11 Clinical Trials for Various Conditions
The purpose of this Phase I study is to conduct a pilot clinical trial using a mobile app-connected, wire-free surface electromyography (sEMG) system, called mGain, that provides biofeedback-based therapy in individuals with upper limb weakness due to neurologic injury or with upper limb amputation. Our overarching hypothesis is that the mGain wireless sEMG device and mobile therapeutic gaming environment will demonstrate improved adherence to therapy when compared to standard of care and will be feasible, acceptable, and usable in individuals with upper limb weakness or limb amputation. All participants will undertake four weeks of therapy. Conducting therapy five days a week for 30 minutes a day. In addition, participants will have an initial and final assessment visit at a study site, with each visit expected to last 1-2 hours.
The purpose of this research is to evaluate how people move about in different settings with different assistive devices or components, and to understand how people interact with different assistive technologies. Individuals that have limb weakness, limb paralysis, limb loss, and movement disorders are often provided assistive devices such as prostheses and orthoses to assist with mobility or use assistive technologies for purposes such as to regain muscle strength or retrain movements. It is important to understand the impact of these different assistive technologies on human movement for technology improvement and in preparation for commercialization. Because this research focuses on evaluating how different people move about in different settings with different assistive devices/components, there are different activities that may take place. These activities have been classified as (1) Movement Analysis in the Laboratory, (2) Movement Analysis Outside the Laboratory, (3) Usability Testing, and (4) Focus Groups. Each participant may or may not complete the same activities as the other participants. Each participant may or may not complete all of the activities. Participants may complete the activities more than once.
Functional Neurological Disorder (FND/ Conversion Disorder) is a highly prevalent and disabling neuropsychiatric condition. Motor FND symptoms include Functional Movement Disorders (FMD) and Functional Weakness and Psychogenic Nonepileptic Seizures (PNES).Though patients with FND present with a wide variety of symptoms, FMD, PNES, and functional weakness may be viewed as overlapping conditions lying along a phenotypic spectrum for a single disorder. Patients with FND frequently present with psychiatric symptoms, including depression, anxiety, Borderline Personality Disorder, and Post-Traumatic Stress Disorder, alongside their physical symptoms. To treat these symptoms, patients with FND are frequently enrolled in physical therapy and cognitive behavioral therapy, which are considered usual care for FND at our center. Developing a further understanding of treatment outcome, including biomarkers of clinical improvement and psychometric factors associated with treatment response, could inform future interventions and better tailor treatments to patients with specific FND symptom profiles. We hypothesize that treatment response will be associated with structural and functional alterations in salience network regions and that more adaptive neuropsychiatric profiles at baseline will predict a positive treatment outcome.
Functional Neurological Disorder (FND/ Conversion Disorder) is a highly prevalent and disabling neuropsychiatric condition. Motor FND symptoms include Nonepileptic Seizures, Functional Movement Disorders and Functional Weakness. Clinical research across these motor FND subtypes, including research studies from the candidate's laboratory, suggest that these populations share many clinical and phenotypic similarities that warrant increased research integration. Furthermore, despite the prevalence of motor FND, little is known about the underlying pathophysiology of this condition, which is a prerequisite for the development of biologically informed prognostic and treatment response biomarkers. Across 3 published neurobiologically focused articles, the candidate proposed a framework through which to conceptualize motor FND. It is suggested that motor FND develops in the context of structural and functional alterations in neurocircuits mediating emotion awareness/expression, bodily awareness, viscerosomatic processing and behavioral regulation. The overall goal of this project is to comprehensively investigate structural and functional magnetic resonance imaging (MRI) biomarkers of prognosis across motor FND. Multimodal structural and functional MRI techniques (including voxel-based morphometry, cortical thickness, resting-state functional connectivity and diffusion tensor imaging tractography) will be used to systemically probe brain-prognosis relationships. Novel aspects of this proposal include the study of the full spectrum of motor FND, consistent with a trans-diagnostic approach.
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 learn if wearable sensor data visualization on smartphones can improve the use of the stroke-affected limb during everyday activities. Chronic stroke survivors (\>12 months from onset) ages 18-80 years old with residual upper extremity motor impairments may be eligible to participate. The main question it aims to answer is: Does the mobile health (mHealth) intervention help to improve the use of the stroke-affected upper-limb during daily living? The study is designed so each participant serves as their own control. Researchers will compare information from the baseline, intervention, and retention time periods to see if visualizing the data on the smartphone impacts the participant's daily use of the arm. Participants will be asked to wear a set of wearable ring and wrist sensors and interact with a custom-designed smartphone app, aiming to increase the use of their stroke-affected limb during daily activities as much as possible. They will receive feedback from the app, communicate with study therapists, participate in goal setting, complete clinical assessments, and share about their experience using the system during a virtual interview.
The purpose of this study is to determine the effects of one week of knee-joint immobilization on muscle size, strength, neuromuscular function, and brain function. In addition, the effects of two different interventions (i.e., neuromuscular electrical stimulation and action observation/mental imagery) throughout immobilization will be determined. Following the immobilization period, participants that have lost strength will be rehabilitated with twice weekly resistance training sessions, and sex-based differences in rehabilitation timelines will be examined.
Patients that are on mechanical ventilators in medical intensive care units (MICU) have extremely weak leg muscles. Currently there is no treatment to prevent or reverse this weakness. Treatments with a thigh muscle stimulator, called an All Stim 2, can improve leg muscle strength and help patients regain leg function after knee surgery. The purpose of the present study is to determine if treatments with the All Stim 2 device can also improve leg muscle strength in patients on mechanical ventilation.
The investigators will determine if administration of HMB (hydroxymethylbutyrate) or EPA (eicosapentaenoic acid) will increase diaphragm and limb muscle strength for patients on breathing machines in an intensive care unit. The investigators will first measure the strength of the diaphragm and a limb muscle (the quadriceps)using magnetic stimulators to activate these muscles. Muscle size will be measured by using an ultrasound to measure diaphragm thickness and quadriceps thickness. The investigators will also perform a vastus lateralis muscle biopsy. Patients will then be randomized to receive either placebo (saline 30 ml every 12 hours via the GI tract, EPA (1000 mg given every 12 hours via the GI tract), HMB (1500 mg given every 12 hours via the GI tract), or the combination of EPA (1000 mg given every 12 hours via the GI tract) and HMB (1500 mg given every 12 hours via the GI tract). Drugs will be given for 10 days; at the end of this time (on day 11), strength measurements, ultrasound muscle size measurements, and the vastus lateralis biopsy will be repeated. On day 21 an additional followup set of diaphragm and quadriceps strength and size measurements will be made (the biopsy will not be repeated for this last set of measurements). Patients will be followed clinically and patient outcomes (mortality, duration of mechanical ventilation after study entry) will be recorded.
The purpose of this study is to identify new genes responsible for neuromuscular disorders and study muscle tissue of patient with known neuromuscular disease, as well as their family members. We are interested in recruiting many types of neuromuscular disease including; Duchenne muscular dystrophy (DMD), Becker muscular dystrophy (BMD), and limb-girdle muscle dystrophy (LGMD). There are still many patients diagnosed with muscular dystrophy with no causative gene implicated in their disease. Using molecular genetics to unravel basis of these neuromuscular disorders will lead to more accurate diagnosis/prognosis of these disorders which will lead to potential therapies.
This study evaluates the effects of robot-assisted therapy for adults more than 6 months after stroke on upper limb functioning. Half of the participants will receive robot-assisted therapy for the arm affected by stroke, and the other half will receive robot-assisted therapy plus training in how to use the weaker arm during every day activities.