Active clinical trials for "Brain Injuries, Traumatic"

This study (Part 3) is designed to build a database including EEG, neurocognitive performance, clinical symptoms, history and other relevant data, which will be used to derive a multimodal EEG based algorithm for the identification of concussion and tracking of recovery.

Using the Blink Reflexometer, athletes are scanned if they are potentially thought to have a concussion during a game or practice.

We assume that an early iterative automatic CT scan analysis (D0, D1 and D3) by different AI approaches will allow an early differentiation of the tissues evolution after TBI. Our objective is to couple theses scan profiles to a neurological evolution, measured by therapeutic intensity.

The purpose of this study is to examine the reliability and validity of the rating of perceived exertion scale in children post severe traumatic brain injury during treadmill exercise.

This study will examine resting dopamine function as well as dopamine response in the brain as it interacts with medicines normally prescribed to subacute Traumatic Brain Injury (TBI) patients.

Currently, there is no direct, reliable, bed-side, and non-invasive method for assessing changes in brain activity associated with concussion. Event Related Potentials (ERPs), which are temporal reflections of the neural mass electrical activity of cells in specific regions of the brain that occur in response to stimuli, may offer such a method, as they provide both a noninvasive and portable measure of brain function. The ERPs provide excellent temporal information, but spatial resolution for ERPs has traditionally been limited. However, by using high-density electroencephalograph (EEG) recording spatial resolution for ERPs is improved significantly. The paradigm for the current study will combine neurophysiological knowledge with mathematical signal processing and pattern recognition methods (BNA™) to temporally and spatially map brain function, connectivity and synchronization. The proposed study will provide additional evidence for the utility and contribution of the BNA™ test (reflecting temporal and spatial changes in brain activity as well as brain functional connectivity associated with concussion) in concussion management.

The purpose of this pilot project is to determine whether using inertial sensors placed on the waist during routine clinical balance testing (i.e. Balance Error Scoring System) (BESS), will be a more immediate, objective, reliable and sensitive way to measure and quantify balance deficits in individuals with mild Traumatic Brain Injury (mTBI). The investigators are also trying to observe if the sensors can be used to detect balance recovery after a mTBI. The investigators hypothesis is that collegiate atheltes with mTBI injury will have different recovery periods between their cognitive testing(IMPACT) and their balance measures.

The aims of this study explore the relationships between cerebral vasospasm, apolipoprotein-E (apo-E) genotype, physiologic symptoms, and neurocognitive outcomes that may either intensify or ameliorate secondary injury, for children with a traumatic brain injury. Exploring the apo-E genotype will help us know if injury response is altered in certain children and will aid in developing interventional approaches.

The goal of this project is to determine if it is possible to assess Cerebrovascular Reactivity (CVR) to hypercapnia with functional Near Infrared Spectroscopy (fNIRS). Such a method would be particularly helpful in traumatic brain injury (TBI), where objective measures are needed, and would greatly expand the capacity to make such assessments in standard clinical practice.

The current study will evaluate the initial reliability and validity of a new instrument, the INTRuST Structured Assessment for Evaluation of TBI (SAFE-TBI), in three samples of Operation Enduring Freedom/Operation Iraqi Freedom/Operation New Dawn (OEF/OIF/OND) veterans. The SAFE-TBI is a relatively brief measure developed by INTRuST consortium investigators and designed to be given by a trained administrator. It allows for a determination of the level of evidence for exposure to a mild traumatic brain injury (TBI) using the following categories: Strong, Moderate, Weak, or No Evidence of mild TBI. The first objective is to determine the reliability (both test-retest and inter-rater) in a sample of 100 veterans recently returned from deployment at Joint Base Lewis-McChord and Fort Bragg (Cohort 1), who have screened positive for TBI on the Post-Deployment Health Assessment. The second objective is to determine the concordance between the SAFE-TBI and the VA TBI Screen in 100 OEF/OIF/OND veterans within the Northern New England VA Research Consortium (Cohort 2). The third objective, to be carried out in a sample of 200 Walter Reed National Military Medical Center (WRNMMC) and Fort Belvoir Community Hospital OEF/OIF/OND patients (Cohort 3), is to determine the sensitivity and specificity of the SAFE-TBI using the INTRuST study "Brain Indices of Risk for Posttraumatic Stress Disorder after Mild Traumatic Brain Injury" initial evaluation as the "gold standard" for TBI assessment.