Graded functional organisation in the left inferior frontal gyrus: evidence from task-free and task-based functional connectivity.
Other Scholarly Work
Diveica, Veronica, Riedel, Michael C, Salo, Taylor et al. (2023). Graded functional organisation in the left inferior frontal gyrus: evidence from task-free and task-based functional connectivity.
. 10.1101/2023.02.02.526818
Diveica, Veronica, Riedel, Michael C, Salo, Taylor et al. (2023). Graded functional organisation in the left inferior frontal gyrus: evidence from task-free and task-based functional connectivity.
. 10.1101/2023.02.02.526818
The left inferior frontal gyrus (LIFG) has been ascribed key roles in numerous cognitive domains, including language, executive function and social cognition. However, its functional organisation, and how the specific areas implicated in these cognitive domains relate to each other, is unclear. Possibilities include that the LIFG underpins a domain-general function or, alternatively, that it is characterized by functional differentiation, which might occur in either a discrete or a graded pattern. The aim of the present study was to explore the topographical organisation of the LIFG using a bimodal data-driven approach. To this end, we extracted functional connectivity (FC) gradients from 1) the resting-state fMRI time-series of 150 participants (77 female), and 2) patterns of co-activation derived meta-analytically from task data across a diverse set of cognitive domains. We then sought to characterize the FC differences driving these gradients with seed-based resting-state FC and meta-analytic co-activation modelling analyses. Both analytic approaches converged on an FC profile that shifted in a graded fashion along two main organisational axes. An anterior-posterior gradient shifted from being preferentially associated with high-level control networks (anterior LIFG) to being more tightly coupled with perceptually-driven networks (posterior). A second dorsal-ventral axis was characterized by higher connectivity with domain-general control networks on one hand (dorsal LIFG), and with the semantic network, on the other (ventral). These results provide novel insights into a graded functional organisation of the LIFG underpinning both task-free and task-constrained mental states, and suggest that the LIFG is an interface between distinct large-scale functional networks.
