Concurrent tACS-fMRI Reveals Causal Influence of Power Synchronized Neural Activity on Resting State fMRI Connectivity

Resting state fMRI (rs-fMRI) is commonly used to study the brain's intrinsic neural coupling, which reveals specific spatiotemporal patterns in the form of resting state networks (RSNs). It has been hypothesized that slow rs-fMRI oscillations (<0.1 Hz) are driven by underlying electrophysiological rhythms that typically occur at much faster timescales (>5 Hz); however, causal evidence for this relationship is currently lacking. Here we measured rs-fMRI in humans while applying transcranial alternating current stimulation (tACS) to entrain brain rhythms in left and right sensorimotor cortices. The two driving tACS signals were tailored to the individual's α rhythm (8–12 Hz) and fluctuated in amplitude according to a 1 Hz power envelope. We entrained the left versus right hemisphere in accordance to two different coupling modes where either α oscillations were synchronized between hemispheres (phase-synchronized tACS) or the slower oscillating power envelopes (power-synchronized tACS). Power-synchronized tACS significantly increased rs-fMRI connectivity within the stimulated RSN compared with phase-synchronized or no tACS. This effect outlasted the stimulation period and tended to be more effective in individuals who exhibited a naturally weak interhemispheric coupling. Using this novel approach, our data provide causal evidence that synchronized power fluctuations contribute to the formation of fMRI-based RSNs. Moreover, our findings demonstrate that the brain's intrinsic coupling at rest can be selectively modulated by choosing appropriate tACS signals, which could lead to new interventions for patients with altered rs-fMRI connectivity. SIGNIFICANCE STATEMENT Resting state fMRI (rs-fMRI) has become an important tool to estimate brain connectivity. However, relatively little is known about how slow hemodynamic oscillations measured with fMRI relate to electrophysiological processes. It was suggested that slowly fluctuating power envelopes of electrophysiological signals synchronize across brain areas and that the topography of this activity is spatially correlated to resting state networks derived from rs-fMRI. Here we take a novel approach to address this problem and establish a causal link between the power fluctuations of electrophysiological signals and rs-fMRI via a new neuromodulation paradigm, which exploits these power synchronization mechanisms. These novel mechanistic insights bridge different scientific domains and are of broad interest to researchers in the fields of Medical Imaging, Neuroscience, Physiology, and Psychology.

[1]  M. Grueschow,et al.  Brain Network Mechanisms Underlying Motor Enhancement by Transcranial Entrainment of Gamma Oscillations , 2016, The Journal of Neuroscience.

[2]  Christoph S. Herrmann,et al.  BOLD signal effects of transcranial alternating current stimulation (tACS) in the alpha range: A concurrent tACS–fMRI study , 2016, NeuroImage.

[3]  S. Swinnen,et al.  Sex differences in autism: a resting-state fMRI investigation of functional brain connectivity in males and females. , 2016, Social cognitive and affective neuroscience.

[4]  Joerg F. Hipp,et al.  Measuring the cortical correlation structure of spontaneous oscillatory activity with EEG and MEG , 2016, NeuroImage.

[5]  Hanbing Lu,et al.  Low- but Not High-Frequency LFP Correlates with Spontaneous BOLD Fluctuations in Rat Whisker Barrel Cortex. , 2014, Cerebral cortex.

[6]  Marina Schmid,et al.  An Introduction To The Event Related Potential Technique , 2016 .

[7]  Axel Thielscher,et al.  Field modeling for transcranial magnetic stimulation: A useful tool to understand the physiological effects of TMS? , 2015, 2015 37th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC).

[8]  Dante Mantini,et al.  Estimating a neutral reference for electroencephalographic recordings: the importance of using a high-density montage and a realistic head model , 2015, Journal of neural engineering.

[9]  M. Grueschow,et al.  The precision of value-based choices depends causally on fronto-parietal phase coupling , 2015, Nature Communications.

[10]  Joerg F. Hipp,et al.  BOLD fMRI Correlation Reflects Frequency-Specific Neuronal Correlation , 2015, Current Biology.

[11]  Gregor Thut,et al.  Alpha Power Increase After Transcranial Alternating Current Stimulation at Alpha Frequency (α-tACS) Reflects Plastic Changes Rather Than Entrainment , 2015, Brain Stimulation.

[12]  Niels Kuster,et al.  MIDA: A Multimodal Imaging-Based Detailed Anatomical Model of the Human Head and Neck , 2015, PloS one.

[13]  S. Swinnen,et al.  Virtual water maze learning in human increases functional connectivity between posterior hippocampus and dorsal caudate , 2015, Human brain mapping.

[14]  G. Rees,et al.  Individual Differences in Alpha Frequency Drive Crossmodal Illusory Perception , 2015, Current Biology.

[15]  S. Swinnen,et al.  Underconnectivity of the superior temporal sulcus predicts emotion recognition deficits in autism. , 2014, Social cognitive and affective neuroscience.

[16]  Steen Moeller,et al.  ICA-based artefact removal and accelerated fMRI acquisition for improved resting state network imaging , 2014, NeuroImage.

[17]  Stephen M. Smith,et al.  Permutation inference for the general linear model , 2014, NeuroImage.

[18]  Ludovica Griffanti,et al.  Automatic denoising of functional MRI data: Combining independent component analysis and hierarchical fusion of classifiers , 2014, NeuroImage.

[19]  Heidi Johansen-Berg,et al.  Local GABA concentration is related to network-level resting functional connectivity , 2014, eLife.

[20]  A. Engel,et al.  Entrainment of Brain Oscillations by Transcranial Alternating Current Stimulation , 2014, Current Biology.

[21]  Abhishek Datta,et al.  Imaging artifacts induced by electrical stimulation during conventional fMRI of the brain , 2014, NeuroImage.

[22]  Dieter Jaeger,et al.  Infraslow LFP correlates to resting-state fMRI BOLD signals , 2013, NeuroImage.

[23]  C. Herrmann,et al.  Transcranial alternating current stimulation: a review of the underlying mechanisms and modulation of cognitive processes , 2013, Front. Hum. Neurosci..

[24]  C. Herrmann,et al.  Orchestrating neuronal networks: sustained after-effects of transcranial alternating current stimulation depend upon brain states , 2013, Front. Hum. Neurosci..

[25]  Sabine Kastner,et al.  Electrophysiological Low-Frequency Coherence and Cross-Frequency Coupling Contribute to BOLD Connectivity , 2012, Neuron.

[26]  M. Nitsche,et al.  The Importance of Timing in Segregated Theta Phase-Coupling for Cognitive Performance , 2012, Current Biology.

[27]  M. Corbetta,et al.  Large-scale cortical correlation structure of spontaneous oscillatory activity , 2012, Nature Neuroscience.

[28]  Rolando J. Biscay-Lirio,et al.  Assessing interactions in the brain with exact low-resolution electromagnetic tomography , 2011, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[29]  Darren Price,et al.  Investigating the electrophysiological basis of resting state networks using magnetoencephalography , 2011, Proceedings of the National Academy of Sciences.

[30]  Ana L. N. Fred,et al.  Unveiling the Biometric Potential of Finger-Based ECG Signals , 2011, Comput. Intell. Neurosci..

[31]  F. Horak,et al.  Deep brain stimulation for Parkinson disease: an expert consensus and review of key issues. , 2011, Archives of neurology.

[32]  Robert Oostenveld,et al.  FieldTrip: Open Source Software for Advanced Analysis of MEG, EEG, and Invasive Electrophysiological Data , 2010, Comput. Intell. Neurosci..

[33]  C. Herrmann,et al.  Transcranial Alternating Current Stimulation Enhances Individual Alpha Activity in Human EEG , 2010, PloS one.

[34]  M. Schölvinck,et al.  Neural basis of global resting-state fMRI activity , 2010, Proceedings of the National Academy of Sciences.

[35]  Alex Fornito,et al.  What can spontaneous fluctuations of the blood oxygenation-level-dependent signal tell us about psychiatric disorders? , 2010, Current opinion in psychiatry.

[36]  Emmanuel Mandonnet,et al.  Direct electrical stimulation as an input gate into brain functional networks: principles, advantages and limitations , 2010, Acta Neurochirurgica.

[37]  Gilles Faÿ,et al.  Características inmunológicas claves en la fisiopatología de la sepsis. Infectio , 2009 .

[38]  N. Filippini,et al.  Group comparison of resting-state FMRI data using multi-subject ICA and dual regression , 2009, NeuroImage.

[39]  A. Villringer,et al.  Rolandic alpha and beta EEG rhythms' strengths are inversely related to fMRI‐BOLD signal in primary somatosensory and motor cortex , 2009, Human brain mapping.

[40]  O. Sporns,et al.  Complex brain networks: graph theoretical analysis of structural and functional systems , 2009, Nature Reviews Neuroscience.

[41]  P. Manganotti,et al.  EEG and fMRI Coregistration to Investigate the Cortical Oscillatory Activities During Finger Movement , 2008, Brain Topography.

[42]  Biyu J. He,et al.  Electrophysiological correlates of the brain's intrinsic large-scale functional architecture , 2008, Proceedings of the National Academy of Sciences.

[43]  I. Fried,et al.  Interhemispheric correlations of slow spontaneous neuronal fluctuations revealed in human sensory cortex , 2008, Nature Neuroscience.

[44]  M. Greicius Resting-state functional connectivity in neuropsychiatric disorders , 2008, Current opinion in neurology.

[45]  Clara A. Scholl,et al.  Synchronized delta oscillations correlate with the resting-state functional MRI signal , 2007, Proceedings of the National Academy of Sciences.

[46]  M. Fox,et al.  Spontaneous fluctuations in brain activity observed with functional magnetic resonance imaging , 2007, Nature Reviews Neuroscience.

[47]  M. Corbetta,et al.  Electrophysiological signatures of resting state networks in the human brain , 2007, Proceedings of the National Academy of Sciences.

[48]  S. Rombouts,et al.  Consistent resting-state networks across healthy subjects , 2006, Proceedings of the National Academy of Sciences.

[49]  Arnaud Delorme,et al.  EEGLAB: an open source toolbox for analysis of single-trial EEG dynamics including independent component analysis , 2004, Journal of Neuroscience Methods.

[50]  J. Haueisen,et al.  Influence of tissue resistivities on neuromagnetic fields and electric potentials studied with a finite element model of the head , 1997, IEEE Transactions on Biomedical Engineering.

[51]  B. Biswal,et al.  Functional connectivity in the motor cortex of resting human brain using echo‐planar mri , 1995, Magnetic resonance in medicine.