Abstract
Initial studies using resting-state functional magnetic resonance imaging on the trajectories of the brain network from childhood to adulthood found evidence of functional integration and segregation over time. The comprehension of how healthy individuals’ functional integration and segregation occur is crucial to enhance our understanding of possible deviations that may lead to brain disorders. Recent approaches have focused on the framework wherein the functional brain network is organized into spatially distributed modules that have been associated with specific cognitive functions. Here, we tested the hypothesis that the clustering structure of brain networks evolves during development. To address this hypothesis, we defined a measure of how well a brain region is clustered (network fitness index), and developed a method to evaluate its association with age. Then, we applied this method to a functional magnetic resonance imaging data set composed of 397 males under 31 years of age collected as part of the Autism Brain Imaging Data Exchange Consortium. As results, we identified two brain regions for which the clustering change over time, namely, the left middle temporal gyrus and the left putamen. Since the network fitness index is associated with both integration and segregation, our finding suggests that the identified brain region plays a role in the development of brain systems.
Highlights
The transition from childhood to adulthood involves major changes in cognitive and emotional functions
We: (i) first defined an index that measures how well one region of interest (ROI) is clustered in its respective sub-system; and (ii) we identified the ROIs in which this index is associated with age
To identify the ROIs associated with age in terms of functional clustering, we developed a framework based on the Network Fitness Index (NFI)
Summary
The transition from childhood to adulthood involves major changes in cognitive and emotional functions. These changes are driven by continuous dynamic interactions between genetic profiles and environmental factors, which impact the structural and functional brain networks [1,2,3]. Current evidence suggests that such neurodevelopmental changes are the result of synaptic pruning and myelination [4,5,6]. Investigating developmental effects on functional networks is fundamental to better understanding cognition maturation, the hierarchical structure of neural circuitries [2], and the association between neural substrates and many psychiatric and neurological disorders [7,8,9,10].
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