Remodeling Pearson's Correlation for Functional Brain Network Estimation and Autism Spectrum Disorder Identification

Functional brain network (FBN) has been becoming an increasingly important way to model the statistical dependence among neural time courses of brain, and provides effective imaging biomarkers for diagnosis of some neurological or psychological disorders. Currently, Pearson's Correlation (PC) i...

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Bibliographic Details
Published in:Frontiers in neuroinformatics 2017-08, Vol.11, p.55-55
Main Authors: Li, Weikai, Wang, Zhengxia, Zhang, Limei, Qiao, Lishan, Shen, Dinggang
Format: Article
Language:English
Subjects:
Alzheimer's disease
Autism
autism spectrum disorder
Brain
Cognitive ability
functional brain network
functional magnetic resonance imaging
Mathematical models
Methods
Neuroimaging
Neurological diseases
Neuroscience
NMR
Nuclear magnetic resonance
Optimization
Pearson's correlation
scale-free
sparse representation
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Summary:Functional brain network (FBN) has been becoming an increasingly important way to model the statistical dependence among neural time courses of brain, and provides effective imaging biomarkers for diagnosis of some neurological or psychological disorders. Currently, Pearson's Correlation (PC) is the simplest and most widely-used method in constructing FBNs. Despite its advantages in statistical meaning and calculated performance, the PC tends to result in a FBN with dense connections. Therefore, in practice, the PC-based FBN needs to be sparsified by removing weak (potential noisy) connections. However, such a scheme depends on a hard-threshold without enough flexibility. Different from this traditional strategy, in this paper, we propose a new approach for estimating FBNs by remodeling PC as an optimization problem, which provides a way to incorporate biological/physical priors into the FBNs. In particular, we introduce an L -norm regularizer into the optimization model for obtaining a sparse solution. Compared with the hard-threshold scheme, the proposed framework gives an elegant mathematical formulation for sparsifying PC-based networks. More importantly, it provides a platform to encode other biological/physical priors into the PC-based FBNs. To further illustrate the flexibility of the proposed method, we extend the model to a weighted counterpart for learning both sparse and scale-free networks, and then conduct experiments to identify autism spectrum disorders (ASD) from normal controls (NC) based on the constructed FBNs. Consequently, we achieved an 81.52% classification accuracy which outperforms the baseline and state-of-the-art methods.
ISSN:1662-5196
1662-5196
DOI:10.3389/fninf.2017.00055