Mechanics of running under simulated low gravity

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Mechanics of running under simulated low gravity

J. P. He, R. Kram and T. A. McMahon
Department of Organismic and Evolutionary Biology, Harvard University, Cambridge, Massachusetts.

Using a linear mass-spring model of the body and leg (T. A. McMahon and G. C. Cheng. J. Biomech. 23: 65-78, 1990), we present experimental observations of human running under simulated low gravity and an analysis of these experiments. The purpose of the study was to investigate how the spring properties of the leg are adjusted to different levels of gravity. We hypothesized that leg spring stiffness would not change under simulated low-gravity conditions. To simulate low gravity, a nearly constant vertical force was applied to human subjects via a bicycle seat. The force was obtained by stretching long steel springs via a hand-operated winch. Subjects ran on a motorized treadmill that had been modified to include a force platform under the tread. Four subjects ran at one speed (3.0 m/s) under conditions of normal gravity and six simulated fractions of normal gravity from 0.2 to 0.7 G. For comparison, subjects also ran under normal gravity at five speeds from 2.0 to 6.0 m/s. Two basic principles emerged from all comparisons: both the stiffness of the leg, considered as a linear spring, and the vertical excursion of the center of mass during the flight phase did not change with forward speed or gravity. With these results as inputs, the mathematical model is able to account correctly for many of the changes in dynamic parameters that do take place, including the increasing vertical stiffness with speed at normal gravity and the decreasing peak force observed under conditions simulating low gravity.

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				S. J. Wickler, D. F. Hoyt, E. A. Cogger, and K. M. Hall Effect of load on preferred speed and cost of transport J Appl Physiol, April 1, 2001; 90(4): 1548 - 1551. [Abstract] [Full Text] [PDF]

				J. Donelan and R Kram Exploring dynamic similarity in human running using simulated reduced gravity J. Exp. Biol., January 8, 2000; 203(16): 2405 - 2415. [Abstract] [PDF]

				S. Wickler, D. Hoyt, E. Cogger, and M. Hirschbein Preferred speed and cost of transport: the effect of incline J. Exp. Biol., January 7, 2000; 203(14): 2195 - 2200. [Abstract] [PDF]

				Y. Chang, H. Huang, C. Hamerski, and R Kram The independent effects of gravity and inertia on running mechanics J. Exp. Biol., January 1, 2000; 203(2): 229 - 238. [Abstract] [PDF]

				T. M. Griffin, N. A. Tolani, and R. Kram Walking in simulated reduced gravity: mechanical energy fluctuations and exchange J Appl Physiol, January 1, 1999; 86(1): 383 - 390. [Abstract] [Full Text] [PDF]

				M. J. Bellizzi, K. A.�D. King, S. K. Cushman, and P. G. Weyand Does the application of ground force set the energetic cost of cross-country skiing? J Appl Physiol, November 1, 1998; 85(5): 1736 - 1743. [Abstract] [Full Text] [PDF]

				C. T. Farley, H. H.�P. Houdijk, C. Van Strien, and M. Louie Mechanism of leg stiffness adjustment for hopping on surfaces of different stiffnesses J Appl Physiol, September 1, 1998; 85(3): 1044 - 1055. [Abstract] [Full Text] [PDF]

				R. Kram, T. M. Griffin, J. M. Donelan, and Y. H. Chang Force treadmill for measuring vertical and horizontal ground reaction forces J Appl Physiol, August 1, 1998; 85(2): 764 - 769. [Abstract] [Full Text] [PDF]

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Mechanics of running under simulated low gravity