With 4 figures in the text)Although the hindlimb is widely considered to provide the propulsive force in lizard locomotion, no study to date has analysed kinematic patterns of hindlimb movements for more than one stride for a single individual and no study has considered limb and axial kinematics together. In this study, kinematic data from several individuals of the Sceloporus clarkii are used to describe the movement patterns of the axial skeleton and hindlimb at different speeds, to analyse how kinematics change with speed, and to compare and contrast these findings with the inferred effects of speed cited in the literature. Angular limb movements and axial bending patterns (standing wave with nodes on the girdles) did not change with speed. Only the relative speed of retracting the femur and flexing the knee during limb retraction changes with speed. Based on these data and similar results from a recent study of salamanders, it appears that, over a range of speeds involving a walking trot, sprawling vertebrates increase speed by simply retracting the femur relatively faster, thus this simple functional adjustment may be a general mechanism to increase speed in tetrapods. The demonstration that femoral retraction alone is the major speed effector in Sceloporus clarkii lends strong functional support to ecomorphological implications of limb length (and especially femur length and caudifemoralis size) in locomotory ecology and performance in phrynosomatid lizards. It also lends support to inferences about the caudifemoralis muscle as a preadaptation to terrestrial locomotion and as a key innovation in the evolution of bipedalisrn.
Although the hindlimb is widely considered to provide the propulsive force in lizard locomotion, no study to date has investigated the kinematic patterns of the lizard hindlimb during running for more than one stride for a single individual. The quantitative kinematics of the hindlimb, pelvis and backbone are described here for two individuals of the lizard Sceloporus clarkii using a fast walking trot on a treadmill moving at a constant speed of 0.833 m s-1. Pelvic rotation, femoral retraction, knee flexion and posterior movement of the foot all begin before the foot hits the substratum and, thus, there is a terminal portion of the swing phase during which the limb is retracting. Pelvic rotation (to the opposite side), femoral protraction and knee flexion all begin before the foot leaves the substratum. The foot, however, continues to move posteriorly into the early swing phase. Thus, limb retraction and protraction movements do not directly correlate with footfall phases. Axial bending involves a rough standing wave with two nodes, one centered on each limb girdle. In Sceloporus clarkii, the foot clearly remains lateral to the knee and, thus, has a more sprawling posture than that of any other vertebrate studied to date. Therefore, the generalization that the 'lacertilian' foot passes under the knee joint is no longer supported. The kinematics of sprawling locomotion in Sceloporus clarkii are compared and contrasted with the general understanding of lizard locomotion based on qualitative work to date. Comparisons with other tetrapods reveal a fundamental functional dichotomy in hindlimb retraction mechanics in salamanders and mammals versus lizards that may be related to a key morphological difference in the saurian caudifemoralis muscle.
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