Abstract
This study investigated how attending to auditory and visual information systematically changes graph theoretical measures of integration and functional connectivity between three network modules: auditory, visual, and a joint task core. Functional MRI BOLD activity was recorded while healthy volunteers attended to colour and/or pitch information presented within an audiovisual stimulus sequence. Network nodes and modules were based on peak voxels of BOLD contrasts, including colour and pitch sensitive brain regions as well as the dorsal attention network. Network edges represented correlations between nodes’ activity and were computed separately for each condition. Connection strength was increased between the task and the visual module when participants attended to colour, and between the task and the auditory module when they attended to pitch. Moreover, several nodal graph measures showed consistent changes to attentional modulation in form of stronger integration of sensory regions in response to attention. Together, these findings corroborate dynamical adjustments of both modality-specific and modality-independent functional brain networks in response to task demands and their representation in graph theoretical measures.
Highlights
Integration and segregation in global brain communication are necessary prerequisites for complex behavior [1,2,3]
Using network analysis and graph theoretical measures, the human brain has been shown to be organised in functionally specialised modules [4,5,6,7,8] and a small number of highly connected and topologically central brain regions, the connective core
We investigated changes in core-periphery interaction when participants attended to auditory vs. visual information
Summary
Integration and segregation in global brain communication are necessary prerequisites for complex behavior [1,2,3]. Using network analysis and graph theoretical measures, the human brain has been shown to be organised in functionally specialised modules [4,5,6,7,8] and a small number of highly connected and topologically central brain regions, the connective core Parallel computation and competition between brain regions–as coordinated by the connective core—result in the formation of dynamic coalitions of specific brain regions, which in turn determine behavior. Such coalitions are formed in a serial manner, corresponding to a sequential shift between states of integration and segregation [3, 13,14]
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