Kinematic Analysis of Locomotion in Unilateral Vestibular Neurectomized Cats

Abstract

The vestibular syndrome following unilateral lesion of the vestibular system and the subsequent behavioral compensation over time have been well documented in many species. However, the locomotor pattern changes and the behavioral strategies used to preserve balance have still not been described. This study was aimed at quantitatively describing posturolocomotor behavior in cats tested before and after unilateral vestibular neurectomy (UVN) by the rotating beam test, which provides locomotor tasks of various difficulty. The position of head, neck, and trunk and the trajectory of the forelimbs and hindlimbs were recorded in 5 cats by 3D motion analysis. Step length and frequency walking velocity, and body height were computed. Results showed that normal cats adapted their locomotor patterns to the speed of beam rotation by increasing step length and/or frequency, that is, by increasing walking velocity, but without drastically changing their body posture. By contrast, UVN cats typically lowered their body centers of gravity and modified their locomotor patterns according to the locomotor task. Mean walking velocity was decreased in the low range of beam rotation as a result of smaller step length and lower frequency, and it was increased in the high range by opposite effects on these step cycle parameters. Modifications of the locomotor parameters were a function of the direction of beam rotation, showing significant reduction of step length, frequency, and velocity in the low range of counterclockwise compared to clockwise beam rotation, that is, during rotations toward the lesioned side. Phase plane plots of foot linear velocity with respect to foot linear displacement along the horizontal longitudinal axis displayed two different limit cycles, adapted to easy (low range of beam rotation) and more difficult (high range of rotation) walking conditions, in the normal cat. These dynamic profiles of the trajectories of the limbs during the step cycle were not greatly modified after vestibular lesion, but the phase plane typically observed in the high range for the normals was also found in the low range for the UVN cats. Thus, locomotor equilibrium function in the cat is strongly impaired following UVN, but locomotor balance can still be achieved in the UVN cats by the development of adaptive posturolocomotor strategies compensating for the lack of vestibular inputs.