A comparison of epigean and subterranean locomotion in the domestic ferret (Mustela putorius furo: Mustelidae: Carnivora)

Burrows are used by many mammals to escape predation, cache food and for parturition. Although the construction of burrows has been studied in some taxa, the locomotion while inside of them has received scant attention. In this study we collected simultaneous video and force data to characterize gaits, kinematics, peak ground reaction forces (GRFs) and external mechanical energy profiles in the domestic ferret, an animal that displays the typical morphology and behaviors associated with subterranean adaptations in mustelines. We compared kinematics and kinetics between locomotion in two experimental conditions: subterranean, simulated by a Plexiglass tunnel designed such that the ferrets’ peak back height was reduced by 40% and hip height by 25%, and epigean, or unconstrained overground. Despite the large change in posture, a striking number of gait and force variables were not statistically different between experimental conditions. In both subterranean and epigean conditions, the ferrets in our study traveled at similar average velocities (∼0.8 m s−1), preferred to use a lateral-sequence diagonal-couplet gait, and were more likely to demonstrate the in-phase fluctuations of external mechanical energy indicative of running mechanics (68% of all trials). The ferrets conformed to gait and mechanical patterns seen in a variety of other small (<1 kg) mammals rather than being unique, despite the divergent morphology of mustelines. Our results demonstrated biodynamically similar locomotion in both epigean and subterranean conditions and support the hypothesis that ferrets possess adaptations for tunnel locomotion.