51 Clinical Trials for Various Conditions
This early phase I trial evaluates different administration techniques (oral or intravenous) for arginine and tests the safety of giving arginine with whole brain radiation therapy in patients who have cancer that has spread from where it first started (primary site) to the brain (brain metastases). Arginine is an essential amino acid. Amino acids are the molecules that join together to form proteins in the body. Arginine supplementation has been shown to improve how brain metastases respond to radiation therapy. The optimal dosing of arginine for this purpose has not been determined. This study measures the level of arginine in the blood with oral and intravenous dosing at specific time intervals before and after drug administration to determine the best dosing strategy.
Study patients will receive Whole-brain radiation therapy (WBRT) - pulsed reduced dose rate (PRDR) within 14 days of registration. All patients will receive single daily fractions using 3D conformal radiotherapy. A dose of 30 Gy in 10 fractions will be delivered using the PRDR technique.
This study assesses neurocognitive outcomes after receiving radiation therapy to the brain (whole brain radiation therapy) in patients with blood cancers (hematologic malignancies). This may help researchers learn more about the effects of whole brain radiation therapy on memory and thinking in patients with blood cancer.
This phase III trial compares the effect of stereotactic radiosurgery to standard of care memantine and whole brain radiation therapy that avoids the hippocampus (the memory zone of the brain) for the treatment of small cell lung cancer that has spread to the brain. Stereotactic radiosurgery is a specialized radiation therapy that delivers a single, high dose of radiation directly to the tumor and may cause less damage to normal tissue. Whole brain radiation therapy delivers a low dose of radiation to the entire brain including the normal brain tissue. Hippocampal avoidance during whole-brain radiation therapy (HA-WBRT) decreases the amount of radiation that is delivered to the hippocampus which is a brain structure that is important for memory. The drug, memantine, is also often given with whole brain radiotherapy because it may decrease the risk of side effects related to thinking and memory. Stereotactic radiosurgery may decrease side effects related to memory and thinking compared to standard of care HA-WBRT plus memantine.
This phase II trial studies how well whole brain radiation therapy works with standard temozolomide chemo-radiotherapy and plerixafor in treating patients with glioblastoma (brain tumor). Radiation therapy uses high energy x-rays to kill tumor cells and shrink tumors. Drugs used in chemotherapy, such as temozolomide, work in different ways to stop the growth of tumor cells, either by killing the cells, by stopping them from dividing, or by stopping them from spreading. Plerixafor is a drug that may prevent recurrence of glioblastoma after radiation treatment. Giving whole brain radiation therapy with standard temozolomide chemo-radiotherapy and plerixafor may work better in treating patients with glioblastoma.
The purpose of this study is to evaluate the efficacy of parotid sparing in reducing measurable xerostomia (dry mouth) in patients undergoing whole brain radiotherapy. This is primarily a two-arm, single-blind, randomized study of parotid sparing whole brain radiation therapy (WBRT), with a third observational arm of patients who were identified after radiation had already started or who refused randomization but were willing to be followed for quality of life assessment. Qualifying patients who are interested in participating in the trial will be asked to complete an anonymous screening baseline xerostomia questionnaire. If their raw score on this questionnaire meets eligibility criteria, they will be offered enrollment on the study. Patients identified prior to radiation start will be offered enrollment into the interventional randomization arm, with the observation arm offered to those who refuse randomization. Patients identified after radiation has already started, but within 5 days of the first day of radiation, will be offered enrollment into the observational arm. Questionnaires completed by patients who consent to the trial will be assigned patient information (de-anonymized) and serve as their baseline quality of life data. After baseline assessment, subjects will be asked to complete the same questionnaire again at the end of treatment, as well as two weeks, one month, three months, and six months after treatment completion.
This is a trial that evaluates the preservation of cognition and neuropsychiatric function following genu-sparing whole brain radiation in patients with brain metastases.
This trial is a pilot, Phase 2, sequential two-cohort study designed to test two de-escalated whole brain radiation therapy (WBRT) dose levels and assess their ability to maintain acceptable in-brain distant control. The WBRT dose would decrease as the study moves forward, both in terms of absolute value and equivalent dose in 2 Gray fractions (EQD2) (as determined by the linear quadratic radiobiological model). The absolute value of the simultaneous integrated boost (SIB) dose will change with each dose level because the number of fractions delivered will depend on the WBRT dose. As such, the SIB dose will be manipulated such that the EQD2 will remain essentially equivalent despite the difference in the number of fractions delivered. This design will ensure that the only variable is the change in WBRT dose. The concept is that WBRT with SIB would be expected to maximize both local and in-brain distant control as has already been shown in studies exploring WBRT with SRS boost. However, by itself WBRT with SIB does not address the concern over neurocognitive outcomes. Therefore, investigators hypothesize that there is a lower WBRT dose threshold that will maintain acceptable in-brain distant control, particularly in the setting of a SIB to gross lesions to maintain treated lesion control. In addition, lower overall brain dose (including lower hippocampal dose without specific hippocampal avoidance) may potentially improve neurocognitive function. Investigators are also interested in evaluating treated lesion control, overall survival, neurocognitive sequelae of therapy, quality of life, performance status, and adverse effects of therapy. Biomarker identification for potential correlative circulating tumor DNA and microRNA is an exploratory endpoint to generate data for future prospective evaluation.
This research study is studying two different types of radiation as treatment for brain metastases (tumors in the brain that spread from a cancer that originated elsewhere in the body)
This phase I trial studies the side effects and best dose of ropidoxuridine when given together with whole brain radiation therapy in treating patients with cancer that has spread to the brain (brain metastases). Ropidoxuridine may help whole brain radiation therapy work better by making cancer cells more sensitive to the radiation therapy.
Some cancers can spread, or metastasize, to the brain. When they do, treatment often involves surgery and/or radiation. Optimal treatment of brain metastases would maximize disease control and minimize toxicity (or side effects), and improve the quality of life of patients. A common type of radiation used for brain metastases is called whole brain radiation, which treats not just the cancer that can be seen on scans (i.e., gross disease), but the smaller sites of cancer that may not be visible (i.e. subclinical disease). Fractionation is used to describe repetitive treatments in which small doses (fractions) of a total planned dose are given at separate clinic visits. The most common dosing regimen is 30 Gray (Gy), using 3 Gy per fraction over 10 fractions. Previous studies have suggested that using intensity modulated radiation therapy (IMRT) may be a safer way to deliver higher doses to gross disease and lower doses to the rest of the brain that may contain subclinical disease. This approach may spare the rest of the brain from radiation complications and side effects. The goal of this study is to determine whether using IMRT to treat brain metastases is more effective than current standard whole brain radiation in controlling gross disease and whether patient quality of life and hair loss is improved compared to previous studies using whole brain radiation.
The goal of this prospective observational study is to investigate whether whole brain radiation leads to measurable xerostomia from parotid gland toxicity.
This randomized phase II/III trial studies how well whole-brain radiation therapy works and compares it with or without hippocampal avoidance in treating patients with small cell lung cancer that is found in one lung, the tissues between the lungs, and nearby lymph nodes only (limited stage) or has spread outside of the lung in which it began or to other parts of the body (extensive stage). Radiation therapy uses high energy x-rays to kill tumor cells and shrink tumors. The hippocampus is part of the brain that is important for memory. Avoiding the hippocampus during whole-brain radiation could decrease the chance of side effects on memory and thinking. It is not yet known whether giving whole-brain radiation therapy is more effective with or without hippocampal avoidance in treating patients with small cell lung cancer.
This phase I trial studies the side effects and best dose of berzosertib (M6620 \[VX-970\]) when given together with whole brain radiation therapy in treating patients with non-small cell lung cancer, small cell lung cancer, or neuroendocrine tumors that have spread from the original (primary) tumor to the brain (brain metastases). Berzosertib 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 and shrink tumors. Giving berzosertib together with radiation therapy may work better compared to standard of care treatment, including brain surgery and radiation therapy, in treating patients with non-small cell lung cancer, small cell lung cancer, or neuroendocrine tumors.
This pilot clinical trial studies how well voxel based diffusion tensor imaging in predicting response in patients with brain metastases undergoing whole-brain radiation therapy or stereotactic radiosurgery. Voxel based diffusion tensor imaging (VB-DTI) may allow doctors to measure response to whole brain radiation therapy or stereotactic radiosurgery earlier than is possible with a standard magnetic resonance imaging. The earlier ability to measure response may allow for consideration of alternative therapies at an earlier stage.
In this dose-escalation study, the safety and tolerability of escalating dose levels of RRx-001 administered intravenously twice a week in subjects with brain metastases receiving whole brain radiation therapy (WBRT) will be assessed. Once a maximum tolerated dose is identified, further (up to approximately 30) participants will be recruited. The study will use MRI to monitor changes in tumor blood flow associated with RRx-001.
This phase I trial studies the side effects and best dose of trametinib with or without whole brain radiation therapy in treating patients with brain metastases. Trametinib 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 and shrink tumors. Drugs, such as trametinib, may make tumor cells more sensitive to radiation therapy. Giving trametinib with whole brain radiation therapy may be a better treatment for brain metastases.
This is a randomized, double blind placebo controlled study to evaluate safety and efficacy of lucanthone administered as an adjunct to patients receiving whole brain radiation therapy (WBRT) as primary treatment for brain metastases secondary to non-small cell lung cancer.
This is a study to evaluate a drug called bevacizumab in patients with cancer whose disease has spread to their brain. This study will not evaluate the effect of bevacizumab on the systemic solid tumor cancer. Bevacizumab is a medication and it is thought that bevacizumab may interfere with the growth of new blood vessels; therefore it might stop tumor growth and possibly shrink the tumor by keeping it from receiving nutrients and oxygen supplied by the blood vessels.
This phase I trial studies the side effects and best dose of ipilimumab when given together with whole brain radiation therapy or stereotactic radiosurgery in treating patients with melanoma with brain metastases. Monoclonal antibodies, such as ipilimumab, can block tumor growth in different ways. Some block the ability of the tumor to grow and spread. Others find Tumor cells and help kill them or carry tumor-killing substances to them. Radiation therapy, such uses high-energy x-rays and other types of radiation to kill tumor cells. Giving radiation therapy in different ways may kill more tumor cells. Giving ipilimumab together with whole-brain radiation therapy or stereotactic radiosurgery may kill more tumor cells.
This randomized phase II trial studies how well whole-brain radiation therapy or stereotactic radiosurgery with or without lapatinib ditosylate works in treating patients with breast cancer that has too many of a protein called human epidermal growth factor receptor 2 (HER2) on its cells and has spread to the brain. Radiation therapy uses high energy x rays to kill tumor cells and shrink tumors. Stereotactic radiosurgery is a specialized radiation therapy that delivers a single, high dose of radiation directly to the tumor and may kill more tumor cells and cause less damage to normal tissue. Lapatinib ditosylate may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth. It is not yet known whether whole-brain radiation therapy or stereotactic radiosurgery together with lapatinib ditosylate is an effective treatment for brain metastasis from breast cancer.
The purpose of this study is to compare two different imaging methods to examine the response of brain metastases to WBRT. These two imaging methods will take pictures of the brain using : 1) a positron emission tomography (PET) scanner and 2) Magnetic Resonance Imaging (MRI) scanner. A PET scanner resembles a CT or MR scanner.PET scans use radioactive substances also called as radioactive markers to "see" cancer cells. We plan to use \[18F\]FLT as a radioactive marker. FLT is used to image tumor growth. FLT PET scan is a new clinical procedure. It is in the testing stage of development unlike FDG-PET which is used more commonly used. Therefore, this is considered a "research" study. This will help us evaluate whether this scan will be safe and better used in the future to evaluate tumors. The amount of radiation to the body is small. The radiation from the radiotracer drug will be gone from the body in a few hours. There is no radiation risk from the MRI scans. Additionally, we also plan to use MRI imaging of the brain. We expect that \[18F\]FLT PET is better when compared to MRI and will give us more information about the brain metastases after WBRT.
This randomized phase III clinical trial compares stereotactic radiosurgery with whole brain radiation therapy to see how well they work in treating patients with non-melanoma cancer that has recently spread from the first location to the brain. Radiation therapy uses high energy x-rays to kill tumor cells and shrink tumors. Stereotactic radiosurgery is a specialized type of radiation therapy that delivers a single, high dose of radiation directly to the tumor and may kill more tumor cells and cause less damage to normal tissue. Whole brain radiation therapy delivers a lower dose of radiation to the entire brain over several treatments. It is not yet known whether stereotactic radiosurgery works better than whole brain radiation therapy in treating patients with non-melanoma brain metastases. Stereotactic radiosurgery may also cause fewer thinking and memory problems than whole brain radiation therapy.
RATIONALE: Stereotactic radiosurgery may be able to send x-rays directly to the tumor and cause less damage to normal tissue. Radiation therapy uses high-energy x rays to kill tumor cells. It is not yet known whether stereotactic radiosurgery is more effective than whole-brain radiation therapy in treating patients with brain metastases that have been removed by surgery. PURPOSE: This randomized phase III trial studies how well stereotactic radiosurgery works compared to whole-brain radiation therapy in treating patients with brain metastases that have been removed by surgery.
RATIONALE: Radiation therapy uses high energy x-rays to kill tumor cells. PURPOSE: This phase II trial is studying how well avoiding the hippocampus during whole-brain radiation therapy works in treating patients with brain metastases.
Brain metastases are the most common adult intracranial tumor, occurring in approximately 10% to 30% of adult cancer patients, and represent an important cause of morbidity and mortality. The most widely used treatment for patients with multiple brain metastases is whole brain radiation therapy (WBRT). The use of WBRT after resection or stereotactic radiosurgery (SRS) has been proven to be effective in terms of improving local control of brain metastases. RapidArc (RA) (Varian Medical Systems, Palo Alto, CA) is a new method of delivering radiation that uses "arcs" to deliver highly conformal intensity modulated three dimensional dose distributions. The purpose of this investigation is to evaluate an alternative strategy for giving WBRT with highly focal boost to gross visible lesions in patients with brain metastasis. Given the limitations of the SRS boost technique, the purpose of our investigation is to evaluate an alternative strategy for giving WBRT with highly focal boost to gross visible lesions in patients with brain metastasis. In this study, we plan to assess the tolerability of using volumetric modulated arc therapy (RapidArc) on patients with brain metastasis to simultaneously treat the entire brain with a concomitant focal boost to grossly identified lesions on MRI scan to try to improve local control and reduce neurocognitive toxicities. This previous version of this study was a phase I dose escalation trial giving 25 Gy in 10 fractions to the whole brain with simultaneous infield boost (SIB) to a total of 45 Gy in 10 fractions to gross brain metastatic disease. Prior to this, patients were enrolled onto one of two cohorts with whole brain dose of 30 Gy in 10 fractions with SIB to total of 45 Gy in 10 fractions to gross brain metastatic disease or whole brain dose of 37.5 Gy in 15 fractions with SIB to total of 52.5 Gy in 15 fractions to gross brain metastatic disease. A total of 12 patients have been previously enrolled on this trial. No patients have experienced a dose limiting toxicity (grade 3 or above) at least possibly due to study therapy. Also, no patients experienced local brain failure/progression at a site of treated metastatic brain disease. Based on this, we no longer feel that dose escalation to the gross brain disease is warranted and would proceed with a single arm pilot study treating patients with 25 Gy in 10 fractions to the whole brain with simultaneous infield boost (SIB) to a total of 45 Gy in 10 fractions to gross brain metastatic disease.
This randomized phase I/II trial studies the side effects and the best dose of RO4929097 (gamma-secretase/Notch signalling pathway inhibitor RO4929097) when given together with whole-brain radiation therapy or stereotactic radiosurgery and to see how well it works compared to whole-brain radiation therapy or stereotactic radiosurgery alone in treating patients with breast cancer or other cancers (such as lung cancer or melanoma) that have spread to the brain. RO4929097 may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth. Whole-brain radiation therapy uses high energy x-rays deliver radiation to the entire brain to treat tumors that can and cannot be seen. Stereotactic radiosurgery may be able to deliver x-rays directly to the tumor and cause less damage to normal tissue. It is not yet known whether giving RO4929097 together with whole-brain radiation therapy or stereotactic radiosurgery may kill more tumor cells.
RATIONALE: Radiation therapy uses high energy x-rays to kill tumor cells. Drugs, such as riluzole, may make tumor cells more sensitive to radiation therapy. Giving riluzole together with whole-brain radiation therapy may kill more tumor cells. PURPOSE: This phase I trial is studying the side effects and best dose of riluzole when given together with whole-brain radiation therapy in treating patients with brain metastases.
This phase I trial is studying the side effects and best dose of cediranib maleate when given together with whole brain radiation therapy in treating patients with brain metastases from non-small cell lung cancer. Cediranib maleate may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth or by blocking blood flow to the tumor. Radiation therapy uses high-energy x-rays and other types of radiation to kill cancer cells and shrink tumors. Giving cediranib maleate together with radiation therapy may kill more tumor cells
RATIONALE: Everolimus may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth and by blocking blood flow to the tumor. Radiation therapy uses high-energy x-rays to kill tumor cells. Giving everolimus together with whole-brain radiation therapy may kill more tumor cells. PURPOSE: This phase I/II trial is studying the side effects and best dose of everolimus and to see how well it works when given together with whole-brain radiation therapy in treating patients with brain metastasis from non-small cell lung cancer.