1,778 Clinical Trials for Various Conditions
The purpose of this study is to test the safety and effectiveness of the study drug datopotamab deruxtecan in participants with metastatic breast cancer that has spread to the brain. The name of the study drug used in this research study is: Datopotamab deruxtecan (a type of antibody-drug conjugate)
This is a single arm study of abemaciclib and endocrine therapy with stereotactic radiosurgery (SRS) among patients with hormone receptor (HR)+/HER2- metastatic breast cancer brain metastases.
This study is a Phase I/II study evaluating the safety and effectiveness of focused radiation therapy (radiosurgery) together with olaparib, followed by immunotherapy, for patients with brain metastases from triple negative or BRCA-mutated breast cancers. This study will have a Phase I portion in which subjects will be enrolled based on 3+3 dose escalation rules. Three dose levels of olaparib will be studied. Cycle 1 of study treatment will consist of Olaparib given twice daily concurrently with stereotactic radiosurgery (SRS). Olaparib will start one week prior to SRS and continue during and following SRS (1-5 fractions) for up to 28 days total. The number of doses of Olaparib will be dependent on how long it takes a subject to recover from SRS (ideally the subject will be off steroids, if they are required, at the start of Cycle 2, with exceptions outlined later in this section). Once the subject has recovered from SRS (based on investigator discretion) that will be considered the DLT period. Cycle 2 will be initiated with physician's choice systemic therapy and durvalumab. Cycle 2+ will equal 21 days. During Cycles 2 and 3, physician's choice systemic monotherapy will be given along with durvalumab per protocol. Each cycle will last 21 days. Imaging to evaluate intracranial and extracranial disease will be performed after Cycle 3, and subjects with response will continue with the systemic therapy and durvalumab until progression (intracranial or extracranial), unacceptable toxicity or death.
This phase II trial investigates how stereotactic radiosurgery affects brain functions while treating patients with small cell lung cancer that has spread to the brain (brain metastasis). Standard of care treatment consists of whole brain radiation therapy, which targets the entire brain, and may result in side effects affecting the nervous system. Stereotactic radiosurgery only targets areas of the brain that are suspected to be affected by the disease. The purpose of this trial is to learn if and how patients' brain functions are affected by the use of stereotactic radiosurgery rather than whole brain radiation therapy in managing brain metastasis caused by small cell lung cancer. Stereotactic radiosurgery may help patients avoid nervous system side effects caused by whole brain radiation therapy.
This is a single arm, open label trial to assess the safety and efficacy of tucatinib in combination with pembrolizumab and trastuzumab for the treatment of HER2+ breast cancer brain metastases (BCBM). A total of 33 patients with untreated or previously treated and progressing HER2+ BCBM not requiring urgent central nervous system (CNS)-directed therapy will be enrolled. The study will determine the recommended dose of tucatinib in this combination and assess the efficacy of this combination in controlling CNS disease in patients with HER2+ BCBM.
This study will test the safety of the study drug, GDC-0084, in combination with radiation therapy in people who have solid tumor brain metastases or leptomeningeal metastases. All participants will have cancer with a PIK3CA mutation. The researchers will test increasing doses of GDC-0084 to find the highest dose that causes few or mild side effects in participants. The study will also try to find out if the combination of the study drug with radiation is effective against participants' cancer.
This study is to find out if administration of stereotactic radiosurgery (SRS) given after Nivolumab will improve overall response rate/anti-tumor activity in patients with metastatic breast cancer with brain metastases.
This trial studies the side effects and how well ketoconazole works before surgery in treating patients with glioma that has come back or breast cancer that has spread to the brain. Ketoconazole is an antifungal drug that may be able to block a protein, tGLI1 and may help to treat brain tumors.
This research study is studying a drug called GDC-0084 as a possible treatment for HER2-Positive Breast Cancer. The drugs involved in this study are: * GDC-0084 * Trastuzumab (Herceptin®)
Background: Sometimes breast cancer spreads (metastasizes) to the brain. Researchers want to study new treatments for brain metastases. The drug Temozolomide is approved to treat brain tumors. Researchers want to see if combining it with the drug trastuzumab emtansine (T-DMI) prevents the formation of new metastases in the brain. Objective: To study if Temozolomide with T-DM1 lowers the chance of having new metastases in the brain. Eligibility: Adults at least 18 years old with a human epidermal growth factor receptor 2 (HER2)-positive breast cancer that has spread to the brain and was recently treated with stereotactic radiation or surgery. Design: Participants will be screened with * Medical history * Physical exam * Heart tests * A scan (computed tomography (CT) that makes a picture of the body using a small amount of radiation * A scan (magnetic resonance imaging (MRI) that uses a magnetic field to make an image of the brain * Blood tests. * Pregnancy test. The study will be done in 3-week cycles. All participants will get T-DM1 on Day 1 of every cycle through a small plastic tube inserted in an arm vein. Some participants will also take Temozolomide capsules by mouth every day. Participants will keep a medication diary. During the study, participants will also: * Repeat most of the screening tests. * Answer questions about their general well-being and functioning. Participants will have lumbar puncture at least 2 times. A needle is inserted into the spinal canal low in the back and cerebrospinal fluid is collected. This will be done with local anesthesia and with the help of images. Participants will be asked to provide tumor samples when available. Participants will have a follow-up visit about 1 month after stopping the study drug. They will be contacted by telephone or email every 3 months after that.
This pilot trial studies the side effects of giving pembrolizumab together with stereotactic radiosurgery to treat patients with melanoma or non-small cell lung cancer that has spread to the brain. Monoclonal antibodies, such as pembrolizumab, may interfere with the ability of tumor cells to grow and spread. 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. Giving pembrolizumab together with stereotactic radiosurgery may be a better treatment for patients with melanoma or non-small cell lung cancer that has spread to the brain.
This study will use advanced MRI techniques to characterize the changes that occur to the structure and functionality of the brain in older breast cancer patients receiving adjuvant chemotherapy, and determine the relationship between the brain changes and severity of chemotherapy toxicity. Our results will be an early step towards identifying neuroimaging markers of aging, breast cancer and chemotherapy treatment, and will contribute to our understanding of the underlying pathophysiology of cognitive changes and chemotherapy toxicity in vulnerable, older adults with cancer. Furthermore, the work will lay the foundation for future, larger scale clinical studies of cognitive changes and chemotherapy toxicity in the aging cancer population.
Sorafenib is a new type of anti-cancer drug. It belongs to a new class of medications known as tyrosine kinase inhibitors. Sorafenib is thought to work against cancer in many ways. It helps decrease blood supply to the tumor. It also blocks some proteins that help the tumor cells to grow." Sorafenib is approved by the Food and Drug administration (FDA) for treatment for other cancers like liver and kidney cancer. Sorafenib has also been studied in the treatment of breast cancer that has spread but is not specifically approved for the treatment of breast cancer. It has been studied both as a single agent and also in combination with other anti-cancer therapies for breast cancer. In laboratory models and in some patients with other cancers, sorafenib has been studied in tumors in the brain. In this study, sorafenib will be given together with whole brain radiation therapy (WBRT). Overall this research study is designed to answer 2 main questions: 1. What dose of sorafenib should be used together with WBRT? 2. What are the side effects of sorafenib and WBRT when given together?
Purpose: This study is a single-arm, open-label phase II clinical trial testing the hypothesis that daily everolimus plus weekly vinorelbine and trastuzumab will be effective, safe, and tolerable among patients with human epidermal growth factor receptor 2 (HER2)-positive breast cancer brain metastases. Once enrolled, patients will receive everolimus PO daily in combination with weekly intravenous (IV) vinorelbine and trastuzumab. Cycles will be repeated every 3 weeks (21 days). At the time of progression, patients will come off study. Participants: Up to 35 adults over 21 with HER-2 positive breast cancer that has metastasized to the brain.
The purpose of the study is to investigate the response rate for triple negative breast cancer patients with brain metastasis when INIPARIB is used in combination with irinotecan. Based on data generated by BiPar/Sanofi, it is concluded that iniparib does not possess characteristics typical of the PARP inhibitor class. The exact mechanism has not yet been fully elucidated, however based on experiments on tumor cells performed in the laboratory, iniparib is a novel investigational anti-cancer agent that induces gamma-H2AX (a marker of DNA damage) in tumor cell lines, induces cell cycle arrest in the G2/M phase in tumor cell lines, and potentiates the cell cycle effects of DNA damaging modalities in tumor cell lines. Investigations into potential targets of iniparib and its metabolites are ongoing.
The purpose of this research study is to determine how well the combination of bevacizumab and carboplatin works in treating breast cancer that has spread to the brain. Bevacizumab is an antibody (a protein that attacks a foreign substance in the body) that is made in the laboratory. Bevacizumab works differently from the way chemotherapy drugs work. Usually chemotherapy drugs attack fast growing cancer cells in the body. Bevacizumab works to slow or stop the growth of cells in cancer tumors by decreasing the blood supply to the tumors. When the blood supply is decreased, the tumors don't get the oxygen and nutrients they need to grow. Carboplatin is in a class of drugs known as platinum-containing compounds and has been approved for use in the treatment of ovarian cancer. Information from other research studies suggests that the combination of bevacizumab with carboplatin may be effective in treating breast cancer.
This trial studies how well stereotactic radiation therapy before surgery works in treating patients with cancer that has spread to the brain (brain metastases) and can be removed by surgery (resectable). Stereotactic radiation therapy 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. Giving stereotactic radiation therapy before surgery may make the return of brain metastases less likely and help patients live longer compared to surgery followed by radiation therapy.
This study is a clinical trial to determine the safety of inoculating G207 (an experimental virus therapy) into a recurrent or refractory cerebellar brain tumor. The safety of combining G207 with a single low dose of radiation, designed to enhance virus replication, tumor cell killing, and an anti-tumor immune response, will also be tested. Funding Source- FDA OOPD
The primary goal of this research study is to determine the efficacy of giving pre-operative radiosurgery to patients pending resection of a brain metastasis.
This was a 2-part, Phase I/IIa, multi-center, open label, study in pediatric and adolescent patients with advanced BRAF V600 mutation-positive solid tumors. Part 1 was a dose escalation study in patients with any BRAF V600 mutation-positive solid tumor using a modified Rolling 6 Design (RSD). Part 2 was an expansion study to further evaluate the safety, tolerability, and clinical activity of dabrafenib in 4 tumor-specific pediatric populations. Patients participated in only either part 1 or part 2 of the study.
The purpose of this study is to determine the safety and utility of 5-aminolevulinic acid (ALA) for identifying your tumor during surgery. 5-ALA is not FDA approved at this time. When the investigators remove the tumor from your brain, it is important that they remove all of the tumor and not remove parts of normal brain. Sometimes this can be difficult because the tumor can look like normal brain. In some brain tumors, 5-ALA can make the tumors glow red under blue light. This may make it easier for your doctor to take out all of the tumor from your brain. The purpose of this study is to: * Make sure that 5-ALA helps the doctor remove more of the tumor. * Make sure 5-ALA does not cause any side effects. If you do not want to participate in this study, your doctor(s) will still do their best to remove all of the tumor in your brain. Whether or not you join this study will not change your treatment for your brain tumor.
RATIONALE: Monoclonal antibodies, such as basiliximab, can block tumor growth in different ways. Some block the ability of tumor cells to grow and spread. Others find tumor cells and help kill them or carry tumor-killing substances to them. 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. Radiation therapy uses high-energy x-rays to kill tumor cells. Vaccines may help the body build an effective immune response to kill tumor cells. Giving these treatments together may kill more tumor cells. Granulocyte Macrophage-Colony Stimulating Factor (GM-CSF) is a powerful adjuvant capable of stimulating macrophage function, inducing proliferation and maturation of DCs, and is able to enhance T-lymphocyte stimulatory function. Intradermal administration of GM-CSF enhances the immunization efficacy at the site of administration PURPOSE: This clinical trial is studying how well basiliximab works in treating patients with newly diagnosed glioblastoma multiforme and temozolomide-caused lymphopenia who are undergoing targeted immunotherapy.
This study will be focused on assessing the molecular, physiological, and emotional correlates of an intensive meditation experience in the context of a retreat setting in a large 2000 plus-person cohort comprised of healthy and clinical populations.
This research study is for Glioblastoma (GBM) patients who will be beginning Optune as part of their clinical care, which is a novel treatment that utilizes - tumor treating fields (TTFields), (aka, electrical therapy), which has shown to improve overall survival in large multi-center trials. As a part of this study, participants will either receive Optune with "standard array mapping" (based on regular contrast enhanced MRI) or an "alternative (more precise) array mapping" based on sophisticated state of the art MRI techniques including "whole brain spectroscopy". Whole brain MRI spectroscopy provides additional metabolic information to map out the full extent of tumor spreading within the brain (far beyond from what is seen on regular MRI), by identifying certain metabolites that are present in cancer cells versus healthy tissue. This study is being performed to show whether alternative array mapping improves treatment outcomes, as opposed to the standard array mapping, by maximizing delivery of TTFields dose, thereby achieving more effective tumor cell killing, decreasing the rate of local recurrence, and improving the overall survival as well as quality of life measures.
The purpose of this study is to pilot test an empirically supported psychotherapeutic intervention, Managing Cancer and Living Meaningfully (CALM). Researchers hope to better understand the potential benefits of this intervention on brain tumor patients' mood and quality of life. This may lead to improvements in doctor's understanding of how to enhance brain tumor patient's wellbeing and overall functioning.
Refractory epilepsy, meaning epilepsy that no longer responds to medication, is a common neurosurgical indication in children. In such cases, surgery is the treatment of choice. Complete resection of affected brain tissue is associated with highest probability of seizure freedom. However, epileptogenic brain tissue is visually identical to normal brain tissue, complicating complete resection. Modern investigative methods are of limited use. An important subjective assessment during surgery is that affected brain tissue feels stiffer, however there is presently no way to determine this without committing to resecting the affected area. It is hypothesized that intra-operative use of a tonometer (Diaton) will identify abnormal brain tissue stiffness in affected brain relative to normal brain. This will help identify stiffer brain regions without having to resect them. The objective is to determine if intra-operative use of a tonometer to measure brain tissue stiffness will offer additional precision in identifying epileptogenic lesions. In participants with refractory epilepsy, various locations on the cerebral cortex will be identified using standard pre-operative investigations like magnetic resonance imagin (MRI) and positron emission tomography (PET). These are areas of presumed normal and abnormal brain where the tonometer will be used during surgery to measure brain tissue stiffness. Brain tissue stiffness measurements will then be compared with results of routine pre-operative and intra-operative tests. Such comparisons will help determine if and to what extent intra-operative brain tissue stiffness measurements correlate with other tests and help identify epileptogenic brain tissue. 24 participants have already undergone intra-operative brain tonometry. Results in these participants are encouraging: abnormally high brain tissue stiffness measurements have consistently been identified and significantly associated with abnormal brain tissue. If the tonometer adequately identifies epileptogenic brain tissue through brain tissue stiffness measurements, it is possible that resection of identified tissue could lead to better post-operative outcomes, lowering seizure recurrences and neurological deficits.
Aqueduct's Smart External Drain (SED) will be compared to the current gold standard for temporary CSF management in a hospital setting. * Evaluate the number of subjects requiring to be switched to a standard of care EVD * Evaluate subject transport while on the SED * Evaluate SED system control from initiation of SED through discharge of external drain system
To evaluate the performance characteristics of the Smart External Drain (SED) compared with standard EVD drains in the hospital setting, specifically: * Number, type and duration of staff interactions. * Regulating and controlling ICP and CSF drainage. * Maintaining system control with patient movement.
Background: The number of people who get tumors of the brain or central nervous system (CNS) is lower than other cancers. But these tumors cause a higher rate of serious effects and even death. Researchers want to test existing samples of tissue from these tumors to learn more about them. This may lead to better treatment. Objective: To study stored samples of CNS tumors to learn more about the tumors and explore new ways to diagnose them. Eligibility: The study will use tissue samples already collected at NIH from people with brain or CNS tumors. Design: The participants will have given their consent in a previous study. Researchers will review the tissue samples and any data collected about them. Researchers will do lab tests and scans on the samples. All data will be kept secure.
The goal of this clinical trial is to study the drug MEK162 in children with a brain tumor call low-grade glioma, as well as in children with other tumors in which a specific growth signal is abnormally turned on. The main questions it aims to answer are: What is the correct dose of MEK162 in children? What are the side effects of MEK162 in children? Is MEK162 effective in children with low-grade glioma? Participants on the study receive MEK162 by mouth twice daily for up to 2 years.