Abstract
Predicting chronological age from functional properties of the brain may be informative of children's neurodevelopmental trajectories. Specifically, neurodevelopmental or learning disorders may be associated with atypical maturation of brain networks. In this study, we examine the relationship between reading disorder (RD) and maturation of functional connectivity (FC) in the brain using a cross-sectional sample of N = 742 participants aged 6-21 years. A support vector regression model was trained to predict chronological age from FC data derived from a whole-brain model as well as multiple 'reduced' models, which were trained on FC data generated from a successively smaller number of regions in the brain's reading network. We hypothesized that the trained models would show systematic underestimation of brain network maturity for poor readers, particularly for the models trained with reading/language regions. Results showed that the most highly weighted regions/functional connections were derived from the default mode and frontoparietal control networks, in line with previous research. The trained whole-brain model implied that participants with RD have a larger brain-age gap (difference between real and predicted age) than controls with typical or advanced reading ability; however additional post-hoc testing only confirmed a tendency for relative overestimation of age in advanced readers in the older cohort. Overall, results suggest that while FC networks may be particularly susceptible to, or reflective of, variation/developmental deviation associated with reading ability, there is large individual variability in the examined population.