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Predictive learning shapes the representational geometry of the human brain

Antonino Greco, Julia Moser, Hubert Preißl, Markus Siegel

2024Nature Communications21 citationsDOIOpen Access PDF

Abstract

Predictive coding theories propose that the brain constantly updates internal models to minimize prediction errors and optimize sensory processing. However, the neural mechanisms that link prediction error encoding and optimization of sensory representations remain unclear. Here, we provide evidence how predictive learning shapes the representational geometry of the human brain. We recorded magnetoencephalography (MEG) in humans listening to acoustic sequences with different levels of regularity. We found that the brain aligns its representational geometry to match the statistical structure of the sensory inputs, by clustering temporally contiguous and predictable stimuli. Crucially, the magnitude of this representational shift correlates with the synergistic encoding of prediction errors in a network of high-level and sensory areas. Our findings suggest that, in response to the statistical regularities of the environment, large-scale neural interactions engaged in predictive processing modulate the representational content of sensory areas to enhance sensory processing.

Topics & Concepts

Computer scienceArtificial intelligenceGeometryMathematicsNeural dynamics and brain functionVisual perception and processing mechanismsCognitive Science and Mapping