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Vibration-induced changes in movement-related EMG activity in humans

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Summary

The effect of muscle tendon vibration during voluntary arm movement was studied in normal humans. Subjects made alternating step flexion and extension movements about the elbow. A small vibrator was mounted over either the biceps or the triceps muscle and vibration was applied during flexion or extension movements. The vibrator was turned off between movements.

After a period of practice, subjects learned the required movements and were able to make them with their eyes closed. Application of vibration to the muscle antagonist to the movement being performed produced an undershoot of the required end-movement position. The undershoot was 20–30% of the total movement amplitude. In contrast, vibration of the muscle agonist to the movement resulted in no change in movement end position. The vibrationinduced undershoot was associated with an increase in the EMG activity of the vibrated (antagonist) muscle and a resultant increase in the ratio of the antagonist to agonist EMG activity. The increase in antagonist EMG produced by the vibration occurred with a latency of approximately 60 ms from vibration onset.

The observed results are consistent with vibration-induced activation of muscle spindle receptors in the lengthening muscle during movement. It is suggested that, during movement, the sensitivity of the spindle receptors in the shortening muscle is decreased and the information concerning limb position during movement comes primarily from the lengthening muscle.

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References

  • Bianconi R, van der Meulen JP (1963) The responses to vibration of the end-organs of mammalian muscle spindles. J Neurophysiol 26: 177–190

    Google Scholar 

  • Brown MC, Engberg IE, Matthews PBC (1967) The relative sensitivity to vibration of muscle receptors on the cat. J Physiol (Lond) 192: 773–800

    Google Scholar 

  • Brown SHC, Cooke JD (1981) Amplitude- and instructiondependent modulation of movement-related electromyogram activity in humans. J Physiol (Lond) 316: 97–107

    Google Scholar 

  • Burgess PR, Wei JY, Clark FJ, Simon J (1982) Signalling of kinesthetic information by peripheral sensory receptors. Ann Rev Neurosci 5: 171–188

    Google Scholar 

  • Burke D, Hagbarth KE, Lofstedt L, Wallin BG (1976a) The responses of human muscle spindle endings to vibration of non-contracting muscles. J Physiol (Lond) 261: 673–693

    Google Scholar 

  • Burke D, Hagbarth KE, Lofstedt L, Wallin BG (1976b) The responses of human muscle spindle endings to vibration during isometric contraction. J Physiol (Lond) 261: 695–711

    Google Scholar 

  • Burton JE, Onoda N (1978) Dependence of the activity of interpositus and red nucleus neurons on sensory input data generated by movement. Brain Res 152: 41–63

    Google Scholar 

  • Capaday C, Cooke JD (1981) The effects of muscle vibration on the attainment of intended final position during voluntary human arm movements. Exp Brain Res 42: 228–230

    Google Scholar 

  • Conrad B, Meyer-Lohmann J, Matsunami K, Brooks VB (1975) Precentral unit activity following torque pulse injections into elbow movements. Brain Res 94: 219–236

    Google Scholar 

  • Evarts E, Tanji J (1976) Reflex and intended responses in motor cortex pyramidal tract neurones of monkey. J Neurophysiol 39: 1069–1080

    Google Scholar 

  • Goodwin GM, Luschei ES (1975) Discharge of spindle afferents from jaw-closing muscles during chewing in alert monkeys. J Neurophysiol 38: 560–571

    Google Scholar 

  • Goodwin GM, McCloskey DI, Matthews PBC (1972a) Proprioceptive illusions induced by muscle vibration: contribution to perception by muscle spindles? Science 175: 1382–1384

    Google Scholar 

  • Goodwin GM, McCloskey DI, Matthews PBC (1972b) The persistence of appreciable kinaesthesia after paralysing joint afferents by preserving muscle afferents. Brain Res 37: 322–325

    Google Scholar 

  • Goodwin GM, McCloskey DI, Matthews PBC (1974) The contribution of muscle afferents to kinaesthesia shown by vibration induced illusions of movement and by the effects of paralysing joint afferents. Brain 95: 705–748

    Google Scholar 

  • Hallett M, Shahani BT, Young RR (1975) EMG analysis of stereotyped voluntary movements in man. J Neurol Neurosurg Psychiat 38: 1154–1162

    Google Scholar 

  • Hammond PH, Merton PA, Sutton GG (1956) Nervous gradation of muscular contraction. Brit Med Bull 12: 214–218

    Google Scholar 

  • Lee RG, Tatton WG (1975) Motor responses to sudden limb displacements in primates with specific CNS lesions and in human patients with motor system disorders. Can J Neurol Sci 2: 285–293

    CAS  Google Scholar 

  • Lestienne F, Polit A, Bizzi E (1981) Functional organization of the motor process underlying the transition from movement to posture. Brain Res 230: 121–131

    Google Scholar 

  • Loeb GE, Duysens J (1979) Activity patterns in individual hindlimb primary and secondary muscle spindle afferents during performance of a biting task. J Neurophysiol 42: 710–725

    Google Scholar 

  • MacKay WA, Murphy JT (1979) Cerebellar modulation of reflex gain. Prog Neurobiol 13: 361–417

    Google Scholar 

  • Matthews PBC (1972) Mammalian muscle receptors and their central actions. Arnold, London

    Google Scholar 

  • Phillips CG, Powell TPS, Wiesendanger M (1971) Projection from low-threshold muscle afferents of hand and forearm to area 3a of baboon's cortex. J Physiol (Lond) 217: 419–446

    Google Scholar 

  • Prochazka A, Westerman RA, Ziccone SP (1976) Discharges of single hindlimb afferents in the freely moving cat. J Neurophysiol 39: 1090–1104

    Google Scholar 

  • Sakitt B (1980) A spring-model and equivalent neural network for arm posture control. Biol Cyber 37: 227–234

    Google Scholar 

  • Vallbo AB (1970) Discharge patterns in human muscle spindles during isometric voluntary contractions. Acta Physiol Scand 80: 552–566

    Google Scholar 

  • van Beekum WT (1979) The participation of muscle spindles in human position sense. Dutch Efficiency Bureau, Pijnacker

    Google Scholar 

  • Watt DGD, Stauffer EK, Taylor A, Reinking RM, Stuart DG (1976) Analysis of muscle receptor connections by spiketriggered averaging. 1. Spindle primary and tendon organ afferents. J Neurophysiol 39: 1375–1392

    Google Scholar 

  • Wiesendanger M (1978) Comments on the problem of transcortial reflexes. J Physiol (Paris) 74: 325–330

    Google Scholar 

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Authors and Affiliations

  1. Dept. of Physiology, University of Western Ontario, London, Ontario, Canada

    C. Capaday &  J. D. Cooke

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  1. C. Capaday
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  2. J. D. Cooke
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Supported by The Medical Research Council of Canada (Grant MT6699)

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Capaday, C., Cooke, J.D. Vibration-induced changes in movement-related EMG activity in humans. Exp Brain Res 52, 139–146 (1983). https://doi.org/10.1007/BF00237158

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  • DOI: https://doi.org/10.1007/BF00237158

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