Capturing inter-subject variability with group independent component analysis of fMRI data: A simulation study

A key challenge in functional neuroimaging is the meaningful combination of results across subjects. Even in a sample of healthy participants, brain morphology and functional organization exhibit considerable variability, such that no two individuals have the same neural activation at the same locat...

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Published inNeuroImage (Orlando, Fla.) Vol. 59; no. 4; pp. 4141 - 4159
Main Authors Allen, Elena A., Erhardt, Erik B., Wei, Yonghua, Eichele, Tom, Calhoun, Vince D.
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 15.02.2012
Elsevier Limited
Subjects
Brain - physiology
Brain research
Datasets
Experiments
fMRI
Group ICA
Humans
Inter-subject variability
Magnetic Resonance Imaging - methods
Model order
Multi-subject
Principal Component Analysis
Quality
Simulations
Standard deviation
Studies
fMRI
Simulations
Group ICA
Multi-subject
Inter-subject variability
Model order
Online AccessGet full text

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Abstract A key challenge in functional neuroimaging is the meaningful combination of results across subjects. Even in a sample of healthy participants, brain morphology and functional organization exhibit considerable variability, such that no two individuals have the same neural activation at the same location in response to the same stimulus. This inter-subject variability limits inferences at the group-level as average activation patterns may fail to represent the patterns seen in individuals. A promising approach to multi-subject analysis is group independent component analysis (GICA), which identifies group components and reconstructs activations at the individual level. GICA has gained considerable popularity, particularly in studies where temporal response models cannot be specified. However, a comprehensive understanding of the performance of GICA under realistic conditions of inter-subject variability is lacking. In this study we use simulated functional magnetic resonance imaging (fMRI) data to determine the capabilities and limitations of GICA under conditions of spatial, temporal, and amplitude variability. Simulations, generated with the SimTB toolbox, address questions that commonly arise in GICA studies, such as: (1) How well can individual subject activations be estimated and when will spatial variability preclude estimation? (2) Why does component splitting occur and how is it affected by model order? (3) How should we analyze component features to maximize sensitivity to intersubject differences? Overall, our results indicate an excellent capability of GICA to capture between-subject differences and we make a number of recommendations regarding analytic choices for application to functional imaging data. ► We assess performance of group ICA under inter-subject variability. ► Spatial variability is captured well when activations overlap moderately. ► Component amplitude is well estimated when using a joint estimator. ► Splitting is affected by spatio-temporal variability, data quantity and quality.
AbstractList A key challenge in functional neuroimaging is the meaningful combination of results across subjects. Even in a sample of healthy participants, brain morphology and functional organization exhibit considerable variability, such that no two individuals have the same neural activation at the same location in response to the same stimulus. This inter-subject variability limits inferences at the group-level as average activation patterns may fail to represent the patterns seen in individuals. A promising approach to multi-subject analysis is group independent component analysis (GICA), which identifies group components and reconstructs activations at the individual level. GICA has gained considerable popularity, particularly in studies where temporal response models cannot be specified. However, a comprehensive understanding of the performance of GICA under realistic conditions of inter-subject variability is lacking. In this study we use simulated functional magnetic resonance imaging (fMRI) data to determine the capabilities and limitations of GICA under conditions of spatial, temporal, and amplitude variability. Simulations, generated with the SimTB toolbox, address questions that commonly arise in GICA studies, such as: (1) How well can individual subject activations be estimated and when will spatial variability preclude estimation? (2) Why does component splitting occur and how is it affected by model order? (3) How should we analyze component features to maximize sensitivity to inter-subject differences? Overall, our results indicate an excellent capability of GICA to capture between-subject differences and we make a number of recommendations regarding analytic choices for application to functional imaging data.
A key challenge in functional neuroimaging is the meaningful combination of results across subjects. Even in a sample of healthy participants, brain morphology and functional organization exhibit considerable variability, such that no two individuals have the same neural activation at the same location in response to the same stimulus. This inter-subject variability limits inferences at the group-level as average activation patterns may fail to represent the patterns seen in individuals. A promising approach to multi-subject analysis is group independent component analysis (GICA), which identifies group components and reconstructs activations at the individual level. GICA has gained considerable popularity, particularly in studies where temporal response models cannot be specified. However, a comprehensive understanding of the performance of GICA under realistic conditions of inter-subject variability is lacking. In this study we use simulated functional magnetic resonance imaging (fMRI) data to determine the capabilities and limitations of GICA under conditions of spatial, temporal, and amplitude variability. Simulations, generated with the SimTB toolbox, address questions that commonly arise in GICA studies, such as: (1) How well can individual subject activations be estimated and when will spatial variability preclude estimation? (2) Why does component splitting occur and how is it affected by model order? (3) How should we analyze component features to maximize sensitivity to intersubject differences? Overall, our results indicate an excellent capability of GICA to capture between-subject differences and we make a number of recommendations regarding analytic choices for application to functional imaging data. ► We assess performance of group ICA under inter-subject variability. ► Spatial variability is captured well when activations overlap moderately. ► Component amplitude is well estimated when using a joint estimator. ► Splitting is affected by spatio-temporal variability, data quantity and quality.
A key challenge in functional neuroimaging is the meaningful combination of results across subjects. Even in a sample of healthy participants, brain morphology and functional organization exhibit considerable variability, such that no two individuals have the same neural activation at the same location in response to the same stimulus. This inter-subject variability limits inferences at the group-level as average activation patterns may fail to represent the patterns seen in individuals. A promising approach to multi-subject analysis is group independent component analysis (GICA), which identifies group components and reconstructs activations at the individual level. GICA has gained considerable popularity, particularly in studies where temporal response models cannot be specified. However, a comprehensive understanding of the performance of GICA under realistic conditions of inter-subject variability is lacking. In this study we use simulated functional magnetic resonance imaging (fMRI) data to determine the capabilities and limitations of GICA under conditions of spatial, temporal, and amplitude variability. Simulations, generated with the SimTB toolbox, address questions that commonly arise in GICA studies, such as: (1) How well can individual subject activations be estimated and when will spatial variability preclude estimation? (2) Why does component splitting occur and how is it affected by model order? (3) How should we analyze component features to maximize sensitivity to intersubject differences? Overall, our results indicate an excellent capability of GICA to capture between-subject differences and we make a number of recommendations regarding analytic choices for application to functional imaging data.A key challenge in functional neuroimaging is the meaningful combination of results across subjects. Even in a sample of healthy participants, brain morphology and functional organization exhibit considerable variability, such that no two individuals have the same neural activation at the same location in response to the same stimulus. This inter-subject variability limits inferences at the group-level as average activation patterns may fail to represent the patterns seen in individuals. A promising approach to multi-subject analysis is group independent component analysis (GICA), which identifies group components and reconstructs activations at the individual level. GICA has gained considerable popularity, particularly in studies where temporal response models cannot be specified. However, a comprehensive understanding of the performance of GICA under realistic conditions of inter-subject variability is lacking. In this study we use simulated functional magnetic resonance imaging (fMRI) data to determine the capabilities and limitations of GICA under conditions of spatial, temporal, and amplitude variability. Simulations, generated with the SimTB toolbox, address questions that commonly arise in GICA studies, such as: (1) How well can individual subject activations be estimated and when will spatial variability preclude estimation? (2) Why does component splitting occur and how is it affected by model order? (3) How should we analyze component features to maximize sensitivity to intersubject differences? Overall, our results indicate an excellent capability of GICA to capture between-subject differences and we make a number of recommendations regarding analytic choices for application to functional imaging data.
A key challenge in functional neuroimaging is the meaningful combination of results across subjects. Even in a sample of healthy participants, brain morphology and functional organization exhibit considerable variability, such that no two individuals have the same neural activation at the same location in response to the same stimulus. This inter-subject variability limits inferences at the group-level as average activation patterns may fail to represent the patterns seen in individuals. A promising approach to multi-subject analysis is group independent component analysis (GICA), which identifies group components and reconstructs activations at the individual level. GICA has gained considerable popularity, particularly in studies where temporal response models cannot be specified. However, a comprehensive understanding of the performance of GICA under realistic conditions of inter-subject variability is lacking. In this study we use simulated functional magnetic resonance imaging (fMRI) data to determine the capabilities and limitations of GICA under conditions of spatial, temporal, and amplitude variability. Simulations, generated with the SimTB toolbox, address questions that commonly arise in GICA studies, such as: (1) How well can individual subject activations be estimated and when will spatial variability preclude estimation? (2) Why does component splitting occur and how is it affected by model order? (3) How should we analyze component features to maximize sensitivity to intersubject differences? Overall, our results indicate an excellent capability of GICA to capture between-subject differences and we make a number of recommendations regarding analytic choices for application to functional imaging data.
Author Wei, Yonghua
Erhardt, Erik B.
Allen, Elena A.
Eichele, Tom
Calhoun, Vince D.
AuthorAffiliation a The Mind Research Network, Albuquerque, NM, USA
b Department of Statistics, University of New Mexico, Albuquerque, NM, USA
c Department of Biological and Medical Psychology, University of Bergen, Bergen, Norway
d Department of Electrical and Computer Engineering, University of New Mexico, Albuquerque, NM, USA
AuthorAffiliation_xml – name: b Department of Statistics, University of New Mexico, Albuquerque, NM, USA
– name: c Department of Biological and Medical Psychology, University of Bergen, Bergen, Norway
– name: d Department of Electrical and Computer Engineering, University of New Mexico, Albuquerque, NM, USA
– name: a The Mind Research Network, Albuquerque, NM, USA
Author_xml – sequence: 1
  givenname: Elena A.
  surname: Allen
  fullname: Allen, Elena A.
  email: eallen@mrn.org
  organization: The Mind Research Network, Albuquerque, NM, USA
– sequence: 2
  givenname: Erik B.
  surname: Erhardt
  fullname: Erhardt, Erik B.
  organization: The Mind Research Network, Albuquerque, NM, USA
– sequence: 3
  givenname: Yonghua
  surname: Wei
  fullname: Wei, Yonghua
  organization: Department of Mathematics & Statistics, University of New Mexico, Albuquerque, NM, USA
– sequence: 4
  givenname: Tom
  surname: Eichele
  fullname: Eichele, Tom
  organization: Department of Biological and Medical Psychology, University of Bergen, Bergen, Norway
– sequence: 5
  givenname: Vince D.
  surname: Calhoun
  fullname: Calhoun, Vince D.
  organization: The Mind Research Network, Albuquerque, NM, USA
BackLink https://www.ncbi.nlm.nih.gov/pubmed/22019879$$D View this record in MEDLINE/PubMed
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Copyright 2011 Elsevier Inc.
Copyright © 2011 Elsevier Inc. All rights reserved.
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Keywords fMRI
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Snippet A key challenge in functional neuroimaging is the meaningful combination of results across subjects. Even in a sample of healthy participants, brain morphology...
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SubjectTerms Brain - physiology
Brain research
Datasets
Experiments
fMRI
Group ICA
Humans
Inter-subject variability
Magnetic Resonance Imaging - methods
Model order
Multi-subject
Principal Component Analysis
Quality
Simulations
Standard deviation
Studies
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Title Capturing inter-subject variability with group independent component analysis of fMRI data: A simulation study
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https://dx.doi.org/10.1016/j.neuroimage.2011.10.010
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