View clinical trials related to Gait, Hemiplegic.
Filter by:To determine the effects of motor imagery technique on lower limb function among stroke patient. To determine the effects of motor imagery technique on lower limb spasticity among stroke patients. To determine the effects of motor imagery technique on gait among stroke patients. To determine the effects of motor imagery technique on quality of life among stroke patients
Cerebral palsy (CP) is a non-progressive disturbance in the development of movement and posture that occurs in the prenatal or postnatal period, causing activity limitations. Most children and adolescents with CP experience limitations in their walking skills. Restrictions in the walking ability of children with CP are an important issue for both parents and healthcare professionals involved in their treatment. The evaluation of walking is of great importance in terms of determining the effectiveness of the physiotherapy program, shaping the program, planning orthopedic and surgical applications, and determining the effectiveness, especially in children with CP who have walking potential. In the literature, easy-to-use, valid and reliable observational gait analysis that can evaluate gait pathologies and clinical gait in children with CP are emphasized. These measurements are of great importance in clinical practice.The ability of backward walking gives the child a different task than normal, allowing the observation of body perception, trunk stability provided by anterior-posterior co-contractions, balance, correction and protective reactions.
In this research study, the investigators aim to test the usability and efficacy of the GaitBetter system for gait rehabilitation after stroke.
When people walk, their ankle joints help to hold them upright and move them forward. Ankle braces are often given to people who have had a stroke to help their ankle joints work properly. The investigators have developed a method to design and make a special type of ankle brace that allows the investigators to control every characteristic of the ankle brace, allowing the investigators to customize the ankle brace to fit and function just the way the investigators want it to. The investigators think that ankle braces customized to meet the needs of each individual person will help the participants walk better. The investigators have also developed a prescription model that tells the investigators how to customize these ankle braces to address different levels of two common impairments experienced by people post stroke -decreased ability to move the ankle joint and weakened calf muscles. The purpose of this study is to test the prescription model to see if wearing the ankle brace customized based on the prescription model improves people's ability to walk. To accomplish this goal, the investigators will first measure each person's ability to move his/her ankle joint and the strength of his/her calf muscles. The investigators will put this information in to the prescription model to determine how to customize the ankle brace for each person. The investigators will then use the method developed to make the customized ankle brace. Finally, the investigators will measure how each person walks in the ankle brace customized just for the participants. This study will allow the investigators to validate and/or refine the prescription model and teach the investigators how persons post-stroke adapt to walking in ankle braces with different characteristics.
Despite current walking rehabilitation strategies, the majority of stroke survivors are unable to walking independently in the community and remain at increased risk of falls. Backward treadmill training is a novel training approach used by elite athletes to enhance speed, agility, and balance; however, it is currently unknown how this exercise interacts with the central nervous system or if it could benefit stroke survivors with residual walking impairment. Knowledge gained from this study will likely lead to more effective walking rehabilitation strategies in stroke and related disorders.
A variety of rehabilitation techniques focused on improving disability after stroke have shown significant changes on walking speed, and endurance. Also, the administration of combined techniques showed better results. Previous studies have suggested that embedding behavioral strategies in neurorehabilitation protocols can enhance patient's adherence and participation outside the clinical setting. The addition of a group of behavioral strategies called Transfer Package (TP) has been widely used in motor training protocol (e.g. Constraint-Induced Movement Therapy). The TP has shown to enhance the effects of treatment 2.4 times when compared to motor training alone. However, the effect of TP when combined with robotic gait training remains unexplored. In this study our goal is to combine the TP with robotic gait training. The hypothesis is that using the TP in combination with robotic gait training will enhance the outcome of robotic gait training alone and will induce long term transference and retention of the motor skills observed after treatment. More importantly, this experimental intervention is more meaningful to the patient and can be more easily implemented on the clinical setting. The aims of this study are (1) to assess transfer and long-term retention of walking and balance skills after robotic treadmill gait training combined with the TP, (2) to understand participants' acceptability and perceptions of the TP as a tool to enhance transfer of skills to real-world situations, and (3) to examine the feasibility of these combined intervention to improve walking and balance after stroke.
Participants are being asked to participate in a research study conducted by Shih-Chiao Tseng, PT, Ph.D. at Texas Woman's University. This research study is to determine whether low-intensive brain stimulation can enhance learning of a leg movement task. The investigators also want to know if brain stimulation can improve the nerve function and walking performance. Our goal is to understand any relationship between brain stimulation and overall movement control improvement. Participants have been invited to join this research if they have had a stroke before or they are healthy adults aged 21 years or older. Research evidence shows stroke can induce permanent brain damage and therefore may cause a person to have trouble learning a new task. This in turn may significantly impact the recovery of motor function in stroke survivors. In addition, the investigators also want to know how a healthy person learns this new leg task and see if her/his learning pattern differs from a stroke survivor. This study comprises two phases: Phase I study investigates short-term effects of brain stimulation on leg skill learning and only requires two visits to TWU. The total time commitment for Phase I study will be about 6.5 hours, 3.5 hours on the first visit and three hours on the second visit; Phase II study is an expanded version of Phase I study to investigate long-term effects of brain stimulation on leg skill learning and requires to complete 12 visits of exercise training paired with brain stimulation over a four-week period and additional one visit for follow-up test. The total time commitment for Phase II study will be about 20 hours, a total of 18 hours for 12 exercise training sessions and two hours for a follow-up test. The investigators hypothesize that people with chronic stroke will show a slower rate of acquiring this leg skill as compared to healthy adults. The investigators also hypothesize that co-applying brain stimulation with 12 sessions of exercise training will enhance skill learning of this leg task for people with chronic stroke and this 12-session exercise program may exert beneficial influences on the nerve function and leg muscle activation, and consequentially improve motor control for walking.
The objective of this research is to investigate the feasibility of delivering gait treatment using the Moterum iStride Solution™ to individuals with hemiparetic gait impairments using a telemedicine modality, the Moterum Digital Platform.
The main hypothesis of the present study is that a safer knee joint is likely to encourage post stroke patients at an early stage to rely on their hemiparetic leg and transfer their weight onto it while walking. The main purpose of the present work is to assess the feasibility of FES-induced muscular control of the hemiplegic knee joint in order to improve stance phase support symmetry recovery in individuals with post stroke hemiplegia. Functional electrical stimulation (FES) is delivered to the quadriceps and hamstrings of the paretic limb based on the real-time estimation of the knee angle and support phase.
Approximately 20% of stroke survivors have difficulties to dorsiflex the ankle and clear the ground during walking. This impairment, termed as "foot drop", is caused by an association of weak dorsiflexors and increased spasticity and stiffness of the plantar-flexors. As a consequence, walking performances are reduced and energy cost of walking is deteriorated. This may increase performance fatigability, as the locomotion will be realized at a higher percentage of the subjects' capacities. In order to overcome these issues, different treatments are proposed. One of the most conventional solutions are the use of ankle foot orthosis (AFO) and it is the most commonly prescribed device used to compensate for "foot drop". There is a very large choice of AFO on the market which can be proposed to patients with foot drop. The aim of this study is thus to assess the mechanical effects of using a manufactured carbon AFO in by comparison to a custom-made thermo-plastic AFO on walking capacity (distance and energy cost), fatigue and "foot drop" control throughout the gait phase in patients with hemiparetic stroke.