View clinical trials related to Brain Neoplasms.
Filter by:MRI is used in clinical routine for diagnosing brain tumors, but has limitations in identifying tumor grade, true tumor extension and differentiate viable tumor tissue from treatment induced changes and recurrences. Amino acid PET has demonstrated a great potential for defining true tumor volume, differentiate viable tumor tissue from postoperative changes or radiation necrosis, selection of biopsy site, non-invasive grading of gliomas and for treatment planning and therapy response assessment. By combining PET with MRI, the diagnostic accuracy can improve significantly for these patients. More research is however needed to compare the most promising amino acid PET tracers in patients with glioma, but also to assess the diagnostic value of amino acid PET in patients with different brain metastases, where the knowledge concerning the uptake characteristics is limited. Three of the most promising amino acid tracers ([11C]-methyl-methionine (11C-MET), [18F] fluoro-ethyl-tyrosin (18F-FET) and anti-1-amino-3-[18F]fluorocyclobutane-1-carboxylic acid (18F-FACBC)) will be evaluated in 3 substudies in this project; WP1 Aminoacid PET/MRI in low and high grade glioma; WP2 Role of 11C-MET in high-grade glioma Gamma Knife® radiosurgery; and WP3 Amino acid PET in brain metastasis. The main aim of the study is to improve diagnostic accuracy, histopathological tissue sampling, delineation of tumor extent and therapy response assessment in gliomas and brain metastases with amino acid PET/MRI.
Despite some encouraging data, systemic treatment of CNS metastases from solid tumors remains experimental. Better knowledge on the evolving epidemiology and biology of BM are key elements for the development of new treatment strategies and identification of promising therapeutic targets for new compounds. Further biological findings may help to better understand the heterogeneity between the primary tumor and the CNS metastases and to identify new targets for therapy thus improving patients' outcome. In this context, the Oncodistinct network and the Jules Bordet institute propose to build a multidisciplinary Brain Metastases Clinical Research Platform called BrainStorm. The BrainStorm program will focus on patients with newly diagnosed non-CNS metastatic solid tumors with high risk of developing CNS metastases and will allow building a large clinico pathological database for CNS metastases including ctDNA analyzes from CSF samples. Substudies will be proposed at each time-period with the final objective to develop innovative treatment approaches and strategies.
Aim of this study is to investigate the influence of social factors on participation and activity among children and adolescents aged 10-18 years with leukemia, brain tumors, and sarcomas. Furthermore personal and treatment-related factors and their impact on participation will be explored
This study is for patients with diffuse midline glioma, high grade glioma, diffuse intrinsic pontine glioma, medulloblastoma, or another rare brain cancer that expresses GD2. Because there is no standard treatment at this time, patients are asked to volunteer in a gene transfer research study using special immune cells called T cells. T cells are a type of white blood cell that help the body fight infection. This research study combines two different ways of fighting cancer: antibodies and T cells. Both antibodies and T cells have been used to treat cancer patients. They have shown promise but have not been strong enough to cure most patients. Researchers have found from previous research that they can put a new antibody gene into T cells that will make them recognize cancer cells and kill them. GD2 is a protein found on several different cancers. Researchers testing brain cancer cells found that many of these cancers also have GD2 on their surface. In a study for neuroblastoma in children, a gene called a chimeric antigen receptor (CAR) was made from an antibody that recognizes GD2. This gene was put into the patients' own T cells and given back to 11 patients. The cells did grow for a while but started to disappear from the blood after 2 weeks. The researchers think that if T cells are able to last longer they may have a better chance of killing tumor cells. In this study, a new gene will be added to the GD2 T cells that can cause the cells to live longer. T cells need substances called cytokines to survive. The gene C7R has been added that gives the cells a constant supply of cytokine and helps them to survive for a longer period of time. In other studies using T cells researchers found that giving chemotherapy before the T cell infusion can improve the amount of time the T cells stay in the body and therefore the effect the T cells can have. This is called lymphodepletion and it will allow the T cells to expand and stay longer in the body and potentially kill cancer cells more effectively. After treating 11 patients, the largest safe dose of GD2-CAR T cells given in the vein (IV) was determined. Going forward, IV infusions will be combined with infusions directly into the brain through the Ommaya reservoir or programmable VP shunt. The goal is to find the largest safe dose of GD2-C7R T cells that can be administered in this way. The GD2.C7R T cells are an investigational product not approved by the FDA.
The Multi-OutcoMe EvaluatioN of radiation Therapy Using the Unity MR-Linac Study (MOMENTUM) is a multi-institutional, international registry facilitating evidenced based implementation of the Unity MR-Linac technology and further technical development of the MR-Linac system with the ultimate purpose to improve patients' survival, local, and regional tumor control and quality of life.
Brain metastases are a source of much morbidity and mortality in adults with primary solid malignant tumors. With improvements in systemic therapy that prolong survival but have limited central nervous system penetration, patients with brain metastases are at increasing risk of developing and experiencing long-term side effects from treatment of brain metastases. The overarching goal of this study is to better understand the determinants of RT-associated changes in white and gray matter function and associated neurocognitive decline.
Brain tumors are the second most frequent malignant diseases in children and adolescents. In the study the short and medium term consequences of proton therapy on cognitive processes in particular on executive functions in pediatric patients shall be highlighted/analysed/evalutated. In a second step, these results are to be compared with 1. a group of children and adolescents who had only /exclusively had operative therapy and 2. with a healthy control group. Thus, the extent to which these treatment options differ in terms of their short and medium-term effect is assessed. Methods of neurocognitive/neurophysiology brain research approaches are applied that may potentially visualize even small / subtle changes in mental activities/neurocognitive function. Therefore the effects of treatment can be evaluated and the neuropsychological outcome of children and adolescents with brain tumors can be improved.
This trial studies how well nTMS works in planning for stereotactic radiosurgery in patients with brain metastases in the motor cortex. Stereotactic radiosurgery is a type of radiation therapy that delivers high doses of radiation, which can sometimes lead to damage occurring to the brain and surrounding areas. The motor cortex (the part of the nervous system that controls muscle movement), however, currently has no radiation dose limit. nTMS is a non-invasive tool that uses sensors on a patient's muscle to trace the location in their brain that controls that muscle and is currently used by doctors to decide where to operate so as not to damage the motor nerves. nTMS may effectively help plan radiation treatment using SRS and help doctors decide on how much radiation can be used on motor nerves.
Brain metastasis accounted for 10-15% of all breast cancer patients and even higher in patients with triple negative and HER2 overexpressed subtype. Stereotactic radiation is the standard option for patients with 1-4 brain metastases. Among patients with 1-4 brain metastases, many studies suggest that stereotactic radiation results in fewer neurologic side effects than whole brain radiation. Also, several studies had demonstrated that 5-10 lesions had similar overall survival by using whole brain radiotherapy or stereotactic radiotherapy. Fractionated stereotactic radiotherapy(FSRT) is increasingly administered in the brain metastatic patients and retrospective studies had shown that FSRT had better local control and lower brain radiation necrosis than single fraction stereotactic radiation. Therefore, In this study, we explore to treat 1-10 brain metastasis lesion in breast cancer patients with FSRT.
The purpose of this study is to evaluate the efficacy of icotinib alone or in combination with radiation therapy for NSCLC patients harboring EGFR mutation with brain metastases. The primary endpoint is overall survival .