Kinematic adaptions to induced short-term pelvic limb lameness in trotting dogs

Subjective evaluation of canine gait has been used for many years. However, our ability to perceive minute details during the gait cycle can be difficult and in some respects impossible even for the most talented gait specialist. The evolution of computer technology in computer assisted gait analysis over the past 20 years has improved the ability to quantitatively define temporospatial gait characteristics. These technological advances and new developments in methodological approaches have assisted researchers and clinicians in gaining a better understanding of canine locomotion. The use of kinematic and kinetic analysis has been validated as a useful tool in veterinary medicine. This paper is an overview of the kinematic and kinetic analytical techniques of the last decade.

Summary The goal of this study was to determine the incidence of musculoskeletal disorders in a large canine population. Patient information was obtained from clinical cases contributed to the Veterinary Medical Data Base (VMDB) by 16 veterinary teaching hospitals during the ten year period of 1980 through 1989. The relative contribution of bone diseases, joint diseases, and muscle-tendon-unit diseases was determined, and the incidence of each musculoskeletal disease reported. Nearly 24% of all patients in the source population had been affected by a disorder of the musculoskeletal system, and over 70% of those diagnoses involved appendicular structures. Diseases of joints, ligaments, and related structures contributed more cases (47%) to this study than diseases of bones (39%) or muscle-tendon-units (14%). Fractures made up the largest disease category, with pelvic fractures most common, followed by femoral fractures, and fractures of the radius and/or ulna. Joint instability and degenerative joint dis- ease were also common diagnosis categories, affecting primarily the hip and stifle joints. Common specific dis-ease entities included hip dysplasia, cruciate ligament rupture, traumatic hip luxation and patellar luxation. In this study we provided a comprehensive analysis of the canine musculoskeletal system. The relative importance of joint disorders compared to those of bones and muscle-tendon-units was illustrated. The incidence of most of the disorders described in this report had not been well documented previously. Patient information was obtained from the clinical cases of 16 veterinary teaching hospitals during a 10-year period. The number of dogs with musculoskeletal disorders was determined. The absolute and relative contribution of bone diseases, joint diseases, and muscle-tendon-unit diseases is reported as well as the incidence of the specific disease entities affecting the canine appendicular musculoskeletal system.

The extrinsic limb muscles perform locomotor work and must adapt their activity to changes in gait and locomotor speed, which can alter the work performed by, and forces transmitted across, the proximal fulcra of the limbs where these muscles operate. We recorded electromyographic activity of 23 extrinsic forelimb and hindlimb muscles and one trunk muscle in dogs while they walked, trotted and galloped on a level treadmill. Muscle activity indicates that the basic functions of the extrinsic limb muscles - protraction, retraction and trunk support - are conserved among gaits. The forelimb retains its strut-like behavior in all gaits, as indicated by both the relative inactivity of the retractor muscles (e.g. the pectoralis profundus and the latissimus dorsi) during stance and the protractor muscles (e.g. the pectoralis superficialis and the omotransversarius) in the first half of stance. The hindlimb functions as a propulsive lever in all gaits, as revealed by the similar timing of activity of retractors (e.g. the biceps femoris and the gluteus medius) during stance. Excitation increased in many hindlimb muscles in the order walk-trot-gallop, consistent with greater propulsive impulses in faster gaits. Many forelimb muscles, in contrast, showed the greatest excitation at trot, in accord with a shorter limb oscillation period, greater locomotor work performed by the forelimb and presumably greater absorption of collisional energy.