Clustering of Resting State Networks

Megan H Lee,Dongyang Zhang,Carl D Hacker,Eric C Leuthardt,Joshua S Shimony,Maurizio Corbetta,Abraham Z Snyder,Kewei Chen

doi:10.1371/journal.pone.0040370

Megan H Lee, Dongyang Zhang + Show 6 more

Open Access

https://doi.org/10.1371/journal.pone.0040370

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Journal: PLoS ONE	Publication Date: Jul 9, 2012
Citations: 223	License type: CC BY 4.0

Affiliation: Washington University in St. Louis

Abstract

BackgroundThe goal of the study was to demonstrate a hierarchical structure of resting state activity in the healthy brain using a data-driven clustering algorithm.Methodology/Principal FindingsThe fuzzy-c-means clustering algorithm was applied to resting state fMRI data in cortical and subcortical gray matter from two groups acquired separately, one of 17 healthy individuals and the second of 21 healthy individuals. Different numbers of clusters and different starting conditions were used. A cluster dispersion measure determined the optimal numbers of clusters. An inner product metric provided a measure of similarity between different clusters. The two cluster result found the task-negative and task-positive systems. The cluster dispersion measure was minimized with seven and eleven clusters. Each of the clusters in the seven and eleven cluster result was associated with either the task-negative or task-positive system. Applying the algorithm to find seven clusters recovered previously described resting state networks, including the default mode network, frontoparietal control network, ventral and dorsal attention networks, somatomotor, visual, and language networks. The language and ventral attention networks had significant subcortical involvement. This parcellation was consistently found in a large majority of algorithm runs under different conditions and was robust to different methods of initialization.Conclusions/SignificanceThe clustering of resting state activity using different optimal numbers of clusters identified resting state networks comparable to previously obtained results. This work reinforces the observation that resting state networks are hierarchically organized.

Highlights

The work of Biswal and colleagues [1] provided the first demonstration of synchrony between right and left sensorimotor areas
Optimal Numbers of Clusters To determine the optimal numbers of clusters, the clustering algorithm was run for 2–20 clusters
Hierarchical Organization of resting state networks (RSNs) We demonstrated a hierarchical organization of RSNs by identifying optimal numbers of clusters and relating the seven and eleven cluster result to the two cluster result

Summary

Introduction

The work of Biswal and colleagues [1] provided the first demonstration of synchrony between right and left sensorimotor areas. Various other RSNs, or regions of the brain disparate in space but synchronous in time, have been described [4,5,6] These include the visual network (VIS) [4,5], the ventral attention network (VAN) [7,8], and the frontoparietal control (FPC) network [9,10,11]. A large scale view of the organization of resting state activity was offered by Fox et al [14], who described two anticorrelated systems in the brain This finding was supported by a k-means clustering analysis by Golland et al [15], who demonstrated two large systems, one primarily involving the DMN, and the other centered on the somatomotor network (SMN). The goal of the study was to demonstrate a hierarchical structure of resting state activity in the healthy brain using a data-driven clustering algorithm

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