View clinical trials related to Brain Neoplasms.
Filter by:This goal of this research study is to learn more about fatigue, sleep quality, and other symptoms in patients with primary brain tumors who are being treated with radiation therapy. Objectives: PRIMARY OBJECTIVE: 1. The primary objective of this study is to provide preliminary data describing the severity and change over time in fatigue using the Brief Fatigue Inventory (BFI) during radiation therapy for patients with primary gliomas. SECONDARY OBJECTIVES: 1. To evaluate longitudinal changes in the severity of symptoms and the mean symptom burden as measured by the M.D. Anderson Symptom Inventory-Brain Tumor Module (MDASI-BT) and mood using the Profile of Mood States (POMS) during radiation therapy. 2. To assess alterations in circadian rhythms using actigraphy during radiation therapy and the association with sleep quality tools - Pittsburgh Sleep Quality Index (PSQI) and the Epworth Sleepiness Scale(ESS), and the severity of BFI and MDASI-BT scores over time. 3. To explore the association between the levels of salivary hormones (melatonin and cortisol) and the occurrence of fatigue and symptom burden.
The purpose of this study is - to assess the feasibility and acceptability of massage therapyto examine the effects of massage therapy - to explore whether psychological outcomes are associated with changes in patient reported QoL.
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).
Removing a tumor from your brain is hard to do because, very often, brain tumors do not have boundaries that are easy for your surgeon to find. In many cases, the surgeon can't tell exactly where the tumor begins or ends. The surgeon usually can remove most of your tumor by looking at the MRI images that were taken of your brain before surgery. However, the surgeon does not have any good way to tell if the entire tumor has been removed or not. Removing the entire tumor is very important because leaving tumor behind may allow it to grow back which could decrease your chances of survival. It is possible to detect tumor cells by making them glow with a specific color of light (a process called fluorescence). This can be done by having you take the drug, ALA, before your surgery. ALA is a molecule that already exists in the cells of your body. Once enough of it is in your body, it gets converted into another molecule named PpIX. If blue light is shined on a tumor that has enough PpIX, it will glow with red light (fluorescence) that can be detected with a special camera. In this study, we want to determine how the fluorescence (red light) is related to the tumor which appears in the images that are normally taken of your brain (which the surgeon uses to guide the removal of your tumor) and the tumor tissue that will be removed during your surgery. Removing the entire tumor is very important because leaving tumor behind may allow it to grow back which could decrease your chances of survival.
The purpose of this research study is to determine if sunitinib can get past the blood-brain barrier and into the brain tumor. Sunitinib has shown promising results in treating other cancers and works by blocking blood flow to tumors, which may prevent them from growing further. At the present time, there is no chemotherapy that can cure glioblastoma. The reason why chemotherapy is not fully effective is that many drugs cannot penetrate into brain tumors. This is due to the presence of the blood-brain barrier (BBB) which normally protects the brain from substances in the blood.
The purpose of this study is to demonstrate the safety of giving Whole Brain Radiotherapy (WBRT) together with intrathecal liposomal cytarabine (DepoCyte®) for patients with leptomeningeal metastases. The study will compare the safety of giving DepoCyte at the same time as WBRT with giving the drug after WBRT is complete.
The primary objective of this study is to assess the efficacy of the radiopharmaceutical 3'-deoxy-3'-[F-18]fluorothymidine, [F-18]FLT, a tracor of cell proliferation, using Positron Emission Tomography (PET) imaging for the tumor diagnosis and prognosis in a group of 50 patients with different type of brain tumors.[F-18]FLT PET imaging will be compared to the current used imaging techniques of MRI, spectroscopy imaging, PET imaging using [11C]MET tracer, immunohistochemical analysis and clinical parameters.
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 learn if lapatinib when given in combination with temozolomide can help to control ependymoma that has come back after treatment. The safety of this combination will also be studied.
This phase II trial studies how well everolimus works in treating patients with recurrent low-grade glioma. Everolimus may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth or by blocking blood flow to the tumor.