Mild Traumatic Brain Injury and Post-Traumatic Stress Disorder
Posttraumatic Stress DisorderTraumatic Brain InjuryBackground: - Some people who have a traumatic brain injury (TBI) recover completely. Others, however, develop post-traumatic stress disorder (PTSD), with anxiety and depression. Research suggests that levels of a brain chemical called GABA may differ in people with PTSD compared to those without PTSD. Researchers want to see if TBI can affect GABA in the brain and help develop PTSD. To look at the brain, researchers will use imaging studies with the chemical 11C-Flumazenil, which will help the scan show GABA levels in the brain. Objectives: - To study the relationship between PTSD and TBI. Eligibility: The subjects will be recruited from the Walter Reed National Military Medical Center (WRNMMC). Individuals between 18 and 50 years of age who have PTSD and/or had a mild TBI. Healthy individuals between 18 and 50 years of age who have no history TBI and no history of PTSD. Design: Participants will be screened with a physical exam and medical history. Urine and breath samples will also be collected. Participants will have two imaging studies, on the same day if possible. The first will be a magnetic resonance imaging scan to look at the brain. The second will be a positron emission tomography scan with the study chemical to look at GABA pathways in the brain....
Telepharmacy Robotic Medicine Delivery Unit "TRMDU" Assessment
Traumatic Brain InjuryPosttraumatic Stress Disorders3 moreThe objective of this study is to evaluate whether use of TRMDU in addition to medication review leads to improved outcomes and reduced health care costs for patients when compared with medication review alone. The study will be conducted in patients assigned to Department of Defense (DOD) Warrior Transition Units (WTU's), similar DOD units, and VA polytrauma centers.
Characterization of Fatigue in Military Personnel With Traumatic Brain Injuries
Traumatic Brain InjuryNeurobehavioral Manifestation2 moreBackground: People who have had a traumatic brain injury (TBI) often experience fatigue. Fatigue is the feeling tired all the time. Researchers want to learn more about how TBI and fatigue are related. Objective: To better understand fatigue after TBI in active duty military and veterans. Eligibility: Active duty service members or veterans ages 25-40 who have sustained at least 1 TBI more than 6 months but less than 5 years ago Design: Participants will be screened with: Medical history Physical exam Blood and urine tests Participants will have Visit 1 the same day as screening. This will include questionnaires and interviews. These will be about their fatigue, quality of life, and health. Participants will wear an activity monitor on their wrist and complete a sleep diary for 7 days at home. Participants will have Visit 2: They will stay in the clinic for 2 nights. The visit will include: Tests of memory, attention, and thinking Placement of intravenous (IV) line: A needle will guide a thin plastic tube into the participant s arm vein. 2 overnight sleeps tests: Participants brain waves will be recorded while they sleep. Small electrodes will be placed on the scalp. Monitors will be placed on the skin. These will measure breathing, heart rate, and movement. Blood will be drawn overnight through the IV line. Optional hydrocortisone stimulation test: Participants will receive the hormone through the IV line. Blood will be drawn through the IV line 5 times over 1 hour. Optional MRI: Participants will lie in a machine. This machine is a metal cylinder that takes pictures of the brain.
Non-invasive Near-infrared Spectroscopy (NIRS) Versus Invasive Licox Intracranial Pressure
Brain InjuriesResearchers are trying to assess how accurately and safely NIRS non-invasive monitoring can detect changes in intracranial pressure to determine if this noninvasive device can be used instead of invasive monitoring with Licox in the future.
Noninvasive Monitoring of Cerebral Blood Flow Autoregulation in Patients With Traumatic Brain Injury...
Traumatic Brain Injury (TBI)BACKGROUND: The brain is very sensitive to both excessive and insufficient flow of blood. Cerebral blood flow (CBF) is normally auto-regulated by the blood vessels in the brain, but this protective mechanism is often disturbed after a traumatic brain injury (TBI). Impairment or loss of the CBF autoregulation makes the brain vulnerable to oscillations of either arterial blood pressure (ABP) or intracranial pressure (ICP). The ideal management of TBI patients, therefore, involves continuous measurement and management of the cerebral perfusion pressure (CPP = ABP - ICP) but the measurement of CPP is currently possible only with specialized equipment and expertise that is not available in all institutions. The investigators have converted a no-longer used system that continuously monitors CBF autoregulation using rheoencephalography (REG) technology into a modern, small, battery-powered, low-cost monitor (aka BM-1) that acquires the REG signals using only noninvasive electrodes placed on the skin/scalp. REG data can then be used to calculate the optimal CPP to maintain in each individual patient. BM-1 is also capable of monitoring electroencephalography (EEG) and impedance plethysmography (IPG), which can, respectively, be used to measure brain electrical activity and changes in peripheral blood flow caused by blood pressure changes. OBJECTIVES: The primary objectives are to (Obj. 1) demonstrate that REG acquired noninvasively is equal to the well-established but invasive method using intracranial pressure (ICP) monitoring, (Obj. 2) retrospectively test the idea that TBI patients have a less favorable outcome if their CPP were found less optimal using the REG data, and (Obj. 3) determine if noninvasive IPG or the PPG finger sensor monitoring (used to measure heart rate in doctor's offices) can replace the invasive monitoring of arterial blood pressure (ABP). METHODOLOGY: This is an observational study with retrospective data analysis. 20 adult patients (18-65 yrs) with acute TBI, who meet the inclusion/exclusion criteria, will be enrolled on a first-come-first-enroll basis. The enrolled patients will have the REG, EEG and IPG signals monitored for the duration of ICU stay or 15 days, whichever is shorter. Standard neurological assessment will be made at the patient's discharge from the ICU and at 3 months after injury. The study is expected to end June 2013.
Risk Prediction for Alzheimer Dementia With Brain Imaging and Genetics
Alzheimer DementiaPosttraumatic Stress Disorder1 moreThe purpose of this study is to learn about how trauma, posttraumatic stress disorder (PTSD), and mild traumatic brain injury that can occur during deployment affect the brain. The investigators also want to learn how PTSD and mild traumatic brain injury can affect the chance of developing Alzheimer disease later in life. The investigators will study this by using magnetic resonance imaging and positron emission tomography scans to obtain pictures of the brain.
Hemp-Derived Botanical Dietary Supplementation During Recovery From Brain Injury
Traumatic Brain InjuryThe objective of the proposed research is to evaluate adult subjects currently taking phytocannabinoid Hemp-derived botanical supplements (HDS) during recovery from traumatic brain injury. This study seeks to answer whether subjects taking HDS formulations experience relief from self-reported symptoms or improved subjective well-being, sleep quality, cognitive benefits, side effects and/or quantifiable changes in brain state neuronal activity or stress biomarkers. We seek to answer whether regular users (once/week to multiple uses/day) of HDS experience signs of dependence, addiction or physiological withdrawal. To accomplish this we will use survey questions, quantitative EEG, cognitive testing and salivary biomarkers to determine the effectiveness of self-initiated HDS administration. In addition, we are interested in whether our objective measures allow us to understand why some people are responders to HDS health benefits while others are not.
Importance of Substance P in Intracranial Pressure Elevation Following Traumatic Brain Injury
Traumatic Brain InjuryTraumatic brain (TBI) injury is the major cause of morbidity and mortality worldwide especially in population under 40 years of age and has a significant socioeconomic impact. TBI results from the head impacting with an object or from acceleration/deceleration forces that produce vigorous movement of the brain within the skull, with the resultant mechanical forces potentially damaging neurones and blood vessels and causing irreversible, primary brain injury. Primary injury leads to activation of cellular and molecular responses which lead to disruption of the blood-brain barrier causing the brain to swell. As the intracranial space is not expandable (i.e. is fixed), this swelling leads to increase in intracranial pressure (ICP) compromising blood supply to the rest of the brain leading to secondary brain injury. As we are unable to reverse the primary injury, current protocols use supportive measures to control the ICP and ensure optimal blood supply to the brain in an attempt to minimize secondary injury. Our understanding of the factors involved in the initiation and propagation of brain swelling in TBI is growing and the role of neuroinflammatory cytokines in this process is increasingly recognized. In preclinical models of TBI, a specific inflammatory cytokine termed substance P (SP) is found to be associated with blood-brain barrier disruption and development of brain oedema in the immediate phase following injury. The aim of this study is to examine the role of SP in the genesis of cerebral oedema and elevation of ICP and thus secondary injury following human TBI. This would be achieved by blocking SP function with a SP receptor antagonist Fosaprepitant (IVEMEND®, Merck) in the first 24 hours following TBI and then continuously measuring ICP and assessing the evolvement of TBI using magnetic resonance imaging.
A Biofeedback Intervention for the Prevention of Challenging Behaviour
Acquired Brain InjuryThis study aims to explore whether feedback from a physical monitoring device (electronic watch) to prompt patients to use an anxiety management strategy can help prevent challenging behaviour.
Feasibility of Two New Software Modules for the Rehabilitation of Patients With Neuromuscular Upper...
StrokeParkinson Disease2 moreIntroduction: In the recent past, medical training systems using virtual reality (VR) have been introduced to neurorehabilitation to train motor function deficits in patients. The usage of VR-based training systems is based on the evidence of neuroplasticity, which is responsible for recovery of patients suffering from motor dysfunction. Such systems are increasingly used to encourage purposeful limb movements in a VR environment and its efficacy has been found comparable with conventional therapeutic intervention. VR training systems, e.g. the YouGrabber® (YG), will increasingly also be used at home. Therefore, it is essential to integrate valid and reliable assessment tools to monitor the recovery process. Objectives: The aim of the clinical study is to evaluate the usability, feasibility and validity of the digital version of the ActionResearchArmTest (d-ARAT) using the YG system as a platform. Additionally, the feasibility and usability of the implementation of two rehabilitation measures that only recently became integral part of neurorehabilitation, e.g. Action Observation (AO) and Motor Imagery (MI), into the YG training software will be evaluated. Patients & methods: This observational study is designed as a single-arm trial for testing the assessment software including pre- to post rehabilitation comparison of a training involving AO and MI. Therefore, 75 adult patients with Parkinson's disease, MS, Stroke, traumatic brain injury or Guillain-Barré syndrome will be included. 30 out of the 75 patients will take part in the 4-week training on the enhanced VR-based system with a total of 16 training sessions of 45 min each. Primary outcomes will be the score on the System Usability Scale (SUS) and the ARAT as well as the d-ARAT scores. Secondary outcomes will be hand dexterity (Box-and-Block Test), upper limb activities of daily living (CAHAI) and quality of life (EQ-5D-5L). Hypothesis: The study was designed to evaluate the d-ARAT and the training software modules for the YG system. Currently AO and MI specific tasks are being integrated and the ARAT subscales will be implemented on the basis of the redesigned glove equipped with new sensors. The results are expected to give recommendations for necessary modifications. They might also contribute knowledge concerning the application of AO and MI tasks within VR training.