Effects of trunk deformation on trunk center of mass mechanical energy estimates in the moving horse, Equus caballus.

The estimation of the position of the center of mass (CM) is essential in a wide range of biomechanical analyses. In horses, the majority of the body mass is contained in the trunk and in most studies, the trunk is assumed to be rigid. However, this rigidity assumption has not been tested. We quantified changes in the position of the trunk CM due to external shape changes by measuring the kinematics of a mesh encompassing the trunk. Using a frame of reference fixed to the horse's spine, we described the shape deformation of the trunk during walking. In addition, we tested for speed and individual differences. The significance of any trunk deformation was illustrated by calculating mechanical energy profiles. Errors in the estimation of the trunk CM due to a rigid body approach were always small in the vertical direction, but can be significant in the transverse direction and in the longitudinal direction at high walking speeds. This is enough to change the mechanical energy expenditure estimates up to 25%. When extrapolating the position of the trunk CM from cadaver data, one should be aware of this extra source of error, separated from the measurement error of the cadaver CM. We also found considerable inter-individual variation, which complicates theoretical correction routines. We suggest using extra markers on the trunk during gait analysis to correct this CM shift experimentally.

[1]  Angelo Cappello,et al.  Influence of body segment parameters and modeling assumptions on the estimate of center of mass trajectory. , 2003, Journal of biomechanics.

[2]  H. C. Schamhardt,et al.  Measurement and computation of inertial parameters in the horse , 1990 .

[3]  T P Andriacchi,et al.  Studies of human locomotion: past, present and future. , 2000, Journal of biomechanics.

[4]  B M Nigg,et al.  A method for inverse dynamic analysis using accelerometry. , 1996, Journal of biomechanics.

[5]  Li-Shan Chou,et al.  Gait stability following concussion , 2006 .

[6]  D. Bramble Axial-Appendicular Dynamics and the Integration of Breathing and Gait in Mammal , 1989 .

[7]  Maarten F. Bobbert,et al.  Validation of vertical ground reaction forces on individual limbs calculated from kinematics of horse locomotion , 2007, Journal of Experimental Biology.

[8]  Thierry Pozzo,et al.  Human whole-body reaching in normal gravity and microgravity reveals a strong temporal coordination between postural and focal task components , 2005, Experimental Brain Research.

[9]  M Scheidl,et al.  Body centre of mass movement in the sound horse. , 2000, Veterinary journal.

[10]  Laurence Mouchnino,et al.  Coordination between postural and movement controls: effect of changes in body mass distribution on postural and focal component characteristics , 2007, Experimental Brain Research.

[11]  A. Biewener Patterns of mechanical energy change in tetrapod gait: pendula, springs and work. , 2006, Journal of experimental zoology. Part A, Comparative experimental biology.

[12]  R. Kram,et al.  Mechanical energy fluctuations during hill walking: the effects of slope on inverted pendulum exchange , 2006, Journal of Experimental Biology.

[13]  H. Buchner,et al.  Inertial properties of Dutch Warmblood horses. , 1997, Journal of biomechanics.

[14]  Brian L. Day,et al.  Predictive control of body mass trajectory in a two-step sequence , 2005, Experimental Brain Research.

[15]  Alan M. Wilson,et al.  Centre of mass movement and mechanical energy fluctuation during gallop locomotion in the Thoroughbred racehorse , 2006, Journal of Experimental Biology.

[16]  Antonie J. van den Bogert,et al.  Analysis and simulation of mechanical loads on the human musculoskeletal system: a methodological overview. , 1994 .

[17]  Yi-Chung Pai,et al.  Movement Termination and Stability in Standing , 2003, Exercise and sport sciences reviews.