Skip to content

Infraslow Dynamic Patterns in Human Cortical Networks Track a Spectrum of External to Internal Attention.

Harrison Watters, Aleah Davis, Abia Fazili, Lauren Daley, T J Lagrow, Eric H Schumacher, Shella Keilholz

Human brain mapping February 15, 2025 DOI: 10.1002/hbm.70049 via PubMed

Summary

Cortical networks shift their dynamic functional connectivity along a spectrum that tracks the level of external to internal attention demanded by tasks. Networks often grouped into a single task-positive network show divergent responses along this axis, suggesting that defining a single task-positive network is misleading. Somatosensory and visual networks exhibit strong phase shifting along this attentional spectrum. Results were robust at both group and individual levels, supporting network dynamics as a potential individual biomarker. This work provides the first spectrum of dynamic network relationships across an axis of attention, using fMRI data from tasks including moving dots, visual working memory, congruence tasks, resting states, mindfulness meditation, and TV watching.

Study at a glance

Characteristics Observational study Peer reviewed
Keywords Anticorrelation Attention Cortical networks Default mode Sliding window correlation
Citations 1
Key finding Cortical networks show shifts in dynamic functional connectivity along a spectrum tracking the level of external to internal attention, with task-positive networks showing divergent responses and somatosensory and visual networks exhibiting strong phase shifting.

Abstract

Early efforts to understand the human cerebral cortex focused on localization of function, assigning functional roles to specific brain regions. More recent evidence depicts the cortex as a dynamic system, organized into flexible networks with patterns of spatiotemporal activity corresponding to attentional demands. In functional MRI (fMRI), dynamic analysis of such spatiotemporal patterns is highly promising for providing non-invasive biomarkers of neurodegenerative diseases and neural disorders. However, there is no established neurotypical spectrum to interpret the burgeoning literature of dynamic functional connectivity from fMRI across attentional states. In the present study, we apply dynamic analysis of network-scale spatiotemporal patterns in a range of fMRI datasets across numerous tasks including a left-right moving dot task, visual working memory tasks, congruence tasks, multiple resting state datasets, mindfulness meditators, and subjects watching TV. We find that cortical networks show shifts in dynamic functional connectivity across a spectrum that tracks the level of external to internal attention demanded by these tasks. Dynamics of networks often grouped into a single task positive network show divergent responses along this axis of attention, consistent with evidence that definitions of a single task positive network are misleading. Additionally, somatosensory and visual networks exhibit strong phase shifting along this spectrum of attention. Results were robust on a group and individual level, further establishing network dynamics as a potential individual biomarker. To our knowledge, this represents the first study of its kind to generate a spectrum of dynamic network relationships across such an axis of attention.

Comments

No comments yet.

Log in to comment