Abstract
The sliding-window-based dynamic functional connectivity network (D-FCN) has been becoming an increasingly useful tool for understanding the changes of brain connectivity patterns and the association of neurological diseases with these dynamic variations. However, conventional D-FCN is essentially low-order network, which only reflects the pairwise interaction pattern between brain regions and thus overlooking the high-order interactions among multiple brain regions. In addition, D-FCN is innate with temporal sensitivity issue, i.e., D-FCN is sensitive to the chronological order of its subnetworks. To deal with the above issues, we propose a novel high-order functional connectivity network framework based on the central moment feature of D-FCN. Specifically, we firstly adopt a central moment approach to extract multiple central moment feature matrices from D-FCN. Furthermore, we regard the matrices as the profiles to build multiple high-order functional connectivity networks which further capture the higher level and more complex interaction relationships among multiple brain regions. Finally, we use the voting strategy to combine the high-order networks with D-FCN for autism spectrum disorder diagnosis. Experimental results show that the combination of multiple functional connectivity networks achieves accuracy of 88.06%, and the best single network achieves accuracy of 79.5%.
Highlights
Autism Spectrum Disorder (ASD) is a childhood nervous system developmental disorder and persists into adulthood
W and s affect the infrastructure of low-order D-FCN (LoD-FCN), and affect the structure of central moment feature FC network (CM-FCN)
The proposed high-order Functional connectivity (FC) network framework is based on sliding-window-based LoD-FCN, the parameters of the sliding window (i.e., W, s) inevitably affect the results, and the results shown in Fig. 4 illustrate this point
Summary
Autism Spectrum Disorder (ASD) is a childhood nervous system developmental disorder and persists into adulthood. According to the latest report by the Centers for Disease Control and Prevention, about one in 59 American children is affected by some forms of ASD and four times more common among boys than among girls. It is of great significance to diagnose and intervene ASD as early as possible for the improvement of patients’ quality of life. Accurate brain imaging-based ASD diagnosis is still challenging since brain anatomical and functional changes in this stage are considerably subtle. Previous studies (Wang et al, 2020; Huang et al, 2018) have already indicated that resting-state functional magnetic resonance imaging (RS-fMRI) can serve as a promising imaging technique for ASD diagnosis
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