Dynamics of functional connectivity in multilayer cortical brain network during sensory information processing

Topology of a functional brain multilayer network is dynamically adjusted to provide optimal performance during accomplishing cognitive tasks, including sensory information processing. Functional connectivity between brain regions is achieved in terms of correlation or synchronization inference in recorded signals of neuronal activity. The promising approach for studying cortical network structure implies considering functional interactions in different frequency bands on the different layers of multilayer network model. Links between these layers can be restored based on cross-frequency couplings. While the topology of functional connectivity within each layer can be effectively restored from registered neurophysiological signals, mechanisms underlying coupling between different layers remain poorly understood. Here we consider evolution of the cortical network topology in alpha and beta frequency bands during visual stimuli processing. For each frequency band the functional connectivity between different brain regions is estimated by comparing Fourier spectra of EEG signals. The obtained functional topologies are considered as the layers of two-layer network. In the framework of a multilayer model we analyze evolution of functional network topology on both layers and reveal features of intralayer interaction underlying visual information processing in the brain.

[1]  Fernando Maestú,et al.  Artificial neural network detects human uncertainty. , 2018, Chaos.

[2]  Vladimir A. Maksimenko,et al.  Increasing Human Performance by Sharing Cognitive Load Using Brain-to-Brain Interface , 2018, Front. Neurosci..

[3]  Vladimir A. Maksimenko,et al.  Betweenness centrality in multiplex brain network during mental task evaluation , 2018, Physical Review E.

[4]  Stefano Boccaletti,et al.  Macroscopic and microscopic spectral properties of brain networks during local and global synchronization. , 2017, Physical review. E.

[5]  Fabrice Bartolomei,et al.  Interictal stereotactic-EEG functional connectivity in refractory focal epilepsies , 2018, Brain : a journal of neurology.

[6]  Kai Hwang,et al.  Frontoparietal Activity Interacts With Task-Evoked Changes in Functional Connectivity , 2019, Cerebral cortex.

[7]  John J. Foxe,et al.  The Role of Alpha-Band Brain Oscillations as a Sensory Suppression Mechanism during Selective Attention , 2011, Front. Psychology.

[8]  A. Wróbel,et al.  EEG beta band activity is related to attention and attentional deficits in the visual performance of elderly subjects. , 2013, International journal of psychophysiology : official journal of the International Organization of Psychophysiology.

[9]  Matthias Wacker,et al.  Matching Pursuit-Based Time-Variant Bispectral Analysis and its Application to Biomedical Signals , 2015, IEEE Transactions on Biomedical Engineering.

[10]  Vladimir Nedayvozov,et al.  Visual perception affected by motivation and alertness controlled by a noninvasive brain-computer interface , 2017, PloS one.

[11]  P. Fries Rhythms for Cognition: Communication through Coherence , 2015, Neuron.

[12]  M. Wibral,et al.  Untangling cross-frequency coupling in neuroscience , 2014, Current Opinion in Neurobiology.

[13]  Alexander Pisarchik,et al.  Multiscale neural connectivity during human sensory processing in the brain. , 2018, Physical review. E.

[14]  Manuel Schabus,et al.  A shift of visual spatial attention is selectively associated with human EEG alpha activity , 2005, The European journal of neuroscience.

[15]  Vladimir A. Maksimenko,et al.  Nonlinear effect of biological feedback on brain attentional state , 2018, Nonlinear Dynamics.

[16]  Pejman Sehatpour,et al.  A human intracranial study of long-range oscillatory coherence across a frontal–occipital–hippocampal brain network during visual object processing , 2008, Proceedings of the National Academy of Sciences.

[17]  J. Martinerie,et al.  Comparison of Hilbert transform and wavelet methods for the analysis of neuronal synchrony , 2001, Journal of Neuroscience Methods.

[18]  Mason A. Porter,et al.  Frequency-based brain networks: From a multiplex framework to a full multilayer description , 2017, Network Neuroscience.

[19]  Jonathan D. Cohen,et al.  Toward a Rational and Mechanistic Account of Mental Effort. , 2017, Annual review of neuroscience.

[20]  Michael Bach,et al.  Necker cube: stimulus-related (low-level) and percept-related (high-level) EEG signatures early in occipital cortex. , 2011, Journal of vision.

[21]  M. Berger,et al.  High Gamma Power Is Phase-Locked to Theta Oscillations in Human Neocortex , 2006, Science.

[22]  R. Desimone,et al.  Laminar differences in gamma and alpha coherence in the ventral stream , 2011, Proceedings of the National Academy of Sciences.

[23]  Gordon Pipa,et al.  Transfer entropy—a model-free measure of effective connectivity for the neurosciences , 2010, Journal of Computational Neuroscience.

[24]  Alex Arenas,et al.  Mapping Multiplex Hubs in Human Functional Brain Networks , 2016, Front. Neurosci..

[25]  H. Kennedy,et al.  Alpha-Beta and Gamma Rhythms Subserve Feedback and Feedforward Influences among Human Visual Cortical Areas , 2016, Neuron.

[26]  Oluwasanmi Koyejo,et al.  Human cognition involves the dynamic integration of neural activity and neuromodulatory systems , 2019, Nature Neuroscience.

[27]  J. Lisman,et al.  The Theta-Gamma Neural Code , 2013, Neuron.

[28]  Olaf Sporns,et al.  Communication dynamics in complex brain networks , 2017, Nature Reviews Neuroscience.

[29]  J. Palva,et al.  Phase Synchrony among Neuronal Oscillations in the Human Cortex , 2005, The Journal of Neuroscience.

[30]  Roger H. S. Carpenter,et al.  Analysing the detail of saccadic reaction time distributions , 2012 .

[31]  Russell A. Poldrack,et al.  Principles of dynamic network reconfiguration across diverse brain states , 2017, NeuroImage.

[32]  Simone Kühn,et al.  Transition of the functional brain network related to increasing cognitive demands , 2017, Human brain mapping.

[33]  Helmut Laufs,et al.  Where the BOLD signal goes when alpha EEG leaves , 2006, NeuroImage.

[34]  Annika Lüttjohann,et al.  Absence Seizure Control by a Brain Computer Interface , 2017, Scientific Reports.