Abstract
Brain connectivity analyses have conventionally relied on statistical relationship between one-dimensional summaries of activation in different brain areas. However, summarizing activation patterns within each area to a single dimension ignores the potential statistical dependencies between their multi-dimensional activity patterns. Representational Connectivity Analyses (RCA) is a method that quantifies the relationship between multi-dimensional patterns of activity without reducing the dimensionality of the data. We consider two variants of RCA. In model-free RCA, the goal is to quantify the shared information for two brain regions. In model-based RCA, one tests whether two regions have shared information about a specific aspect of the stimuli/task, as defined by a model. However, this is a new approach and the potential caveats of model-free and model-based RCA are still understudied. We first explain how model-based RCA detects connectivity through the lens of models, and then present three scenarios where model-based and model-free RCA give discrepant results. These conflicting results complicate the interpretation of functional connectivity. We highlight the challenges in three scenarios: complex intermediate models, common patterns across regions, and transformation of representational structure across brain regions. The article is accompanied by scripts (https://osf.io/3nxfa/) that reproduce the results. In each case, we suggest potential ways to mitigate the difficulties caused by inconsistent results. The results of this study shed light on some understudied aspects of RCA, and allow researchers to use the method more effectively.
Highlights
To study the neural underpinnings of cognitive processes, we need to characterize the response of individual brain regions but understand the functional connectivity between them
For simpler explanation and interpretation of the results one can think of region of interest (ROI) 1 as visual area 2 (V2) and regions of interest (ROIs) 2 as inferior temporal cortex (ITC)
The reason is that the representations that were transformed from the source to the destination ROI no longer matched the common model in the destination ROI
Summary
To study the neural underpinnings of cognitive processes, we need to characterize the response of individual brain regions but understand the functional connectivity between them. For heterogeneous ROIs, where multiple response modes co-exist, projecting multivariate response patterns on a line (one dimension) could lead to strong distortions This has led to a recent shift from univariate to multi-dimensional (multivariate) connectivity analyses (Coutanche and ThompsonSchill, 2013; Goddard et al, 2016; Anzellotti and Coutanche, 2018; Basti et al, 2019, 2020; Karimi-Rouzbahani et al, 2021a,c; Shahbazi et al, 2021). Model-based RCA allows one to target specific aspects of information, based on hypotheses about how a specific aspect of information is transferred, avoiding the influence from undesired confounders on connectivity (Clarke et al, 2018; Karimi-Rouzbahani et al, 2021a) Despite these advantages, under some circumstances representational connectivity analysis can miss true connectivity or erroneously detect non-existing (false) connectivity. We raise some cautions for using each method by showing simulated cases where one method fails to capture functional connectivity between two regions with shared information
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