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Abstract

Introduction:

Synchronized oscillatory brain activity is considered a basis for flexible neuronal network communication. However, the causal role of inter-regional oscillatory phase relations in modulating signaling efficacy in cortical networks has not been directly demonstrated in humans so far.

Aim:

The current study addresses the causal role of transcranial alternating current stimulation (tACS)-induced oscillatory cross-network phase relations in modulating signaling efficacy across human cortical networks.

Methods:

To this end, concurrent tACS, transcranial magnetic stimulation (TMS), and electroencephalography (EEG) were employed to measure the modulation of excitability and signaling efficacy across cortical networks during externally induced neural oscillations. Theta oscillatory activity was introduced through tACS in two nodes of the human frontoparietal network: the dorsolateral prefrontal cortex (DLPFC) and the posterior parietal cortex (PPC). Six Hertz tACS was applied to the DLPFC and PPC simultaneously in an in-phase or antiphase manner. In addition, single-pulse TMS was administered over the DLPFC at four different phases of tACS and the propagation of TMS-evoked neuronal activity was measured with EEG.

Results:

We show that tACS-induced theta oscillations modulate TMS-evoked potentials (TEPs) in a phase-dependent manner, and that the induced oscillatory phase relation across the frontoparietal network affects the propagation of phase-dependent TEPs within as well as beyond the frontoparietal network.

Conclusion:

We show that the effect of tACS-induced phase relation across the frontoparietal network on signal transmission extends beyond the frontoparietal network. The results support a causal role of inter-nodal oscillatory phase synchrony in routing cortico-cortical information flow.

Impact statement

Theoretical models have proposed that phase relations of cross-network neural oscillations control communication efficacy across human cortical networks. The current study introduced concurrent transcranial alternating current stimulation-transcranial magnetic stimulation-electroencephalography (tACS-TMS-EEG) to experimentally study the theoretical framework. Dual-site in-phase or antiphase 6 Hz tACS was applied to the frontoparietal network. Synchronized tACS was shown to affect signaling within as well as beyond the targeted network. The study demonstrates how inter-regional oscillatory coherence supports the control of brain network signaling.

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References

Alagapan

, Schmidt

, Lefebvre

, et al. 2016. Modulation of cortical oscillations by low-frequency direct cortical stimulation is state-dependent. PLoS Biol, 14:e1002424.

Alekseichuk

, Pabel

, Antal

, et al. 2017. Intrahemispheric theta rhythm desynchronization impairs working memory. Restor Neurol Neurosci, 35:147–158.

Bächinger

, Zerbi

, Moisa

, et al. 2017. Concurrent tACS-fMRI reveals causal influence of power synchronized neural activity on resting state fMRI connectivity. J Neurosci, 37:4766–4777.

Barbas

, Pandya

. 1984. Topography of commissural fibers of the prefrontal cortex in the rhesus monkey. Exp Brain Res, 55:187–191.

Buzsáki

, Anastassiou

, Koch

. 2012. The origin of extracellular fields and currents—EEG, ECoG, LFP and spikes. Nat Rev Neurosci, 13:407–420.

Buzsáki

, Chrobak

. 1995. Temporal structure in spatially organized neuronal ensembles: a role for interneuronal networks. Curr Opin Neurobiol, 5:504–510.

Buzsáki

, Draguhn

. 2004. Neuronal oscillations in cortical networks. Science, 304:1926–1929.

Cohen

. 2014. A neural microcircuit for cognitive conflict detection and signaling. Trends Neurosci, 37:480–490.

Delorme

, Makeig

. 2004. EEGLAB: an open source toolbox for analysis of single-trial EEG dynamics including independent component analysis. J Neurosci Methods, 134:9–21.

10.

Engel

, Fries

, Singer

. 2001. Dynamic predictions: oscillations and synchrony in top-down processing. Nat Rev Neurosci, 2:704–716.

11.

Fehér

, Morishima

. 2016. Concurrent electroencephalography recording during transcranial alternating current stimulation (tACS). J Vis Exp, 107:e53527.

12.

Fehér

, Nakataki

, Morishima

. 2017. Phase-dependent modulation of signal transmission in cortical networks through tACS-induced neural oscillations. Front Hum Neurosci, 11:471.

13.

Feurra

, Pasqualetti

, Bianco

, et al. 2013. State-dependent effects of transcranial oscillatory currents on the motor system: what you think matters. J Neurosci, 33:17483–17489.

14.

Fries

. 2005. A mechanism for cognitive dynamics: neuronal communication through neuronal coherence. Trends Cogn Sci, 9:474–480.

15.

Fries

. 2015. Rhythms for cognition: communication through coherence. Neuron, 88:220–235.

16.

Fuscà

, Ruhnau

, Neuling

, et al. 2018. Local network-level integration mediates effects of transcranial alternating current stimulation. Brain Connect, 8:212–219.

17.

Guerra

, Pogosyan

, Nowak

, et al. 2016. Phase dependency of the human primary motor cortex and cholinergic inhibition cancelation during beta tACS. Cereb Cortex, 26:3977–3990.

18.

Helfrich

, Knepper

, Nolte

, et al. 2014a. Selective modulation of interhemispheric functional connectivity by HD-tACS shapes perception. PLoS Biol, 12:e1002031.

19.

Helfrich

, Schneider

, Rach

, et al. 2014b. Entrainment of brain oscillations by transcranial alternating current stimulation. Curr Biol, 24:333–339.

20.

Herrmann

, Strüber

, Helfrich

, et al. 2015. EEG oscillations: from correlation to causality. Int J Psychophysiol, 103:12–21.

21.

Hofer

, Merboldt

K-D

, Tammer

, et al. 2008. Rhesus monkey and human share a similar topography of the corpus callosum as revealed by diffusion tensor MRI in vivo. Cereb Cortex, 18:1079–1084.

22.

Horvath

, Carter

, Forte

. 2014. Transcranial direct current stimulation: five important issues we aren't discussing (but probably should be). Front Syst Neurosci, 8:2.

23.

Horvath

, Forte

, Carter

. 2015a. Evidence that transcranial direct current stimulation (tDCS) generates little-to-no reliable neurophysiologic effect beyond MEP amplitude modulation in healthy human subjects: a systematic review. Neuropsychologia, 66:213–236.

24.

Horvath

, Forte

, Carter

. 2015b. Quantitative review finds no evidence of cognitive effects in healthy populations from single-session transcranial direct current stimulation (tDCS). Brain Stimulat, 8:535–550.

25.

Hsu

T-Y

, Juan

C-H

, Tseng

. 2016. Individual differences and state-dependent responses in transcranial direct current stimulation. Front Hum Neurosci, 10:643.

26.

Jasper

. 1958. The ten twenty electrode system of the international federation. Electroencephalogr Clin Neurophysiol, 10:371–375.

27.

Kanai

, Chaieb

, Antal

, et al. 2008. Frequency-dependent electrical stimulation of the visual cortex. Curr Biol, 18:1839–1843.

28.

Kar

, Krekelberg

. 2014. Transcranial alternating current stimulation attenuates visual motion adaptation. J Neurosci, 34:7334–7340.

29.

Koessler

, Maillard

, Benhadid

, et al. 2009. Automated cortical projection of EEG sensors: anatomical correlation via the international 10–10 system. Neuroimage, 46:64–72.

30.

Lehmann

, Skrandies

. 1980. Reference-free identification of components of checkerboard-evoked multichannel potential fields. Electroencephalogr Clin Neurophysiol, 48:609–621.

31.

Lewis

, Van Essen

. 2000. Corticocortical connections of visual, sensorimotor, and multimodal processing areas in the parietal lobe of the macaque monkey. J Comp Neurol, 428:112–137.

32.

, Uehara

, Hanakawa

. 2015. The contribution of interindividual factors to variability of response in transcranial direct current stimulation studies. Front Cell Neurosci, 9:181.

33.

Mars

, Jbabdi

, Sallet

, et al. 2011. Diffusion-weighted imaging tractography-based parcellation of the human parietal cortex and comparison with human and macaque resting-state functional connectivity. J Neurosci, 31:4087–4100.

34.

Maunsell

, van Essen

. 1983. The connections of the middle temporal visual area (MT) and their relationship to a cortical hierarchy in the macaque monkey. J Neurosci, 3:2563–2586.

35.

Mizuhara

, Yamaguchi

. 2007. Human cortical circuits for central executive function emerge by theta phase synchronization. Neuroimage, 36:232–244.

36.

Nakazono

, Ogata

, Kuroda

, et al. 2016. Phase and frequency-dependent effects of transcranial alternating current stimulation on motor cortical excitability. PLoS One, 11:e0162521.

37.

Narayanan

, Cavanagh

, Frank

, et al. 2013. Common medial frontal mechanisms of adaptive control in humans and rodents. Nat Neurosci, 16:1888–1895.

38.

Neuling

, Rach

, Herrmann

. 2013. Orchestrating neuronal networks: sustained after-effects of transcranial alternating current stimulation depend upon brain states. Front Hum Neurosci, 7:161.

39.

O'Keefe

, Recce

. 1993. Phase relationship between hippocampal place units and the EEG theta rhythm. Hippocampus, 3:317–330.

40.

Oostenveld

, Fries

, Maris

, et al. 2011. FieldTrip: open source software for advanced analysis of MEG, EEG, and invasive electrophysiological data. Comput Intell Neurosci, 2011:156869.

41.

Pascual-Marqui

. 2002. Standardized low-resolution brain electromagnetic tomography (sLORETA): technical details. Methods Find Exp Clin Pharmacol, 24(Suppl D):5–12.

42.

Paulus

. 2011. Transcranial electrical stimulation (tES—tDCS; tRNS, tACS) methods. Neuropsychol Rehabil, 21:602–617.

43.

Polanía

, Moisa

, Opitz

, et al. 2015. The precision of value-based choices depends causally on fronto-parietal phase coupling. Nat Commun, 6:8090.

44.

Polanía

, Nitsche

, Korman

, et al. 2012. The importance of timing in segregated theta phase-coupling for cognitive performance. Curr Biol, 22:1314–1318.

45.

Raco

, Bauer

, Tharsan

, et al. 2016. Combining TMS and tACS for closed-loop phase-dependent modulation of corticospinal excitability: a feasibility study. Front Cell Neurosci, 10:143.

46.

Rossi

, Hallett

, Rossini

, et al. 2011. Screening questionnaire before TMS: an update. Clin Neurophysiol, 122:1686.

47.

Ruff

, Blankenburg

, Bjoertomt

, et al. 2006. Concurrent TMS-fMRI and psychophysics reveal frontal influences on human retinotopic visual cortex. Curr Biol, 16:1479–1488.

48.

Ruhnau

, Neuling

, Fuscá

, et al. 2016. Eyes wide shut: transcranial alternating current stimulation drives alpha rhythm in a state dependent manner. Sci Rep, 6:27138.

49.

Sassenhagen

, Draschkow

. 2019. Cluster-based permutation tests of MEG/EEG data do not establish significance of effect latency or location. Psychophysiology, 56:e13335.

50.

Saturnino

, Madsen

, Siebner

, et al. 2017. How to target inter-regional phase synchronization with dual-site transcranial alternating current stimulation. Neuroimage, 163:68–80.

51.

Sauseng

, Klimesch

, Schabus

, et al. 2005. Fronto-parietal EEG coherence in theta and upper alpha reflect central executive functions of working memory. Int J Psychophysiol, 57:97–103.

52.

Sellers

, Yu

, Zhou

, et al. 2016. Oscillatory dynamics in the frontoparietal attention network during sustained attention in the ferret. Cell Rep, 16:2864–2874.

53.

Strüber

, Rach

, Trautmann-Lengsfeld

, et al. 2014. Antiphasic 40Hz oscillatory current stimulation affects bistable motion perception. Brain Topogr, 27:158–171.

54.

Thut

, Schyns

, Gross

. 2011. Entrainment of perceptually relevant brain oscillations by non-invasive rhythmic stimulation of the human brain. Front Psychol, 2:170.

55.

Tong

. 2003. Cognitive neuroscience: primary visual cortex and visual awareness. Nat Rev Neurosci, 4:219–229.

56.

Tseng

, Iu

K-C

, Juan

C-H

. 2018. The critical role of phase difference in theta oscillation between bilateral parietal cortices for visuospatial working memory. Sci Rep, 8:349.

57.

Ungerleider

, Desimone

. 1986. Cortical connections of visual area MT in the macaque. J Comp Neurol, 248:190–222.

58.

Varela

, Lachaux

, Rodriguez

, et al. 2001. The brainweb: phase synchronization and large-scale integration. Nat Rev Neurosci, 2:229–239.

59.

Veniero

, Benwell

CSY

, Ahrens

, et al. 2017. Inconsistent effects of parietal α-tACS on pseudoneglect across two experiments: a failed internal replication. Front Psychol, 8:952.

60.

Violante

, Li

, Carmichael

, et al. 2017. Externally induced frontoparietal synchronization modulates network dynamics and enhances working memory performance. eLife, 6:e22001.

61.

Womelsdorf

, Everling

. 2015. Long-range attention networks: circuit motifs underlying endogenously controlled stimulus selection. Trends Neurosci, 38:682–700.

62.

Womelsdorf

, Schoffelen

J-M

, Oostenveld

, et al. 2007. Modulation of neuronal interactions through neuronal synchronization. Science, 316:1609–1612.

63.

Zaehle

, Rach

, Herrmann

. 2010. Transcranial alternating current stimulation enhances individual alpha activity in human EEG. PLoS One, 5:e13766.

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Phase-Synchronized Transcranial Alternating Current Stimulation-Induced Neural Oscillations Modulate Cortico-Cortical Signaling Efficacy

Abstract

Introduction:

Aim:

Methods:

Results:

Conclusion:

Impact statement

Get full access to this article

References

Supplementary Material