Abstract

Auditory event-related fields (ERFs) measured with magnetoencephalography (MEG) are useful for studying the neuronal underpinnings of auditory cognition in human cortex. They have a highly subject-specific morphology, albeit certain characteristic deflections (e.g., P1m, N1m, and P2m) can be identified in most subjects. Here, we explore the reason for this subject-specificity through a combination of MEG measurements and computational modeling of auditory cortex. We test whether ERF subject-specificity can predominantly be explained in terms of each subject having an individual cortical gross anatomy, which modulates the MEG signal, or whether individual cortical dynamics is also at play. To our knowledge, this is the first time that tools to address this question are being presented. The effects of anatomical and dynamical variation on the MEG signal is simulated in a model describing the core-belt-parabelt structure of the auditory cortex, and with the dynamics based on the leaky-integrator neuron model. The experimental and simulated ERFs are characterized in terms of the N1m amplitude, latency, and width. Also, we examine the waveform grand-averaged across subjects, and the standard deviation of this grand average. The results show that the intersubject variability of the ERF arises out of both the anatomy and the dynamics of auditory cortex being specific to each subject. Moreover, our results suggest that the latency variation of the N1m is largely related to subject-specific dynamics. The findings are discussed in terms of how learning, plasticity, and sound detection are reflected in the auditory ERFs. The notion of the grand-averaged ERF is critically evaluated.

Highlights

  • The auditory event-related response is revealed by presenting a stimulus multiple times, and averaging the evoked magnetoencephalography (MEG) or electroencephalography (EEG) signal across the stimulus presentations

  • The results show that the intersubject variability of the event-related fields (ERFs) arises out of both the anatomy and the dynamics of auditory cortex being specific to each subject

  • The ERFs of populations of subjects are generated with the assumption that, in each population, the anatomical parameters A and the dynamical parameters D vary across the population in a specified way

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Summary

Introduction

The auditory event-related response is revealed by presenting a stimulus multiple times, and averaging the evoked magnetoencephalography (MEG) or electroencephalography (EEG) signal across the stimulus presentations. The resulting typical trial-averaged response is characterized by a sequence of peaks and troughs. The respective labels for these responses are P1, N1, and P2 when these are observed in EEG as the part of the event-related potential (ERP). There is a large between-subject variability of auditory event-related responses. Averaging the peak amplitude and the peak latency across subjects results in sizeable standard deviations. The grand-averaged response tends to be broader than any of the individual responses because of the variations in peak latencies. The N1/N1m can have a double-peak structure, or its rising or falling slope can have a pronounced shoulder, and many subjects exhibit no clear P2/P2m response at all

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