Active clinical trials for "Brain Injuries"

Veterans with mild traumatic brain injury (mTBI) and post-traumatic stress disorder (PTSD) commonly experience cognitive impairments including attention and executive function deficits that interfere with their ability to engage in productive personal and social activities. Of the limited interventions available to address cognition, none rigorously train attention beyond strategy management. This study will evaluate an innovatively combined strategy training known as Goal Management Training plus computerized attention training in Veterans with mTBI/PTSD. Preliminary testing suggests an effectiveness in improving problem solving, attention and functional tasks in a small number of Veterans. Considering these promising results, cost effectiveness, and the demand for access to care from Veterans living in rural areas, a Randomized Controlled Trial will determine and compare the effects of this treatment, administered either in-person or via telehealth, on executive function, attention, other aspects of cognition and real life functional tasks.

Narrative: Worldwide, traumatic brain injury (TBI) is a leading cause of death and disability among children and adolescents. The Investigators aim to test whether pediatric TBI treatment guided by invasive intracranial pressure monitoring produces better patient outcomes than care guided by a protocol without invasive monitoring. Study findings will inform clinical practice in treating pediatric severe TBI globally. Focused didactic and experience-based learning opportunities will increase the research capacity of pediatric intensivists in Latin America.

The purpose of this study is to assess a balance training program to see if it can be helpful to avoid falls in people who have had traumatic brain injuries (TBIs). The study will include 3 groups: TBI Intervention group , TBI Control Group, and healthy control group. TBI Intervention group - These individuals will participate in 16 anticipatory postural adjustments (APA) and compensatory postural adjustments (CPA) training sessions using the Neurocom Balance Platform. Each session will last for 1 hour. During the APA portion, participants will be provided with a visual cue on the front screen in the form of a countdown timer showing the remaining seconds to the onset of the upcoming perturbation. This information will allow an opportunity for the participant to adjust their posture to handle the upcoming perturbation in the best possible way and also train them to anticipate upcoming disturbances and execute corrective motor outputs. In CPA, after a 5 second pause, the platform will oscillate at 1 Hz, with a constant amplitude, in the anterior-posterior direction for 50 seconds, followed by an additional 5 second quiet period. The participant will wear a safety harness at all times and a spotter will be present at all times. TBI Control Group- They do not receive any intervention. healthy control group- They do not receive any intervention. All three groups will participate in two data collection sessions: Baseline and follow-up. At baseline and follow-up, we will collect functional, clinical, biomechanical, and physiological metrics. During training and data collection, a spotter will be present at all times to prevent falls and participants will be allowed as much rest as needed by them..

Hand motor and sensory impairments resulting from neurological disorders or injuries affect more than 50 million individuals worldwide. Conditions such as stroke, spinal cord injury (SCI), and traumatic brain injury (TBI) can cause long-term hand impairments, greatly impacting daily activities and social integration. Since traditional physiotherapy has limited effectiveness in rehabilitation, assistive devices helping in performing in daily activities have emerged as a necessary solution. Soft exoskeletons offer advantages as they are more comfortable and adaptable for the user, but they often struggle to generate sufficient force. On the other hand, electrical stimulation garments, like e-sleeves, show promise by stimulating nerves and muscles in the forearm. However, achieving precise and stable movement control remains challenging due to difficulties in electrode placement for targeted stimulation. Furthermore, none of the currently available devices are capable of artificially restoring lost sensation in users' hands, limiting their ability to manipulate with fragile objects. Recognizing these limitations, our study proposes a solution that combines a standard hand soft exoskeleton with: (i) electrical stimulation to the fingers' flexor and extensor muscles to generate artificial muscle contractions synchronized with the exoskeleton motion, compensating for the lack of gripping force, and (ii) electrical stimulation to the nerves to artificially restore the lost sensation of touch, enabling users to receive feedback on the force they are applying when interacting with the environment. The investigators refer to this proposed combination as Sensible-Exo. To achieve this goal, our project aims to evaluate the functional improvements in assistive and rehabilitative scenarios using SensoExo in comparison to use only the exoskeleton or having no support at all. The exoskeleton will be coupled with an electrical stimulating sleeve capable of delivering non-invasive electrical stimulation in the form of Functional Electrical Stimulation (FES) and Transcutaneous Electrical Nerve Stimulation (TENS). A glove with embedded force and bending sensors will be used to modulate the electrical stimulation. Additionally, apart from studying the enhancement of functional tasks, the investigators will explore improvements in body perception, representation, and multi-sensory integration. Indeed, the investigators also aim at identifying the way patients perceive their body by means of ad-hoc virtual reality assessments that has been developed. Before each assessment patient will perform some predefined movement in virtual reality to familiarize with it and increase embodiment. During the study, participants will perform a range of tasks based on their residual abilities, including motor tasks (e.g., grab and release, Toronto Rehabilitation Institute Hand Function Test, grip force regulation test, virtual egg test), cognitive tasks (dual tasks), and assessments of body representation and perception. Some of these tasks will be conducted in Virtual Reality environments, both with and without active stimulation.

The purpose of this innovative adaptive phase II trial design is to determine the optimal combination of hyperbaric oxygen treatment parameters that is most likely to demonstrate improvement in the outcome of severe TBI patients in a subsequent phase III trial.

This study aims to compare 2 alveolar recruitment maneuvers (ARM) in patients with cerebral injuries and acute respiratory distress syndrome (ARDS) in term of efficacy and tolerance.

Posttraumatic Stress Disorder (PTSD) is a common cause of morbidity in combat veterans, but current treatments are often inadequate. Reconsolidation of Traumatic Memories (RTM) is a novel treatment that seeks to alter key aspects of the target memory (e.g., color, clarity, speed, distance, perspective) to make it less impactful, and reduce nightmares, flashbacks, and other features of PTSD. The memory is reviewed in the context of an imaginal movie theater, presenting a fast (~45 sec) black and white movie of the trauma memory, with further adjustment as needed so the patient can comfortably watch it. Open and waitlist studies of RTM have reported high response rates and rapid remission, setting the stage for this randomized, controlled, single-blind trial comparing RTM versus prolonged exposure (PE), the PTSD therapy with the strongest current evidence base. The investigators hypothesize that RTM will be non-inferior to PE in reducing PTSD symptom severity post-treatment and at 1-year follow up; will achieve faster remission, with fewer dropouts; will improve cognitive function; and that epigenetic markers will correlate with treatment response. The investigators will randomize 108 active or retired service members (SMs) with PTSD to ≤10 sessions of RTM or PE, affording power to test our hypotheses while allowing for ≤ 25% dropouts. The investigators will use an intent to treat analysis, and the Clinician Administered PTSD Scale for the Diagnostic and Statistical Manual of Mental Disorders, 5th Edition, or DSM5 (CAPS-5), conducted by blinded assessors, will be the primary outcome measure. Secondary measures of depression (PHQ-9), anxiety (GAD-7), sleep (PSQI), and functional status (WHOQOL-100), will be assessed pre- and post-treatment, and at 2, 6, and 12 months. ANOVA will compare symptom severity over time within and between groups. The investigators will track comorbid TBI, anticipating it will not adversely impact response. More effective therapies for PTSD, with and without TBI, must be developed and evaluated. RTM is safe and promising, but requires testing against evidence-based interventions in well-designed randomized clinical trials (RCTs). The full study can be conducted either in person or via secure video conferencing.

The goal of this study is to establish that a memory retraining protocol, originally developed for English-speakers, and translated into Spanish, is effective.

Ambulatory children with cerebral palsy (CP) experience walking limitations which negatively influence their ability to physically participate in day to day life. The investigators propose that impaired muscle power generation is the key limiting factor affecting walking activity and participation. This proposal represents a combined approach where participants undergo resistance training for muscle power generation in combination with locomotor treadmill training that is based on typical pediatric walking and activity patterns rather than adult protocols, which are endurance or time-based. Therefore, the primary objective of this randomized controlled trial is to determine the effect of lower extremity Power Training combined with interval Treadmill Training (PT³) on functional walking capacity and community-based activity and participation in children with CP. We hypothesize that remediating the most pronounced muscle performance impairment (i.e., muscle power) with power training combined with a task- specific approach to walking that is developmentally appropriate will have a significant effect on walking capacity and performance.

Behavioral changes following a traumatic brain injury (TBI) are one of the biggest challenges for patients, as well as their family members and others involved in their recovery. One of the most common behavioral changes following TBI is the emergence of impulsive behavior, which has been associated with destructive, suicidal, and aggressive behavior, and is related to poor rehabilitation program adherence. The primary objective of this study is to investigate the effect of a novel neuroplasticity based intervention that combines cognitive training and transcranial direct current stimulation (tDCS) to reduce impulsivity and to improve outcomes and quality of life for those who have suffered a TBI.