Modulation of large-scale brain networks by transcranial direct current stimulation evidenced by resting-state functional MRI

Background Brain areas interact mutually to perform particular complex brain functions such as memory or language. Furthermore, under resting-state conditions several spatial patterns have been identified that resemble functional systems involved in cognitive functions. Among these, the default-mode...

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Published in:Brain stimulation 2012-07, Vol.5 (3), p.252-263
Main Authors: Peña-Gómez, Cleofé, Sala-Lonch, Roser, Junqué, Carme, Clemente, Immaculada C, Vidal, Dídac, Bargalló, Núria, Falcón, Carles, Valls-Solé, Josep, Pascual-Leone, Álvaro, Bartrés-Faz, David
Format: Article
Language:English
Subjects:
Action Potentials - physiology
Adult
Brain - physiology
default mode network
Evidence-Based Medicine
Female
functional connectivity networks
Humans
Magnetic Resonance Imaging
Male
Nerve Net - physiology
Neurology
Rest - physiology
resting state fMRI
transcranial direct current stimulation
Transcranial Magnetic Stimulation - methods
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Summary:Background Brain areas interact mutually to perform particular complex brain functions such as memory or language. Furthermore, under resting-state conditions several spatial patterns have been identified that resemble functional systems involved in cognitive functions. Among these, the default-mode network (DMN), which is consistently deactivated during task periods and is related to a variety of cognitive functions, has attracted most attention. In addition, in resting-state conditions some brain areas engaged in focused attention (such as the anticorrelated network, AN) show a strong negative correlation with DMN; as task demand increases, AN activity rises, and DMN activity falls. Objective We combined transcranial direct current stimulation (tDCS) with functional magnetic resonance imaging (fMRI) to investigate these brain network dynamics. Methods Ten healthy young volunteers underwent four blocks of resting-state fMRI (10-minutes), each of them immediately after 20 minutes of sham or active tDCS (2 mA), on two different days. On the first day the anodal electrode was placed over the left dorsolateral prefrontal cortex (DLPFC) (part of the AN) with the cathode over the contralateral supraorbital area, and on the second day, the electrode arrangement was reversed (anode right-DLPFC, cathode left-supraorbital). Results After active stimulation, functional network connectivity revealed increased synchrony within the AN components and reduced synchrony in the DMN components. Conclusions Our study reveals a reconfiguration of intrinsic brain activity networks after active tDCS. These effects may help to explain earlier reports of improvements in cognitive functions after anodal-tDCS, where increasing cortical excitability may have facilitated reconfiguration of functional brain networks to address upcoming cognitive demands.
ISSN:1935-861X
1876-4754
DOI:10.1016/j.brs.2011.08.006