View clinical trials related to Glioblastoma.
Filter by:This is a feasibility single arm study designed for obtaining early data for optimization and evaluation of the clinical potential for a new MR technique using deuterated glucose. The purpose of the study is to investigate whether this technique is useful in metabolic imaging of glioblastoma multiforme (GBM) and whether radiochemotherapy (RCT) induced changes in the brain metabolism can be detected and might be predictive for treatment response. The study will include 10 patients with histologically verified GBM scheduled for standard RCT. Patients will have MRI scan performed before and within 8 weeks after starting RCT. The scans will include imaging after oral intake of deuterated glucose, so called deuterium metabolic imaging (DMI). Based on this study, the most optimal scanning technique, output variables of highest discriminative power with respect to RCT, and potential predictive markers for response will be selected for further clinical investigation.
Glioblastoma patients are confronted with a debilitating disease associated with a low survival rate and poor quality of life. The goal of this study will be to reach a largely underrepresented population in the exercise literature and explore the role of a tailored circuit-based resistance training program on functional fitness (i.e., ability to carry out tasks of daily living) and associated health outcomes (e.g., quality of life) for GBM patients on active treatment.
An open-label, single institutional phase II trial of losartan in patients with primary and metastatic brain tumors with an individual stepped-wedge, randomized, assessor-blinded, dose-finding design on three indications.
This study is designed to treat patients who have been diagnosed with brain cancer, including glioblastoma (GBM) and diffuse intrinsic pontine glioma (DIPG). The treatment uses immunomodulatory vaccine generated by autologous dendritic cells (DCs) pulsed with genetically modified tumor cells or tumor-related antigens including neoantigens to inject into patients. Vaccine-induced T cell responses have been associated with improved survival. The study will evaluate the safety and potential benefit of the novel immunomodulatory DC vaccines.
This study aims to treat patients who have been diagnosed with brain cancer including glioblastoma multiforme (GBM). The treatment combines two different approaches to fight cancer: immune modulators and antigen-specific T cells. Immune checkpoint antibodies have been tested on various tumors with good outcomes. GBM is known to express increased levels of certain antigens that can be targeted by antigen-specific T cells. Thus, in this study, the gene-modified T cells specific for GBM antigens will be combined with immune modulatory genes to treat patients in dose escalation cohorts.
It is known that after application of MK-3475 activated PD -1 negatively regulates the activation of T cells through suppression of the path of PI3K / Akt. This study will identify the effectiveness of oral inhibitors of PI3K / Akt pathway in comparison with MK-3475 (pembrolizumab).
Trial Hypothesis: Acute, progressing lethal neurooncological process can be transferred into chronic and non-lethal, the survival rates and life quality can be improved by of control of tumor cells (TCs) quantity and targeted regulation of effector functions of tumor stem cells (TSCs). Brief Description: The first line therapy of glioblastoma multiforme (GBM) involves allogeneic haploidentical hematopoietic stem cells (HSCs), dendritic vaccine (DV) and cytotoxic lymphocytes (CTLs). TCs and TSCs are isolated from GBM sample. Dendritic cells are isolated from peripheral blood mononuclear cells and cultured. Tumor sample provides tumor specific antigens to prepare DV. CTLs are obtained from peripheral blood after DV administrations. HSCs are harvested from closely related donor after granulocyte-colony-stimulating factor (G-CSF) administration. Allogeneic HSCs are administered intrathecally 5 times every 2 weeks, at day 1, 14, 28, 42, 56. DV is given 3 times every 2 weeks (day 14, 28, 42) subcutaneously in four points. CTLs are administered every 2 weeks for 3 months, then 3 times every 1 month intrathecally. Six months after the therapy completion, the efficiency is evaluated and the cohort demonstrating efficiency continues the therapy, while cohort demonstrating no efficiency is transferred to active comparator arm. Second line therapy involves DV with recombinant proteins, CTLs and autologous HSC with modified proteome. Autologous HSCs are mobilized by G-CSF. Carcinogenesis-free intracellular pathways of signal transduction able to respond to targeted regulation of therapeutic cell systems with specific properties, are detected in TSCs using complete transcriptome profiling of gene expression, proteome mapping and profiling of proteins, bioinformation and mathematical analysis and mathematical modeling of protein profiles. To find key oncospecific proteins in TSCs and TCs, the targets for TSCs regulation are detected, as well as protein ligands able to regulate reproductive and proliferative properties of TSCs. Using these data of TCs and TSCs proteins, the cell preparations to initiate adoptive immune response are prepared: DV loaded with recombinant proteins analogous to key tumor antigens, CTLs and autologous proteome-modified HSCs. Autologous proteome-modified HSCs, DV and CTLs are administered as in the first line therapy.