View clinical trials related to Malignant Glioma of Brain.
Filter by:In this research study, we want to learn about the safety of the study drugs, ribociclib and everolimus, when given together at different doses after radiation therapy. We also want to learn about the effects, if any, these drugs have on children and young adults with brain tumors. We are asking people to be in this research study who have been diagnosed with a high grade glioma, their tumor has been screened for the Rb1 protein, and they have recently finished radiation therapy. If a patient has DIPG or a Bi-thalamic high grade glioma, they do not need to have the tumor tissue screened for the Rb1 protein, but do need to have finished radiation therapy. Tumor cells grow and divide quickly. In normal cells, there are proteins that control how fast cells grow but in cancer cells these proteins no longer work correctly making tumor cells grow quickly. Both study drugs work in different ways to slow down the growth of tumor cells. The researchers think that if the study drugs are given together soon after radiation therapy, it may help improve the effect of the radiation in stopping or slowing down tumor growth. The study drugs, ribociclib and everolimus, have been approved by the United States Food and Drug Administration (FDA). Ribociclib is approved to treat adults with breast cancer and everolimus is approved for use in adults and children who have other types of cancers. The combination of ribociclib and everolimus has not been tested in children or in people with brain tumors and is considered investigational. The goals of this study are: - Find the safest dose of ribociclib and everolimus that can be given together after radiation. - Learn the side effects (both good and bad) the study drugs have on the body and tumor. - Measure the levels of study drug in the blood over time. - Study the changes in the endocrine system that may be caused by the tumor, surgery or radiation.
This human Phase I trial involves taking the patient's own tumor cells during surgical craniotomy, treating them with an investigational new drug (an antisense molecule) designed to shut down a targeted surface receptor protein, and re-implanting the cells, now encapsulated in small diffusion chambers the size of a dime in the patient's abdomen within 24 hours after the surgery. Loss of the surface receptor causes the tumor cells to die in a process called apoptosis. As the tumor cells die, they release small particles called exosomes, each full of tumor antigens. It is believed that these exosomes as well as the presence of the antisense molecule work together to activate the immune system against the tumor as they slowly diffuse out of the chamber. This combination product therefore serves as a slow-release antigen depot. Immune cells are immediately available for activation outside of the chamber because a wound was created to implant these tumor cells and a foreign body (the chamber) is present in the wound. The wound and the chamber fortify the initial immune response which eventually leads to the activation of immune system T cells that attack and eliminate the tumor. By training the immune system to recognize the tumor, the patient is also protected through immune surveillance from later tumor growth should the tumor recur. Compared to the other immunotherapy strategies, this treatment marshalls the native immune system (specifically the antigen presenting cells, or dendritic cells) rather than engineering the differentiation of these immune cells and re-injecting them. Compared to traditional treatment alternatives for tumor recurrence, including a boost of further radiation and more chemotherapy, this treatment represents potentially greater benefit with fewer risks. This combination product serves as a therapeutic vaccine with an acceptable safety profile, which activates an anti-tumor adaptive immune response resulting in radiographic tumor regression.
Malignant gliomas are the most common primary brain tumor in adults, but the prognosis for patients with these tumors remains poor despite advances in diagnosis and standard therapies such as surgery, radiation therapy, and chemotherapy. The advantages of ADV-TK gene therapy highlight its efficacy and safety for glioma patients. This clinical trial was conducted to assess the anti-tumor efficacy and safety of intraarterial cerebral infusion of replication-deficient adenovirus mutant ADV-TK, in combination with systemic intravenous GCV administration in patients with recurrent high-grade glioma.