Human Muscle Spindle Sensitivity Reflects the Balance of Activity between Antagonistic Muscles

Muscle spindles are commonly considered as stretch receptors encoding movement, but the functional consequence of their efferent control has remained unclear. The “α–γ coactivation” hypothesis states that activity in a muscle is positively related to the output of its spindle afferents. However, in addition to the above, possible reciprocal inhibition of spindle controllers entails a negative relationship between contractile activity in one muscle and spindle afferent output from its antagonist. By recording spindle afferent responses from alert humans using microneurography, I show that spindle output does reflect antagonistic muscle balance. Specifically, regardless of identical kinematic profiles across active finger movements, stretch of the loaded antagonist muscle (i.e., extensor) was accompanied by increased afferent firing rates from this muscle compared with the baseline case of no constant external load. In contrast, spindle firing rates from the stretching antagonist were lowest when the agonist muscle powering movement (i.e., flexor) acted against an additional resistive load. Stepwise regressions confirmed that instantaneous velocity, extensor, and flexor muscle activity had a significant effect on spindle afferent responses, with flexor activity having a negative effect. Therefore, the results indicate that, as consequence of their efferent control, spindle sensitivity (gain) to muscle stretch reflects the balance of activity between antagonistic muscles rather than only the activity of the spindle-bearing muscle.

[1]  A Prochazka,et al.  The continuing debate about CNS control of proprioception , 1998, The Journal of physiology.

[2]  N Kakuda,et al.  Coupling between single muscle spindle afferent and EMG in human wrist extensor muscles: physiological evidence of skeletofusimotor (beta) innervation. , 1998, Electroencephalography and clinical neurophysiology.

[3]  T. Sears Efferent discharges in alpha and fusimotor fibres of intercostal nerves of the cat , 1964, The Journal of physiology.

[4]  Benoni B. Edin,et al.  Single unit retrieval in microneurography: a microprocessor-based device controlled by an operator , 1988, Journal of Neuroscience Methods.

[5]  Eric J. Perreault,et al.  Stretch sensitive reflexes as an adaptive mechanism for maintaining limb stability , 2010, Clinical Neurophysiology.

[6]  Bernard Grandjean,et al.  Model-based prediction of fusimotor activity and its effect on muscle spindle activity during voluntary wrist movements , 2013, Journal of Computational Neuroscience.

[7]  Hagbarth Ke,et al.  Mechnoreceptor activity recorded from human peripheral nerves. , 1968 .

[8]  Reza Shadmehr,et al.  Internal models of limb dynamics and the encoding of limb state , 2005, Journal of neural engineering.

[9]  J. Andrew Pruszynski,et al.  Primary motor cortex underlies multi-joint integration for fast feedback control , 2011, Nature.

[10]  P. Zangger,et al.  ‘Fusimotor set’: new evidence for α-independent control of γ-motoneurones during movement in the awake cat , 1985, Brain Research.

[11]  P. Matthews,et al.  Mammalian muscle receptors and their central actions , 1974 .

[12]  B. Edin,et al.  Discharges in Human Muscle Receptor Afferents during Block Grasping , 2008, The Journal of Neuroscience.

[13]  B. Edin,et al.  Discharges in human muscle spindle afferents during a key‐pressing task , 2008, The Journal of physiology.

[14]  B. Edin,et al.  Human Muscle Spindles Act as Forward Sensory Models , 2010, Current Biology.

[15]  Uwe Windhorst,et al.  Muscle spindles are multi-functional , 2008, Brain Research Bulletin.

[16]  D. McCloskey,et al.  Proprioceptive Illusions Induced by Muscle Vibration: Contribution by Muscle Spindles to Perception? , 1972, Science.

[17]  M. Illert,et al.  Skeletofusimotor (β) innervation of proximal and distal forelimb muscles of the cat , 1995, Neuroscience Letters.

[18]  H. Helmholtz Handbuch der physiologischen Optik , 2015 .

[19]  B. Edin,et al.  Dynamic response of human muscle spindle afferents to stretch. , 1990, Journal of neurophysiology.

[20]  J. Houk An assessment of stretch reflex function. , 1976, Progress in brain research.

[21]  A. Vallbo,et al.  Discharge patterns in human muscle spindle afferents during isometric voluntary contractions. , 1970, Acta physiologica Scandinavica.

[22]  Michael I. Jordan,et al.  An internal model for sensorimotor integration. , 1995, Science.

[23]  A. Prochazka Proprioceptive Feedback and Movement Regulation , 2011 .

[24]  Glenn Carruthers,et al.  The case for the comparator model as an explanation of the sense of agency and its breakdowns , 2012, Consciousness and Cognition.

[25]  J. A. Pruszynski,et al.  Temporal evolution of "automatic gain-scaling". , 2009, Journal of neurophysiology.

[26]  Zoubin Ghahramani,et al.  Computational principles of movement neuroscience , 2000, Nature Neuroscience.

[27]  C. Marsden,et al.  Servo action in the human thumb. , 1976, The Journal of physiology.

[28]  J. Petit,et al.  A quantitative study of skeletofusimotor innervation in the cat peroneus tertius muscle. , 1982, The Journal of physiology.

[29]  N Kakuda,et al.  Dynamic response of human muscle spindle afferents to stretch during voluntary contraction , 1998, Journal of Physiology.

[30]  J. Roll,et al.  Kinaesthetic role of muscle afferents in man, studied by tendon vibration and microneurography , 2004, Experimental Brain Research.

[31]  Uwe Proske,et al.  What is the role of muscle receptors in proprioception? , 2005, Muscle & nerve.

[32]  U. Windhorst Muscle proprioceptive feedback and spinal networks , 2007, Brain Research Bulletin.

[33]  S. Gandevia,et al.  The kinaesthetic senses , 2009, The Journal of physiology.

[34]  A. Prochazka,et al.  Sensory systems in the control of movement. , 2012, Comprehensive Physiology.

[35]  B. Edin,et al.  Muscle afferent responses to isometric contractions and relaxations in humans. , 1990, Journal of neurophysiology.

[36]  R. Shadmehr,et al.  Adaptation and generalization in acceleration-dependent force fields , 2006, Experimental Brain Research.

[37]  R. Sperry Neural basis of the spontaneous optokinetic response produced by visual inversion. , 1950, Journal of comparative and physiological psychology.

[38]  D. Wolpert,et al.  Abnormalities in the awareness and control of action. , 2000, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[39]  J. A. Pruszynski,et al.  Long-Latency Reflexes of the Human Arm Reflect an Internal Model of Limb Dynamics , 2008, Current Biology.

[40]  T. Sinkjaer,et al.  Muscle stiffness in human ankle dorsiflexors: intrinsic and reflex components. , 1988, Journal of neurophysiology.

[41]  R. Durbaba,et al.  Distinctive patterns of static and dynamic gamma motor activity during locomotion in the decerebrate cat , 2000, The Journal of physiology.

[42]  A Prochazka,et al.  'Fusimotor set': new evidence for alpha-independent control of gamma-motoneurones during movement in the awake cat. , 1985, Brain research.

[43]  J. A. Pruszynski,et al.  Optimal feedback control and the long-latency stretch response , 2012, Experimental Brain Research.

[44]  C. Frith The self in action: Lessons from delusions of control , 2005, Consciousness and Cognition.