# Multiscale and multimodal network dynamics underpinning working memory

**Authors:** Andrew C. Murphy, Maxwell A. Bertolero, Lia Papadopoulos, David M., Lydon-Staley, Danielle S. Bassett

arXiv: 1901.06552 · 2020-09-09

## TL;DR

This study uncovers how multiscale neural dynamics involving frontoparietal and default mode systems, their subnetworks, and structural linkages influence working memory performance, integrating neuroimaging and computational modeling.

## Contribution

It reveals the distinct roles of frontoparietal subnetworks and their gene expression, structural connectivity, and dynamic interactions in working memory, advancing mechanistic understanding.

## Key findings

- Inverse correlation between FPS-DMS interaction strength and WM performance
- Identification of two FPS subnetworks with different gene expression patterns
- Computational model shows subnetwork activity modulates functional interactions

## Abstract

Working memory (WM) allows information to be stored and manipulated over short time scales. Performance on WM tasks is thought to be supported by the frontoparietal system (FPS), the default mode system (DMS), and interactions between them. Yet little is known about how these systems and their interactions relate to individual differences in WM performance. We address this gap in knowledge using functional MRI data acquired during the performance of a 2-back WM task, as well as diffusion tensor imaging data collected in the same individuals. We show that the strength of functional interactions between the FPS and DMS during task engagement is inversely correlated with WM performance, and that this strength is modulated by the activation of FPS regions but not DMS regions. Next, we use a clustering algorithm to identify two distinct subnetworks of the FPS, and find that these subnetworks display distinguishable patterns of gene expression. Activity in one subnetwork is positively associated with the strength of FPS-DMS functional interactions, while activity in the second subnetwork is negatively associated. Further, the pattern of structural linkages of these subnetworks explains their differential capacity to influence the strength of FPS-DMS functional interactions. To determine whether these observations could provide a mechanistic account of large-scale neural underpinnings of WM, we build a computational model of the system composed of coupled oscillators. Modulating the amplitude of the subnetworks in the model causes the expected change in the strength of FPS-DMS functional interactions, thereby offering support for a mechanism in which subnetwork activity tunes functional interactions. Broadly, our study presents a holistic account of how regional activity, functional interactions, and structural linkages together support individual differences in WM in humans.

## Full text

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## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/1901.06552/full.md

## References

83 references — full list in the complete paper: https://tomesphere.com/paper/1901.06552/full.md

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Source: https://tomesphere.com/paper/1901.06552