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01-01-2012 | Research Article

Suppression of proprioceptive feedback control in movement sequences through intermediate targets

Authors: C. Minos Niu, Daniel M. Corcos, Mark B. Shapiro

Published in: Experimental Brain Research | Issue 2/2012

Abstract

Simple movements can be seen as building blocks for complex action sequences, and neural control of an action sequence can be expected to preserve some control features of its constituent blocks. It was previously found that during single-joint elbow movements to a single target, the proprioceptive feedback control is initially suppressed, and we tested this feedback suppression in a two-segment sequence during which subjects momentarily slowed down at an intermediate target at a 30° distance (first segment) and then immediately moved another 30° to the final target (second segment). Either the first or second segment was unexpectedly perturbed; the latency of the earliest response to the perturbation in the muscle surface electromyogram was analyzed. The perturbations were delivered either at the onset of each segment or about 0.1 s later. We found that in both segments, the response latency to the late perturbation was shorter than the latency to the early perturbation, which suggests that the proprioceptive feedback control is suppressed in the beginning of each segment. Next, we determined the latency of the response to unexpected perturbations in 30° movements to a single target. We found that the response latency was not significantly different in the movement to a single target and in each segment in the sequence. This result suggests that the initial suppression of the proprioceptive feedback control in movements to single targets is preserved in movements through intermediate targets and supports the idea of modular organization of neural control of movement sequences.

Alexander GE, DeLong MR, Crutcher MD (1992) Do cortical and basal ganglionic motor areas use “motor programs” to control movement? Behav Brain Sci 15(4):656–665

Armitage P, Berry G (1994) Statistical methods in medical research. 3rd edn. Blackwell Science, Oxford. ISBN 0632036958

Aymard C, Baret M, Katz R, Lafitte C, Penicaud A, Raoul S (2001) Modulation of presynaptic inhibition of la afferents during voluntary wrist flexion and extension in man. Exp Brain Res 137(1):127–131PubMedCrossRef

Baldauf D, Cui H, Andersen RA (2008) The posterior parietal cortex encodes in parallel both goals for double-reach sequences. J Neurosci 28(40):10081–10089. doi:10.1523/jneurosci.3423-08.2008 PubMedCrossRef

Basmajian JV, DeLuca CJ (1985) Muscle alive. Their functions revealed by electromyography, 5th edn. Williams & Wilkins Comp, Baltimore

Bennett DJ (1994) Stretch reflex responses in the human elbow joint during a voluntary movement. J Physiol (Lond) 474(2):339–351

Brown SH, Cooke JD (1981) Responses to force perturbations preceding voluntary human arm movements. Brain Res 220(2):350–355PubMedCrossRef

Brown SH, Cooke JD (1986) Initial agonist burst is modified by perturbations preceding movement. Brain Res 377(2):311–322PubMedCrossRef

Churchland MM, Santhanam G, Shenoy KV (2006) Preparatory activity in premotor and motor cortex reflects the speed of the upcoming reach. J Neurophysiol 96(6):3130–3146PubMedCrossRef

Cisek P (2005) Neural representations of motor plans, desired trajectories, and controlled objects. Cogn Process 6:15–24. doi:10.1007/s10339-004-0046-7 CrossRef

Cisek P, Crammond DJ, Kalaska JF (2003) Neural activity in primary motor and dorsal premotor cortex in reaching tasks with the contralateral versus ipsilateral arm. J Neurophysiol 89(2):922–942. doi:10.1152/jn.00607.2002 PubMedCrossRef

Conrad B, Meyer-Lohmann J, Matsunami K, Brooks VB (1975) Precentral unit activity following torque pulse injections into elbow movements. Brain Res 94(2):219–236. doi:0006-8993(75)90058-X PubMedCrossRef

David FJ, Poon C, Niu CM, Corcos DM, Shapiro MB (2009) EMG responses to unexpected perturbations are delayed in slower movements. Exp Brain Res 199(1):27–38PubMedCrossRef

Day BL, Marsden CD (1982) Accurate repositioning of the human thumb against unpredictable dynamic loads is dependent upon peripheral feed-back. J Physiol (Lond) 327:393–407

Desmurget M, Epstein CM, Turner RS, Prablanc C, Alexander GE, Grafton ST (1999) Role of the posterior parietal cortex in updating reaching movements to a visual target. Nat Neurosci 2(6):563–567PubMedCrossRef

Donchin O, Gribova A, Steinberg O, Bergman H, Vaadia E (1998) Primary motor cortex is involved in bimanual coordination. Nature 395(6699):274–278PubMedCrossRef

Fischer MH, Rosenbaum DA, Vaughan J (1997) Speed and sequential effects in reaching. J Exp Psychol Hum Percept Perform 23(2):404–428PubMedCrossRef

Flash T, Hogan N (1985) The coordination of arm movements: an experimentally confirmed mathematical model. J Neurosci 5(7):1688–1703PubMed

Franklin DW, Burdet E, Peng Tee K, Osu R, Chew C-M, Milner TE, Kawato M (2008) CNS learns stable, accurate, and efficient movements using a simple algorithm. J Neurosci 28(44):11165–11173. doi:10.1523/jneurosci.3099-08.2008 PubMedCrossRef

Fujii N, Graybiel AM (2003) Representation of action sequence boundaries by macaque prefrontal cortical neurons. Science 301(5637):1246–1249. doi:10.1126/science.1086872 PubMedCrossRef

Ghez C, Scheidt R, Heijink H (2007) Different learned coordinate frames for planning trajectories and final positions in reaching. J Neurophysiol 98(6):3614–3626. doi:10.1152/jn.00652.2007 PubMedCrossRef

Gottlieb GL (1996) On the voluntary movement of compliant (inertial-viscoelastic) loads by parcellated control mechanisms. J Neurophysiol 76(5):3207–3229PubMed

Hallett M, Marsden CD (1979) Ballistic flexion movements of the human thumb. J Physiol (Lond) 294:33–50

Hasan Z (2005) The human motor control system’s response to mechanical perturbation: should it, can it, and does it ensure stability? J Mot Behav 37(6):484–493PubMedCrossRef

Hayashi R, Becker WJ, Lee RG (1990) Effects of unexpected perturbations on trajectories and EMG patterns of rapid wrist flexion movements in humans. Neurosci Res (NY) 8(2):100–113CrossRef

Hesse C, Deubel H (2010) Advance planning in sequential pick-and-place tasks. J Neurophysiol 104(1):508–516PubMedCrossRef

Hoshi E, Tanji J (2000) Integration of target and body-part information in the premotor cortex when planning action. Nature 408(6811):466–470PubMedCrossRef

Kurtzer I, Pruszynski JA, Scott SH (2009) Long-latency responses during reaching account for the mechanical interaction between the shoulder and elbow joints. J Neurophysiol 102(5):3004–3015. doi:10.1152/jn.00453.2009 PubMedCrossRef

Latash ML (1994) Control of fast elbow movement: a study of electromyographic patterns during movements against unexpectedly decreased inertial load. Exp Brain Res 98(1):145–152PubMedCrossRef

Lu X, Ashe J (2005) Anticipatory activity in primary motor cortex codes memorized movement sequences. Neuron 45(6):967–973PubMedCrossRef

Meunier S, Pierrot-Deseilligny E (1998) Cortical control of presynaptic inhibition of Ia afferents in humans. Exp Brain Res 119(4):415–426PubMedCrossRef

Mushiake H, Saito N, Sakamoto K, Itoyama Y, Tanji J (2006) Activity in the lateral prefrontal cortex reflects multiple steps of future events in action plans. Neuron 50(4):631–641PubMedCrossRef

Nakajima T, Hosaka R, Mushiake H, Tanji J (2009) Covert representation of second-next movement in the pre-supplementary motor area of monkeys. J Neurophysiol 101(4):1883–1889. doi:10.1152/jn.90636.2008 PubMedCrossRef

Nichols TR (1973) Reflex and non-reflex stiffness of soleus muscle in the cat. In: Stein RB, Pearson KB, Smith RS, Redford JB (eds) Control of posture and locomotion, vol 7. Advances in behavioral biology. Plenum, New York, pp 407–410

Niu CM, Corcos DM, Shapiro MB (2010) Temporal shift from velocity to position proprioceptive feedback control during reaching movements. J Neurophysiol 104(5):2512–2522PubMedCrossRef

Prablanc C, Desmurget M, Grea H (2003) Neural control of on-line guidance of hand reaching movements. Prog Brain Res 142:155–170PubMedCrossRef

Prochazka A, Trend PS (1988) Instability of human forearm movements studied with feedback controlled muscle vibration. J Physiol 402:421–442PubMed

Scheidt RA, Dingwell JB, Mussa-Ivaldi FA (2001) Learning to move amid uncertainty. J Neurophysiol 86(2):971–985PubMed

Seki K, Perlmutter SI, Fetz EE (2003) Sensory input to primate spinal cord is presynaptically inhibited during voluntary movement. Nat Neurosci 6(12):1309–1316PubMedCrossRef

Shapiro MB, Gottlieb GL, Moore CG, Corcos DM (2002) Electromyographic responses to an unexpected load in fast voluntary movements: descending regulation of segmental reflexes. J Neurophysiol 88(2):1059–1063PubMed

Shapiro MB, Gottlieb GL, Corcos DM (2004) EMG responses to an unexpected load in fast movements are delayed with an increase in the expected movement time. J Neurophysiol 91(5):2135–2147PubMedCrossRef

Shapiro MB, Niu CM, Poon C, David FJ, Corcos DM (2009) Proprioceptive feedback during point-to-point arm movements is tuned to the expected dynamics of the task. Exp Brain Res 195(4):575–591PubMedCrossRef

Shen L, Alexander GE (1997) Preferential representation of instructed target location versus limb trajectory in dorsal premotor area. J Neurophysiol 77(3):1195–1212PubMed

Soechting JF, Dufresne JR, Lacquaniti F (1981) Time-varying properties of myotatic response in man during some simple motor tasks. J Neurophysiol 46(6):1226–1243PubMed

Sosnik R, Hauptmann B, Karni A, Flash T (2004) When practice leads to co-articulation: the evolution of geometrically defined movement primitives. Exp Brain Res 156(4):422–438PubMedCrossRef

Stein RB (1995) Presynaptic inhibition in humans. Prog Neurobiol 47(6):533–544PubMedCrossRef

Tanji J, Shima K (1994) Role for supplementary motor area cells in planning several movements ahead. Nature 371(6496):413–416PubMedCrossRef

Tanji J, Okano K, Sato KC (1987) Relation of neurons in the nonprimary motor cortex to bilateral hand movement. Nature 327(6123):618–620PubMedCrossRef

Vindras P, Viviani P (2005) Planning short pointing sequences. Exp Brain Res 160(2):141–153PubMedCrossRef

Wolpert DM, Kawato M (1998) Multiple paired forward and inverse models for motor control. Neural Netw 11(7–8):1317–1329PubMedCrossRef

Title: Suppression of proprioceptive feedback control in movement sequences through intermediate targets
Authors: C. Minos Niu
Daniel M. Corcos
Mark B. Shapiro
Publication date: 01-01-2012
Publisher: Springer-Verlag
Published in: Experimental Brain Research / Issue 2/2012
Print ISSN: 0014-4819
Electronic ISSN: 1432-1106
DOI: https://doi.org/10.1007/s00221-011-2928-0

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Suppression of proprioceptive feedback control in movement sequences through intermediate targets

Abstract

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