View clinical trials related to Brain Injuries, Traumatic.
Filter by:Background: - Studies have shown that some people develop post-traumatic stress disorder (PTSD) after being exposed to the trauma of military combat. They may have repeated thoughts, images, and dreams of the trauma; feel detached from others; have difficulty sleeping and concentrating; or be easily startled. Some studies have also shown that after having a blow or blast to the head, some people may develop post-concussive syndrome (PCS), which may include symptoms such as headaches, difficulty concentrating, and feeling moody or irritable. Researchers are interested in using magnetic resonance imaging (MRI) to study combat veterans from Operation Iraqi Freedom or Operation Enduring Freedom in order to evaluate possible changes in the brain that may be attributed to PTSD or PCS. Objectives: - To evaluate changes in brain function in recent combat veterans that may be related to post-traumatic stress disorder or post-concussive syndrome. Eligibility: - Combat veterans of Operation Iraqi Freedom/Operation Enduring Freedom who are enrolled in Walter Reed Army Medical Center protocol 351030, have returned within the last 6 weeks from a deployment in Iraq or Afghanistan that lasted at least 3 months, and are able to have magnetic resonance imaging scans. Design: - This study involves between 1 and 4 outpatient visits to the NIH Clinical Center over the course of 1 year. The second, third, and fourth visits will occur 3, 6, and 12 months after the first visit. - At the first visit, participants will have a baseline MRI scan, followed by a functional MRI (fMRI) scan to see what parts of the brain are used while performing simple tasks and responding to images. Participants will complete questionnaires after the scan to report on their experiences during the MRI scan. - For the remaining three study visits, participants will have further MRI and fMRI scans and will complete additional questionnaires. Participation is complete after the 12-month study visit, or following a diagnosis of PTSD, major depression, or PCS at any time during the study. - No treatment will be provided as part of this protocol.
The purpose of this study is to assess if putative brain injury biomarkers have utility as blood-based traumatic brain injury (TBI) diagnostic and monitoring tools. This will be accomplished by examining the relationships between potential serum-based TBI biomarkers and clinical measures of injury severity, occurrence of complications, and outcome, in subjects with mild or moderate TBI. The assay will be evaluated in a sample population of subjects over the age of 18 who have been referred to the health care provider for closed head injury evaluation.
Background: - Many people who have traumatic brain injury (TBI) have low levels of physical fitness. Low physical fitness causes severe fatigue that reduces the ability to perform routine daily activities, and may also cause increased depression, anxiety, or sadness. Aerobic exercise, such as treadmill walking or running, improves physical fitness in most people and may also decrease fatigue and improve mood. However, more information is needed to determine if exercise improves these conditions in people who have TBI. Objectives: - To examine the effect of an aerobic treadmill walking exercise program on physical fitness, fatigue, and mood in people with TBI. Eligibility: - Individuals between 21 and 45 years of age who had a nonpenetrating traumatic brain injury at least 6 months before participating; able to understand oral and written English language, give informed consent and sign a consent form; are physically inactive (including activities related to both job and recreation); and are able to stand and walk on a treadmill safely without help. Design: - This study requires 4 testing visits and 36 exercise visits over 14 weeks. - The first and third testing visits will last about 4 hours and the second and final testing visits will take about 2 hours. - Testing visits will consist of a medical history and physical examination, completion of questionnaires (about fatigue, daily physical activity, sleep quality, mood, and overall quality of life), tests of thinking and a treadmill exercise test. - Participants will have treadmill exercise training 3 days per week for 12 weeks. Each session includes a check-in, warm-up, treadmill walking at the training heart rate, and cool-down. Thirty-two of the sessions will last for about 1 hour, and four of the sessions will include questionnaires to fill out and will last about one-and-a-half hours. - After completing the exercise training program, participants will have a final testing visit to complete the questionnaires (about fatigue, daily physical activity, sleep quality, mood, and overall quality of life), tests of thinking and a treadmill exercise test....
The investigators hypothesize that individual differences exist in resting-state cortical attention, control, sensory, and emotion networks prior to noise exposure and these differences predispose some to the development of bothersome tinnitus. Furthermore, the investigators hypothesize that these changes in functional connectivity of these vulnerable systems after noise exposure are responsible for tinnitus. The proposed study will use a case-control cohort study design. Cases will be those soldiers who develop tinnitus and controls will be those who do not. This will be the first prospective study of tinnitus and will provide important information about the neurobiology of tinnitus. If a cortical neural network etiology for bothersome tinnitus is confirmed, it will be an astounding, powerful, paradigm shifting model for the diagnosis, prevention and, most importantly, treatment of tinnitus. Furthermore, if a battery of neurocognitive tests can identify soldiers at risk for the development of tinnitus then appropriate primary prevention strategies can be introduced. There are three Specific Aims to this project. Specific Aim 1. To determine if soldiers who develop tinnitus display pre-deployment differences in a set of physical, functional, cognitive, vulnerability, perpetuating factors, pre-deployment neurocognitive scores, or neuroimaging features compared to soldiers who do not develop tinnitus ("control group"). Specific Aim 2. To determine if particular scores on neurocognitive tests or neuroimaging features of functional/structural connectivity networks are associated with the development of tinnitus. Specific Aim 3. To identify a set of pre-deployment physical, functional, cognitive, vulnerability, and perpetuating factors, neurocognitive responses, and neuroimaging features that are associated with the development of tinnitus. The investigators plan to recruit 200 soldiers, between the ages of 18 and 30 years who do not have hearing loss or tinnitus and have never been deployed to military theater. The soldier participants will undergo a variety of tests before and after deployment, which will include a hearing test, neurocognitive tests (i.e., brain function tests), and a variety of novel radiologic imaging studies of the brain. One of these novel radiologic imaging studies is functional connectivity Magnetic Resonance Imaging, a proven methodology that monitors changes in brain activity and connections based on blood flow between different brain areas and levels of consumption of oxygen. This information is used to describe the condition of important neural networks responsible for such things as attention, mood, sensation, vision, hearing, and introspection or self-contemplation.
Background: - The Center for Neuroscience and Regenerative Medicine is working to improve physicians' understanding of brain injury. More information is needed on traumatic brain injury (TBI), especially how well a person recovers from TBI and how the brain changes over time in people with TBI. To conduct this research, the center is sponsoring a number of research studies on TBI and is interested in evaluating individuals with TBI or post-concussive syndrome to determine if they might be eligible for future studies. Objectives: - To develop a pool of individuals with traumatic brain injury and post-concussive syndrome for future research studies. Eligibility: - Individuals at least 18 years of age who have symptoms of or have been diagnosed with traumatic brain injury or post-concussive syndrome and are willing to participate in future studies. Design: - Participants will be screened with an initial telephone interview, and will be asked to come to the National Institutes of Health for an in-person screening visit. - At the screening visit, participants will provide a medical history, have a physical examination and complete a study questionnaire on their TBI and its symptoms, including how the injury occurred, when it occurred, and any previous brain-related injuries. - Subjects may also return for a second visit at the NIH CC if eligible. - Each visit may involve blood samples, an MRI scan, and a series of tests to evaluate brain function. - Participants will also provide contact information to enable researchers to contact them for future studies.
This study is being conducted to understand whether training in tasks that require perceiving and thinking about things, or cognition, can improve memory in veterans who have been exposed to a blast explosion and have TBI and PTSD. A primary goal of the study is to determine whether it is feasible for veterans who don't live close to a VA to perform this cognitive training at home.
Traumatic brain injury has a high morbidity and mortality in both civilian and military populations. Blast and other mechanisms of traumatic brain injury damage the brain by causing neurons to disconnect and atrophy. Such traumatic axonal injury can lead to persistently vegetative and minimally conscious states, for which extremely limited treatment options exist, including physical, occupational, speech and cognitive therapies. More than 50,000 patients have received vagus nerve stimulation for epilepsy and depression. In addition to decreased seizure frequency and severity, patients report enhanced mood, reduced daytime sleepiness independent of seizure control, increased slow wave sleep, and improved cognition, memory, and quality of life. The purpose of this study is to demonstrate objective improvement in clinical outcome by placement of a vagus nerve stimulator in patients who are recovering from severe traumatic brain injury. Our hypothesis is that stimulation of the vagus nerve results in increased cerebral blood flow and metabolism in the forebrain, thalamus and reticular formation, which promotes arousal and improved consciousness, thereby improving outcome after traumatic brain injury resulting in minimally conscious or persistent vegetative states. If this study demonstrates that vagus nerve stimulation can safely and positively impact outcome, then a larger randomized prospective crossover trial will be proposed. The investigators will achieve this objective by evaluating whether vagus nerve stimulation impacts clinical recovery from minimally conscious or persistent vegetative states caused by traumatic brain injury as assessed by the FIMâ„¢ instrument and Functional Assessment Measure (FIM+FAM) as well as the JFK Coma Recovery Scale Score. The investigators will also evaluate whether vagus nerve stimulation alters resting and activational functional MRI. Twelve patients will be enrolled in this initial crossover pilot study. These patients will have sustained a severe traumatic brain injury (Disability Rating Scale score of 22 to 29) more than twelve months from starting the study, and have no other concurrent active severe medical problems. Baseline EEG and magnetic resonance imaging (MRI) will be performed prior to left vagus nerve stimulation implantation. Patients will be randomized to alternating three month periods with the device on or off. Outcomes will be assessed at three month intervals with the FIMâ„¢ instrument and Functional Assessment Measure (FIM+FAM) and JFK Coma Recovery Scale by a neuropsychologist blinded to the status of the device. Outcomes will also be assessed using quantitative eye movement tracking and functional magnetic resonance imaging. Patients will cross over every 3 months and be followed for at least 18 months.
The purpose of this research study is to assess the long term safety of Dysport® in hemiparetic subjects with lower limb spasticity due to stroke or traumatic brain injury over repeated treatment cycles.
Annual incidence of severe traumatic brain injuries (TBI) varies from 180 to 300 out of 100.000. Mortality or severe sequelae risk is increased 8 fold after a TBI. Studies in adults showed an ante-hypophyseal deficit in 28 to 68 % of patients with a TBI. The most common deficit is Growth Hormone Deficit (GHD); followed by gonadotropic and corticotropic (AdrenoCorticoTropic Hormone (ACTH)) insufficiencies. Thyrotropic deficits (Thyroid-Stimulating Hormone (TSH)) are less frequent. From a pathophysiological point of view, the lesional mechanism responsible for hypopituitarisms would be a damage of hypophyseal vessels or hypothalamic-pituitary vessels. The frequency of pituitary deficits and the potential beneficial effects of replacement therapy on quality of life, tiredness, loss of energy and productivity, justify the systematic detection of the deficits in patients with moderate to severe TBI. Study hypotheses : At the present time, the lack of data in children does not give us the opportunity to affirm that one part of the symptoms showed by children with post-TBI neuropsychological sequelae, are linked to pituitary deficiency and that they can be improved with a replacement therapy. Firstly, it is essential to better understand the natural history of post-TBI pituitary deficiencies, studying the connexion between observed deficiencies in acute and late phase of sequelae.
The goals of this study are to identify outcome indicators of optimal care for brain injury patients, including pre-hospital care, prompt delivery to neurosurgical care and access to early rehabilitation services. Nova Scotia's centralized Neurosurgical services and integrated provincial Emergency Health Services provide a rich opportunity to construct a cohesive, integrated data management system. This system will allow us to answer important research questions related to the outcomes, care and prevention of brain trauma. Retrospective data collection The retrospective arm of the BTO study has created full data sets and care pathways from multiple sources covering the continuum of brain trauma care. Investigators continue to analyze this large amount of data and prepare it for publication. Prospective data Collection Patients with a major head injury (initial GCS 3-12), have been considered for enrollment in the BTO study.The prospective arm of the BTO study has 52 patients enrolled. Screening and Enrollment was complete on June 30, 2007. These patients are participating in long term follow up at 6, 12 and 24 months post injury for assessment of qualitative and quantitative outcomes. Completion of patient follow up will be in June 2009.