Active clinical trials for "Gait Disorders, Neurologic"

Parkinson's disease (PD) is a progressive neurological disorder characterized by motor and non-motor symptoms such as rigidity, bradykinesia, resting tremor, cognitive and autonomic dysfunctions, gait and balance difficulties. The impairment of gait, balance and cognitive performances is partially responsive to dopaminergic medications. This emphasizes the importance of non-pharmacological interventions for people with PD (pwPD). Intensive multidisciplinary motor and cognitive rehabilitation has been proposed as a complementary and effective treatment for managing pwPD. Several structural and physiological mechanisms have been suggested to underpin exercise-induced neuroplastic changes in PD, such as enhanced synaptic strength and preservation of dopamine neurons. To date, studies on brain changes induced by motor and cognitive exercises in pwPD have been small-scaled and uncontrolled. Identifying accessible and measurable biomarkers for monitoring the events induced by intensive motor and cognitive rehabilitation program would help in testing the treatment effectiveness and would allow personalization of rehabilitation strategies by predicting patients' responsiveness. Based on validated clinical assessments of intensive multidisciplinary rehabilitation treatment, the project will test the ability of a new set of biomarkers to evaluate rehabilitative outcomes in a cohort of people with PD.

While there are a number of prospective studies evaluating powered exoskeletons in SCI patients, to date, not a single well-designed, randomized clinical trial has been published. However, there is evidence for beneficial effects of over-ground exoskeleton therapy on walking function post-intervention from a meta-analysis on non-randomized, uncontrolled studies. Functional electrical stimulation (FES), on the other hand, is a common and established method for the rehabilitation of persons with SCI and has been demonstrated to be beneficial in, e.g., improving muscle force, power output and endurance. Combining FES and overground robotic therapy within the same therapy session could potentially merge and potentiate the effects of each separate treatment, making it a very powerful and efficient therapy method. Up to date, however, comparative studies evaluating benefits of this combined approach (i.e., powered exoskeleton and FES) to robotic therapy without FES are missing.

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.

Gait changes appear and become the main cause of disability, loss of independence, falls, fractures and reduced quality of life for patients with Parkinson Disease. Optimal gait management is complex and challenging. Some characteristics, such as gait variability, postural instability, and postural changes, continue to worsen over time despite optimal dopaminergic treatment, suggesting that additional interventions are needed. Given the physiology of gait and postural control in humans, spinal cord stimulation is a potential target for neuromodulatory approaches to gait and postural disorders. Repetitive transspinal magnetic stimulation ( rTSMS) has attracted a lot of attention, due to the possibility of modulating motor and sensory networks in a non-invasive way, activating directly the dorsal ascending pathways and projecting to the thalamic nuclei, cerebral cortex, and brainstem nuclei, thus stimulating descending motor tracts and interrupting aberrant oscillatory activity in corticobasal nuclei circuits. The combination of non-invasive neuromodulation with other therapies can enhance the effectiveness of rehabilitation, increasing plasticity and clinical efficacy, offering a greater and more sustained effect than either therapy alone.It's recommended that patients with PD perform a specific exercise for walking, such as treadmill training (tt), that imposes an external rhythm and concentration of attention on gait, acting as an external cue or marker, promoting a more stable gait, reducing gait variability and decreasing risk of falls. It is proposed, in this study, to develop a new treatment model through the integration of two promising and complementary approaches to improve gait disorders in PD: rTSMS and tt. Thus, the investigators idealized the realization of the first randomized, double-blind, placebo-controlled, parallel, phase III clinical trial that will evaluate the efficacy of tt associated with rTSMS in patients with PD.

There is debate regarding the efficiency of different dilutions of Botulin toxin type A (BTX-A) injections. Some authors believe that highly diluted BTX-A injections achieve greater neuromuscular blockade resulting in higher spasticity reduction. On the other hand, other researchers suggest that there is no difference in spasticity decrease if either high or low volume toxin is being injected. Studies on this subject lack either the design or the power of study was low. Therefore, there is no clear guideline for an optimal botulinum toxin dilution protocol. In an attempt to have a better understanding, a cross over study was designed. The material will be patients with spastic hemiparesis which will be treated with Botulin toxin at different dilutions. Gait analysis will be used for the evaluation of the Botulin toxin injection on gait improvement. To the best of our knowledge such a trial hasn't been performed yet.

The current study aims to investigate the effect of walking with the SAIRE smart walker on spatiotemporal parameters and gait kinematics in a population who suffer from difficulties during gait, and compare this to walking with a standard walker or no walking aid.

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.

Gait difficulties are common in Parkinson's disease (PD) and cause significant disability. No treatment is available for these symptoms. Spinal Cord Stimulation (SCS) has been found to improve gait, including freezing of gait, in a small number of PD patients. The mechanism of action is unclear and some patients are nonresponders. With this double-blind placebo-controlled proof of concept and feasibility imaging study, we aim to shed light on the mechanism of action of SCS and collect data to inform development of a scientifically sound clinical trial protocol. We also hope to identify imaging biomarkers at baseline that could be predictive of a favourable or a negative outcome of SCS and improve patient selection. Patients will be assessed with clinical rating scales and gait evaluations at baseline and 6 and 12 months after SCS. They will also receive serial 18F-FDG and ([18F]FEOBV) PET scans to assess the effects of SCS on cortical/subcortical activity and brain cholinergic function

Safe walking needs the older adult to anticipate and respond quickly to external demands and sudden environmental changes. The practice of complex and challenging situations of the usual daily walking is very important to prevent balance loss and falls in the elderly. Researchers reported that subjects trained in a virtual environment with enhanced feedback performed walking skills better than those trained with conventional methods. The C-Mill treadmill is an innovative device that was recently used for the training of impaired gait and balance. C-Mill treadmill uses virtual reality, augmented feedback, and force plate technology that provides the best solution for efficient functional movement therapy. Therefore, this study will evaluate the efficacy of gait training with a virtual reality treadmill on walking abilities in elderly people.