Intensity warping for multisite MRI harmonization

J. Wrobel; M. L. Martin; R. Bakshi; P. A. Calabresi; M. Elliot; D. Roalf; R. C. Gur; R. E. Gur; R. G. Henry; G. Nair; J. Oh; N. Papinutto; D. Pelletier; D. S. Reich; W. D. Rooney; T. D. Satterthwaite; W. Stern; K. Prabhakaran; N. L. Sicotte; R. T. Shinohara; J. Goldsmith

doi:10.1016/j.neuroimage.2020.117242

Intensity warping for multisite MRI harmonization

J. Wrobel, M. L. Martin, R. Bakshi, P. A. Calabresi, M. Elliot, D. Roalf, R. C. Gur, R. E. Gur, R. G. Henry, G. Nair, J. Oh, N. Papinutto, D. Pelletier, D. S. Reich, W. D. Rooney, T. D. Satterthwaite, W. Stern, K. Prabhakaran, N. L. Sicotte, R. T. ShinoharaJ. Goldsmith

School of Medicine

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

In multisite neuroimaging studies there is often unwanted technical variation across scanners and sites. These “scanner effects” can hinder detection of biological features of interest, produce inconsistent results, and lead to spurious associations. We propose mica (multisite image harmonization by cumulative distribution function alignment), a tool to harmonize images taken on different scanners by identifying and removing within-subject scanner effects. Our goals in the present study were to (1) establish a method that removes scanner effects by leveraging multiple scans collected on the same subject, and, building on this, (2) develop a technique to quantify scanner effects in large multisite studies so these can be reduced as a preprocessing step. We illustrate scanner effects in a brain MRI study in which the same subject was measured twice on seven scanners, and assess our method's performance in a second study in which ten subjects were scanned on two machines. We found that unharmonized images were highly variable across site and scanner type, and our method effectively removed this variability by aligning intensity distributions. We further studied the ability to predict image harmonization results for a scan taken on an existing subject at a new site using cross-validation.

Original language	English (US)
Article number	117242
Journal	NeuroImage
Volume	223
DOIs	https://doi.org/10.1016/j.neuroimage.2020.117242
State	Published - Dec 2020

Keywords

Elsarticle.cls
Image harmonization
Intensity normalization
Multisite imaging
Warping

ASJC Scopus subject areas

Neurology
Cognitive Neuroscience

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10.1016/j.neuroimage.2020.117242

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Wrobel, J., Martin, M. L., Bakshi, R., Calabresi, P. A., Elliot, M., Roalf, D., Gur, R. C., Gur, R. E., Henry, R. G., Nair, G., Oh, J., Papinutto, N., Pelletier, D., Reich, D. S., Rooney, W. D., Satterthwaite, T. D., Stern, W., Prabhakaran, K., Sicotte, N. L., ... Goldsmith, J. (2020). Intensity warping for multisite MRI harmonization. NeuroImage, 223, Article 117242. https://doi.org/10.1016/j.neuroimage.2020.117242

Wrobel, J, Martin, ML, Bakshi, R, Calabresi, PA, Elliot, M, Roalf, D, Gur, RC, Gur, RE, Henry, RG, Nair, G, Oh, J, Papinutto, N, Pelletier, D, Reich, DS, Rooney, WD, Satterthwaite, TD, Stern, W, Prabhakaran, K, Sicotte, NL, Shinohara, RT & Goldsmith, J 2020, 'Intensity warping for multisite MRI harmonization', NeuroImage, vol. 223, 117242. https://doi.org/10.1016/j.neuroimage.2020.117242

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abstract = "In multisite neuroimaging studies there is often unwanted technical variation across scanners and sites. These “scanner effects” can hinder detection of biological features of interest, produce inconsistent results, and lead to spurious associations. We propose mica (multisite image harmonization by cumulative distribution function alignment), a tool to harmonize images taken on different scanners by identifying and removing within-subject scanner effects. Our goals in the present study were to (1) establish a method that removes scanner effects by leveraging multiple scans collected on the same subject, and, building on this, (2) develop a technique to quantify scanner effects in large multisite studies so these can be reduced as a preprocessing step. We illustrate scanner effects in a brain MRI study in which the same subject was measured twice on seven scanners, and assess our method's performance in a second study in which ten subjects were scanned on two machines. We found that unharmonized images were highly variable across site and scanner type, and our method effectively removed this variability by aligning intensity distributions. We further studied the ability to predict image harmonization results for a scan taken on an existing subject at a new site using cross-validation.",

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AU - Martin, M. L.

AU - Bakshi, R.

AU - Calabresi, P. A.

AU - Elliot, M.

AU - Roalf, D.

AU - Gur, R. C.

AU - Gur, R. E.

AU - Henry, R. G.

AU - Nair, G.

AU - Oh, J.

AU - Papinutto, N.

AU - Pelletier, D.

AU - Reich, D. S.

AU - Rooney, W. D.

AU - Satterthwaite, T. D.

AU - Stern, W.

AU - Prabhakaran, K.

AU - Sicotte, N. L.

AU - Shinohara, R. T.

AU - Goldsmith, J.

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AB - In multisite neuroimaging studies there is often unwanted technical variation across scanners and sites. These “scanner effects” can hinder detection of biological features of interest, produce inconsistent results, and lead to spurious associations. We propose mica (multisite image harmonization by cumulative distribution function alignment), a tool to harmonize images taken on different scanners by identifying and removing within-subject scanner effects. Our goals in the present study were to (1) establish a method that removes scanner effects by leveraging multiple scans collected on the same subject, and, building on this, (2) develop a technique to quantify scanner effects in large multisite studies so these can be reduced as a preprocessing step. We illustrate scanner effects in a brain MRI study in which the same subject was measured twice on seven scanners, and assess our method's performance in a second study in which ten subjects were scanned on two machines. We found that unharmonized images were highly variable across site and scanner type, and our method effectively removed this variability by aligning intensity distributions. We further studied the ability to predict image harmonization results for a scan taken on an existing subject at a new site using cross-validation.

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Intensity warping for multisite MRI harmonization

Abstract

Keywords

ASJC Scopus subject areas

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