Active clinical trials for "Glioblastoma"

The goal of this study is to determine the utility of cerebrospinal fluid (CSF) cell-free DNA (cfDNA) as a prognostic biomarker in glioblastoma (GBM).

The purpose of this clinical study is to confirm the utility of chemosensitivity tumor testing on cancer stem cells (ChemoID) as a predictor of clinical response in poor prognosis malignant brain tumors such as recurrent glioblastoma (GBM).

Radiotherapy (RT) is one of the most important local treatments besides surgery, but currently, no consensus has been made regarding the optimal radiation volume for high grade gliomas. The most main growth characteristics of glioblastoma is infiltrative growth through the white matter tracts, regions along the white matter tracts especially at the direction of the main fiber bundles would have a higher risk of microscopic tumor cell dissemination. However, in current practice, recommends for the CTV definition is adding a 2 cm symmetrical margin to GTV or peritumoral edema in all directions, which hardly account for the growth characteristics of gliomas that are known from histopathological findings.

This is a pilot phase I study to evaluate the safety and efficacy of NKG2D CAR-T cell therapy in patients with relapsed and/or refractory glioblastoma

The study is designed as an international, multicenter prospective cohort study. Patients with presumed glioblastoma (GBM) in- or near eloquent areas on diagnostic MRI will be selected by neurosurgeons. Patients will be treated following one of three study arms: 1) a craniotomy where the resection boundaries for motor or language functions will be identified by the "awake" mapping technique (awake craniotomy, AC); 2) a craniotomy where the resection boundaries for motor functions will be identified by "asleep" mapping techniques (MEPs, SSEPs, continuous dynamic mapping); 3) a craniotomy where the resection boundaries will not be identified by any mapping technique ("no mapping group"). All patients will receive follow-up according to standard practice.

Glioblastomas (GBM) are the most common primary malignant brain tumor with a very high recurrence rate and an average survival of 14 months. Identifying an imaging biomarker to predict recurrence is critical. Using a special MRI technique called diffusion weighted imaging (DWI), a recent retrospective study described isolated restricted diffusion (IRD) foci. The presence of IRD was found in 40% of patients with GBM on index imaging and was associated with longer survival. IRD foci are not currently identified as having a tumor focus and are not included in treatment strategies and guidelines. These findings need to be confirmed in a prospective study. The investigators propose a prospective pilot study to establish the incidence of IRD on the index imaging of patients with GBM. The investigators will collect surgical samples from these foci to establish the histological and molecular signature to confirm GBM in these newly identified foci. The results from this pilot study will guide the planning of a larger well powered multicenter study that will help establish IRD as an imaging biomarker in the GBM management guidelines, which will help improve the outcomes in patients with GBM.

This is a multi-center prospective phase 3 clinical trial to explore the efficacy and side effects of standard-dose photon radiation versus standard-dose proton radiation versus carbon ion boost plus standard proton radiation for newly diagnosed glioblastoma. The patients enrolled will be randomly allocated with 1:1:1 to three group: Control Group, standard-dose photon radiotherapy; Study Group A, standard-dose proton radiotherapy; Study Group B, standard-dose proton radiotherapy plus induction carbon-ion radiotherapy boost. The primary endpoint is overall survival (OS).

Gliomas are the most frequent type of primary brain tumors in adults; among them glioblastoma multiforme (GBM) is the most malignant, being associated with the worst prognosis. Glutamate (Glu) is an aminoacid, responsible for essential functions in the Central Nervous System (CNS), acting both as metabolite and neurotransmitter. It is essential for regulating cellular metabolism and developmental synaptogenesis, cellular migration, differentiation and death. Recent scientific evidences have demonstrated alteration in Glu synthesis and signaling being directly involved in GBM growth and invasion

This phase 1 study will evaluate a novel hEGFRvIII-CD3-biscFv Bispecific T cell engager (BRiTE) in patients diagnosed with pathologically documented World Health Organization (WHO) grade 4 malignant glioma (MG) with an EGFRvIII (epidermal growth factor receptor variant III) mutation (either newly diagnosed or at first progression/recurrence). The primary objective is to evaluate the safety of BRiTE in such patients.

GBMs are still considered tumors with few available treatment options that are able only to achieve a temporary local control of the disease. In case of a GBM, tumor recurrence is generally expected within 12 months and it is due to the presence of marginal tumoral cells with pro-oncogenic molecular phenotypes that are resistant to actual chemotherapies and to radiation therapy. Nowadays, surgery still represent the first treatment option in case of suspected GBM and it aims to remove the contrast enhancing lesion seen at the pre-operative brain MRI. In particular, the peripheral layer of the tumor is made of low replicating cellsglioblastoma-associated stromal cell (GASC) that can show different carcinogenic properties and that are probably responsible for tumor recurrence. Metabolism of GBMs is mainly anaerobialglicolisis that leads to the transformation of glucose in ATP and lactates. The production of high lactate levels determines a decrease of intracellular pH that is counterbalanced by V-ATPase activity through H+ ions extrusion from the intracellular to the extracellular environment. Increased V-ATPase activity affects different pro-tumoral activities and plays a crucial role in chemoresistance. In fact, a low extracellular pH can reduce the efficacy of antineoplastic agents since a low pH might affect the structural integrity of drugs and their ability to pass through the plasmatic membrane. Finally, V-ATPase can act as an active pump able to excrete antineoplastic agents. GBMs with high V-ATPAse expression are able to transmit malignant features and to activate proliferation of GASC in vitro through a network of microvescicles (MV) like exosomes and large oncosomes (LO) that transport cell to cell copy DNA (cDNA) and micro-RNAs (miRNA).In this view, our work is intended to study: 1) the effects of proton pump inhibitors (PPI) on CSC and GASCs cultures as in vitro add-on treatments; 2) the MVs load (in terms of miRNAs and cDNAs) during the neuro-oncological follow-up in order to understand how it changes after surgery and adjuvant treatments; 3) the possible roles of V-ATPase as a clinical marker to be used to check tumor response to adjuvant treatments.