Assessment of physiological performance and perception of pushing different wheelchairs on indoor modular units simulating a surface roughness often encountered in under-resourced settings

• Published in: Assistive technology Vol. 29; no. 4; pp. 173 - 180
• Main Authors: Sasaki, Kotaro, Rispin, Karen
• Format: Journal Article
• Language: English
• Published: United States Taylor & Francis 02.10.2017
• Subjects: assistant; Disabled Persons; energy cost; Equipment Design; Humans; Physical Exertion - physiology; Poverty Areas; rolling resistance; rough surface; Task Performance and Analysis; Upper Extremity; wheelchair; Wheelchairs; rolling resistance; rough surface; wheelchair; energy cost; assistant
• ISSN: 1040-0435; 1949-3614; 1949-3614
• DOI: 10.1080/10400435.2016.1216473

In under-resourced settings where motorized wheelchairs are rarely available, manual wheelchair users with limited upper-body strength and functionalities need to rely on assisting pushers for their mobility. Because traveling surfaces in under-resourced settings are often unpaved and rough, wheelchair pushers could experience high physiological loading. In order to evaluate pushers' physiological loading and to improve wheelchair designs, we built indoor modular units that simulate rough surface conditions, and tested a hypothesis that pushing different wheelchairs would result in different physiological performances and pushers' perception of difficulty on the simulated rough surface. Eighteen healthy subjects pushed two different types of pediatric wheelchairs (Moti-Go manufactured by Motivation, and KidChair by Hope Haven) fitted with a 50-kg dummy on the rough and smooth surfaces at self-selected speeds. Oxygen uptake, traveling distance for 6 minutes, and the rating of difficulty were obtained. The results supported our hypothesis, showing that pushing Moti-Go on the rough surface was physiologically less loading than KidChair, but on the smooth surface, the two wheelchairs did not differ significantly. These results indicate wheelchair designs to improve pushers' performance in under-resourced settings should be evaluated on rough surfaces.