Two brains in action: Joint-action coding in the primate frontal cortex

Ferrari-Toniolo, Simone; Visco-Comandini, Federica; Battaglia-Mayer, Alexandra

doi:10.1523/jneurosci.1512-18.2019

Cited by 20 publications

(48 citation statements)

References 47 publications

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“…As a final neurobiological consideration, our results highlight that the very same lvPMc, belonging to the "mirror" motor system (Rizzolatti and Sinigaglia 2016), contributes to the deciphering of motor goals beyond mere low-level movement imitation. A recent neurophysiological study on nonhuman primates (Ferrari-Toniolo et al, 2019) showed that there is a population of left premotor neurons that preferentially discharge when a monkey cooperates with a partner to achieve a motor goal, independently of the specific visual input that the monkey receives at a given moment ( Ferrari-Toniolo et al, 2019): this is in line with our suggestion that that the activity of premotor regions might be shaped by social motor experience and acquire the possibility to code higher-order "joint" motor representations.…”

Section: Discussionsupporting

confidence: 88%

How Task Interactivity Shapes Action Observation

et al. 2019

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Action observation triggers imitation, a powerful mechanism permitting interpersonal coordination. Coordination, however, also occurs when the partners’ actions are nonimitative and physically incongruent. One influential theory postulates that this is achieved via top-down modulation of imitation exerted by prefrontal regions. Here, we rather argue that coordination depends on sharing a goal with the interacting partner: this shapes action observation, overriding involuntary imitation, through the predictive activity of the left ventral premotor cortex (lvPMc). During functional magnetic resonance imaging (fMRI), participants played music in turn with a virtual partner in interactive and noninteractive conditions requiring 50% of imitative/nonimitative responses. In a full-factorial design, both perceptual features and low-level motor requirements were kept constant throughout the experiment. Behaviorally, the interactive context minimized visuomotor interference due to the involuntary imitation of physically incongruent movements. This was paralleled by modulation of neural activity in the lvPMc, which was specifically recruited during the interactive task independently of the imitative/nonimitative nature of the social exchange. This lvPMc activity reflected the predictive decoding of the partner’s actions, as revealed by multivariate pattern analysis. This demonstrates that, during interactions, we process our partners’ behavior to prospectively infer their contribution to the shared goal achievement, generating motor predictions for cooperation beyond low-level imitation.

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Section: Discussionsupporting

confidence: 88%

How Task Interactivity Shapes Action Observation

et al. 2019

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“…Interestingly, this neural mechanism has recently been reported by Thornton et al (2019), who found that the adjustment of current social behavior based on the prediction of the other's future mental state, depended on the action of the medial prefrontal cortex. Similar findings have been found in pairs of monkeys that perform cooperative tasks (Ferrari-Toniolo et al, 2019). Specifically, a unique set of dorsal premotor neurons called "joint-action cells" was found to discharge preferentially during cooperative tasks involving interactive visuomotor coordination between co-acting monkeys.…”

Section: Gamma Interbrain Coupling As a Marker Of Prosocial Behaviorsupporting

confidence: 78%

Brain-to-Brain Coupling in the Gamma-Band as a Marker of Shared Intentionality

Barraza

Pérez

Rodríguez

2020

Front. Hum. Neurosci.

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Cooperation and competition are two ways of social interaction keys to life in society. Recent EEG-based hyperscanning studies reveal that cooperative and competitive interactions induce an increase in interbrain coupling. However, whether this interbrain coupling effect is just a reflection of inter-subject motor coordination or can also signal the type of social interaction is unknown. Here, we show that behavioral coordination and social interaction type can be distinguished according to the frequency of oscillation in which the brains are coupled. We use EEG to simultaneously measure the brain activity of pairs of subjects, while they were performing a visual cue-target task in a cooperative and competitive manner. Behavioral responses were quasi-simultaneous between subject pairs for both competitive and cooperative conditions, with faster average response times for the competitive condition. Concerning brain activity, we found increased interbrain coupling in theta band (3-7 Hz) during cooperation and competition, with stronger coupling during competitive interactions. This increase of interbrain theta coupling correlated with a decrease in reaction times of the dyads. Interestingly, we also found an increase in brain-to-brain coupling in gamma band (38-42 Hz) only during cooperative interactions. Unlike the theta coupling effect, the gamma interbrain coupling did not correlate with dyads' reaction times. Taken together, these results suggest that theta interbrain coupling could be linked to motor coordination processes common to cooperative and competitive interactions, while gamma brain-tobrain coupling emerges as an electrophysiological marker of shared intentionality during cooperative interactions.

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“…Our and others’ previous results suggest that this interactivity-dependent modulation of action observation might depend on a modulation of the brain activity in fronto-parietal areas 51 – 59 , see also Ref. 60 . Specifically, in the present paradigm, the left ventral premotor cortex might play a critical role 16 , because it is responsible for goal predictions for hand movements in humans 61 , 62 and non-human primates 63 , 64 .…”

Section: Discussionsupporting

confidence: 55%

Mechanisms for mutual support in motor interactions

Sacheli

Musco

Zazzera

et al. 2021

Sci Rep

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What is the key to successful interaction? Is it sufficient to represent a common goal, or does the way our partner achieves that goal count as well? How do we react when our partner misbehaves? We used a turn-taking music-like task requiring participants to play sequences of notes together with a partner, and we investigated how people adapt to a partner’s error that violates their expectations. Errors consisted of either playing a wrong note of a sequence that the agents were playing together (thus preventing the achievement of the joint goal) or playing the expected note with an unexpected action. In both cases, we found post-error slowing and inaccuracy suggesting the participants’ implicit tendency to correct the partner’s error and produce the action that the partner should have done. We argue that these “joint” monitoring processes depend on the motor predictions made within a (dyadic) motor plan and may represent a basic mechanism for mutual support in motor interactions.

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Two brains in action: Joint-action coding in the primate frontal cortex

Cited by 20 publications

References 47 publications

How Task Interactivity Shapes Action Observation

How Task Interactivity Shapes Action Observation

Brain-to-Brain Coupling in the Gamma-Band as a Marker of Shared Intentionality

Mechanisms for mutual support in motor interactions

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