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Broadband Dynamics Rather than Frequency-Specific Rhythms Underlie Prediction Error in the Primate Auditory Cortex

Andrés Canales-Johnson, Ana Filipa Teixeira Borges, Misako Komatsu, Naotaka Fujii, Johannes J. Fahrenfort, Kai J. Miller, Valdas Noreika

2021Journal of Neuroscience20 citationsDOIOpen Access PDF

Abstract

Detection of statistical irregularities, measured as a prediction error response, is fundamental to the perceptual monitoring of the environment. We studied whether prediction error response is associated with neural oscillations or asynchronous broadband activity. Electrocorticography was conducted in three male monkeys, who passively listened to the auditory roving oddball stimuli. Local field potentials (LFPs) recorded over the auditory cortex underwent spectral principal component analysis, which decoupled broadband and rhythmic components of the LFP signal. We found that the broadband component captured the prediction error response, whereas none of the rhythmic components were associated with statistical irregularities of sounds. The broadband component displayed more stochastic, asymmetrical multifractal properties than the rhythmic components, which revealed more self-similar dynamics. We thus conclude that the prediction error response is captured by neuronal populations generating asynchronous broadband activity, defined by irregular dynamic states, which, unlike oscillatory rhythms, appear to enable the neural representation of auditory prediction error response. SIGNIFICANCE STATEMENT This study aimed to examine the contribution of oscillatory and asynchronous components of auditory local field potentials in the generation of prediction error responses to sensory irregularities, as this has not been directly addressed in the previous studies. Here, we show that mismatch negativity—an auditory prediction error response—is driven by the asynchronous broadband component of potentials recorded in the auditory cortex. This finding highlights the importance of nonoscillatory neural processes in the predictive monitoring of the environment. At a more general level, the study demonstrates that stochastic neural processes, which are often disregarded as neural noise, do have a functional role in the processing of sensory information.

Topics & Concepts

Local field potentialAsynchronous communicationAuditory cortexBroadbandComputer scienceRhythmArtificial neural networkComponent (thermodynamics)Principal component analysisSpeech recognitionMean squared prediction errorNeurosciencePerceptionField (mathematics)Auditory systemAuditory perceptionRepresentation (politics)ElectrocorticographyDynamics (music)Auditory scene analysisNeural activityIndependent component analysisSpike (software development)Artificial intelligenceElectroencephalographyPattern recognition (psychology)Sensory systemPsychologyNeuroscience and Music PerceptionNeural dynamics and brain functionComplex Systems and Time Series Analysis
Broadband Dynamics Rather than Frequency-Specific Rhythms Underlie Prediction Error in the Primate Auditory Cortex | Litcius