Shunsuke Yamaji, Shinichi Demura, Hiroki Sugiura
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DOI: 10.4236/health.2011.32018   PDF    HTML     5,360 Downloads   9,196 Views   Citations

Abstract

This study examined the effect on gait of de-grading visual input by simulation on a course with obstacles. Thirty healthy, young adult males walked on a 6 m path with three obstacles (height: 5, 10, 20 cm, width: 10 cm) set at inter-vals of 150 cm with and without degraded visual input from light-scattering goggles. Gait was examined with respect to time, length, angle and walk speed parameters. Gait changed signifi-cantly in the degraded visual input condition. The distances between the obstacles and foot before the obstacles were significantly larger in 10 and 20 cm obstacles under the degraded visual input condition, but distances after passing the obstacle had no significant difference among obstacle height. We therefore conclude that a decrease of visual function alters the perception of an obstacle’s height, particularly the 5 cm height obstacle.

Keywords

Walk Analysis; Visual Information; Contrast Sensitivity; Posture Stable

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Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	Masani, K. (1999) Walking and vision. Japanese Journal of Biomechanics in Sports and Exercise, 3, 300-307.
[2]	Diez, V. (1992) Human neuronal control of automatic functional movements: Interaction between central programs and afferent input. Physiological Reviews, 72, 33- 69.
[3]	Patla, A.E., Tomescu, S.S. and Ishac, M.G. (2004) What visual information is used for navigation around obstacles in a cluttered environment? Canadian Journal of Physiology and Pharmacology, 82, 682-692.
[4]	Black, A. and Wood, J. (2005) Vision and falls. Clinical and Experimental Optometry, 88, 212-222.
[5]	Rubenstein, L.Z., Josephson, K.R., Trueblood, P.R., Yeung, K. and Harker, J.O. (1997) The reliability and validity of an obstacle course as a measure of gait and balance in older adults. Aging, 9, 127-135.
[6]	Anand, V., Buckley, J.G., Scally, A. and Elliott, D.B. (2003) Postural stability changes in the elderly with cataract simulation and refractive blur. Investigative Ophthalmology and Visual Science, 44, 4670-4675.
[7]	Lord, S.R. (2006) Visual risk factors for falls in older people. Age and Ageing, 35, 42-45.
[8]	Rietdyk, S. and Rhea, C.K. (2006) Control of adaptive locomotion: Effect of visual obstruction and visual cues in the environment. Experimental Brain Research, 169, 272-278.
[9]	Suzuki, T. (2003) Epidemiology and implications of falling among the elderly. Nippon Ronen Igakkai Zasshi, 40, 85-94.
[10]	Mohagheghi, A.A., Moraes, R. and Patla, A.E. (2004) The effects of distant and on-line visual information on the control of approach phase and step over an obstacle during locomotion. Experimental Brain Research, 155, 459-468.
[11]	Ferrandez, A.M., Pailhous, J. and Durup, M. (1990) Slowness in elderly gait. Experimental Aging Research, 16, 79-89.
[12]	Jensen, J., Nyberg, L., Rosendahl, E., Gustafson, Y. and Lundin-Olsson, L. (2004) Effects of a fall prevention program including exercise on mobility and falls in frail older people living in residential care facilities. Aging Clinical and Experimental Research, 16, 283-292.
[13]	Murray, M.P., Kory, R.C. and Clarkson, B.H. (1969) Walking patterns in healthy old men. Journal of Gerontology, 24, 169-178.
[14]	Lord, S.R. and Menz, H.B. (2000) Visual contributions to postural stability in older adults. Gerontology, 46, 306- 310.
[15]	Means, K.M. and O'Sullivan, P.S. (2000) Modifying a functional obstacle course to test balance and mobility in the community. Journal of Rehabilitation Research and Development, 37, 621-632.