Abstract
A model for the stretch reflex is proposed incorporating a nonlinear description of muscle receptor behavior, a delay in the reflex loop and a model of muscle mechanical properties. The model adequately describes the nonlinear response properties of EMG and force to constant ramps in loading and unloading direction. The EMG responses during the ramp and at ramp plateau could be simulated adequately for all ramp velocities except for high stretch velocities where EMG activity appeared in bursts, presumably due to spinal nonlinearities. Force responses during ramp stretches could be simulated except at ramp plateau, where the measured force response decayed slower than the simulated responses. The model also explained that EMG and force responses during ramp stretches after a displacement of about 1 cm could be approximately described by a product relationship between a position-related term and a low-fractional power of velocity. During unloading ramps the model did not predict a clear velocity dependence in agreement with the data.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abbott BC, Aubert XM (1952) The force exerted by active striated muscle during and after change of length. J Physiol (London) 117:77–86
Aldridge A, Stein RB (1982) Nonlinear properties of stretch reflex studied in the decerebrate cat. J Neurophysiol 47:179–192
Bawa P, Mannard A, Stein RB (1976) Predictions and experimental tests of a visco-elastic muscle model using elastic and inertial loads. Biol Cybern 22:139–145
Bigland B, Lippold OCJ (1954) The relation between force, velocity and integrated electrical activity in human muscles. J Physiol (London) 123:214–224
Brown MC, Goodwin GM, Matthews PBC (1969) After-effects of fusimotor stimulation on the response of muscle spindle primary afferent endings. J Physiol (London) 205:667–694
Carp JS, Boskov D, Rymer WZ (1986) Nonlinear muscle spindle behavior in stretch reflex of the decerebrate cat. Soc Neurosci 12(1):681 (abstr)
Crowe A, Matthews PBC (1964) The effects of stimulation of static and dynamic fusimotor fibres on the response to stretching of the primary endings of muscle spindles. J Physiol (London) 174:109–131
Cussons PD, Hulliger M, Matthews PBS (1977) Effects of fusimotor stimulation on the responses of the secondary endings of the muscle spindle to sinusoidal stretching. J Physiol (London) 270:835–850
DeLuca CJ, LeFever RS, McCue MP, Xenakis AP (1982a) Behavior of human motor units in different muscles during linearly varying contractions. J Physiol (London) 329:113–128
DeLuca CJ, LeFever RS, McCue MP, Xenakis AP (1982b) Control scheme governing concurrently active human motor units during voluntary contractuons. J Physiol (London) 329:129–142
Edman KAP, Elzinga G, Noble MIM (1976) Force enhancement induced by stretch of contracting single skeletal muscle fibres of the frog. J Physiol (London) 258:95P-96P
Gielen CCAM, Houk JC (1984) Nonlinear viscosity of human wrist. J Neurophysiol 52:553–569
Gielen CCAM, Houk JC, Marcus SL, Miller LE (1984) Viscoelastic properties of the wrist motor servo in man. Ann Biomed Eng 12:599–620
Hasan Z (1983) A nodel of spindle afferent response to muscle stretch. J Neurophysiol 49:989–1006
Hasan Z, Houk JC (1975a) Analysis of response properties of deefferented mammalian spindle receptors based on frequency response. J Neurophysiol 38:663–672
Hasan Z, Houk JC (1975b) Transition in sensitivity of spindle receptors that occurs when muscle is stretched more than a fraction of a millimeter. J Neurophysiol 38:673–689
Hill AV (1938) The heat of shortening and theories of contraction. Proc R Soc Ser B 126:136–195
Houk JC (1981) Afferent mechanisms mediating autogenic reflexes. In: Marsan CA, Pompeiano O (eds) Brain mechanisms of perceptual awareness and purposeful behavior. Raven Press, New York, pp 167–181
Houk J, Gielen C (1986) Stiffness versus length control. Proc Int Union Physiol Sci 16:253
Houk JC, Rymer WZ (1981) Neural control of muscle length and tension. In: Brooks VB (ed) Motor control. Handbook of physiology, sect 1, vol I. American Physiological Society, Bethesda, Md, pp 257–323
Houk JC, Singer JJ, Goldman MR (1970) An evaluation of length and force feedback to soleus muscles of decerebrate cat. J Neurophysiol 33:784–811
Houk JC, Harris DA, Hasan Z (1973) Non-linear behavior of spindle receptors. In: Stein RB, Pearson KB, Smith RS, Redford JB (eds) Control of posture and locomotion. Plenum, New York, pp 147–163
Houk JC, Rymer WZ, Crago PE (1981 a). Dependence of dynamic response of spindle receptors on muscle length and velocity. J Neurophysiol 46:143–166
Houk JC, Crago PE, Rymer WZ (1981 b) Function of the spindle dynamic response in stiffness regulation. A predictive mechanism provided by non-linear feedback. In: Taylor H, Prochazka A (eds) Muscle receptors and movement. MacMillan, London, pp 229–309
Huxley AF (1957) Muscle structure and theories of contraction. Proc Biophys Biophys Chem 7:257–318
Jack JJB, Roberts RC (1978) The role of muscle spindle afferents in stretch and vibration reflexes of the soleus muscle of the decerebrate cat. Brain Res 146:366–372
Jørgensen K (1976) Force-velocity relationship in human elbow flexons and extensors. In: Komi (ed) International series on biomechanics, vol 1A. University Press, pp 145–151
Joyce GC, Rack PMH (1969) Isotonic lengthening and shortening movements of cat soleus muscle. J Physiol (London) 204:475–491
Joyce GC, Rack PMH, Westbury DR (1969) The mechanical properties of cat soleus muscle during controlled lengthening and shortening movements. J Physiol (London) 204:461–474
Julian FJ, Morgan DL (1979) The effect on tension of nonuniform distribution of length changes applied to frog muscle fibres. J Physiol (Lond) 293:379–392
Kilmer W, Kroll W, Pelosi R (1983) On the stability of delay equation models of simple human stretch reflexes. J Math Biol 17:331–349
Lennerstrand G (1968) Position and velocity sensitivity of muscle spindles in the cat. I. Primary and secondary endings deprived of fusimotor activation. Acta Physiol Scand 73:281–299
Lennerstrand G, Thoden U (1968) Dynamic analysis of muscle spindle endings in the cat using length changes of different length-time relations. Acta Physiol Scand 73:234–250
Matthews PBC (1969) Evidence that the secondary as well as the primary endings of the muscle spindles may be responsible for the tonic stretch reflex of the decerebrate cat. J Physiol (Lond) 204:365–393
Matthews PBC (1972) Mammalian muscle receptors and their central actions. Arnold, London
Matthews PBC, Stein RB (1969) The sensitivity of muscle spindle afferents to sinusoidal stretching. J Physiol (Lond) 200:723–743
Oguztoreli MN, Stein RB (1976) The effects of multiple reflex pathways on the oscillations in neuro-muscular systems. J Math Biol 3:87–101
Poppele RE, Bowman RJ (1970) Quantitative description of linear behavior of mammalian muscle spindles. J Neurophysiol 33:59–72
Prochazka A (1981) Muscle spindle function during normal movement. In: Porter R (ed) Neurophysiology IV, vol 25. University Park, Baltimore, Md pp 47–90
Rack PMH (1981) Limitations of somatosensory feedback in control of posture and movement. In: Brooks VB (ed). Motor control. Handbook of physiology, sect 1, vol II. American Physiological Society, Bethesda, Md, pp 229–259
Rack PMH, Ross HF (1984) The tendon of flexor pollicis longus: its effects on the muscular control of force and position at the human thumb. J Physiol (Lond) 351:99–110
Rymer WZ, Hasan Z (1980) Absence of force feedback in soleus muscle of the decerebrate cat. Brain Res 184:203–209
Stein RB (1974) The peripheral control of movement. Physiol Rev 54:215–243
Wei HY, Kripke BR, Burgess PR (1986) Classification of muscle spindle receptors. Brain Res 370:119–126
Zahalak GI (1981) A distribution-moment approximation for kinetic theories of muscular contraction. Math Biosci 55:89–114
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Gielen, C.C.A.M., Houk, J.C. A model of the motor servo: Incorporating nonlinear spindle receptor and muscle mechanical properties. Biol. Cybern. 57, 217–231 (1987). https://doi.org/10.1007/BF00338815
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF00338815