View clinical trials related to Anaplastic Astrocytoma.
Filter by:This is a phase I study to evaluate the safety and tolerability of Sorafenib in combination with Temodar and radiation therapy in patients with newly diagnosed high grade glioma (glioblastoma, gliosarcoma, anaplastic astrocytoma and anaplastic oligodendroglioma or oligoastrocytoma). The mechanism of action of sorafenib, an oral multikinase inhibitor, makes it an interesting drug to investigate in the treatment of patients with high grade glioma as this agent has anti-angiogenic activity and inhibits other pathways such as Ras, Platelet-derived growth factor (PDGF) and fms-like tyrosine kinase receptor-3 (Flt-3), which are potential targets against gliomas.
Currently, there are few effective treatments for the following aggressive brain tumors: glioblastoma multiforme, anaplastic astrocytoma, gliomatosis cerebri, gliosarcoma, or brainstem glioma. Surgery and radiation can generally slow down these aggressive brain tumors, but in the majority of patients, these tumors will start growing again in 6-12 months. Adding chemotherapy drugs to surgery and radiation does not clearly improve the cure rate of children with malignant gliomas. The investigators are conducting this study to see if the combination of valproic acid and bevacizumab (also known as AvastinTM) with surgery and radiation will shrink these brain tumors more effectively and improve the chance of cure.
In this multinational Phase III study the efficacy and safety of 10 µM AP 12009 is compared to standard chemotherapy (temozolomide or BCNU or CCNU) in adult patients with confirmed recurrent or refractory anaplastic astrocytoma (WHO grade III) or secondary glioblastoma (WHO grade IV).
This phase I study evaluated a Gene Mediated Cytotoxic Immunotherapy approach for malignant gliomas, including glioblastoma multiforme and anaplastic astrocytoma. The purpose of this study was to assess the safety and feasibility of delivering an experimental approach called GliAtak which uses AdV-tk, an adenoviral vector containing the Herpes Simplex thymidine kinase gene, plus an oral anti-herpetic prodrug, valacyclovir, in combination with standard of care radiation.
The primary objective of this study is to determine the maximum tolerated dose (MTD) and dose limiting toxicity (DLT) of dasatinib when combined with protracted, daily temozolomide (TMZ). Secondary objectives are: To further evaluate the safety and tolerability of dasatinib plus protracted, daily TMZ; 2. To evaluate the pharmacokinetics of dasatinib when administered with protracted, daily TMZ among recurrent malignant glioma patients who are on and not on CYP-3A enzyme inducing anti-epileptic drugs (EIAEDs); 3. To evaluate for anti-tumor activity with this regimen in this patient population.
This is a Phase I study of Nanoliposomal CPT-11 in patients with Recurrent high-grade gliomas. Patients must have a histologically proven intracranial malignant glioma, which includes glioblastoma multiforme (GBM), gliosarcoma (GS), anaplastic astrocytoma (AA), anaplastic oligodendroglioma (AO), anaplastic mixed oligoastrocytoma (AMO), or malignant astrocytoma NOS (not otherwise specified). Patients who are wild type or heterozygous for the UGT1A1*28 gene will received Nanoliposomal CPT-11. The total anticipated accrual will be approximately 36 patients (depending upon the actual MTD). The investigators hypothesis is that this new formulation of CPT-11 will increase survival over that seen in historical controls who have recurrent gliomas because CPT-11 will be encapsulated in a liposome nanoparticle, which has been seen to reduce toxicities from the drug.
Background: The optimal treatment of anaplastic gliomas is controversial. Standard of care in most centers is still radiotherapy. This phase III study compared the efficacy and safety of radiotherapy vs chemotherapy in patients (pts) with newly-diagnosed, supratentorial gliomas of WHO grade III. Methods: Pts were randomized 2:1:1 between June 1999 and February 2005 in 34 German centers to receive (i) a 6-week course of radiotherapy (1,8-2 Gy fractions, total dose 54-60 Gy) or (ii) four 6-week cycles of CCNU at 110 mg mg/m2 on day 1, vincristine at 2 mg on days 8 and 29 and procarbazine at 60 mg/m2 on days 8-21 or eight 4-week cycles of 200 mg/m2 temozolomide on days 1-5. Treatment was stopped prematurely at disease progression or occurrence of unacceptable toxicity. At this time or at disease progression, treatment in the radiotherapy group was continued with one of the chemotherapies (1:1 randomization) and with radiotherapy in both chemotherapy groups. The primary endpoint was time-to-treatment-failure (TTF) defined as progression after radiotherapy and one chemotherapy in either sequence, or any time before if further therapy could not be employed. Assuming a 50% improvement in TTF of starting with chemotherapy, 318 pts were to be enrolled to provide 80% power to achieve statistical significance at a one-sided level of 0.05.
Background: In order to survive, brain tumors must have a network of blood vessels to supply it with oxygen and nutrients. The tumors produce substances that enable new blood vessels to form. Tandutinib and Bevacizumab are experimental drugs that may prevent new blood vessel formation and thereby slow or stop tumor growth in the brain. Objectives: To determine the safety and side effects of Tandutinib in combination with Bevacizumab in patients with brain tumors. To evaluate the response of brain tumors to treatment with Tandutinib and Bevacizumab. Eligibility: Patients 18 years of age and older with a malignant brain tumor for whom standard treatments (surgery, radiation and chemotherapy) are no longer effective. Design: Patients receive treatment in 4-week cycles as follows: Tandutinib by mouth twice a day every day and intravenous (through a vein) infusions of Bevacizumab over 90 minutes (or less if well tolerated) every 2 weeks. Treatment may continue for up to 1 year, and possibly longer, as long as there are no signs of tumor growth or serious treatment side effects. Patients are evaluated with magnetic resonance imaging (MRI), computed tomography (CT) and positron emission tomography (PET) scans before starting treatment and then periodically to determine the response to treatment. Patients have physical and neurological examinations every 4 weeks and blood tests every 2 weeks. They complete quality of life questionnaires every 4 weeks.
Subjects with newly diagnosed brain tumors who undergo surgical resection and whose pathology in the operating room shows a high grade glioma will be eligible. During a screening visit, the study will be discussed, inform consent discussed and signed, a medical history will be taken and a physical examination and laboratory tests will be performed. If these tests are all within acceptable ranges, the subject will be considered for inclusion on this treatment protocol. If the results of any tests are extremely different from normal expected values, she/he may not be able to participate. Prior to surgery, the subject will have a contrast enhanced MRI and MRS. The neurosurgeon will attempt to remove the majority of the tumor in the operating room and will send a portion of the specimen removed to the pathologist immediately. This is called a "frozen section". If the pathologist believes that the tumor is a high-grade malignant brain tumor, then the surgeon will place up to 8 dime-sized chemotherapy wafers in the tumor cavity of the brain. The remainder of the tumor specimen will be given to the pathologist to review more closely in the laboratory. If the frozen section does not show that the tumor is a high-grade malignant brain tumor, the subject will not receive the Gliadel wafers and will be removed from the study. The surgeon will then discuss with the subject the appropriate treatment options for the disease he or she has. During recovery in the hospital, another contrast enhanced MRI will be performed within the first 72 hours after surgery. This is a standard of care for patients who are not involved on this protocol as well. The subject will have another contrast enhanced MRI and MRS performed at the 21st Day after his or her surgery. After Day 21, He or she may begin other forms of treatment. The last contrast enhanced MRI and MRS assessment will be performed 12 weeks after the surgery and the implantation of the Gliadel wafers. Further MRI and MRS may be performed subsequently at the discretion of the doctor. Throughout the course of treatment, clinical data will be collected.
Objectives: To determine maximum tolerated dose of farnesyl transferase inhibitor, SCH 66336, when administered w TEMODAR®. To characterize any toxicity associated w combo of farnesyl transferase inhibitor, SCH 66336, & TEMODAR®. To observe patients for clinical antitumor response when treated with combination of farnesyl transferase inhibitor, SCH 66336, & TEMODAR®. To assess pharmacokinetics of SCH 66336 for patients on & not on enzyme inducing antiepileptic drugs.