Active clinical trials for "Oligodendroglioma"

The Investigators will examine the disease specificity of 2-hydroxyglutarate in non-glioma brain lesions, and the clinical utility of 2-hydroxyglutarate, glycine and citrate in isocitrate dehydrogenase (IDH) mutated gliomas and IDH wild type gliomas.

This pilot clinical trial studies gallium Ga 68-edotreotide (68Ga-DOTATOC) positron emission tomography (PET)/computed tomography (CT) in finding brain tumors in younger patients. Diagnostic procedures, such as gallium Ga 68-edotreotide PET/CT imaging, may help find and diagnose brain tumors.

The objective of this study is to evaluate patients with tumors of the central nervous system (CNS) for eligibility in the National Cancer Institute s research studies. These patients will undergo a series of procedures, usually including a complete medical history and physical examination; laboratory testing of blood, CSF, urine, bone marrow, or other samples; an evaluation of tumor location and size by x-rays, CT (computed tomography) or MRI (magnetic resonance imaging) scans, or nuclear medicine scans; lumbar puncture; electrocardiogram and echocardiogram; and procedures to evaluate the function of specific organs. A bone marrow biopsy is occasionally performed. Research samples may also be collected and stored to avoid having to do a painful test more than once. Tissue specimens collected during this process may be stored and used in future studies. Patients of both genders, any age, and all racial and ethnic groups with tumors of the CNS or a history of a CNS tumor are eligible. Up to 100 people are expected to participate. The physician will discuss the results of these procedures with the patient and his or her family. On the basis of the eligibility screening and the patient s wishes, the patient may then be enrolled in a primary research protocol.

This study will analyze tissue and blood samples from patients with gliomas (a type of brain tumor) to develop a new classification system for these tumors. Tumor classification can help guide treatment, in part by predicting how aggressive a tumor may be. Gliomas are currently classified according to their grade (how quickly they may grow) and the type of cells they are composed of. This system, however, is not always accurate, and sometimes two tumors that appear to be identical under the microscope will have very different growth patterns and responses to treatment. The new classification system is based on tumor genes and proteins, and may be used in the future to better predict a given tumor s behavior and response to therapy. Patients with evidence of a primary brain tumor and patients with a known glioma who will be undergoing surgery to remove the tumor may participate in this study. A sample of tumor tissue removed in the course of a participant s normal clinical care will be used in this study for laboratory analysis of genes and chromosome abnormalities. A small blood sample will also be collected for genetic analysis. In addition, clinical information on patients condition and response to treatment will be collected every 6 months over several years. This information will include findings from physical and neurologic examinations, radiographic findings, and response to therapy, including surgery, radiation and chemotherapy.

This research trial studies qualitative, qualitative, and functional studies over the first year in measuring immune system response in patients with brain tumors. Measuring the number of immune cells, whether these immune cells work correctly, and response to 2 vaccines at several times during the first year of treatment may help find out how active the immune system responds to fight infection and cancer.

At present, diagnosis of oligodendroglioma is made on histological and radiographic criteria in the French Mayo-Ste Anne classification. The less frequent grade A oligodendrogliomas are characterized by no vascular contrast on RMN evaluation comparatively to grade B forms. This benign histological subtype relapses in few cases with a more aggressive histology. To determine these relapsed cases at diagnosis, a collection of tumour begun in February 2004. Then, our study was designed to identify diagnostic molecular and metabolic markers that could eventually be used as a signature characterising grade A versus grade B oligodendrogliomas. The molecular analysis will use genomic techniques like allelotyping study, quantitative real-time PCR, gene sequencing , serial analysis of genomic expression and immunohistochemistry, since the metabolic study will be the spectroscopic examination of in vivo tumour. This study will include paediatric and adult patients followed for oligodendrogliomas, medulloblastomas and gliomas to compare the different tumour signatures. All these results will be correlated to survival and clinical features.

The Investigators will examine the disease specificity of 2-hydroxyglutarate in non-glioma brain lesions, and the clinical utility of 2-hydroxyglutarate, glycine and citrate in IDH mutated gliomas and IDH wild type gliomas.

The purpose of this study is to collect and store brain tissue samples and blood from children with brain cancer that will be tested in the laboratory. Collecting and storing samples of tumor tissue and blood from patients to test in the laboratory may help the study of cancer in the future.

This study offers evaluation of patients with brain and spinal cord tumors. Its purpose is threefold: 1) to allow physicians in NIH s Neuro-Oncology Branch to increase their knowledge of the course of central nervous system tumors and identify areas that need further research; 2) to inform participants of new studies at the National Cancer Institute and other centers as they are developed; and 3) to provide patients consultation on possible treatment options. Children (at least 1 year old) and adults with primary malignant brain and spinal cord tumors may be eligible for this study. Participants will have a medical history, physical and neurological examinations and routine blood tests. They may also undergo one or more of the following procedures: Magnetic resonance imaging (MRI) MRI is a diagnostic tool that uses a strong magnetic field and radio waves instead of X-rays to show detailed changes in brain structure and chemistry. For the procedure, the patient lies on a table in a narrow cylinder containing a magnetic field. A contrast material called gadolinium may be used (injected into a vein) to enhance the images. The procedure takes about an hour, and the patient can speak with a staff member via an intercom system at all times. Computed axial tomography (CAT or CT) CT is a specialized form of X-ray imaging that produces 3-dimensional images of the brain in sections. The scanner is a ring device that surrounds the patient and contains a moveable X-ray source. The scan takes about 30 minutes and may be done with or without the use of a contrast dye. Positron emission tomography (PET) PET is a diagnostic test that is based on differences in how cells take up and use glucose (sugar), one of the body s main fuels. The patient is given an injection of radioactive glucose. A special camera surrounding the patient detects the radiation emitted by the radioactive material and produces images that show how much glucose is being used by various tissues. Fast-growing cells, such as tumors, take up and use more glucose than normal cells do, and therefore, the scan might indicate the overall activity or aggressiveness of the tumor. The procedure takes about an hour. When all the tests are completed, the physician will discuss the results and potential treatment options with the patient. Follow-up will vary according to the individual. Some patients may end the study with just one visit to NIH, while others may be followed at NIH regularly, in conjunction with their local physicians. Patients with aggressive tumors may be seen every 3 or 4 months, while those with less active tumors may be seen every 6 to 12 months. Permission may be requested for telephone follow-up (with the patient or physician) of patients not seen regularly at NIH. ...

Oligodendrogliomas represent a distinct subgroup of adult gliomas characterized by specific molecular alterations (1p/19q codeletion, mutations of IDH, TERT promoter, CIC, FUBP1). These tumors account for 5 to 10% of adult gliomas and are of special relevance in the neuro-oncology field because of their frequent chemosensitivity (Louis et al. 2016). The genetics of oligodendrogliomas is relatively well characterized but the mechanisms of oncogenesis for these tumors are poorly understood. Although oligodendrogliomas prognosis is usually better than that of other adult glioma subtypes, it remains heterogeneous and there is no effective treatment at recurrence after radiotherapy and chemotherapy. Our recent work conducted within the INCa-funded national POLA network has related this clinical heterogeneity to inter-tumoral heterogeneity. Based on a transcriptomic analysis of a large series of oligodendroglial gliomas we identified 3 subgroups, the most aggressive group being characterized by aggressive clinical and molecular pattern. Recent studies, however, have shown a relatively low level of concordance between mRNA and protein expression, emphasizing the need to use proteomic-based approaches to better understand tumor biology. Taking advantage of the POLA cohort, we propose to expand our previous analysis by integrating a proteomic analysis of oligodendrogliomas. The aim of this project is to identify drivers of oligodendroglioma subgroups, among which potential druggable targets (i.e receptors, metabolism effectors). For this purpose, the proteomic profiles of 90 oligodendrogliomas will be generated and integrated with transcriptomic, genomic and methylation profiles in order to identify signaling pathways specifically associated with each subtype, especially with the most aggressive one. Associations will be explored between candidate signaling pathways expression and clinical outcomes (survival, progression-free survival, objective response). The relevance of the 2 most promising candidate signaling pathways will be assessed in vitro and in vivo using genetically relevant mouse and xenograft models. Our project will identify targetable oncogenic pathways associated with poor prognosis that could lead to new therapeutic strategies.