Abstract
Functional magnetic resonance imaging (fMRI) is one of the most useful methods to generate functional connectivity networks of the brain. However, conventional network generation methods ignore dynamic changes of functional connectivity between brain regions. Previous studies proposed constructing high-order functional connectivity networks that consider the time-varying characteristics of functional connectivity, and a clustering method was performed to decrease computational cost. However, random selection of the initial clustering centers and the number of clusters negatively affected classification accuracy, and the network lost neurological interpretability. Here we propose a novel method that introduces the minimum spanning tree method to high-order functional connectivity networks. As an unbiased method, the minimum spanning tree simplifies high-order network structure while preserving its core framework. The dynamic characteristics of time series are not lost with this approach, and the neurological interpretation of the network is guaranteed. Simultaneously, we propose a multi-parameter optimization framework that involves extracting discriminative features from the minimum spanning tree high-order functional connectivity networks. Compared with the conventional methods, our resting-state fMRI classification method based on minimum spanning tree high-order functional connectivity networks greatly improved the diagnostic accuracy for Alzheimer's disease.
Highlights
In recent years, complex brain network analyses from the whole-brain perspective have become increasingly used to study neuropsychiatric diseases (van Diessen et al, 2013)
The results showed that the rs-Functional magnetic resonance imaging (fMRI) classification method of Alzheimer’s disease (AD) based on the HONMST could accurately distinguish between control and AD subjects
Previous studies have suggested that the pattern of intrinsic interaction between different brain regions changes over time
Summary
Complex brain network analyses from the whole-brain perspective have become increasingly used to study neuropsychiatric diseases (van Diessen et al, 2013). In traditional functional connectivity network analysis, it is assumed that the correlation between different brain regions does not change with time during rs-fMRI scanning Because these seedbased correlation approaches represent the relationship between two regions of interest as a single correlation coefficient that is calculated from the time series of the entire scan; but, temporal variations in this value will not be captured (Salvador et al, 2005; Achard et al, 2006; Wang et al, 2010; Suk et al, 2013; Zhang et al, 2013). These methods ignore the changes of neural activity or interaction that may occur during the scan
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