Active clinical trials for "Brain Injuries"

The goal of this observational study is to learn about the impact of historic and current Traumatic Brain Injuries on a Marine Battalion. Its main objectives are: Establish individual mental and physical performance profile and brain health baseline in Infantry Marines Develop predictive models to identify early signs of mental and/or physical degradation that can help predict "red-line" behavioral events and degradation in brain health. Gather insights that will lead to developing personalized, evidence-based interventions to restore mental and physical performance. Increase warfighter self-knowledge and personal awareness to monitor and maximize performance. Participants will wear wear smart watches and analyte sensors to track their real time physiological and sleep measures and complete subjective and psychological measures in a custom research app.

Children with concussion may improve with intravenous fluids.

A non-blinded randomised controlled feasibility study of weighted blankets to help agitation and disturbed sleep after brain injury. This is a single centre study based in a community hospital in the UK. Outcomes centre on determining the feasibility and acceptability of the study taking place in an NHS setting.

to investigate the function of the autonomic nervous system in children with with post traumatic brain injury and children with cerebral palsy through an analysis of heart rate variability (HRV) occurring with walking performance.

The purpose of this study is to investigate changes in response to robotic gait training in individuals with a traumatic brain injury.

The purpose of this study is to evaluate the clinical performance of the i-STAT TBI test for the proposed intended use; to assist in determining the need for a CT scan in patients presenting with suspected mild traumatic brain injury who are 18 years of age or older. The secondary objective of this study is the collection of additional data and specimens from all study subjects that may support other purposes related to the understanding of TBI.

The Tbit™ System will detect S100B and GFAP concentrations with the blood specimen to produce and compare repeated measures from 3 blood samples from 3 fingersticks from one subject and one 1 venous whole blood sample will be collected from the same subject, on 3 different Tbit™ System by 3 different operators.

The purpose of this study is to develop a highly portable, ruggedized diagnostic tool for concussion, EyeBOX Lens (EBLens), that can be utilized in deployed field and far-forward settings. The EBLens will be based on a concussion diagnostic algorithm from the FDA cleared EyeBOX device, developed by Oculogica, and eye-tracking data collected from a wearable set of eye-tracking glasses, developed by Adhawk Microsystems. Once the EBLens is prototyped, an algorithm for diagnosing concussion will be developed that is specifically appropriate for the EBLens via a case-control clinical study comparing 100 concussed to 100 non-concussed subjects (Phase I). Participants, age 18-35 years, will be recruited from the KACH research team and affiliated providers and clinical sites. Concussed individuals will be assessed within 72 hours of concussion. Demographics, basic medical history, symptom severity, a visio-vestibular exam and the EBLens scan will be collected on both injured cases and uninjured controls at a single time point. The algorithm and the EBLens will be validated in a subsequent, prospective cohort validation study (Phase II) designed for FDA submission. The correlation of the EBLens output with resolution of symptoms will also be observed in longitudinal follow-up of concussed participants in the validation study. The participant population for this study will be cadets recruited from the USMA and young athletes recruited from affiliated sites during baseline concussion testing. Participants will be assessed at baseline at the start of their academic year or sports season. Those participants who experience a concussive injury will be assessed again at three time points; 1) within 72 hours of injury, 2) weekly until and at the time of initiation of a graded return to activity protocol, and 3) upon clearance for unrestricted RTP/RTD.

When fever is present in patients with stroke, traumatic brain injury (TBI), or brain hemorrhage, it has been associated with worse outcomes including larger areas of tissue death, increased length of stay, worse degree of coma, lower ability to function, and higher mortality. Both adult and pediatric TBI national guidelines state that maintenance of normal body temperature should be a standard of care. However, no further standards or options are presented to specifically guide practice. The current ischemic stroke guidelines state that fever should be treated with fever-reducing agents and offer "cooling devices" as an option but do not provide specifics to guide practice. Over 50% of patients in the Neurosurgical Intensive Care Unit (ICU) at Harborview Medical Center develop fever during the course of their stay. With elevated temperatures the body consumes more oxygen than if the temperature was normal, causing less oxygen to be available to the brain. This may lead to injury of the brain cells and a diminished capacity for healing. Thus, temperature management in neurologically vulnerable patients is both a prevalent and problematic challenge. Based on this information the goal of the present proposal is to evaluate if 1) A standardized, step-wise approach to temperature management using a Normothermia Protocol is successful in achieving and maintaining normal temperature in Neurosurgical ICU patients; and 2) If maintenance of normal temperature will be associated with fewer episodes of diminished responsiveness in their neurological exams as evidenced by a measure of depth of coma, as measured by the Glasgow Coma Score (GCS) compared to a control group treated according to usual care.

Studies in patients with disorders of consciousness (DOC) after severe brain injury implicate dysfunction of the anterior forebrain mesocircuit dysfunction a key underlying mechanism. The anterior forebrain metabolism in DOC is markedly downregulated across brain regions underpinning highly elaborated cognitive behaviors demonstrating a collapse of the level of synaptic background activity required for consistent goal-directed behavior and arousal regulation. Since dopamine levels are one of the primary controllers of the level of synaptic background activity within these forebrain structures and in regulating excitatory glutamatergic homeostasis, the investigators propose to investigate the specific contribution of presynaptic dopamine function in glutamatergic neurotransmission in posttraumatic DOC. The aim of the present study is to measure metabotropic glutamate receptors 5 occupancy in the main gutamatergic structures of the brain using (3-[18F]fluoro-5-(2-pyridinylethynyl)benzonitrile)-positron emission tomography ( [18F]FPEB-PET) at rest and following a short pharmacological challenge with amantadine, an N-methyl-D-aspartate receptor (NMDA-R) antagonist, following L-DOPA, and amantadine + L-DOPA. Using this novel technique in DOC the investigators will characterize the relevance of a presynaptic deficiency to synthesize and/or release dopamine in the final regulation of excitatory interneurons of the anterior forebrain mesocircuit. It is unknown whether glutamatergic neurotransmission is affected across the population of subjects with DOC and, if this condition is secondary to a presynaptic dopaminergic failure of the anterior forebrain mesocircuit (i.e., down-regulation). Since the investigators previously identified the existence of a presynaptic dopaminergic deficit in these subjects due to a failure in the biosynthesis of dopamine, the investigators will evaluate if by providing the main biological substrate of the biosynthesis process (i.e., L-DOPA) the glutamatergic system regains homeostasis. The investigators therefore propose to investigate patients with posttraumatic DOC using [18F]FPEB-PET at rest and following short pharmacological challenges aimed at increasing glutamate and dopamine release.