View clinical trials related to Traumatic Brain Injury.
Filter by:The primary purpose of this project is to determine the effect of morning bright light therapy (MBLT) on sleep in Veterans with traumatic brain injury (TBI). Secondarily, the project aims to identify blood-based brain biomarkers (BBBM) associated with sleep in Veterans. Specific Aim 1. Determine the effect of MBLT on sleep quality in Veterans (primary outcome). Specific Aim 2. Determine the effect of MBLT on downstream effectors of improved sleep, including cognition, mood, and quality of life measures in Veterans (exploratory outcomes). Specific Aim 3. Determine the effect of MBLT on levels of specific BBBM related to sleep, and whether changes in specific BBBM predict response to MBLT (secondary outcome). This study can now be completed 100% remotely.
This will be a multistate, multicenter clinical study to determine the efficacy and safety of medical cannabis for a wide variety of chronic medical conditions.
Introduction: Patients suffering a time-critical medical condition require rapid prehospital assessment and treatment and most often quick transportation to definitive care. This can be decisive for patient outcome. In order to minimize time from assessment to treatment, thus lowering mortality and morbidity, it is important to have a well-coordinated chain of care. The efficient use of Ground Emergency Medical Services (GEMS) and Helicopter Emergency Medical Services (HEMS) is essential in such a chain of care. Objectives: The aim is to describe differences in mortality, morbidity, assessment and treatment of two time-critical conditions, traumatic brain injury (TBI) and acute myocardial infarction (MI), in patients assessed by GEMS and HEMS respectively. Method: The project consists of a descriptive observational study and comparative cohort study. Inclusion criteria are patients considered to be suffering from TBI and acute MI, which are treated by GEMS or HEMS in the regions of Uppsala, Jämtland/Härjedalen, Dalarna and Värmland. Clinical significance: The results expect to be the basis for further studies aiming to optimize the utilization of GEMS and HEMS.
Whilst deep vein thrombosis (DVT) is common following traumatic brain injury (TBI), optimal timing and safety of pharmacological prophylaxis is uncertain. Paradoxically the harm associated with the occurrence of is also unclear. This study is an observational pilot that aims to define the incidence of proximal DVT in patients with moderate to severe TBI. It seeks prospectively to determine if there is an association between DVT and outcome. It also seeks to explore possible associations between the occurrence of DVT and the incidence of lung injury and/or ventilator associated pneumonia.
Preliminary clinical evidence suggests that Service Members with symptoms of post-traumatic stress disorder (PTSD) or Post Traumatic Stress (PTS) who participate in the Service Dog Training Program (SDTP) report improved physical and psychological outcomes, including those with overlapping symptoms associated with traumatic brain injury (TBI) and post-concussion symptoms (PCS). This study intends to examine the psychological, social, and biological effects of learning how to train a future service dog combined with standard of care for individuals with symptoms of Post-Traumatic Stress (PTS), including those with overlapping TBI and persistent Post-Concussive Symptoms (PCS). Biological, social, and behavioral measures will be collected throughout study participation.
Traumatic brain injury (TBI) is a leading cause of death among trauma patients accounting for one-third of all trauma mortalities. Patients who survive the initial trauma are liable to secondary insults from the ensuing inflammatory state in the brain. Treatment goals are aimed at reducing secondary injury. Maintaining adequate brain perfusion, limiting cerebral edema, and optimizing oxygen delivery are part of established treatment protocols. Numerous therapeutics have been evaluated as potential treatment for TBI with very limited success and there is no medication that alters survival. Various novel therapeutic options have been investigated to prevent the secondary brain injury. Remote Ischemic Conditioning (RIC) is one of these therapies. RIC involves decreasing blood flow to a normal tissue usually the arm by inflating the blood pressure cuff 30mmHg over the systolic blood pressure. The decreased blood flow or ischemia is maintained for 5 minutes followed by releasing the pressure and re-perfusion of the arm. This cycle is usually repeated 4 times. RIC has been shown to improve outcomes in patients with heart attacks, strokes, elective neurosurgeries. A prospective observational study and a randomized clinical trial has shown the protective effect of RIC in TBI patients. Additionally, multiple studies in animals have shown that RIC is neuroprotective after TBI. RIC is non-invasive and harmless except for a little discomfort in the arm. The aim of the study is to evaluate the impact of RIC on long term outcomes in patients with TBI.
EEG signals have been collected and studied since the early 1990's as a way of assessing brain function at a gross level. As early as the 1930's a derivative of the raw EEG signal - event-related potentials (ERPs) - have been computed. The current research is primarily focused on three ERP components: the N100, P300 and N400. Each of the three ERPs have been studied in the academic laboratory for multiple decades. Through this research, a strong understanding has been developed regarding what can affect these components (e.g. task set, emotional state, etc.). However, these signals within various pediatric populations (e.g., those with persistent mTBI symptoms or multiple concussions) are not well characterized. Being able to safely and effectively employ the NeuroCatchâ„¢ Platform in a post-concussive pediatric cohort could provide researchers with the potential to elucidate the persistence of objective measures of impairment, patterns of recovery, and chronicity of problems due to mTBI in children. Secondly, understanding the degree to which these neurophysiological components fluctuate over time is crucial to the understanding of brain functioning. However, for this type of technology to be useful in quantifying brain health in this population,the degree to which a post-concussive pediatric brain naturally fluctuates in its processing capability must be quantified. NeuroCatchâ„¢ Platform has the ability to measure changes in several domains of brain function. These cognitive processes are foundational blocks for some of the highest cognitive processes: information integration and executive functioning.
Traumatic brain injury (TBI) typically provokes secondary injury mechanisms, including the dynamic interplay between the ischemic, inflammatory, and cytotoxic processes. Moreover, such an impact induces a substantial level of cell death and results in the degeneration of the dendrites, thereby leading to persistent motor, sensory, and cognitive dysfunction. Previous studies have shown that the adult-born immature granule neurons in the dentate gyrus are the most susceptible of all the cell types in the hippocampus to damage following a moderate TBI due to a controlled cortical impact (CCI) device. Currently, there is no efficient approach available for avoiding immature neuron death or degeneration following TBI. Hence, this study aimed to assess the neuro-regenerative properties of co-ultramicronized PEALut (Glialia®), which is composed of palmitoylethanolamide (PEA) and the flavonoid luteolin (Lut), in an in vivo model of TBI, as well as in patients affected by TBI.
Background and Purpose: Posttraumatic stress disorder (PTSD) and mild traumatic brain injury (mTBI) are persistent and frequently comorbid complications of recent combat. There is no proven treatment for mTBI, and standard treatments for PTSD frequently achieve only transient, modest impact. Motion-assisted, Multi-modular Memory Desensitization and Reconsolidation (3MDR) is a novel treatment for PTSD combining aspects of virtual reality exposure therapy (VRET) and Eye Movement Desensitization and Reprocessing (EMDR), within the Computer Assisted Rehabilitation Environment (CAREN). The added benefit of the eye movement (EM) component of EMDR is controversial; the purpose of this pilot study is therefore to: 1) obtain an initial estimate of the efficacy of 3MDR in service members with comorbid PTSD and mTBI, and 2) determine the impact of EM on treatment response. The investigators hypothesize that 3MDR will significantly improve symptom severity, both with and without EM. Population: Participants will be active or retired service members with a history of mTBI who meet criteria for probable PTSD on the PCL5. It is anticipated that participants will be recruited through the Center for Neuroscience and Regenerative Medicine (CNRM) Recruitment Core and the National Intrepid Center of Excellence (NICoE). Design type and procedures: This is a pilot, controlled clinical trial in which all 20 participants with comorbid PTSD and mTBI receive 10 sessions (3 preparatory, 6 3MDR treatment, and 1 conclusion), but will be randomized to either include EM (EM+) or not (EM-). In the preparatory sessions, the therapist will help each participant select 2 songs and 14 pictures to be used in their treatment sessions. The therapist will help the participant rate the pictures from least to most impactful. Each 3MDR treatment session will start by playing the first song, to bring them back to the time of their trauma. This will be done while the participant walks on the CAREN's embedded treadmill through the 3MDR virtual environment (VE) projected onto the system's curved screen. This is followed by a display of one of their pictures, a manifestation of their trauma, which they directly face and walk down a hallway toward, until the picture looms before them. The therapist, standing next to the participant along the treadmill's edge, will query the participant about what the picture means to them, how it makes them feel, etc., while the CAREN operator superimposes key words (said by the participant) over the picture, which the therapist later asks the participant to read aloud. Then, for ~60 seconds, the EM+ group will see a red ball "bounce" across the screen in front of the picture, and a number appears on the ball as it touches the screen's edge. The participant will be asked to recite each number aloud. This element is absent for EM- participants. All participants repeats these procedures for 5-7 pictures in each 3MDR treatment session; the pictures used will be agreed upon by therapist and participant, targeting more impactful pictures, whether repeats or new, in later sessions. The pictures are followed by playing the second song, chosen to bring the participant back to present day. The participant will walk at a comfortable pace throughout the session, with each session lasting typically ~60 minutes. The primary outcome measure will be change in PCL-5 score from pre- to post-intervention, with additional measures at 3 and 6 months.
Traumatic brain injury (TBI) is a major cause of disability in the Veteran population, often resulting in chronic pain and sleep disturbances, among other issues. Extensive rehabilitative efforts are usually required and often prevent return to the workforce and community. Disturbed sleep and excessive daytime sleepiness are among the most pervasive and enduring problems after TBI, which the investigators hypothesize is a significant contributor to these functional impairments and an impediment toward rehabilitation. Thus, this research aims to enhance sleep quality as a means to reduce pain and improve quality of life and functional outcome measures in Veterans with TBI. The investigators predict that the proposed intervention, morning bright light therapy, if found effective, will be cost-effective, rapidly deployable, and highly accepted by Veterans with TBI.