120 Clinical Trials for Various Conditions
The purpose of this research study is to assess the effects of receiving transcutaneous spinal stimulation while performing walking exercises compared to completing walking exercises without spinal stimulation for individuals with hemiplegic TBI.
The goal of this randomized clinical controlled trial is examine the effects of gait training with auditory biofeedback (AudFB) on gait biomechanics, clinical measures of ankle joint health, and patient-centered outcomes. The following specific aims will achieve this objective: * Specific Aim 1: Determine if a 6-week gait training with AudFB intervention improves lower extremity biomechanics compared to a Control condition in participants with CAI. * Specific Aim 2: Determine if a 6-week gait training with AudFB reduces talar cartilage deformation compared to a Control condition in participants with CAI. * Specific Aim 3: Determine if a 6-week gait training with AudFB reduces episodes of ankle giving-way and reduces self-perceived severity of symptoms relative to a Control condition in participants with CAI. Participants will: * Complete 12 intervention sessions over a 6-week period of walking, ruck marching, and runninig. * Complete testing sessions before and after the intervention, then after 6 and 12-months following the intervention.
The purpose of this pilot study is to investigate the feasibility of 1) providing virtual reality walking training using a custom developed setup able to be replicated in routine clinical practice and 2) combining the virtual reality training with high-intensity gait training.
The purpose of this research is to compare improvements between the rehab intervention with walking practice using the robotic exoskeleton versus walking practice that is vigorous enough to keep participants' heart rate over a certain target level during physical therapy sessions. Investigators want to compare improvements in your walking function and mental health that occur after 20 interventions. The study also aims to evaluate if participants' mental health, social support, and health literacy affect attendance at physical therapy sessions.
The ERA Stroke project will compare the effects of robotic gait training (RGT) and usual care (UC) gait training in patients in the subacute phase of stroke recovery undergoing inpatient rehabilitation at the Baylor Scott \& White Institute for Rehabilitation (BSWIR).
Stroke is a leading cause of disability in the United States, affecting approximately 795,000 people annually. The Veteran's Health Administration provides over 60,000 outpatient visits for stroke-related care annually at a cost of over $250 million. Among ambulatory people with chronic stroke (PwCS), impaired balance is a common health concern that substantially limits mobility (those with the worst balance walk the least). This project will explore adaptive strategies employed by PwCS in balance challenging environments and if a novel gait training intervention using a robotic device to amplify a person's self-generated movements can improve walking balance. The development of effective interventions to increase walking balance among PwCS will positively impact Veterans' health, quality of life, and ability to participate in walking activities.
The purpose of this research is to study the improvements from walking practice that is vigorous enough to keep participants' heart rate over a certain target level during their physical therapy sessions. The investigators want to know about improvements in participants' walking function and mental health after 20 interventions. The study also aims to evaluate if participants' mental health, social support, and health literacy affect their attendance at physical therapy sessions.
Nearly 1 million individuals in the United States have multiple sclerosis, which causes fatigue and problems with walking. Fatigue and walking problems are poorly treated, but exercise training, particularly high-intensity walking exercise, may help. This provide insight into whether high-intensity walking exercise can improve fatigue and walking problems in people with multiple sclerosis, which could improve quality of life and reduce economic burden.
The purpose of the project is to compare intensity (minutes in target heart rate zone) and steps per session across three gait training modalities, including body-weight supported treadmill training (BWSTT), overground gait training with body weight-support (BWS), and overground gait training utilizing a lower extremity exoskeleton, between patients presenting with varying functional ambulation capacities in the inpatient setting. Additionally, the researchers will compare physical therapist (PT) burden across these modalities and patient functional presentation levels.
The goal of this clinical trial is to improve walking speed, balance, and walking in the community for people with multiple sclerosis. This trial involves intense exercise combined with walking on a shaky treadmill. Walking on a shaky treadmill helps to practice balance and intense exercise promotes the ability to walk faster and farther. In this study, participants will train with a combination of high or low intensity, and with a stable or shaky treadmill. Walking speed and endurance, balance while walking and the number of steps taken in the community will be measured before, half way through the training (15 sessions), after training (30 sessions) and six months after training.
Stroke is a major cause of disability, with 2-3% of Americans reporting stroke related impairments (Tsao 2022). Following stroke, over half of Medicare patients are discharged to post-acute care facilities or receive home-based health care (Tsao 2022). Inpatient rehabilitation guidelines are lacking, with many interventions based on research of patients with chronic stroke. There is great need for randomized clinical trials during the early subacute period (Bernhardt 2017, Jordan 2021). Clinical practice guidelines recommend high intensity gait training (HIGT) for ambulatory patients with chronic stroke (Hornby 2020). Outpatient HIGT protocols incorporating variable stepping demonstrate equivalent effectiveness to forward stepping protocols (Hornby 2019) and have yielded superior results to lower intensity therapies (Hornby 2019, Hornby 2016). Research suggests that HIGT with variable stepping is feasible during inpatient rehabilitation (Hornby 2015, Moore 2020). Pre-post studies suggest that participation in HIGT during inpatient rehabilitation yields greater improvements in walking without an increase in adverse events. (Moore 2020). Despite this, there are no randomized controlled trials evaluating HIGT in the inpatient setting. The subacute phase of stroke recovery may be a critical time for neuroplasticity (Dromerick 2021). Not only might rehabilitation interventions be more effective when initiated earlier (Biernaskie 2004, Dromerick 2021) but because inpatient rehabilitation represents the transition from hospital to home, interventions during this timeframe have the potential to improve discharge disposition, enhance quality of life, and reduce utilization of post-discharge services. In this randomized controlled study, investigators will determine how participation in HIGT during inpatient rehabilitation affects balance, ambulation, and quality of life after 14 and/or 21 days of inpatient rehabilitation, and 8 weeks post-discharge. Investigators will also determine if HIGT reduces health care burden with a cost-effectiveness analysis.
The project will consist of subjects who have suffered Traumatic Brain Injury (TBI) and who are able to ambulate on treadmill with or without a harness system. This will be a 4-week controlled study consisting of two groups of TBI patients, high-intensity intervention group and low-intensity control group. Both groups will receive physical therapy treatment 3 times per week for 1 hour. The intervention group will undergo 30-minute sessions of high-intensity walking on a treadmill with an overhead harness attached for safety. In addition, they will also get up to 30-minutes of low-intensity physical therapy in order to receive 1 hour of treatment time. The control group will undergo only low-intensity physical therapy activities for 1-hour. Low-intensity physical therapy will include strength exercises, stretches, balance, and low-intensity gait training. All participants in both groups will complete these outcome measures on the first day of the study, after 2 weeks of participation, and again at the end of 4 weeks or on their last day before discharge from Carilion's services. Later on, all participants in both groups will be followed up to complete the same set of outcome measures at the end of 1 month since completion of the protocol. This follow up session will take up to 45 minutes to complete.
Over 90% of persons with MS (pwMS) complain of difficulty with walking. High intensity interval gait training (HIIGT), where persons alternate brief periods of walking at high speeds with periods of rest has been found to improve walking in other neurologic diagnoses. However its impact on pwMS is not known. Most gait training in MS is done continuously at a slower pace. The purpose of this study is to compare the effects of HIIGT to traditional Moderate Intensity Continuous Gait Training (MICGT) in pwMS.
Over 90% of persons with MS (pwMS) complain of difficulty with walking. High intensity interval gait training (HIIGT), where persons alternate brief periods of walking at high speeds with periods of rest has been found to improve walking in other neurologic diagnoses. However its impact on pwMS is not known. Most gait training in MS is done continuously at a slower pace. The purpose of this study is to compare the effects of HIIGT to traditional Moderate Intensity Continuous Gait Training (MICGT) in pwMS.
The Ekso (Ekso Bionics) is a wearable exoskeleton that provides robotic support and walking assistance for patients with lower extremity paralysis. Research suggests that exoskeleton-assisted gait training is as effective as conventional gait training at improving walking outcomes and balance during both the chronic and subacute period following stroke (Goffredo et al., 2019; Molteni et al., 2017; Molteni et al., 2021; Nam et al., 2019; Rojek, 2019). Exoskeleton-assisted gait training during acute inpatient rehabilitation provides a means for patients to actively participate in gait training during the early and most severe stages of stroke recovery. Most acute inpatient rehabilitation facilities (IRFs) report a feasibility of 5-8 Ekso sessions during inpatient stays and demonstrate significant improvement from baseline (Nolan et al., 2020; Swank, 2020). Nolan et al. (2020) demonstrated that stroke patients receiving Ekso ambulated 1640 feet more than patients undergoing more conventional gait training techniques during inpatient rehabilitation, suggesting that the exoskeleton may offer additional benefit during this phase of recovery. Despite promising evidence, there have been no randomized controlled trials within the IRF setting. Because Ekso-gait training increases the number of steps patients can take, during acute inpatient physical therapy (PT), the investigators hypothesize that patients who participate in Ekso-gait training will demonstrate quicker improvements in balance, gait speed, endurance and independence in functional ambulation during their stay in the IRF. In this study, eligible patients admitted to Sunnyview Rehabilitation Hospital (SRH) for rehabilitation following stroke will be randomized to receive conventional or Ekso-gait training therapy. Meaningful clinical benchmarks for balance and walking will be assessed using the Berg Balance Scale (BBS) (Alghadir, 2018; Moore, 2018), the 10 Meter Walk Test (10MWT) (Bowden, 2008; Moore, 2018), the Six Minute Walk Test (6MWT) (Kubo et al., 2020; Moore, 2018), and Functional Ambulation Category (FAC) (Mehrholz, 2007). Achieving these benchmark scores are associated with several positive outcomes, including increased ability to ambulate in the community and reduced risk of falling (Alghadir, 2018; Bowden, 2008; Kubo et al., 2020). The investigators also hypothesize that patients in the Ekso cohort will report greater value/usefulness when compared to patients receiving standard care.
The DOOR SCI project examines dosing effects of robotic gait training (RGT) and transcranial magnetic stimulation (TMS) initiated during inpatient rehabilitation and continued through early outpatient rehabilitation
The study design will consist of a cohort of adolescents and young adults with cerebral palsy (CP) that will undergo a gait training protocol. All participants will complete MEG baseline brain imaging measures of their sensorimotor cortical activity, MRI brain/spinal cord imaging (previous MRI or template brain may be substituted), neurophysiological tests of the spinal cord H-reflex, and a series of mobility clinical tests. After completing the baseline tests, the participants with CP will undergo the therapeutic gait training using either traditional physical therapy or utilizing a robotic exoskeleton. After completing all of the therapeutic gait training sessions, the participants will repeat the same assessments that were completed at baseline. The two groups will be compared based on the assessments for therapeutic outcomes.
The proposed study aims to optimize patient outcomes and treatment intervention using a robotic exoskeleton in adults with cerebrovascular accidents (CVA, stroke) by investigating the following: AIM 1 is to investigate the effect of backward gait training with exoskeleton on motor function. AIM 2 is to investigate the effect of backward gait training with exoskeleton on depression. AIM 3 is to investigate the impact of social determinants of health and depression on patient adherence to physical therapy.
The focus of this study is to optimize the delivery of a combined strength and aerobic training regimen to individuals with post stroke hemiparesis and reduce overuse and inefficiencies associated with the nonparetic leg during walking. This study proposes to use 1) split-belt treadmill and 2) single belt treadmill walking using split belt simulation software for enhancing symmetrical walking patterns for people with stroke.
The FIRST project compares the dose of robotic gait training (RGT) with usual care gait training for patients with spinal cord injury (SCI) undergoing rehabilitation at Baylor Scott \& White Institute for Rehabilitation (BSWIR).
The objective of this RCT is to explore the clinical, functional and neurophysiological effectiveness of RE-assisted (Robotic Exoskeleton) early intervention gait therapy in stroke patients during inpatient and outpatient stroke rehabilitation as compared to traditional gait training in three groups: 1) RE; 2) RE-Standard of Care (SOC) and 3) SOC. We will evaluate the short and long-term effects on functional mobility, clinical, neurophysiological, community participation and quality of life.
The purpose of this study is to investigate the effect of two high-intensity gait training interventions on contraversive pushing behaviors in individuals poststroke in the acute inpatient rehabilitation setting. We will also evaluate the effect of these interventions on functional mobility, strength, balance, and endurance. Furthermore, we intend to measure therapist burden when mobilizing individuals with contraversive pushing behaviors.
A variety of rehabilitation techniques focused on improving disability after stroke have shown significant changes on walking speed, and endurance. Also, the administration of combined techniques showed better results. Previous studies have suggested that embedding behavioral strategies in neurorehabilitation protocols can enhance patient's adherence and participation outside the clinical setting. The addition of a group of behavioral strategies called Transfer Package (TP) has been widely used in motor training protocol (e.g. Constraint-Induced Movement Therapy). The TP has shown to enhance the effects of treatment 2.4 times when compared to motor training alone. However, the effect of TP when combined with robotic gait training remains unexplored. In this study our goal is to combine the TP with robotic gait training. The hypothesis is that using the TP in combination with robotic gait training will enhance the outcome of robotic gait training alone and will induce long term transference and retention of the motor skills observed after treatment. More importantly, this experimental intervention is more meaningful to the patient and can be more easily implemented on the clinical setting. The aims of this study are (1) to assess transfer and long-term retention of walking and balance skills after robotic treadmill gait training combined with the TP, (2) to understand participants' acceptability and perceptions of the TP as a tool to enhance transfer of skills to real-world situations, and (3) to examine the feasibility of these combined intervention to improve walking and balance after stroke.
The study seeks to develop an understanding of how, why, and for whom fast treadmill walking (Fast) and Fast with functional electrical stimulation (FastFES) induce clinical benefits, allowing future development of cutting-edge, individually-tailored gait treatments that enhance both gait quality and gait function.
This study will enroll patients with Multiple Sclerosis and some difficulty with walking. The purpose of this study is to use Rhythmic Auditory Stimulation (RAS) a music therapy technique that provides rhythmic auditory cues (like a beat) to help improve a patient's movements, especially when walking. Participants will be asked to participate in a walking program (WP) with Rhythmic Auditory Stimulation (RAS), or a WP without RAS.
The overarching purpose of this project is to use sensor-derived patterns to guide running interventions during in-field training scenarios for runners with exercise-related lower leg pain. The investigators plan to use the RunScribe sensors to facilitate in-field gait-training to determine the effects of real-time gait-training interventions along with a home exercise program (intervention group) on biomechanical and patient-reported outcome measures of pain and function in runners with leg pain as opposed to receiving a home exercise program alone (control group).
The goal of this study is to determine the efficacy of electromechanical exoskeleton-assisted gait training on rehabilitation functional outcomes in patients with stroke undergoing therapy in an in-patient rehabilitation facility.
This trial is being conducted to determine if the CPWalker can be used as a gait training intervention for pediatric patients with gait impairments due to cerebral palsy
This is a single blind, sham controlled crossover trial that will evaluate the effectiveness of acute intermittent hypoxia therapy (AIH) combined with transcutaneous (non-invasive) spinal cord stimulation on gait and balance function for individuals after spinal cord injury.
The purpose of this study is to investigate changes in response to robotic gait training in individuals with a traumatic brain injury.