Active clinical trials for "Glioblastoma"

This phase II trial is studying how well giving vorinostat together with bortezomib works in treating patients with progressive, recurrent glioblastoma multiforme. Vorinostat and bortezomib may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth. Giving vorinostat together with bortezomib may kill more tumor cells.

The purpose of this study is to evaluate the objective response rate and 6-month progression-free survival rate of XL184 in subjects with recurrent or progressive glioblastoma multiforme. XL184 is a new chemical entity that inhibits VEGFR2, MET and RET, kinases implicated in tumor formation, growth and migration.

The purpose of this study is to evaluate the safety of combination therapy of radiotherapy and temozolomide ("concomitant radiotherapy phase"), and then temozolomide monotherapy ("monotherapy phase"), in patients with newly diagnosed glioblastoma multiforme. Progression free survival and response rate will also be calculated.

The purpose of this study is to see how effective cediranib is in treating a brain tumour called recurrent glioblastoma. Two drugs are being tested in this study. Lomustine is an approved oral chemotherapy that belongs to the class of drugs called alkylating agents. Cediranib is a new drug that has not yet been approved for this disease. This study will compare the use of lomustine with cediranib, cediranib alone or lomustine with placebo ("inactive substance") to see whether the combination or cediranib alone will be more effective than the chemotherapy alone (lomustine) in preventing the growth of cancer cells.

Glioblastomas represent 40% of all tumors of the central nervous system (CNS) and are among the most lethal tumors. Temozolomide (TMZ) combined with radiotherapy was the first substance to significantly improve the overall survival (to 14.6 months) as compared to surgery and radiotherapy alone and increased the proportion of patients surviving more than 2 years to 26%. TMZ showed the best efficacy in patients with a methylated O6-methylguanine-DNA methyltransferase (MGMT) promoter in part by eliminating stem cell-like tumor cells. Among patients with a methylated MGMT promoter, the median survival after treatment with combined radio-chemotherapy was 21.7 months, as compared to 15.3 months among those who were assigned to radiotherapy only. In the absence of methylation of the MGMT promoter, there was a smaller and statistically insignificant difference in survival between the treatment groups. Doxorubicin is one of the most effective substances in vitro against cells derived from glioblastoma. However, it has no significant effect in vivo due to poor blood-brain-barrier penetration. In a tumor model, tissue and CSF-concentrations of doxorubicin were substantially increased when sterically stabilized liposomes were used resulting in a comparable clinical response using approximately half of the dose of stabilized liposomes compared to conventional doxorubicin. A pegylated formulation (PEG-liposomal Doxorubicin) even further improved the penetration of the blood-brain barrier. Case series and two phase II-studies in patients with recurrent glioblastoma have shown modestly promising results for PEG-Dox. In this study, the investigators treated patients with recurrent glioblastoma with 20 mg/m2 PEG-Dox on days 1 and 15 of each 28-day cycle. To determine the dose limiting toxicity of PEG-Dox combined with prolonged administration of TMZ, the investigators performed a phase I part ahead of the phase II study. To investigate, by means of a historical control analysis, if the addition of PEG-Dox to TMZ and radiotherapy improves the survival of patients, the investigators chose similar inclusion criteria and identical TMZ and radiotherapeutic regimes as in the EORTC26981/NCIC-CE.3 study.

The standard treatment for children with brain tumors is surgical removal of the tumor followed by radiation to the brain and chemotherapy (medicines) given to shrink any remaining tumor or to prevent tumor from growing back. There are very few treatment options available for children whose brain tumor grows back after receiving radiation treatment. There is a greater risk of complications and side effects when the brain is repeatedly treated with external radiation. The side effects of repeat radiation treatment are dependent on the amount of the brain that is radiated. Radiation given with PRS during surgery is focused to the specific area of the brain where the tumor is located. Therefore, the area of the brain affected by the radiation is smaller. It is hoped that this targeted radiation will lessen the side effects to the normal brain that is not affected by the tumor. It is also hoped that a lower occurrence of side effects will increase the quality of life of children with brain tumors. The optimal dose of targeted radiation is not known. Therefore, increasing doses will be given to treat different patients, starting with the lowest possible dose. The amount of radiation to be given will depend on whether or not your child received prior radiation therapy and where the tumor is located. The groups of patients will first be divided into 2 groups: Group A, who are those who received radiation as part of their prior treatment, and Group B, who are those who did not receive any radiation treatment. Each group will be then divided again into 2 groups depending on the location of the tumor. In each group, if the lowest dose is well-tolerated with only minimal side effects by 3 patients, then the next higher dose will be given to the next 3 patients. The purposes of this research are: To evaluate the potential side effects of a single high dose of x-rays using the Photon Radiosurgery System (PRS) given to a small area of the brain. To determine the maximum dose of targeted radiation that can be safely given to brain tumors with the fewest side effects. To see how well this treatment works for children with recurrent brain tumors and newly-diagnosed glioblastoma multiforme.

To determine whether a mild ketogenic diet can influences quality of life and survival of patients with recurrent glioblastoma

The purpose of the Dendritic Cell Immunotherapy study for patients with glioblastoma and/or brainstem glioma is to determine whether in patients with malignant brain tumors, dendritic cells injected peripherally can reactivate the immune system against the brain tumor.

Primary: To determine maximum tolerated dose & dose limiting toxicity of dasatinib when combined w erlotinib among pts w recurrent MG Secondary: To further evaluate safety & tolerability of dasatinib + erlotinib To evaluate pharmacokinetics of dasatinib when administered w erlotinib among recurrent MG pts who are on & not on CYP-3A enzyme inducing anti-epileptic drugs To evaluate for anti-tumor activity with this regimen in this patient population

In this multinational dose finding Phase IIb study the efficacy and safety of two doses of AP 12009 compared to standard chemotherapy (temozolomide or PCV) is investigated in adult patients with confirmed recurrent high-grade glioma.