Manual wheelchair stroke characteristics during an extended period of propulsion

Rice, Ian; Impink, Bradley G; Niyonkuru, Christian; Boninger, Michael L.

doi:10.1038/sc.2008.139

Cited by 29 publications

(25 citation statements)

References 15 publications

(22 reference statements)

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“…Rice et al reported an increase in push time during an extended period of propulsion, while stroke frequency remained static [42]. In the present study, no significant effects of kinetic variables on the endurance time of wheelchair propulsion were found.…”

Section: Effect Of Muscle Fatigue On Wheelchair Kineticscontrasting

confidence: 44%

Changes in surface electromyography signals and kinetics associated with progression of fatigue at two speeds during wheelchair propulsion

Wakeling²,

Grange³

et al. 2012

JRRD

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Abstract-The purpose of this study was to determine whether muscle balance is influenced by fatigue in a recordable way, toward creating novel defensive activity strategies for manual wheelchair users (MWUs). Wheelchair propulsion to a point of mild fatigue, level 15 on the Rating of Perceived Exertion scale, was investigated at two different speeds. Surface electromyographic (EMG) activity of 7 muscles was recorded on 14 nondisabled participants. Kinetic variables were measured using a SmartWheel. No significant effect was found of percentage endurance time on kinetic variables for the two propulsion speeds. Fatigue-related changes in the EMG spectra were identified as an increase of EMG intensity and a decrease of mean power frequency as a function of percent endurance time for the tested muscles under both fast and slow speed conditions. The greater increases in activity for propulsive muscles compared with recovery muscles during fast speed wheelchair propulsion indicated muscle imbalance associated with fatiguing wheelchair propulsion. This study shows how kinetic and EMG information might be used as feedback to MWUs to ensure that they conduct activity in ways that do not precipitate injury.

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Section: Effect Of Muscle Fatigue On Wheelchair Kineticscontrasting

confidence: 44%

Changes in surface electromyography signals and kinetics associated with progression of fatigue at two speeds during wheelchair propulsion

Wakeling²,

Grange³

et al. 2012

JRRD

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“…These studies found lower cadences increased mechanical efficiency and reduced self-reported perceived exertion measures, suggesting that lower demand is placed on the upper extremity (Goosey-Tolfrey and Kirk, 2003; Lenton et al, 2009). To our knowledge, only one study has investigated how altering contact angle influences wheelchair mechanics (using a single subject), but did not analyse specific measures of upper extremity demand (Rice et al, 2009). Potential reasons for the lack of studies may be due to the extreme difficulty in obtaining specific measures of upper extremity demand (e.g., muscle stress) or that longitudinal intervention studies can be confounded by other influences (e.g., physiological adaptation).…”

Section: Introductionmentioning

confidence: 99%

The influence of wheelchair propulsion technique on upper extremity muscle demand: A simulation study

Rankin

Kwarciak

Richter

et al. 2012

Clinical Biomechanics

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Background The majority of manual wheelchair users will experience upper extremity injuries or pain, in part due to the high force requirements, repetitive motion and extreme joint postures associated with wheelchair propulsion. Recent studies have identified cadence, contact angle and peak force as important factors for reducing upper extremity demand during propulsion. However, studies often make comparisons between populations (e.g., able-bodied vs. paraplegic) or do not investigate specific measures of upper extremity demand. The purpose of this study was to use a musculoskeletal model and forward dynamics simulations of wheelchair propulsion to investigate how altering cadence, peak force and contact angle influence individual muscle demand. Methods Forward dynamics simulations of wheelchair propulsion were generated to emulate group-averaged experimental data during four conditions: 1) self-selected propulsion technique, and while 2) minimizing cadence, 3) maximizing contact angle and 4) minimizing peak force using biofeedback. Simulations were used to determine individual muscle mechanical power and stress as measures of muscle demand. Results Minimizing peak force and cadence had the lowest muscle power requirements. However, minimizing peak force increased cadence and recovery power, while minimizing cadence increased average muscle stress. Maximizing contact angle increased muscle stress and had the highest muscle power requirements. Interpretation Minimizing cadence appears to have the most potential for reducing muscle demand and fatigue, which could decrease upper extremity injuries and pain. However, altering any of these variables to extreme values appears to be less effective; instead small to moderate changes may better reduce overall muscle demand.

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“…In another study by Rice et al, 11 experienced users pushing for an extended period tended to propel with longer stroke lengths and reduced forces toward the end of a 10-min trial vs. at start-up. Many of these subjects were very experienced and seemed to place an emphasis on push efficiency and energy conservation toward the end of the extended trial.…”

Section: Propulsion Trainingmentioning

confidence: 94%

The Need for Updated Clinical Practice Guidelines for Preservation of Upper Extremities in Manual Wheelchair Users

Sawatzky

DiGiovine

Berner

et al. 2015

American Journal of Physical Medicine &Amp; Rehabilitation

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The purposes of this article were to examine the existing 2005 Clinical Practice Guidelines for preservation of the upper extremities in spinal cord injury and explore the literature to determine what might need to be included in an update. This is a consensus position article based on a literature review and the expertise of the authors. The findings support the original recommendations of the Clinical Practice Guidelines and provide evidence that suggests that information regarding equipment and skills training as well as impact to caregivers is needed.

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Manual wheelchair stroke characteristics during an extended period of propulsion

Cited by 29 publications

References 15 publications

Changes in surface electromyography signals and kinetics associated with progression of fatigue at two speeds during wheelchair propulsion

Changes in surface electromyography signals and kinetics associated with progression of fatigue at two speeds during wheelchair propulsion

The influence of wheelchair propulsion technique on upper extremity muscle demand: A simulation study

The Need for Updated Clinical Practice Guidelines for Preservation of Upper Extremities in Manual Wheelchair Users

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