View clinical trials related to Central Nervous System Neoplasms.
Filter by:This is an open-label, Phase 1/2 multicenter dose escalation study in pediatric patients with relapsed or refractory extracranial solid tumors (Phase 1), with additional expansion cohorts (Phase 2) in patients with primary brain tumors harboring NTRK1/2/3 or ROS1 gene fusions, and extracranial solid tumors harboring NTRK1/2/3 or ROS1 gene fusions.
This study aims to determine the efficacy of daily sirolimus and celecoxib, with low dose etoposide alternating with cyclophosphamide for pediatric participants with relapsed or refractory tumors.
This study will explore neurocognitive performance in pediatric brain tumor patients receiving proton beam radiation therapy (PBRT). The investigators goal is to gather baseline neurocognitive testing prior to the completion of the first week of radiation therapy along with follow-up testing 6-12 months after the completion of radiation and serial annual testing thereafter. With these data the investigators plan to evaluate the effects of PBRT on neurocognitive performance as it relates to patients' age at diagnosis, tumor location, and radiation dose. Modeling studies have demonstrated that PBRT could improve neurocognitive outcomes, but there is a paucity of prospectively-collected patient data. The investigators are uniquely positioned to address this important question given the busy pediatric central nervous system (CNS) tumor service, the delivery of proton therapy at the S. Lee Kling Proton Therapy Center at Barnes-Jewish Hospital, and the multi-disciplinary research team with extensive experience into the late effects of therapy as it relates to neurocognition.
The development of next generation sequencing (NGS) techniques, including whole genome (WGS), exome (WES) and RNA sequencing has revolutionized the ability of investigators to query the molecular mechanisms underlying tumor formation. Through the Pediatric Cancer Genome Project (PCGP), investigators at St. Jude Children's Research Hospital (SJCRH) have successfully used NGS approaches to evaluate more than 1,000 pediatric cancers ranging from hematologic malignancies to central nervous system (CNS) and non-CNS solid tumors. From these and related studies, it has become clear that genomic approaches can accurately classify tumors into distinct pathologic and prognostic subtypes and detect alterations in cellular pathways that may serve as novel therapeutic targets. Collectively, these studies suggest that by characterizing the genomic make-up of individual tumors, investigators will be able to develop personalized and potentially more effective cancer treatments and/or preventive measures. This protocol was initially enacted to usher NGS approaches into routine clinical care. During the initial phase of the G4K protocol, 310 participants were recruited and enrolled onto the study. Tumor and/or germline sequencing was completed on all 310 patients, with 253 somatic reports generated (representing 96% of the 263 participants for whom tumor tissue was available and analyzed) and 301 germline reports generated (100% of the 301 participants who agreed to the receipt of germline results). Analyses of the study data are ongoing with plans to prepare initial manuscripts within the next several months. Due to the successful initial execution of the G4K protocol, clinical genomic sequencing of tumor and germline samples is now offered as part of standard clinical care for pediatric oncology patients at St. Jude. The G4K protocol has now been revised. With the revision, the study team will record, store and analyze germline and tumor genomic information. Through the collection of these data, we will examine how germline mutations in 150 cancer predisposition genes influence clinical presentation, tumor histology, tumor genomic findings, response to therapy and long-term outcomes. The overall goals of this research are to further define the prevalence, spectrum and heritability of germline variants in these genes and to decipher how germline mutations influence the phenotypes of an expanding array of cancer predisposition syndromes. These studies allow us to provide more accurate genetic counseling and management strategies to future children harboring mutations in these genes. This remains a non-therapeutic study. Investigators anticipate a sample size of approximately 5000 patients who will be recruited over the next 7 years.
Phase I/II, open, prospective clinical trial, historically controlled. The objective is to evaluate the safety and, as a secondary measure, the efficacy of an experimental treatment based on a cellular therapy (vaccination with autologous dendritic cells pulsed with tumor lysate) in patients affected of metastatic or relapsed sarcomas or (Central Nervous System) CNS tumors.
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. The investigators hypothesize that BLZ-100 will improve surgical outcomes by allowing surgeons to visualize the edges of the tumor and small groups of cancer cells that have spread to other sites in real-time as they operate. This is a safety study to assess the safety of BLZ-100 in pediatric patients with central nervous system tumors.
Laser Interstitial Thermal Therapy (LITT) is a minimally invasive surgical technique that allows for biopsy and thermal ablation of brain tumors. Pediatric patients with brain tumors who are eligible and enroll in the trial will undergo LITT at the time of diagnosis or at the time of recurrence/progression rather than undergo an open craniotomy and tumor resection/biopsy. LITT will include a stereotactic biopsy followed by thermal ablation of the tumor. This study will monitor the safety and efficacy of LITT for the treatment of pediatric brain tumors.
This phase I trial studies the side effects and best dose of pomalidomide in treating younger patients with tumors of the brain or spine (central nervous system) that have come back or are continuing to grow. Pomalidomide may interfere with the ability of tumor cells to grow and spread and may also stimulate the immune system to kill tumor cells.
This study gathers health information for the Project: Every Child for younger patients with cancer. Gathering health information over time from younger patients with cancer may help doctors find better methods of treatment and on-going care.
The purpose of this crossover, single-dose, bioequivalence study is to compare the rate and extent of absorption of Temozolomide after the administration of the study product (Dralitem®, Monte Verde S.A.) and the reference product (Temodal®, Schering Plough) in primary Central Nervous System patients.