View clinical trials related to Brain Cancer.
Filter by:This research protocol makes pictures of brain tumors. The pictures are made with a positron emission tomography (PET) scanner. PET scans use radioactivity to "see" cancer cells. We are using a new kind of PET scan. The new PET scan is called [18F]-FACBC PET. We will compare this to the standard PET scan. The standard PET scan is called [11C]-methionine PET. We expect these pictures will give us information about your tumor. We also hope to collect information about the amount of radioactivity exposure. We will measure radioactivity exposure to your tumor, brain and other organs. The research study results will be used to support the submission of an investigational new drug (IND) application to the Food and Drug Administration (FDA).
This is a pilot study. The goal of this study is to test whether Bevacizumab is safe enough in patients with brain tumors so that a larger study can be conducted. This study will also give us some information about whether the combination of Bevacizumab and radiation has potential to become an effective treatment for regrowing brain tumors. Bevacizumab is an experimental drug that blocks a molecule called VEGF that is found in high amounts in malignant gliomas. VEGF promotes the growth of blood vessels that bring nutrients to tumor cells. In studies with laboratory animals, Bevacizumab slowed the growth of several different types of human cancer cells by blocking the effects of VEGF. There is also evidence that Bevacizumab enhances the effects of radiation on tumor cell
A significant number of brain tumor patients who received radiation or chemotherapy have thinking problems as a result of their treatment. The purpose of this study is to find out if treatment with Aricept (donepezil) may improve some aspects of thinking abilities in patients with brain tumors who received radiation or chemotherapy. This research will also study whether persons having particular genes for a blood-borne substance called apolipoprotein E (APOE) are more likely to have thinking problems after radiation or chemotherapy treatment for their brain tumors. The findings of this study will help us find out whether Aricept can improve thinking abilities after cancer treatment, and whether some of the thinking difficulties may be in part related to having certain genes.
The purpose of this study is to test the effectiveness of perifosine in preventing further tumor growth using the established optimal dose of the drug. A second goal is to determine if perifosine can block the molecules in the tumor that drive it to divide and grow.
The purpose of this study is to obtain chemical information from part of your body without a biopsy. This is done using a technique called magnetic resonance spectroscopy (MRS) which is similar to magnetic resonance imaging (MRI) except that signals are detected from the chemicals (spectroscopy) naturally present in your body using radio waves. To receive this information from your body, small loops of wire (surface coils), placed near the tissue of interest, may be used to more effectively detect signals that come from the chemicals in your body. The investigators may use a second radio channel simultaneously, which will allow us to obtain greater chemical information (decoupling). The results may also help us to understand how this study can be used to help other patients with your condition.
This is a ten subject, phase 1 study. The purpose of the Phase 1 study is to demonstrate drug safety in a target group of subjects with high grade brain cancer. This population represents a potential clinical population that may benefit from this PET imaging tracer. The study will also begin collection of baseline imaging data and allow us to gain information to improve design and conduct of future trials.
The goal of this clinical research study is to learn if your thinking ability (cognitive function) will be better preserved by delivering whole brain radiation therapy immediately after radiosurgical treatment of 1-3 brain metastases or to carefully observe patients after radiosurgery and hold back whole brain radiation therapy until the disease comes back.
The Environmental Protection Agency has recognized that organophosphorus pesticides require close regulation and continued monitoring for human health effects and some (e.g chlorpyrifos) have been phased-out from the consumer market due to the special risk that it posed for children. There is growing evidence in support of the association between pesticide exposure and childhood leukemia. Studies of pesticides and their association with childhood cancer have been limited by study designs, self-reporting and lack of biological measurements. While several large studies in California found little evidence of an association between agricultural pesticide use and childhood leukemia, these results are in contrast with the associations observed with household exposures to pesticides. The real association may depend on timing of exposure, type of pesticide, dose and pathway of exposure. Furthermore, some persons may be more susceptible to the effects of specific pesticides due to inherited mutations in their detoxification pathways. We are conducting a pilot study to test the hypothesis that environmental exposure to pesticides in pregnancy or during the neonatal period, together with genetic susceptibility may lead to childhood ALL or brain cancer. The study is a multicenter, case-control study, based on collaboration between clinical researchers and basic science research to evaluate the risk for childhood cancer in relation to measured levels of pesticides (and their metabolites) and genetic polymorphisms. Biomarkers will be used to examine the risks of chronic low-dose exposures, and to characterize relationships between specific pesticides, childhood cancer and genetic susceptibility. Hypothesis: Interaction between environmental factors (pesticides) and maternal or child genetic polymorphisms may lead to childhood cancer.
The goal of this clinical research study is to learn if the combination of 6-Thioguanine, Xeloda (capecitabine), and Celebrex (celecoxib) with Temodar (temozolomide) or Lomustine (CCNU) is effective in the treatment of recurrent or progressive anaplastic glioma or glioblastoma multiforme in patients who have failed previous treatments. The safety of these combination treatment will also be studied. Objectives: 1.1 To determine the efficacy, as measured by 12 month progression-free survival, of TEMOZOLOMIDE or CCNU with 6-THIOGUANINE followed by CAPECITABINE and CELECOXIB in the treatment of patients with recurrent and/or progressive anaplastic gliomas or glioblastoma multiforme. 1.2 To determine the long-term toxicity of TEMOZOLOMIDE or CCNU with 6-THIOGUANINE followed by CAPECITABINE and CELECOXIB in recurrent anaplastic glioma or glioblastoma multiforme patients treated in this manner. 1.3 To determine the clinical relevance of genetic subtyping tumors as a predictor of response to this chemotherapy and long term survival
Study Objectives: - To compare the survival (overall, systemic, and neurological) of patients with single cerebral metastases treated with either conventional surgical resection or stereotactic radiosurgery. - To compare their rates of recurrence, complications, and their cognitive ability, functional status, and quality of life. Although surgical resection is a proven and effective treatment for brain metastases in patients with systemic cancer, stereotactic radiosurgery has been suggested to be equally effective and less morbid. Nonrandomized retrospective comparisons have been unable to resolve whether stereotactic radiosurgery is as effective as conventional surgery because of the complexity and variability of the population of patients with cancer and brain metastases. This controversy can only be resolved by a prospective randomized trial comparing these treatment modalities. Patients not randomized will be analyzed as a separate group.