View clinical trials related to Brain Neoplasms.
Filter by:A single arm observational study investigating the incidence of brain metastasis in patients with cancer recti and lung metastasis
In this study, the investigators aim to undertake a retrospective analysis of CT and MRI scans for patients undergoing radiation treatment to develop radiomic signatures to predict treatment response and clinical outcomes.
To evaluate the efficacy and safety of TY-9591 tablets in the treatment of EGFR mutation-positive non-small cell lung cancer (NSCLC) patients with brain or leptomeningeal metastases.
This phase II trial studies whether low dose dexamethasone works as well as standard dose dexamethasone to reduce brain swelling after brain surgery in patients with primary brain tumors or cancer that has spread from other places in the body to the brain (metastatic). Surgery is an important part of the treatment of brain tumors; however, it results in injury to surrounding brain tissue, leading to brain swelling. Dexamethasone is effective for controlling the swelling of the brain; however, dexamethasone can cause many unwanted side effects. To minimize the side effects of dexamethasone, the lowest dose needed to control swelling of the brain should be used. This research study is assessing the safety of using a lower than standard dose of dexamethasone after the surgery to control brain swelling.
The purpose of this prospective, interventional, single-arm pilot study is to evaluate whether virtually delivered group-based physical activity is feasible for adolescent and young adult (AYA) cancer survivors. AYAs who were diagnosed with cancer and have completed cancer treatment will be recruited for this study. This study will enroll 20 participants in total and will last approximately 3 months.
Brain metastases (BM) are a common systemic cancer manifestation which incidence increases. Therapeutic options include whole-brain radiotherapy (WBRT), surgery, and stereotactic radiosurgery (SRS). The concept of "oligometastatic" cerebral disease (oligoBM) has emerged and led to consider alternative approaches. The main challenge is to preserve neurological function and independence the longest as possible. Stereotactic radiotherapy (SRT) has emerged as an alternative treatment modality for selected oligoBM patients. It allows to achieve the balance of tumour destruction and normal tissue preservation by precisely and accurately delivering a very high dose of radiation in one (SRS) or a few (HSRT) fractions to a limited, well-defined volume. However, no standard exists for decision-making between SRS and HSRT and this important question is being discussed in the recent literature. HSRT appears particularly interesting, assuming the patient convenience of few fractions, the normal tissue sparing achieved through focal irradiation, and the improved normal tissue tolerance of high dose radiation through fractionation. Common adverse effects of SRT are rare but can occasionally be serious, notably radionecrosis that may induce neurological deficits in patients. Although SRS is often less well-tolerated, it remains the mainstay of treatment. To investigators knowledge, SRS and HSRT have not been prospectively compared.
During gamma scalpel treatment of brain tumors and metastases, a follow-up magnetic resonance imaging (MRI) scan is performed. The radiologist who reviews the MRI assesses whether there is an increase in signal at the tumor site. This increase potentially indicates that the treatment was not effective. However, in 25% of cases (one in four people), this signal enhancement is not due to ineffective treatment, but to inflammation (swelling/damage) and tissue death around the tumor. This is why when an increase in signal is detected, additional follow-up is essential. The standard additional follow-up has an accuracy of about 83%. This is an observational study on patients with brain metastatis comparing MRI alone or combined to PET-FET to improve accuracy of diagnosis of metastasis recurrence.
To identify potential adaptations of the managing cancer and living meaningfully (CALM) intervention that will be required for service members, Veterans, their beneficiaries, and civilian cancer metastasis to the brain (bMET) populations.
The goal of this study is to evaluate whether providing Pembrolizumab prolongs survival and preserves quality of life while minimizing side effects for patients with NSCLC with untreated asymptomatic brain metastasis.
Background: Exercise, or physical activity, is beneficial for all cancer survivors. Despite this knowledge, there is generally a gap between the evidence and practice. And this gap is widened with (a) underserved tumour groups in exercise oncology, such as neuro-oncology patients, or (b) underutilized timelines across the cancer treatment phases to deliver exercise oncology education or programming. Thus, our current work is building a hybrid implementation effectiveness study into the clinical care pathway across Alberta in neuro-oncology - ACE-Neuro. Objectives: The purpose of this study is to assess the impact of an online, tailored exercise oncology program for neuro-oncology patients using a participant-oriented research (POR) approach as well as both quantitative and qualitative research methods. Specifically, the primary outcome of this study is to determine the feasibility of recruitment, referral, triage, adherence, and adverse events. The secondary outcome is to examine the preliminary effectiveness of the neuro-oncology exercise program on patient-reported outcomes and physical function. Methods: Neuro-oncology patients >18 years and able to consent in English will be referred to a study-based Rehabilitation Triage Clinic, where a Physician-Researcher will assess patients on their overall health and functional status, and next triage them to either ACE-Neuro, rehabilitation oncology, or cancer physiatry. Once referred to ACE-Neuro, participants will partake in a 12-week online exercise program, delivered by a Clinical Exercise Physiologist. Participants will complete online assessments of physical function, patient-reported outcomes, and objective physical activity at baseline (pre-program), 12-weeks (post-program completion), 6-months, and 12-months. The exercise program includes weekly one-on-one online exercise delivery, health coaching to support behaviour change, and access to an online group exercise session. Participants will also be invited to a post-program qualitative interview to get perspectives on their experiences participating in ACE-Neuro. Relevance: By working directly with patients, healthcare providers, and community partners, this implementation project will develop a framework that streamlines patient triage, and provides a tailored online exercise program for neuro-oncology patients, thereby advancing exercise oncology research and clinical practice.