LAUSR

Accumulating evidence suggests that peripheral physiological processes, such as the cardiac cycle, impact the individual's ability to appropriately exert control over behaviour and emotional responses. We examine, whether response selection processes during cognitive-emotional control and its neurophysiological correlates, can be experimentally controlled in a cardiac-cycle dependent manner. To this end, we designed an experimental setup in which the EEG experiment, an emotional Stroop task, was controlled by the individual's electrocardiogram (ECG). Since theoretical considerations suggest that the effects of the cardiac cycle may affect only specific aspects during information processing, we apply EEG signal decomposition before examining functional neuroanatomical regions associated with cardiac-cycle dependent effects with EEG-beamforming approaches. Analyzing N=27 healthy participants, we show that the cardiac-cycle specifically affects response selection processes, when demands on cognitive-emotional control are low. Response execution processes are sped up when trials are presented shortly after the ECG R peak. These effects were confined to conditions were response selection is not modulated by cognitive-emotional conflicts, which is in line with theoretical concepts on response selection. Corroborating the behavioural data, the EEG data show that particularly motor response-related processes encoded in the theta frequency band in middle and superior frontal regions (BA6) are differentially modulated by cardiac phase and difficulty to select a response. The presented work has an essential methodological focus in cognitive neuroscience for investigating brain-body interaction. It shows how peripheral-physiological parameters can be used to control EEG experiments and that the cardiac cycle has very specific effects in neurophysiological processes and associated functional neuroanatomical structures.