Interaction effects in simultaneous motor control and movement perception tasks

Abstract

Recent findings in neuroscience suggest an overlap between those brain regions involved in the control and execution of movement and those activated during the perception of another's movement. This so called `mirror neuron' system is thought to underlie our ability to automatically infer the goals and intentions of others by observing their actions. Kilner et al. (Curr Biol 13(6):522---525, 2003) provide evidence for a human `mirror neuron' system by showing that the execution of simple arm movements is affected by the simultaneous perception of another's movement. Specifically, observation of `incongruent' movements made by another human, but not by a robotic arm, leads to greater variability in the movement trajectory than observation of movements in the same direction. In this study we ask which aspects of the observed motion are crucial to this interference effect by comparing the efficacy of real human movement to that of sparse `point-light displays'. Eight participants performed whole arm movements in both horizontal and vertical directions while observing either the experimenter or a virtual `point-light' figure making arm movements in the same or in a different direction. Our results, however, failed to show an effect of `congruency' of the observed movement on movement variability, regardless of whether a human actor or point-light figure was observed. The findings are discussed, and future directions for studies of perception-action coupling are considered.