Abstract
Previous studies investigated the distinct roles played by different cognitive regions and suggested that the patterns of connectivity of these regions are associated with working memory (WM). However, the specific causal mechanism through which the neuronal circuits that involve these brain regions contribute to WM is still unclear. Here, in a large sample of healthy young adults, we first identified the core WM regions by linking WM accuracy to resting-state functional connectivity with the bilateral dorsolateral prefrontal cortex (dLPFC; a principal region in the central-executive network, CEN). Then a spectral dynamic causal modeling (spDCM) analysis was performed to quantify the effective connectivity between these regions. Finally, the effective connectivity was correlated with WM accuracy to characterize the relationship between these connections and WM performance. We found that the functional connections between the bilateral dLPFC and the dorsal anterior cingulate cortex (dACC) and between the right dLPFC and the left orbital fronto-insular cortex (FIC) were correlated with WM accuracy. Furthermore, the effective connectivity from the dACC to the bilateral dLPFC and from the right dLPFC to the left FIC could predict individual differences in WM. Because the dACC and FIC are core regions of the salience network (SN), we inferred that the inter- and causal-connectivity between core regions within the CEN and SN is functionally relevant for WM performance. In summary, the current study identified the dLPFC-related resting-state effective connectivity underlying WM and suggests that individual differences in cognitive ability could be characterized by resting-state effective connectivity.
Highlights
Working memory (WM) refers to the temporary maintenance and manipulation of information that is essential for higherorder cognitive processing, including comprehension, learning, and reasoning (Baddeley, 1992)
The resting-state functional connectivity (rsFC) between the left dorsolateral prefrontal cortex (dLPFC) and the bilateral dorsal anterior cingulate cortex (dACC) was positively correlated with WM performance (r = 0.263, p = 0.000); the rsFC between the right dLPFC and the bilateral dACC was positively correlated with WM performance (r = 0.222, p = 0.000), and the rsFC between the right dLPFC and the left fronto-insular cortex (FIC) was positively correlated with WM performance (r = 0.208, p = 0.001)
These results suggest that the stronger the rsFC between the bilateral dLPFC and the bilateral dACC and between the right dLPFC and the left FIC, the better a subject’s WM performance
Summary
Working memory (WM) refers to the temporary maintenance and manipulation of information that is essential for higherorder cognitive processing, including comprehension, learning, and reasoning (Baddeley, 1992). Regional activation studies reported that WM tasks consistently recruit the dorsolateral prefrontal cortex (dLPFC; linked to encoding and manipulating information), the dorsal anterior cingulate cortex (dACC; implicated in error detection and performance adjustment), and the ventrolateral prefrontal cortex (vLPFC) extending to the anterior insula (involved in retrieving, selecting information, and inhibitory control; Owen, 1997, 2000; Carter et al, 1999; D’Esposito et al, 2000; Ramautar et al, 2006; Aron et al, 2014) These task-based findings have elucidated some aspects of the functional anatomy of the WM. Some core regions (e.g., the dLPFC, insular areas, and anterior cingulate cortex) in the intrinsic
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