View clinical trials related to Glioma.
Filter by:This is a pilot study of a vaccination regime that is designed to efficiently induce anti-tumor T-cell responses in patients with WHO grade II glioma. The proposed regime with BTIC Lysate in combination with imiquimod, an FDA-approved immune response modifier will induce potent anti-glioma immune response with minimal or no toxicity.
The purpose of this research study is to determine whether taking either of two low dose drugs that would prevent new blood vessels from growing after stem cell transplant is feasible, and what the side effects of taking each of these drugs after autologous transplant might be. The reason the investigators are looking at these drugs is because one of the things that allows tumors to grow quickly is their ability to stimulate the growth of new blood vessels. By suppressing the growth of new blood vessels after stem cell transplant, the investigators hope to prevent the tumors from coming back or continuing to grow.
This partially randomized phase I/II trial studies the side effects and the best dose of anti-endoglin monoclonal antibody TRC105 when given together with bevacizumab and to see how well they work in treating patients with glioblastoma multiforme that has come back. Monoclonal antibodies, such as anti-endoglin monoclonal antibody TRC105 and bevacizumab, may find tumor cells and help kill them. Giving anti-endoglin monoclonal antibody TRC105 together with bevacizumab may be an effective treatment for glioblastoma multiforme.
This study is being done to evaluate the toxicity and safety of carboplatin administered by convection enhanced delivery into the tumor in patients with high grade glial neoplasms. This study is a dose escalating study, (the dose of the study drug is increased at set time points). Carboplatin is in a class of drugs known as platinum-containing compounds; it slows or stops the growth of cancer cells in your body. Convection enhanced delivery involves placing one or more catheters into the brain and delivering chemotherapy through those catheters directly into the brain
This is a phase I study to find the highest tolerable dose of crizotinib and dasatinib given in combination to patients with diffuse intrinsic pontine glioma (DIPG) and other types of high grade gliomas (HGG). Participants will receive escalating doses until the highest dose is determined. Participants will be enrolled in two strata: stratum A for recurrent/ progressive tumors and stratum B for recently diagnosed patients who have completed standard radiation therapy without progressive disease. Up to 7 dosage levels will be tested. Both drugs are taken orally daily, once per day. Correlative pharmacokinetic and biology studies are planned, as well as advanced methods of magnetic resonance imaging (MRI).
1. Purpose of the Study - This protocol aims to demonstrate the feasibility and safety of autologous ALD-451 cells administered intravenously in World Health Organization (WHO) grade IV malignant glioma patients following surgery, radiation therapy and temozolomide; as well as to obtain an initial description of the effects of ALD-451 cells on neuro-cognition allowing the design of a subsequent phase 2 trial of this intervention in patients with malignant glioma. The primary objective of this study is to demonstrate the safety of intravenously administered autologous bone marrow derived ALD-451 cells in the brain following surgery, radiation therapy and temozolomide in patients with WHO grade IV malignant glioma. The secondary objective of this study is to determine the recovery of ALD-451 from bone marrow of patients following radiation therapy and temozolomide. The exploratory objective of this study is to determine if intravenous administration of autologous ALD-451 cells following surgery, radiation therapy and temozolomide in WHO grade IV malignant glioma patients may have an effect on subsequent deterioration of neurocognition and patient-reported outcomes.
The primary purpose of this phase II clinical trial is to determine the safety and effect on survival of patients autologous dendritic cells pulsed with autologous tumor lysate as a treatment for low-grade glioma patients. Other goals of this study are to determine if the vaccine can cause an immune response against patients' cancer cells and slow the growth of their brain tumors
Hypofractionated radiotherapy reduce the patient and family burden through decreasing the overall treatment time. This study is to evaluate the clinical end results of the hypofractionated radiotherapy in DIPG compared to the conventional treatment. The non-inferiority of the hypofractionated radiotherapy will result in decrease the hospital, stay or engagement, for more than its half with the same results.
This study will be carried out in children with diagnosis of cancer with tumors known to express N-glycolylated gangliosides. The disease must be resistant to conventional therapy. The acute toxicity and immune response will be evaluated. The expression of N-glycolylated gangliosides in tumors has previously been investigated in the tumor sample bank at this Hospital. The expression of N-glycolyl GM3 was shown in neuroblastoma, Ewing's sarcoma, Wilm's tumor and retinoblastoma. Gliomas and the aforementioned tumor types have a very bad prognosis when conventional treatment is ineffective. New therapeutic strategies have thus been examined, and several immunotherapeutic approaches, including dendritic cell vaccines, peptide vaccines and anti-idiotype vaccines are currently being assessed. Racotumomab is an anti-idiotype antibody capable of inducing anti-N-glycolyl GM3 antibodies in patients with melanoma, breast cancer and lung cancer. Dose escalation studies have shown the safety of racotumomab in the 0.5 to 2 mg dose range. The 1 mg dose level was selected for the ensuing clinical studies. This clinical trial in children involves three dose levels: 0.15 mg, 0.25 mg and 0.4 mg, owing to the difference in body surface between an adult (1.73 sq. m in average) and the candidate population for this study (0.55 to 0.7 sq. m).
MicroRNAs are small molecules which have recently been discovered in cells. They are known to be responsible for the normal development of cells and when they are disrupted can contribute to the development of cancer. Many previous studies have been done evaluating the expression of microRNAs in normal tissues as well as in a wide variety of cancers. Recently, microRNAs from tumor cells have been detected circulating in the blood of patients with cancer. This presents a novel opportunity to assess the utility of microRNAs in the blood as an early predictor of cancer as well as a marker of response to therapy. No previous studies have been performed evaluating microRNAs in archived tumor tissue and blood of patients with Neurofibromatosis type 1 (NF-1). The investigators propose a feasibility study to evaluate the presence of microRNAs in archived tumor tissue and the blood of patients with NF-1. If the investigators are able to identify circulating microRNAs in this population of pediatric patients, they will build upon this data in proposing a future study.