Abstract
Making predictions about future events relies on interpreting streams of information that may initially appear incomprehensible. This skill relies on extracting regular patterns in space and time by mere exposure to the environment (i.e., without explicit feedback). Yet, we know little about the functional brain networks that mediate this type of statistical learning. Here, we test whether changes in the processing and connectivity of functional brain networks due to training relate to our ability to learn temporal regularities. By combining behavioral training and functional brain connectivity analysis, we demonstrate that individuals adapt to the environment's statistics as they change over time from simple repetition to probabilistic combinations. Further, we show that individual learning of temporal structures relates to decision strategy. Our fMRI results demonstrate that learning-dependent changes in fMRI activation within and functional connectivity between brain networks relate to individual variability in strategy. In particular, extracting the exact sequence statistics (i.e., matching) relates to changes in brain networks known to be involved in memory and stimulus-response associations, while selecting the most probable outcomes in a given context (i.e., maximizing) relates to changes in frontal and striatal networks. Thus, our findings provide evidence that dissociable brain networks mediate individual ability in learning behaviorally-relevant statistics.
Highlights
Successful interactions in a new environment entail interpreting initially incomprehensible streams of information and making predictions about upcoming events
For learning context-based statistics, we found a significant positive correlation of fMRI activation change in the Left Central Executive Network (CP_21, peak activations in left inferior parietal and left middle frontal gyrus) with strategy (r 1⁄4 .63, confidence interval (CI) 1⁄4 [.29, .84]) (Fig. 5b), suggesting that higher activation after training in this region relates to maximization
For context-based statistics, we found that connectivity change between Right Central Executive and Basal Ganglia Networks correlated positively with strategy (r 1⁄4 .55, CI 1⁄4 [.01, .85]), suggesting that increased connectivity between these networks with training relates to maximization
Summary
Successful interactions in a new environment entail interpreting initially incomprehensible streams of information and making predictions about upcoming events. The brain is thought to succeed in this challenge by finding regular patterns and meaningful structures that help us to predict and prepare for future actions. This skill is thought to rely on our ability to extract spatial and temporal regularities, often with minimal explicit feedback (Aslin & Newport, 2012; Perruchet & Pacton, 2006). We know little about the functional brain networks and their interactions that mediate statistical learning of temporal structures
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