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Transmission delays and frequency detuning can regulate information flow between brain regions

Aref Pariz, Ingo Fischer, Alireza Valizadeh, Cláudio R. Mirasso

2021PLoS Computational Biology106 citationsDOIOpen Access PDF

Abstract

Brain networks exhibit very variable and dynamical functional connectivity and flexible configurations of information exchange despite their overall fixed structure. Brain oscillations are hypothesized to underlie time-dependent functional connectivity by periodically changing the excitability of neural populations. In this paper, we investigate the role of the connection delay and the detuning between the natural frequencies of neural populations in the transmission of signals. Based on numerical simulations and analytical arguments, we show that the amount of information transfer between two oscillating neural populations could be determined by their connection delay and the mismatch in their oscillation frequencies. Our results highlight the role of the collective phase response curve of the oscillating neural populations for the efficacy of signal transmission and the quality of the information transfer in brain networks.

Topics & Concepts

Information transferOscillation (cell signaling)Transmission (telecommunications)Information transmissionInformation flowArtificial neural networkNeuroscienceSIGNAL (programming language)PhysicsComputer scienceTopology (electrical circuits)Nerve netBiological systemControl theory (sociology)BiologyArtificial intelligenceTelecommunicationsMathematicsComputer networkGeneticsProgramming languageLinguisticsControl (management)PhilosophyCombinatoricsNeural dynamics and brain functionNonlinear Dynamics and Pattern Formationstochastic dynamics and bifurcation
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