1,003 Clinical Trials for Various Conditions
The goal of this observational study is to develop and validate a clinical tool to predict which adolescents aged 11 to less than 18 years of age with mild traumatic brain injury (mTBI) are at an increased risk for developing significant new or worsening mental health conditions. The main aims the study wish to answer are: * Does the adolescent have new or worsening depression or anxiety defined as a change from their previous medical history using self-reported questionnaires at either one or three months post-injury? * Does the adolescent have unmet mental health care needs, defined as not receiving any mental or behavior health care in patients with new or worsening anxiety or depression as defined by the self reported questionnaires? Participants will be enrolled after being diagnosed in the emergency department (ED) with an mTBI. During the ED visit, the child's parent/caregiver and the adolescent will complete several questionnaires related to mental health which include tools to measure anxiety and depression. Participants will be asked to complete these questionnaires again at 1 month and 3 months post enrollment.
This study is testing the usefulness of two types of Brain Health \& Wellness classes for Veterans with a history of concussion to improve mental health.
Rebion has developed a device, the Rebion trauma tool (referred to as the head and intraocular trauma tool, or "HITT"), that detects ocular fixation and alignment using a binocular retinal scan. Preliminary data obtained from hospitalized patients with a clinically-confirmed traumatic brain injury (TBI) and uninjured controls indicates that the device can detect changes in ocular fixation, alignment, and saccades that are related to brain injury. This study seeks to evaluate the ability of the Rebion trauma tool to assess perturbations in eye movements resulting from TBI. The study will enroll 60 TBI patients and 20 controls.
Upwards of 3.8 million concussions occur annually in the United States. Driving is a highly complicated activity that requires visual, motor, and cognitive skills, which are commonly impaired after concussion. Yet, the time course of post-concussion driving impairment has not been characterized. There is a critical need to 1) determine when concussed individuals should return to driving and 2) identify the key concussion assessment predictors of readiness to return to driving. In the absence of formal recommendations, impaired concussed drivers are at risk to themselves and others on the road. The first specific aim is to compare simulated driving between concussed individuals and non-concussed yoked matched controls across five longitudinal timepoints (pre-injury baseline, day 2, day 4, asymptomatic, and unrestricted medical clearance) and daily naturalistic driving from day 2 to day 9. Driving recommendations must be appropriate and necessitated by concussion impairments, since excessively strict recommendations wrongfully strip concussed patients of their independence and may dissuade individuals from seeking medical care. The second specific aim is to identify widely used concussion assessment outcomes that predict simulated driving performance among concussed individuals throughout concussion recovery. To address these aims, 100 concussed and 100 yoked matched control young adult college athletes will complete a simulated driving assessment and a robust concussion assessment battery at pre-injury baseline, day 2, day 4, asymptomatic, and unrestricted medical clearance. Naturalistic driving (measured with in-car global positioning systems) will be captured from day 2 to day 9 (7 days total). This study will determine the acute and subacute time course of post-concussion driving impairment and determine key predictors of post-concussion driving performance. Results from this innovative approach will have a broad and positive impact that will improve the safety of both concussed individuals and the general population, guide the practices of health professionals, inform the future work of researchers, and substantiate the work of policy-makers by providing evidence-based recommendations for managing post-concussion driving.
Veterans with traumatic brain injury (TBI) frequently experience insomnia, which is linked with delayed TBI recovery, more severe functional impairment, and exacerbation of disabling TBI after-effects such as depression, chronic pain, and fatigue. Current research suggests that TBI can impact numerous systems involved in sleep, suggesting that insomnia can have various causes and that a "one-size-fits-all" approach to treatment is likely inadequate. As such, it is necessary to determine which Veterans may benefit from standard evidence-based treatments, such as Cognitive Behavior Therapy for Insomnia, and which may require enhanced treatments targeting specific underlying mechanisms. An emerging body of evidence has established a link between circadian rhythm disruption and post-TBI insomnia. A mismatch between circadian and desired sleep timing (i.e., "circadian misalignment") is common following TBI, as evidenced by disruptions of key circadian rhythms involved in sleep regulation (e.g., melatonin production), as well as the onset of circadian rhythm sleep-wake disorders. Importantly, circadian-driven sleep disturbances require specialized treatments that target circadian rhythms (i.e., "chronotherapies"), such as timed sleep windows or enhanced light exposure, as standard treatment approaches can fail to address or even exacerbate the underlying circadian misalignment. Thus, circadian misalignment represents a novel and modifiable treatment target and has the potential to improve functional outcomes in Veterans with TBI and insomnia. Detection of circadian misalignment and optimal use of chronotherapies require the ability to measure circadian phase (i.e., timing of the central circadian clock). However, current sleep medicine in TBI is hampered by a lack of pragmatic options for measuring circadian phase. This is because laboratory dim light melatonin onset (DLMO), the gold standard measure of circadian phase, is time and cost prohibitive, requiring specialized sample (e.g., saliva) collection facilities and placing substantial burden on the patient. Recently, novel methods of DLMO measurement have been developed that may enhance the accessibility and practicality of circadian phase assessment, although, as of yet, they have not been used in Veterans with TBI. The proposed single-arm, longitudinal study seeks to evaluate the feasibility of two methods of measuring DLMO in the home environment of Veterans with TBI and insomnia: 1) direct measurement of self-collected salivary melatonin; and 2) indirect estimation of DLMO using activity and light-exposure data collected through actigraphy. Additionally, this study seeks to explore the relationships between circadian misalignment, sleep disturbance, and functional impairment in Veterans with TBI. The specific aims of this study are to: Aim 1) evaluate the feasibility of two methods of home DLMO measurement (i.e., self-collected salivary melatonin and actigraphy data) in Veterans with TBI and insomnia; and Aim 2) examine associations between circadian misalignment (i.e., the difference in timing between DLMO and attempted sleep onset), sleep disturbance, and functional impairment. Veterans with TBI and insomnia will be asked to wear a wrist-based actigraphy device for one week, which will collect data on light exposure and sleep-wake states. They will then be asked to self-collect seven hourly saliva samples under dim light conditions in their own home and mail them to a testing facility using a provided pre-paid shipping label. Saliva samples will be used to directly measure DLMO and actigraphy data will be used to indirectly estimate DLMO using established mathematical models of the human circadian pacemaker. Evaluating the feasibility of home DLMO measurement is a crucial first step for enhancing precision sleep medicine for Veterans with TBI and insomnia. Findings will inform the development and testing of tailored sleep interventions for use with this patient population.
The purpose of the study is to calibrate and to validate the accuracy of the oximeter with an estimate of brain oxygen levels assessed by measuring arterial and internal jugular vein blood oxygen saturations.
The overall objective is to obtain an initial assessment of the value of using \[18F\]3F4AP for imaging demyelinating diseases such as traumatic brain injury (TBI), neurodegenerative diseases such as mild cognitive impairment (MCI) and Alzheimer's Disease (AD): * Aim 1) Assess the safety of \[18F\]3F4AP in healthy volunteers and subjects with traumatic brain injury (TBI) and neurocognitive impaired subjects (AD/MCI). Hypothesis 1: Administration of \[18F\]3F4AP will result in no changes in vitals or other adverse events. * Aim 2) Assess the radiation doses to the main organs in healthy volunteers. Hypothesis 2: the radiation doses to each organ will be comparable in all subjects and within the acceptable limits. * Aim 3) Assess the pharmacokinetics of a bolus infusion of \[18F\]3F4AP in humans including healthy volunteers and patients. Hypothesis 3: the pharmacokinetics of \[18F\]3F4AP at the whole brain level will be similar in controls, TBI and AD/MCI subjects. The kinetics in demyelinated lesions will be slower than in healthy areas. * Aim 4) Correlate MR images with \[18F\]3F4AP PET images. Hypothesis 4A: all the lesions seen on the MRI will show increased signal (VT or SUV) on the PET images. Hypothesis 4B: some of the lesions on the MRI will show increased signal (VT or SUV) on the PET but not all. * Aim 5) Correlate \[18F\]3F4AP PET signal with neuropsychological testing in people with TBI and AD/MCI. Hypothesis 5A: increased PET signal (VT or SUV) will correlate with impaired Mini Mental State Examination (MMSE).
This is a prospective study enrolling 5 patients with a diagnosis of traumatic brain injury (TBI) without polytrauma and 5 patients with TBI with polytrauma admitted to the University of Kentucky (UK) Chandler Medical Center to evaluate differences in platelet bioenergetics in the populations. Additionally, five healthy subjects will be recruited to the control group.
This study will use technology to deliver effective treatment for cognitive problems associated with TBI to Veterans at home, which may result in improved daily functioning and increased access to health care for the growing population of aging Veterans with history of TBI. The successful completion of this project may also increase older Veterans' ability to participate in research through increased understanding of the effect of in-home research opportunities on recruitment and retention. Additionally, the evidence gathered from this study may be used in future research studying home-based cognitive rehabilitation treatments for Veterans using telehealth technology.
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.
Phase 1 of the STIMPACT trial is an open label,dose-escalation,safety study of intravenous (IV) methylphenidate (MPH) therapy in patients with disorders of consciousness (DoC) caused by severe brain injuries. To be classified as having a DoC, a patient must be in a coma, vegetative state (VS), or minimally conscious state (MCS), as determined by behavioral assessment using the Coma Recovery Scale-Revised (CRS-R). Patients with DoC admitted to the intensive care unit (ICU) will be eligible for the study. A total of 10 patients with DoC will be enrolled in the Phase 1 study. Patients will receive escalating daily doses of IV MPH starting at 0.5 mg/kg, increasing stepwise to 1.0mg/kg and 2.0 mg/kg unless an adverse event (AE) necessitates dose de-escalation or a serious adverse event (SAE) necessitates that the patient stop participation in the study. Pharmacokinetics will be evaluated in selected patients with indwelling venous catheters or arterial catheters via serial serum measurements of MPH at each dose. The pharmacodynamic properties of IV MPH at each dose will be assessed by comparison of pre-versus post-dose EEG-based measures. The pharmacodynamic properties of the maximum tolerated dose will also be assessed by comparison of pre-versus post-dose resting state functional MRI (rs-fMRI) connectivity measures. Finally, we will test the association between structural connectivity of the ventral tegmental area (VTA), a dopaminergic brainstem nucleus that is believed to mediate MPH activation of the cerebral cortex, and EEG and rs-fMRI pharmacodynamic measures.
BOOST3 is a randomized clinical trial to determine the comparative effectiveness of two strategies for monitoring and treating patients with traumatic brain injury (TBI) in the intensive care unit (ICU). The study will determine the safety and efficacy of a strategy guided by treatment goals based on both intracranial pressure (ICP) and brain tissue oxygen (PbtO2) as compared to a strategy guided by treatment goals based on ICP monitoring alone. Both of these alternative strategies are used in standard care. It is unknown if one is more effective than the other. In both strategies the monitoring and goals help doctors adjust treatments including the kinds and doses of medications and the amount of intravenous fluids given, ventilator (breathing machine) settings, need for blood transfusions, and other medical care. The results of this study will help doctors discover if one of these methods is more safe and effective.
The proposed study will evaluate the safety, durability and efficacy of repetitive Transcranial Magnetic Stimulation (rTMS) as a promising non-invasive therapeutic treatment for improving memory in older adults with mild or moderate Traumatic Brain Injury (TBI) who have been experiencing residual memory or cognitive problems that affect daily functioning.
This study is Part 2 of data collection from 13-25 years old subject population for validation of previously derived algorithms. This data will be combined with that collected under NCT02957461 (Part 1 with subject age range 18-25 years) for the final analyses of validation of the algorithms.
One of the principal complicating factors associated with traumatic brain injury (TBI) is sleep-wake disturbances (e.g., insomnia, excessive daytime sleepiness, and circadian rhythm sleep disorders). Morning bright light therapy (MBLT) has been shown to improve sleep quality in a variety of conditions, but little has been done investigating the utility of MBLT in improving sleep in Veterans with TBI. This proposal aims to determine the effect of MBLT on sleep quality in Veterans with TBI. Veterans with and without TBI will be recruited from the VA Portland Health Care System. Baseline questionnaires and 7 days of actigraphy will be collected prior to engaging in 60 minutes of MBLT daily for 4 weeks, during which actigraphy will also be collected continuously. Post-MBLT questionnaire data will be collected, and follow-up questionnaire data will be collected at 3 months post-MBLT.
SMART is an interactive web-based program that will allow youth with mild traumatic brain injuries (mTBI) to monitor their symptoms and receive education on problem-solving and coping strategies. This study will evaluate the effectiveness of SMART as a means of improving symptom-management, coping skills, and general well-being during recovery from mTBI. Half of participants will receive the SMART intervention, while half will receive usual care.
This research aims to develop an intervention that combines mTBI-specific motor and cognitive challenges into a progressive and challenging rehabilitation program. We plan to develop and refine a combined motor and cognitive intervention using healthy athletic young adults (n=12) and people with a positive history of non-resolving mTBI (n=12). We will conduct limited feasibility testing by conducting 6 week training sessions with each subject group. We also plan to identify best measures for determining readiness for duty or full function by incorporating and testing 3 dual-task assessment measures using state-of-the-art wearable sensors to quantify movement.
The aim of the study is to quantitate Central Nervous System (CNS) autoantibody development in human blood using ELISA after human brain injury, spinal cord injury, and intra-axial brain surgeries.
This study is Part 1 of data collection from 18-25 years old subject population for validation of previously derived algorithms. This data will be combined with that collected under NCT03671083 (Part 2 with subject age range 13-25 years) for the final analyses of validation of the algorithms.
One of the most pressing concerns within the VA currently is the provision of interventions that address the cognitive as well as emotional problems faced by Veterans with mild TBI and comorbid conditions. When completed, these studies will inform us whether training core attentional self-regulatory control functions via personally-relevant activities will be effective in improving daily life for Veterans with mild TBI and comorbid conditions. The study design will provide a test not only of potential benefits for real life functioning, but also determine to what extent these benefits are related to actual changes in cognitive/behavioral performance and brain networks corresponding to these functions. This project will provide a foundation for future studies to investigate the neural mechanisms that support improvements of cognition and behavior in mTBI.
People who sustain moderate to severe traumatic brain injury (TBI) have an increased risk for unintentional injury and harm when resuming day to day activities in the home and community. People who sustain brain injuries primarily want to independently do the activities they enjoy while families primarily focus on avoiding injury or other harm events. Safe@Home is an injury prevention education and activity training program. Participants who have sustained a moderate or severe TBI receive a personalized strengths and safety risk assessment, tailored injury prevention education, and in-home training with a transition coach on self-selected activities. This study will evaluate whether the Safe@Home program reduces injuries and harm and increases clients' independence in their everyday activities in the home and community compared to a usual care control group.
This study (Part 2) 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. In addition, neuroimaging will be conducted at time of injury and following Return to Play (RTP).
The experimental design is an open-label two-week trial of tolcapone to evaluate which clinical domains are affected by tolcapone treatment and to identify "responders" to tolcapone treatment in the two subject groups (BI and NCD)
The purpose of this study is to test an innovative combination of direct-attention training and metacognitive training in the treatment of attention impairments in Veterans with moderate-to-severe traumatic brain injury (TBI) who report experiencing attentional problems. Enrolled participants will be randomized to receive either the direct-attention training or metacognitive training first and then will be crossed over to receive the opposite intervention. The study will consist of two treatment periods of 4 weeks and a post-treatment 4 weeks later. In addition to the rehabilitation treatments, participants will also perform measures of complex functional activities (e.g., independent activities of daily living or IADLs) and neurocognitive tests of attention-control functions. Participants will also perform an attentional task that probes the function of three different attentional systems while brain wave activity (i.e., electroencephalography or EEG) is being recorded in order to assess changes in brain function that may be improved by the rehabilitation approach. Planned enrollment will be 36 Veterans.
The purpose of this study is to determine the effect of intravenous infusion of autologous bone marrow mononuclear cells (BMMNC) on brain structure and neurocognitive/functional outcomes after severe traumatic brain (TBI) injury in adults. The primary objective is to determine if the intravenous infusion of autologous BMMNC after severe TBI results in structural preservation of global gray matter (GM) volume and white matter (WM) volume and integrity; as well as select regions of interest in the corpus callosum. THe secondary objectives are to determine if autologous BMMNC infusion improves functional and neurocognitive deficits in adults after TBI; reduces the neuroinflammatory response to TBI; evaluate spleen size and splenic blood flow over time using ultrasound and corresponding changes in inflammatory cytokines; and infusion related toxicity and long-term follow-up safety evaluations.
The investigators will conduct an observational crossover study. The investigators aim to recruit 50 participants with severe Traumatic Brain Injury (TBI) requiring intracranial pressure (ICP) monitoring during their stay at the Neuro Trauma ICU at the R Adams Cowley Shock Trauma Center. Overall, participants will be monitored, on average, for approximately 6-8 hours during the study period. The investigators do not anticipate the need for prolonged monitoring during the duration of their hospital stay or post hospital period.
This study (Part 1) 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. In addition, neuroimaging will be conducted at time of injury and following Return to Play (RTP).
The purpose of the study is to gather information about patients with mild traumatic brain injury in order to develop guidelines for evaluation and treatment.
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.
The specific aim of this research is to determine if the blood from brain-injured patients contains reproducible protein markers that appear prior to elevations in intracranial pressure (ICP).