View clinical trials related to Brain Cancer.
Filter by:The goal of this clinical research study is to learn whether Tarceva (erlotinib hydrochloride), when given in addition to whole brain radiation therapy, is better to treat brain metastases in patients with Non-Small Cell Lung Cancer (NSCLC).
The researchers think that the use of advanced MR imaging may help people with this disease, because it may better predict areas within a malignant glioma (brain tumor) that are at a high risk of recurring. WeThe reserchers are doing this study to see whether this advanced imaging is a safe treatment that causes few or mild side effects in people with brain tumors.
The purpose of this study is to help us understand gliomas, one type of brain tumor. This research protocol makes pictures of gliomas. We will take pictures of the glioma before and after treatment. The pictures are made with a positron emission tomography (PET) scanner. PET scans use radioactive markers to "see" cancer cells. We plan to use two different radioactive markers, [18F]FACBC and [18F]FLT, to "see" if the glioma responds to the treatment being recommended by the doctor. We are investigating whether one or both of these types of PET scans can help us to better understand gliomas and their response to treatment. We expect these pictures will give us information the your tumor and may help us to understand why the treatment that the patient is receiving is affecting the tumor the way that it is. We also hope to collect information about the amount of radioactivity exposure. We will measure radioactivity exposure to the tumor, brain and other organs.
The goal of this clinical research study is to find the highest tolerable dose of DNX-2401 that can be injected directly into brain tumors and into the surrounding brain tissue where tumor cells can multiply. A second goal is to study how the new drug DNX-2401 affects brain tumor cells and the body in general.
The purpose of this study is to test the safety of a new plan for treating glioblastoma. The usual first treatment for glioblastoma is to give focused radiation over 6 weeks in combination with a chemotherapy called temozolomide. In this study the radiation will be given over 2 weeks in combination with temozolomide and another drug, bevacizumab, will also be given. Our idea is that this treatment plan may attack both the tumor and the blood vessels feeding the tumor more effectively. This study will look at what effects, good or bad, this approach has on the patient and the tumor.
The main purpose of this study is to evaluate the safety and performance of the AutoLITT system for the treatment of recurrent/progressive glioblastoma multiforme tumors (GBM).
The purpose of this study is to determine normal measurements (ADC values) from the head and neck of healthy volunteers using 3T MRI.
Meningiomas account for 20% of primary adult brain tumors, occurring at an annual incidence of 6 per 100,000 (Louis, Scheithauer et al. 2000). Complete surgical resection is the treatment of choice but may not possible when the tumor invades critical structures (e.g., skull base, sagittal sinus) (Mirimanoff, Dosoretz et al. 1985; al-Rodhan and Laws 1990; Al-Rodhan and Laws 1991; Newman 1994; De Monte 1995; Levine, Buchanan et al. 1999; Barnett, Suh et al. 2000; Ragel and Jensen 2003). Up to 20% of meningiomas exhibit a more aggressive phenotype that does not respond to standard therapies (Kyritsis 1996). Adjuvant therapies are critical for patients with this subset of meningiomas. Radiation therapy and stereotactic radiosurgery are good adjuvant therapies but are limited by radiation neurotoxicity, tumor size constraints, and injury to adjacent vascular structures or cranial nerves (Goldsmith, Wara et al. 1994; Barnett, Suh et al. 2000; Goldsmith and Larson 2000). Standard chemotherapeutic treatments have been disappointing (Kyritsis 1996). Even drugs like temozolomide that have shown efficacy against malignant brain tumors have failed to inhibit the growth of refractory meningiomas in a phase II study (Chamberlain, Tsao-Wei et al. 2004).
1. Primary Objective: - To determine the efficacy and tolerability of palonosetron and dexamethasone in preventing acute CINV in brain tumor patients during the first 24 hours of receiving Irinotecan /Bevacizumab regimens. 2. Secondary Objective - To determine the safety and tolerability of palonosetron in brain tumor patients. - To determine the effects of glucocorticoid and anticonvulsants on the efficacy of palonosetron. - To determine the efficacy of palonosetron and dexamethasone in preventing delayed CINV in brain tumor patients during days 2-5. - To determine if patients receiving palonosetron have less fatigue than baseline.
The purpose of this study is to use an imaging method called functional magnetic resonance imaging (fMRI) in patients who have a tumor near an area of the brain that is believed to control language. The fMRI is a new kind of imaging that uses a strong magnetic field to look at functioning brain tissue. This kind of imaging will be used to study the effect of the brain tumor on your speech.