Active clinical trials for "Glioblastoma"

This is a study of drug KB004 in patients with recurrent glioblastoma (GBM). Eligible patients with measurable tumours will receive an initial trace (5mg) dose of zirconium labelled KB004 (89ZrKB004) on day 1 followed by sequential Positron emission tomography (PET) imaging over 1 week to determine its biodistribution into GBM and normal tissues. Safety assessments and pharmacokinetic (movement of drug) sampling will also be undertaken over this time. On Day 8, patients commence weekly KB004 infusions over 2 hours with standard premedications. Three cohorts are planned in this study (3.5mg/kg, 5.25 mg/kg, 7.9 mg/kg; additional dose levels may be explored based on toxicity, efficacy and biodistribution data as determined by the safety monitoring committee). On day 36, patients receive both 89ZrKB004 and KB004, allowing assessment of receptor occupancy to guide recommended phase two dose (RPTD) determination. Response rate (RANO) and survival data will be collected and patients benefiting may continue KB004 treatment until disease progression. Primary objective: to determine the toxicity and recommended phase two dose (RPTD) of KB004 in patients with advanced Glioblastoma (GBM). Secondary objectives: to determine the biodistribution and pharmacokinetics of 89ZrKB004; to determine frequency of EphA3 (ephrin receptor A3) positive glioblastoma in archival specimens and by 89ZrKB004 scans, and correlate with known biomarkers; to describe response rates per RANO criteria (Response Assessment in Neuro-Oncology Criteria) and pharmacodynamics following KB004 infusion; Exploratory objectives: to perform exploratory analysis between clinical outcomes and biodistribution/Pharmacokinetics (PK)/pharmacodynamics (PD) data, including from matched biopsies.

In this research study, we want to learn about the safety of the study drugs, ribociclib and everolimus, when given together at different doses after radiation therapy. We also want to learn about the effects, if any, these drugs have on children and young adults with brain tumors. We are asking people to be in this research study who have been diagnosed with a high grade glioma, their tumor has been screened for the Rb1 protein, and they have recently finished radiation therapy. If a patient has DIPG or a Bi-thalamic high grade glioma, they do not need to have the tumor tissue screened for the Rb1 protein, but do need to have finished radiation therapy. Tumor cells grow and divide quickly. In normal cells, there are proteins that control how fast cells grow but in cancer cells these proteins no longer work correctly making tumor cells grow quickly. Both study drugs work in different ways to slow down the growth of tumor cells. The researchers think that if the study drugs are given together soon after radiation therapy, it may help improve the effect of the radiation in stopping or slowing down tumor growth. The study drugs, ribociclib and everolimus, have been approved by the United States Food and Drug Administration (FDA). Ribociclib is approved to treat adults with breast cancer and everolimus is approved for use in adults and children who have other types of cancers. The combination of ribociclib and everolimus has not been tested in children or in people with brain tumors and is considered investigational. The goals of this study are: Find the safest dose of ribociclib and everolimus that can be given together after radiation. Learn the side effects (both good and bad) the study drugs have on the body and tumor. Measure the levels of study drug in the blood over time. Study the changes in the endocrine system that may be caused by the tumor, surgery or radiation.

Background: Glioblastoma (GBM) brain tumors almost always return after treatment. When that happens the tumor can never completely be removed by surgery, so most people also receive drugs. Researchers want to see if combining the drugs nivolumab and BMS-986016 may help. Objectives: To study how nivolumab affects the brain s immune system in people who have had glioblastoma brain tumors return. To study how nivolumab and BMS-986016 affect brain tumors. Eligibility: Adults age 18 and older who have had a return of GBM Design: Participants will be screened with: Medical history Physical exam Cheek swab Heart, blood and urine tests Chest x-ray Magnetic resonance imaging (MRI) brain scan. Participants will lie on a table that slides in and out of a cylinder in a strong magnetic field. A contrast agent will be injected in an arm vein. Participants will stay in the hospital. They will: Have surgery. A tube will be inserted into the back. Brain tumor and bone marrow samples will be taken. Tubes will be inserted into the brain. Have a computed tomography brain scan. Stay in Intensive Care (ICU) 7 days. Fluid from the brain and back will be collected every few hours. In the ICU, participants will get nivolumab by IV for 30 minutes. Have surgery to remove the tubes. Have standard surgery to remove as much of the GBM as possible. Bone marrow will be removed. After leaving the hospital, participants will have visits every 2 weeks to get the study drugs by IV and have physical exams and blood tests. Participants will have a brain MRI once a month. ...

The purpose of this research study is to test the safety and tolerability of the combination treatment of the investigational drugs vorinostat and pembrolizumab, in combination with chemotherapy (temozolomide), and radiotherapy. The U.S. Food and Drug Administration (FDA) has approved pembrolizumab for use to treat a deadly skin cancer called melanoma and lung cancer and vorinostat to treat some forms of blood and lymph node cancers. However, both vorinostat and pembrolizumab are considered investigational drugs in this study because they are not approved for treatment of glioblastoma.

The combination of anatomical MRI examination with functional examination of tissue metabolic activity such as FET-PET (PET using the radiotracer - 18F-fluoro-ethyl-tyrosine) is a valuable tool to determine the actual tumor infiltration. The FET-PET examination can be performed using the dual-time point aqusition of FET for exact treatment planning. It has also been proven that using the dual FET-PET method, it is possible to obtain a precise image of the glioblastoma infiltration corresponding to the location and shape of the recurrence, and the tumor volumes in dual FET-PET are significantly larger than in MRI. Moreover, tumor defined in dual FET-PET is different than that of the tumor defined in single FET-PET acquisition. In the DualFETboosT trial we plan to assess the safety and preliminary efficacy of hypofractionated irraditon using simultaneous in-field boost directed on dual FET-PET based tumor volumes for treatment of primary glioblastoma multiforme with concomitant temozolomide.

Objective: In preparation of a randomized controlled trial, the investigators aim to assess pilot data on technical feasibility and safety of laser interstitial thermal therapy (LITT) at Radboud University Medical centre and to assess practical feasibility of a randomized study in patients with primary irresectable glioblastoma, as compared with standard of care. Study design: Prospective randomized pilot study. Randomization stopped (amendment September 2nd, 2021), Study population: 20 patients aged >= 18 with radiologically suspected diagnosis of primary glioblastoma and contra-indication for surgical resection. Intervention: Patients will be randomized to receive either (i) biopsy and LITT (n=10) or (ii) biopsy alone (n=10).

This study is designed to evaluate the role of Oxygen Enhanced (OE) Magnetic resonance imaging (MRI) and Blood Oxygenation Level Dependent (BOLD) MRI in detecting regions of hypoxic tumour and to evaluate their use as imaging methods to selectively deliver targeted radiotherapy to regions of aggressive disease.

The MRI linac Unity is a major technological evolution in radiotherapy combining a linear accelerator with a 1.5T MRI (radiological quality). It allows to target the target volume more precisely and to adapt the daily dose distribution according to variations in the position and volume of the tumor, critical organs and the tumor response. In many studies conducted in radiology, the analysis of specific MRI sequences, particularly in radiomics, aims to characterize tumors and their sensitivity to treatment. Initial data show that in radiotherapy, it would eventually be possible to characterize the radiosensitivity of healthy and tumorous tissues. With linac 1.5T MRI, the performance of selected MRI sequences, at each session, could make it possible to identify different levels of radiosensitivity within the tumour. The reproduction of these sequences on a daily basis could make it possible to follow the variations in radiosensitivity during the treatment. The final objectives would be: 1- to adapt the doses of radiotherapy to each session with a modulation of the dose according to the daily level of intra-tumor radiosensitivity, 2- to develop Artificial Intelligence (AI) tools allowing an analysis sequences and the generation of 3D maps of intra-tumor radiosensitivity, fast and suitable for carrying out a radiotherapy session. A first work carried out in collaboration with the CREATIS lab of the University Claude Bernard Lyon 1 (UCBL1) made it possible to generate maps of tissue oxygenation from sequences produced on the MRI linac Unity of the Hospices Civils de Lyon (T2* , IVIM, Carto T2 Multi Echo-Gradient). Hypoxia is known to be the first factor of tumor resistance to irradiation. A research program is structured in collaboration with UCBL1 in order to develop radiobiological adaptive radiotherapy approaches, based on 3D maps of intra-tumoral hypoxia and their variation during treatment. Several tumor locations were selected because of the preponderant place of MRI in tumor characterization: prostate, cervix, kidney, ENT and glioblastoma. Hypoxia is not the only factor of radioresistance. Changes in the microenvironment could also impact the sensitivity of tumor cells. The program will therefore also aim to optimize the maps initially based on hypoxia, by identifying other relevant factors to be taken into account to define intra-tumor sensitivity.

This study aims to evaluate the role of Regorafenib in prolonging the overall survival of glioblastoma multiforme patients who progressed after surgery and Stupp regimen with or without bevacizumab.

This phase I trial studies the side effects and best dose of ubidecarenone injectable nanosuspension (BPM31510) in treating patients with high-grade glioma (anaplastic astrocytoma or glioblastoma) that has come back and have been previously treated with bevacizumab. BPM31510 may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth.