Abstract
AbstractNeural states shape perception at earliest cortical processing levels. Previously we showed a relationship between the N20 component of the somatosensory evoked potential (SEP), pre-stimulus alpha oscillations, and the perceived intensity in a somatosensory discrimination paradigm (Stephani et al., 2021, eLife). Here we address the follow-up question whether these excitability dynamics reflect changes in feedforward or feedback signals. Re-examining the previous EEG data, we leveraged high-frequency oscillations (HFO) as a metric for neuronal population spiking activity of the first excitatory feedforward volley in the cortex. Using Bayesian statistics, we found evidence against the involvement of HFO in moment-to-moment variability of perceived stimulus intensity, in contrast to previously observed pre-stimulus alpha and N20 effects. Given that the N20 component presumably reflects backpropagating membrane potentials towards the apical dendrites, we argue that top-down feedback processes (e.g., related to alpha oscillations) may thus rely on modulations at distal sites of involved pyramidal cells rather than on output firing changes at basal compartments.
Publisher
Cold Spring Harbor Laboratory