Active clinical trials for "Brain Neoplasms"

This protocol compares the toxicity of radiotherapy or radiochemotherapy applied with different radiation modalities - protons or photons. Patients with different kinds of brain tumours and foreseen high-dose radiotherapy can be included. The hypothesis of the trial is that the rate of chronic toxicity 1 year after the end of radiotherapy is 15% lower after proton compared to photon treatment.

Objective of the study is to determine whether intraoperative ultrasound guided resection of gliomas with contrast enhancement in magnetic resonance imaging and brain metastases can achieve as high rate of gross total resection as fluorescence-guided surgery with 5-aminolevulinic acid

The primary goal of this Phase I study is to determine the maximum tolerated dose of oncolytic adenovirus mediated double suicide-gene therapy in combination with fractionated stereotactic radiosurgery in patients with recurrent high-grade astrocytoma undergoing resection.

Background. Brain metastases (BM) are the most common intracranial tumor and occur in 20-40% of all oncological patients. The most common primary cancer in brain metastases is lung cancer, followed by melanoma, breast cancer, renal cancer and colorectal cancer. The incidence of brain metastases has been increasing but the occurrence of brain metastases is still associated with high morbidity and poor prognosis. The main treatment methods are stereotactic radiosurgery (SRS), microsurgical resection and whole brain irradiation (WBRT). In contrast to microsurgical resection, Gamma Knife radiosurgery (GKRS) is a non-invasive neurosurgical method, which allows treatment in multimorbid patients with contraindications for surgery in general anesthesia. Furthermore, stereotactic radiosurgery is the only local treatment method for multiple disseminated and thereby non-resectable brain metastases. In general, microsurgical resection is considered the treatment of choice for BM exceeding >3 cm in diameter. However, since the establishment of the dose-staged technique, larger metastases can also be treated radiosurgically in selected patients. This novel method allows the application of high cumulative dose for the treatment of complex brain metastases. Aim. The aim of the study is to evaluate the clinical outcome in brain metastases patients with tumor volume between 8 and 20 ccm3. The clinical outcome will be compared between surgically and radiosurgically treated BM patients. Patients and methods. The investigators plan to conduct an explorative prospective study including about 50 radiosurgically and 50 surgically treated patients with brain metastases. If a patient fulfill study-relevant inclusion criteria at the time of BM diagnosis, the principle study investigator will offer both treatment options to the patient. Depending on patient's choice, he/she will be categorized either to surgical or to radiosurgical treatment group. For the outcome evaluation of the different treatment options, a comprehensive database will be established. The study participations will not interfere with any clincally indicated therapeutic decisions and the study participants will not be exposed to any additional risks since both treatments represent suitable therapy options.

SRS dose escalation for brain metastases in radiation-naïve patients will establish true tolerable doses, which may exceed the current standard doses. This may lead to an improvement in local control, patient survival, and/or quality-of life.

BT-M01 is a software that has been pre-learned based on a brain metastasis detection model using brain MR images, and clinical decision support system for brain metastasis by automatically analyzing brain MR images by assisting the medical team. The specific aims of this study are to evaluate efficacy of BT-M01 for brain metastasis compared to the sensitivity and false positive rates of radiologists group.

The purpose of the research study is to test new methods that could improve diagnosis and assessment of brain tumors. One of these methods is a new MR (magnetic resonance) imaging technique called magnetic resonance fingerprinting (MRF), which allows for rapidly scanning the patient and provides quantitative information on tumor tissue. The investigators will compare the data gathered from MR Fingerprinting with other imaging tests, clinical information, treatment details and biopsy results to evaluate the accuracy of this new technique.

This phase II trial studies how well ¹⁸F- fluoromisonidazole (FMISO) works with positron emission tomography (PET)/magnetic resonance imaging (MRI) in assessing participants with malignant (cancerous) brain tumors. FMISO provides information about the oxygen levels in a tumor, which may affect how the tumor behaves. PET/MRI imaging produces images of the brain and how the body functions. FMISO PET/MRI may help investigators see how much oxygen is getting in the brain tumors.

Background: Accessing brain tumor material for pathological diagnosis requires invasive procedures that carry risk to patients including brain hemorrhages and death. Liquid biopsies are emerging non-invasive alternatives to direct tumour biopsies but the abundance of circulating tumor DNA (ctDNA) is relatively low and this limits our ability to accurately make the molecular diagnosis of brain tumors. We have recently shown promising results that suggest that the analysis of blood samples can distinguish brain tumor types. We now want to couple liquid biopsies with high intensity focused ultrasound (HIFU) to enhance the release of tumor DNA into the circulation and increase the sensitivity/and specificity of liquid biopsies for brain tumors. The aim of this project is to build on our preliminary findings and investigate the the time dependent changes associated with HIFU of a tumor to see if it improves accuracy of diagnosis and specifically molecular subtyping of tumors based on peripheral blood and cerebrospinal fluid (CSF) circulating tumor derived markers following HIFU.

About 20 to 30% of patients treated for cancer will have brain metastases. These brain metastases are found more frequently in patients with lung cancer, breast cancer or melanoma. The prognosis of these patients is unfavorable but prolonged survival can be obtained with the local and systemic treatments currently available. Brain MRI is the gold standard for evaluating brain metastases but has limitations in therapeutic evaluation, partially offset by PET imaging of amino acid metabolism. Our work aims to compare the performance of PET-DOPA with standard MRI for the detection of brain metastases (≥ 5mm) in lung cancer, breast cancer and melanoma; and to characterize these lesions using dynamic acquisitions obtained with a digital PET camera with high spatial resolution. Having better knowledge of the metabolic characteristics of newly discovered brain metastases, the objective of subsequent studies will be to better assess the per- or post-therapeutic efficacy of radiotherapy and the various systemic therapies available (chemotherapy, targeted therapy, immunotherapy).