Bayesian spatial transformation models with applications in neuroimaging data

Michelle F. Miranda; Hongtu Zhu; Joseph G. Ibrahim

doi:10.1111/biom.12085

Bayesian spatial transformation models with applications in neuroimaging data

Michelle F. Miranda, Hongtu Zhu, Joseph G. Ibrahim

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

6 Scopus citations

Abstract

Summary: The aim of this article is to develop a class of spatial transformation models (STM) to spatially model the varying association between imaging measures in a three-dimensional (3D) volume (or 2D surface) and a set of covariates. The proposed STM include a varying Box-Cox transformation model for dealing with the issue of non-Gaussian distributed imaging data and a Gaussian Markov random field model for incorporating spatial smoothness of the imaging data. Posterior computation proceeds via an efficient Markov chain Monte Carlo algorithm. Simulations and real data analysis demonstrate that the STM significantly outperforms the voxel-wise linear model with Gaussian noise in recovering meaningful geometric patterns. Our STM is able to reveal important brain regions with morphological changes in children with attention deficit hyperactivity disorder.

Original language	English (US)
Pages (from-to)	1074-1083
Number of pages	10
Journal	Biometrics
Volume	69
Issue number	4
DOIs	https://doi.org/10.1111/biom.12085
State	Published - Dec 2013

Keywords

Bayesian analysis
Big data
Box-Cox transformation
Gaussian Markov random field
MCMC
Neuroimaging data

ASJC Scopus subject areas

Statistics and Probability
General Biochemistry, Genetics and Molecular Biology
General Immunology and Microbiology
General Agricultural and Biological Sciences
Applied Mathematics

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10.1111/biom.12085

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abstract = "Summary: The aim of this article is to develop a class of spatial transformation models (STM) to spatially model the varying association between imaging measures in a three-dimensional (3D) volume (or 2D surface) and a set of covariates. The proposed STM include a varying Box-Cox transformation model for dealing with the issue of non-Gaussian distributed imaging data and a Gaussian Markov random field model for incorporating spatial smoothness of the imaging data. Posterior computation proceeds via an efficient Markov chain Monte Carlo algorithm. Simulations and real data analysis demonstrate that the STM significantly outperforms the voxel-wise linear model with Gaussian noise in recovering meaningful geometric patterns. Our STM is able to reveal important brain regions with morphological changes in children with attention deficit hyperactivity disorder.",

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AU - Zhu, Hongtu

AU - Ibrahim, Joseph G.

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AB - Summary: The aim of this article is to develop a class of spatial transformation models (STM) to spatially model the varying association between imaging measures in a three-dimensional (3D) volume (or 2D surface) and a set of covariates. The proposed STM include a varying Box-Cox transformation model for dealing with the issue of non-Gaussian distributed imaging data and a Gaussian Markov random field model for incorporating spatial smoothness of the imaging data. Posterior computation proceeds via an efficient Markov chain Monte Carlo algorithm. Simulations and real data analysis demonstrate that the STM significantly outperforms the voxel-wise linear model with Gaussian noise in recovering meaningful geometric patterns. Our STM is able to reveal important brain regions with morphological changes in children with attention deficit hyperactivity disorder.

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KW - Box-Cox transformation

KW - Gaussian Markov random field

KW - MCMC

KW - Neuroimaging data

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Bayesian spatial transformation models with applications in neuroimaging data

Abstract

Keywords

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