View clinical trials related to Glioma.
Filter by:This is a study of DSP-0390 in patients with recurrent high grade glioma.
Childhood aggressive gliomas are rare brain tumors with very poor prognosis. Due to the tumor's location and infiltrative nature, surgical removal is not always possible, and even when resection is performed and combined with chemo- and/or radiotherapy, tumor cells frequently persist, eventually giving rise to tumor recurrence. A promising strategy to eradicate persisting tumor cells is vaccination with dendritic cells (DC). DC are immune cells that play an important role in organizing the body's defense against cancer. The goal of DC vaccination is to activate these natural anti-tumor defense mechanisms to delay or prevent tumor progression or recurrence. Previous clinical studies have demonstrated that DC vaccination is well-tolerated, safe and capable of eliciting tumorspecific immunity. A clinical study including 10 pediatric patients (aged ≥ 12 months and < 18 years at the time of signing the informed consent) with brain (stem) tumors is initiated at the Antwerp University Hospital to investigate intradermal vaccination with WT1 mRNA-loaded autologous monocyte-derived DCs, either combined with first-line chemoradiation treatment or administered as adjuvant therapy following previous therapies. The general objective of this phase I/II clinical study is (1) to demonstrate that WT1-targeted DC vaccine production and administration in pediatric patients with HGG and DIPG, either combined with first-line chemoradiation treatment or administered as adjuvant therapy following previous therapies, is feasible and safe, (2) to study vaccine-induced immune responses, (3) to document patients' quality of life and clinical outcome for comparison with current patients' outcome allowing indication of the added value.
The purpose of the study is to assess the efficacy of rozanolixizumab as measured by seizure freedom, change in cognitive function, use of rescue medication, onset of seizure freedom and to assess safety and tolerability.
[18F]fluorodopa (3, 4-dihydroxy-6-[18F]fluoro-L-phenylalanine/ FDOPA) is an amino acid PET tracer originally developed for brain imaging in patients with movement disorders but has been found to be useful in brain tumour imaging. [18F]fluorodopa has been demonstrated to be predominantly transported by the L-type amino acid transporter without significant uptake into surrounding normal brain parenchyma with the exception of the basal ganglia. Assessing the feasibility of performing PET guided histopathology in a single and multi-site setting will be crucial in order to use PET as a planning tool for brain biopsy to detect high-grade transformation in low-grade gliomas.
There is a high medical need to improve treatment outcome for high-grade and low-grade glioma since no curative treatment is available. To achieve this goal, a broader understanding is needed of the causes of inter-and intratumoral heterogeneity; glioma dedifferentiation and invasion; the major determinants of malignancy and treatment failure in glioma patients. Patient-derived organoid (PDOs) of high-grade gliomas and low-grade gliomas will be used to identify the mechanisms that underlie this malignant behaviour and treatment resistance. This insight may be used to develop patient avatars to simultaneously test multiple new treatment modalities that are predictive for survival and quality of life of glioma patients.
This study is looking at the safety and efficacy of the drug combination of ASP8374 with cemiplimab in people with recurrent malignant glioma. The study will be conducted in two parts, the first portion of the study will be to establish the highest dose of ASP8374 that can be given safely with cemiplimab and will be used as the recommended dose of ASP8374 in combination with cemiplimab for the second portion of the study. The second portion of the study will be to compare the effect of having ASP8374 in combination with cemiplimab prior to surgery. The names of the study drugs involved in this study are: - ASP8374 - Cemiplimab
The blood brain barrier (BBB) prevents some drugs from successfully reaching the target tumor. Focused Ultrasound (FUS) using microbubbles and neuro-navigator-controlled sonication is a non-invasive method of temporarily opening up the blood brain barrier to allow a greater concentration of the drug to reach into the brain tumor. This may improve response and may also reduce system side effects in the patient. The primary purpose of this study is to evaluate the feasibility of safely opening the BBB in children with progressive diffuse midline gliomas (DMG) treated with oral Panobinostat using FUS with microbubbles and neuro-navigator-controlled sonication. For the purpose of the study, the investigators will be opening up the BBB temporarily in one, two, or three locations around the tumor using the non-invasive FUS technology, and administrating oral Panobinostat in children with progressive DMG.
This early phase I trial tests the use of a radioactive tracer (a drug that is visible during an imaging test) known as 18F-FMAU, for imaging with positron emission tomography/computed tomography (PET/CT) in patients with brain cancer or cancer that has spread to the brain (brain metastases). A PET/CT scan is an imaging test that uses a small amount of radioactive tracer (given through the vein) to take detailed pictures of areas inside the body where the tracer is taken up. 18F-FMAU may also help find the cancer and how far the disease has spread. Magnetic resonance imaging (MRI) is a type of imaging test used to diagnose brain tumors. 18F-FMAU PET/CT in addition to MRI may make the finding and diagnosing of brain tumor easier.
This study investigates how seizures can vary over time with changes in low grade gliomas and its treatments. This study may help doctors find symptoms or triggers of seizures earlier than normal, and ultimately earlier care or treatment for seizures.
This study aims to evaluate the safety and effectiveness of the combination of 30Gy/5fx HSRT and 20Gy/10fx IMRT adjuvant therapy. The total biological effective dose (BED) of the PTV is 72 Gy in a ratio of alpha/beta ratio of 3, which equals to the conventional 60Gy/30fx treatment. This study can provide evidence for future non-inferiority phase III randomized controlled trials. The abbreviated course of radiotherapy can reduce the treatment time by half, benefit patients, and utilize the health resource.