View clinical trials related to Brain Injuries.
Filter by:This pilot study aims to determine the feasibility of a virtual reality treadmill training intervention in individuals with Traumatic Brain Injury (TBI). Participants will be stratified based on age into adults' group or older adults' group and then randomized into the virtual reality treadmill training (intervention) group with feedback or the treadmill training (control) group. This pilot study will also provide preliminary evidence on the impact of the virtual reality treadmill training on mobility, balance, fear of falls, fall risk, attention and physical activity in the community in individuals with TBI. The data collected in this pilot study will also help to estimate sample size for subsequent large clinical trial.
Children suffer proportionally more head injuries than any other age group and children with head injuries have the highest mortality of all children admitted with traumatic injuries. The investigators aim to investigate the factors that contribute to poor outcomes after paediatric acute brain injury by collecting observational and outcome data. Much of the brain damage that results in poor outcomes actually happens in the hours and days after the injury. This is due to several factors such as brain swelling and poor oxygen delivery to the brain. Treatment is directed to try and protect the brain against these factors. Current management of the head injured child focuses on monitoring pressure within the head. However, this does not detect all the factors that cause continuing brain damage. Special monitors that follow oxygen levels and chemical changes in the brain are used safely in adult patients but have not been widely employed in children despite their potential benefit. There is therefore the opportunity to evaluate extra monitoring of the child brain, and in doing so, help refine the management of these patients.
New learning and memory impairment (NLMI) is a common and devastating manifestation of TBI associated with substantial life burdens. Persons with moderate to severe TBI have shown improvement in NLM for prose material (e.g. story) as well as beneficial changes in default-mode network (DMN) activation during list-learning19 following treatment with the Kessler Foundation modified Story Memory Technique® (KF-mSMT®). Benefits, however, were moderate and did not yield downstream improvements in daily life. It is thus critical to examine other approaches to complement the KF-mSMT® for robustly managing NLMI in TBI. The proposed RCT will be the first to include aerobic exercise training (AET) as a highly-promising complement to the KF-mSMT® for robustly managing NLMI, examining impact on NLM, its neural correlates, and daily life in NLM impaired persons with moderate-to-severe TBI. We thus propose a two-arm, parallel group, double-blind RCT comparing the effects of the KF-mSMT+AET with the KF-mSMT+S/T (active control condition) on NLM (Aim 1), hippocampal MRI (Aim 2), and daily life outcomes (Aim 3). 60 NLM impaired persons with moderate-to-severe TBI will be randomized to one of 2 conditions (30 per condition). Each condition will take place 3 days per week for 12 weeks and will be supervised by KF personnel. Participants will be blinded as to the intent of the conditions. We will further explore baseline predictors of clinically meaningful changes in NLM for those completing the KF-mSMT + AET condition (Exploratory Aim 4). If successful, this trial will position combinatory KF-mSMT and AET within the clinician's arsenal for robustly managing NLMI in persons with TBI. By augmenting the effects of KF-mSMT with AET, this treatment aims to exert a powerful countermeasure to TBI-related NLMI, and ultimately help those with TBI-related NLMI return to the workforce, independently manage their everyday lives, and maintain optimal quality of life. Additionally, while rigorously designed to answer the scientific question of the relative benefit of AET with the KF-mSMT, the proposed study is will likely provide some level of benefit to all study participants. If successful, this trial will provide Class I evidence of combined KF-mSMT and AET for rehabilitating NLMI in TBI, based on standards published for therapeutic trials by the American Academy of Neurology, thus positioning such an approach within the clinician's arsenal for robustly managing NLMI. By augmenting the effects of KF-mSMT with AET, we anticipate this treatment will ultimately help those with TBI-related NLMI return to the workforce, independently manage their everyday lives, and maintain optimal quality of life.
A moderate traumatic brain injury (TBI) occurring in early or middle adulthood might have long-lasting effects on the brain that can accelerate the decline of physical and cognitive function in older age. The proposed study seeks to better understand the implications of aging with a TBI, in order to help Veterans maintain their health and independence. The overarching hypothesis of this new line of research is that participants who experienced a moderate TBI in early or middle adulthood (at least 15 years prior to study enrollment) will have poorer performance on balance and cognitive tests, despite self-reporting no persistent motor or cognitive impairment from the TBI. The investigators also seek to evaluate the potential for practice-based learning and improvement of complex balance tasks in this population, to gain experience for conducting future rehabilitation studies. The long term goal of this line of research is to design rehabilitative and lifestyle interventions to preserve brain health and function in Veterans who have previously experienced a TBI.
The purpose of this study is to evaluate the effectiveness of NeuroResource Facilitation, a novel/innovative intervention, in reducing recidivism in offenders with brain injury (BI).
This is a prospective observational substudy of the STEPCARE trial ClinicalTrials.gov Identifier: NCT05564754) with the aim to examine whether prognostication of neurological outcome after cardiac arrest can be performed earlier than the 72 h time-point recommended by guidelines today.
Pediatric traumatic brain injury (TBI) is often associated with difficulties in social functioning. Loss of social contacts and difficulties maintaining social connections is common after pediatric TBI, extending into adulthood. Social skills are a key aspect of social functioning critical to forming and maintaining social relationships with others, including family, friends, teachers and co-workers. Social skills deficits are thus critical to social participation and overall quality of life. The identification of treatment techniques to effectively address these issues are thus of paramount importance. The ability to improve social skills in adolescents and young adults is critical as they transition from school settings into the workforce. Impairments in social skills have been demonstrated to underlie difficulties transitioning from school to work and independent living in students with disabilities. Therefore, targeting social skills interventions as individuals enter adulthood and enter the workforce is likely to improve overall functioning during this transitional period in their lives. The current study will examine preliminary efficacy of a manualized group intervention that targets social skills, specifically work-related social skills known as soft skills. Targeting not only general social skills, but soft skills in particular, is expected to be particularly useful for teens and young adults as they transition from school into the workforce. The Assistive Soft Skills and Employment Training (ASSET) is a 15-session training program that combines specific skill training, structured learning, social performance training and a social hour to practice skills through a manualized group intervention. Specific skills taught within the program include communication, attitude and enthusiasm, teamwork, networking, problem-solving and critical thinking, professionalism, mental health and stress management, awareness of self and others, workplace relationships and self-advocacy. ASSET utilizes a manualized curriculum and provides additional support including handouts, PowerPoint summaries, instructional procedures, video models, materials for caregivers, and an online platform to support learning the program. ASSET has been utilized with young adults with ASD with very positive results, improving performance on measures of social skills, social communication, self-confidence/self-efficacy and psychological wellness. The current proposal will test the efficacy of the ASSET program in youth and young adults with TBI between the ages of 15 and 25, a critical time as individuals' transition from school settings into the workforce. The proposal will evaluate the primary outcome of improvements in social skills following completion of the ASSET program. Secondary outcomes of self-efficacy, depression, anxiety and quality of life will also be evaluated following completion of the program.
This study will explore whether the types and intensity of the interventions being delivered will yield measurable cognitive benefits in addition to improved mobility and balance. The study evaluates three therapeutic approaches to improve mobility and balance after traumatic brain injury (TBI): Conventional Gait and Balance Training, high intensity step training, and high intensity step training with virtual reality.
The goal of this clinical trial is to extend the accessibility of the Diabetes Prevention Program Group Lifestyle Balance (DPP-GLB) modified for people with TBI (GLB-TBI) to reduce health inequities and reach a broad and diverse sample. To increase the accessibility and reach of the GLB-TBI we will conduct a randomized control trial (RCT) to assess intervention efficacy of telehealth delivery of the GLB-TBI (tGLB-TBI). Results will provide a scalable telehealth weight-loss program that clinicians and community workers across the country can use to help people with TBI lose weight and improve health.
Robotic assisted laparoscopic surgery has become an alternative to open or laparoscopic technique in various surgical fields. Robot assisted laparoscopic surgery is preferred by surgeons and patients due to easy accessibility, lower blood loss and lower transfusion rates. However, robotic assisted laparoscopic surgery can cause significant changes in cardiovascular, respiratory, metabolic and cerebral physiology because it requires a deep trendy position. When long -lasting deep trendelenburg position is applied, the cerebral autoregulation is impaired. In the literature, the presence of cases with brain edema is shown. In recent years, many biomarkers have been used in the evaluation of brain damage. S100 Calcium Binding Protein (S100β), N Ron specific enolase (NSE), Glial Fibrils are among the biomarkers used to show acidic protein (GFAP) brain damage. The S100β is specific and is mainly produced by astrocytes and enters the bloodstream after neuron damage. Glial fibrils is an acidic protein (GFAP), a protein encoded by the GFAP gene in humans, an intermediate filament protein produced in the central nervous system. Neuron specific enolase (NSE) is one of the enzymes that increase brain damage encoded by Enolase 2 (ENO2) gene. Mini Mental State Examination and Montreal Cognitive Assessment will be performed to determine neurological changes developing in patients. The purpose of this study; Robotic assisted laparoscopic surgery is to examine the brain damage that may develop in patients due to deep trendelenburg position in patients with the said biomarkers and to evaluate the anesthesia methods applied in these surgery in line with the study results.