View clinical trials related to Gait Disorders, Neurologic.
Filter by:Video game-based training programs, in the following referred to as "exergames" are an innovative digital training approach to simultaneously train physical and cognitive functions and increase training motivation for various populations. Patients who are differently limited in their physical and cognitive performance due to a decline in functioning can profit from a motivating and combined physical-cognitive training approach. An interdisciplinary team of movement scientists, sports and training experts, as well as game and industrial designers developed an innovative and immersive video game-based training product for patients - the ExerCube training software licence. The exergame development focused on a user-centred process together with the target population. The ExerCube training software licence is an exergame training product that includes immersive mixed-reality training programs (or video games) for patients. Depending on the patient's training requirements, the therapists can choose from the training program repertoire. The patients control the training program (or video game) by specific (whole) body movements. To present the virtual training programs from the ExerCube training software licence in the physical environment, the ExerCube hardware and harness system is used to serve as a physical training room. It allows the virtual video game environment to be presented in the physical world. This summative usability study aims to assess the training system's safety, usability and validate the user experience. Primary end-users (defined as patients aged 18 and above) and secondary end-users (defined as sports scientists, training therapists or physiotherapists/occupational therapists with a focus on sports/training therapy) will test and review the system in different testing scenarios.
İntroduction The upper limb can be involved in children with cerebral palsy (CP), while the lower limb is more commonly affected. Little is known regarding the alterations in the upper limb kinematics after the orthopedic surgery of the lower extremity during gait. This study aimed to evaluate the differences in the upper limb kinematics in children with CP between preoperative and postoperative parameters.
To determine the effects of bilateral versus unilateral lower limb training on balance and gait parameters in stroke patients
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.
The aim of this study is to assess the safety and the feasibility of two versions of TWIICE Rise for exoskeleton-assisted ambulation in patients with a spinal cord injury. This study is done in two phases: The first phase evaluates the safety and feasibility of TWIICE Rise 0.0 with 5 patients over 6 sessions in clinic. The second phase is being conducted with TWIICE Rise 1.0. This version has potentially improved functionalities based on feedback from Phase 1. Safety and feasibility will be assessed with 10 patients over 24 sessions in different settings (clinic, home, and community environment).
The goal of this clinical trial is to compare the gait of patients with hemiplegia, with or without the use of insole splint. The main questions it aims to answer are: Does the insole splint improve the gait of these patients? Does any difference exist in the use of muscles? Participants will have to walk in the gait analysis' aisle with and without the insole splint, using wireless EMG device.
Variable Frequency Stimulation(VFS) is a stimulation pattern applied in Deep Brain Stimulation(DBS) therapy for Parkinson's disease(PD). Peking Union Medical College Hospital was the first centre conducting research on VFS. The studies in the past have resembled conclusion that VFS provides improvement not only in the major symptoms such as tremor and rigidity, but also in gait and balance disorder. However, the best programming strategy of VFS has not met agreement. The random-controlled double blinded crossover study is designed for participants who underwent DBS surgery in bilateral subthalamic nucleus for parkinson's disease. The investigators study several strategies on programming and observe the improvement of symptom to look for the best one. A 4-month follow-up is designed to observe a relatively long-term effectiveness of VFS. The study intends to gather more clinical evidence to guide further studies on VFS application.
The primary objective of this single-center, no-profit, longitudinal interventional randomized controlled, single-blind trial is to compare the effects of 2 different treadmill training treatments using C-Mill: the experimental one, endowed with augmented virtual reality (AVR) applications, versus the conventional one, the standard treadmill training in PD patients with gait and or balance disturbances. The main questions the study aims to answer are 1) Is the experimental treatment more effective than the conventional one? 2) Is it possible to identify predictive and indicative biomarkers of an outcome measure of rehabilitation using extracellular vesicles (cEVs) assessed by Raman spectroscopy? Participants will be randomized into two groups: the experimental group that will receive the experimental intervention, and the control group that will receive the conventional intervention. Both groups will train three times per week for 8 weeks, the first session starting from 25 minutes (25'). The experimental and the conventional treatments are planned to be progressive and will be individualized to the participant's level of performance. Clinical, neuropsychological, and instrumental variables will be collected at baseline (T0), at the end of the treatment (T1), and 3 months after the end of treatment (T2). At 6 months after the end of treatment (T3), a phone interview will be performed. Both within-group and between-group analyses will be conducted. Biosamples will be collected at baseline (T0) and at the end of treatment (T1).
Healthy subjects will be invited to fill out a questionnaire regarding falls and balance skills followed by normal walking trials on a treadmill at 9 different speeds (0.28-1.4 m/s). Key gait parameters for the normative database will be collected. During the perturbation trials, the subjects will walk at a constant speed (1.2 m/s). The treadmill belts are ac, - or decelerated during the perturbations according to three different perturbation algorithms with varying perturbation onset. Movements will be analyzed by 3D motion capture, force plates, surface electromyography and IMU sensors. All methods are non-invasive and commonly used in the field of biomechanics.
Glucose transporter deficiency syndrome type 1 (GLUT1DS) is a rare, genetically determined, neurometabolic disorder . It is estimated that about 90% of affected patients present various pathological gait patterns. Ataxic, spastic, ataxo-spastic, or dystonic walking are the main manifestations described to date. The kinematic gait analysis with inertial sensors represents a method that is easily applicable in clinical practice, with possible application in numerous neurological syndromes of the pediatric and adult age. Through the kinematic gait analysis, it will be possible to obtain an accurate characterization of the gait of patients with GLUT1DS. This will allow, in the first place, a better knowledge of locomotor parameters in this rare cohort of patients. Given that kinematic analysis through a wearable sensor is a method that can be easily integrated into daily clinical practice, the data obtained could become prognostic biomarkers and significant outcome measures of the disease (also in relation to possible improvements deriving from treatment with a ketogenic diet or in the context of future pharmacological trials).