View clinical trials related to Glioblastoma.
Filter by:This study is the first step in testing the hypothesis that adding Photobac® Photodynamic Therapy to surgical removal of a glioblastoma or gliosarcoma will be both safe and effective. Photodynamic Therapy (PDT) combines light and a photosensitizer. PDT has been used to treat a variety of cancers with varying degrees of success. For the past thirty years Photolitec has been working to develop a treatment for glioblastoma or gliosarcoma using light and a photosensitizer. Photolitec's scientists were looking for a photosensitizer that: 1. has no significant systemic toxicity apart from some temporary skin photosensitivity, 2. crosses the blood brain barrier, 3. accumulates to a high level in glioblastoma and minimally in the brain, 4. is activated by the wavelength of light that penetrates most deeply into the brain, 5. minimizes any temporary skin photosensitivity. Preliminary testing indicates the Photolitec team has achieved these five goals. Photolitec is now able to offer a clinical trial based on the results of this work.
This is a phase I study to assess the safety and feasibility of IL-8 receptor modified patient-derived activated CD70 CAR T cell therapy in CD70+ adult glioblastoma.
In summary, standard of care postoperative chemoradiation for patients with newly diagnosed GBM does not routinely provide durable local control or prolonged overall survival. As discussed above it seems unlikely that patient outcomes will be significantly improved with radiation dose escalation given at the time of the EBRT boost. However, as most failures are local, improving LC could potentially improve the OS of patients. To do this, we propose a shift in the traditional radiation paradigm. This study will assess the feasibility and tolerability of adding GT radiation therapy as an upfront boost at the time of maximum safe resection, along with the backbone of the current standard of care approach, concomitant and adjuvant temozolomide +/- TTF, for patients with newly diagnosed GBM. GT, a novel brain brachytherapy device utilizing Cs-131 embedded in bioresorbable collagen tiles, offers a more sophisticated carrier and a shorter half-life radioisotope, Cs-131. Use of this device allows for radiation initiation at an earlier time point and a more rapid dose delivery and possibly more effective tumor control particularly for rapidly proliferating tumors such as GBM. Two prospective studies have demonstrated the safety and efficacy of re-irradiation with GT in patients with recurrent GBM. The overarching goal of this single-arm, open label phase 4 study is to determine the feasibility and tolerability of treating patients with GammaTile in combination with the Stupp Protocol and how to proceed with testing this treatment in a future, larger, randomized clinical study. The aims of the study are to demonstrate that the use of GammaTile at the time of surgery is well tolerated and does not delay the start of the Stupp protocol. Efficacy outcomes (e.g., LC, OS, PFS) will also be described.
The study is to evaluate the safety and efficacy of tumor infiltrating lymphocyte (TIL) therapy for patients with maligant glioblastoma multiforme. Autologous TiLs should be given by intravenous infusion after 5 days of lymphodepletion treatment.
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.
The purpose of this study is to examine the effects of Tofacitinib in patients with recurrent Glioblastoma.
This is a pilot or feasibility study to test the study plan and to find out whether enough participants will join a larger study and accept the study procedures. Eligible participants (adults with newly diagnosed glioblastoma multiforme [GBM] and had a good tumour resection [>= 70% of initial tumour volume] and plan to receive 6 weeks of chemoradiation followed by up to 6 months of chemotherapy) are asked to donate their own stool samples at 4 different time points during their treatment course. Participants will also complete a 7-day diet diary and two questionnaires about their health-related quality of life. Glioblastoma multiforme (GBM) is the most common and aggressive form of primary brain cancer in adults. The current best evidence-proven treatment for GBM includes maximum safe tumour resection, brain radiation over a 6-week period given with chemotherapy pills called temozolomide (Brand name: Temodal or Temodar), followed by approximately 6 months / cycles of temozolomide. Despite these treatments, the average life expectancy is generally less than 2 years. Researchers are recognizing that the immune system has an important role in directing the effectiveness of chemotherapy, radiation, and newer therapies such as immunotherapies. Some immunotherapies have been quite successful in improving cancer control and survival in other cancers like melanoma (an aggressive skin cancer), but when these drugs were given to patients with GBM, there appeared to only be a small effect. Therefore, finding ways to make existing and new treatments work better should be a priority. Recent scientific studies have shown that the bacteria that make up our stool, often referred to as the gut microbiome, play a major role in regulating the immune system. For example, researchers were able to make patients with melanoma who previously did not respond to immunotherapy become responsive to the treatment after receiving a stool transplant from responders to immunotherapy. This provides proof of concept that we could modify the body's immune environment to favour cancer killing by changing a person's gut bacteria environment. The role of the gut bacteria in patients with brain cancer is poorly understood as very few studies have been published about it in this population. We believe that understanding the composition of the gut microbiome and how it relates to the effectiveness and side effects of treatments in GBM patients will be an important first step to understanding how we can modify the gut microbiome to improve outcomes for patients living with GBM.
The FRONTIER Study is a prospective, interventional, single-arm, multi-center, study to assess the safety and technical feasibility of TheraSphere GBM in patients with recurrent GBM.
This will be an open-label, pilot, exploratory, single centre clinical investigation. This is an early feasibility single arm study. No formal hypothesis is proposed. A total of up to 15 evaluable subjects receiving a non-radical ablation is planned. The safety and feasibility outcomes will be measured directly post-treatment, 48h and 3 months post-treatment. A minimal invasive neurosurgical approach with a Magnetic Resonance Imaging (MRI)-based stereotactic guidance system will be utilized for the planning, navigation, intracranial access, placement and confirmation of the Laser applicator prior to ablation.
The purpose of this research is to find hidden cancer with an experimental magnetic resonance imaging (MRI) scan called spectroscopic magnetic resonance imaging (sMRI). That spectroscopic MRI scan will be used to increase the area of the brain receiving radiation and then the dose of radiation in attempt to kill more of the cancer. Proton radiotherapy and bevacizumab (Avastin) are used to minimize the possible side effects of this approach.