Abstract
Over the past two decades, resting-state functional connectivity (RSFC) methods have provided new insights into the network organization of the human brain. Studies of brain disorders such as Alzheimer’s disease or depression have adapted tools from graph theory to characterize differences between healthy and patient populations. Here, we conducted a review of clinical network neuroscience, summarizing methodological details from 106 RSFC studies. Although this approach is prevalent and promising, our review identified four challenges. First, the composition of networks varied remarkably in terms of region parcellation and edge definition, which are fundamental to graph analyses. Second, many studies equated the number of connections across graphs, but this is conceptually problematic in clinical populations and may induce spurious group differences. Third, few graph metrics were reported in common, precluding meta-analyses. Fourth, some studies tested hypotheses at one level of the graph without a clear neurobiological rationale or considering how findings at one level (e.g., global topology) are contextualized by another (e.g., modular structure). Based on these themes, we conducted network simulations to demonstrate the impact of specific methodological decisions on case-control comparisons. Finally, we offer suggestions for promoting convergence across clinical studies in order to facilitate progress in this important field.
Highlights
Efforts to characterize a “human connectome” have brought sweeping changes to functional neuroimaging research, with many investigators transitioning from indices of local brain activity to measures of interregional communication (Friston, 2011)
We review the current state of graph theory approaches to resting-state functional connectivity (RSFC) in the clinical neurosciences
There are important advantages of EEG/MEG in some respects (Papanicolaou et al, 2017), we focused on fMRI in part because the vast majority of clinical RSFC studies have used this modality
Summary
Efforts to characterize a “human connectome” have brought sweeping changes to functional neuroimaging research, with many investigators transitioning from indices of local brain activity to measures of interregional communication (Friston, 2011). The broad goal of this conceptual revolution is to understand the brain as a functional network whose coordination is responsible for complex behaviors (Biswal et al, 2010). The prevailing approach to studying functional connectomes involves quantifying coupling of the intrinsic brain activity among regions. Resting-state functional connectivity (RSFC) methods (Biswal, Yetkin, Haughton, & Hyde, 1995) focus on interregional correspondence in low-frequency oscillations of the BOLD signal (approximately 0.01–0.12 Hz). Work over the past two decades has demonstrated the value of RSFC approaches for mapping functional network organization, including the identification of separable brain. There are numerous methodological challenges, including concerns about the quality of RSFC data (Power et al, 2014) and the effect of data processing on substantive conclusions (Ciric et al, 2017; Hallquist, Hwang, & Luna, 2013; Shirer, Jiang, Price, Ng, & Greicius, 2015)
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