Large-scale DCMs for resting-state fMRI.

Olaf Sporns,Mohamed L Seghier,Peter Mccolgan,Peter Zeidman,Geraint Rees,Adeel Razi,Hae-Jeong Park,Karl J Friston,Yuan Zhou

doi:10.1162/netn_a_00015

Abstract

This paper considers the identification of large directed graphs for resting-state brain networks based on biophysical models of distributed neuronal activity, that is, effective connectivity. This identification can be contrasted with functional connectivity methods based on symmetric correlations that are ubiquitous in resting-state functional MRI (fMRI). We use spectral dynamic causal modeling (DCM) to invert large graphs comprising dozens of nodes or regions. The ensuing graphs are directed and weighted, hence providing a neurobiologically plausible characterization of connectivity in terms of excitatory and inhibitory coupling. Furthermore, we show that the use of Bayesian model reduction to discover the most likely sparse graph (or model) from a parent (e.g., fully connected) graph eschews the arbitrary thresholding often applied to large symmetric (functional connectivity) graphs. Using empirical fMRI data, we show that spectral DCM furnishes connectivity estimates on large graphs that correlate strongly with the estimates provided by stochastic DCM. Furthermore, we increase the efficiency of model inversion using functional connectivity modes to place prior constraints on effective connectivity. In other words, we use a small number of modes to finesse the potentially redundant parameterization of large DCMs. We show that spectral DCM—with functional connectivity priors—is ideally suited for directed graph theoretic analyses of resting-state fMRI. We envision that directed graphs will prove useful in understanding the psychopathology and pathophysiology of neurodegenerative and neurodevelopmental disorders. We will demonstrate the utility of large directed graphs in clinical populations in subsequent reports, using the procedures described in this paper.

Highlights

Dynamic causal modeling is a Bayesian framework that allows one to make inferences about the causal interactions between the nodes of a coupled system; namely, effective connectivity (Razi & Friston, 2016)
We have described a framework for estimating effective connectivity from functional MRI (fMRI) data collected at rest
Our framework builds upon three recent developments: (a) a robust and fast inversion scheme called spectral dynamic causal modeling (DCM) (Friston, Kahan, Biswal, et al, 2014), (b) an informed data-driven procedure to reduce the effective number of parameters in large DCMs (Seghier & Friston, 2013), and (c) a principled network discovery procedure that produces sparse graphs using Bayesian model reduction (Friston et al, 2016)

Summary

Introduction

Dynamic causal modeling is a Bayesian framework that allows one to make inferences about the causal (directed) interactions between the nodes (e.g., brain regions) of a coupled system; namely, effective connectivity (Razi & Friston, 2016). Dynamic causal modeling: A Bayesian framework that is used to infer causal interaction between coupled or distributed neuronal systems. Effective connectivity: A measure of the directed (causal) influence of one neural system over another using a model of neuronal interactions. Functional connectivity: A (undirected) measure of the statistical dependencies between spatially remote neurophysiological events. Generative model: A model for randomly generating observable data values, typically given some hidden parameters. Bayesian model selection: Procedure to determine the most likely among a set of competing hypotheses (or models) about mechanisms that generated observed data

Methods

Results

Conclusion