View clinical trials related to Glioblastoma.
Filter by:The goal of this interventional study is to evaluate the efficacy of APG-157 in combination with Bevacizumab in subjects with recurrent high-grade glioma. The main questions the study aims to answer are: - Progression-free and overall survival of patients receiving this combination; - Quality of Life (QOL); and - Tumor response on imaging The participants will take APG-157 daily by dissolving two pastilles in their mouth at around breakfast, lunch and dinner time (total of six pastilles per day). The pastilles dissolve in the mouth. The participants will continue to receive Bevacizumab as standard of care.
Glioblastoma is the most common malignant primary brain tumor with poor prognosis because of its diffusive and infiltrative nature. The FDA approved the use of the anti-VEGF antibody bevacizumab in recurrent GBM. However, resistance to this anti-angiogenic reagent is frequent and fails to enhance patients' overall survival. The investigators previously identified one novel mechanism responsible for bevacizumab-resistance in CD146-positive glioblastoma (Joshkon et al. Acta Neuropathol Commun, 2022). Now, the investigators objective is to prospectively monitor the soluble CD146 value in plasma from patients treated by bevacizumab for recurrent glioblastoma. The investigators will collect plasma at baseline, before the first bevacizumab administration, before the second administration, at the time of first MRI evaluation and at progression. Plasma CD146 value will be analyzed by ELISA. The investigators expect to confirm the correlation between soluble CD146 value in plasma and patient response to bevacizumab.
Glioblastoma is the most common primary malignancy of the central nervous system with a very poor prognosis. Most of the immunotherapies that have made significant breakthroughs in the treatment of other tumors in recent years are unsatisfactory in the application of glioblastoma, which is mainly inseparable from the highly inhibitory immune microenvironment formed by the latter. Therefore, how to change this "immune desert" and better activate immune effector cells to play an anti-tumor effect is currently a hot spot in glioma immune research. In recent years, there has been continuous research support that the myeloid cells of the central nervous system are partly derived from the bone marrow of the skull, and there is a special channel connection between the skull and the dura mater, through which immune cells can be transported. This suggests that some of the tumor-associated macrophages recruited in the glioblastoma microenvironment may be passed through the dura mater. In previous animal experiments, we blocked the main blood supply to the dura mater by ligating the bilateral external carotid arteries of mice, cutting off the potential supply of dura mater to suppressor myeloid cells in the lesion. The results showed that after ligation of bilateral external carotid arteries, the survival period of tumor-forming mice was significantly prolonged and the prognosis was improved. The proportion of myeloid cells in the tumor microenvironment of mice decreased significantly, and the expression of tumor suppressor molecules such as arginase Arg1 decreased, indicating that the improvement of mouse prognosis was closely related to the proportion and phenotypic changes of myeloid cells after dural blood supply blockade. The meningeal lymphatic system of the human central nervous system has been shown to be an important part of the immune system, while the external carotid artery system, the main source of blood supply to the dura, carries abundant immune cells that ooze out to the dura mater through the endothelial window hole of the dural blood vessel, which is an important source of dural immune cells. In the glioblastoma immune microenvironment, the source of immune cells includes dural branches from the external carotid artery system in addition to branches of the internal carotid artery system. Therefore, for patients diagnosed with glioblastoma, this study involves embolization of the dural branch of the external carotid artery system (bilateral middle meningeal artery) to block the dural blood supply before craniotomy. At the same time, microsurgery under multimodal image navigation was used to remove the tumor. It is expected to be effective in reducing the proportion of myeloid suppressor cells in the tumor microenvironment, slowing the growth rate of residual tumor cells, and prolonging the tumor-free progression and survival of patients.
This is a phase 2 study to evaluate the safety and preliminary evidence of effectiveness of azeliragon, in combination with radiation therapy, as an initial treatment of a form of glioblastoma. Glioblastoma is a type of brain cancer that grows quickly and can invade and destroy healthy tissue. There's no cure for glioblastoma, which is also known as glioblastoma multiforme. Treatments, including surgery, radiation, and chemotherapy might slow cancer growth and reduce symptoms. New treatments of glioblastoma are needed.
This single center, single arm, open-label, phase I study will assess the safety of laparoscopically harvested autologous omentum, implanted into the resection cavity of recurrent glioblastoma multiforme (GBM) patients.
The goal of this Phase 0 trial is to study if pre-operative oral pitavastatin administration reaches the tumour in patients with primary or a recurrent glioblastoma. The main question[s] it aims to answer are: - Does pitavastatin reach a cytotoxic concentration in gadolinium-enhanced tumour tissue after oral administration? - Does pitavastatin achieve a concentration that can synergize with temozolomide in the gadolinium non-enhanced area of the tumour? Participants will receive pitavastatin in differing dosages a week before their elective surgery and blood and tumour samples will be collected.
The purpose of the study is to test the safety and dosing of [177Lu]Lu-FF58, a radioligand therapy for patients with advanced or metastatic tumors that express proteins known as integrins: alpha-v beta-3 integrin (αvβ3) and alpha-v beta-5 integrin (αvβ5). The study will also further characterize the radioligand imaging agent [68Ga]Ga-FF58 including its ability to identify tumor lesions and its safety profile.
AVM Biotechnology, Inc., provides immunomodulatory AVM0703 to solid tumor and blood cancer patients upon request by a US licensed MD or DO. As of July 2023, 22 patients have been treated through this FDA-EAP including patients diagnosed with relapsed or recurring glioblastoma, inoperable/chemotherapy ineligible CNS Squamous Cell Carcinoma, metastatic Breast Cancer, ovarian cancer, gastric cancer, Hodgkin's Lymphoma, Mixed Phenotype Acute Myelogenous Leukemia, colon cancer, B-ALL, Malignant Myxoid Spindle Cell Neoplasm, non-small cell lung cancer, DLBCL with CNS involvement, metastatic prostate cancer, Anaplastic T-cell Non-Hodgkin's Lymphoma.
This will be a prospective, open label, single center, phase I lead-in study of 10 patients to a single arm phase-II study of 37 additional patients to assess the effectiveness of pembrolizumab and lenvatinib combination therapy for recurrent glioblastoma (rGBM) patients wearing TTFields electrodes.
After surgery, a key step in treatment of patients diagnosed with glioblastoma (high grade brain tumour) is radiotherapy. The ideal clinical target volume (CTV) for radiotherapy treatment planning includes all tumour cells remaining after surgery. Currently, the GTV is delineated on conventional imaging techniques that are only visualizing macroscale structural changes due to the presence of a large number of tumour cells. After delineating these visible macroscale changes, the GTV is expanded in all directions with 1.5cm into visibly healthy tissue to account for microscale tumour invasion. This standard CTV therefore also contains healthy tissue that should not be receiving radiation, causing side effects of treatment, hereby reducing quality of life for patients. Generating a physiological CTV, in which microscale invasion of tumour cells is taken into account specifically whilst sparing healthy tissue that is not in need of radiation, is essential for reducing side effects of radiotherapy. To do so, visualisation is necessary of physiological processes of tumour cells, which are present before macroscale structural changes occur. State-of-the-art MRI techniques are now in use at the Erasmus MC that can assess these physiological processes, including oxygenation status and cell proliferation. We aim to generate proof-of-concept of using a physiological CTV for radiotherapy treatment planning for patients with brain tumours. By extending the clinical standard MRI session used for radiotherapy planning in 10 patients diagnosed with glioblastoma with advanced MRI techniques that assess oxygenation status and cell proliferation, we will generate the physiological CTV including this information and illustrate that it is more precise in capturing microscale tumour invasion. This proof-of-principle work will be used to obtain external funding to perform the much needed, and the first of its kind globally, clinical trial to show the benefit of a physiological CTV for radiotherapy treatment planning in glioblastoma.