View clinical trials related to Brain Tumor.
Filter by:The study is an open-label pilot study in newly diagnosed glioblastoma patients following surgery. Eligible patients will receive treatment with tumor treating fields therapy using the Optune device starting less than 2 weeks prior to start of chemoradiation. Patients will receive radiation and temozolomide at a routine treatment dose and schedule.
Dynamic contrast-enhanced (DCE) magnetic resonance imaging (MRI) is a potentially powerful diagnostic tool for the management of brain cancer and other conditions in which the blood-brain barrier is compromised. This trial studies how well precise DCE MRI works in diagnosing participants with high grade glioma that has come back or melanoma that has spread to the brain. The specially-tailored acquisition and reconstruction (STAR) DCE MRI could provide improved assessment of brain tumor status and response to therapy.
This protocol is designed to assess the need for seizure prophylaxis in the perioperative period for patients undergoing neurosurgical procedure (gross-total resection, sub-total resection or biopsy) for suspected diagnosis of new, recurrent or transformed glioma (WHO grade I-IV) and brain metastasis. This will be determined by observing the impact of Lacosamide (LCM), Levetiracetam (LEV), or no anti-epileptic drug (AED) on whether visits to the emergency department (ED) or hospital re-admissions occur within 30 days after procedure. A secondary endpoint will evaluate the safety and tolerability of LCM and LEV. Exploratory endpoints will evaluate admission duration for the procedure, number of post-operative provider communications (telephone, email, and additional clinic encounters, etc.), and patient risk factors associated with post-operative seizure.
This study aims to evaluate anatomical and functional changes during RT for patients receiving fractionated RT for brain tumors. Anatomical changes during RT will be registered and analyzed and if needed the radiotherapy plan will be modified for the individual patient. This means that the "to be irradiated volume" will be modified according to the shape changes of the tumor. The functional MRI sequences will be used to evaluate what parameters, and at which time point, are important for radiotherapy outcome.
The hypothesis of this exploratory clinical trial in patients with high-grade a primary brain tumor who receive chemoradiation is that the PET imaging agents [18F]Fluciclovine and/or [18F]FLT will be a better predictor of tumor response than standard MRI based brain tumor response criteria. When used in conjunction, the two PET agents may be better able to predict tumor aggressiveness and thus overall survival than the use of individual-tracer PET biomarkers. This may eventually lead to improved assessment of response (including time to progression and overall survival) and differentiation of tumor recurrence/progression from treatment effect (pseudoprogression).
This project attempts to correlate wireless activity data with quality of life and sleep surveys in order to find a new method of monitoring patients during their treatment.
In the setting of progressive or recurrent cancer, adolescent and young adult (AYA) patients, parents, and healthcare providers (HCP) are faced with multiple therapeutic options. Each treatment option has a unique risk/benefit ratio, resulting in a need to trade one desirable outcome for another or accept acute toxicities and treatment-related morbidity to increase the chance of survival. Adding to the complexity of this decision, stake holders characterize and value the risk/benefit ratios differently. This study seeks to learn what things are important to an adolescent or young adult with cancer, parents, and health care providers when making decisions about their treatment choices. PRIMARY OBJECTIVE: To quantify the relative importance of various factors believed to be important to adolescent and young adult patients with cancer, parents, and health care providers when choosing between treatment options in the hypothetical situation of progressive or refractory disease.
Topotecan is an FDA-approved drug when given by intravenous infection. The purpose of this study is to determine if treatment with topotecan by an alternative method, direct delivery into the part of the brain where the tumor has spread, is safe and well tolerated. The Cleveland Multiport Catheter is a new, investigational device that will be used to deliver topotecan into tumor-infiltrated brain. A second purpose of this study is to determine whether the Cleveland Multiport Catheter can be used effectively and safely to deliver topotecan into tumor-infiltrated brain. This study will also examine how tumors responds to treatment with topotecan. This study will also look at the way topotecan is injected into tumors-infiltrated brain. A small amount of contrast dye (called gadolinium DTPA) will be added to topotecan before it is injected. Pictures will be taken of the brain with an MRI machine. This will allow the investigators to see where in the tumor-infiltrated brain the topotecan has been injected. This study will collect medical information before, during, and after treatment in order to better understand hot to make this type of procedure accessible to patients.
This study will look at the feasibility of using magnetic resonance fingerprinting (MRF) in children, adolescents and young adults (AYA) with and without brain tumors. This study will also look at subjects with and without neurofibromatosis type 1(NF1), a genetic disorder that affects the growth of nervous system cells. Further, it will explore potential ways of using of MRF signal measurements in children, adolescents, and young adults with brain tumors, including tissue characterization, looking at whether the treatment was effective, and finding metastasized tumors of unknown origin (occult tumors). To explore the feasibility and potential applications of MRF, this study will recruit up to 80 subjects but will stop once 10 subjects have usable data in each of six groups.
This protocol is designed to generate and provide preliminary data to determine the safety and activity of combination therapy using tumor treating fields (TTFields; Optune(NovoTTF-100A); Novocure, Haifa, Israel), a novel FDA-approved therapy utilizing alternating electric fields to inhibit tumor cell growth, along with bevacizumab (Avastin; Genentech, San Francisco, CA), a humanized monoclonal antibody that inhibits vascular endothelial growth factor (VEGF), and hypofractionated stereotactic radiotherapy, a highly-focal abbreviated course of brain irradiation, in the treatment of patients with bevacizumab-naive recurrent GBM. Each of these individual therapies, and also several combinations in doublets, has already demonstrated safety and efficacy but prospective clinical data for the concurrent combination of all three therapies are lacking.