Statistical Methods for Brain Network Estimation 公开
Lukemire, Joshua (Spring 2021)
Published
Abstract
Functional Magnetic Resonance Imaging (fMRI) allows researchers to study neural activity by measuring changes in blood oxygen levels throughout the brain at rest or in response to experimental tasks/stimuli. In recent years, there has been great interest in using fMRI data to study brain networks. In this dissertation, we develop new statistical methods for providing reliable and robust estimation and characterization of brain networks across different cognitive states, subpopulations and imaging study designs.
In the first topic, we propose the Bayesian Joint Network Learning (BJNL) approach to joint brain network estimation that pools information across groups to estimate group-specific brain networks under a graph theoretic approach. BJNL uses information from multiple groups to estimate the probability of edges between nodes without forcing similarity in the edge strengths. The BJNL approach is shown to outperform other individual and joint estimation techniques in simulations. The technique is then applied to a Stroop fMRI data set.
Next, we propose a Sparse Bayesian Independent Component Analysis (SparseBayes ICA) for reliable estimation of individual differences in brain networks. We model the population-level ICA source signals for brain networks using a Dirichlet process mixture of Gaussians. To reliably capture individual differences on brain networks, we propose sparse estimation of the covariate effects in a hierarchical ICA model via a horseshoe prior. Through extensive simulation studies, we show our approach has improved performance in detecting covariate effects in comparison with the current group ICA methods. We then use it to perform an ICA decomposition of a motivating Zen meditation resting-state study.
In our third topic, we introduce a general framework of repeated measures Sparse Bayesian ICA (RM-SparseBayes ICA). This method provides a rigorous and much needed tool for investigating brain networks in imaging studies with complex study designs including longitudinal and/or multi-center studies. Through simulations, we show that the proposed method has considerably improved performance as compared to other potential approaches. We apply the RM-SparseBayes ICA to investigate brain network changes using the longitudinal multi-center Alzheimer’s disease data from the ADNI2 study.
Table of Contents
Introduction 1
Magnetic Resonance Imaging 2
Brain Networks 3
Bayesian Nonparametric Approaches 10
Research Topics 11
Bayesian Joint Network Learning 13
Introduction 14
Methods 19
Simulation 30
Stroop Task fMRI Analysis 38
Discussion 45
Sparse Bayesian Independent Component Analysis 50
Introduction 51
SparseBayes ICA 55
Posterior Computation 59
Simulation Studies 67
Zen Meditation Study 70
Discussion 75
Repeated Measures Sparse Bayesian Independent Component Analysis 78
Introduction 79
Methods 83
Posterior Computation 88
Simulation 93
ADNI2 Study 97
Discussion 102
Summary and Future Directions 105
Appendix for Chapter 2 108
Appendix for Chapter 3 110
Bibliography 111
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Statistical Methods for Brain Network Estimation () | 2021-04-26 12:19:56 -0400 |
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