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在新符号-语音学习过程中,功能性脑激活与关联强度及预测误差相关。

Functional brain activations correlated with association strength and prediction error during novel symbol-speech sound learning.

作者信息

Fraga-González Gorka, Haller Patrick, Willinger David, Gehrig Vanessa, Frei Nada, Brem Silvia

机构信息

Neurolinguistics and Department of Psychology, University of Zurich, Zurich, Switzerland.

Department of Child and Adolescent Psychiatry and Psychotherapy, University Hospital of Psychiatry, University of Zurich, Zurich, Switzerland.

出版信息

Imaging Neurosci (Camb). 2025 Jan 13;3. doi: 10.1162/imag_a_00439. eCollection 2025.

DOI:10.1162/imag_a_00439
PMID:40800879
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12319737/
Abstract

Efficient learning of letters-speech sound associations results in the specialization of visual and audiovisual brain regions, which is crucial for the development of proficient reading skills. However, the brain dynamics underlying this learning process remain poorly understood, and the involvement of learning and performance monitoring networks remains underexplored. Here we applied two mutually dependent feedback learning tasks in which novel symbol-speech sound associations were learned by 39 healthy adults. We employed functional magnetic resonance (fMRI) along with a reinforcement learning drift diffusion model to characterize trial-by-trial learning in behavior and brain. The model-based analysis showed that posterior-occipital activations during stimulus processing were positively modulated by trial-wise learning, as indicated by the increase in association strength between audiovisual pairs. Prediction errors, describing the update mechanism to learn from feedback across trials, modulated activations in several mid-frontal, striatal, and cingulate regions. Both tasks yielded similar patterns of results, despite differences in their relative difficulty. This study elucidates the processes involved in audiovisual learning that contribute to rapid visual specialization within a single experimental session and delineates a set of coactivated regions involved in learning from feedback. Our paradigm provides a framework to advance our understanding of the neurobiology of learning and reading development.

摘要

高效学习字母与语音的关联会导致视觉和视听脑区的专门化,这对熟练阅读技能的发展至关重要。然而,这一学习过程背后的脑动力学仍知之甚少,学习和表现监测网络的参与情况也仍未得到充分探索。在此,我们应用了两项相互依赖的反馈学习任务,39名健康成年人通过这些任务学习新的符号与语音的关联。我们采用功能磁共振成像(fMRI)以及强化学习漂移扩散模型来刻画行为和大脑中逐次试验的学习情况。基于模型的分析表明,在刺激处理过程中枕叶后部的激活受到逐次试验学习的正向调节,视听对之间关联强度的增加表明了这一点。预测误差描述了跨试验从反馈中学习的更新机制,它调节了几个额中回、纹状体和扣带区域的激活。尽管两项任务的相对难度有所不同,但都产生了相似的结果模式。本研究阐明了视听学习中有助于在单个实验环节内实现快速视觉专门化的过程,并描绘了一组参与从反馈中学习的共同激活区域。我们的范式提供了一个框架,以推进我们对学习和阅读发展神经生物学的理解。

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