Summary
The study was aimed at defining the role of hand (and arm) kinaesthetic information in coordination control of the visuo-oculo-manual tracking system. Baboons were trained to follow slow-moving and stepping visual targets either with the eyes alone or with the eyes and a lever moved by the forelimb about the vertical axis. A LED was attached to the lever extremity. Four oculo-manual tracking condidtions were tested and compared to eye-alone tracking: Eye and hand tracking of a visual target presented on a screen, eye tracking of the hand, and eye tracking of an imaginary target actively moved by the arm. The performance of the animals evaluated in terms of latency, and velocity and position precision for both eye and hand movements was seen to be equivalent to that of humans in similar situations. After dorsal root rhizotomy (C1-T2) the animals were unable to produce slow arm motion in response to slow-moving targets. Instead, they produced successions of ballistic-like motions whose amplitude decreased as retraining proceeded. In addition, the animals could not longer respond with smooth pursuit eye movements to an imaginary target actively displaced by the animal's forelimb. It was concluded that the absence of ocular smooth pursuit after lesion results from the disruption of a signal derived from arm kinaesthetic information and addresses to the oculomotor system. This signal is likely to be used in the control of coordination between arm and eye movements during visuo-oculo-manual tracking tasks. One cause of the animal's inability to achieve slow arm movement in response to slow target motion is thought to be due to a lesion-induced alteration of the spinal common pathway dynamics which normally integrate the velocity signal descending from the arm movement command system.
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References
Adams JA (1977) Feedback theory of how joint receptors regulate the timing and positioning of a limb. Psychol Rev 84: 504–523
Bahill AT, Stark L (1979) The trajectory of saccadic eye movements. Sci Am 240: 108–117
Batini C, Buisseret P, Kado RT (1974) Extraocular proprioceptive and trigeminal projections to the Purkinje cells of the cerebellar cortex. Arch Ital Biol 112: 1–17
Beaubaton D, Trouche E, Amato G, Grangetto A (1978) Dentate cooling in monkeys performing a visuo-motor pointing task. Neurosci Lett 8: 225–229
Bessou O, Laporte Y (1962) Responses from primary and secondary endings of the same neuromuscular spindle of the tenuissimus muscle of the cat. 105–119. In: Barker D (ed) Symposium on muscle receptors. Hong-Kong University Press, Hong-Kong
Bizzi E (1968) Discharge of frontal eye field neurons during saccadic and following eye movements in unanesthetized monkeys. Exp Brain Res 10: 69–80
Bossom J (1972) Time of recovery of voluntary movement following dorsal rhizotomy. Brain Res 45: 247–250
Bossom J (1974) Movement without proprioception. Brain Res 71: 285–296
Buchtel HA, Iosif G, Marchesi OF, Provini L, Strata P (1972) Analysis of the activity evoked in the cerebellar cortex by stimulation of the visual pathways. Exp Brain Res 15: 278–288
Contamin F (1976) Recherches sur la repousse intra-cordonale de fibres sensitives sectionnées dans la racine postérieure chez le chat. Rev Neurol Paris 132: 445–466
DeLong MR, Georgopoulos AP (1981) Motor functions of the basal ganglia. Handbook of physiology, Sect I, Chap 21. American Physiological Society, Bethesda, pp 1017–1069
Ebihara Y, Gauthier GM, Mandelbrojt P, Marchetti E, Mussa Ivaldi A, Vercher JL (1983) Coordination control in ocular and manual tracking of visual targets in monkeys. J Physiol (London) 345: 76–77
Evarts EV (1973) Brain mechanisms in the movement. Sci Am 229: 96–103
Flowers K (1978) Some frequency response characteristics of parkinsonism on pursuit tracking. Brain 101: 19–34
Fuchs AF (1967) Saccadic and smooth pursuit eye movement in the monkey. J Physiol (London) 191: 609–631
Fuchs AF, Kornhuber HH (1969) Extra-ocular muscle afferents to the cerebellum of the cat. J Physiol (London) 200: 713–722
Fuchs AF, Robinson DA (1966) A method for measuring horizontal and vertical eye movement chronically in the monkey. J Appl Physiol 21: 1068–1070
Gandevia SC (1982) The perception of motor commands or effort during muscular paralysis. Brain 105: 151–159
Gauthier GM, Hofferer JM (1976) Eye tracking of self-moved targets in the absence of vision. Exp Brain Res 26: 121–139
Gauthier GM, Hofferer JM, Mussa-Ivaldi F (1981) Etude des troubles oculomoteurs affectant certains enfants infirmes moteurs cérébraux: sémiologie instrumentale et possibilités de rééducation. Ann Med Physique 24: 64–76
Gauthier GM, Vercher JL, Mussa Ivaldi F, Marchetti E (1988) Oculo-manual tracking of visual targets: control learning and coordination control model. Exp Brain Res 73: 127–137
Gilman S, Carr D, Hollenberg J (1976) Kinematic effects of deafferentation and cerebellar ablation. Brain 99: 311–330
Goodwin GM, McCloskey DI, Matthews PBC (1972) The contribution of muscle afferents in kinaesthesia shown by vibration induced illusions of movement and by the effects of paralysing joint afferents. Brain 95: 705–748
Greer K, Harvey N (1978) Timing and positioning of limb movements: comments on Adam's theory. Psychol Rev 85: 482–484
Haaxma R, Kuypers HGJM 61975) Intrahemispheric cortical connexions and visual guidance of hand and finger movements in the rhesus monkey. Brain 98: 239–260
Held R, Bauer J (1967) Visually guided reaching in infant monkeys after restricted rearing. Science 155: 718–720
Held R, Bauer J (1974) Development of sensorially guided reaching in infant monkey. Brain Res 102: 27–43
Jeannerod M, Prablanc C, Perenin MT (1980) Do oculomotor signals contribute in eye-hand coordination. In: Stelmach G, Requin J (eds) Tutorials in motor behavior. Elsevier North Holland, Amsterdam, pp 297–303
Jones B (1976) The perception of passive joint-movements by cerebral palsied children. Dev Med Child Neurol 18: 25–30
Kato M, Hirata Y (1968) Sensory neurons in the spinal ventral roots of the cat. Brain Res 7: 479–482
Kelso JAS (1978) Joint receptors do not provide a satisfactory basis for motor timing and positioning. Psychol Rev 85: 474–481
Knapp HD, Taub E, Berman AJ (1963) Movements in monkeys with deafferented forelimb. Exp Neurol 7: 305–315
Lamarre Y, Bioulac B, Jacks B (1978) Activity of precentral neurones in conscious monkey's: effects of deafferentation and cerebellar ablation. J Physiol Paris, 74: 253–264
Mano NI (1979) Analyses of cerebellar Purkinje cell activity in relation to the direction, position and velocity of wrist tracking movement. In: Massion J, Sasaki K (eds) Cerebrocerebellar interactions. Elsevier, Amsterdam, pp 163–183
Mano NI, Yamamoto K (1980) Simple spike activity of cerebellar Purkinje cells related to visually guided wrist tracking movements in the monkey. J Neurophysiol 43-3: 713–728
Marsden CD, Rothwell JC, Day BL (1984) The use of peripheral feedback in the control of movement. TINS 7: 253–257
Mather JA, Lackner JR (1981) The influence of afferent, proprioceptive and timing factors on the accuracy of eye-hand tracking. Exp Brain Res 43: 406–412
Miall RC, Weir DJ, Stein JF (1986) Manual tracking of visual targets by trained monkeys. Behav Brain Res 20: 185–201
Miall RC, Weir DJ, Stein JF (1987) Visuo-motor tracking during reversible inactivation of the cerebellum. Exp Brain Res 65: 455–464
Navas I, Stark L (1968) Sampling or intermittency in hand control system dynamics. Biophys J 8: 252–302
Pelisson D, Prablanc C, Gooddale MA, Jeannerod M (1986) Visual control of reaching movements without vision of the limb. Exp Brain Res 62: 303–311
Polit A, Bizzi E (1978) Processes controlling arm movements in monkeys. Science 201: 1235–1237
Prablanc C, Echallier JF, Komilis E, Jeannerod M (1979) Optimal response of eye and hand motor systems in pointing at a visual target. Biol Cybern 35: 113–124
Roll JP, Vedel JP (1982) Kinaesthetic role of muscle afferents in man, studied by tendon vibration and microneurography. Exp Brain Res 47: 177–190
Schwarz DWF, Tomlinson RD (1977) Neuronal responses to eye muscle stretch in cerebellar lobule VI of the cat. Exp Brain Res 27: 101–111
Stark L (1968) Neurological control systems. Plenum Press, New York, pp 338–347
Steinbach MJ (1976) Pursuing the perceptual rather than the retinal stimulus. Vision Res 16: 1371–1376
Steinbach MJ, Held R (1968) Eye tracking of observer-generated target movements. Science 161: 187–188
Taub E, Berman AJ (1968) Movement and learning in the absence of sensory feedback. In: Freedman SJ (ed) The neurophysiology and spatially oriented behavior. Dorsey Press, Homewood Ill, pp 173–192
Taub E, Ellman SJ, Berman AJ (1966) Deafferentation in monkeys: effects on conditioned grasp response. Science 151: 593–594
Taub E, Goldberg IA, Taub P (1975) Deafferentation in monkeys: pointing at a target without visual feedback. Exp Neurol 46: 178–186
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Gauthier, G.M., Mussa Ivaldi, F. Oculo-manual tracking of visual targets in monkey: role of the arm afferent information in the control of arm and eye movements. Exp Brain Res 73, 138–154 (1988). https://doi.org/10.1007/BF00279668
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DOI: https://doi.org/10.1007/BF00279668