Virtual Reality Exercise for Stroke Rehabilitation in Inpatients Who Are Unable to Stand

Not Applicable

Completed

• Conditions: Stroke
• Interventions: Other: control; Other: virtual reality training

• Registration Number: NCT02285933
• Lead Sponsor: Bruyere Research Institute

Brief Summary

The purpose of this study is to determine if the addition of 10 to 12 sessions of sitting balance exercises using virtual reality training will provide additional gains in balance ability and function over standard inpatient rehabilitation in stroke patients.

Detailed Description

Introduction Sitting balance may be affected by stroke, resulting in functional impairment and reduced mobility. Early return of sitting balance predicts greater return of motor function and mobility after stroke. Task-specific therapy is effective but patients must be motivated to perform the exercises repeatedly for the greatest benefit.

Virtual reality training (VRT) allows patients to do exercises while interacting with a video game interface. It is enjoyable and may encourage repetition of therapeutic exercises. Past work in our laboratory showed that standing balance exercises performed with VRT produced additional improvements in gait speed and leg function over traditional inpatient rehabilitation (1). Because of legislative change in Ontario most stroke rehabilitation inpatients today cannot stand independently. There have been no studies on the effect of VRT on sitting balance.

Purpose To assess whether additional sitting balance exercises performed via VRT can improve sitting balance and sitting function (ex. reaching) in stroke rehabilitation inpatients.

Hypothesis The addition of VRT for sitting balance will significantly improve sitting balance and function, beyond the gains realized from traditional inpatient rehabilitation.

Experimental Approach In this blinded randomized control trial funded by the Heart \& Stroke Foundation, 76 participants with stroke will be recruited from an inpatient rehabilitation unit. This number will provide enough power to detect a large effect size (0.83) with the primary outcome measure and accounting for a 20% drop-out rate. Individuals who are medically stable and who can sit for at least 20 minutes with or without trunk support but cannot stand independently for more than one minute will be eligible. These criteria will target our selection to those who need to work most on sitting balance. Participants will be randomized into experimental and control groups.

Participants in both groups will perform VRT for 30-50 minutes daily for 10-12 sessions, in addition to their rehabilitation program. VRT will be delivered with Jintronix software and motion capture technology. Exercises for the experimental group will challenge sitting balance control, reaching and shifting the base of support. Control group exercises will require limited hand and arm movements, to equalize the additional time spent in an engaging activity without working on trunk balance. Control group participants will be strapped into their chair to minimize trunk movement. A CONFORMat pressure mat will be used to monitor centre of pressure changes during the intervention.

Outcome measures will be performed pre-, post- and 1 month post-intervention, by an assessor blinded to group allocation. The primary outcome measure will be the Function in Sitting Test. Secondary outcome measures will be: Ottawa Sitting Scale, Reaching Performance Scale, Wolf Motor Function Test and quantitative measures of postural control performed in sitting. Two-way analyses of variance \[factors: time (pre-, post-, 1 month post-)and group(experimental, control)\] and Tukey's post-hoc analyses will be used to test the effect of VRT on the outcome measures.

Significance and Knowledge Translation If we show that the addition of sitting balance exercises via VRT to traditional rehabilitation improves sitting balance and function, VRT may be added to inpatients' rehabilitation therapy. The ultimate goal is to improve the quality of patients' lives and decrease the burden on their caregivers. Since the Jintronix system is portable, we hope to acquire funding for several units. We would then be able to assess the use of VRT by therapists for inpatients and outpatients with stroke.

(1) McEwen D et al. Stroke 2014;45:1853-1855

Study Timeline

• Study First Submitted: 2014-11-03
• Study First Submitted QC: 2014-11-05
• Study First Posted: 2014-11-07
• Study Start: 2015-01
• Primary Completion: 2017-03-01
• Study Completion: 2017-03-30
• Status Verified: 2017-04
• Last Update Submitted: 2017-04-11
• Last Update Posted: 2017-04-12

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 76

Inclusion Criteria

• ischemic or hemorrhagic stroke in the left or right cortical or subcortical regions
• medically stable
• cannot stand independently for >1 minute or cannot stand at all
• can sit for at least 20 minutes with or without trunk support and can sit for at least 1 minute without trunk support
• able to provide informed consent

Exclusion Criteria

• unstable cardiovascular, respiratory, endocrine, orthopedic or neurological condition that precludes exercise of low to moderate intensity
• vestibular deficits or vertigo
• seizure activity in the previous 6 months

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
control	control	virtual reality training requiring limited arm movements and no challenge to sitting balance
VRT	virtual reality training	sitting balance exercises delivered via virtual reality training

Primary Outcome Measures

Name	Time	Method
Change in the Function In Sitting Test (FIST) from baseline to after 10-12 treatment sessions	baseline, immediately after 10-12 treatments	assesses static, dynamic and reactional sitting balance
Change in the Function In Sitting Test (FIST) from baseline to 1 month after second assessment	baseline,1 month after second assessment	assesses static, dynamic and reactional sitting balance

Secondary Outcome Measures

Name	Time	Method
Change in Limits of stability in sitting (LoS) from baseline to 1 month after second assessment	baseline, 1 month after second assement	assesses dynamic sitting balance using a force plate or pressure mat
Change in the Reaching Performance Scale (RPS) from baseline to after 10-12 treatment sessions	baseline, immediately after 10-12 treatments	assesses sitting balance function during reaching
Change in The Motivation for Physical Activity Questionnaire from baseline to after 10-12 treatment sessions	before treatment, immediately after 10-12 treatments	Likert scale from 0-6 to assess motivation to engage in exercise
Change in the Ottawa Sitting Scale (OSS) from baseline to after 10-12 treatment sessions	baseline, immediately after 10-12 treatments	assesses static and dynamic sitting balance
Change in the Ottawa Sitting Scale (OSS) from baseline to 1 month after second assessment	baseline, 1 month after second assement	assesses static and dynamic sitting balance
Change in Limits of stability in sitting (LoS) from baseline to after 10-12 treatment sessions	before treatment, immediately after 10-12 treatments	assesses dynamic sitting balance using a force plate or pressure mat
Change in the Behavioral Regulation in Exercise Questionnaire (BREQ-2) from baseline to after 10-12 treatment sessions	baseline, immediately after 10-12 treatments	assesses quality of motivation to engage in exercise
Change in Postural sway in sitting from baseline to 1 month after second assessment	baseline, 1 month after second assement	assesses static sitting balance using a force plate or pressure mat
Change in Postural sway in sitting from baseline to after 10-12 treatment sessions	baseline, immediately after 10-12 treatments	assesses static sitting balance using a force plate or pressure mat
Change in the Reaching Performance Scale (RPS) from baseline to 1 month after second assessment	baseline, 1 month after second assement	assesses sitting balance function during reaching
Change in the Wolf Motor Function Test (WMFT) from baseline to after 10-12 treatment sessions	baseline, immediately after 10-12 treatments	assesses sitting balance function using global arm function
Change in the Behavioral Regulation in Exercise Questionnaire (BREQ-2) from baseline to 1 month after second assessment	baseline, 1 month after second assessment	assesses quality of motivation to engage in exercise
Psychosocial Impact of Assistive Devices Scale (PIADS)	1 month after first assement	assesses the psychosocial impact of assistive devices or technology on "functional independence, well-being and quality of life"
Change in the Wolf Motor Function Test (WMFT) from baseline to 1 month after second assessment	baseline, 1 month after second assement	assesses sitting balance function using global arm function
Change in The Motivation for Physical Activity Questionnaire from baseline to 1 month after second assessment	baseline, 1 month after second assement	Likert scale from 0-6 to assess motivation to engage in exercise
The ability to enroll an average of five new participants a month, to obtain a consent rate of 60% of eligible patients and a rate of protocol violations resulting in noncompliance with VRT of less than 10%.	immediately after 76 participants have finished the protocol and assessments	assesses the feasibility of performing a larger multicentre trial of VRT with rehabilitation inpatients

Trial Locations

Locations (1)

Elisabeth Bruyere Hospital; 🇨🇦 Ottawa, Ontario, Canada