View clinical trials related to Traumatic Brain Injury.
Filter by:This intervention study aims to investigate the effects of the m-Health supportive care transition program on response patterns (transition stress and the burden of caregiving) among traumatic brain injury (TBI) caregivers and patients' readmission rate one month after hospital discharge. Specific objectives: 1. Compare the response patterns (transition stress and the burden of caregiving) of TBI caregivers before and after receiving the program within the group. 2. Compare TBI caregivers' response patterns (transition stress and the burden of caregiving) between the control and intervention groups. 3. Compare patients' readmission rates at one month after hospital discharge between the control and intervention groups TBI caregivers are divided into two groups: the intervention group (who receive the transitional care program) and the control group (who receive the standard care program) according to standard operating procedures applicable in the hospital. If there is a comparison group: Researchers will compare [insert groups] to see if [insert effects]
The purpose of this study is to investigate the accessibility of beauty products for individuals with upper extremity disabilities. By examining various factors such as packaging design, product applicators, and ease of use, this research aims to identify barriers faced by individuals with upper extremity disabilities or visual deficits when using beauty products. The study seeks to provide insights and recommendations for improving the accessibility of beauty products, ultimately promoting inclusivity and enhancing the overall beauty experience for individuals with disabilities.
The purpose of the project is to evaluate the feasibility, acceptability, and effectiveness of the internet-delivered Acceptance and Commitment Therapy treatment (I-Navigator ACT) for parents who experience stress, distress, depression or anxiety that may be associated with being a parent of a child with disabilities. The project consists of three studies: Study 1: An open feasibility trial in which parents participate in an individual, clinician-supported internet-delivered Acceptance and Commitment Therapy treatment. Study 2: A randomized controlled trial in which participants are randomly assigned either: 1. Navigator ACT group treatment, where parents participate in an Acceptance and Commitment Therapy group together with other parents, led by two group leaders, or 2. I-Navigator ACT internet-delivered Acceptance and Commitment Therapy treatment, where the parent participates on their own, coached by a clinician via a message function. Study 3: A qualitative study in which a smaller sample of parents from the open feasibility trial participate in semi-structured interviews. The interviews take place after the parents have completed I-Navigator ACT. All three studies are conducted in a clinical health care context.
The purpose of this study is to test the efficacy of a walking and balance training program designed to safely challenge and improve walking performance and balance in relation to walking speed, strength, endurance, and balance after traumatic brain injury (TBI). The aim and primary hypothesis of this research project is: Aim) Test and implement a new personalized intervention strategy, in addition to usual and customary care at an inpatient rehabilitation clinic, to improve patient outcomes with secondary conditions associated with impaired balance and walking that typically occur post brain injury. After validation of the locomotor Battery of tests, we will implement a personalized training strategy for individuals based on their battery profile. Hypothesis) Individuals training with this individualized protocol will demonstrate improved walking and balance outcomes and those with lesser pre-intervention impairment will improve at a greater rate than those with greater pre-intervention impairment.
This is a hybrid type III implementation-effectiveness trial; this study design blends elements of implementation and clinical effectiveness research, with the primary aim of determining the utility of an implementation strategy and a secondary aim of assessing clinical outcomes associated with the implementation trial. Consistent with best practices for this type of design, the study team will conduct a randomized test of the effect of implementation strategy on effective delivery of the Online EmReg intervention in clinical practice. Specifically, the study team will compare Standard Training (a 3-hour on-demand training workshop) to Extended Training, (a 3-hour on-demand training workshop with 3 months of bi-weekly consultation). The research team's primary aim is to determine the optimal strategy to train clinicians in effectively delivering Online EmReg, and secondary aim is to assess patient improvement per clinician-administered DERS. Outcome measures will be assessed via self-report surveys, performance evaluations (via role-plays), and tracked clinician participation and fidelity. Study participation is expected to last up to 15 months.
Despite racial/ethnic disparities in outcomes for younger adults with traumatic brain injury (TBI), there are no U.S. standards for TBI transitional care for patients discharged home from acute hospital care. To enhance the standard of care, the investigators will examine the efficacy of the existing intervention named BETTER (Brain Injury, Education, Training, and Therapy to Enhance Recovery), a culturally-tailored, patient- and family-centered TBI transitional care intervention, compared to usual care, among younger adults with TBI and families. The knowledge generated will drive improvements in health equity for younger adults with TBI of various races/ethnicities and families, resulting in improved health of the public.
Repetitive blast exposure has been shown to lead to more severe neurobehavioral impairments versus a single exposure. Blast-induced Traumatic Brain Injury (TBI) can lead to short- and long-term adverse outcomes Even mild brain injuries can impair neurocognitive performance, and repeated injuries can amplify negative outcomes. Service members with repeated exposure to low-level blasts as a necessary part of their job or training display altered neural activity during a memory task that is paralleled by a reduction in accuracy on neurocognitive memory tasks. As a result, it is important to monitor service members that are exposed to multiple blast-generated mTBIs to allow the earliest identification of acute or chronic brain and body insult and provide individualized measures of time to recovery. While TBI is clinically diagnosable, the methods of diagnosis have up to now been typically expensive and immobile, and treatments and interventions sparse. The investigators will conduct a longitudinal assessment of mTBI brain biomarkers by collecting repeated measures of FDA approved mTBI brain injury biomarkers, correlated with sound and blast exposure, as well as continuous monitoring through smart watches (activity, sleep, biometrics, calorie expenditure, balance) and analyte data through analyte sensors (glucose, lactate, ketones). Study data will be organized into categories and presented to participants daily within the application and will be securely stored within the application. At the completion of the study, participants will be provided with the study data digitally within the mobile application and study data will also be provided to the credentialed unit medical provider to enable it to be ported to the participants' electronic medical record. This study will create a continuous record of blast overpressure and sound exposures and correlate those to the participants health state over the course of several 9-week courses. This will enable an assessment of individualized susceptibility to brain injury as well as providing novel data on time to recovery. The investigators hope to develop dynamic and accurate risk profiles that are individual and will lead to further understanding of how to protect participants from mTBI (mild TBI) events.
The intent of this study is to establish technical feasibility in a clinical population (PTSD, with or without mild TBI) of personalized TMS-fNIRS technology. Thereby demonstrating the utility of transcranial magnetic stimulation - functional near-infrared spectroscopy (TMS-fNIRS) technology as a direct measure of frontal brain activity, potentially replacing the indirect motor threshold procedure that may lead to improper dosing of TMS. Personalized TMS-fNIRS technology will guide therapy for depression, post-traumatic stress disorder (PTSD), and/or traumatic brain injury (TBI)
Individuals with mild traumatic brain injury will be randomly assigned to an active heart rate variability biofeedback condition and a sham condition. The investigators will use a randomized pre-post design that will consist of two data collection phases and a 5-week treatment condition. The heart rate variability biofeedback active condition is designed to increase heart rate oscillations (Osc+ condition) consistent with current best practices, while the sham control heart rate variability biofeedback condition is designed to decrease heart rate oscillations (Osc- condition).
The investigators hypothesize that Heterotopic Ossification (HO) formation can be suppressed if the application of a Continuous Passive Motion (CPM) device can be performed for a substantial amount of time. The investigators will use the following study design: a pilot study with 10 ICU patients receiving CPM and 10 matched cases which will follow a conventional physiotherapy program at the time of the conduction of the study. The comparison between the treatment and referent groups of the outcomes will prove the prophylactic power of CPM against HO.