Abstract
The motor cortex is a large frontal structure in the cerebral cortex of eutherian mammals. A vast array of evidence implicates the motor cortex in the volitional control of motor output, but how does the motor cortex exert this 'control'? Historically, ideas regarding motor cortex function have been shaped by the discovery of cortical 'motor maps' — that is, ordered representations of stimulation-evoked movements in anaesthetized animals. Volitional control, however, entails the initiation of movements and the ability to suppress undesired movements. In this article, we highlight classic and recent findings that emphasize that motor cortex neurons have a role in both processes.
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References
Fritsch, G. & Hitzig, E. Über die elektrische Erregbarkeit des Grosshirns [German]. Arch. Anat. Physiol. wiss. Med. 37, 300–332 (1870).
Ferrier, D. Experiments on the brain of monkeys — No. I. Proc. R. Soc. Lond. 23, 409–430 (1874).
Leyton, A. S. F. & Sherrington, C. S. Observations on the excitable cortex of the chimpanzee, orang-utan, and gorilla. Q. J. Exp. Physiol. 11, 135–222 (1917).
Graziano, M. S. Taylor, C. S. & Moore, T. Complex movements evoked by microstimulation of precentral cortex. Neuron 34, 841–851 (2002).
Penfield, W. & Rasmussen, T. The Cerebral Cortex of Man (New York: The Macmillan Company, 1952).
Asanuma, H. & Rosén, I. Topographical organization of cortical efferent zones projecting to distal forelimb muscles in the monkey. Exp. Brain Res. 14, 243–256 (1972).
Ikeda, A. et al. Movement-related potentials associated with bilateral simultaneous and unilateral movements recorded from human supplementary motor area. Electroencephalogr. Clin. Neurophysiol. 95, 323–334 (1995).
Lüders, H. O., Dinner, D. S., Morris, H. H., Wyllie, E. & Comair, Y. G. Cortical electrical stimulation in humans. The negative motor areas. Adv. Neurol. 67, 115–129 (1995).
Nii, Y., Uematsu, S., Lesser, R. P. & Gordon, B. Does the central sulcus divide motor and sensory functions? Cortical mapping of human hand areas as revealed by electrical stimulation through subdural grid electrodes. Neurology 46, 360–367 (1996).
Mikuni, N. et al. Evidence for a wide distribution of negative motor areas in the perirolandic cortex. Clin. Neurophysiol. 117, 33–40 (2006).
Filevich, E., Kühn, S. & Haggard, P. Negative motor phenomena in cortical stimulation: implications for inhibitory control of human action. Cortex 48, 1251–1261 (2012).
Neafsey, E. J. et al. The organization of the rat motor cortex: a microstimulation mapping study. Brain Res. 11, 77–96 (1986).
Ayling, O. G. S., Harrison, T. C., Boyd, J. D., Goroshkov, A. & Murphy, T. H. Automated light-based mapping of motor cortex by photoactivation of channelrhodopsin-2 transgenic mice. Nat. Methods 6, 219–224 (2009).
Harrison, T. C., Ayling, O. G. S. & Murphy, T. H. Distinct cortical circuit mechanisms for complex forelimb movement and motor map topography. Neuron 74, 397–409 (2012).
Lemon, R. N. An enduring map of the motor cortex. Exp. Physiol. 93, 798–802 (2008).
Brecht, M. et al. Organization of rat vibrissa motor cortex and adjacent areas according to cytoarchitectonics, microstimulation, and intracellular stimulation of identified cells. J. Comp. Neurol. 479, 360–373 (2004).
Matyas, F. et al. Motor control by sensory cortex. Science 330, 1240–1243 (2010).
Molnár, Z. et al. Evolution and development of the mammalian cerebral cortex. Brain. Behav. Evol. 83, 126–139 (2014).
Hall, R. D. & Lindholm, E. P. Organization of motor and somatosensory neocortex in the albino rat. Brain Res. 66, 23–38 (1974).
Nudo, R. J. & Frost, S. B. in Evolution of nervous systems (eds Kass, J. H.) 373–395 (Academic Press, 2007).
Kaas, J. H. Evolution of somatosensory and motor cortex in primates. Anat. Rec. A Discov. Mol. Cell. Evol. Biol. 281, 1148–1156 (2004).
Frost, S. B., Milliken, G. W., Plautz, E. J., Masterton, R. B. & Nudo, R. J. Somatosensory and motor representations in cerebral cortex of a primitive mammal (Monodelphis domestica): a window into the early evolution of sensorimotor cortex. J. Comp. Neurol. 421, 29–51 (2000).
Karlen, S. J. & Krubitzer, L. The functional and anatomical organization of marsupial neocortex: evidence for parallel evolution across mammals. Prog. Neurobiol. 82, 122–141 (2007).
Gioanni, Y. & Lamarche, M. A reappraisal of rat motor cortex organization by intracortical microstimulation. Brain Res. 344, 49–61 (1985).
Zilles, K. & Wree, A. in The Rat Nevous System (ed. Paxinos, G.) 649–685 (Academic Press, 1995).
Brodmann, K. Vergleichende Lokalisationslehre der Großhirnrinde: in ihren Prinzipien dargestellt auf Grund des Zellenbaues [German] (J. A. Barth, 1909).
Yamawaki, N. et al. A genuine layer 4 in motor cortex with prototypical synaptic circuit connectivity. eLife 4, e05422 (2014).
Nudo, R. J. & Masterton, R. B. Descending pathways to the spinal cord, III: sites of origin of the corticospinal tract. J. Comp. Neurol. 296, 559–583 (1990).
Rathelot, J.-A. & Strick, P. L. Muscle representation in the macaque motor cortex: an anatomical perspective. Proc. Natl Acad. Sci. USA 103, 8257–8262 (2006).
Sreenivasan, V. et al. Movement initiation signals in mouse whisker motor cortex. Neuron 92, 1368–1382 (2016).
Ferezou, I. et al. Spatiotemporal dynamics of cortical sensorimotor integration in behaving mice. Neuron 56, 907–923 (2007).
Paxinos, G. & Watson, C. The Rat Brain in Stereotaxic Coordinates (Academic Press, 1982).
Brecht, M. Movement, confusion, and orienting in frontal cortices. Neuron 72, 193–196 (2011).
Barthas, F. & Kwan, A. C. Secondary motor cortex: where 'sensory' meets 'motor' in the rodent frontal cortex. Trends Neurosci. 40, 181–193 (2017).
Murakami, M., Vicente, M. I., Costa, G. M. & Mainen, Z. F. Neural antecedents of self-initiated actions in secondary motor cortex. Nat. Neurosci. 17, 1574–1582 (2014).
Murakami, M., Shteingart, H., Loewenstein, Y. & Mainen, Z. F. Distinct sources of deterministic and stochastic components of action timing decisions in rodent frontal cortex. Neuron 94, 908–919.e7 (2017).
Reep, R. L., Goodwin, G. S. & Corwin, J. V. Topographic organization in the corticocortical connections of medial agranular cortex in rats. J. Comp. Neurol. 294, 262–280 (1990).
Reep, R. L., Corwin, J. V., Hashimoto, A. & Watson, R. T. Efferent connections of the rostral portion of medial agranular cortex in rats. Brain Res. Bull. 19, 203–221 (1987).
Sul, J. H., Jo, S., Lee, D. & Jung, M. W. Role of rodent secondary motor cortex in value-based action selection. Nat. Neurosci. 14, 1202–1208 (2011).
Brody, C. D. & Hanks, T. D. Neural underpinnings of the evidence accumulator. Curr. Opin. Neurobiol. 37, 149–157 (2016).
Erlich, J. C., Bialek, M. & Brody, C. D. A cortical substrate for memory-guided orienting in the rat. Neuron 72, 330–343 (2011).
Erlich, J. C., Brunton, B. W., Duan, C. A., Hanks, T. D. & Brody, C. D. Distinct effects of prefrontal and parietal cortex inactivations on an accumulation of evidence task in the rat. eLife http://dx.doi.org/10.7554/eLife.05457 (2015).
Hanks, T. D. et al. Distinct relationships of parietal and prefrontal cortices to evidence accumulation. Nature 520, 220–223 (2015).
Lemon, R. N. Descending pathways in motor control. Annu. Rev. Neurosci. 31, 195–218 (2008).
O'Donoghue, D. L., Kartje-Tillotson, G. & Castro, A. J. Forelimb motor cortical projections in normal rats and after neonatal hemicerebellectomy: an anatomical study based upon the axonal transport of WGA/HRP. J. Comp. Neurol. 256, 274–283 (1987).
Grinevich, V., Brecht, M. & Osten, P. Monosynaptic pathway from rat vibrissa motor cortex to facial motor neurons revealed by lentivirus-based axonal tracing. J. Neurosci. 25, 8250–8258 (2005).
Sreenivasan, V., Karmakar, K., Rijli, F. M. & Petersen, C. C. H. Parallel pathways from motor and somatosensory cortex for controlling whisker movements in mice. Eur. J. Neurosci. 41, 354–367 (2015).
Rouiller, E. M., Moret, V. & Liang, F. Comparison of the connectional properties of the two forelimb areas of the rat sensorimotor cortex: support for the presence of a premotor or supplementary motor cortical area. Somatosens. Mot. Res. 10, 269–289 (1993).
Deschênes, M. et al. Inhibition, not excitation, drives rhythmic whisking. Neuron 90, 374–387 (2016).
Kuypers, H. G. New look at the organization of the motor system. Prog. Brain Res. 57, 381–403 (1982).
Fetz, E. E., Perlmutter, S. I. & Prut, Y. Functions of mammalian spinal interneurons during movement. Curr. Opin. Neurobiol. 10, 699–707 (2000).
Rathelot, J.-A. & Strick, P. L. Subdivisions of primary motor cortex based on cortico-motoneuronal cells. Proc. Natl Acad. Sci. USA 106, 918–923 (2009).
Heffner, R. & Masterton, B. Variation in form of the pyramidal tract and its relationship to digital dexterity. Brain. Behav. Evol. 12, 161–200 (1975).
Nakajima, K., Maier, M. A., Kirkwood, P. A. & Lemon, R. N. Striking differences in transmission of corticospinal excitation to upper limb motoneurons in two primate species. J. Neurophysiol. 84, 698–709 (2000).
Osten, P. & Margrie, T. W. Mapping brain circuitry with a light microscope. Nat. Methods 10, 515–523 (2013).
Hooks, B. M. et al. Organization of cortical and thalamic input to pyramidal neurons in mouse motor cortex. J. Neurosci. 33, 748–760 (2013).
Jeong, M. et al. Comparative three-dimensional connectome map of motor cortical projections in the mouse brain. Sci. Rep. 6, 20072 (2016).
Calabresi, P., Picconi, B., Tozzi, A., Ghiglieri, V. & Di Filippo, M. Direct and indirect pathways of basal ganglia: a critical reappraisal. Nat. Neurosci. 17, 1022–1030 (2014).
Kress, G. J. et al. Convergent cortical innervation of striatal projection neurons. Nat. Neurosci. 16, 665–667 (2013).
Cui, G. et al. Concurrent activation of striatal direct and indirect pathways during action initiation. Nature 494, 238–242 (2013).
Tecuapetla, F., Jin, X., Lima, S. Q. & Costa, R. M. Complementary contributions of striatal projection pathways to action initiation and execution. Cell 166, 703–715 (2016).
Grillner, S. & Robertson, B. The basal ganglia downstream control of brainstem motor centres — an evolutionarily conserved strategy. Curr. Opin. Neurobiol. 33, 47–52 (2015).
Cheney, P. D. & Fetz, E. E. Comparable patterns of muscle facilitation evoked by individual corticomotoneuronal (CM) cells and by single intracortical microstimuli in primates: evidence for functional groups of CM cells. J. Neurophysiol. 53, 786–804 (1985).
Lemon, R., Muir, R. & Mantel, G. The effects upon the activity of hand and forearm muscles of intracortical stimulation in the vicinity of corticomotor neurones in the conscious monkey. Exp. Brain Res. 66, 621–637 (1987).
Cheney, P. D., Fetz, E. E. & Palmer, S. S. Patterns of facilitation and suppression of antagonist forelimb muscles from motor cortex sites in the awake monkey. J. Neurophysiol. 53, 805–820 (1985).
Ebbesen, C. L., Doron, G., Lenschow, C. & Brecht, M. Vibrissa motor cortex activity suppresses contralateral whisking behavior. Nat. Neurosci. 20, 82–89 (2017).
Hill, D. N., Curtis, J. C., Moore, J. D. & Kleinfeld, D. Primary motor cortex reports efferent control of vibrissa motion on multiple timescales. Neuron 72, 344–356 (2011).
Moore, J. D. et al. Hierarchy of orofacial rhythms revealed through whisking and breathing. Nature 497, 205–210 (2013).
Buys, E. J., Lemon, R. N., Mantel, G. W. & Muir, R. B. Selective facilitation of different hand muscles by single corticospinal neurones in the conscious monkey. J. Physiol. 381, 529–549 (1986).
Lemon, R. N., Mantel, G. W. & Muir, R. B. Corticospinal facilitation of hand muscles during voluntary movement in the conscious monkey. J. Physiol. 381, 497–527 (1986).
Davidson, A. G., Chan, V., O'Dell, R. & Schieber, M. H. Rapid changes in throughput from single motor cortex neurons to muscle activity. Science 318, 1934–1937 (2007).
Ramanathan, D., Conner, J. M. & Tuszynski, M. H. A form of motor cortical plasticity that correlates with recovery of function after brain injury. Proc. Natl Acad. Sci. USA 103, 11370–11375 (2006).
Stoney, S. D., Thompson, W. D. & Asanuma, H. Excitation of pyramidal tract cells by intracortical microstimulation: effective extent of stimulating current. J. Neurophysiol. 31, 659–669 (1968).
Tehovnik, E. J., Tolias, A. S., Sultan, F., Slocum, W. M. & Logothetis, N. K. Direct and indirect activation of cortical neurons by electrical microstimulation. J. Neurophysiol. 96, 512–521 (2006).
Histed, M. H., Bonin, V. & Reid, R. C. Direct activation of sparse, distributed populations of cortical neurons by electrical microstimulation. Neuron 63, 508–522 (2009).
Shenoy, K. V., Sahani, M. & Churchland, M. M. Cortical control of arm movements: a dynamical systems perspective. Annu. Rev. Neurosci. 36, 337–359 (2013).
Georgopoulos, A. P., Kalaska, J. F., Caminiti, R. & Massey, J. T. On the relations between the direction of two-dimensional arm movements and cell discharge in primate motor cortex. J. Neurosci. 2, 1527–1537 (1982).
Kalaska, J. F., Cohen, D. A., Hyde, M. L. & Prud'homme, M. A comparison of movement direction-related versus load direction-related activity in primate motor cortex, using a two-dimensional reaching task. J. Neurosci. 9, 2080–2102 (1989).
Evarts, E. V. Relation of pyramidal tract activity to force exerted during voluntary movement. J. Neurophysiol. 31, 14–27 (1968).
Cheney, P. D. & Fetz, E. E. Functional classes of primate corticomotoneuronal cells and their relation to active force. J. Neurophysiol. 44, 773–791 (1980).
Fetz, E. E. Are movement parameters recognizable coded in the activity of single neurons? Behav. Brain Sci. 15, 679–690 (1992).
Kaufman, M. T., Churchland, M. M. & Shenoy, K. V. The roles of monkey M1 neuron classes in movement preparation and execution. J. Neurophysiol. 110, 817–825 (2013).
Armstrong, D. M. & Drew, T. Discharges of pyramidal tract and other motor cortical neurones during locomotion in the cat. J. Physiol. 346, 471–495 (1984).
Drew, T., Jiang, W. & Widajewicz, W. Contributions of the motor cortex to the control of the hindlimbs during locomotion in the cat. Brain Res. Rev. 40, 178–191 (2002).
Beloozerova, I. N., Farrell, B. J., Sirota, M. G. & Prilutsky, B. I. Differences in movement mechanics, electromyographic, and motor cortex activity between accurate and nonaccurate stepping. J. Neurophysiol. 103, 2285–2300 (2010).
Drew, T. Motor cortical activity during voluntary gait modifications in the cat. I. Cells related to the forelimbs. J. Neurophysiol. 70, 179–199 (1993).
Beloozerova, I. N. & Sirota, M. G. The role of the motor cortex in the control of vigour of locomotor movements in the cat. J. Physiol. 461, 27–46 (1993).
Ölveczky, B. P. Motoring ahead with rodents. Curr. Opin. Neurobiol. 21, 571–578 (2011).
Fisher, S. P. et al. Stereotypic wheel running decreases cortical activity in mice. Nat. Commun. 7, 13138 (2016).
Barthó, P. et al. Characterization of neocortical principal cells and interneurons by network interactions and extracellular features. J. Neurophysiol. 92, 600–608 (2004).
Gentet, L. J., Avermann, M., Matyas, F., Staiger, J. F. & Petersen, C. C. Membrane potential dynamics of GABAergic neurons in the barrel cortex of behaving mice. Neuron 65, 422–435 (2010).
Sjulson, L. L., Hjerling-Leffler, J., Rudy, B. & Fishell, G. Reforming our ideas about cell types and spike waveforms. J. Neurosci http://www.jneurosci.org/content/31/40/14235/tab-article-info#reforming-our-ideas-about-cell-types-and-spike-waveforms (2011).
Suter, B. A., Migliore, M. & Shepherd, G. M. G. Intrinsic electrophysiology of mouse corticospinal neurons: a class-specific triad of spike-related properties. Cereb. Cortex 23, 1965–1977 (2013).
Schiemann, J. et al. Cellular mechanisms underlying behavioral state-dependent bidirectional modulation of motor cortex output. Cell Rep. 11, 1319–1330 (2015).
Gao, P., Bermejo, R. & Zeigler, H. P. Whisker deafferentation and rodent whisking patterns: behavioral evidence for a central pattern generator. J. Neurosci. 21, 5374–5380 (2001).
Moore, J. D. et al. Hierarchy of orofacial rhythms revealed through whisking and breathing. Nature 497, 205–210 (2013).
Dörfl, J. The musculature of the mystacial vibrissae of the white mouse. J. Anat. 135, 147–154 (1982).
Welker, W. I. Analysis of sniffing of the albino rat. Behaviour 22, 223–244 (1964).
Sachdev, R. N. S., Sato, T. & Ebner, F. F. Divergent movement of adjacent whiskers. J. Neurophysiol. 87, 1440–1448 (2002).
Carvell, G. E., Miller, S. A. & Simons, D. J. The relationship of vibrissal motor cortex unit activity to whisking in the awake rat. Somatosens. Mot. Res. 13, 115–127 (1996).
Friedman, W. A., Zeigler, H. P. & Keller, A. Vibrissae motor cortex unit activity during whisking. J. Neurophysiol. 107, 551–563 (2012).
Gerdjikov, T. V., Haiss, F., Rodriguez-Sierra, O. E. & Schwarz, C. Rhythmic whisking area (RW) in rat primary motor cortex: an internal monitor of movement-related signals? J. Neurosci. 33, 14193–14204 (2013).
Kleinfeld, D., Berg, R. W. & O'Connor, S. M. Anatomical loops and their electrical dynamics in relation to whisking by rat. Somatosens. Mot. Res. 16, 69–88 (1999).
Isomura, Y., Harukuni, R., Takekawa, T., Aizawa, H. & Fukai, T. Microcircuitry coordination of cortical motor information in self-initiation of voluntary movements. Nat. Neurosci. 12, 1586–1593 (2009).
Estebanez, L., Hoffmann, D., Voigt, B. C. & Poulet, J. F. A. Parvalbumin expressing GABA-ergic neurons in primary motor cortex signal reaching. Cell Rep. 20, 308–318 (2017).
Vigneswaran, G., Kraskov, A. & Lemon, R. Large identified pyramidal cells in macaque motor and premotor cortex exhibit 'thin spikes': implications for cell type classification. J. Neurosci. 31, 14235–14242 (2011).
Zaitsev, A. V., Povysheva, N. V., Gonzalez-Burgos, G. & Lewis, D. A. Electrophysiological classes of layers 2–3 pyramidal cells in monkey prefrontal cortex. J. Neurophysiol. 108, 595–609 (2012).
Li, N., Chen, T., Guo, Z. V., Gerfen, C. R. & Svoboda, K. A motor cortex circuit for motor planning and movement. Nature 519, 51–56 (2015).
Chen, T.-W., Li, N., Daie, K. & Svoboda, K. A. Map of anticipatory activity in mouse motor cortex. Neuron 94, 866–879.e4 (2017).
Travers, J. B., Dinardo, L. A. & Karimnamazi, H. Motor and premotor mechanisms of licking. Neurosci. Biobehav. Rev. 21, 631–647 (1997).
Guo, Z. et al. Flow of cortical activity underlying a tactile decision in mice. Neuron 81, 179–194 (2014).
Peters, A. J., Lee, J., Hedrick, N. G., O'Neil, K. & Komiyama, T. Reorganization of corticospinal output during motor learning. Nat. Neurosci. 20, 1133–1141 (2017).
Kolb, B. Functions of the frontal cortex of the rat: a comparative review. Brain Res. 320, 65–98 (1984).
Franz, S. I. & Lashley, K. S. The retention of habits by the rat after destruction of the frontal portion of the cerebrum. Psychobiology 1, 3–18 (1917).
Semba, K. & Komisaruk, B. R. Neural substrates of two different rhythmical vibrissal movements in the rat. Neuroscience 12, 761–774 (1984).
Goulding, M. Circuits controlling vertebrate locomotion: moving in a new direction. Nat. Rev. Neurosci. 10, 507–518 (2009).
Kiehn, O. Locomotor circuits in the mammalian spinal cord. Annu. Rev. Neurosci. 29, 279–306 (2006).
Bourane, S. et al. Identification of a spinal circuit for light touch and fine motor control. Cell 160, 503–515 (2015).
Whelan, P. Control of locomotion in the decerebrate cat. Prog. Neurobiol. 49, 481–515 (1996).
Brown, T. G. The intrinsic factors in the act of progression in the mammal. Proc. R. Soc. Lond. B 84, 308–319 (1911).
Schieber, M. H. & Poliakov, A. V. Partial inactivation of the primary motor cortex hand area: effects on individuated finger movements. J. Neurosci. 18, 9038–9054 (1998).
Laplane, D., Talairach, J., Meininger, V., Bancaud, J. & Bouchareine, A. Motor consequences of motor area ablations in man. J. Neurol. Sci. 31, 29–49 (1977).
Barnes, M. P. & Johnson, G. R. Upper Motor Neurone Syndrome and Spasticity. Clinical Management and Neurophysiology (Cambridge Univ. Press, 2008).
Sasaki, S. et al. Dexterous finger movements in primate without monosynaptic corticomotoneuronal excitation. J. Neurophysiol. 92, 3142–3147 (2004).
Rouiller, E. M. et al. Dexterity in adult monkeys following early lesion of the motor cortical hand area: the role of cortex adjacent to the lesion. Eur. J. Neurosci. 10, 729–740 (1998).
Lawrence, D. G. & Kuypers, H. G. The functional organization of the motor system in the monkey. I. The effects of bilateral pyramidal lesions. Brain 91, 1–14 (1968).
Gao, P., Hattox, A. M., Jones, L. M., Keller, A. & Zeigler, H. P. Whisker motor cortex ablation and whisker movement patterns. Somatosens. Mot. Res. 20, 191–198 (2003).
Stoltz, S., Humm, J. L. & Schallert, T. Cortical injury impairs contralateral forelimb immobility during swimming: a simple test for loss of inhibitory motor control. Behav. Brain Res. 106, 127–132 (1999).
Martin, J. H. & Ghez, C. Impairments in reaching during reversible inactivation of the distal forelimb representation of the motor cortex in the cat. Neurosci. Lett. 133, 61–64 (1991).
Martin, J. H. & Ghez, C. Differential impairments in reaching and grasping produced by local inactivation within the forelimb representation of the motor cortex in the cat. Exp. Brain Res. 94, 429–443 (1993).
Castro, A. J. The effects of cortical ablations on digital usage in the rat. Brain Res. 37, 173–185 (1972).
Alaverdashvili, M. & Whishaw, I. Q. Motor cortex stroke impairs individual digit movement in skilled reaching by the rat. Eur. J. Neurosci. 28, 311–322 (2008).
Guo, J.-Z. et al. Cortex commands the performance of skilled movement. eLife 4, 1–18 (2015).
Otchy, T. M. et al. Acute off-target effects of neural circuit manipulations. Nature 528, 358–363 (2015).
Südhof, T. C. Reproducibility: experimental mismatch in neural circuits. Nature 528, 338–339 (2015).
Zagha, E., Ge, X. & McCormick, D. A. Competing neural ensembles in motor cortex gate goal-directed motor output. Neuron 88, 565–577 (2015).
Huber, D. et al. Multiple dynamic representations in the motor cortex during sensorimotor learning. Nature 484, 473–478 (2012).
Sachidhanandam, S., Sreenivasan, V., Kyriakatos, A., Kremer, Y. & Petersen, C. C. H. Membrane potential correlates of sensory perception in mouse barrel cortex. Nat. Neurosci. 16, 1671–1677 (2013).
Dalley, J. W., Cardinal, R. N. & Robbins, T. W. Prefrontal executive and cognitive functions in rodents: neural and neurochemical substrates. Neurosci. Biobehav. Rev. 28, 771–784 (2004).
Kim, S. & Lee, D. Prefrontal cortex and impulsive decision making. Biol. Psychiatry 69, 1140–1146 (2011).
Miller, E. K. The prefrontal cortex and cognitive control. Nat. Rev. Neurosci. 1, 59–65 (2000).
Mayer-Gross, W., Slater, E. & Roth, M. Clinical Psychiatry (Cassell & Co., 1954).
Narayanan, N. S. & Laubach, M. Top-down control of motor cortex ensembles by dorsomedial prefrontal cortex. Neuron 52, 921–931 (2006).
Kawai, R. et al. Motor cortex is required for learning but not for executing a motor skill. Neuron 86, 800–812 (2015).
Peters, A. J., Chen, S. X. & Komiyama, T. Emergence of reproducible spatiotemporal activity during motor learning. Nature 510, 263–267 (2014).
Quallo, M. M., Kraskov, A. & Lemon, R. N. The activity of primary motor cortex corticospinal neurons during tool use by macaque monkeys. J. Neurosci. 32, 17351–17364 (2012).
Dushanova, J. & Donoghue, J. Neurons in primary motor cortex engaged during action observation. Eur. J. Neurosci. 31, 386–398 (2010).
Tkach, D., Reimer, J. & Hatsopoulos, N. G. Congruent activity during action and action observation in motor cortex. J. Neurosci. 27, 13241–13250 (2007).
Kraskov, A et al. Corticospinal mirror neurons. Philos. Trans. R. Soc. Lond. B Biol. Sci. http://dx.doi.org/10.1098/rstb.2013.0174 (2014).
Vigneswaran, G., Philipp, R., Lemon, R. N. & Kraskov, A. M1 corticospinal mirror neurons and their role in movement suppression during action observation. Curr. Biol. 23, 236–243 (2013).
Goard, M. J., Pho, G. N., Woodson, J. & Sur, M. Distinct roles of visual, parietal, and frontal motor cortices in memory-guided sensorimotor decisions. eLife 5, e13764 (2016).
Kleinfeld, D., Sachdev, R. N. S., Merchant, L. M., Jarvis, M. R. & Ebner, F. F. Adaptive filtering of vibrissa input in motor cortex of rat. Neuron 34, 1021–1034 (2002).
Kilner, J. M. & Lemon, R. N. What we know currently about mirror neurons. Curr. Biol. 23, R1057–R1062 (2013).
Mountcastle, V. Modalily and topographic properties of single neurons of cat's somatic sensory system. J. Neurophysiol. 20, 408–434 (1956).
Hubel, D. H. & Wiesel, T. N. Receptive fields of single neurones in the cat's striate cortex. J. Physiol. 148, 574–591 (1959).
Mountcastle, V. in The Mindful Brain (eds Edelman, G. & Mountcastle, V. B.) 7–50 (MIT Press, 1978).
Sanes, J. N. & Donoghue, J. P. Plasticity and primary motor cortex. Annu. Rev. Neurosci. 23, 393–415 (2000).
Laubach, M., Caetano, M. S. & Narayanan, N. S. Mistakes were made: neural mechanisms for the adaptive control of action initiation by the medial prefrontal cortex. J. Physiol. Paris 109, 104–117 (2015).
Harlow, J. M. Recovery from the passage of an iron bar through the head (D. Clapp, 1868).
Harlow, J. M. Passage of an iron rod through the head. J. Neuropsychiatry Clin. Neurosci. 11, 281–283 (1848).
Shadmehr, R. Distinct neural circuits for control of movement vs. holding still. J. Neurophysiol. 117, 1431–1460 (2017).
Schall, J. D., Stuphorn, V. & Brown, J. W. Monitoring and control of action by the frontal lobes. Neuron 36, 309–322 (2002).
Wardak, C. The role of the supplementary motor area in inhibitory control in monkeys and humans. J. Neurosci. 31, 5181–5183 (2011).
Nachev, P., Kennard, C. & Husain, M. Functional role of the supplementary and pre-supplementary motor areas. Nat. Rev. Neurosci. 9, 856–869 (2008).
Filevich, E., Kühn, S. & Haggard, P. Intentional inhibition in human action: the power of 'no'. Neurosci. Biobehav. Rev. 36, 1107–1118 (2012).
Brainin, M., Seiser, A. & Matz, K. The mirror world of motor inhibition: the alien hand syndrome in chronic stroke. J. Neurol. Neurosurg. Psychiatry 79, 246–252 (2008).
Mischel, W., Ebbesen, E. B. & Raskoff Zeiss, A. Cognitive and attentional mechanisms in delay of gratification. J. Pers. Soc. Psychol. 21, 204–218 (1972).
Freud, S. Das Ich und das Es. Gesammelte Werke: XIII [German] (Internationaler Psychoanalytischer Verlag, 1923).
Acknowledgements
The authors thank J. Poulet, M. Vestergaard, A. Clemens, R. Rao and A. Neukirchner for valuable discussions and comments on the manuscript. This work was funded by the Humboldt Universität zu Berlin within the Excellence Initiative of the states and the federal government, BCCN Berlin (German Federal Ministry of Education and Research BMBF, Förderkennzeichen 01GQ1001A), NeuroCure and the Gottfried Wilhelm Leibniz Prize of the DFG.
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Ebbesen, C., Brecht, M. Motor cortex — to act or not to act?. Nat Rev Neurosci 18, 694–705 (2017). https://doi.org/10.1038/nrn.2017.119
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DOI: https://doi.org/10.1038/nrn.2017.119
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