Learning Amidst Noise: The Complementary Roles of Neural Predictive Activity and Representational Changes

The ability to extract structured patterns from a noisy environment is fundamental to cognition, yet how the brain learns complex, non-adjacent regularities remains unclear. Using magnetoencephalography (MEG) during a visuomotor task, we tracked the neural dynamics as humans learned non-adjacent dependencies embedded in noise. We reveal that learning is supported by two temporally dissociable mechanisms. A rapid emergence of predictive activity, where neural patterns of expected stimuli appear before their onset, precedes measurable behavioral improvements. This is followed by a much slower representational change, characterized by an increased neural pattern similarity between linked, non-adjacent elements. Both processes are supported by a distributed consortium of sensorimotor, dorsal attention, salience, central executive, and cerebellar networks. These findings establish a temporal hierarchy for the neural mechanisms of learning, suggesting that fast predictions guide online behavior, which in turn facilitates the gradual consolidation of knowledge into stable neural representations.