Auditory Cortical Changes Precede Brainstem Changes During Rapid Implicit Learning: Evidence From Human EEG.

Erika Skoe,Nina Kraus,Emily R Spitzer,Jennifer Krizman

doi:10.3389/fnins.2021.718230

Erika Skoe, Nina Kraus + Show 2 more

Open Access

https://doi.org/10.3389/fnins.2021.718230

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Abstract

The auditory system is sensitive to stimulus regularities such as frequently occurring sounds and sound combinations. Evidence of regularity detection can be seen in how neurons across the auditory network, from brainstem to cortex, respond to the statistical properties of the soundscape, and in the rapid learning of recurring patterns in their environment by children and adults. Although rapid auditory learning is presumed to involve functional changes to the auditory network, the chronology and directionality of changes are not well understood. To study the mechanisms by which this learning occurs, auditory brainstem and cortical activity was simultaneously recorded via electroencephalogram (EEG) while young adults listened to novel sound streams containing recurring patterns. Neurophysiological responses were compared between easier and harder learning conditions. Collectively, the behavioral and neurophysiological findings suggest that cortical and subcortical structures each provide distinct contributions to auditory pattern learning, but that cortical sensitivity to stimulus patterns likely precedes subcortical sensitivity.

Highlights

Natural sound environments are rich with temporal and spectral patterns that repeat over different timescales
Evidence of rapid neural computations relating to predictive coding can be observed across the central auditory network, from brainstem to auditory cortex (Carbajal and Malmierca, 2018)
Groups were statistically matched with respect to pure tone hearing thresholds in the 250–8kHz range, auditory brainstem response Wave V latency, IQ, auditory working memory, total years of musical training, and performance on a musical skills test

Summary

Introduction

Natural sound environments are rich with temporal and spectral patterns that repeat over different timescales. To extract these patterns, the brain must analyze the soundscape to learn about its statistical properties, including the probability that two sounds repeatedly co-occur. The brain must analyze the soundscape to learn about its statistical properties, including the probability that two sounds repeatedly co-occur This analysis happens rapidly and often without conscious awareness. Brainstem and cortical structures operate reciprocally through ascending and descending pathways (Winer, 2006). Through the descending corticofugal pathway, the auditory cortex can alter the input it receives, inducing short-term changes and long-term subcortical reorganization that either facilitate or

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