View clinical trials related to Glioma.
Filter by:This study explores whether DESI-MS can be used to identify cancerous vs. noncancerous tissue during brain tumor surgery.
Background Lower-grade-gliomas affect young patients, thus the longest progression-free-survival (PFS) with a high level quality of life is crucial. Surgery most significantly impacts on tumor natural history, postponing recurrence, improving symptoms, decreasing the need of adjuvant therapies, with extent of resection, gross-total and supra-total (GTR and STR), strongly associating with longest PFS. Achievement of GTR or STR depends on the degree of functional reorganization induced by glioma. Consequently, a successful treatment fostering neural circuit reorganization before surgery, would increase the chance of GRT/STR. Hypothesis The plastic potential of motor system suggests that reorganization of circuits controlling hand movements could be presurgically fostered in LGG patients by enhancing plasticity with up-front motor-rehabilitation and/or by decreasing tumor infiltration with up-front chemotherapy. Advanced neuroimaging allows to infer the neuroplasticity potential. Intraoperative assessment of the motor circuits functionality will validate reliability of preoperative analyses. Aims The project has 4 aims, investigating: A) the presurgical functional (FC) and structural (SC) connectomics of the hand-motor network to picture the spontaneous reorganization and the influence of clinical, imaging and histomolecular variables; B) the dynamic of FC and SC after tumor resection; C) changes in FC and SC maps after personalized upfront motor rehabilitation and/or chemotherapy; D) the effect of FC and SC upfront treatment on the achievement of GTR/STR preserving hand dexterity. Experimental Design Resting-state fMRI and diffusion-MRI will provide FC and SC maps pre- and post-surgery; personalized up-front motor rehabilitation and/or chemotherapy will be administered; Intraoperative brain mapping procedures will generate data to validate the maps. Expected Results 1. Provide a tool to render the motor functional reorganization predictive of surgical outcome. 2. Identify demographic, clinical and imaging variables associated with functional reorganization. 3. Describe the gain induced by up-front treatment. 4. Distinguish "patterns" predicting chance for GTR/STR from "patterns" suggesting need for up-front treatment. Impact On Cancer Results will increase the achievement of GTR/STR, preserving motor integrity, with dramatic impact on LGGs natural history.
This is a Pilot, multicenter, open-label study of patients less than or equal to 25 years, with recurrent or progressive LGG harboring a CRAF or BRAF alteration, including BRAF V600 mutations and KIAA1549: BRAF fusions. Patients with BRAF or CRAF alterations will be identified through molecular assays as routinely performed at Clinical Laboratory Improvement Amendments (CLIA) of 1988 or other similarly certified laboratories. The study will be conducted in two sequential phases: Phase A: A Feasibility (combination dose finding) phase, followed by Phase B: An Efficacy phase. The maximum tolerated dose (MTD)/Recommended Phase 2 Dose (RP2D) of the combination as determined in Phase A would be the dose used in Phase B. The patients on Phase A who were below the MTD/RP2D would be eligible for intra-patient dose escalation to MTD/RP2D subject to criteria outlined later
To distinguish various molecular subtypes of gliomas by spectra data obtained from Raman analyzer, including IDH mutant, 1p/19q-codeleted, ATRX deletion, TERT promoter mutation, MGMT promoter methylation, EGFR amplification, H3 K27-altered, TP53 mutant, PTEN deficiency, ki 67, AQP4, VEGF, and so on, comparing with the results of Immunohistochemistry or genetic test on the same brain tissue samples.
This is a dose exploration clinical trial to assess the safety and feasibility of the IL13Ra2-targeted CAR-T in glioma.
Tumors of the central nervous system affect 21 people per 100,000 every year, a figure that refers to countries with advanced economies, with an increase in incidence over time. Experimental evidence suggests that cancer stem cells (CSCs) may play a key role in the malignancy of these tumors. In fact, due to the hypoxic tumor microenvironment, these cells are able to create compensatory pathways that confer stem-like, angiogenic and pro-tumoral functions. Furthermore, it has been demonstrated that brain tumor stem cells are radio- and chemo-resistant and therefore not treatable with the therapeutic protocols currently in use. To date, in fact, there are no definitive treatments for the eradication of brain tumors. In this scenario, sphingolips, a class of lipid deputized to several physiological functions, are also involved in tumor onset, progression, drug resistance, and aggressiveness. In hypoxic tumor microenvironment, CSCs present a modified rheostat in the metabolism of sphingolipid, in favor of Sphingosine-1-phosphate (S1P). S1P is an intermediate of sphingolipid metabolism, formed from sphingosine through the action of sphingosine kinases (SK). Increasing evidence suggests that S1P acts as a tumor-promoting signal, predominantly in the extracellular environment, regulating important cellular properties correlated with tumor potential. The project aims to identify new molecular and metabolic targets involved in the survival and chemo-resistance of tumor stem cells in relation to the tumor microenvironment.
Gliomas are the most common type of primary brain tumors, with surgery followed by radiotherapy and chemotherapy as the main treatment modalities. However, they are highly prone to recurrence, presenting significant treatment challenges, especially for high-grade gliomas, which have a 5-year survival rate of only 5.5%. Paclitaxel, a common chemotherapeutic agent, exhibits antitumor effects in vitro that are 1400 times stronger than those of temozolomide (the first-line chemotherapy drug for gliomas). However, due to its large molecular weight (approximately 893 Da), it cannot cross the blood-brain barrier, precluding its use as a first-line treatment for gliomas. Preliminary research by our team has demonstrated that Specific Mode Electroacupuncture Stimulation (SMES) can open the blood-brain barrier, enhancing the concentration of albumin-bound paclitaxel (ABX) in tumor tissues, peritumoral tissues, and surrounding invasive tissues, thereby exerting antitumor effects. Consequently, this study aims to observe the safety and efficacy of SMES combined with ABX in treating patients with recurrent high-grade gliomas postoperatively, to explore its mechanisms of action, extend survival, improve quality of life, and forge new theories and methods for the integrative treatment of brain tumors combining traditional Chinese and Western medicine.
The purpose of this study is to form an interdisciplinary team to dynamically evaluate patient cognitive outcomes and develop an individualized cognitive training program for Chinese brain tumor patients
This is a two-part Phase 1, open label, multi-center, single arm, non-randomized, multiple dose, safety, pharmacokinetic (PK) and preliminary efficacy study of single agent NST-628 in adult patients with MAPK pathway mutated/dependent advanced solid tumors who have exhausted standard treatment options.
This is a single center Phase I study of a new adjuvant CD200 activation receptor ligand, CD200AR-L, in combination with imiquimod and GBM6-AD vaccine to treat malignant glioma in children and young adults. The primary objective of this study is to determine the maximum tolerated dose (MTD) of CD200AR-L when given with a fixed dose of GBM6-AD vaccine, imiquimod, and a single dose of radiation for patients with recurrent High Grade Glioma (HGG) or following standard of care therapy radiation therapy for newly diagnosed Newly Diagnosed Diffuse Midline Glioma/Diffuse Intrinsic Pontine Glioma (DIPG/DMG).