加工需求驱动下词汇阅读神经通路的动态协作机制

doi:10.3724/SP.J.1042.2024.00118

摘要/Abstract

摘要：

建构统一的认知和神经生理模型是词汇阅读认知神经科学研究面临的核心问题。阅读的认知理论模型一致认为阅读是语音和语义加工通路分工协作的结果, 认知神经科学研究也表明词汇阅读是背侧和腹侧神经通路动态协作的结果。为了系统地阐述阅读网络的这种动态协作机制, 结合神经功能和生理基础两个层面, 从以下三个方面对最新研究进展进行系统疏理：首先, 指出潜在的加工需求是背/腹侧神经通路动态协作的实质; 然后进一步阐明潜在加工需求驱动了不同正字法深度下背/腹侧神经通路的分工合作模式; 最后, 深入剖析了潜在加工如何通过语言经验塑造了神经通路间的动态协作。从而揭示出阅读神经通路动态协作的实质可能是特定任务下加工需求驱动的结果, 这种动态协作可能成为跨语言普遍的词汇阅读理论模型。

关键词: 词汇阅读, 模型, 通路, 动态协作

Abstract:

Constructing a unified cognitive and neurophysiological model is a central issue in cognitive neuroscience studies of visual word reading. Cognitive theoretical models of reading agree that reading results from the division of labor between phonological and semantic processing pathways, and cognitive neuroscience studies have also shown that the reading neural network results from the dynamic collaboration between dorsal and ventral neural pathways. In order to systematically elaborate this dynamic collaboration mechanism of the reading network, the latest research progress is systematically disentangled from the following three aspects by combining the two levels of neural function and physiological basis.

Firstly, it points out that the underlying processing demand is the essence of the dynamic collaboration between the dorsal and ventral neural pathways. Reading different types of words recruits an overlapped neural network, and their differences result from a dynamic interaction between phonological and semantic processing regions. This section reviewed studies that suggest that dynamic changes characterize the activation of reading-related brain regions. The activation of these brain regions is influenced by bottom-up stimulus properties and modulated by top-down task demands. Reading different types of words requires the division of labor between dorsal and ventral neural pathways, manifested in the difference in the pattern of interplay between phonological and semantic processing. The underlying cognitive processing may determine the activation of reading-related brain regions involved.

Secondly, it further elucidates how underlying processing demands drive the division of labor and collaborative patterns between the dorsal and ventral neural pathways under different levels of orthographic depth. Cross-linguistic differences, mainly influenced by corpus properties and corresponding processing strategies, show neural differences in collaboration patterns between functional reading brain regions. We elaborate on this issue regarding both cross-linguistic comparative and bilingual studies. Evidence from cross-linguistic comparative studies reveals that word reading at different orthographic depths relies on different functional brain region activations, brain region connectivity patterns, and neurophysiological basis. The resulting differences in brain mechanisms for cross-linguistic reading rely on varying degrees of dependence on dorsal and ventral neural pathways. Evidence from bilingual studies suggests that bilinguals selectively rely on either dorsal or ventral neural pathways and the dynamics of connectivity patterns between brain regions, depending on the properties of the corpus, when reading words with different orthographic depths in the two languages. In turn, the similarity of the two languages mastered by bilinguals affects the activation pattern of the reading neural network.

Lastly, it profoundly analyzes how latent processing shapes the dynamic collaboration between neural pathways through the shaping effect of language experience. The shaping effect of reading experience on related brain mechanisms is not only reflected in the influence on the activation sensitivity of brain regions corresponding to reading processing components but also affects the connectivity mechanisms among reading functional brain regions and further shapes the differences in collaboration mechanisms among different neural pathways. In particular, we review the studies to show how reading experience shapes the visual word form area, the form-sound processing area, and their connections with other reading functional brain areas. It also shows how reading experience shapes the dorsal/ventral neural pathway division of labor and cooperation mechanisms.

This review expounds upon the dynamic collaboration mechanism of reading neural pathways driven by processing demands from three distinct perspectives, which not only helps to clarify the internal processing mechanisms of the brain neural network during visual word reading but also provides new evidence for the construction of a universal cognitive and neurophysiological model across languages.

Key words: word reading, model, pathway, dynamics of collaboration

中图分类号:

B842

党敏, 蔡文琦, 陈发坤, 王小娟, 杨剑峰. (2024). 加工需求驱动下词汇阅读神经通路的动态协作机制. 心理科学进展 , 32(1), 118-130.

DANG Min, CAI Wenqi, CHEN Fakun, WANG Xiaojuan, YANG Jianfeng. (2024). Dynamic collaboration of reading neural pathways driven by the processing demands. Advances in Psychological Science, 32(1), 118-130.

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