A Graph Theoretic Interpretation of Neural Complexity

TL;DR

This paper provides a graph-theoretic framework to analytically understand how neural complexity, a measure of information integration in neural systems, depends on network topology and motifs.

Contribution

It introduces an analytical approximation of neural complexity based on graph motifs and weight distribution moments, clarifying its relation to network topology.

Findings

Neural complexity depends explicitly on cyclic graph motifs.

An approximation relates neural complexity to weight distribution moments.

The approach clarifies the influence of network topology on neural complexity.

Abstract

One of the central challenges facing modern neuroscience is to explain the ability of the nervous system to coherently integrate information across distinct functional modules in the absence of a central executive. To this end Tononi et al. [Proc. Nat. Acad. Sci. USA 91, 5033 (1994)] proposed a measure of neural complexity that purports to capture this property based on mutual information between complementary subsets of a system. Neural complexity, so defined, is one of a family of information theoretic metrics developed to measure the balance between the segregation and integration of a system's dynamics. One key question arising for such measures involves understanding how they are influenced by network topology. Sporns et al. [Cereb. Cortex 10, 127 (2000)] employed numerical models in order to determine the dependence of neural complexity on the topological features of a network. However, a complete picture has yet to be established. While De Lucia et al. [Phys. Rev. E 71, 016114 (2005)] made the first attempts at an analytical account of this relationship, their work utilized a formulation of neural complexity that, we argue, did not reflect the intuitions of the original work. In this paper we start by describing weighted connection matrices formed by applying a random continuous weight distribution to binary adjacency matrices. This allows us to derive an approximation for neural complexity in terms of the moments of the weight distribution and elementary graph motifs. In particular we explicitly establish a dependency of neural complexity on cyclic graph motifs.