Detecting (Un)seen Change: The Neural Underpinnings of (Un)conscious Prediction Errors

Detecting (Un)seen Change: The Neural Underpinnings of (Un)conscious Prediction Errors

Detecting changes in the environment is fundamental for our survival. According to predictive coding theory, detecting these irregularities relies both on incoming sensory information and our top–down prior expectations (or internal generative models) about the world. Prediction errors (PEs), detect...

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Main Authors: Elise G. Rowe, Naotsugu Tsuchiya, Marta I. Garrido
Format: Article
Language:English
Published: Frontiers Media S.A. 2020-11-01
Series:Frontiers in Systems Neuroscience
Subjects:
consciousness
prediction errors
DCM
vMMN
EEG
Online Access:https://www.frontiersin.org/articles/10.3389/fnsys.2020.541670/full
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spelling doaj-2c71032f13ac46ef9725bffef5c74a9b2020-11-25T03:59:07ZengFrontiers Media S.A.Frontiers in Systems Neuroscience1662-51372020-11-011410.3389/fnsys.2020.541670541670Detecting (Un)seen Change: The Neural Underpinnings of (Un)conscious Prediction ErrorsElise G. Rowe0Elise G. Rowe1Elise G. Rowe2Elise G. Rowe3Naotsugu Tsuchiya4Naotsugu Tsuchiya5Naotsugu Tsuchiya6Naotsugu Tsuchiya7Naotsugu Tsuchiya8Marta I. Garrido9Marta I. Garrido10Marta I. Garrido11Marta I. Garrido12School of Psychological Sciences, Faculty of Medicine, Nursing and Health Sciences, Monash University, Clayton, VIC, AustraliaTurner Institute for Brain and Mental Health, Monash University, Clayton, VIC, AustraliaQueensland Brain Institute, The University of Queensland, Saint Lucia, QLD, AustraliaCentre for Advanced Imaging, The University of Queensland, Saint Lucia, QLD, AustraliaSchool of Psychological Sciences, Faculty of Medicine, Nursing and Health Sciences, Monash University, Clayton, VIC, AustraliaTurner Institute for Brain and Mental Health, Monash University, Clayton, VIC, AustraliaCenter for Information and Neural Networks, National Institute of Information and Communications Technology, Suita, JapanAdvanced Telecommunications Research Computational Neuroscience Laboratories, Kyoto, JapanARC Centre of Excellence for Integrative Brain Function, Clayton, VIC, AustraliaQueensland Brain Institute, The University of Queensland, Saint Lucia, QLD, AustraliaCentre for Advanced Imaging, The University of Queensland, Saint Lucia, QLD, AustraliaARC Centre of Excellence for Integrative Brain Function, Clayton, VIC, AustraliaMelbourne School of Psychological Sciences, The University of Melbourne, Melbourne, VIC, AustraliaDetecting changes in the environment is fundamental for our survival. According to predictive coding theory, detecting these irregularities relies both on incoming sensory information and our top–down prior expectations (or internal generative models) about the world. Prediction errors (PEs), detectable in event-related potentials (ERPs), occur when there is a mismatch between the sensory input and our internal model (i.e., a surprise event). Many changes occurring in our environment are irrelevant for survival and may remain unseen. Such changes, even if subtle, can nevertheless be detected by the brain without emerging into consciousness. What remains unclear is how these changes are processed in the brain at the network level. Here, we used a visual oddball paradigm in which participants engaged in a central letter task during electroencephalographic (EEG) recordings while presented with task-irrelevant high- or low-coherence background, random-dot motion. Critically, once in a while, the direction of the dots changed. After the EEG session, we confirmed that changes in motion direction at high- and low-coherence were visible and invisible, respectively, using psychophysical measurements. ERP analyses revealed that changes in motion direction elicited PE regardless of the visibility, but with distinct spatiotemporal patterns. To understand these responses, we applied dynamic causal modeling (DCM) to the EEG data. Bayesian Model Averaging showed visible PE relied on a release from adaptation (repetition suppression) within bilateral MT+, whereas invisible PE relied on adaptation at bilateral V1 (and left MT+). Furthermore, while feedforward upregulation was present for invisible PE, the visible change PE also included downregulation of feedback between right MT+ to V1. Our findings reveal a complex interplay of modulation in the generative network models underlying visible and invisible motion changes.https://www.frontiersin.org/articles/10.3389/fnsys.2020.541670/fullconsciousnessprediction errorsDCMvMMNEEG
collection DOAJ
language English
format Article
sources DOAJ
author Elise G. Rowe
Elise G. Rowe
Elise G. Rowe
Elise G. Rowe
Naotsugu Tsuchiya
Naotsugu Tsuchiya
Naotsugu Tsuchiya
Naotsugu Tsuchiya
Naotsugu Tsuchiya
Marta I. Garrido
Marta I. Garrido
Marta I. Garrido
Marta I. Garrido
spellingShingle Elise G. Rowe
Elise G. Rowe
Elise G. Rowe
Elise G. Rowe
Naotsugu Tsuchiya
Naotsugu Tsuchiya
Naotsugu Tsuchiya
Naotsugu Tsuchiya
Naotsugu Tsuchiya
Marta I. Garrido
Marta I. Garrido
Marta I. Garrido
Marta I. Garrido
Detecting (Un)seen Change: The Neural Underpinnings of (Un)conscious Prediction Errors
Frontiers in Systems Neuroscience
consciousness
prediction errors
DCM
vMMN
EEG
author_facet Elise G. Rowe
Elise G. Rowe
Elise G. Rowe
Elise G. Rowe
Naotsugu Tsuchiya
Naotsugu Tsuchiya
Naotsugu Tsuchiya
Naotsugu Tsuchiya
Naotsugu Tsuchiya
Marta I. Garrido
Marta I. Garrido
Marta I. Garrido
Marta I. Garrido
author_sort Elise G. Rowe
title Detecting (Un)seen Change: The Neural Underpinnings of (Un)conscious Prediction Errors
title_short Detecting (Un)seen Change: The Neural Underpinnings of (Un)conscious Prediction Errors
title_full Detecting (Un)seen Change: The Neural Underpinnings of (Un)conscious Prediction Errors
title_fullStr Detecting (Un)seen Change: The Neural Underpinnings of (Un)conscious Prediction Errors
title_full_unstemmed Detecting (Un)seen Change: The Neural Underpinnings of (Un)conscious Prediction Errors
title_sort detecting (un)seen change: the neural underpinnings of (un)conscious prediction errors
publisher Frontiers Media S.A.
series Frontiers in Systems Neuroscience
issn 1662-5137
publishDate 2020-11-01
description Detecting changes in the environment is fundamental for our survival. According to predictive coding theory, detecting these irregularities relies both on incoming sensory information and our top–down prior expectations (or internal generative models) about the world. Prediction errors (PEs), detectable in event-related potentials (ERPs), occur when there is a mismatch between the sensory input and our internal model (i.e., a surprise event). Many changes occurring in our environment are irrelevant for survival and may remain unseen. Such changes, even if subtle, can nevertheless be detected by the brain without emerging into consciousness. What remains unclear is how these changes are processed in the brain at the network level. Here, we used a visual oddball paradigm in which participants engaged in a central letter task during electroencephalographic (EEG) recordings while presented with task-irrelevant high- or low-coherence background, random-dot motion. Critically, once in a while, the direction of the dots changed. After the EEG session, we confirmed that changes in motion direction at high- and low-coherence were visible and invisible, respectively, using psychophysical measurements. ERP analyses revealed that changes in motion direction elicited PE regardless of the visibility, but with distinct spatiotemporal patterns. To understand these responses, we applied dynamic causal modeling (DCM) to the EEG data. Bayesian Model Averaging showed visible PE relied on a release from adaptation (repetition suppression) within bilateral MT+, whereas invisible PE relied on adaptation at bilateral V1 (and left MT+). Furthermore, while feedforward upregulation was present for invisible PE, the visible change PE also included downregulation of feedback between right MT+ to V1. Our findings reveal a complex interplay of modulation in the generative network models underlying visible and invisible motion changes.
topic consciousness
prediction errors
DCM
vMMN
EEG
url https://www.frontiersin.org/articles/10.3389/fnsys.2020.541670/full
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