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Oscillatory and Aperiodic Neural Activity Jointly Predict Language Learning

Zachariah R. Cross, Andrew W. Corcoran, Matthias Schlesewsky, Mark Kohler, Ina Bornkessel‐Schlesewsky

2022Journal of Cognitive Neuroscience53 citationsDOI

Abstract

Memory formation involves the synchronous firing of neurons in task-relevant networks, with recent models postulating that a decrease in low-frequency oscillatory activity underlies successful memory encoding and retrieval. However, to date, this relationship has been investigated primarily with face and image stimuli; considerably less is known about the oscillatory correlates of complex rule learning, as in language. Furthermore, recent work has shown that nonoscillatory (1/ƒ) activity is functionally relevant to cognition, yet its interaction with oscillatory activity during complex rule learning remains unknown. Using spectral decomposition and power-law exponent estimation of human EEG data (17 women, 18 men), we show for the first time that 1/ƒ and oscillatory activity jointly influence the learning of word order rules of a miniature artificial language system. Flexible word-order rules were associated with a steeper 1/ƒ slope, whereas fixed word-order rules were associated with a shallower slope. We also show that increased theta and alpha power predicts fixed relative to flexible word-order rule learning and behavioral performance. Together, these results suggest that 1/ƒ activity plays an important role in higher-order cognition, including language processing, and that grammar learning is modulated by different word-order permutations, which manifest in distinct oscillatory profiles.

Topics & Concepts

CognitionPsychologyAperiodic graphLearning ruleWord orderElectroencephalographyWord (group theory)Encoding (memory)Cognitive psychologyArtificial intelligenceNatural language processingArtificial neural networkComputer scienceNeuroscienceLinguisticsMathematicsPhilosophyCombinatoricsNeural dynamics and brain functionNeural Networks and ApplicationsEEG and Brain-Computer Interfaces