Representation of Wrist Joint Kinematics by the Ensemble of Muscle Spindles From Synergistic Muscles

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Representation of Wrist Joint Kinematics by the Ensemble of Muscle Spindles From Synergistic Muscles

Sabine M. P. Verschueren¹^,², Paul J. Cordo¹^,³, and Stephan P. Swinnen²

¹ Robert S. Dow Neurological Sciences Institute, Portland 97209; ² Laboratory of Motor Control, Department of Kinesiology, Catholic University of Leuven, B3001 Heverlee, Belgium; and ³ Department of Physiology and Pharmacology, Oregon Health Sciences University, Portland, Oregon 97201

Verschueren, Sabine M. P., Paul J. Cordo, and Stephan P. Swinnen. Representation of wrist joint kinematics by the ensembleof muscle spindles from synergistic muscles. J. Neurophysiol.79: 2265-2276, 1998. Proprioceptive information about movementis transmitted to the central nervous system by a variety of receptortypes, which are widely distributed among the muscles, joints,and skin. Muscle spindles are known to be an important and reliablesource of information for the perception of movement kinematics.Previous studies that focused on the characteristics of singlemuscle spindle firing patterns have left the impression that eachreceptor fires in relation to a number of kinematic variables,leaving the following question unanswered: what role is playedby the ensemble of muscle spindles within the same muscle or withinsynergistic muscles? The study described in this paper addressedwhether the perception of joint position and velocity is basedon the net input of muscle spindles residing in all synergisticmuscles crossing a joint. Normal human adults performed a motorcoordination task that required perception of joint velocity anddynamic position at the wrist. The task was to open the left handbriskly as the right wrist was passively rotated in the flexiondirection through a prescribed target angle. In randomly occurringtrials, the tendons to three muscles [extensor carpi radialis(ECR), extensor carpi ulnaris (ECU), and extensor digitorum (ED)]were vibrated either individually or in different combinationsduring the performance of the motor task. Tendon vibration isknown to distort muscle spindle firing patterns, and consequently,kinesthesia. By comparing performance errors with and withouttendon vibration, the relative influences of muscle spindles residingin ECR, ECU, and ED were quantified. Vibration of the individualECR, ECU, or ED tendons produced systematic undershoot errorsin performance, consistent with the misperception of wrist velocityand dynamic position. Performance errors were larger when combinationsof, rather than individual, muscle tendons were vibrated. Theerror resulting from simultaneous vibration of ECR and ECU wasroughly equal to the sum of the errors produced by vibration ofthe individual tendons. These effects of vibrating synergistictendons at the wrist suggest that kinesthesia is derived fromthe integrated input of muscle spindles from all synergistic muscles.

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