Effect of Overground Gait Training Using a Torgue-Assisted Exoskeletal Wearable Device on Ambulatory Function in Subacute Stroke Patients

Summary

Stroke is reported as one of leading causes of adult disability. Recent advances in in revascularization therapy have had a significant impact on clinical and functional outcomes in patients with ischemic stroke. However, revascularization therapy can only be applied to a limited population of patients. Many stroke survivors are still suffering from significant motor impairments and gait disturbance. The recovery of the ambulatory function in stroke patients is one of the most important goals of their rehabilitation and a critical factor influencing the patient's home and social activities.

One of the most frequently occurring disabilities in stroke patients is the ambulatory impairment. Ambulation is a key factor in performing the activities of daily living. About 80% of stroke patients showed the ambulatory impairment in acute stroke phase, and many stroke patients were not fully regain the ambulatory function although the ambulatory function was rapidly restored within 6 months after onset. Because the ambulatory function is the most important relating factor on activities of daily living and quality of life, one of the most important goals of stroke rehabilitation can be the achievement of independent gait. The conventional gait rehabilitation has been performed as a 1:1 training session between the therapist and a stroke patient. This gait rehabilitation can make a significant burden on the therapist and restriction of the rehabilitation time. The limited number of rehabilitation facilities and therapists for the number of stroke patients requiring rehabilitation means that many stroke patients might receive not enough gait rehabilitation.

To overcome these issues, a lot of studies have been conducted to develop rehabilitation robots for effective gait training. Nonetheless, in previous studies regarding robot-assisted gait rehabilitation, the stroke patients varied in terms of their baseline gait ability, functional level, and onset of stroke. In addition, robots for gait rehabilitation robots were various such as exoskeletal, end effector and overground gait types with varied frequency, duration and intensity of the gait rehabilitation training. Such heterogeneity inevitably limited the quality of the studies as well as the application in clinical practice. For an adequate robot-assisted gait rehabilitation in clinical practice, the functional level and the phase of stroke patients should be taken into consideration. In addition, for the gait rehabilitation robots to be applied effectively, it also should be considered to have a defined indication as well as a protocol including frequency, duration and intensity of robot-assisted gait rehabilitation.

A robot could have efficiency in assisting patients to practice correct and repetitive movements with the adequate quantity and intensity of training. The robot-assisted gait rehabilitation using a treadmill-based robot for location control has increased in stroke rehabilitation. However, the conditions of treadmill gait differ from those of actual overground gait so that the increase in gait ability after treadmill-based training might not directly translate into the improvement of overground gait. In addition, a drawback of such gait training using a robot for location control could be the difficulty in adapting the robotic movements to the patient's efforts to move the muscles and to the passive characteristics of the musculoskeletal system. On the contrary, overground gait training has been reported to improve the gait speed and endurance to a greater degree than treadmill gait training in stroke patients.

Recently, overground gait training using an exoskeletal wearable robot has been proposed to promote the activation of the nervous system by inducing an active participation from the patient who performed active balance control, weight shift, and muscle activation. In the previous study, the effect of gait training using an exoskeletal robot was reported in patients with incomplete paraplegia caused by spinal cord injury. Nevertheless, lack of studies have reported on the effect of gait training using an exoskeletal wearable robot in subacute stroke patients.

Conditions

• Subacute Stroke

Interventions

OTHER

Robot-assisted Training

The gait training in this study uses an exoskeletal wearable robot (Product name: ANGEL LEGS M20, Angel robotics, Co., Ltd.) consisting of a wearable part, a hip or knee joint gear providing the auxiliary force, and a controller backpack. This product is a powered orthopedic device for gait rehabilitation and treatment such as the lower limb muscle reconstruction and joint motion recovery in patients or handicapped individuals. The product consists of a power part, a controller part and a gear part, while the device is powered by an electric motor and the device motion induces the gait posture to support the lower limbs and allow the gait training to be performed.

OTHER

Conventional Therapy

The conventional gait rehabilitation has been performed as a 1:1 training session between the therapist and a stroke patient.

Sponsors & Collaborators

• Yonsei University

  lead OTHER

Principal Investigators

• Deogyoung Kim · Department and Research Institute of Rehabilitation Medicine Yonsei University College of Medicine

Study Design

Allocation

RANDOMIZED

Purpose

TREATMENT

Masking

SINGLE

Model

PARALLEL

Eligibility

Min Age

19 Years

Sex

ALL

Healthy Volunteers

No

Timeline & Regulatory

Start

2021-12-31

Primary Completion

2023-11-30

Completion

2023-12-31

Countries

• South Korea

Study Locations