46 Clinical Trials for Various Conditions
Recovery of arm and hand motor control is critical for independence and quality of life following incomplete spinal cord injury (iSCI). Blood flow-restricted resistance exercise (BFRE) has emerged as a potential treatment addressing this need, but treatment guidelines and research reporting effectiveness are sparse. The purpose of this work is to provide case reports of people with cervical iSCI who use BFRE supplemented by electrical stimulation (ES) to increase the strength and functional use of selected upper extremity muscles.
The purpose of this research is to test the effectiveness of a new therapy, called Brain-Computer Interface (BCI)-Transcutaneous Spinal Cord Stimulation (TSCS), for improving walking in people with an incomplete spinal cord injury (SCI).
The purpose of this study is to determine if playing a virtual reality walking game can help improve neuropathic pain in adults with incomplete spinal cord injury.
Aim 1: Determine the safety and feasibility of administration of TSCS to children in a clinical setting. Participants will be randomly assigned to experimental (TSCS) or control (sham stimulation) groups. Both groups will receive eight-weeks of individualized gait training. We will measure adverse events, including pain and skin irritation, to determine safety as the primary outcome. Hypothesis 1: Administration of TSCS to children in a clinical setting will be safe based on similar safety outcomes as sham TSCS. Hypothesis 2: TSCS is feasible based on compliance to session interventions and long-term adherence to the protocol. Additionally, we will collect data on effort during sessions of both participant and therapist. We anticipate that the participants will report less effort in the experimental condition, as compared to the control and therapists will report equal effort across conditions. Aim 2: Determine the neurophysiologic impact of TSCS within a single session. We hypothesize that participants will demonstrate increased volitional muscle activity and strength with TSCS as compared to sham stimulation. This will be assessed by surface EMG and hand-held dynamometry of the dominant-side quadriceps muscle during maximum volitional contraction (MVC), across multiple time points. Changes in EMG activity will indicate change in central excitability in response to stimulation. Aim 3: Exploratory measurement of TSCS and gait training on walking function. We hypothesize that concurrent TSCS and gait training will augment walking function in children with iSCI, as compared to gait training with sham stimulation. In addition to outcomes defined above, participants will be assessed with clinically relevant outcome measures, to include the Timed Up and Go, 10-Meter Walk Test, Walking Index for Spinal Cord Injury II, and 6-Minute Walk Test. Data collected as part of this aim will elucidate trends in responder qualities and timeline of changes to inform future studies.
The purpose of this study is to examine the relationship between common clinical assessments and measurements of the function of brain-spinal cord-muscle connections, and to examine the effects of training a brain-spinal cord-muscle response in individuals with incomplete spinal cord injury. A transcranial magnetic stimulator (TMS) is used for examining brain-to-muscle pathways. This stimulator produces a magnetic field for a very short period of time and indirectly stimulates brain cells with little or no discomfort. The target muscle is the wrist extensor (extensor carpi radialis) muscle that bends the wrist back. It is hypothesized that training the wrist extensor muscle response to transcranial magnetic stimulation will increase the strength of the brain-to-muscle pathway, which will improve the ability to move the arm. It is hoped that the results of this training study will help in developing therapy strategies for individuals, promoting better understanding of clinical assessments, and understanding treatments that aim to improve function recovery in people with spinal cord injury (SCI). This study requires 30 visits, and each visit will last approximately 1.5 hours.
The purpose of the study is to investigate the effects of a novel therapeutic approach with transcutaneous spinal direct current stimulation (tsDCS) to promote functional recovery and spasticity in chronic spinal cord injury (SCI).
The primary goal of the proposed clinical trial is to investigate the combined effects of walking training and monoaminergic agents (SSRIs and TIZ) on motor function of individuals in sub-acute (2-7 mo) human motor incomplete Spinal Cord Injury (SCI), with a primary emphasis on improvement in locomotor capability. We hypothesize that the use of these drugs applied early following SCI may facilitate independent stepping ability, and its combination with intensive stepping training will result in improved locomotor recovery following incomplete SCI. Loss of descending control via norepinephrine inputs following spinal cord injury can impair normal sensorimotor function through depressing motor excitability and impairing walking capacity. Replacing these inputs with drugs can alter the excitability and assist with reorganization of locomotor circuits. Assessment of single-dose administration of these agents has been tested in patients with motor incomplete spinal cord injury; only limited changes in walking performance have been noted. The resultant onset of weakness and increase in involuntary reflexes following motor incomplete SCI may partly be a result of damage to descending pathways to the spinal cord that control the release of serotonin. In models of SCI, for example, application of agents that simulate serotonin has been shown to change voluntary motor behaviors, including improvement of walking recovery. In humans following neurological injury, the effects of 5HT agents are unclear. Few previous reports indicate improved motor function following administration of agents which enhance the available serotonin in the brain, although some data suggests that increased serotonin may be beneficial. In this application, we propose to study the effects of clinically used agents that increase or decrease intrinsic serotonin activity in the brain on strength and walking ability following human motor incomplete SCI. Using detailed electrophysiological recordings, and biomechanical and behavioral measures, we will determine the effects of single or chronic doses of these drugs on voluntary and involuntary motor behaviors during clinical measures and walking measures. The novelty of this proposed research is the expectation that agents that increase serotonin activity may increase abnormal reflexes in SCI, but simultaneously help to facilitate motor and walking recovery. Despite potential improvements in voluntary function, the use of pharmacological agents that may enhance spastic motor behaviors following SCI is in marked contrast to the way in which drugs are typically used in the clinical setting.
The purpose of this study is to determine the efficacy, safety, and tolerability of treatment with dalfampridine in combination with locomotor training in persons with chronic, motor incomplete SCI.
The purpose of this study is to determine whether exercising (walking) at different intensities increases levels of factors in the blood and saliva that are known to impact neuroplasticity (how the connections in the spinal cord and brain can change) and if these levels are changed by pairing exercise with a single dose of commonly used prescription drugs or by your mood.
Many people with spinal cord injury (SCI) hold some ability to move their leg muscles, and are therefore considered to demonstrate a motor incomplete injury. After such a spinal cord injury, individuals are able to walk less both in their home and in their community. De-conditioning, or a lack of endurance and fitness also occurs. Several methods are available to try to improve walking ability and the fitness of persons with motor incomplete spinal cord injury. This study examines two of these methods. The first is the use of robotically assisted body-weight supported walking using a device called the Lokomat. The second is aquatic or pool-based exercise. The investigators are researching the impact of these two techniques on walking ability and fitness in people who experienced motor incomplete spinal cord injury for at least 12 months.
The purpose of this study is to determine if tetraplegic individuals with incomplete spinal cord injury (SCI) who remain unable to move their arms normally 1 year after their SCIs are able to sense and move the affected arm(s) better after 10-13 weeks of treatment with a new robotic therapy device. The hypothesis is that using the AMES device on the arm(s) of chronic tetraplegic subjects with incomplete SCI will result in improved strength, sensation, and functional movement in treated limb(s).
The purpose of this study is to collect data comparing two means of providing locomotor training: manual and robotic and the possible differential effects it may have on walking ability for persons with spinal cord injury (SCI).
The goal of this study is to clarify mechanisms of acute intermittent hypoxia and to examine the effect on lower limb function in persons with chronic, incomplete spinal cord injury.
For many people with spinal cord injury (SCI), the goal of walking is a high priority. There are many approaches available to restore walking function after SCI; however, these approaches often involve extensive rehabilitation training and access to facilities, qualified staff, and advanced technology that make practicing walking at home difficult. For this reason, developing training approaches that could be easily performed in the home would be of great value. In addition, non-invasive spinal stimulation has the potential to increase the effectiveness of communication between the brain and spinal cord. Combining motor skill training (MST) with transcutaneous spinal stimulation (TSS) may further enhance the restoration of function in persons with SCI. Therefore, the purpose of this study is to determine if moderate-intensity, MST can improve walking-related outcomes among persons with SCI and to determine if the addition of non-invasive TSS will result in greater improvements in function compared to training alone.
The goal of this study is to examine the effect of repetitive acute intermittent hypoxia on motor learning abilities in able-bodied individuals for subsequent study in individuals with incomplete spinal cord injury.
Robotic therapies aim to improve limb function in individuals with neurological injury. Modulation of robotic assistance in many of these therapies is achieved by measuring the extant volitional strength of limb muscles. However, current sensing techniques, such as electromyography, are often unable to correctly measure the voluntary strength of a targeted muscle. The difficulty is due to their inability to remove ambiguity caused by interference from activities of neighboring muscles. These discrepancies in the measurement can cause the robot to provide inadequate assistance or over-assistance. Improper robotic assistance slows function recovery, and can potentially lead to falls during robot-assisted walking. An ultrasound imaging approach is an alternative voluntary strength detection methodology, which can allow direct visualization and measurement of muscle contraction activities. The aim is to formulate an electromyography-ultrasound imaging-based technique to sense residual voluntary strength in ankle muscles for individuals with neuromuscular disorders. The estimated voluntary strength will be involved in the advanced controller's design of robotic rehabilitative devices, including powered ankle exoskeleton and functional electrical stimulation system. It is hypothesized that the ankle joint voluntary strength will be estimated more accurately by using the proposed electromyography-ultrasound imaging-based technique. And this will help the robotic rehabilitative devices achieve a more adaptive and efficient assistance control, and maximize the ankle joint rehabilitation training benefits.
This study evaluates a remotely supervised, home-based therapeutic program to improve upper-limb voluntary movement in adults with tetraplegia caused by incomplete spinal cord injury (iSCI).
Spinal cord injury (SCI) affects \~42,000 Veterans. The VA provides the single largest network of SCI care in the nation. The lifetime financial burden of SCI can exceed $3 million. A major cost of SCI is impaired mobility. Limited mobility contributes to decreased ability to work, increased care requirements, secondary injury, depression, bone mineral density loss, diabetes, and decreased cardiovascular health. Among ambulatory individuals with iSCI, residual balance deficits are common and are strongly correlated with both functional walking ability and participation in walking activities. The development of effective rehabilitation tools to improve dynamic balance would substantially improve quality of life for Veterans living with iSCI. Improving mobility through interventions that enhance dynamic balance would positively impact health, independence, and the ability to integrate into social, intellectual, and occupational environments.
The purpose of this study is to further establish safety and efficacy of the BQ EMF treatment of chronic SCI subjects who demonstrate stability in The Graded and Redefined Assessment of Strength, Sensibility and Prehension (GRASSP) strength score following a one-month physical therapy run-in period.
Background: - Cerebral palsy (CP) is the most common motor disorder in children. CP often causes crouch gait, an abnormal way of walking. Knee crouch has many causes, so no single device or approach works best for everybody. This study s adjustable brace provides many types of walking assistance. Researchers will evaluate brace options to find the best solution for each participant, and whether one solution works best for the group. Objective: - To evaluate a new brace to improve crouch gait in children with CP. Eligibility: * Children 5 17 years old with CP. * Healthy volunteers 5 17 years old. Design: * All participants will be screened with medical history and physical exam. * Healthy volunteers will have 1 visit. They will do motion analysis, EMG, and EEG described below. * Participants with CP will have 6 visits. * Visit 1: \<TAB\>1. Motion analysis: Balls will be taped to participants skin. This helps cameras follow their movement. \<TAB\>2. EMG: Metal discs will be taped to participants skin. They measure electrical muscle activity. \<TAB\>3. Participants knee movement will be tested. \<TAB\>4. Participants will walk 50 meters. \<TAB\>5. Participants legs will be cast to make custom braces. * Visit 2: * Participants will wear their new braces and have them adjusted. * Steps 1 3 will be repeated. * EEG: Small metal discs will be placed on the participants scalp. They record brain waves. * Participants will have electrical stimulation of their knees and practice extending them. * Participants will take several walks with the braces in different settings. * Visits 3 5: participants will repeat the walking and some other steps from visit 2. * Visit 6 will repeat visit 2.
The purpose of this study is: (1) to establish assessment techniques (in our laboratory) to identify the functional integrity of long spinal tracts associated with adaptive walking recovery post-spinal cord injury and (2) to preliminary investigate locomotor outcomes associated with an adaptive locomotor training approach post-spinal cord injury.
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.
Background: People with cerebral palsy, spina bifida, muscular dystrophy, or spinal cord injury often have muscle weakness and problems controlling how their legs move. This can affect how they walk. The NIH has designed a robotic device (exoskeleton) that can be worn on the legs while walking. The wearable robot offers a new form of gait training. Objective: To learn whether a robotic device worn on the legs can improve walking ability in those with a gait disorder. Eligibility: People aged 3 to 17 years with a gait disorder involving the knee joint. Design: Participants will be screened. They will have a physical exam. Their walking ability will be tested. Participants will have markers taped on their body; they will walk while cameras record their movements. They will undergo other tests of their motor function and muscle strength. The study will be split into three 12-week phases. During 1 phase, participants will continue with their standard therapy. During another phase, participants will work with the exoskeleton in a lab setting. Their legs will be scanned to create an exoskeleton with a customized fit. The exoskeleton operates in different modes: in exercise mode, it applies force that makes it difficult to take steps; in assistance mode, it applies force meant to aid walking; in combination mode, it alternates between these two approaches. During the third phase, participants may take the exoskeleton home. They will walk in the device at least 1 hour per day, 5 days per week, for 12 weeks. Participants walking ability will be retested after each phase....
Neuromuscular electrical stimulation (NMES) remains as one of the effective rehabilitation modalities for addressing recovery of neuromuscular function after a spinal cord injury (SCI). To achieve optimal effects, the NMES interventions that involve or promote voluntary efforts from SCI participants are preferred. However, these interventions are limited by the fact that the active monitoring of voluntary effort, particularly at the stimulated muscle level is unattainable. The objective of the proposed study is to develop SMARTq (Stimulated Muscle Assessment in Real-Time). This novel system will provide a quasi real-time assessment of intrinsic neuromuscular responses of a stimulated muscle during NMES. Specifically, the proposed system will consist of our novel algorithms interfaced with the EMG data acquisition hardware to process the EMG data recorded from a stimulated muscle in real-time during NMES. The term 'quasi' is used to account for the processing delay of approximately 1 to 2 seconds that may potentially occur. The proposed system will be developed and validated using the data collected from the able-bodied (AB) as well as individuals with incomplete SCI (iSCI). The applicability of the system will be evaluated on individuals with complete SCI (cSCI). Our central hypothesis is that the real-time tracking of neuromuscular responses during a train of NMES will provide valuable information on inherent neuromuscular changes, volitional participation, and neuromuscular recovery. The significance of the proposed study is that, if successful, it will deliver a highly novel system which can allow researchers and clinicians to - 1) evaluate the direct electrophysiological effects of varied combination of NMES on a stimulated muscle in real-time; 2) quantify, track and manipulate the levels of voluntary efforts or volitional drive 'on-fly' during NMES for extracting optimal benefits; 3) track the neuromuscular recovery of the stimulated muscle, particularly for cSCI populations, when any functional changes have not been observed yet; and 4) directly observe the neuromuscular fatigue derived from the electrophysiological data at the stimulated muscle. These are highly significant opportunities that can allow the clinicians and researchers to transform the current as well as future NMES interventions into highly effective training modalities as each intervention will be operated at an individual's neuromuscular level.
This pilot study will investigate the effects of transcutaneous direct current stimulation (tsDCS) on walking function in individuals with incomplete spinal cord injury. Following rehabilitation, individuals with ISCI often demonstrate improved walking function, but continue to have serious impairments that limit mobility, community participation and quality of life. Adjuvants to rehabilitation that increase spinal excitation during training may enhance its effectiveness. tsDCS is a non-invasive neuromodulation approach that uses a mild electrical current, applied over the skin of the low back, to alter the membrane potential of spinal neurons. tsDCS will be applied during locomotor training, a well-established rehabilitation strategy that promotes walking recovery. Locomotor training emphasizes repetitive and task-specific practice of coordinated walking, often with therapist assistance or cueing to promote high quality movement patterns. The study team will explore if tsDCS combined with locomotor training increases spinal excitation and thereby improves the effectiveness of walking rehabilitation.
The purpose of this study is to develop an algorithmic-based evaluation and treatment approach for wearable robotic exoskeleton (WRE) gait training for patients with neurological conditions.
People with cerebral palsy (CP), muscular dystrophy (MD), spina bifida, or spinal cord injury often have muscle weakness, and problems moving their arms and legs. The NIH designed a new brace device, called an exoskeleton, that is worn on the legs and helps people walk. This study is investigating new ways the exoskeleton can be used in multiple settings while performing different walking or movement tasks, which we call ubiquitous use. For example, we will ask you to walk on a treadmill at different speeds, walk up and down a ramp, or walk through an obstacle course. Optionally, the exoskeletons may also use functional electrical stimulation (FES), a system that sends electrical pulses to the muscle to help it move the limb.
The goal of this clinical trial is to determine whether people with paralysis due to a spinal cord injury can benefit from breathing short intermittent bouts of air with low oxygen (O2) combined with slightly higher levels of carbon dioxide (CO2), interspaced by breathing room air. The technical name for this therapeutic air mixture is 'acute intermittent hypercapnic-hypoxia,' abbreviated as AIHH. Following exposure to the gas mixture, participants will receive non-invasive electrical stimulation to the spinal cord paired with specific and targeted exercise training. The main question this trial aims to answer is: Can the therapeutic application of AIHH, combined with non-invasive electrical stimulation to the spinal cord plus exercise training, increase the strength of muscles involved in breathing and hand function in people with paralysis due to a spinal cord injury? Participants will be asked to attend a minimum of five study visits, each separated by at least a week. During these visits, participants will be required to: * Answer basic questions about their health * Receive exposure to the therapeutic air mixture (AIHH) * Undergo non-invasive spinal electrical stimulation * Complete functional breathing and arm strength testing * Undergo a single blood draw * Provide a saliva sample Researchers will compare the results of individuals without a spinal cord injury to those of individuals with a spinal cord injury to determine if the effects are similar.
Accumulating evidence suggests that repeatedly breathing low oxygen levels for brief periods (termed intermittent hypoxia) is a safe and effective treatment strategy to promote meaningful functional recovery in persons with chronic spinal cord injury (SCI). The goal of the study is to understand the mechanisms by which intermittent hypoxia enhances motor function and spinal plasticity (ability of the nervous system to strengthen neural pathways based on new experiences) following SCI.
The purpose of this study is to determine how the nervous system controlling leg muscles is altered following spinal cord injury and how they may be affected by brief periods of low oxygen inhalation over time. The investigators hypothesize: * Acute intermittent hypoxia (AIH) exposure will increase maximum voluntary leg strength in persons with incomplete cervical spinal cord injury (SCI) * AIH exposure will increase multijoint reflex excitability of leg muscles in persons with incomplete cervical SCI * AIH exposure will increase walking performance in persons with incomplete cervical SCI