View clinical trials related to Glioma.
Filter by:Tumours of the brain and of the central nervous system (CNS) are the most common solid tumours in children. Amongst these, gliomas are the most frequent, although this term covers different histological subtypes, the most frequent being astrocytoma. However, they are rare diseases of low prevalence. The interest in the cisplatin/irinotecan combination in brain tumours motivated a previous pilot study at our hospital, with encouraging results. This experience, together with the need for new strategies for high-risk pediatric gliomas has motivated the conduct of this study.
This is a Phase II study in a single center to determine the efficacy of autologous dendritic cells (DCs) loaded with autogeneic glioma stem-like cells (A2B5+) administered as a vaccination in adults with glioblastoma multiforme (primary or secondary).
This randomized phase II trial studies how well low-dose lenalidomide works compared with high-dose lenalidomide in treating younger patients with juvenile pilocytic astrocytomas or optic nerve pathway gliomas that have come back (recurrent), have not responded to treatment (refractory), or are growing, spreading, or getting worse (progressive). Lenalidomide is classified as an immunomodulatory drug as it boosts the immune system. It has other potential anti-tumor effects, for example, it may stop the growth of tumor cells by blocking blood flow to the tumor. It is not yet known whether low-dose lenalidomide is more or less effective than high-dose lenalidomide in treating patients with juvenile pilocytic astrocytomas or optic nerve pathway gliomas.
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.
This open-label, multicenter, Phase I, dose-escalating study will evaluate the safety and tolerability, pharmacokinetics, pharmacodynamics and efficacy of GDC-0084 in patients with progressive or recurrent high-grade glioma. Stage 1 is the dose escalation part of the study. Stage 2, patients will receive GDC-0084 at a recommended dose for future studies.
1. The management of anaplastic gliomas of WHO grade 3 is currently largely based on surgery followed by radiotherapy, of which prognosis remains still dismal with the median survival of 2-5 years. To date, the benefit of chemo for WHO grade 3 gliomas is unclear of modest at best with conventional cytotoxic agents, and the role of temozolomide for these entities still is not elucidated. 2. Codeletion of chromosome 1p/19q is considered the most important marker of prognostic significance in WHO grade 3 gliomas. 3. To project a randomized phase 2 screening trial examining the efficacy of concurrent chemoradiotherapy with temozolomide followed by adjuvant temozolomide for WHO grade 3 gliomas without codeletion of chromosome 1p/19q. 4. The prognostic significance of methylation status of MGMT and IDH1 mutation as molecular markers will be also assessed in each arm as key secondary analysis.
Study on glioma patients treated with brain surgery is focusing on the analysis of their transcriptome expression profile measured in two immune cell populations, CD4+ T cells and CD56+ NK cells. The results of analysis will be compared to the reference data of healthy population. Furthermore, the metabolomic and immunological status will also be monitored and compared to healthy group reference data, before and after the surgery*. With comparative crossomics analysis the investigators intend to possibly identify new diagnostic and prognostic biological markers for the relapse of the disease. The results are expected to convey a deeper insight into pathophysiology of the glioma as well as into the mechanisms of the current surgical therapy. * The healthy reference data have been published in collaborative efforts of BTC, UMC and NIB (Gruden et al. 2012).
The primary objective of this study is to evaluate the efficacy of a combined treatment with cilengitide and metronomic oral temozolomide as measured by 6 months overall survival (OS) after diagnosis of relapse or tumour progression in children and adolescents with relapsed or refractory high-grade malignant glioma and diffuse intrinsic pontine glioma. Secondary objectives include: 1. To evaluate the safety and toxicity of the study treatment by common toxicity criteria (CTC; version 4.0). 2. To assess - the response rates at 6 months (continuous complete response = CCR, complete response = CR, partial response = PR, stable disease = SD, progressive disease = PD) and - progression-free survival (PFS) at 6 months, and - response rates, OS, and PFS at 12 months after relapse diagnosis or diagnosis of tumor progression. Response will be presented including histopathological variants. 3. To assess the pharmacokinetics of cilengitide administered as part of the study treatment. Indication and study population for this trial: Treatment of relapsed or refractory high grade gliomas and diffuse intrinsic pontine gliomas in paediatric patients ≥ 3 years and < 18 years of age. Patients included in the study receive - Cilengitide 1800 mg/m² i.v. twice weekly - Temozolomide 75 mg/m²/d p.o. for 6 weeks, followed by 1 week rest with a mandatory platelet-count dependent dose adaptation rule: mandatory blood counts twice weekely: Platelets ≥ 100 000/µl (≥ 100 Gpt/l): 75 mg/m², platelets ≥ 50 000 - < 100 000/µl (≥ 50 - <100 Gpt/l): 50 mg/m², platelets < 50 000/µl (<50 Gpt/l): stop temozolomide until platelet recovery ≥ 100 000/µl (≥100 Gpt/l) - Study treatment in the individual patient is scheduled for 1 year unless tumor progression or excessive toxicity occurs. However, study treatment may be extended beyond 1 year upon individual decision.
This phase I/II trial studies the side effects and the best dose of veliparib when given together with radiation therapy and temozolomide and to see how well they work in treating younger patients newly diagnosed with diffuse pontine gliomas. Veliparib may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth. Radiation therapy uses high-energy x rays to kill tumor cells. Drugs used in chemotherapy, such as temozolomide, work in different ways to stop the growth of tumor cells either by killing the cells or by stopping them from dividing. Giving veliparib with radiation therapy and temozolomide may kill more tumor cells.
The purpose of this study is to test the safety of a new method to treat Diffuse Intrinsic Pontine Glioma (DIPG). The researchers will use "convection-enhanced delivery" (CED) to deliver an agent called 124I-omburtamab. CED is performed during surgery. The study agent is infused through a small tube placed into the tumor in the brain. Many studies have shown this can safely be done in animals but this study is the first time 124I-omburtamab will be given by CED in humans. This will be one of the first times that CED has been performed in the brain stem. Omburtamab is something called an antibody. Antibodies are made by the body to fight infections and sometimes cancer. The antibody omburtamab is produced by mice and can attack many kinds of tumors. A radioactive substance, 124I-omburtamab, is attached to omburtamab. 124I-omburtamab sticks to parts of tumor cells and can cause the tumor cells to die from radiation. Studies have also been done on humans using 124I-omburtamab to treat other kinds of cancer. Our studies of some DPG and related tumors suggest that omburtamab will bind to the tumor, but the investigators don't know that for sure. In this study, the researchers want to find out how safe 124I-omburtamab given by CED is at different dose levels. They will look to see what effects (both good and bad) it has on the patient. The dose of 124I-omburtamab will increase for each new group of patients. The procedure has already been safely performed with lower doses and infusion volumes in a number of patients here at MSKCC. The amount they get will depend on when they enter the study. If too many serious side effects are seen with a certain dose, no one will be treated with a higher dose, and some more patients may be treated with a lower dose to make sure that dose is safe.