Inferring task-related networks using independent component analysis in magnetoencephalography

H Luckhoo,J.R Hale,M.W Woolrich,M.G Stokes,A.C Nobre,P.G Morris,M.J Brookes

doi:10.1016/j.neuroimage.2012.04.046

Abstract

A novel framework for analysing task-positive data in magnetoencephalography (MEG) is presented that can identify task-related networks. Techniques that combine beamforming, the Hilbert transform and temporal independent component analysis (ICA) have recently been applied to resting-state MEG data and have been shown to extract resting-state networks similar to those found in fMRI. Here we extend this approach in two ways. First, we systematically investigate optimisation of time-frequency windows for connectivity measurement. This is achieved by estimating the distribution of functional connectivity scores between nodes of known resting-state networks and contrasting it with a distribution of artefactual scores that are entirely due to spatial leakage caused by the inverse problem. We find that functional connectivity, both in the resting-state and during a cognitive task, is best estimated via correlations in the oscillatory envelope in the 8–20 Hz frequency range, temporally down-sampled with windows of 1–4 s. Second, we combine ICA with the general linear model (GLM) to incorporate knowledge of task structure into our connectivity analysis. The combination of ICA with the GLM helps overcome problems of these techniques when used independently: namely, the interpretation and separation of interesting independent components from those that represent noise in ICA and the correction for multiple comparisons when applying the GLM. We demonstrate the approach on a 2-back working memory task and show that this novel analysis framework is able to elucidate the functional networks involved in the task beyond that which is achieved using the GLM alone. We find evidence of localised task-related activity in the area of the hippocampus, which is difficult to detect reliably using standard methods. Task-positive ICA, coupled with the GLM, has the potential to be a powerful tool in the analysis of MEG data.

Highlights

Current theories of brain function postulate that a relatively small number of spatially distributed networks are involved in many cognitive functions
This was the case even when beamformer cross-talk was taken into account. This is in agreement with previous work, showing that electrophysiological signals correlate across nodes of previously well-characterised ‘haemodynamic’ networks, including the lateral frontoparietal networks, the default mode network, the motor network and bilateral hippocampi
The independent component analysis (ICA) identified significant theta band oscillatory amplitude changes in the task blocks relative to the rest blocks in the visual cortex and medial superior parietal lobule (SPL), again consistent with the z-statistical maps derived from a traditional general linear model (GLM) analysis

Summary

Introduction

Current theories of brain function postulate that a relatively small number of spatially distributed networks are involved in many cognitive functions These networks are recruited through spontaneous synchronisation of neural oscillations across different, spatially separate regions (Uhlhaas and Singer, 2010). This synchrony is not attributed to the physical connections between the regions alone but has an underlying functional component. Methods for quantifying this functional connectivity are critical to furthering the general understanding of how the brain carries out cognitive tasks One such method is independent component analysis (ICA). ICA is a widely used blind source separation technique that decomposes a mixture of signals into a set of statistically independent components

Methods

Results

Discussion

Conclusion