View clinical trials related to Gliomas.
Filter by:The purpose of this study is to determine the safety and utility of 5-aminolevulinic acid (ALA) for identifying your tumor during surgery. 5-ALA is not FDA approved at this time. When the investigators remove the tumor from your brain, it is important that they remove all of the tumor and not remove parts of normal brain. Sometimes this can be difficult because the tumor can look like normal brain. In some brain tumors, 5-ALA can make the tumors glow red under blue light. This may make it easier for your doctor to take out all of the tumor from your brain. The purpose of this study is to: - Make sure that 5-ALA helps the doctor remove more of the tumor. - Make sure 5-ALA does not cause any side effects. If you do not want to participate in this study, your doctor(s) will still do their best to remove all of the tumor in your brain. Whether or not you join this study will not change your treatment for your brain tumor.
Background: - An important new area of brain tumor research is the development of tumor and brain stem cell lines. Successful growth of these cell lines requires obtaining large volumes of fresh tumor and brain tissue, which is best accomplished by harvesting whole brains from recently deceased patients. These cell lines will help researchers understand how these tumors develop and will also help identify new targets for treatment. Researchers are interested in conducting a pilot study of planned inpatient hospice care with timely brain tumor tissue harvest at the time of death. Objectives: - To provide high-quality end of life inpatient hospice care for patients with untreatable brain tumors. - To procure brain and tumor tissue shortly after time of death in order to derive viable tumor and neural stem cell lines for research purposes. Eligibility: - Individuals at least 18 years of age who have an untreatable primary brain or central nervous system tumor, are able to give informed consent (either their own or through a designated power of attorney), and have agreed to a Do Not Resuscitate order and Consent for Autopsy as part of the end-of-life care plan. - HIV-positive individuals or those suspected of having infectious cerebritis are not eligible because of the potential for contamination of brain tissue. Design: - Participants will be enrolled in inpatient hospice admission to the National Institutes of Health Clinical Center either from home or from an outside hospital once a study investigator estimates an expected survival of less than 2 weeks. - Participants will receive palliative care at the Clinical Center. Care will be tailored to each participant depending on the information provided in the individual's end-of-life care plan. - Supportive medications such as antiseizure medications and pain relievers will be administered as appropriate. - At the time of death, researchers will follow standard procedures for notifying next of kin and will collect brain tissue and tumor samples from the deceased. - Following tissue collection, the deceased will be released for autopsy and funeral procedures.
In this study, we evaluate the role of diffusion kurtosis imaging (DKI) and MR spectroscopy (MRS), two advanced imaging techniques in magnetic resonance (MR) in grading and detection of microscopic infiltrating tumour in gliomas. These parameters are of utmost importance in optimal choice and planning of treatment. Patients treated with gliomatous brain tumours are included voluntarily. They undergo one imaging session on a 3T MR scanner prior to treatment. DKI data are quantitively analyzed in order to estimate specific parameters in normal appearing white matter, grey matter, tumor and peritumoral edema. MRS data are analyzed quantitatively and qualitatively with peak integration, ratio calculation and classification algorithms. Histological confirmation is obtained at subsequent surgery. Information from this study can be of significant importance in avoiding brain biopsies. Furthermore, information on microscopic tumour spread can be used during neurosurgery or in radiotherapy planning. An important advantage of these advanced MR techniques is the non-invasivity and the lack of ionizing radiation, two important issues in this relatively young patient population.
The purpose of this research study to determine if treating recurrent malignant gliomas with another person's (donor) immune system cells known as aCTL cells, will be safe. This study will also try to determine if persons who receive aCTL's are more or less likely to survive their brain tumor than persons who had similar tumors in the past. Approximately 15 patients will be enrolled at UCLA.
The purpose of this study is to evaluate changes in tumor blood flow and disease response to the investigation agent, 177Lu-J591.
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.
Data from the wistar institute indicated that this anti-body labeled with iodine-125 would localized in the tumor cells of high grade gliomas of the brain. the project combines surgery, radiation therapy, chemotherapy with the labeled antibody in a prospective phase II trial in this disease entity.
Patients have a newly diagnosed brain tumor called a malignant glioma and participate in the study to see if it is possible to increase the benefit of temozolomide when given after radiation. A recent study showed that patients with newly diagnosed glioblastoma lived longer when treated with both temozolomide and radiotherapy followed by 6 months of temozolomide than patients treated with radiotherapy alone. Patients will receive standard low dose temozolomide during radiation. After radiation, they will be randomized to receive either more intense temozolomide or continuous low dose temozolomide.