Abstract
The objective of this study was to conduct a kinetic analysis of manual wheelchair propulsion during start-LIP on select indoor and Outdoor surfaces. Eleven manual wheelchairs were fitted with a SMART(Wheel) and their users were asked to Push on a Course consisting of high- and low-pile carpet, indoor tile, interlocking concrete pavers, smooth level concrete, grass, hardwood flooring, and a sidewalk with a 5-degree grade. Peak resultant force, wheel torque, mechanical effective force, and maximum resultant force rate of rise were analyzed during start-up for each Surface and normalized relative to their steady-state values on the smooth level concrete. Additional variables included peak velocity, distance traveled, and number of strokes in the first 5 s of the trial. We compared biomechanical data between surfaces using repeated-measures mixed models and paired comparisons with a Bonferroni adjustment. Applied resultant force (p = 0.0154), wheel torque (p <0.0001), and mechanical effective force (p = 0.0047) were significantly different between surfaces. The kinetic values for grass, interlocking pavers, and ramp ascent were typically higher compared with tile, wood, smooth level concrete, and high- and low-pile carpet. Users were found to travel shorter distances up the ramp and across grass (p <0.0025) and had a higher stroke Count on the ramp (p = 0.0124). While peak velocity was not statistically different, average velocity was slower for the ramp and grass, which indicates greater wheelchair/user deceleration between strokes. The differences noted between surfaces highlight the importance of evaluating wheelchair propulsion ability over a range of surfaces.
Original language | English |
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Pages (from-to) | 447-458 |
Number of pages | 12 |
Journal | Journal of Rehabilitation Research and Development |
Volume | 42 |
Issue number | 4 |
DOIs | |
Publication status | Published - 2005 |
Event | Annual Meeting of the American-Society-of-Biomechanics - Toledo, Netherlands Duration: 25-Sept-2003 → 27-Sept-2003 |
Keywords
- access
- biomechanics
- community access
- driving surfaces
- manual wheelchair
- propulsion forces
- ramps
- rolling resistance
- sidewalks
- standards
- surface resistances
- wheelchair propulsion
- SPINAL-CORD INJURIES
- MECHANICAL EFFICIENCY
- UPPER EXTREMITY
- NERVE FUNCTION
- ENERGY-COST
- USERS
- BIOMECHANICS
- WEIGHT
- PEOPLE