AI Article Synopsis
- Our brain can recognize actions through sound alone by simulating the movement associated with those sounds, even without visual cues.
- Previous research showed that familiar motor actions activate specific areas in our motor cortex, but this study focused on how new action-related sounds can evoke similar motor responses.
- The findings indicate that passive listening to these newly learned sounds activates a motor representation that is linked to the intention of the action rather than the muscle movements themselves, highlighting a complex relationship between auditory perception and intended action goals.
Article Abstract
In the absence of visual information, our brain is able to recognize the actions of others by representing their sounds as a motor event. Previous studies have provided evidence for a somatotopic activation of the listener's motor cortex during perception of the sound of highly familiar motor acts. The present experiments studied (a) how the motor system is activated by action-related sounds that are newly acquired and (b) whether these sounds are represented with reference to extrinsic features related to action goals rather than with respect to lower-level intrinsic parameters related to the specific movements. TMS was used to measure the correspondence between auditory and motor codes in the listener's motor system. We compared the corticomotor excitability in response to the presentation of auditory stimuli void of previous motor meaning before and after a short training period in which these stimuli were associated with voluntary actions. Novel cross-modal representations became manifest very rapidly. By disentangling the representation of the muscle from that of the action's goal, we further showed that passive listening to newly learnt action-related sounds activated a precise motor representation that depended on the variable contexts to which the individual was exposed during testing. Our results suggest that the human brain embodies a higher-order audio-visuo-motor representation of perceived actions, which is muscle-independent and corresponds to the goals of the action.
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| http://dx.doi.org/10.1162/jocn_a_00134 | DOI Listing |
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