View clinical trials related to Gliosis.
Filter by:In this clinical study, we proposed to perform [18F]BF3-BPA PET imaging in subjects with gliomas, to observe the binding ability and non-specific binding of the tracer to glioma lesions in vivo, and at the same time to evaluate the effectiveness of [18F]BF3-BPA in the diagnosis and differential diagnosis of glioma, and to evaluate the tolerability and safety of the tracer and the imaging method. The efficacy of [18F]BF3-BPA in the diagnosis and differential diagnosis of gliomas will be evaluated, as well as the tolerability and safety of this tracer and imaging method. This study will provide a new method for in vivo imaging of gliomas and provide a clear and intuitive imaging basis for clinical diagnosis, differential diagnosis and treatment.
The purpose of this study is to use magnetic resonance imaging (MRI) to evaluate the human hypothalamus for signs of inflammation in response to specific diets. This research may lead to a better understanding of how poor nutritional quality may lead to obesity through effects on regions of the brain known to regulate body weight.
This study is to evaluate the efficacy of a mobile app for monitoring the quality of life of patients but also on detection delay of side effects and/or complications linked to the therapeutic management. This allow to adapt their care more quickly, through a prospective randomized study. The impact of this connected monitoring of patients' anxiety will also be evaluated in this study as well as the time taken by the medical team to manage alerts generated by this application.
Refractory epilepsy, meaning epilepsy that no longer responds to medication, is a common neurosurgical indication in children. In such cases, surgery is the treatment of choice. Complete resection of affected brain tissue is associated with highest probability of seizure freedom. However, epileptogenic brain tissue is visually identical to normal brain tissue, complicating complete resection. Modern investigative methods are of limited use. An important subjective assessment during surgery is that affected brain tissue feels stiffer, however there is presently no way to determine this without committing to resecting the affected area. It is hypothesized that intra-operative use of a tonometer (Diaton) will identify abnormal brain tissue stiffness in affected brain relative to normal brain. This will help identify stiffer brain regions without having to resect them. The objective is to determine if intra-operative use of a tonometer to measure brain tissue stiffness will offer additional precision in identifying epileptogenic lesions. In participants with refractory epilepsy, various locations on the cerebral cortex will be identified using standard pre-operative investigations like magnetic resonance imagin (MRI) and positron emission tomography (PET). These are areas of presumed normal and abnormal brain where the tonometer will be used during surgery to measure brain tissue stiffness. Brain tissue stiffness measurements will then be compared with results of routine pre-operative and intra-operative tests. Such comparisons will help determine if and to what extent intra-operative brain tissue stiffness measurements correlate with other tests and help identify epileptogenic brain tissue. 24 participants have already undergone intra-operative brain tonometry. Results in these participants are encouraging: abnormally high brain tissue stiffness measurements have consistently been identified and significantly associated with abnormal brain tissue. If the tonometer adequately identifies epileptogenic brain tissue through brain tissue stiffness measurements, it is possible that resection of identified tissue could lead to better post-operative outcomes, lowering seizure recurrences and neurological deficits.
BEAM is a multi-site longitudinal cohort study of hypothalamic gliosis, central regulation of appetite and weight gain in children. Participants will be recruited from the community in the greater Seattle and greater Baltimore area. All participants will consent to enroll in the 24-month study during which they will complete 5 in-person study visits.
Patients and clinicians need better options to prevent the weight regain that almost universally follows a weight loss intervention. In lay terms, a new, higher "set point" seems to occur after people gain weight. Evidence from some research studies reinforces these observations, showing that processes of energy homeostasis vigorously defend the higher level of adiposity for years, if not permanently. Only bariatric surgery appears to "re-set" to a lower level of adiposity. No clear mechanism has been elucidated to date that explains these phenomena. The current proposal endeavors to address this crucial scientific gap by translating preclinical data into human studies testing novel mechanistic hypotheses. Prior studies in rodents show that a high-fat diet causes inflammation and a cellular response, known as gliosis, within hypothalamic regions regulating energy balance and glucose homeostasis. Evidence further suggests that gliosis might play a pathogenic role in obesity and type 2 diabetes mellitus (T2D) because its development precedes weight gain and impaired glucose homeostasis and its inhibition improves metabolic health. Importantly, gliosis is detectable in mice and humans by magnetic resonance imaging (MRI). Using MRI, the investigators discovered the first evidence of gliosis in obese humans and went on to show associations of gliosis with insulin resistance in humans, independent of the level of adiposity. New findings suggest that people with T2D have more extensive gliosis than is seen in nondiabetic obese subjects. Further findings reveal that gliosis improves, but is not completely reversed, 8 mo. after Roux-en-Y gastric bypass (RYGB) surgery in T2D patients. It remains unknown whether gliosis improves similarly when weight loss occurs by lifestyle change or if the efficacy and durability of weight loss via bariatric surgery is partially explained by its ability to reverse gliosis via an as yet unknown mechanism of action. We therefore propose three studies in humans to discover 1) if hypothalamic gliosis is reversed by a standard behavioral weight loss intervention, 2) if the extent of gliosis predicts successful weight loss during, or weight regain after, behavioral weight loss, and 3) the time course of improvement in gliosis after RYGB and the relation of its improvement to the short- and long-term efficacy of RYGB. Future research would define dietary, environmental, or other risk factors for the development of hypothalamic gliosis in humans. Achieving a better understanding of the role of the brain in obesity and its treatment could open new avenues for research, intervention, and prevention.