Abstract
In the framework of the cognitive neuroscience research strategy, data are accumulating which provide strong support for the central assumption of motor control studies : the organization of motor behavior would be based upon the utilization by the motor system of information stored in memory in the form of multiple, more or less abstract, hierarchically-organised representations of motor actions. Especially, studies conducted with single-neuron recording techniques in monkeys trained in tasks derived from those used in cognitive psychology, have demonstrated brain mechanisms which can be associated with three levels of representational processes. At the highest level, which may be called “semantic”, the action goal would be represented in a non-motoric, holistic, context-independent and symbolic mode, from which the “response” to be made is determined. At the middle level, which may be called “syntactic”, the motor features would be represented in a non-motoric, parametric, context-dependent and subsymbolic mode, from which the subroutines of the motor program would be specified and then assembled. At the lowest level, motor commands would be represented in a motoric, anatomical, biomechanically-constrained and neuromuscular mode which, when activated, results in a specific motor output. However, neurophysiological data appear to be increasingly incompatible with the traditional view in which, according to the hypothesis of a one-to-one mapping between functional processes and neural structures, these three representational levels would be implemented in association,premotor and motor cortical areas, respectively. The functional heterogeneity of cortical areas, which differ quantitatively more than qualitatively, as well as the continuum of function for individual neurons, between which differences are also more quantitative than qualitative, suggest another organization of the neocortex: each “behavioral” function would be implemented in a widely distributed neuronal network, which explains that the three different representational functions can be found closely intermixed in the same cortical region. A key point for future research is, thus, to understand how cognitive processes, as representations of action, are implemented in the microstructure of the cortical tissue.
This work was supported by ONR grant N00014 89 J1557
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References
Andersen, R.A. (1989) Visual and eye movement functions of the posterior parietal cortex, Annual Review of Neuroscience, 12, 377–403.
Andersen, R.A., Essick, G.K., and Siegel, R.M. (1987) Neurons of area 7 activated by both visual stimuli and oculomotor behavior, Experimental Brain Research, 67, 316–322.
Bizzi, E. (1980) Central and peripheral mechanisms in motor control, in G.E. Stelmach and J. Requin (eds.), Tutorials in Motor Behavior, North-Holland, Amsterdam, pp. 131–143.
Bonnet, M. (1983) Anticipatory changes of long latency stretch responses during preparation for directional hand movements, Brain Research 280, 51–62.
Bonnet, M., and MacKay, W.A. (1989) Changes in CNV and reaction time related to precueing of direction and force of a forearm movement, Brain, Behavior and Evolution 33, 147–152.
Bonnet, M., Requin, J., and Stelmach, G.E. (in press) Changes in electromyographic responses to muscle stretch, related to the programming of movement spatial parameters, EEG and Clinical Neurophysiology.
Brooks, V.B. (1979) Motor programs revisited, in R.E. Talbott and D.R. Humphrey (eds.), Posture and Movement, Raven Press, New York, pp. 13– 49.
Coles, M.G.H., Gratton, C., and Donchin, E. (1988) Detecting early communication: using measures of movement-related potentials to illuminate human information processing, Biological Psychology 26, 69–89.
Eriksen, B.A., and Eriksen, C.W. (1974) Effects of noise letters upon the identification of target letter in visual search, Perception and Psychophysics 16, 143–149.
Eriksen, C.W., Coles, M.G.H., Morris, L.R., and O’Hara, W.P. (1985) An electromyographic examination of response competition, Bulletin of the Psychonomic Society 23, 165–168.
Evarts, E.V. (1984) Neurophysiological approaches to brain mechanisms for preparatory set, in S. Kornblum and J. Requin (eds.), Preparatory States and Processes, Lawrence Erlbaum, Hillsdale, pp. 137–153.
Evarts, E.V., Bizzi, E., Burke, R.E., Delong, M., and Thach, W.T. (1971) Central control of movement, Neurosciences Research Program Bulletin 9, n° 1.
Evarts, E.V., Shinoda, Y., and Wise, S.P. (1984) Neurophysiological approaches to higher brain functions, Wiley and Sons, New York.
Georgopoulos, A.P. (1990) Neurophysiology of reaching, in M. Jeannerod (ed.), Attention and Performance XIII, Lawrence Erlbaum, Hillsdale, pp. 227– 263.
Godschalk, M., and Lemon, R.N. (1983) Involvement of monkey premotor cortex in the preparation of arm movements, Experimental Brain Research , suppl. 7, 114–119.
Goldman-Rakic, P.S. (1988) Topography of cognition: parallel distributed networks in primate associative cortex, Annual Review of Neuroscience, 11, 137–156.
Grillner, S. (1975) Locomotion in vertebrates: central mechanisms and reflex interactions, Physiological Reviews 55, 247–304.
Kalaska, J.F. (1988) The representation of arm movements in postcentral and parietal cortex, Canadian Journal of Physiological Pharmacology 66, 455– 463.
Kurata, K., and Tanji, J. (1985) Contrasting neuronal activity in supplementary and precentral motor cortex of monkeys. II. Responses to movement triggering vs nontriggering sensory signals, Journal of Neurophysiology, 53, 142–152.
Kutas, M., and Donchin, E. (1980) Preparation to respond as manifested by movement-related brain potentials, Brain Research 202, 95–115.
Lashley, K.S. (1951) The problem of serial order in behavior, in L.A. Jeffress (ed.), Central mechanisms in behavior, Wiley, New York, pp.
Lecas, J.C., Requin, J., Anger, C., and Vitton, N. (1986) Changes in neuronal activity of the monkey precentral cortex during preparation for movement, Journal of Neurophysiology, 56, 1680–1702.
Lemon, R. (1989) Cognitive control of movement, Nature 337, 410–411.
Lynch, J.C. (1980) The functional organization of posterior parietal association cortex, Behavioral and Brain Sciences, 3, 485–534.
Mountcastle, V.B. (1978) An organizing principle for cerebral function: the unit module and the distributed system, in F.O. Schmitt and F.G. Worden (eds.), The Neurosciences. Fourth Study Program, MIT Press, Cambridge, pp. 21–42.
Mountcastle, V.B., Lynch, J.C., Georgopoulos, A., Sakata, H., and Acuna, C. (1975) Posterior parietal association cortex of the monkey: command functions for operations within extrapersonal space, Journal of Neurophysiology 38, 871–908.
Paillard, J. (1982) Apraxia and neurophysiology of motor control, Philosophical Transactions, Royal Society of London. B 298, 111–134.
Requin, J., Lecas, J.C., Vitton, N. (1990) A comparison of preparation-related neuronal activity changes in the prefrontal, premotor, primary motor and posterior parietal areas of the monkey cortex: preliminary results, Neuroscience Letters 111, 151–156.
Requin, J., Riehle, A., and Seal, J. (1988) Neuronal activity and information processing in motor control: from stages to continuous flow, Biological Psychology, 26, 179–198.
Requin, J., Riehle, A., Seal, J. (in press) Neuronal networks for movement preparation, in D.E. Meyer and S. Kornblum (eds.), Attention and Performace XIV. Lawrence Erlbaum, Hillsdale.
Riehle, A., and Requin, J. (1989) Monkey primary motor and premotor cortex: single-cell activity related to prior information about direction and extent of an intended movement, Journal of Neurophysiology, 61 (3), 534–549.
Rizzolatti, G., Camarda, R., Fogassi, L., Gentilucci, M., Luppino, G and Matelli, M. (1988) Functional organization of inferior area 6 in the macaque monkey, Experimental Brain Research 71, 491–507.
Schmidt, R.A. (1982) Motor control and learning. A behavioral emphasis, Human Kinetics, Champaign.
Seal, J. (1989) Sensory and motor functions of the superior parietal cortex of the monkey as revealed by single neuron recordings, Brain, Behavior and Evolution, 33, 113–117.
Seal, J., and Requin, J. (1987) Sensory to motor transformation within area 5 of the posterior parietal cortex in the monkey, Society for Neuroscience Abstracts 13, part 1, p. 673.
Shaffer, L.H. (1982) Rhythm and timing in skill, Psychological Review, 89, 102– 122.
Smolensky, P. (1988) On the proper treatment of connectionism, Behavioral and Brain Sciences 11, 1–74.
Tanji, J., and Kurata, K. (1982) Comparison of movement-related activity in two cortical motor areas of primates, Journal of Neurophysiology, 48, 633–653.
Tanji, J., Taniguchi, J., and Saga, T. (1980) Supplementary motor area: neuronal response to motor instructions, Journal of Neurophysiology 44, 60–68.
Vidal, F., Bonnet, M. and Macar, F. (in press) Programming response duration in a precueing reaction time paradigm, Journal of Motor Behavior.
Von Monakow, C. (1914) Die Lokalisation im Grosshirn und der Abbau der Funktion durch kortikale Herde, Bergman, Wiesbaden.
Wiesendanger, M. (1990) The motor cortical areas and the problem of hierarchies, in M. Jeannerod (ed.), Attention and Performance XIII, Lawrence Erlbaum, Hillsdale, pp. 59–75.
Wise, S.P. (1985) The primate premotor cortex: past, present, and preparatory, Annual Review of Neuroscience, 8, 1–19.
Wise, S.P., and Mauritz, K.H. (1985) Set-related neuronal activity in the premotor cortex of rhesus monkey:effects of changes in motor set, Proceedings of the Royal Society of London, B 223, 331–354.
Wise, S.P., Weinrich, M., and Mauritz, K.H. (1986) Movement-related activity in the premotor cortex of rhesus macaques, in H.J. Freund, U. Buttner, B. Cohen and J. Noth (eds.), Progress in Brain Research 4. Elsevier, Amsterdam, pp. 117–131.
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Requin, J. (1991). Neural Basis of Movement Representations. In: Requin, J., Stelmach, G.E. (eds) Tutorials in Motor Neuroscience. NATO ASI Series, vol 62. Springer, Dordrecht. https://doi.org/10.1007/978-94-011-3626-6_27
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DOI: https://doi.org/10.1007/978-94-011-3626-6_27
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