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Dynamical differential covariance recovers directional network structure in multiscale neural systems

Yusi Chen, Burke Q. Rosen, Terrence J. Sejnowski

2022Proceedings of the National Academy of Sciences24 citationsDOIOpen Access PDF

Abstract

Investigating neural interactions is essential to understanding the neural basis of behavior. Many statistical methods have been used for analyzing neural activity, but estimating the direction of network interactions correctly and efficiently remains a difficult problem. Here, we derive dynamical differential covariance (DDC), a method based on dynamical network models that detects directional interactions with low bias and high noise tolerance under nonstationarity conditions. Moreover, DDC scales well with the number of recording sites and the computation required is comparable to that needed for covariance. DDC was validated and compared favorably with other methods on networks with false positive motifs and multiscale neural simulations where the ground-truth connectivity was known. When applied to recordings of resting-state functional magnetic resonance imaging (rs-fMRI), DDC consistently detected regional interactions with strong structural connectivity in over 1,000 individual subjects obtained by diffusion MRI (dMRI). DDC is a promising family of methods for estimating connectivity that can be generalized to a wide range of dynamical models and recording techniques and to other applications where system identification is needed.

Topics & Concepts

CovarianceComputer scienceArtificial neural networkComputationArtificial intelligenceFunctional connectivityDiffusion MRIPattern recognition (psychology)AlgorithmMathematicsMagnetic resonance imagingNeuroscienceStatisticsBiologyRadiologyMedicineFunctional Brain Connectivity StudiesAdvanced Neuroimaging Techniques and ApplicationsNeural dynamics and brain function