Ventral premotor and inferior parietal cortices make distinct contribution to action organization and intention understanding

It is well known that ventral premotor area F5 codes the goal of executed and observed motor acts. This area is anatomically connected with part of the inferior parietal cortex (area PFG), which has been recently shown to play a role in action organization and intention understanding. The aims of the present study were 1) to assess whether the discharge of F5 motor neurons and mirror neurons (MNs) codes action goals and 2) to clarify the relative contribution of F5 and PFG in action organization and intention understanding. To this purpose, we first recorded from F5 motor neurons and MNs of 2 monkeys while performing a motor task constituted by 2 actions ("grasp-to-eat" and "grasp-to-place") or observing the same task done by an experimenter. Results showed that some F5 neurons code grasping according to the goal of the action in which it is embedded. Subsequently, we recorded from PFG motor neurons and MNs of the same monkeys, using the same tasks. The comparison between the neuronal properties of F5 and PFG motor neurons suggests that PFG plays a major role in organizing natural actions. Furthermore, the similarities between MNs properties of the 2 areas indicate that they constitute a functional circuit underlying others' intention understanding

Monkey gaze behaviour during action observation and its relationship to mirror neuron activity

Mirror neurons (MNs) of the monkey ventral premotor cortex (area F5) are a class of cells that match the visual descriptions of others' actions with correspondent motor representations in the observer's brain. Several human studies suggest that one's own motor representations activated during action observation play a role in directing proactive eye movements to the site of the upcoming hand-target interaction. However, there are no data on the possible relationship between gaze behaviour and MN activity. Here we addressed this issue by simultaneously recording eye position and F5 MN activity in two macaques during free observation of a grasping action. More than half of the recorded neurons discharged stronger when the monkey looked at the action than when it did not look at it, but their firing rate was better predicted by 'when' rather than by 'how long' the monkey gazed at the location of the upcoming hand-target interaction. Interestingly, the onset of MN response was linked to the onset of the experimenter's movement, thus making motor representations potentially exploitable to drive eye movements. Furthermore, MNs discharged stronger and earlier when the gaze was 'proactive' compared with 'reactive', indicating that gaze behaviour influences MN activity. We propose that feedforward, automatic representations of other's actions could lead eye movements that, in turn, would provide the motor system with feedback information that enhances the neural representations of the ongoing action. Mirror neurons (MNs) can discharge stronger during action observation depending on whether or not the monkey looks at the action. MN response is triggered by the onset of the experimenter's movement, but when the gaze is proactive the peak of activity is earlier and the discharge intensity stronger than when the gaze is reactive. We propose that feed-forward and feed-back mechanisms might contribute to both MN response and the control of gaze behaviour during action observation. © 2013 Federation of European Neuroscience Societies and John Wiley & Sons Ltd