93 Clinical Trials for Various Conditions
The purpose of this study is to evaluate a new virtual reality (VR)-based rehabilitation program designed to help individuals with traumatic brain injury (TBI) improve their walking abilities in real-world settings. By comparing immersive VR-assisted overground gait therapy to contemporary non-immersive, treadmill-based VR therapy (i.e., C-Mill), the investigators aim to determine its effectiveness in enhancing mobility and quality of life for TBI patients.
The purpose of this study is to determine the effects of real-time gait biofeedback delivered over a 6-week period on early markers of FastOA and conduct 6-week and 6-month follow-up assessments in anterior cruciate ligament reconstructed patients.
The purpose of this study is to investigate the implementation of a novel gait rehabilitation stimulus (G-EO System) that could advance current clinical practices. The goal is to establish the safety and feasibility of gait training using the G-EO System as well as investigating the impact on mobility, function, quality of life, and participatory outcomes. Research Design: We propose a single-blinded, randomized trial of electromechanically-assisted gait training using the G-EO System in patients with Parkinson's disease with gait disability. Specific Aim 1 will establish the safety and feasibility of gait training using the G-EO System. Specific Aim 2 will determine the efficacy of gait training using the G-EO System for improving mobility, function, and quality of life
In this research study, the investigators aim to test the usability and efficacy of the GaitBetter system for gait rehabilitation after stroke.
Achieving functional ambulation post stroke continues to be a challenge for stroke survivors, clinicians, and researchers. In the effort to enhance outcomes of motor training, cortical priming using brain stimulation has emerged as a promising adjuvant to conventional rehabilitation. This project focuses on the development of a long term gait rehabilitation protocol using brain stimulation to improve walking outcomes in people with stroke. The project will also aim to understand the neural mechanisms that are associated with response to the intervention.
The goal of this project is to determine the feasibility and optimal parameters of a novel, comprehensive approach to gait training in individuals with chronic stroke. The comprehensive approach includes biofeedback-based gait training and aerobic exercise intensity-based gait training.
This study will conduct a preliminary evaluation of and obtain user data on a novel game-based visual interface for stroke gait training. Study participants will complete one session comprising exposure to gait biofeedback systems in an order determined by randomization. Participants will be exposed to 2 types of biofeedback interfaces: * newly developed game-based interface (projector screen display) * traditional, non-game interface
The investigator plans to test the use of the Ekso Bionics® Gait Training (Ekso GT™) exoskeleton for gait training in MS patients. The device will solely be used in the clinic under direct supervision from a physical therapist. This is a small PI-initiated uncontrolled pilot study to gather safety and feasibility data on the exoskeleton in individuals with MS and walking impairment.
The population of older Veterans with non-traumatic lower limb amputation is growing. Following lower limb amputation, asymmetrical movements persist during walking and likely contribute to disabling sequelae including secondary pain conditions, poor gait efficiency, impaired physical function, and compromised skin integrity of the residual limb. This study seeks to address chronic gait asymmetry by evaluating the efficacy of two error-manipulation gait training programs to improve gait symmetry for Veterans with non-traumatic lower limb amputation. Additional this study will evaluate the potential of error-manipulation training programs to improve secondary measures of disability and residual limb skin health. Ultimately, this study aims to improve conventional prosthetic rehabilitation for Veterans with non-traumatic amputation through gait training programs based in motor learning principles, resulting in improved gait symmetry and lower incidence of long-term disability after non-traumatic lower limb amputation.
The logistic advantages and advanced training capabilities of the G-EO System, as well as the benefits reported in other populations, support this strategy as a potentially potent rehabilitation tool for restoring and maintaining function in progressive Multiple Sclerosis (MS). This approach represents a paradigm shifting opportunity for improving current clinical practices for patients with progressive MS. If successful, this project will provide initial evidence for increasing patient access to the G-EO System, and this could be accomplished through "regional technology centers" using a rural health-delivery approach. There are several novel aspects of the proposed trial: (1) the examination of a novel gait rehabilitation stimulus (G-EO System) that could alter current clinical practices; (2) the focus on patients with progressive MS who have gait impairment (i.e., those who have received minimal research attention), which was recently described as the greatest therapeutic challenge facing the MS community; and (3) a study design that accounts for standard therapy. Specific Aims: The investigators designed a single-blinded, randomized pilot trial of electromechanically-assisted gait training using the G-EO System in patients with progressive MS with gait disability (EDSS=4.0-7.5). Specific Aim 1 will establish the safety and feasibility of gait training using the G-EO System. Specific Aim 2 will determine the efficacy of gait training using the G-EO System for improving mobility, symptomatic, quality of life, and participatory outcomes.
Phase II of this study includes a pragmatic clinical trial which will take place at Northwest Rehabilitation Associates (NWRA) in Salem, OR to verify the efficacy of the system in a physical therapy clinic.
Deterioration in walking performance as a result of disease or simply as a result of aging is a serious threat to independence in older adults. In this project, the investigators propose an innovative visual stimulus, based on advanced mathematical and biological theories, with which older adults can walk in time to improve their walking. The investigators' goal is to apply this simple, cost-effective, and novel gait rehabilitation therapy across all populations who have difficulties walking, e.g. stroke patients, fallers or those who undergo joint replacement.
The objective of this research is to test a passive shoe to correct gait in individuals with asymmetric walking patterns. This will be done in a clinic and within their own home. Individuals with central nervous system damage, such as stroke, often have irregular walking patterns and have difficulty walking correctly. Recent research has shown that using a split-belt treadmill can create after-effects that temporarily correct the inefficient walking patterns. However, the corrected walking pattern does not efficiently transfer from the treadmill to walking over ground. The iStride, formerly known as the Gait Enhancing Mobile Shoe (GEMS), may allow a patient to practice walking in many different locations, such as their own home, which we hypothesize will result in a more permanent transfer of learned gait patterns. To enable long-term use, our proposed shoe design is passive and uses the wearer's natural forces exerted while walking to generate the necessary motions.
The aging Veteran population, together with high exposure to Agent Orange or other herbicides during military service, has made diseases such as Parkinson's disease (PD), currently affecting more than 80,000 Veterans, a major health issue in the Veterans' health system. Mobility and cognitive limitations are a common problem in PD and are associated with significant disability, increased fall risk, reduced quality of life, and increased caregiver burden. While less is known about its benefit on cognition, physical therapy has proven to be an effective treatment to mitigate mobility limitations, though the response to rehabilitation interventions is highly variable. The proposed research will inform the investigators' understanding of the impact of certain genetic profiles associated with learning impairments on motor and cognitive benefits in response to gait rehabilitation, and will provide an important foundation for more personalized and improved gait rehabilitation programs for different subgroups of PD patients.
Over four million stroke survivors currently living in the United States are unable to walk independently in the community. To increase the effectiveness of gait rehabilitation, it is critical to develop therapies that are based on an understanding of brain adaptations that occur after stroke. This project will be the first step towards the development of a novel therapeutic approach using brain stimulation to increase walking capacity in stroke survivors and understand the neural mechanisms that are associated with impairment and functional recovery.
The study is a prospective interventional study to assess the changes in corticospinal excitability and spinal reflex excitability of in response to rehabilitative strategies and protocols that are commonly used during physical therapy treatment of gait disorders among post-stroke subjects. As part of this protocol, 55 individuals with chronic stroke will be assigned to either Cohort 1 or Cohort 2, and will participate in 1-18 gait training sessions. If interested, study participants can also complete both study cohorts sequentially (with at least 3-weeks duration between switching from one cohort to the second). The study examines the effects among two cohorts of post stroke patients. Cohort 1 will participate in 18 sessions of fast treadmill walking plus Functional Electrical Stimulation (FastFES) and Cohort 2 will participate in 1-3 sessions of FastFES and fast walking without FES.
This pilot study will evaluate the feasibility and preliminary effectiveness of incorporating Extended Reality (XR) into the treatment of patients undergoing Lower Limb Rehabilitation (LLR) using the Vector Gait and Safety System. LLR requires repetitive motions over the span of weeks or months with the aim of restoring mobility. This duration of time poses challenges with motivation and increases the burden on the physical therapists. The use of XR in conjunction with conventional physical therapy could significantly increase motivation, along with providing therapists with new ways of tracking the patient's recovery. Pilot study results will be used to propose new and innovative approaches to physical recovery during inpatient rehabilitation, potentially increasing motivation, enhancing therapy participation, and reducing the overall time taken for recovery.
Physical therapists use dry static cupping for the treatment of many conditions, including spasticity for patients post-stroke. While research better describes the effects of dry static cupping for patients with orthopedic conditions, information is lacking on central conditions, such as stroke and resulting spasticity.
This study will test the ability of myoelectric interface for neurorehabilitation (MINT) training to improve walking function.
This interventional study evaluates the effects of an overground propulsion neuroprosthesis that delivers adaptive neurostimulation assistance to the paretic plantarflexors and dorsiflexors of people post-stroke. Individuals with chronic post-stroke hemiparesis will walk with and without the neuroprosthesis overground and on a treadmill. The goal of the study is to understand how adaptive neurostimulation delivered by the neuroprosthesis affects clinical and biomechanical measures of walking function in order to guide future rehabilitation approaches for restoring walking ability after stroke.
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.
This is a single-arm longitudinal study for children with cerebral palsy with gait impairments that involves robot-assisted gait training (RGT) and includes pre and post-data collection visits. The study aims to evaluate changes in muscle synergies in children with Cerebral Palsy (CP) in response to RGT. Additionally, the study aims to investigate the relationship between muscle synergies and the clinical outcomes of RGT.
The purpose of this study is to compare two interventions currently used to improve gait and lower limb function in individuals with chronic stroke (i.e., high-intensity gait training and high-intensity gait training with functional electrical stimulation (FES)) with novel interventions based on the coordinated activity of multiple muscles, known as muscle synergies. To this end, the researchers will recruit chronic stroke patients to participate in training protocols according to the currently used rehabilitation programs as well as novel rehabilitation programs that provide real time feedback of muscle synergies using multichannel FES and visual feedback.
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.
PoNS therapy is a rehabilitation program that uses the PoNS device in conjunction with individualized physical exercise. This is an outcome research open label observational interventional multi-center study investigating the relationship between subject's adherence to PoNS therapy and therapeutic outcomes.
Previous studies of the exosuit technology have culminated in strong evidence for the gait-restorative effects of soft robotic exosuits for patients post-stroke by means of substitution for lost function. The present study builds on this work by suggesting that an exosuit's immediate gait-restorative effects can be leveraged during high intensity gait training to produce long-lasting gait restoration. Current gait training efforts are focused on either quality or intensity. They focus on gait quality often by reducing the training intensity to allow patients to achieve a more normal gait. In contrast, efforts focused on training intensity push participants without focusing on the quality of their movements. These intervention paradigms generally fail to substantially impact community mobility. In this study, the investigators posit that exosuits can uniquely enable an integration of these paradigms (ie, high intensity gait training that promotes quality of movements). For this protocol, exosuits developed in collaboration with an industry partner, ReWalk™ Robotics will be used. To evaluate the effects of REAL gait training, the investigators will use clinical measures of motor and gait function, locomotor mechanics and energetics, and physiologic measures that may infer on motor learning. The spectrum of behavioral and physiologic data that we will collect will enable us to understand more comprehensively the gait-restorative effects of REAL. This study is a single-arm mechanistic clinical trial that will examine clinical and physiological factors that determine response to the intervention. This study will assist in informing best candidates and outcomes for future randomized controlled trials.
Previous studies of the exosuit technology have culminated in strong evidence for the gait-restorative effects of soft robotic exosuits for patients post-stroke by means of substitution for lost function. The present study builds on this work by suggesting that an exosuit's immediate gait-restorative effects can be leveraged during high intensity gait training to produce long-lasting gait restoration. Current gait training efforts are focused on either quality or intensity. They focus on gait quality often by reducing the training intensity to allow patients to achieve a more normal gait. In contrast, efforts focused on training intensity push participants without focusing on the quality of their movements. These intervention paradigms generally fail to substantially impact community mobility. In this study, the investigators posit that exosuits can uniquely enable an integration of these paradigms (ie, high intensity gait training that promotes quality of movements). For this protocol, exosuits developed in collaboration with an industry partner, ReWalk™ Robotics will be used. To evaluate the effects of REAL gait training, the investigators will use clinical measures of motor and gait function, locomotor mechanics and energetics, and physiologic measures that may infer on motor learning. The spectrum of behavioral and physiologic data that we will collect will enable us to understand more comprehensively the gait-restorative effects of REAL.
The purpose of this study is to identify neural muscle synergies of patients post-stroke and track them during an inpatient acute rehabilitation. To this end, the researchers will use an innovative approach based on the identification of large populations of motor units from recordings of surface high-density electromyography (HD-EMG).
This study consists of three phases that aim to develop an exercise intervention to promote maximal activation of ankle plantar flexors in the paretic lower extrimty (LE) in order to restore a more normalized gait pattern in chronic stroke survivors. The aim of the first phase is to determine if there are differences between standing on different levels of inclination on plantar flexion activation during forward movement of the contralateral LE in adults with chronic with stroke. The aim of second phase is to determine if there are differences between different percentages of weight bearing on the paretic LE on plantar flexion activation during forward movement of the contralateral LE in adults with chronic stroke. The aim of the third phase is to determine if there are differences between a 4-week plantar flexion training intervention and conventional physical therapy.
The long-term study goal is to develop a more engaging, motivating gait biofeedback methodologies specifically designed for post-stroke gait training. The current project aims to address fundamental questions regarding the optimal methodology to deliver AGRF biofeedback during gait, and the feasibility and preliminary efficacy of AGRF progression protocols for improved gait patterns and gait function. The study objectives are to (1) evaluate the immediate effects of biofeedback training methodology on gait biomechanics; and (2) evaluate the feasibility and short-term effects on gait performance of a real-time biofeedback protocol incorporating progression criteria (similar to those employed during clinical rehabilitative training).