View clinical trials related to Brain Cancer.
Filter by:Cancer is a leading cause of death worldwide. It is estimated that approximately 55,000 Canadians are surviving with brain tumors. It is projected that around 3000 persons will be diagnosed with brain and spinal cord tumors, and approximately 75 percent patients will not survive. Out of all brain cancers, high-grade gliomas [Glioblastoma Multiforme (GBM)] impose highest morbidity and mortality. Therefore, it is important to explore ways in which Investigators can improve and prolong the lives of patients suffering from brain cancers, particularly high-grade glioma, which is the most common and aggressive primary brain tumor. So far the Investigators know that the surgery, chemotherapy and radiotherapy are the three corner stones management options for these patients, and majority of the research have been conducted on these three major domains. Therefore, it is imperative to explore the other variables those may impact survival characteristics. One of the integral variables of the brain cancer surgery is anesthesia. Interestingly, the role of anesthetics was explored in some other non-brain solid organ tumor surgeries. It is observed that out of the two main types of anesthesia [one is through intravenous (propofol) and other one is gaseous (sevoflurane)], intravenous based anesthesia maintenance regime may delay the cancer progression and prolong the recurrence free period. In addition, two very large retrospective studies with approximately 11,000 and 18,000 patients respectively, showed that as compared to gaseous (volatile anesthetics) based, intravenous (propofol) based anesthesia conferred some protection against cancer progression and was also associated with lesser overall mortality. The exact nature of these protective mechanisms is not known but in animal and other laboratory-based experiments, propofol seems to inhibit cancer formation steps, delays inflammation and provide protection from cancer cell growth. This is a feasibility study for knowing various aspects of workflow; recruitment characteristics of participants and various obstacles in implying anesthesia based protocols so that the Investigators can conduct a well-designed multicenter international randomized study.
The purpose of this study is to determine whether AGuIX (Activation and Guidance of Irradiation by X-ray) gadolinium-based nanoparticles make radiation work more effectively in the treatment of patients with brain metastases that are more difficult to control with stereotactic radiation alone.
This study assesses the feasibility of SGM-101, a fluorochrome-labeled anti-carcinoembryonic antigen monoclonal antibody, for intraoperative near-infrared fluorescence imaging of colorectal brain metastases by injecting SGM-101 intravenously 3 - 5 days prior to surgery.
The spread of cancer to the brain is referred to as brain metastases. Brain metastases are a common complication of cancer. This study is being done to determine whether the use of a new imaging agent, 18F-fluciclovine, is able to detect which patients are responding to radiation therapy. In addition, this study will look at the changes of the treated brain metastases using this imaging agent over time.
Posterior fossa tumours (PFT) account for 2/3 of childhood brain cancers. They can be highly malignant requiring combined chemotherapy and radiotherapy post-surgery for a >50% chance of cure. PFT frequently involve the cerebellum which is responsible for coordinating movement, balance, emotional control, and links closely to control of affect and executive function. PFT survivors show highly variable profiles for cognitive and sensorimotor functioning which are influenced strongly by the severity of the pre-diagnostic or post-surgical brain injury State-of-the-art magnetic resonance imaging (MRI) scans can allow to measure a variety of different biological processes in the brain, and the investigators believe that some of these MRI measures (called MRI biomarkers) have the potential to improve our ability to understand and monitor consequences of the ablative brain surgery and complex mechanisms of motor skills recovery. Biomarkers are very important for the development of intervention because 1) they help understand the recuperation process and 2) they allow to effectively assess whether or not a treatment or intervention works. Transcranial magnetic stimulation (TMS) is a powerful non-invasive neuro-modulatory intervention that has the potential to evaluate the integrity of the nervous tracts from the brain to the hand. It is a procedure that applies magnetic pulses on the surface of the scalp to reach underlying brain tissue. TMS has built a reputable status among neuro-rehabilitative research, and there is currently a major effort to translate the positive research findings into clinically useful therapeutic strategies. This study is therefore an important first step towards understanding how potential MRI biomarkers and responses to TMS relate to motor symptoms in PFT young survivors. Once completed, this study will allow the investigators to select the most promising MRI biomarkers and TMS protocols to take forward into future treatment trials. The investigators aim to stimulate the recovery of coordination skills, help the development of targeted therapies, and consequently improve long-term quality of life in children and young people with history of brain tumour. The proposed research intends to prove the feasibility of such brain stimulation and imaging and collect some preliminary measures
This is an open-label, two-part, phase 1-2 dose-finding study designed to determine the safety, tolerability, PK, PD, and proof-of-concept efficacy of ST101 administered IV in patients with advanced solid tumors. The study consists of two phases: a phase 1 dose escalation/regimen exploration phase and a phase 2 expansion phase.
This trial is a paucicentric, clinico-biological cohort study with retrospective and prospective enrollment, aiming to identify biomarkers predictive of response to Proton Beam Therapy (PBT) in cancer patients (high grade sarcoma, brain tumors and meningioma). This study include collection of clinical data, of tumor samples (collected during standard of care) and a blood sample for alive patients.
The purpose of the study is to determine if family caregivers of neuro-oncology patients feel less burdened by utilizing the Electronic Social Network Assessment Program (eSNAP) + the Caregiver Navigator.
The Multi-OutcoMe EvaluatioN of radiation Therapy Using the Unity MR-Linac Study (MOMENTUM) is a multi-institutional, international registry facilitating evidenced based implementation of the Unity MR-Linac technology and further technical development of the MR-Linac system with the ultimate purpose to improve patients' survival, local, and regional tumor control and quality of life.
The trial is designed as a multicenter randomized controlled study. 246 patients with presumed Glioblastoma Multiforme in eloquent areas on diagnostic MRI will be selected by the neurosurgeons according the eligibility criteria (see under). After written informed consent is obtained, the patient will be randomized for an awake craniotomy (AC) (+/-123 patients) or craniotomy under general anesthesia (GA) (+/-123 patients), with 1:1 allocation ratio. Under GA the amount of resection of the tumour has to be performed within safe margins as judged by the surgeon during surgery. The second group will be operated with an awake craniotomy procedure where the resection boundaries for motor or language functions will be identified by direct cortical and subcortical stimulation. After surgery, the diagnosis of GBM will have to be histologically confirmed. If GBM is not histologically confirmed, patients will be considered off-study and withdrawn from the study. These patients will be followed-up according to standard practice. Thereafter, patients will receive the standard treatment with concomitant Temozolomide and radiation therapy and standard follow up. Total duration of the study is 5 years. Patient inclusion is expected to take 4 years. Follow-up is 1 year after surgery. Statistical analysis, cost benefit analysis and article writing will take 3 months.