Abstract
The brain is an extraordinarily complex system that facilitates the optimal integration of information from different regions to execute its functions. With the recent advances in technology, researchers can now collect enormous amounts of data from the brain using neuroimaging at different scales and from numerous modalities. With that comes the need for sophisticated tools for analysis. The field of network neuroscience has been trying to tackle these challenges, and graph theory has been one of its essential branches through the investigation of brain networks. Recently, topological data analysis has gained more attention as an alternative framework by providing a set of metrics that go beyond pairwise connections and offer improved robustness against noise. In this hands-on tutorial, our goal is to provide the computational tools to explore neuroimaging data using these frameworks and to facilitate their accessibility, data visualisation, and comprehension for newcomers to the field. We will start by giving a concise (and by no means complete) overview of the field to introduce the two frameworks and then explain how to compute both well-established and newer metrics on resting-state functional magnetic resonance imaging. We use an open-source language (Python) and provide an accompanying publicly available Jupyter Notebook that uses the 1000 Functional Connectomes Project dataset. Moreover, we would like to highlight one part of our notebook dedicated to the realistic visualisation of high order interactions in brain networks. This pipeline provides three-dimensional (3-D) plots of pairwise and higher-order interactions projected in a brain atlas, a new feature tailor-made for network neuroscience.
Highlights
Neuroscience is still a young research field, with its emergence as a formal discipline happening only around 70 years ago (Cowan et al 2000)
Our work differs from previous literature (Hallquist and Hillary 2018; Otter et al 2017) since we describe the concepts central to graph theory and topological data analysis (TDA) and provide an easy-to-grasp step-by-step tutorial on how to compute these metrics using an accessible, open-source computer language
Moving on to the newer framework of TDA in neuroscience, fewer studies have been published using resting-state functional magnetic resonance imaging (MRI) (rsfMRI). This tutorial has explained some of the main metrics related to two network neuroscience branches—graph theory and TDA—providing short theoretical backgrounds and code examples accompanied by a publicly available Jupyter Notebook
Summary
Neuroscience is still a young research field, with its emergence as a formal discipline happening only around 70 years ago (Cowan et al 2000). Various imaging modalities are available to reconstruct the brain network (Hart et al 2016; Bullmore and Sporns 2009). The focus of this hands-on paper will be resting-state functional MRI (rsfMRI). RsfMRI indirectly measures brain activity while a subject is at rest (i.e., does not perform any task). This type of data provides information about spontaneous brain functional connectivity (Raichle 2011). Considering the focus on this type of data here, we recommend readers who are not familiar with this imaging method to read Lee et al (2013); van den Heuvel and Hulshoff Pol (2010); Smith et al (2013); Smitha et al (2017) for a comprehensive overview
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