View clinical trials related to Brain Neoplasms.
Filter by:The goal of this proposal is to test the performance of a novel optical imaging system for real-time quantitative imaging of brain function through multiple hemodynamic measures during neurosurgery. This pilot study encompasses two sub-aims: - Evaluate the ability of laser speckle contrast imaging to image cerebral blood flow (CBF) intraoperatively. We will image the changes in CBF in response to somatosensory stimulation. (5 patients). - Simultaneously image hemoglobin oxygenation, blood volume, blood flow, and cerebral metabolic rate of oxygen (CMRO2) changes during somatosensory stimulation using a combined laser speckle and multi-wavelength reflectance imaging system. (5 patients).
The first phase of the study will investigate if there is increased uptake of [F-18]FDOPA in pediatric brain tumors when compared to normal brain tissue.
If the anesthetic regimen can influence the serum level of inflammatory cytokines and if the levels of cytokines are related to the incidence of post operative complications, these complications may be a function of the anesthetic method. In an effort to find the best anesthetic regimen for patients undergoing craniotomy for intracranial tumors, the researchers will compare the effect of volatile anesthetic with that of total intravenous anesthesia (TIVA) on cytokine levels. The researchers will also compare the composite incidence of some common major post-operative complications after craniotomy for intracranial malignancy.
We have developed a safe, non-contact, intra-operative guidance system to optimize tumor resection in neurosurgery. The Modulated Imaging is non-contact optical imaging technology developed at the Beckman Laser Institute, UCI. Compared to other imaging approaches, MI has the unique capability of performing both diffuse optical tomography and rapid, wide-field quantitative mapping of tissue optical properties within a single measurement platform. Preliminary in vivo studies have shown that brain tumors, infiltrating tumor margins and normal brain may have intrinsically different optical properties.
Ionizing radiation produces cancer cell death by creating high levels of reactive oxygen species (ROS), such as superoxide and hydrogen peroxide, in irradiated cells. Cancer cells are preferentially affected by ROS. The investigators, therefore, propose that interfering with the detoxification of ROS will make radiation more toxic to cancer cells. Several cellular mechanisms exist to detoxify ROS, and glucose metabolism plays an important role in many of these mechanisms. The investigators propose that interfering with glucose metabolism will sensitize cancer cells to radiation. The investigators' central hypothesis is that 2DG will sensitize cancer cells to ionizing radiation by inhibiting the use of glucose to detoxify reactive oxygen species produced by radiation. As an initial step to evaluate this hypothesis, the investigators have designed this phase I study.
Primary Objective: - The primary objective is to evaluate the efficacy of photodynamic therapy in the treatment of malignant intracranial tumors. Secondary Objective: - The secondary objective is to evaluate the safety of photodynamic therapy in the treatment of malignant intracranial tumors.
Clinical measurement of renal function is generally performed using either laboratory tests or nuclear medicine techniques, however, both of these techniques suffer from some limitations. Notably the lab tests only assess global, rather than individual kidney, function and the nuclear medicine tests are demanding to perform well. Children with brain tumors are often treated with chemotherapeutic in order to try and kill the cancer. Amongst the known side effect of some of the drugs used in the chemotherapy is the fact that they may damage the kidneys. For this reason the function of the kidneys is assessed using a laboratory test at 3 or 6 months intervals during the treatment. In addition, to the problem mentioned above the tests also require a separate visit to the hospital. Children with brain tumors who are undergoing chemotherapy also routinely have contrast-enhanced MRI of the brain performed at intervals of three months in order to evaluate the response of the tumor to the chemotherapy. Recently, MRI techniques have been developed which can evaluate single kidney renal function. The aim of this study is to establish if a single MRI exam can be used to assess both the effect of the chemotherapy on both the tumor and the renal function. The results of the MRI measurement of the single kidney renal function would be combined to provide a measure of global renal function and this would be compared with that obtained from the laboratory test. The MRI exam will require only require an extra 10 minutes of scanning time and will not affect the rest of the MRI exam in any way. This study is being performed to validate a new technique for measuring kidney function. Patients are being asked to volunteer for this study because they require serial contrast enhanced MR scans to monitor their response to chemotherapy. Because some chemo-therapeutic agents can be toxic to the kidney the patient's kidney function will also be evaluated using conventional methods, and the results of these tests can be compared to those obtained using MRI. We plan to study 50 children in this study. The additional procedure for measuring renal function will add 10 minutes to the duration of the MRI exam and will have no effect on the routine brain study. If validated the proposed MRI technique would allow renal function to be evaluated at the time of a routine, contrast enhanced MRI exam and would avoid additional testing using radioactive tracers or urine collection over 24 hours. If successful, MRI could be used to measure single kidney renal function in all any patient undergoing a routine MRI exam by simply extending the scanning time by a maximum of 10 minutes. This would save such patients additional visits to the hospital and would have the advantage of measuring single kidney, rather than global, renal function.
The purpose of this study is to examine the safety and efficacy of XERECEPT (human Corticotropin-Releasing Factor, or hCRF) compared to dexamethasone in patients with primary malignant glioma who require increased dexamethasone doses to control symptom of peritumoral brain edema.