View clinical trials related to Central Nervous System Neoplasms.
Filter by:The purpose of research is to study to adverse cardiovascular disorder and risks factors in childhood cranial and craniospinal tumors survivors. In this research the investigators investigate cardiological instrumental diagnostic, such as electrocardiography, echocardiography with the determination of global longitudinal strain, cardiopulmonary exercise test, and diagnostic of endothelial function by Angioscan for the prediction of cardiovascular complications after cranial and craniospinal radiotherapy and chemotherapy.
This phase I trial collects blood samples to investigate the prevalence of changes in genes (genetic mutations) in solid tumor patient populations seeking care at Mayo Clinic Embedded Cancer Center at St. Vincent's Riverside. This may help doctors better understand and/or treat others who have genetic mutations.
Tumours of central nervous system (CNS) is the most common type of solid tumour in childhood. In China, there is limited epidemiology information. Released data from Chinese CDC did not include types of CNS tumours and geographic contribution. As the Children's Neuro-Oncology Group (CNOG) was established in China in May 2017, it makes studies from multiple centers in children's brain tumors become practical. This retrospective cross-sectional study was aligned on CNOG annual meeting in 2018 and research group was named as CNOG-MC001 (MC, multicenter) collaborative group.
This trial gathers information from patients with primary central nervous system or base of skull tumors that receive proton beam therapy and see if certain imaging techniques can help detect radiation-related changes over time. This study may help providers learn more about proton beam radiotherapy and how to improve the way it is delivered.
This trial studies the feasibility of using intensity modulated proton therapy to deliver craniospinal irradiation while avoiding the bones of the vertebral column. Intensity modulated proton therapy is an advanced radiation therapy modality that uses high energy protons to kill cancer cells and shrink tumors, and may reduce the side effects of treatment by reducing radiation exposure to the spinal column.
The integrated cancer research site (SIRIC) of Montpellier proposes to develop a prospective and regional Clinical Database Project and regional biological collection (blood and tumor samples), which is an expanding data collection designed to contribute to a better understand the patient's management with brain metastases including quality of life and neuropsychological/cognitive aspects.
Safety and Efficacy Study in pediatric subjects <2 years of age who have undergone Brain or Spine MRI pre and post 0.1 mmol/kg ProHance administration. Imaging conditions will represent those in routine clinical practice. Retrospective enrolment with a prospective blinded read.
Pediatric high-grade gliomas are highly aggressive and treatment options are limited. The purpose of this first-in-pediatrics study is to examine the safety, tolerability, and pharmacokinetics of GDC-0084 and to estimate its maximum tolerated dose (MTD) when administered to pediatric patients with diffuse intrinsic pontine glioma (DIPG) or other diffuse midline H3 K27M-mutant gliomas after they have received radiation therapy (RT). GDC-0084 is a brain-penetrant inhibitor of a growth-promoting cell signaling pathway that is dysregulated in the majority of diffuse midline glioma tumor cells. This study is also designed to enable a preliminary assessment of the antitumor activity of single-agent GDC-0084, in the hope of enabling rational combination therapy with systemic therapy and/or radiation therapy (RT) in this patient population, which is in desperate need of therapeutic advances. Primary Objectives 1. To estimate the maximum tolerated dose (MTD) and/or the recommended phase 2 dosage (RP2D) of GDC-0084 in pediatric patients with newly diagnosed diffuse midline glioma, including diffuse intrinsic pontine glioma (DIPG) 2. To define and describe the toxicities associated with administering GDC-0084 after radiation therapy (RT) in a pediatric population 3. To characterize the pharmacokinetics of GDC-0084 in a pediatric population Secondary Objectives 1. To estimate the rate and duration of radiographic response in patients with newly diagnosed DIPG or other diffuse midline glioma treated with RT followed by GDC-0084 2. To estimate the progression-free survival (PFS) and overall survival (OS) distributions for patients with newly diagnosed DIPG or other diffuse midline glioma treated with RT followed by GDC-0084
Many types of cancer are primarily treated with surgery and patient survival is directly related to the extent to which the tumor is able to be removed. It is often difficult for surgeons to distinguish tumor tissue from normal tissue or to detect tumor cells that have spread from the original tumor site, resulting in incomplete removal of the tumor and reduced patient survival. In some sites, such as the brain, it is critical to avoid damage to normal tissue around the tumor to prevent adverse effects of surgery on function. Tozuleristide is a drug that is thought to attach to tumor tissue and then fluoresces (glows) when a special light from the Canvas is shined on it. It is hypothesized that tozuleristide, when imaged with the Canvas, will improve surgical outcomes by allowing surgeons to visualize the edges of the tumor or other ambiguous tissue in real-time as they operate. The purpose of this study is to evaluate how well tozuleristide imaged with Canvas work at helping to distinguish between tumor and normal tissue during surgery in pediatric primary central nervous system tumors.
This early phase I trial studies how well hyperpolarized carbon C 13 pyruvate magnetic resonance imaging works in detecting lactate and bicarbonate in participants with central nervous system tumors. Hyperpolarized carbon C 13 pyruvate magnetic resonance imaging may be used to measure the metabolic state of malignant brain tumors.