. However, studies have shown that carboplatin can be infused directly into the brain at a concentration that is highly toxic to tumour cells, but not to normal brain tissue. Using very small tubes implanted around the tumour, the investigators are able to infuse carboplatin reliably and repeatedly into the area where tumours typical recur. In this study, the investigators intend to evaluate the safety of this approach and determine the optimal dose of carboplatin to administer. It is hoped that this study will also provide evidence of improved survival for patients with high-grade glioma.
Purpose and Objective: 1. To compare the effects of either an abbreviated or protracted taper of dexamethasone on functional capacity in newly diagnosed glioblastoma multiforme (GBM) patients. 2. To compare neurocognitive function in newly diagnosed GBM patients receiving either an abbreviated or protracted taper of dexamethasone. 3. To compare skeletal muscle strength in newly diagnosed GBM patients receiving either an abbreviated or protracted taper of dexamethasone. 4. To examine the association between functional capacity and neurocognitive function and patient-reported measures (i.e. quality of life, fatigue, etc.) in newly diagnosed GBM patient on either an abbreviated or protracted taper of dexamethasone. 5. To examine the association between functional capacity and neurocognitive function and body composition measures (body-mass index, etc.) in newly diagnosed GBM patient on either an abbreviated or protracted taper of dexamethasone. 6. To examine the association between functional capacity and neurocognitive function and biochemical metabolic measurements in newly diagnosed GBM patient on either an abbreviated or protracted taper of dexamethasone. All study endpoints will be assessed at three timepoints as follows: (1) initial assessment after surgery in the hospital, (2) second assessment at initial clinical visit at the Preston Robert Tisch Brain Tumor Center (PRT-BTC) at Duke, approximately 1 week post-operatively, and (3) third assessment at second clinical visit in the PRT-BTC at Duke, approximately 10 weeks post-operatively and after completion of radiotherapy. An additional fourth assessment will be obtained at 4 weeks post-operatively if the subject is undergoing radiotherapy here at Duke.
Background: - Children with brain tumors often have magnetic resonance imaging (MRI) scans to see if the tumor has responded to therapy or to see if the tumor has grown. Sometimes, it is difficult to tell if the scan is abnormal because of tumor size or shape, swelling, scar tissue, or dead tissue. Because brain tumor biopsies require surgery, researchers are looking for more noninvasive ways of evaluating brain tumors. - Positron emission tomography (PET) scans use a radioactive sugar known as 18F-FDG to try to determine if a tumor is active or not. Active tumors generally take up more sugar than the surrounding tissue, but because normal brain tissue uses the same sugar as brain tumors, it is then difficult to tell if tumor tissue is taking up sugar or not. A different radioactive agent, 18F-FLT, is now being studied in some adults with different kinds of tumors. Researchers are interested in determining whether it is possible to use this agent as a marker of tumor activity in children. Objectives: - To determine the safety and effectiveness of 18F-FLT for pediatric glioma scans. - To compare the results of 18F-FLT studies with studies using the radioactive agents 18F-FDG and 1H-MRSI. Eligibility: - Children less than 18 years of age who are having radiation therapy to treat malignant gliomas. Design: - Participants will have scanning tests before radiation therapy, 1 to 3 weeks after radiation therapy, and if researchers suspect that the tumor is growing. - This study will involve three separate imaging tests (1H-MRSI, 18F-FDG PET, and 18F-FLT PET). - Proton spectroscopy (1H-MRSI) is a procedure that is similar to MRI and is performed in the same scanner as an MRI. Because this scan is long (2-3 hours), most children will receive medications from an anesthesiologist so that they can sleep through the procedure. - Within 2 weeks of the 1H-MRSI scan, participants will have the PET scans with both the standard contrast agent (18F-FDG) and the experimental agent (18F-FLT). These scans will last approximately 1 hour each.