A Wheelchair Propulsion Training Program

Washington University School of Medicine20 enrolled

Overview

The overall purpose of this project is to test the feasibility of a manual wheelchair propulsion program which aims to reduce the chance of development of upper limbs pain and injury.

The purpose of this project is to develop a feasible wheelchair propulsion training that can fit into an in-patient rehabilitation schedule, and determine the effectiveness of the training protocol. This project consists of a randomized control trial (RCT) for manual wheelchair users (MWUs) that examines the number of manual wheelchair propulsion repetitions required to produce change. For the RCT, we will recruit twenty individuals who use manual wheelchairs as their primary means of mobility and who do not follow the recommended clinical guidelines for propulsion. Participants will be randomized into two independent groups: motor learning repetitions overground (Training Group; n =10), and general education on recommended propulsion techniques (Education Group; n =10). Demographics, cognition, shoulder strength, participation, and wheelchair seating may only be assessed at baseline. Participants then may be assessed from the kinematics of their wheelchair performance overground and on a motorized treadmill. Participants may be tested on their wheelchair propulsion techniques in and outside of the lab, upper extremity pain at baseline, post-intervention, and three-week follow-up; participants may also be asked qualitative questions regarding the intervention experience, the experience with the equipment and the laboratory research, the monitoring setting, and the general experience with the research study. The primary research question is that will repetition of proper propulsion technique practiced overground result in improved manual wheelchair propulsion biomechanics?

Study Type

INTERVENTIONAL

Allocation

RANDOMIZED

Purpose

TREATMENT

Masking

NONE

Enrollment

Conditions

Spinal Cord Injuries Multiple Sclerosis Amputation Spina Bifida

Interventions

In-person wheelchair propulsion training programBEHAVIORAL

The wheelchair propulsion (WP) intervention is based on our previous pilot work and the best available evidence on WP training. The CPGs recommend minimizing the force and frequency of pushes while using long strokes during propulsion. Each training session will include massed practice with repetitions overground. Each session is organized to limit the number of variables (i.e., long push strokes and dropping the hands down below axle) presented to the participant at one time. Propulsion Set A will focus on using longer push strokes. Propulsion Set B will focus on dropping the hand down toward the axle. Propulsion Set C will focus on both A and B.

30-minute education sessionBEHAVIORAL

Both groups will receive a 30-minute education session regarding the CPGs. This education session will follow the instructions provided in Rice and colleagues. (L. A. Rice et al., 2014). It consists of the importance of practicing biomechanical efficient propulsion. The material lists out the consequences and the impact of upper limb pain and injury. It provides a detailed step by step on how to propel properly. They will view the video that shows the biomechanics of efficient and inefficient propulsion.

Eligibility

Sex: ALLMin age: 18 YearsMax age: 65 Years

Medical Language ↔ Plain English

Inclusion Criteria: * 18-65 years of age * have a mobility limitation requiring the use of a manual wheelchair (MWC) * be able to self-propel a MWC bilaterally with their upper extremities * plan to use a MWC for at least 75% of their activities throughout the day * live in the community * understand English at a sixth-grade level or higher * can follow multi-step instructions * able to provide informed consent independently * able to tolerate propelling their wheelchair independently for 10m * be willing to participate in three assessments and six training sessions at the Enabling Mobility in the Community Laboratory (EMC Lab). Exclusion Criteria: * maneuver their MWC with their lower extremities or with only one upper extremity * display the proper wheelchair propulsion techniques during the screening process * MWC position inhibits them from following the CPGs * bilateral incoordination * upper extremity strength inequalities resulting in a 12-inch deviation from a marked pathway * surgeries compromising the integrity of the upper extremities * cardiovascular complications within the past year * upper extremity or overall bodily pain is rated 8/10 or higher per the Wong-Baker FACES Numeric Pain Scale (FACES) * currently receiving medical treatment for an acute upper extremity injury * have a Stage IV pressure injury or are currently hospitalized

Locations (1)

Washington University School of Medicine

St Louis, Missouri, United States

Outcomes

Primary Outcomes

Motion capture - changes in push angle

Push angle during the push phase of propulsion is assessed with video motion capture (VMC). The VMC system consists of 14 Vero 2.2 digital cameras to detect the location of the reflective markers, specifically on the shoulder, elbow, and wrist. The 3D infrared coordinates will be recorded while participants propel their wheelchair over the ground and on a dynamic roller system. Push angle will be calculated by finding the inner product of the vectors formed by the elbow-shoulder and elbow-wrist. The push angles will be compared across the three testing sessions. This variable corresponds to the recommendations outlined in the clinical practice guidelines. We hypothesize that the increase of push angle will be greater in the training group than the control group.

Time frame: Baseline, 3-week after baseline for the control group/immediate after training group intervention, 3-weeks after second assessment

Motion capture - changes in hand-axle distance

Hand-axle distance during the recovery phase of propulsion assessed with video motion capture (VMC). The VMC system consists of 14 Vero 2.2 digital cameras to detect the location of the reflective markers, specifically on the axle and the third metacarpal joint. The 3D infrared coordinates will be recorded while participants propel their wheelchair over the ground and on a dynamic roller system. Hand-axle distance will be calculated by the magnitude of the vector formed by the third metacarpal joint and the axle. The hand-axle will be compared across the three testing sessions. This variable corresponds to the recommendations outlined in the clinical practice guidelines. We hypothesize that the increase of hand-axle distance will be greater in the training group than the control group.

Time frame: Baseline, 3-week after baseline for the control group/immediate after training group intervention, 3-weeks after second assessment

Wheelchair Propulsion Test (WPT) - changes in effectiveness

The WPT assesses wheelchair mobility and performance of manual wheelchair users (MWU). The WPT requires MWU to propel using a self-selected natural velocity across 10 meters of a smooth flat surface from a static start. The number of pushes and the time will be recorded. The effectiveness of the propulsion is the displacement per push and will be calculated by the 10 meters divided by the number of pushes. We hypothesize that the increase in the effectiveness of propulsion will be greater in the training group than the control group.

Data from ClinicalTrials.gov

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