View clinical trials related to Brain Injuries, Traumatic.
Filter by:The PreTBI II study aims to investigate the diagnostic potential of prehospital S100B and GFAP measurements in prediction of need for neurosurgical observation and/or intervention in moderate TBI patients, to rule-in high-risk patients. Ultimately to select patients who will benefit from neuro surgical expertise in specialized departments and thereby possibly better patient outcome. Hopefully also minimize treatment delay, secure optimal resource consumption and streamline patient courses by predicting the presence of neurotrauma. Hypotheses: 1. A prehospital serum S100B level > 0,10 microgram/L and expectedly above a certain and currently unknown cut-off value indicates the need for neurosurgical observation and/or intervention in moderate TBI patients. 2. A prehospital serum GFAP level above a certain and currently unknown cut-off value can significantly predict a need for urgent neurosurgical observation and/or intervention in moderate TBI patients. 3. Biomarker dynamics between prehospital and in-hospital biomarker values of S100B and GFAP can significantly predict a need for urgent neurosurgical observation and/or intervention. 4. Biomarker dynamics between prehospital and in-hospital biomarker values of S100B and GFAP can significantly predict hospital course and outcome of patients with moderate TBI.
This study utilizes multimodal brain imaging to obtain quantitative biomarkers of brain injury and to improve understanding of the biological basis of brain pathology in adolescents with concussion. Adolescents with a concussion will undergo neuroimaging and neuropsychology assessments acutely and four months after injury.
This long-term goal of this project was to advance best practices in occupational therapy in conjunction with yoga. To address the long-term goal, this research team developed a pilot yoga intervention. The intervention was designed to focus on balance, balance confidence, body responsiveness, pain, physical ability and quality of life. Assessments were then chosen to address these areas pre and post yoga intervention. A manual and protocol were developed for the intervention and then the intervention was implemented with a group of individuals with chronic traumatic brain injury.
The purpose of this study is to determine the effectiveness of a multi-professional theoretically based family centered intervention, The Traumatic Brain Injury Family System Intervention (TBIFSI), for the family members and TBI patients in improving family dynamics and functioning. The intervention will be provided in collaboration with the municipal rehabilitation service. The intervention group will be compared with a control group receiving treatment as usual, defined as an individually tailored multidisciplinary approach, and the family members will attend one ongoing psycho-educational group session of 2.5 hour provided by Oslo University Hospital (OUH).
Head injury is a common and devastating condition that can affect people at any stage of their lives. The treatment of severe head injury takes place in intensive care where interventions are designed to protect the brain from further injury and provide the best environment for recovery. A number of different monitors are used after head injury, including a monitor called microdialysis, to measure how the brain is generating energy. Abnormalities in these monitors guide doctors to the right treatments when the brain is at risk of further injury. There are lots of ways that the brain can be injured further after head injury such as raised pressure in the skull from brain swelling, low oxygen levels and low glucose levels. In this study we aim to combine information from all of these monitors to figure out what the underlying problem is and choose the right intervention to treat the problem that is affecting the patient at the time and compare this with previous treatment protocols to see if it improved outcome. Aim: To establish and validate a protocol to treat abnormalities in a microdialysis measure called lactate/pyruvate ratio (LPR) that reflects how cells are generating energy, and compare it with patient cohorts not being monitored using the current protocol.
The purpose of this study is to evaluate the safety and efficacy of individualized, Biometrics-guided Magnetic e-Resonance Therapy (MeRT) treatment of Post-Traumatic Stress Disorder
This is a Phase 2 clinical trial designed to obtain data on relationships between potentially therapeutic doses of n-3 HUFA (highly unsaturated fatty acids) and their bioactive molecular derivatives, synaptamide, 17-hydroxy-DHA, and D-series resolvins, on clinical outcomes after TBI.
The investigators will longitudinally measure cerebrovascular reactivity (CVR) by functional near-infrared spectroscopy (fNIRS) in acute (≤3 days from injury), subacute, and chronic phases after TBI as a biomarker of TCVI as compared to healthy controls. CVR will be measured by fNIRS response to hypercapnia. The investigators hypothesize that CVR will be decreased after TBI and that these decreases will correlate with clinical outcomes. Furthermore, the investigators predict that administration of a vasodilatory medication (sildenafil) will augment CVR after TBI.
The goals of the project are to evaluate a noninvasive monitor of brain metabolism and blood flow in critically ill humans. If validated, such a reliable noninvasive brain blood flow and metabolism monitor, by allowing physiologic and pharmacologic decisions based on real-time brain physiology, potentially will become an important tool for clinicians in their efforts to prevent additional brain tissue death in patients admitted with stroke, brain hemorrhage and traumatic brain injury.
Despite improvements in management, mortality in severe traumatic brain injury (TBI) remains 25% and only 40% of patients survive without major handicap. Medical/surgical interventions aim to maintain adequate brain perfusion, which is critically dependent on cerebral perfusion pressure (CPP); calculated as the difference between mean arterial pressure (MAP) and intracranial pressure (ICP). Current guidelines aim for a CPP above 50 mmHg, based on population means. However, this 'one size fits all' approach is flawed, because the relation between CPP and brain perfusion varies between individuals. Further, this approach takes no account of autoregulation, a key protective mechanism that maintains cerebral perfusion despite CPP fluctuations. Autoregulation is variably preserved following TBI, and there are large between patient variances in the 'optimal' CPP (CPPopt) at which autoregulation operates best. Individual CPPopt can be retrieved automatically by plotting autoregulation data against the CPP over a certain time window. The investigators have shown that maintenance of CPP close to CPPopt is associated with improved outcomes. These data pose the hypothesis that optimisation of management in individuals may be achieved by using the zone of optimal autoregulation as a basis for defining individualised CPP targets. The investigators propose, together with collaborators in the CPPopt study group (Maastricht, Cambridge, Leuven and Aachen) to set up a pilot (multicenter) feasibility study to develop a protocol for a definitive outcome randomized controlled trial (RCT). This study aims to develop protocols for CPPopt guided critical care, and show that they maintain patients closer to their optimum perfusion levels than standard protocols which keep above a population CPP threshold of 60 mmHg. Hence, the main objective is to offer clinicians monitoring and therapy algorithms that achieve individualized optimal CPPopt targets and potentially improve TBI outcome.