View clinical trials related to Brain Tumor.
Filter by:The primary aims of this mixed-methods trial are to test the feasibility and acceptability of the novel Cognitive Strategies, Mindfulness, and Rehabilitation Therapy (C-SMART) delivered via telehealth to patients with primary brain tumors and mild neurocognitive disorder (mNCD).
Plastic particles are a ubiquitous pollutant in the living environment and food chain, so far, plenty of studies have reported the internal exposure of microplastics and nanoplastics in human tissues and enclosed body fluids. Neurosurgery is the only department that can open the skull. In addition to blood and cerebrospinal fluid, there are brain tissue and tumors in the presence of lesions. Whether any of these microplastics and nanoplastics are present remains a mystery. This prospective observational study will harvest biological samples of neurosurgery patients. The objective of this research is to be able to detect microplastics and nanoplastics on blood and operation samples of neurosurgery patients.
The objective of this study is to estimate the feasibility and acceptability of cognitive training in the virtual reality setting with children undergoing radiotherapy for brain tumors. To achieve this goal, the investigators plan to study children undergoing radiotherapy for brain tumors randomly assigned to cognitive training administered via an iPad or virtual reality. Both groups will also participate in cognitive testing and exams using functional near infrared spectroscopy (fNIRS) pre- and post-intervention. The questions to be investigated are: 1. Will cognitive training via virtual reality be feasible and acceptable for children undergoing radiotherapy for brain tumors as indicated by participation rates, adherence and frequency of side effects? 2. Will cognitive training via virtual reality provide neurocognitive benefits? 3. Will there be predictable changes in brain activity as measured by neuroimaging? Findings from this study will be used to develop a larger, definitive trial with direct potential to improve cognitive outcomes for children treated for cancer using a safe and effective alternative to desktop- or laptop-based computerized cognitive interventions with great promise for improving quality of life.
The research aims to develop a novel pathological technology, including rapid whole-mount tissue H&E & IHC staining protocol and high-resolution nonlinear optical microscopy imaging system, to intraoperatively assess brain tumor grade, types and other biological parameters.
1. Eligible participants were assessed prior to anesthesia. After the patient is admitted to the hospital, the subject's consent form is explained, and the consent form must be signed before the operation. 2. This is a two-arm, parallel-group randomized clinical trial.In the preoperative waiting area, the patients are randomly assigned and divided into two groups according to the allocation sequence table (corresponding to 1:1 randomization) generated by the computer. The propofol group was both induced and maintained at an effect-site concentration (Ce) of 2.0-4.0 mcg/mL by a target-controlled infusion (TCI) system. The sevoflurane group was maintained via sevoflurane vaporizer between 1% and 3% (target minimum alveolar concentration of 0.7-1.3). During the operation, the dose of anesthetic drugs (propofol/fentanyl /remifentanil and sevoflurane/cisatracurium/rocuronium) are adjusted to maintain the mean arterial pressure and heartbeat fluctuations within 20% of the baseline value and Entropy (or BIS) value at 40-60in both groups. The following patient data were recorded, the type of anesthesia, sex, age at the time of surgery, preoperative Karnofsky performance status (KPS) score and functional capacity, the postoperative complications within 30 days (according Clavien-Dindo classification), ASA physical status scores, tumor marker ,tumor size, intraoperative blood loss/transfusion, duration of surgery, duration of anesthesia, total opioid (remifentanil/fentanyl) use, postoperative radiation therapy, postoperative chemotherapy, postoperative concurrent chemoradiotherapy, the presence of disease progression, and 6-month, 1-year, 3-year and 5-year overall survival and Karnofsky performance status score were recorded.
The research aims to establish a big database of multiple kinds of brain tissues and prove the relevance of human brain tissue models and hiPSCs-derived organoid models.
To engineer immune organoids from pediatric patient tissues using induced-pluripotent stem cells (iPSC)
The goal of the present pilot single-cohort feasibility trial is to investigate the feasibility and understand potential mechanisms of efficacy for Neuromodulation-Induced Cortical Prehabilitation (NICP) in adults with brain tumours and eligible for neurosurgery. The main questions it aims to answer are: - is the intervention feasible, in terms of adherence, retention, safety and patient's satisfaction; - what are the mechanisms of neuroplasticity primed by NICP Participants will undergo a prehabilitation protocol, consisting of daily sessions (total: 10-20 sessions) structured as follows: - Intervention 1: non-invasive neuromodulation (TMS/tDCS). - Intervention 2: motor and/or cognitive training, during or immediately after non-invasive neuromodulation, for about 60 minutes. The timeline is structured as follows: T1: baseline (before NICP) T2-T3: NICP period T4: after NICP T5: surgery T6: after surgery Clinical, neuroimaging and neurophysiology assessments will be performed before NICP (T1), after NICP (T4), and after neurosurgery (T6). Feasibility outcomes will be determined during NICP protocol (T2-T3). The objective of the proposed intervention is to progressively reduce the functional relevance of eloquent areas, which are healthy brain areas close with the tumour and thus exposed to the risk of being lesioned during surgery. In fact, previous studies have shown that temporary inhibition of eloquent areas (by neuromodulation) coupled with intensive motor/cognitive training promoted the activation of alternative brain resources, with a shift of functional activity from eloquent areas to areas functionally related, but anatomically distant from the tumour. By moving the activation of key motor/cognitive functions away from the tumour, the risk of postoperative functional sequelae will be reduced; which in turn will falicitate a more radical tumour excision by the neurosurgeon.
For the last decades, many aspects of human life have been altered by digital technology. For health care, this have opened a possibility for patients who have difficulties travelling a long distance to a hospital to meet with their health care providers over different digital platforms. With an increased digital literacy, and an aging population often living in the countryside, far from hospitals or other health care settings, an increasing need for digitalization of meetings between patients and health care personnel is inevitable. However, neuropsychological assessment is one sort of health care not possible to directly transfer into digital form. These evaluations are most often performed with well validated tests, only to be used in a paper-pencil form with a specially trained psychologist during physical meetings. The aim of this project is to investigate whether a newly developed digital neuropsychological test battery can be used to perform remote assessments of cognitive function in patients with neurological injuries and impairments. To this date, there are no such test batteries available in the Swedish language. Mindmore (www.mindmore.com) is a test system developed in Sweden, performing neuropsychological tests on a tablet, but still with the psychologist present in the room. This system is now evolving into offering the possibility for the patient to perform the test in their own home, using their own computer or tablet. The aim of the present research project is to validate this latter system (Mindmore Distance), using the following research questions: 1. Are the tests in Mindmore Distance equivalent to traditional neuropsychological tests in patients with traumatic brain injury, stroke, multiple sclerosis, Parkinson's Disease, epilepsy, and brain tumor? 2. Can the results from Mindmore Distance be transferred into neuropsychological profiles that can be used in diagnostics for specific patient groups? 3. How do the patients experience undergoing a neuropsychological evaluation on their own compared to traditional neuropsychological assessment in a physical meeting with a psychologist?
The present project aims to investigate the financial capacity in patients diagnosed with Parkinson's Disease or parkinsonism, brain tumor (glioma or meningioma) and cerebrovascular lesion (stroke), in order to evaluate the presence and degree of impairment, and the role of some factors as potential predictors of financial incapacity. The term 'financial capacity' means both operations relating, for example, to asset management or investing money, and activities of daily life such as shopping or using small sums of money; these activities are mediated by different cognitive functions, from numerical and arithmetic skills to decision making. Financial capacity is, in fact, an instrumental activity of daily life (i.e. Instrumental Activity Of Daily Living, I-ADL) whose impairment negatively affects the functional autonomy of the individual, so as to be subject to legal protection. To assess financial capacity, the Numerical Activities of Daily Living - Financial (NADL-F; Arcara et al., 2017) will be administered, a battery of tests aimed at investigating both financial performance and financial competence according to the most recent neuropsychological models proposed in the literature.