View clinical trials related to Brain Tumor.
Filter by:PRIMARY OBJECTIVE To establish feasibility and acceptability of diagnostic brain MRI in young children for specified indications using an upright MRI system without sedation or anaesthesia. SECONDARY OBJECTIVES To establish how young children who undergo brain MRI using upright MRI view the experience To establish how parents / carers of young children who undergo brain MRI using the upright MRI view the experience for their child and for themselves. To establish how image quality compares between brain MRI using the upright MRI scanner and the standard MRI scanner used in clinical practice.
Magnetic Resonance Imaging (MRI) is an excellent method for diagnosis and staging of brain disease. However, lengthy scan times and sensitivity to patient motion limit its efficacy. To address this, a novel method has recently been demonstrated, called MR Fingerprinting (MRF). The investigators' improved implementation of MRF, featuring fully-quantitative data and a reduced sensitivity to patient motion, can be used to acquire an anatomical exam in less than five minutes at a standard resolution. The potential for wide applicability of this technique, combined with an implied reduction in complexity and cost of MRI exams, has generated wide interest. However, published studies have been limited to demonstrations in healthy volunteers, and the effectiveness of MRF in the clinical practice has not yet been proven. Here, the investigators aim to assess the efficacy of MRF in performing diagnostic exams avoiding sedation in children and for increasing diagnosis rates in challenging adult patients.
The goal of this clinical trial is to test the effect of a drug called tranexamic acid (TXA) on reducing blood loss in participants undergoing surgery to remove brain tumors. The main questions it aims to answer are: 1. Does TXA 20 mg/kg IV bolus of TXA, and 1 mg/kg/hr infusion of TXA reduce the amount of estimated blood loss during surgery? 2. Does TXA 20 mg/kg IV bolus of TXA, and 1 mg/kg/hr infusion of TXA prevent re-operation, disability or death related to bleeding inside the head during and after surgery? Participants are randomized to receive 20 mg/kg IV bolus of TXA or matching placebo within 30 minutes of start of surger, and then 1 mg/kg/hr infusion of TXA or matching from the start of surgery to end of surgery. Treatment allocation is blinded. Investigator will compare the two treatment arms to see whether there are differences in the amount of blood loss during surgery and bleeding-related complications. Investigators will also monitor for any side effects of TXA.
To assess the effect of web-based 360° Virtual Reality movies on fear and anxiety, The investigators would like to assess the patient-perceived level of fear and anxiety quantitatively, making use of several questionnaires.
The purpose of this study is to test an empirically supported psychotherapeutic intervention, Managing Cancer and Living Meaningfully (CALM), compared to treatment as usual (TAU) in those with malignant brain cancer diagnoses.
The purpose of this study is to discover the potential convenience and ease of using a Magnetic Resonance Imaging (MRI) technique, named Magnetic Resonance Fingerprinting (or MRF), to achieve high-quality images within a short scan time of 5 min for viewing the entire brain. This is an advanced quantitative assessment of brain tissues. This method is being applied with IVIM MRI to be able to tell the difference between a brain with radiation necrosis and a brain with tumor recurrence. Participants will consist of individuals who have received radiation therapy in the past and were diagnosed with radiation necrosis, individuals with recurrent tumors, and healthy individuals who have no brain diseases and have not had radiation treatment to the brain. Participants will undergo an MRI scan at a one-time research study visit; no extra tests or procedures will be required for this research study. The primary objectives of this study are: - To demonstrate the clinical feasibility of combining MRF with state-of-the-art parallel imaging techniques to achieve high-resolution quantitative imaging within a reasonable scan time of 5 min for whole brain coverage. - To apply the developed quantitative approach in combination with IVIM MRI for differentiation of tumor recurrence and radiation necrosis.
Visualization of the tissue microstructure during neurosurgery using a non destructive handheld imaging technology producing a real time digital image ("optical biopsy") at cellular resolution is a novel method that holds great promise for optimization and improvement of the surgical treatment of brain pathologies, brain tumors in particular. The goal of this project is to investigate and assess the ease of use of the CONVIVO FDA cleared system in discriminating healthy and abnormal tissues during in vivo use on the brain during neurosurgery in 30 patients with a working diagnosis of intrinsic brain tumors.
Randomized, placebo-controlled, double-blinded, parallel group clinical trial to investigate if 6 months of oral lithium tablets (S-lithium 0,5-1,0 mmol/l) will prevent cognitive decline after brain radiotherapy in pediatric brain tumor survivors. Primary outcome measure is Processing Speed Index (PSI) 2 years after start of study treatment.
This prospective study aims to investigate and validate the use of resting-state functional MRI (rs-fMRI) and high angular resolution diffusion imaging (HARDI), specifically constrained spherical deconvolution (CSD) tractography, for functional and structural brain mapping prior to neurosurgery. The goal is to assess the feasibility of replacing task-based fMRI (tb-fMRI) and diffusion tensor imaging (DTI) with fiber tractography (FT) using the fiber assignment by continuous tracking (FACT) algorithm. The study focuses on mapping sensory-motor, language, visual, and higher cognitive functional and structural networks in patients with brain pathology suitable for surgical intervention. The objective is to improve neurosurgical planning, navigation, and risk assessment through the utilization of rs-fMRI and CSD tractography.
Pear Bio has developed a 3D microtumor assay and computer vision pipeline through which the response of an individual patient's tumor to different anti-cancer regimens can be tested simultaneously ex vivo. This study will recruit patients with primary brain tumors who are due to undergo surgery. Oncologists will be blinded to treatment response on the Pear Bio tool (the assay will be run in parallel with the patient's treatment). The primary objective of this study is to establish the ex vivo model and confirm whether approved therapies exhibit their intended mechanism of action in the model. Secondary objectives include correlating test results to patient outcomes, where available.