Neural mechanisms of awareness of action
David S Jin, Oumayma Agdali, Taruna Yadav, Sharif I Kronemer, Sydney Kunkler, Shweta Majumder, Maya Khurana, Marie McCusker, Ivory Fu, Emily J Siff, Aya Khalaf, Kate L Christison-Lagay, Shanae L Aerts, Qilong Xin, Jing-Jing Li, Sarah H McGill, Michael J Crowley, Hal BlumenfeldAbstract
Awareness of action (AoA), or conscious awareness of an action just performed, is an important part of daily experience with major practical and ethical relevance, yet the neural mechanisms of AoA remain largely unknown. The main barrier to studying AoA is a lack of experimental paradigms to directly compare neural activity in aware versus unaware actions. Borrowing from the field of perceptual awareness, where exciting progress has been made by contrastive analysis of aware versus unaware stimuli, we developed a game where participants repeatedly perform nearly identical moves while engaged in a distractor task, and the participants then report awareness or unawareness of the moves they just performed. We found that on short timescales, aware actions had larger neurophysiological signals both preceding and following movement. The differences included both volitional and perceptual event related potentials (PMP, N140, P300), as well as frontal midline theta, event-related alpha/beta desynchronization, and post-move blink rates. On longer time scales, we identified a positive event related potential only preceding unaware moves, and found behavioral and pupillometric evidence for decreased attention and arousal over minutes concurrent with AoA loss. Our findings reveal three neural mechanisms that may synergistically contribute to AoA – 1. Long-term increases in arousal/attentional state at time of action; 2. Increased action-related motor volitional signals; and 3. Increased action-related sensory perceptual signals. Deeper understanding of AoA may ultimately elucidate the causes of variable AoA in daily life and lead to better treatments for impaired AoA in neuropsychiatric disorders.