View clinical trials related to Glioma.
Filter by:This phase I trial studies best dose and side effects of oncolytic adenovirus DNX-2401 in treating patients with high-grade glioma that has come back (recurrent). Oncolytic adenovirus DNX-2401 is made from the common cold virus that has been changed in the laboratory to make it less likely to cause an infection (such as a cold). The virus is also changed to target brain cancer cells and attack them.
The trial will address safety and tolerability of the combination of the IDH1R132H-specific vaccine with checkpoint blockade and seeks to explore predictive biomarkers for response to checkpoint blockade in post-treatment tumor tissue. The study will enroll 48 evaluable patients (presumably, 60 in total) with IDH1R132H-mutated gliomas with an unfavorable molecular profile (no 1p/19q co-deletion, nuclear ATRX- loss) progressive after radiotherapy and alkylating chemotherapy eligible for re-resection. After diagnosis of recurrent disease on imaging patients will be randomized assigned in a 1:1:2 ratio into three arms. Arm 1 (12 patients) will receive three IDH1R132H peptide vaccines alone in two week intervals. Arm 2 (12 patients) will receive three IDH1R132H peptide vaccines in combination with three doses of Avelumab in two week intervals. Arm 3 (24 patients) will receive three doses of Avelumab in two week intervals. After 6 weeks of treatment patients (Arms 1-3) will undergo planned re-resection. Four weeks after the operation treatment will be resumed consisting of five additional vaccines (Arm 1+2) in 4 week intervals, followed by maintenance vaccines until progression in three months' intervals after a pause of 16 weeks. Avelumab will be administered in monthly intervals in Arms 2 and 3 starting four weeks after the operation until progression. Key outcome parameters will be safety and immunogenicity (Arms 1 and 2) based on peripheral and intratumoral immune analyses assessed 9 months after re-resection.
This trial studies how well fimepinostat works in treating patients with newly diagnosed diffuse intrinsic pontine glioma, or medulloblastoma, or high-grade glioma that have come back. Fimepinostat may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth.
This pilot study will assess feasibility and to obtain initial estimates of efficacy of Sleep Activity and Task Effectiveness (SAFTE) model, which can accurately estimate the impact of scheduling factors and sleep history on both safety and productivity. The SAFTE model will be used to asses cancer-related fatigue and study potential associations of change in sleep patterns to tumor recurrence in patients with high grade glioma. Data will be collected using the Readiband™ Sleep Tracker (https://www.fatiguescience.com/sleep-science-technology/). The Readiband device captures high-resolution sleep data, validated against the clinical gold standard of polysomnography with 92% accuracy. Sleep data is transmitted to the cloud automatically for SAFTE Fatigue Model analysis. We will correlate clinical progression data obtained from the patient's electronic medical record with SAFTE data.
This phase III trial studies if selumetinib works just as well as the standard treatment with carboplatin/vincristine (CV) for subjects with NF1-associated low grade glioma (LGG), and to see if selumetinib is better than CV in improving vision in subjects with LGG of the optic pathway (vision nerves). Selumetinib is a drug that works by blocking some enzymes that low-grade glioma tumor cells need for their growth. This results in killing tumor cells. Drugs used as chemotherapy, such as carboplatin and vincristine, work in different ways to stop the growth of tumor cells, either by killing the cells, by stopping them from dividing, or by stopping them from spreading. It is not yet known whether selumetinib works better in treating patients with NF1-associated low-grade glioma compared to standard therapy with carboplatin and vincristine.
This phase II trial studies the side effects of solriamfetol in improving sleep in patients with grade II-IV glioma. Solriamfetol is a wakefulness-promoting drug. Giving solriamfetol may improve sleep, memory, fatigue, mood, or quality of life in patients with brain tumors (gliomas).
This is an exploratory, non-interventional and translational clinical study. The aim of this study is to analyze blood and cerebrospinal fluid metabolomic profile in glioma patients.
Gliomas are the most common primary intracranial tumors, representing at least 75% of all primary malignant brain tumors. Histopathologically, gliomas are classified into different subgroups including astrocytomas (60-70%), oligodendrogliomas (10-30%), ependymomas (<10%) and mixed gliomas (i.e. oligoastrocytomas) depending on the cell type from which they originate. The World Health Organization currently classifies gliomas based on histopathological analysis in which the presence (or absence) and the degree of specific histopathological features determines the grade of malignancy. Grade I (pilocytic astrocytoma) and grade II (diffuse astrocytoma, oligodendroglioma, mixed oligoastrocytoma, and pleomorphic xanthoastrocytoma) are termed low-grade gliomas (LGGs), whereas grade III (anaplastic astrocytoma, anaplastic oligodendroglioma or anaplastic oligoastrocytoma) and grade IV (glioblastoma) represent high-grade gliomas (HGGs). Given the incurable nature of gliomas, the maintenance or improvement of the patient's quality of life are extremely important. The benefits of multimodal treatment strategies, in terms of prolonged survival or delay of progression, have to be carefully balanced against the side effects of the treatment, which may adversely influence patient's functioning and well-being during his/her remaining life span. Measuring a brain tumor patients functioning and well-being goes far beyond assessing (progression-free) survival or tumor response to treatment on imaging. A more integrated way to measure patients functioning and well-being is the assessment of a patient's health-related quality of life (HRQOL). HRQOL is defined as a personal self-assessed ability to function in the physical, psychological, emotional, and social domains of day-to-day life. The main goal of this study is to perform a large-scale, prospective and long-term analysis of the HRQOL in patients diagnosed with glioma.
This research is being done to study the pattern of changes in various parts of the magnetic resonance imaging (MRI) studies that patients have done to help plan their radiation therapy and to evaluate the effects of therapy. The MRI of the brain is one of the major ways a participant's doctors determine how to treat a participant's tumor and if the participant's tumor is growing or not. In this study the investigators want to learn if new sequences added to the MRI that the investigators are already getting to guide partipants' radiation treatment can be analyzed to help make better treatment decisions. MRI sequences that examine the composition and structure of the tissues in the brain in a different way will be obtained. These are called called Amide Proton Transfer (APT) and Diffusion Weighted MRI. These scans will first be performed at the time of participants' radiation plannings scan done before treatment and near the end of the course of radiation treatments. This will allow the study team to investigate if there are changes in these sequences before radiation treatment and to see if using these MRI studies will allow us to better plan radiation treatments for patients in the future. This pre-treatment scan will be done at the same time as participants' standard radiation planning MRI, but will cause the scan to take longer. Participants will also have an extra MRI during one of the last 5 days of the planned 28-33 radiation treatments that are standardly used. This additional scan will not include administration of injected contrast agents, and would occur on a day when participants are also coming in for radiation. This scan will be compared with the first scan. The investigators will determine whether these changes may predict later long term outcome of treatment for patients. Patients who enroll in this study will get all of the standard therapy they would get for their tumor whether or not they participate in this study. There is no extra or different therapy given. The investigators anticipate that the radiation treatment volumes created using APT will largely overlap with the conventional plan but will be distinct at the margins. Disease failure is more likely to occur in areas with APT abnormalities suggestive of active tumor. In patients that have failure outside the contrast enhancing area, the region of failure will be predicted by regions of increased APT activity. Current MRI sequences do not allow for prediction of regions of recurrence or progression, or distinguish between tumor, pressure, or surgical injury as the cause of FLAIR/T2 abnormalities. Disease failure is more likely to occur in areas with APT abnormalities suggestive of active tumor. In patients that have failure outside the contrast enhancing area, the region of failure will be predicted by regions of increased APT activity. Current MRI sequences do not allow for prediction of regions of recurrence or progression, or distinguish between tumor, pressure, or surgical injury as the cause of FLAIR/T2 abnormalities. Volume containing elevated APT signal may be associated with outcome (survival). In an exploratory analysis, the investigators will evaluate whether there are characteristic patterns that should be prospectively studied in a larger trial.
This study evaluates the feasibility of hypofractionated radiotherapy (RT) in the palliative treatment of recurrent diffuse intrinsic pontine glioma (DIPG). Participants will receive 15 Gy in 3 fractions as opposed to the standard 20 Gy in 10 fractions.