The energetics of the trot-gallop transition

doi:10.1242/jeb.00276

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The Journal of Experimental Biology 206, 1557-1564 (2003)
doi: 10.1242/jeb.00276

The energetics of the trot–gallop transition

Steven J. Wickler¹^,*, Donald F. Hoyt², Edward A. Cogger¹ and Gregory Myers¹

^¹ Departments of Animal and Veterinary Science, California State Polytechnic University, Pomona, CA 91768, USA
^² Biological Sciences and the Equine Research Center, California State Polytechnic University, Pomona, CA 91768, USA

^* Author for correspondence (e-mail: sjwickler{at}csupomona.edu)

Accepted 3 February 2003

Two studies have focused on potential triggers for the trot–gallop transitionin the horse. One study concluded that the transition was triggered bymetabolic economy. The second study found that it was not metabolicfactors but, rather, peak musculoskeletal forces that determinegait transition speeds. In theory, peak musculoskeletal forcesshould be the same when trotting up an incline as when trottingat the same speed on the level. Assuming this is the case, wehypothesized that if peak forces determine gait transition speedsthen horses should switch from a trot to a gallop at the samespeed (i.e. the same critical force) regardless of incline.The aim of the present research was to examine the effects ofincline on the trot–gallop transition speed in horsesand to re-examine the role of metabolism in determining thetrot–gallop transition. Horses (Equus caballus) were conditionedto run on a high-speed treadmill prior to data collection. Gaitchanges were recorded for each horse using a standardized testingprotocol on the level and when trotting up a 10% incline. Bothmaximum sustained trotting speeds and minimum sustained gallopingspeeds, representing the lower and upper limits of the trot–galloptransition, respectively, were significantly slower when trottingup an incline. After completing collection of gait transitiondata, the horses were trained to extend their gaits beyond thenormal transition speeds, and metabolic data were collected. Maximumsustained trotting speeds were not different from the energetically optimaltransition speeds, i.e. the speed at which metabolic rates arethe same for both gaits.

Key words: equine, horse, Equus caballus, oxygen consumption, time of contact, trot–gallop transition, gait

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