Abstract

Reconstruction of anatomical connectivity from measured dynamical activities of coupled neurons is one of the fundamental issues in the understanding of structure-function relationship of neuronal circuitry. Many approaches have been developed to address this issue based on either electrical or metabolic data observed in experiment. The Granger causality (GC) analysis remains one of the major approaches to explore the dynamical causal connectivity among individual neurons or neuronal populations. However, it is yet to be clarified how such causal connectivity, i.e., the GC connectivity, can be mapped to the underlying anatomical connectivity in neuronal networks. We perform the GC analysis on the conductance-based integrate-and-fire (IF) neuronal networks to obtain their causal connectivity. Through numerical experiments, we find that the underlying synaptic connectivity amongst individual neurons or subnetworks, can be successfully reconstructed by the GC connectivity constructed from voltage time series. Furthermore, this reconstruction is insensitive to dynamical regimes and can be achieved without perturbing systems and prior knowledge of neuronal model parameters. Surprisingly, the synaptic connectivity can even be reconstructed by merely knowing the raster of systems, i.e., spike timing of neurons. Using spike-triggered correlation techniques, we establish a direct mapping between the causal connectivity and the synaptic connectivity for the conductance-based IF neuronal networks, and show the GC is quadratically related to the coupling strength. The theoretical approach we develop here may provide a framework for examining the validity of the GC analysis in other settings.

Highlights

  • The relation between structure and function is one of the central research themes in biology

  • To examine whether the reconstruction is dependent on particular dynamical regimes, which are often described by a particular choice of network system parameters, we investigate the robustness of the reconstruction by scanning the magnitude f and the rate m in the Poisson drive of the I&F networks [See Eq (23) in Methods]

  • We have shown that the linear Granger causality (GC) framework with either continuous voltage or discrete spike train time series, can be successfully applied to the reconstruction of I&F-type neuronal networks

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Summary

Introduction

The relation between structure and function is one of the central research themes in biology. Based on experimentally measured data, many network analysis approaches have been developed in attempt to probe the underlying brain connectivity through various statistical approaches [10,11,12,13], such as Granger causality [14,15,16] and dynamic Bayesian inference [17,18]. Through these analyses, the obtained connectivity is often referred to as functional or effective connectivity [19]. To infer the underlying network structure from observation, it is desirable to explore the relationship between structural and functional connectivity [22,23,24,25]

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