Cross‐scale functional connectivity patterns of the aging brain learned from the multi‐cohort iSTAGing study

Abstract

AbstractBackgroundBrain functional connectivity (FC) measures derived from resting‐state fMRI (rsfMRI) data have advanced our understanding of the brain organization. However, most existing studies investigate the brain functional networks (FNs) at a specific scale, ignoring potentially complementary FC information at different levels of spatial granularity as well as the cross‐scale information. Given that the brain is a multi‐scale, hierarchical system, FCs between FNs at different spatial scales may provide complementary information to those measured within‐scales for characterizing the aging brain.MethodWe computed multiscale FNs to capture their FC measures across multiple scales and investigated the associations between cross‐scale FCs and the brain aging based on rsfMRI data of a diverse cohort (n = 4186, aged 22 to 97 years) from seven sites of the iSTAGING study [1]. For each subject, we computed the FNs at seven scales, yielding seven sets of k (k = 17, 25, 50, 75, 100, 125 and 150) FNs, same as our previous study [2‐3]. We estimated FC measures between the 542 FNs using Pearson’s correlation, yielding the cross‐scale FC matrices that were harmonized across sites in the tangent space using ComBat‐GAM [4] with sex and age as covariates. The harmonized FC measures were used as features to build an age prediction model using Ridge regression as illustrated in Figure 1. The brain age prediction model was compared with that built on harmonized FC measures between FNs of the same scales, with the performance estimated with a nested five‐fold cross‐validation.ResultThe cross‐scale FC measures performed significantly better than the within‐scale FC measures for the brain age prediction, as summarized in Table 1. Figure 2 shows the most informative FC measures for the brain age prediction. Specifically, FC measures computed both cross‐ and within‐scales between the visual, somatomotor, and frontoparietal networks provided relatively more useful information for the brain age prediction than FC measures between other FNs.ConclusionOur study demonstrated that the cross‐scale FC measures provided complementary information to the within‐scale FC measures for predicting the brain age, facilitating enhanced understanding of aging related changes of the brain functional organization.