M1 Corticospinal Mirror Neurons and Their Role in Movement Suppression during Action Observation

Evidence is accumulating that neurons in primary motor cortex (M1) respond during action observation [1, 2], a property first shown for mirror neurons in monkey premotor cortex [3]. We now show for the first time that the discharge of a major class of M1 output neuron, the pyramidal tract neuron (PT...

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Published inCurrent biology Vol. 23; no. 3; pp. 236 - 243
Main Authors Vigneswaran, Ganesh, Philipp, Roland, Lemon, Roger N., Kraskov, Alexander
Format Journal Article
LanguageEnglish
Published England Elsevier Inc 04.02.2013
Cell Press
Subjects
adults
Animals
cortex
Female
Hand - innervation
Humans
Macaca
Macaca mulatta
Male
Mirror Neurons - physiology
monkeys
Motor Cortex - physiology
muscles
neurons
Pyramidal Tracts - physiology
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Summary:Evidence is accumulating that neurons in primary motor cortex (M1) respond during action observation [1, 2], a property first shown for mirror neurons in monkey premotor cortex [3]. We now show for the first time that the discharge of a major class of M1 output neuron, the pyramidal tract neuron (PTN), is modulated during observation of precision grip by a human experimenter. We recorded 132 PTNs in the hand area of two adult macaques, of which 65 (49%) showed mirror-like activity. Many (38 of 65) increased their discharge during observation (facilitation-type mirror neuron), but a substantial number (27 of 65) exhibited reduced discharge or stopped firing (suppression-type). Simultaneous recordings from arm, hand, and digit muscles confirmed the complete absence of detectable muscle activity during observation. We compared the discharge of the same population of neurons during active grasp by the monkeys. We found that facilitation neurons were only half as active for action observation as for action execution, and that suppression neurons reversed their activity pattern and were actually facilitated during execution. Thus, although many M1 output neurons are active during action observation, M1 direct input to spinal circuitry is either reduced or abolished and may not be sufficient to produce overt muscle activity. ► PTNs in primary motor cortex show mirror properties ► These neurons project to the spinal cord, but no overt muscle activity was detected ► Compared with execution, mirror PTNs reduce or abolish discharge during observation ► Disfacilitation of mirror PTNs during observation may prevent unintended movement
Bibliography:http://dx.doi.org/10.1016/j.cub.2012.12.006
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ISSN:0960-9822
1879-0445
DOI:10.1016/j.cub.2012.12.006