View clinical trials related to Glioblastoma Multiforme.
Filter by: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).
Currently, the optimal treatment regimen for elderly Glioblastoma (GBM) patients with poor performance status (PS) is unknown. Based on data for elderly GBM patients and the limited data for patients with poor PS, hypofractionated RT or a short course of Temozolomide (TMZ) may provide survival benefit without the added toxicity and inconvenience of a more protracted treatment regimen. In particular, treatment with RT or TMZ monotherapy on the basis of methylated O6 - methyl guanine - DNA methyltransferase (MGMT) promoter methylation status, followed by the alternative therapy at progression, may provide a safe and effective treatment regimen for patients with poor PS. The hypothesis of this trial is that in elderly GBM patients with poor performance status (age ≥ 65 years and KPS 50-70), a biomarker-guided approach to therapy results in non-inferior overall survival compared to combined TMZ/RT. Specifically, biomarker-guided therapy will consist of TMZ monotherapy for patients with a methylated MGMT promoter, and hypofractionated RT (40 Gy in 15 fractions) for patients with a non-methylated MGMT promoter. It is hypothesized that biomarker-guided therapy will result in non-inferior progression-free survival, reduced toxicity and increased cost-effectiveness compared to combined chemoradiotherapy. Primary objective: • To compare overall survival of standard vs biomarker-guided therapy in elderly and frail patients with newly diagnosed GBM. Secondary objective: - To evaluate progression-free survival following treatment in both arms. - To evaluate adverse events according to CTCAE criteria in both arms. - To evaluate health-related quality-of-life as assessed by MoCA and EORTC QLQ-C30/QLQ-BN20 questionnaires in both arms. - To evaluate cost-effectiveness of standard vs biomarker-guided therapy Methods: Patients will be randomized to two treatment groups in a 1:1 ratio. Standard Arm: TMZ with concurrent RT (combined modality arm) Patients will receive 15 days of TMZ daily with concurrent RT. TMZ will be delivered at a dose of 75 mg/m2, given daily with RT. TMZ will be administered 1 hour before each session of RT. After a 4-week break, patients will receive six cycles of adjuvant TMZ according to the standard 5-day schedule (days 1-5) every 28 days, up to 6 cycles as tolerated by the patient. The dose will be 150 mg/m2 for the first cycle and increased to 200 mg/m2 beginning with the second cycle, so long as there are no hematologic adverse events, intractable nausea or fatigue. Investigational Arm: Biomarker based treatment MGMT (+): TMZ monotherapy Patients will receive TMZ at a dose of 75 mg/m2 daily for 15 days on weekdays (Monday through Friday). This will be followed by six cycles of TMZ according to the standard 5-day schedule (days 1-5) every 28 days. The dose will be 150 mg/m2 for the first cycle and increased to 200 mg/m2 beginning with the second cycle, so long as there are no hematologic adverse events. Dose will be determined using the body surface area (BSA) calculation. MGMT methylation (-): No TMZ will be given. Participants will receive radiation treatment with 40Gy / 15 fractions over a period of 21 days (3 weeks). Upon treatment completion, participants will be followed by every 3 months for 2 years and every 6 months for years 3-5. Response and progression will be evaluated using the new international criteria proposed by the Response Assessment in Neuro-Oncology working group (RANO).
The investigator propose a single-center randomized phase II controlled study designed to compare the management of first recurrence of GBM using etoposide versus tamoxifen.
This is a single-arm, non-randomized, open-label Phase 2 therapeutic study that will assess the effects of adding BPM31510 onto a conventional treatment framework of RT and concurrent TMZ chemotherapy for subjects with newly diagnosed glioblastoma.
Glioblastoma (GBM) is a high grade glioma (brain tumor) that is treated with surgery or biopsy followed by radiotherapy (RT) given daily over 3 or 6 weeks with or without an oral chemotherapy. Radiation is targeted to the visible residual tumor on magnetic resonance imaging (MRI) images plus a large margin of 15 to 30 mm to account for possible cancer cells outside the visible tumor and for potential growth or shifts in tumor position throughout the prolonged RT course. Standard RT uses MRI to create a reference plan (with large margins) and treats that same volume every day. This exposes a large amount of healthy brain tissue to radiation leading to toxicity and reduced quality of life. A new technology, the MR-Linac, combines an MRI scanner and a Linac (radiation delivery machine) into one unit. This allows for "adaptive" RT by obtaining an updated MRI scan each day just prior to treatment, adapting the RT plan to take into account any changes in the tumor or the patient's anatomy on that given day. This allows for a smaller (5 mm) margin on the visible tumor as its position can be tracked daily. The goal of this study is to use adaptive RT with small margins to demonstrate that the local control of the visible tumor is not compromised compared to the large volumes used with standard non-adaptive RT, while determining whether smaller margins lead to decreased radiation toxicity and therefore improved quality of life by minimizing radiation exposure.
This is a First-In-Human (FIH) study of [68Ga]-FF58 to characterize the imaging properties, safety, biodistribution and dosimetry properties of [68Ga]-FF58 in adults with relapsed or refractory (r/r) glioblastoma multiforme (GBM), breast cancer (BC) that has metastasized to the brain, gastroesophageal adenocarcinoma (GEA) or pancreatic ductal adenocarcinoma (PDAC) expected to overexpress alpha-v beta 3 (αvβ3) and alpha-v beta 5 (αvβ5) integrins.
All patients will receive TTFields therapy and additionally Stereotactic Radiosurgery . Radiosurgery will be based on MRI and FET-PET or MRI alone. Addition of FET-PET will be preferred option.
This is an open-label, single-center Phase 0/2 study that will enroll up to 30 participants with newly diagnosed (N=12) and recurrent glioblastoma (N=18). The trial will be composed of a Phase 0 component (subdivided into Arm A, Arm B, and Arm C), and an Exploratory Phase 2 component. Participants with tumors demonstrating a PK response in the Phase 0 component of the study will graduate to an exploratory Phase 2 component that combines therapeutic dosing of pamiparib plus fractionated radiotherapy (for unmethylated MGMT promoter newly-diagnosed cases), pamiparib plus fractionated radiotherapy (for recurrent cases) or Olaparib plus fractionated radiotherapy (recurrent cases).
Relapsed GBMs have a life expectancy of a few months and re-radiation has proven to be safe in terms of toxicity and effective in increasing OS. One of our studies [Ciammella P, 2013, 8:222] reported a median survival of 9.5 months in patients with recurrent GBM and treated with stereotactic radiotherapy with a total dose of 25 Gy in 5 consecutive sessions, in which the dose was prescribed to 70% isodose with a homogeneous gradient towards the center of the target volume. The identification with functional imaging of specific areas with higher tumor cell density, and the possibility of delivering precisely, thanks to the most advanced therapy units, different doses to the different sub-volumes, can lead to an increase in the maximum dose that can be delivered at the expense of the most aggressive areas (with a greater effect on the tumor), compared to smaller doses in areas with lower signal alteration. This selectivity of the doses should allow an increase in the efficacy of the therapy and therefore a hypothetical increase in local control, compared to a radio-induced toxicity on the surrounding healthy tissues almost comparable to that achieved with the previous hypofractionated treatments [Ciammella P, 2013]. In fact, delivering many high doses to the entire volume would result in an excess of radio-induced necrosis within the irradiated regions with high dose, as well as the impossibility of minimizing the doses on healthy areas and / or on non-neoplastic critical areas keeping them at internal dose ranges related to minimal and acceptable toxicity levels. Since there are no studies providing clear indications on the acute and late toxicity of irradiated healthy tissues that have already been the subject of a first course of radiotherapy (STUPP), the choice of safety is the primary objective of the study.
The primary goal of this Phase 1 study is to determine if a new investigational drug, OS2966, when delivered directly to the brain of adult participants with recurrent/progressive high-grade glioma (HGG) is safe and well tolerated. OS2966 is a therapeutic antibody blocking a cell surface receptor governing fundamental biological processes that allow cancer cells to grow, spread and become resistant to cancer treatment. Despite availability of new promising cancer treatments, successful treatment of HGG has been limited by the presence of the brain's protective blood brain barrier (BBB). The BBB is made up of tightly knit cells that block entry of several substances including cancer treatments. To overcome this obstacle, a technique called convection-enhanced-delivery (CED) will be utilized to deliver OS2966 directly to the site of disease. Convection-enhanced delivery involves placement of one or more catheters into the brain tumor and tumor-infiltrated brain in order to slowly pump a therapy into the tissue. To be eligible for this study participants must require surgical resection of their recurrent HGG.