Active clinical trials for "Brain Neoplasms"

Although the Magnetic resonance imaging with contrast is the gold standard for diagnosis of intra axial brain masses. The conventional Magnetic resonance imaging appearances of intra axial brain masses can be non-specific and even the use of contrast agent is of limited benefit. Contrast enhancement reflects only disruption of blood brain barrier. One third of high-grade malignancies are non-enhanced and may non-neoplastic lesions show contrast enhancement. Reliable differentiation of neoplastic from non-neoplastic brain masses, or of high grade from low grade tumor, is difficult with conventional Magnetic resonance imaging

Esophagectomy is the cornerstone of the curative treatment of esophageal carcinoma. Despite this treatment, patients can suffer from locoregional or distant metastatic disease and only a very selected group of patients can be cured: mostly those with recurrence in one single organ. Brain metastases are rare after esophagectomy for cancer, but they have a serious impact on survival. Agressive treatment is often moren difficult for brain metastases compared to other metastases and some risk factors have been identified earlier. There is an impression that the incidence of brain metastases in esophageal cancer patients has increased since the introduction of neoadjuvant treatment schemes. However, this is not clear yet. A potential explanation could be that chemotherapy disturbs the blood-brain-barrier, hereby facilitating the migration of tumor cells to the brain. The purpose of this study is to retrospectively analyze the incidence and potential risk factors of brain metastases in patients who underwent esophagectomy for esophageal cancer. Patients treated between 2000 and 2019 will be included and outcome parameters are Odds Ratio for brain metastases (comparison between primary surgery and neoadjuvant treatment followed by surgery), time to recurrence and risk factors, number and characteristics of the brain metastases.

Numerous studies document the ability of tumors to shed DNA into the blood stream. Circulating DNA can thus be recovered for analyses, representing a surrogate tumor material to test for potential applications in disease diagnosis and prognosis. Detection of genetic alternation is one of the most important tests for cancer patient since they offen correlated with the clinical course, prognosis and chemosensitivity of primary brain tumors. Currently in brain tumor patients these molecular aberrations can be analyzed only on tumor tissue that was obtained at surgery or biopsy. Paucity of pathologic samples or poor fixation technique often make the tissue samples unassessable for molecular aberrations. Therefore, the ability to extract tumor DNA from peripheral blood holds a great clinical significance. Still, the molecular aberration evaluated on serum DNA should be correlated and verified by comparison to standard evaluations performed on tumor samples. Our study aim is to evaluate the feasibility of using serum DNA for routine diagnosis of tumor molecular aberrations.

The HuR protein binds to AU-rich elements in the untranslated 3' region of messenger RNA, thus allowing their stabilization. Its targets include multiple cell cycle regulating proteins, cytokines and growth factors. In some cancers, its overall expression level but especially its cytoplasmic expression are correlated to a higher grade and constitute a poor prognostic factor. To date, HuR's deregulation mechanisms remain poorly understood. A few experimental studies have shown the role of certain microARNS, or of post-translational modifications. In brain tumours, HuR expression, its prognostic value and its deregulation mechanisms have been little studied to date. The first part of the project will be a monocentric retrospective study of human brain tumour samples collected during biopsies or surgical removal. We will first evaluate HuR expression in 140 brain tumors, including 40 meningiomas and 100 gliomas of increasing grade, and look for a correlation with histological grade and survival. We will then apprehend the consequences of its deregulation by analyzing different factors involved in the cell cycle and stress response markers. Finally, we will study the mechanisms of HuR deregulation by analyzing the expression level of several microRNAs (miR16, miR519) and the methylation state of HuR. The second part of the project will focus on cell lines from human brain tumours. We will first attempt to confirm the interactions between HuR and markers involved in the cell cycle and stress response, then the regulation of HuR by its methylation and by microRNAs (miR16 and miR519). We would also like to study the consequences of HuR inhibition and overexpression on cell proliferation, under various conditions of induced stress (pharmacological agents, physical stress). Finally, we will study the consequences of an experimental vitamin B12 deficiency on HuR expression and tumor cell adaptation to stress.

This registry study will evaluate patients with metastatic brain tumors undergoing, or having undergone, stereotactic radiosurgery (SRS) at Swedish Medical Center. Clinical outcomes will be evaluated at the 3, 6 and 12-month time points. Clinical data, SRS treatment data, and imaging data (including anatomic and advanced imaging sequences obtained prior to and serially following SRS) will be archived in an online informatics platform, specifically a metastatic brain tumor registry known as the Comprehensive Neuro-oncology Data Repository for Metastatic Tumors (CONDR - Mets).

The purpose of this study is to explore the experiences and needs of patients with a high-grade glioma and their caregivers. Semi-structured interviews with patients and caregivers will be conducted and analysed using Grounded-Theory approach.

Background and purpose: In adult, the half of the CNS neoplasms are metastatic, and high grade astrocytomas and oligodendrogliomas are most frequent malignant tumors among the last half. Recently, integrated MRI-PET (Biograph mMR, Siemens, Germany) was introduced, and can provide simultaneous whole body MRI-PET imaging as well as brain-specific advanced imaging (e.g. DWI, PWI, and DCE). The purpose of the present study is to evaluate whether the simultaneous MRI-PET acquisition can improve the diagnostic yield for the patients initially presented with brain tumors, and predict the prognosis in the patients diagnosed with primary high graded astrocytoma or oligodendroglioma.

The normal cerebral blood flow is guided by factors such as cerebral autoregulation (CA) and carbon dioxide reactivity (CO2R). Authors have demonstrated that CA and CO2R may be impaired in presence of intracranial tumors.Most studies pertaining to assessment of CA and CO2R in patients with brain tumors is limited to supratentorial tumors. Due to their anatomic location, posterior fossa tumors result in obstruction of ventricular outflow, produce hydrocephalus and features of raise intracranial pressure (ICP). It is possible that lesions in the posterior fossa may affect CA and CO2R. It should also be noted that posterior fossa surgeries are carried out in positions such as prone, lateral and sitting. Altered surgical positions themselves affect systemic hemodynamics which may influence cerebral blood flow; with presence of anesthetics further compromising the blood flow to the brain. Understanding the homeostatic mechanisms of CA and CO2R may help in deciding proper positioning of patients and maintenance of intraoperative hemodynamic. The aim of this observational study was to evaluate CA and CO2R in patients with posterior fossa tumor prior to surgical decompression of the lesion.

The goal of this research study is to investigate the role of genes that may point to a higher risk of developing a glioma. Researchers will use new gene mapping techniques to study how high-risk factors are passed on through a family's genes and increase the risk of developing gliomas. Objectives: We propose an international multi-center, multidisciplinary study consortium, GLIOGENE, to identify susceptibility genes in high-risk familial brain tumor pedigrees using the most sophisticated genetic analysis methods available. To address our hypothesis, we propose the following specific aims: Aim 1: Establish a cohort of 400 high-risk pedigrees for genetic linkage analysis. To date, we have identified and collected biologic samples from 20 high-risk families that have met our criteria of 2 or more relatives diagnosed with a brain tumor. From the 15 centers in the United States and Europe, we will screen and obtain epidemiologic data from approximately 17,080 gliomas cases to identify a target of 400 families for genetic analysis. We will establish a cohort of the first and second-degree relatives from these glioma cases to obtain new knowledge about how cancer aggregates in glioma families. We will also acquire biospecimens (blood and tumor tissue), and risk factor data from relevant family members. Aim 2: Identify candidate regions linked to familial brain tumors. To strengthen evidence of linkage to regions found in our preliminary analysis and to identify additional regions linked to brain tumors, we will genotype informative glioma pedigrees identified in aim 1 using Affymetrix 10K GeneChip with markers spaced throughout the genome, and conduct a genome-wide multipoint linkage scan with these markers. Aim 3: Fine map the regions established in Aim 2 by genotyping selected SNPs from genome databases. We will attempt to further refine the regions identified in Aim 2 to less than 1cM by using approximately 1,500 - 2,000 carefully selected SNPs. The prioritization of regions will be based on a combination of the strength of evidence for linkage from families of various ethnic backgrounds and the presence of obvious candidate genes.

The cognitive function of 150 patients that undergone any Radiotherapy treatment to the brain will be assessed at 3 time points before and after the treatment.