View clinical trials related to Chronic Stroke.
Filter by:The purpose of this study is to examine the reflex excitability of the rectus femoris in individuals with and without post-stroke Stiff-Knee gait. We use electrical stimulation of the peripheral nerve innervating the rectus femoris for a well-controlled reflex stimulus. We are investigating whether reflex excitability of the rectus femoris correlates with gait kinematics.
Difficulty walking is common after a stroke. Although physical rehabilitation helps a little with the improvement of walking ability, recovery is usually incomplete. The purpose of this study is to explore how two different treadmill training approaches influence walking speed, symmetry, and balance in people with chronic severe stroke-related walking impairment. The two approaches involve either forward or backwards treadmill training. This study will look at changes in walking performance and balance, before and after training. This study may lead to more efficient methods for improving walking performance and balance after stroke.
Stroke is commonly associated with increased spasticity that affects patients' function and increased risk of fall. Interventional approaches have been used to decrease spasticity including pharmacological and non-pharmacological interventions. However, Limited research has examined non-pharmacological interventions such as neuromuscular electric stimulation (NMES) on spasticity and health outcomes in people with stroke. So, The primary purpose of this study is to establish a protocol for a randomized clinical trial to examine using NMES on spasticity, muscle strength, physical functions, and self-reported health outcomes in people with chronic stroke in Saudi Arabia. This randomized clinical trial will be double blinded for both participants and assessors to enroll 40 participants with chronic stroke to either interventional group or control shame group. The intervention will be 3 times a week for 4 weeks for both groups. Outcomes will include calf muscle spasticity, pretibial muscle strength, ankle range of motion, gait speed, balance, functional mobility, walking endurance, and self-reported health measures such as quality of life, physical activity, fatigue, and risk of fall. Independent t-test will be utilized to examine the effect of intervention on change score means for outcome measures. Using 4 weeks of NMES will provide information about its effect in improving spasticity, physical functions, and other self-reported health outcomes in people with chronic stroke when compared to control shame NMES. We assume this electrical stimulation will reduce leg muscle spasticity and improve muscle strength. Therefore, this study will help individuals with chronic stoke in improve walking function, balance, and quality of life.
Texas Biomedical Device Center (TxBDC) has developed an innovative strategy to enhance recovery of motor and sensory function after neurological injury termed targeted plasticity therapy (TPT). This technique uses brief pulses of vagus nerve stimulation to engage pro-plasticity neuromodulatory circuits during rehabilitation exercises. Preclinical findings demonstrate that VNS paired with rehabilitative training enhances recovery in multiple models of neurological injury, including stroke, spinal cord injury, intracerebral hemorrhage, and traumatic brain injury. Recovery is associated with neural plasticity in spared motor networks in the brain and spinal cord. Moreover, two initial studies and a recently completed Phase 3 clinical trial using a commercially available device demonstrates that paired VNS with rehabilitation is safe and improves motor recovery after stroke. The purpose of this study is to extend these findings and evaluate whether VNS delivered with the new device paired with rehabilitation represents a safe and feasible strategy to improve recovery of motor and sensory function in participants with stroke.
A single-site, interventional, single-arm trial to evaluate the safety and efficacy on functional mobility following Samsung GEMS-H (Gait Enhancing and Motivating System - Hip) device training in participants with sub-acute and chronic stroke.
Participants are seeking to unleash the full therapeutic potential of a newly developed, customizable and potentially commericializable 10-channel Functional Electrical Stimulation (FES) to rehabilitate the gait of chronic stroke survivors. Each subject will undergo 18-sessions (~1 month) FES training. Participants will utilize the theory of muscle synergies from motor neurosciences, which are defined as neural modules of motor control that coordinate the spatiotemporal activation patterns of multiple muscles, to guide our personal selections of muscles for FES. It is hypothesized that chronic stroke survivors will learn from FES stimulations, over several daily sessions, both by suppressing the original abnormal muscle synergies and by employing the normal muscle synergies as specified in the FES. It is also expected that the walk synergies of the paretic side of chronic stroke survivors should be more similar to healthy muscle synergies at the two post-training time points than before training.
Stroke can drastically impact the ability to walk and keep your balance. In addition people with chronic stroke feel social isolated, become less satisfied with their walking and lose confidence in their ability to move without falling. Ned new treatments are needed for walking and balance. Dancing is a fun, social activity that has similar benefits to traditional exercise. Another benefit of dancing is the use of music, which improves mood, increases motivation and can even improve motor performance. Finally, moving in synchrony with other people during dancing can make people feel connected. We believe that dance classes can benefit people with stroke, but few studies have been done. The objective of our project is to conduct a randomized controlled trial to test whether dance can improve balance and walking for people with chronic stroke. The investigators are also interested in whether dancing improves people's confidence in their ability to do activities without losing their balance (i.e. balance confidence), decreases their feelings of isolation and increases their quality of life.
Much recent interest was raised by the use of Action Observation Treatment (AOT) in stroke patients rehabilitation. AOT, well-grounded in neurophysiology, is an updated approach, based on mirror neuron system (MNS) used to rebuild motor function despite injuries by engaging the brain regions active during action execution in individuals with limited mobility. This project aims at identifying, for the first time in Italy, neurophysiological electroencephalographic (EEG) biomarkers able to predict rehabilitation outcomes and providing an innovative optimized AOT rehabilitation protocol for chronic Stroke outpatients. EEG will be recorded to identify the most effective stimuli, quantify changes/recovery, profile patients. Moreover, an innovative AOT home-based program will be implemented. The translational research results will ensure advances in the optimization and personalization of the rehabilitative process thus contributing to improve the quality of life of chronic stroke patients. Stroke is a leading cause of death and one of the greatest causes of long-term disability that interferes with a good quality of life. Nowadays the rehabilitation interventions are the major component of patient's care to achieve functional outcome. In the last few years, in order to improve Activity of Daily Living (ADL), new noninvasive strategies have emerged as rehabilitative treatments rather than traditional physical therapies. The Action Observation Treatment (AOT), supported by results collected through randomized controlled trials, is one of these. This new rehabilitation approach is based on the properties of the Mirror Neuron System (MNS; 11-13). The extensive research of the last 20 years on the human MNS (hMNS) showed its importance not only in action recognition but also in motor intentions and other social cognitive functions. Lastly, because recruited also in damage brain (18,19), the MNS is demonstrated to provide satisfactory rehabilitative outcomes. The AOT takes advantage of the opportunity to restore functions despite the patient's impairment and it seems to be a valid example of translational medicine from basic neuroscience to rehabilitation. To date, neurophysiological outcomes were never used for translational purposes aimed to the optimization of the therapy and no evidence, in Italy, related to the effectiveness of the home-based program were proposed.
Gait training in stroke is a complex process of motor learning although restoring patients ability to walk would not prepare the individual with the challenges faced in the real environment. The aim is not simply walking in controlled environment, but to achieve dynamic walking. Dynamic walking is the ability of an individual to adjust to the changing surfaces and terrains. thereby returning to achieve active participation in the community. Hence, recovery of walking ability is the primary goal when planning treatment for patients with stroke.
In this study, it is being investigated if the association between high frequency repetitive transcranial magnetic stimulation associated with motor physical therapy reduces spasticity, increases upper limb motor function, and quality of life of post-chronic stroke patients than motor physical therapy alone. For this purpose, patients included will be submitted to ten sessions with active or sham hf-rTMS followed by a protocol of physical therapy.