Active clinical trials for "Brain Neoplasms"

Background: - Brain metastases are cancer cells that have spread to the brain from primary cancers in other organs. These tumors can be removed surgically. However, researchers are trying to find better ways to treat brain metastases. A new drug, GRN1005, has been designed to cross into the brain and deliver the cancer treatment drug paclitaxel to treat tumors. Researchers want to see how well GRN1005 works on brain metastases from breast or lung cancer. Objectives: - To test the safety and effectiveness of GRN1005 in treating brain metastases from breast or lung cancer. Eligibility: - Individuals at least 18 years of age who have breast or lung cancer that has spread to the brain. Design: Participants will be screened with a physical exam and medical history. Blood and urine samples will be collected. Tumor tissue samples may also be collected. Imaging studies will also be performed. Participants who have breast cancer will be divided into two groups. Those whose cancer contains the HER2 protein will be treated with the drug Herceptin as well as GRN1005. Those without HER2 will have only GRN1005. Participants who have lung cancer will also have only GRN1005. All participants will have two doses of GRN1005, each 3 weeks apart. On the day the second dose of GRN1005 is given, participants will undergo surgery to remove the brain tumors. Treatment will be monitored with frequent blood tests and imaging studies.

Brain metastases occur in 20-40% of patients with primary extracerebral tumors. Despite important advances in therapy of malignant solid tumors and treatment of 1-3 brain metastases, multiple brain metastases continue to present a significant problem in attempting to prevent progression of disease and limit morbidity associated with therapy. The majority of patients who develop brain metastases have a short survival, effective palliation being transient. The median survival after diagnosis is as low as 3-6 months. However, there is some evidence that selected patients survive prolonged periods with vigorous therapeutic approach. Specific therapeutic options are surgery, chemotherapy, conventional fractionated whole-brain radiotherapy (WBRT) and radiosurgery. Radiosurgery allows delivering of a single high dose fraction of radiation to targets of 3-3.5 cm maximum diameter. In patients with newly diagnosed brain metastases, a rapid decrease of symptoms, local tumor response rate of 73-90% and a median survival of 7-12 month have been reported. WBRT alone is the treatment of choice for patients with multiple brain metastases, and for patients with single brain metastases not amenable to surgery or radiosurgery. Median survival after WBRT alone is 3-6 months. WBRT and radiosurgery boost have been shown to improve survival in RPA class I patients and in patients with favorable histological status and squamous cell or non-small cell lung tumors. All randomized trials showed improved local control with the addition of radiosurgery to WBRT (Andrews, 2004). WBRT in conjunction with radiosurgery improves local control and reduces the risk of new distant brain metastases, but most studies support that combined radiosurgery and WBRT does not improve the overall survival expect for patients without evidence of extracranial disease. Helical Tomotherapy (HT) allows as a sole modality a new treatment option: Using HT, the advantage of applying a highly conformal boost dose to the metastases and WBRT can be combined in one treatment session. Therefore, it allows applying a high dose to multiple brain metastases in the sense of an integrated boost. The focus of this study is to investigate the efficacy and safety of WBRT with an integrated boost using this new treatment modality in comparison to the effects of conventional WBRT alone. The principal objective of the trial is to assess the therapeutic efficacy of WBRT as compared to WBRT combined with integrated boost with HT delivered to patients with 2-10 brain metastases of solid tumors. The secondary objective is to evaluate the safety of WBRT as opposed to WBRT combined with integrated boost as delivered by HT in patients with 2-10 brain metastases.

In this study, the Visualase Thermal Therapy System will be used on metastatic brain tumors that cannot be removed by surgery. Researchers want to find out if it is possible to use this new device in subjects with 1-3 metastatic brain tumor(s), each measuring 3 centimeters (cm) or smaller. The safety of the device will also be studied.

Study Objective: Brain tumors are poorly understood. The purpose of this research is to examine whether factors in lifestyle play a role in brain tumor development. The study will also investigate the contribution of inherited susceptibility to the risk of brain cancer. By gaining a better understanding of these influences, the investigators hope to learn how to prevent brain tumors in future generations, and to develop more effective strategies for treatment. Study Protocol: This is a case-control investigation. Persons affected with a brain tumor are compared to unaffected persons on previous medical history, diet and other factors. Those enrolled in the study will participate in an interview on general background, diet, medical history and lifestyle, and will provide a sample of DNA, clippings of your toenails, and a tap water sample from your home. All procedures are performed in the clinic or through the mail. 'Cases': Cases eligible for the study are persons with a recent diagnosis of a primary brain tumor (glioma or meningioma), at least 18 years of age. 'Controls': Controls in the study are non-family members of patients, similar in age and of the same gender. Suitable controls include in-laws, friends, neighbors and co-workers.

Maximizing surgical removal of brain tumors while minimizing neurologic deficits is challenging. Functional brain tissue may reside close to or even within the abnormality, and inadvertent removal or disturbance of such areas can result in neurologic deficits. At present, the gold standard for identifying critical motor areas in tumor surgery is intraoperative invasive direct current stimulation (DCS) through a handpiece. More recently, new non-invasive preoperative method for brain mapping, functional magnetic resonance imaging (fMRI), may be used to identify the eloquent motor areas. fMRI signals used in localization of the motor areas are generated when the brain is activated during the performance of specific motor tasks. However, as fMRI signals are also generated by sensory input, the resulting fMRI map may include sensory as well as motor areas. Nexstim has developed a Navigated Brain Stimulation (NBS) system that uses TMS with a software based Navigational System that together may have more specific spatial accuracy. This study aims to determine whether navigated TMS is able to identify the eloquent motor cortical areas in patients with brain tumors and to determine the clinical accuracy of the procedure by comparing it to results obtained by intraoperative DCS and fMRI.

Anti PD-1 monoclonal antibodies (nivolumab and pembrolizumab) alone or in association with antiCTLA4 (Ipilimumab) are established as indisputable treatment of metastatic melanoma, with unprecedented overall survival, and are indicated for first-line treatment including patients with BRAF mutation. Given their high molecular weight, their penetration in the brain sanctuary is uncertain and relies on disruption of the Blood Brain Barrier (BBB) which occurs occasionally. SonoCloud® is an implantable device delivering low intensity pulsed UltraSound (US). Along with systemic injection of an US resonator, SonoCloud® demonstrated safe and efficient at repetitively opening the BBB. The investigators anticipate that BBB opening could help at increasing brain penetration of monoclonal antibodies and potentially boosting immunity in the brain. This could translate in controlling brain disease with the same magnitude as for extra-cranial disease. This would also open avenues for optimizing the treatment of brain metastases in combination with checkpoint inhibitors in many other cancers.

This clinical trial is being done to learn more about how different types of cancer treatments affect cancer cells when they spread to the brain. Many cancer treatments are not able to make their way into the brain or into spinal fluid of the central nervous system. This is because they cannot cross what is called the "blood-brain barrier" or "BBB". The BBB is like a protective shield that only allows certain materials pass through to reach the brain but not others. This study is being initiated to help researchers learn more about what types of cancer treatments make it through the BBB to attack cancer cells within the brain, and what treatments do not make it through the BBB. Learning more about this may help future researchers develop more effective cancer drugs that better fight cancer cells that have spread to the brain.

The study will enrol adult female and male patients with BRAF wild-type melanoma and brain metastases who are not eligible for surgery or radiosurgery and failed prior therapy with ipilimumab, and patients with BRAF V600 mutation-positive melanoma and brain metastases who are not eligible for surgery or radiosurgery and who failed prior therapy with a BRAF inhibitor.

This trail is designed to assess the efficacy and safety of high dose Iconitib combined with SRS for NSCLC patients harboring EGFR mutation with brain metastases.

The study is a prospective, randomly controlled phase II trial, designed to test the efficacy, safety and neurocognitive outcomes of a medical device, the NovoTTF-100A, in the treatment of NSCLC patients with controlled systemic disease, following optimal standard local treatment for 1-5 brain metastases (BM). The device is an experimental, portable, battery operated device for chronic administration of alternating electric fields (termed TTFields or TTF) to the region of the malignant tumor, by means of surface, insulated electrode arrays.