View clinical trials related to Brain Neoplasms.
Filter by:This research study is evaluating an investigational drug, an oncolytic virus called rQNestin34.5v.2. This research study is a Phase I clinical trial, which tests the safety of an investigational drug and also tries to define the appropriate dose of the investigational drug as a possible treatment for this diagnosis of recurrent or progressive brain tumor.
The purpose of this study is to determine the ability of letrozole to penetrate the blood brain barrier and concentrate in gliomas.
This research study is studying two different types of radiation as treatment for brain metastases (tumors in the brain that spread from a cancer that originated elsewhere in the body)
This is a non-randomized, purely observational, feasibility study to detect metabolic changes in patients with brain malignancy using a novel hyperpolarized [1-13C]pyruvate MRSI.
The goal of this prospective, non-randomized, single-arm, feasibility study is to develop data to evaluate the safety and feasibility of ExAblate 4000 treatment of benign intracranial tumors which require clinical intervention in pediatric and young adult subjects. Indication of Use: Ablation of benign intracranial tumors in children and young adults which are ExAblate accessible.
This clinical trial was designed to investigate the efficiency and toxicity of tomotherapy for refractory brain metastases.
In this study the investigators will evaluate the effect of high-dose, intermittent sunitinib versus treatment with lomustine in patients with recurrent glioblastoma multiforme. The investigators hypothesize that sunitinib, when given in a high-dose, intermittent schedule, will achieve adequate concentration levels in the tumor and will, besides its anti-angiogenic properties, inhibit gliomagenesis by inhibition of multiple kinases.
Based on evidence that radiation-induced damage to the hippocampus plays a considerable role in neurocognitive decline after cranial irradiation, hippocampal-sparing whole brain radiation therapy (HS-WBRT) has been proposed. This study will investigate the neurocognitive function and prognosis between HS-WBRT and conventional WBRT for the treatment of brain metastases from breast cancer.
The purpose of the research study is to test new methods that could improve diagnosis and assessment of brain tumors. One of these methods is a new MR (magnetic resonance) imaging technique called magnetic resonance fingerprinting (MRF), which allows for rapidly scanning the patient and provides quantitative information on tumor tissue. The investigators will compare the data gathered from MR Fingerprinting with other imaging tests, clinical information, treatment details and biopsy results to evaluate the accuracy of this new technique.
The investigators will focus on three cohorts of brain tumor patients aged, 4-18 years, to answer two critical questions: 1) Can the investigators acquire high quality data relevant to cognitive function during the peri-diagnostic period and, 2) can the investigators develop predictive models for cognitive outcomes using serial examination of functional imaging and cognitive function. Any patient with a newly diagnosed brain tumor aged 4-18 will be eligible for enrollment in cohort 1. Only patients with previously diagnosed tumors of the posterior fossa will be eligible for cohort 2. For cohort 3, eligible patients will include patients with a clinical diagnosis of posterior fossa syndrome with physical impairments that prohibit completion of the NIH Toolbox Cognitive Battery. The investigators have decided to expand the eligible tumor types to better capture the most significant deficit variability that can be caused by tumors outside the posterior fossa. Thus, this focus will provide a platform to analyze the impact that different tumor types and different standard treatments have on cognitive dysfunction. The rationale for inclusion of subjects on cohort 3 is that posterior fossa syndrome is one of the most cognitively devastating diagnoses following a posterior fossa surgery. The causes of posterior fossa syndrome and unknown and there are currently no interventions to improve symptoms. RsfcMRI would offer a novel and non-invasive assessment of posterior fossa syndrome patients by assessing connectivity within and outside of the cerebellum. Expanding the tumor eligibility will allow us to further explore the effect tumor location will have on cognitive testing and rsfcMRI. Here, repeated evaluations on and off therapy will provide the necessary data points to establish trajectories of cognitive development and recovery in this population.