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Abstract

Cognitively demanding goal-directed tasks in the human brain are thought to involve the dynamic interplay of several large-scale neural networks, including the default-mode network (DMN), salience network (SN), and central-executive network (CEN). Resting-state functional magnetic resonance imaging (rsfMRI) studies have consistently shown that the CEN and SN negatively regulate activity in the DMN, and this switching is argued to be controlled by the right anterior insula (rAI) of the SN. However, what remains to be investigated is the pattern of directed network interactions during difficult perceptual decision-making tasks. We recorded fMRI data while participants categorized the left–right motion of moving dots. We defined regions of interest, extracted fMRI time series, and performed directed connectivity analysis using Granger causality techniques. Our analyses demonstrated that the slow oscillation (0.07–0.19 Hz) mediated the interactions within and between the DMN, SN, and CEN nodes both for easier and harder decision-making tasks. We found that the rAI, a key node of the SN, played a causal control over the DMN and CEN for easier decision-making tasks. The combined effort of the rAI and dorsal anterior cingulate cortex of the SN had the causal control over the DMN and CEN for a harder task. These findings provide important insights into how a sensory signal organizes among the DMN, SN, and CEN during sensory information-guided, goal-directed tasks.

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References

Adhikari

, Sathian

, Epstein

, Lamichhane

, Dhamala

. 2014. Oscillatory activity in neocortical networks during tactile discrimination near the limit of spatial acuity. Neuroimage, 91:300–310.

Allman

, Watson

, Tetreault

, Hakeem

. 2005. Intuition and autism: a possible role for Von Economo neurons. Trends Cogn Sci, 9:367–373.

Bajaj

, Adhikari

, Dhamala

. 2013. Higher frequency network activity flow predicts lower frequency node activity in intrinsic low-frequency BOLD fluctuations. PLoS One, 8:e64466.

Becerra

, Pendse

, Chang

, Bishop

, Borsook

. 2011. Robust reproducible resting state networks in the awake rodent brain. PLoS One, 6:e25701.

Blair

, Karniski

. 1993. An alternative method for significance testing of waveform difference potentials. Psychophysiology, 30:518–524.

Bonnelle

, Ham

, Leech

, Kinnunen

, Mehta

, Greenwood

, Sharp

. 2012. Salience network integrity predicts default mode network function after traumatic brain injury. Proc Natl Acad Sci U S A, 109:4690–4695.

Chand

, Dhamala

. 2014. Spectral factorization-based current source density analysis of ongoing neural oscillations. J Neurosci Methods, 224:58–65.

Chen

, Oathes

, Chang

, Bradley

, Zhou

, Williams

, Glover

, Deisseroth

, Etkin

. 2013. Causal interactions between fronto-parietal central executive and default-mode networks in humans. Proc Natl Acad Sci U S A, 110:19944–19949.

Critchley

, Wiens

, Rotshtein

, Ohman

, Dolan

. 2004. Neural systems supporting interoceptive awareness. Nat Neurosci, 7:189–195.

10.

Crottaz-Herbette

, Menon

. 2006. Where and when the anterior cingulate cortex modulates attentional response: combined fMRI and ERP evidence. J Cogn Neurosci, 18:766–780.

11.

Deco

, Jirsa

, McIntosh

. 2011. Emerging concepts for the dynamical organization of resting-state activity in the brain. Nat Rev Neurosci, 12:43–56.

12.

Dhamala

, Rangarajan

, Ding

. 2008a. Analyzing information flow in brain networks with nonparametric Granger causality. Neuroimage, 41:354–362.

13.

Dhamala

, Rangarajan

, Ding

. 2008b. Estimating Granger causality from fourier and wavelet transforms of time series data. Phys Rev Lett, 100:018701.

14.

Dosenbach

, Visscher

, Palmer

, Miezin

, Wenger

, Kang

, Burgund

, Grimes

, Schlaggar

, Petersen

. 2006. A core system for the implementation of task sets. Neuron, 50:799–812.

15.

Egner

. 2009. Prefrontal cortex and cognitive control: motivating functional hierarchies. Nat Neurosci, 12:821–822.

16.

Fox

, Snyder

, Vincent

, Corbetta

, Van Essen

, Raichle

. 2005. The human brain is intrinsically organized into dynamic, anticorrelated functional networks. Proc Natl Acad Sci U S A, 102:9673–9678.

17.

Fransson

. 2005. Spontaneous low-frequency BOLD signal fluctuations: an fMRI investigation of the resting-state default mode of brain function hypothesis. Hum Brain Mapp, 26:15–29.

18.

Goulden

, Khusnulina

, Davis

, Bracewell

, Bokde

, McNulty

, Mullins

. 2014. The salience network is responsible for switching between the default mode network and the central executive network: replication from DCM. NeuroImage, 99:180–190.

19.

Ham

, Leff

, de Boissezon

, Joffe

, Sharp

. 2013. Cognitive control and the salience network: an investigation of error processing and effective connectivity. J Neurosci, 33:7091–7098.

20.

Heekeren

, Marrett

, Ruff

, Bandettini

, Ungerleider

. 2006. Involvement of human left dorsolateral prefrontal cortex in perceptual decision making is independent of response modality. Proc Natl Acad Sci U S A, 103:10023–10028.

21.

Haufe , et al. 2013. A critical assessment of connectivity measures for EEG data: a simulation study. NeuroImage, 64:120–133.

22.

Kucyi

, Moayedi

, Weissman-Fogel

, Hodaie

, Davis

. 2012. Hemispheric asymmetry in white matter connectivity of the temporoparietal junction with the insula and prefrontal cortex. PLoS One, 7:e35589.

23.

Menon

, Uddin

. 2010. Saliency, switching, attention and control: a network model of insula function. Brain Struct Funct, 214:655–667.

24.

Power

, Cohen

, Nelson

, Wig

, Barnes

, Church

, Vogel

, Laumann

, Miezin

, Schlaggar

, Petersen

. 2011. Functional network organization of the human brain. Neuron, 72:665–678.

25.

Ridderinkhof

, Ullsperger

, Crone

, Nieuwenhuis

. 2004. The role of the medial frontal cortex in cognitive control. Science, 306:443–447.

26.

Seeley

, Menon

, Schatzberg

, Keller

, Glover

, Kenna

, Reiss

, Greicius

. 2007. Dissociable intrinsic connectivity networks for salience processing and executive control. J Neurosci, 27:2349–2356.

27.

Sridharan

, Levitin

, Menon

. 2008. A critical role for the right fronto-insular cortex in switching between central-executive and default-mode networks. Proc Natl Acad Sci U S A, 105:12569–12574.

28.

Uddin

. 2015. Salience processing and insular cortical function and dysfunction. Nat Rev Neurosci, 16:55–61.

29.

Uddin

, Menon

. 2009. The anterior insula in autism: under-connected and under-examined. Neurosci Biobehav Rev, 33:1198–1203.

30.

Uddin

, Supekar

, Amin

, Rykhlevskaia

, Nguyen

, Greicius

, Menon

. 2010. Dissociable connectivity within human angular gyrus and intraparietal sulcus: evidence from functional and structural connectivity. Cereb Cortex, 20:2636–2646.

31.

Ullsperger

, Harsay

, Wessel

, Ridderinkhof

. 2010. Conscious perception of errors and its relation to the anterior insula. Brain Struct Funct, 214:629–643.

32.

van den Heuvel

, Mandl

, Kahn

, Hulshoff Pol

. 2009. Functionally linked resting-state networks reflect the underlying structural connectivity architecture of the human brain. Hum Brain Mapp, 30:3127–3141.

33.

Vincent

, Kahn

, Snyder

, Raichle

, Buckner

. 2008. Evidence for a frontoparietal control system revealed by intrinsic functional connectivity. J Neurophysiol, 100:3328–3342.

34.

Vinck , et al. 2015. How to detect the Granger-causal flow direction in the presence of additive noise?. NeuroImage, 108:301–318.

35.

Watson

, Jones

, Allman

. 2006. Dendritic architecture of the von Economo neurons. Neuroscience, 141:1107–1112.

36.

Zuo

, Di Martino

, Kelly

, Shehzad

, Gee

, Klein

, Castellanos

, Biswal

, Milham

. 2010. The oscillating brain: complex and reliable. Neuroimage, 49:1432–1445.

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Interactions Among the Brain Default-Mode,Salience,and Central-Executive Networks During Perceptual Decision-Making of Moving Dots

Abstract

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