520 Clinical Trials for Various Conditions
All patients will complete best standard of care radiation, temozolomide and bevacizumab (6 weeks). Within two weeks of completion of this initial treatment period, study patients will be fitted with the NovoTTF-100A System and treated continuously. They will be treated with TTFields for 12 months for an average of 18 hours per day. The patient may elect to take a treatment break for a total of 3 days per month, for each month and still be in compliance. This will consist of wearing four electrically insulated electrode arrays on the head. The patients will also continue with maintenance temozolomide/ bevacizumab.
The PIONEER Initiative stands for Precision Insights On N-of-1 Ex vivo Effectiveness Research. The PIONEER Initiative is designed to provide access to functional precision medicine to any cancer patient with any tumor at any medical facility. Tumor tissue is saved at time of biopsy or surgery in multiple formats, including fresh and cryopreserved as a living biospecimen. SpeciCare assists with access to clinical records in order to provide information back to the patient and the patient's clinical care team. The biospecimen tumor tissue is stored in a bio-storage facility and can be shipped anywhere the patient and the clinical team require for further testing. Additionally, the cryopreservation of the biospecimen allows for decisions about testing to be made at a later date. It also facilitates participation in clinical trials. The ability to return research information from this repository back to the patient is the primary end point of the study. The secondary end point is the subjective assessment by the patient and his or her physician as to the potential benefit that this additional information provides over standard of care. Overall the goal of PIONEER is to enable best in class functional precision testing of a patient's tumor tissue to help guide optimal therapy (to date this type of analysis includes organoid drug screening approaches in addition to traditional genomic profiling).
We hope to determine the importance of different genes (including B receptors) in anthracycline-induced cardiomyopathy. This has important benefits to patients exposed to anthracyclines, as this could help determine whether certain individuals have increased susceptibility to cardiac injury.
The purpose of this study is to investigate the safety and effectiveness of a combination treatment for glioblastoma multiforme utilizing radiotherapy plus the FDA-approved chemotherapy drug temozolomide
The maximum tolerated dose of 3-session (ie, treatment) stereotactic radiosurgery (SRS) to treat brain metastases greater than 4.2 cm³ in size will be determined. This study investigates if increasing radiation dose improves outcome for patients without greater toxicity (side effects).
A research study of liver perfusion (how blood flows to the liver over time). We hope to learn whether perfusion characteristics of liver masses may be predictive of response to treatment and whether liver perfusion characteristics can be used to follow response to treatment.
The purpose of this study is to determine the usefulness of Cyberknife precision radiation in eliminating or preventing the further growth of spinal tumors and lesions.
In recent years, remarkable advances in medical oncology, surgery, and radiology have allowed for increasing cure rates for childhood malignancies. This success has led to an emerging understanding of the kinds of effects that treatments can have on the pediatric population and how such effects can influence pediatric cancer survivor's functioning and quality of life. It has become tremendously important to assess the long-term complications due to therapy in this growing sector of survivors and to tailor our treatments so as to minimize these late effects. The Investigators at MGH are committed to improving the delivery of radiotherapy to our patients and improving the outcome for these patients. MGH has an on-site cyclotron for proton radiotherapy in order to provide the most advanced care for patients in need. Proton therapy possesses a clinical advantage over standard photon therapy in that its optimal dose distribution delivers the bulk of radiation to the tumor site. This method spares the greatest volume of normal tissue, resulting in decreased short-term and long-term morbidity. Through open pediatric protocols for patients treated with proton radiotherapy, the investigators aim to define and report the acute and late effects associated with treatment. The investigators also treat a number of patients off-protocol with both proton and photon radiotherapy, and are interested in reporting these patients' QOL outcomes in conjunction with other clinical data that may be pertinent to the site of tumor treatment. This research is significant in that it will allow us to delineate the positive and negative effects of radiation treatment on patients' QOL, highlighting points of success and exposing areas that are in need of improvement. Such knowledge will be used to improve the experience of pediatric cancer survivors in the future. The aims of this study are: 1) to prospectively collect and report the QOL outcomes in patients treated with radiotherapy and 2) to correlate the QOL data with pertinent clinical information.
The purpose of this study is to see if mifepristone prevents worsening of your cancer. Mifepristone is an antiprogesterone agent, a drug which blocks female hormones, that is commonly used for the termination of pregnancies. It has not been approved by the Food and Drug Administration for use in the treatment of cancer. It is unlicensed in the United States for your condition. However, previous work has indicated that mifepristone may be useful due to how it works. It is being made available for use in the United States for compassionate use through the Feminist Majority Foundation.
Combidex (ferumoxtran-10) is an ultra-small iron oxide particle covered with a sugar coating. It has been evaluated as an MRI contrast agent for use in imaging well perfused organs such as the liver and spleen and for imaging lymph nodes. In this study, Combidex is being used to compare the standard imaging agent, Gadolinium, in imaging brain tumors and the area adjacent to the tumor location. Combidex may provide the ability to better see brain tumors and inflammatory lesions on magnetic resonance imaging (MRI) scans. Combidex may be useful in its ability to cross blood vessels into brain tumors, and because of its size and ability to get into the area next to brain tumors, could assist in the treatment of brain tumors with other drugs in the future.
This study proposes to do a prospective observational cohort study evaluating the quality of life (QOL) of children with Central Nervous System (CNS) tumors and their families who choose to self-medicate with marijuana-derived products while undergoing treatment at Children's Hospital Colorado (CHCO).
This study seeks to investigate an evidence-based, manualized, behavioral health intervention, Cognitive Behavioral Therapy for Insomnia (CBT-I), in individuals with primary brain tumors (PBT) and insomnia. Our project will assess the feasibility and acceptability of recruitment, enrollment, data collection procedures, and retention of individuals with PBT and insomnia in the behavioral health intervention, CBT-I, and investigate the potential benefits of CBT-I within this at-risk and understudied population. In the long term, the goals are to expand treatment options for neuro-oncology patients and improve their mission readiness and overall wellbeing.
Background: About 90,000 new cases of brain and spinal cord tumors are diagnosed annually in the United States. Most of these tumors are benign; however, about 30% are malignant, and 35% of people with malignant tumors in the brain and spinal cord will die within 5 years. Many of these people have changes in certain genes (MYC or MYCN) that drive the development of their cancers. Objective: To test a study drug (PLX038) in people with tumors of the brain or spinal cord. Eligibility: People aged 18 years or older with a tumor of the brain or spinal cord. Some participants must also have tumors with changes in the MYC or MYCN genes. Design: Participants will be screened. They will have a physical exam and blood tests. They will have imaging scans and a test of their heart function. They may need to have a biopsy: A sample of tissue will be removed from their tumor. PLX038 is given through a tube attached to a needle inserted into a vein in the arm. All participants will receive PLX038 on the first day of each 21-day treatment cycle. They will take a second drug 3 days later to help reduce the risk of infection; for this drug, participants will be shown how to inject themselves under the skin at home. Blood tests, imaging scans, and other tests will be repeated during study visits. Hair samples will also be collected during these visits. Some participants may have an additional biopsy. Study treatment will continue up to 7 months. Follow-up visits will continue every few months for up to 5 years.
This biospecimen collection study will evaluate the feasibility of engrafting and testing resected Central nervous system (CNS) tumors tumor tissue ex vivo to estimate drug response, in pediatric and adult subjects. CNS tumors display remarkable heterogeneity and unfortunately there are no reliable precision oncology platforms that can identify the most effective therapy for each patient. Recent work has demonstrated the success of functional precision oncology platforms using patient-derived explant (PDE) at predicting drug response in various cancers. Since PDEs maintain important aspects of tumor heterogeneity they may prove effective as functional models for CNS tumors. The purpose of this study is to explore the feasibility of using a novel PDE platform to generate drug sensitivity scores from patients with central nervous system tumors in Pediatric and adult subjects having low- or high-grade CNS tumors resected. The secondary objective is to estimate the proportion of successfully scaled PDEs generated per given tumor size.
Recent advances in technology have allowed for the detection of cell-free DNA (cfDNA). cfDNA is tumor DNA that can be found in the fluid that surrounds the brain and spinal cord (called cerebrospinal fluid or CSF) and in the blood of patients with brain tumors. The detection of cfDNA in blood and CSF is known as a "liquid biopsy" and is non-invasive, meaning it does not require a surgery or biopsy of tumor tissue. Multiple studies in other cancer types have shown that cfDNA can be used for diagnosis, to monitor disease response to treatment, and to understand the genetic changes that occur in brain tumors over time. Study doctors hope that by studying these tests in pediatric brain tumor patients, they will be able to use liquid biopsy in place of tests that have more risks for patients, like surgery. There is no treatment provided on this study. Patients who have CSF samples taken as part of regular care will be asked to provide extra samples for this study. The study doctor will collect a minimum of one extra tube of CSF (about 1 teaspoon or 5 mL) for this study. If the patients doctor thinks it is safe, up to 2 tubes of CSF (about 4 teaspoons or up to 20 mL) may be collected. CSF will be collected through the indwelling catheter device or through a needle inserted into the lower part of the patient's spine (known as a spinal tap or lumbar puncture). A required blood sample (about ½ a teaspoon or 2 3 mL) will be collected once at the start of the study. This sample will be used to help determine changes found in the CSF. Blood will be collected from the patient's central line or arm as a part of regular care. An optional tumor tissue if obtained within 8 weeks of CSF collection will be collected if available. Similarities between changes in the DNA of the tissue that has caused the tumor to form and grow with the cfDNA from CSF will be compared. This will help understand if CSF can be used instead of tumor tissue for diagnosis. Up to 300 people will take part in this study. This study will use genetic tests that may identify changes in the genes in the CSF. The report of the somatic mutations (the mutations that are found in the tumor only) will become part of the medical record. The results of the cfDNA sequencing will be shared with the patient. The study doctor will discuss what the results mean for the patient and patient's diagnosis and treatment. Looking for inheritable mutations in normal cells (blood) is not the purpose of this study. Genetic tests of normal blood can reveal information about the patient and also about the their relatives. The doctor will discuss what the tests results may mean for the patient and the their family. Patient may be monitored on this study for up to 5 years.
This is a Phase 1 study of central nervous system (CNS) locoregional adoptive therapy with SC-CAR4BRAIN, an autologous CD4+ and CD8+ T cells lentivirally transduced to express to express combinations of B7-H3, EGFR806, HER2, and IL13-zetakine chimeric antigen receptors (CAR). CAR T cells are delivered via an indwelling catheter into the ventricular system in children and young adults with diffuse intrinsic pontine glioma (DIPG), diffuse midline glioma (DMG), and recurrent or refractory CNS tumors. A child or young adult meeting all eligibility criteria, including having a CNS catheter placed into their ventricular system, and meeting none of the exclusion criteria will have their T cells collected. The T cells will then be bioengineered into a second-generation CAR T cell that target B7H3, EGFR806, HER2, and IL13-zetakine on tumor cells. Patients will be assigned to 1 of 2 treatment Arms based on the type of their tumor: * Arm A is for patients with DIPG (meaning primary disease localized to the pons, metastatic disease is allowed) anytime after standard radiation OR after progression. * Arm B is for patients with non-pontine DMG (meaning DMG in other parts of the brain such as the thalamus or spine) anytime after standard radiation OR after progression. This Arm also includes other recurrent/refractory CNS tumors.
Recent lab-based discoveries suggest that IDO (indoleamine 2,3-dioxygenase) and BTK (Bruton's tyrosine Kinase) form a closely linked metabolic checkpoint in tumor-associated antigen-presenting cells. The central clinical hypothesis for the GCC2020 study is that combining ibrutinib (BTK-inhibitor) with indoximod (IDO-inhibitor) during chemotherapy will synergistically enhance anti-tumor immune responses, leading to improvement in clinical response with manageable overlapping toxicity. GCC2020 is a prospective open-label phase 1 trial to determine the best safe dose of ibrutinib to use in combination with a previously studied chemo-immunotherapy regimen, comprised of the IDO-inhibitor indoximod plus oral metronomic cyclophosphamide and etoposide (4-drug combination) for participants, age 6 to 25 years, with relapsed or refractory primary brain cancer. Those previously treated with indoximod plus temozolomide may be eligible, including prior treatment via the phase 2 indoximod study (GCC1949, NCT04049669), the now closed phase 1 study (NLG2105, NCT02502708), or any expanded access (compassionate use) protocols. A dose-escalation cohort will determine the best safe dose of ibrutinib for the 4-drug combination. This will be followed by an expansion cohort, using ibrutinib at the best safe dose in the 4-drug combination, to allow assessment of preliminary evidence of efficacy.
This phase III trial compares memantine to placebo in treating patients with primary central nervous system tumors. Memantine may block receptors (parts of nerve cells) in the brain known to contribute to a decline in cognitive function. Giving memantine may make a difference in cognitive function (attention, memory, or other thought processes) in children and adolescents receiving brain radiation therapy to treat a primary central nervous system tumors.
The purpose of this study is to examine the use of a single dose of tozuleristide (24 or 36 mg) and the Canvas imaging system during surgical resection of primary central nervous system (CNS) tumors: Primary gadolinium enhancing (high grade) CNS tumors, primary non-gadolinium enhancing CNS tumors, and primary vestibular schwannoma. The primary objectives of the study is to see how well tozuleristide and the Canvas imaging system during surgical resection will show fluorescence among primary enhancing/high grade CNS tumors; and among the tumors that demonstrate tozuleristide fluorescence, to estimate the true positive rate and true negative rate of fluorescence in tissue biopsies, as well as sensitivity and specificity of tozuleristide fluorescence for distinguishing tumor from non-tumoral tissue. The secondary objectives of the study include evaluating the safety of tozuleristide and the Canvas imaging system, and to determine if the presence of remaining fluorescence at the time of surgery corresponds to remaining tumor evident on post-operative MRI images, or if the absence of fluorescence corresponds to evidence of no gross residual tumor on post-operative magnetic resonance imaging (MRI).
This study examines cerebrospinal biomarkers in patients with brain tumors. A biomarker is a measurable indicator of the severity or presence of your disease state. Collecting and storing samples of cerebrospinal fluid from patients with brain tumors to study in the laboratory may help doctors develop new strategies to better diagnose, monitor, and treat brain tumors.
This phase II trial studies the best approach to combine chemotherapy and radiation therapy (RT) based on the patient's response to induction chemotherapy in patients with non-germinomatous germ cell tumors (NGGCT) that have not spread to other parts of the brain or body (localized). This study has 2 goals: 1) optimizing radiation for patients who respond well to induction chemotherapy to diminish spinal cord relapses, 2) utilizing higher dose chemotherapy followed by conventional RT in patients who did not respond to induction chemotherapy. Chemotherapy drugs, such as carboplatin, etoposide, ifosfamide, and thiotepa, 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. Radiation therapy uses high energy x-rays or high-energy protons to kill tumor cells and shrink tumors. Studies have shown that patients with newly-diagnosed localized NGGCT, whose disease responds well to chemotherapy before receiving radiation therapy, are more likely to be free of the disease for a longer time than are patients for whom the chemotherapy does not efficiently eliminate or reduce the size of the tumor. The purpose of this study is to see how well the tumors respond to induction chemotherapy to decide what treatment to give next. Some patients will be given RT to the spine and a portion of the brain. Others will be given high dose chemotherapy and a stem cell transplant before RT to the whole brain and spine. Giving treatment based on the response to induction chemotherapy may lower the side effects of radiation in some patients and adjust the therapy to a more efficient one for other patients with localized NGGCT.
The PIRATE study tests the experimental drug RRx-001 in combination with 2 chemotherapy drugs that are commonly used in patients with cancer. RRx-001 has been used alone and with other anti-cancer medicines in adults. However, the investigators do not know what effects it will have in children and young adults.
This is a Phase 1 study of central nervous system (CNS) locoregional adoptive therapy with autologous CD4+ and CD8+ T cells lentivirally transduced to express a B7H3-specific chimeric antigen receptor (CAR) and EGFRt. CAR T cells are delivered via an indwelling catheter into the tumor resection cavity or ventricular system in children and young adults with diffuse intrinsic pontine glioma (DIPG), diffuse midline glioma (DMG), and recurrent or refractory CNS tumors. A child or young adult meeting all eligibility criteria, including having a CNS catheter placed into the tumor resection cavity or into their ventricular system, and meeting none of the exclusion criteria, will have their T cells collected. The T cells will then be bioengineered into a second-generation CAR T cell that targets B7H3-expressing tumor cells. Patients will be assigned to one of 3 treatment arms based on location or type of their tumor. Patients with supratentorial tumors will be assigned to Arm A, and will receive their treatment into the tumor cavity. Patients with either infratentorial or metastatic/leptomeningeal tumors will be assigned to Arm B, and will have their treatment delivered into the ventricular system. The first 3 patients enrolled onto the study must be at least 15 years of age and assigned to Arm A or Arm B. Patients with DIPG will be assigned to Arm C and have their treatment delivered into the ventricular system. The patient's newly engineered T cells will be administered via the indwelling catheter for two courses. In the first course patients in Arms A and B will receive a weekly dose of CAR T cells for three weeks, followed by a week off, an examination period, and then another course of weekly doses for three weeks. Patients in Arm C will receive a dose of CAR T cells every other week for 3 weeks, followed by a week off, an examination period, and then dosing every other week for 3 weeks. Following the two courses, patients in all Arms will undergo a series of studies including MRI to evaluate the effect of the CAR T cells and may have the opportunity to continue receiving additional courses of CAR T cells if the patient has not had adverse effects and if more of their T cells are available. The hypothesis is that an adequate amount of B7H3-specific CAR T cells can be manufactured to complete two courses of treatment with 3 or 2 doses given on a weekly schedule followed by one week off in each course. The other hypothesis is that B7H3-specific CAR T cells can safely be administered through an indwelling CNS catheter or delivered directly into the brain via indwelling catheter to allow the T cells to directly interact with the tumor cells for each patient enrolled on the study. Secondary aims of the study will include evaluating CAR T cell distribution with the cerebrospinal fluid (CSF), the extent to which CAR T cells egress or traffic into the peripheral circulation or blood stream, and, if tissues samples from multiple timepoints are available, also evaluate disease response to B7-H3 CAR T cell locoregional therapy.
Indoximod was developed to inhibit the IDO (indoleamine 2,3-dioxygenase) enzymatic pathway, which is important in the natural regulation of immune responses. This potent immune suppressive mechanism has been implicated in regulating immune responses in settings as diverse as infection, tissue/organ transplant, autoimmunity, and cancer. By inhibiting the IDO pathway, we hypothesize that indoximod will improve antitumor immune responses and thereby slow the growth of tumors. The central clinical hypothesis for the GCC1949 study is that inhibiting the pivotal IDO pathway by adding indoximod immunotherapy during chemotherapy and/or radiation is a potent approach for breaking immune tolerance to pediatric tumors that will improve outcomes, relative to standard therapy alone. This is an NCI-funded (R01 CA229646, MPI: Johnson and Munn) open-label phase 2 trial using indoximod-based combination chemo-radio-immunotherapy for treatment of patients age 3 to 21 years who have progressive brain cancer (glioblastoma, medulloblastoma, or ependymoma), or newly-diagnosed diffuse intrinsic pontine glioma (DIPG). Statistical analysis will stratify patients based on whether their treatment plan includes up-front radiation (or proton) therapy in combination with indoximod. Central review of tissue diagnosis from prior surgery is required, except non-biopsied DIPG. This study will use the "immune-adapted Response Assessment for Neuro-Oncology" (iRANO) criteria for measurement of outcomes. Planned enrollment is up to 140 patients.
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
Background: A sarcoma is a rare cancer. It grows in the body's connective tissue. Sarcomas in the brain and central nervous system are especially rare. The drug Sunitinib has been approved in many countries for treating other types of rare or advanced cancers. These include kidney, pancreas, and bowel cancer. Researchers want to see if it can help people with sarcomas of the central nervous system. Objective: To study the effects of Sunitinib on gliosarcomas or sarcomas of the central nervous system. Eligibility: Adults ages 18 and older with a gliosarcoma or sarcoma of the central nervous system Design: Participants will be screened with the following tests. Some may be done as part of their regular cancer care: Medical history Medication review Physical exam Blood, heart, and pregnancy tests Cranial scans to locate and measure their tumor Participants will take Sunitinib by mouth every day for 2 weeks and then take none of the drug for 1 week. These 3 weeks equal 1 cycle. Participants will have 2 study visits in cycle 1. They will have 1 visit in all other cycles. They will answer questions about quality of life and repeat some screening tests. Participants will take their blood pressure at home weekly. They keep a diary of each dose of Sunitinib and blood pressure reading. Participants can choose to share data about their physical activity levels and quality of sleep. These participants will wear a small, portable watch-sized accelerometer device on the wrist for 6 cycles. About 1 month after their last study drug dose, participants will have a final study visit. They will have a physical exam, blood tests, and scans.
Approximately 90% of children with malignant brain tumors that have recurred or relapsed after receiving conventional therapy will die of disease. Despite this terrible and frustrating outcome, continued treatment of this population remains fundamental to improving cure rates. Studying this relapsed population will help unearth clues to why conventional therapy fails and how cancers continue to resist modern advances. Moreover, improvements in the treatment of this relapsed population will lead to improvements in upfront therapy and reduce the chance of relapse for all. Novel therapy and, more importantly, novel approaches are sorely needed. This trial proposes a new approach that evaluates rational combination therapies of novel agents based on tumor type and molecular characteristics of these diseases. The investigators hypothesize that the use of two predictably active drugs (a doublet) will increase the chance of clinical efficacy. The purpose of this trial is to perform a limited dose escalation study of multiple doublets to evaluate the safety and tolerability of these combinations followed by a small expansion cohort to detect preliminary efficacy. In addition, a more extensive and robust molecular analysis of all the participant samples will be performed as part of the trial such that we can refine the molecular classification and better inform on potential response to therapy. In this manner the tolerability of combinations can be evaluated on a small but relevant population and the chance of detecting antitumor activity is potentially increased. Furthermore, the goal of the complementary molecular characterization will be to eventually match the therapy with better predictive biomarkers. PRIMARY OBJECTIVES: * To determine the safety and tolerability and estimate the maximum tolerated dose/recommended phase 2 dose (MTD/RP2D) of combination treatment by stratum. * To characterize the pharmacokinetics of combination treatment by stratum. SECONDARY OBJECTIVE: * To estimate the rate and duration of objective response and progression free survival (PFS) by stratum.
This study will assess the efficacy, safety and tolerability of pomalidomide in children and young adults aged 1 to \< 21 years with recurrent or progressive primary brain tumors in one of four primary brain tumor types: high-grade glioma (HGG), medulloblastoma, ependymoma and diffuse intrinsic pontine glioma (DIPG).
This pilot research trial studies blood brain barrier differences in patients with brain tumors undergoing surgery. Studying samples of tissue and blood from patients with brain tumors in the laboratory may help doctors to understand how well drugs get into different parts of a brain tumor. This may help them to determine which types of drugs may be best for treating brain tumors.
This pilot will study the feasibility and exploratory efficacy of using Cabozantinib for recurrent or refractory central nervous system tumors for which there are no curative options. Patients will also be followed for safety, time to progression, event free survival and overall survival