清醒静息过程的记忆巩固: 来自脑电和功能磁共振的证据

doi:10.3724/SP.J.1042.2025.0729

摘要/Abstract

摘要： 清醒静息和睡眠都有利于记忆离线巩固。但两者在记忆巩固中的联系和区别, 特别是共有的认知神经机制我们仍知之甚少。本研究拟采用脑电、功能磁共振、时域干涉电刺激、计算神经科学建模等多项前沿技术, 从三个方面开展工作: 第一, 通过清醒和睡眠的联合神经影像实验, 对比记忆巩固在两种状态中的神经活动, 揭示记忆离线巩固的本质特征; 第二, 搭建基于神经重放的闭环刺激系统, 从因果关系出发探究记忆离线巩固的神经特征; 第三, 开展基于实时神经反馈的海马电刺激研究, 开发针对记忆巩固调控的方案。本研究的开展, 对阐明记忆离线巩固的神经机制具有重要的理论意义, 也为未来清醒状态下记忆巩固的调控提供了科学依据。

关键词: 记忆巩固, 陈述性记忆, 程序性记忆, 睡眠, 静息态

Abstract: Both wakeful rest and sleep are beneficial for offline memory consolidation. However, our understanding of the connections and differences in memory consolidation between these two states, particularly regarding the shared cognitive neural mechanisms, remains limited. This study will focus on “memory consolidation during wakefulness”, using declarative and procedural memory tasks to examine memory consolidation activities under natural conditions as well as during modulation by neural replay-based closed-loop Targeted Memory Reactivation (TMR) and closed-loop electrical stimulation. The aim is to investigate the roles of wakeful rest and sleep in memory consolidation and explore the underlying neural mechanisms involved.
To this end, the study will address the following key objectives: (1) Propose a unified theory of offline memory consolidation that spans both sleep and wake states, leveraging the identification of common characteristics between these states as a breakthrough to explore neural biomarkers of memory consolidation during wakeful rest. (2) Use neural replay activity as an entry point, this study will capture it to pinpoint the time window during which memory consolidation occurs and specifically identify the relevant neural features. (3) Building on sleep-state research to verify the effectiveness of the neural replay-based closed-loop TMR and provide guidance for its application during wakeful rest, while exploring the corresponding neural mechanisms. (4) Investigate the modulatory effects of direct hippocampal stimulation on memory consolidation and develop an electrical stimulation protocol for memory enhancement. (5) Conduct long-term follow-up studies to assess the effects of memory consolidation interventions over time, observing changes in memory performance across extended time scales, verifying the ecological validity of the interventions, and exploring the potential to apply laboratory findings to real-world learning contexts.
This study presents three major innovations. First, it enhances our understanding of the role of wakeful rest in facilitating memory consolidation. While sleep has been extensively studied in the context of offline memory consolidation, with its mechanisms well understood, research on memory consolidation during wakefulness remains insufficient and requires further in-depth exploration. Currently, most human studies focus on the behavioral level, with few examining the underlying neural mechanisms, which limits our understanding of offline memory consolidation during wakefulness. Therefore, this study specifically focuses on memory consolidation during wakefulness and conducts a series of experiments to broaden our understanding of offline consolidation. Second, it offers an accurate characterization of the macroscopic neural representation of offline memory consolidation during wakeful rest. Neural replay, a key mechanism in memory consolidation, is challenging to detect directly in healthy humans using non-invasive methods. However, with the aid of computational neuroscience techniques, we can capture neural replay activity using non-invasive neuroimaging techniques, such as electroencephalography (EEG) and functional magnetic resonance imaging (fMRI). By focusing on neural replay activity, this study offers a more precise depiction of the neural processes involved in offline memory consolidation during wakeful rest, in contrast to traditional approaches that rely on correlation analysis to infer neural representations. Third, it provides new approaches to memory regulation. This study leverages neural replay activity to explore closed-loop TMR and closed-loop electrical stimulation as novel memory regulation techniques. By providing new insights into memory modulation, this study offers valuable directions for future research on memory intervention.
In summary, this study aims to utilize advanced techniques such as EEG, fMRI, temporal interference (TI) electrical stimulation, and computational neuroscience techniques to capture the dynamic memory consolidation activities during both waking and sleep states, uncover the core characteristics of offline memory consolidation, and explore novel pathway for memory regulation based on real-time neural feedback. The implementation of this study will be instrumental in elucidating the neural mechanisms underlying memory consolidation across different brain states and laying the foundation for regulating memory consolidation during wakeful rest. Going forward, this study aims to apply its findings to educational interventions, such as learning strategy design, and initiate translational research to unlock the full potential of these interventions in real-world applications.

Key words: memory consolidation, declarative memory, procedural memory, sleep, resting-state

中图分类号:

B845

雷旭, 翁琳曼, 喻婧. (2025). 清醒静息过程的记忆巩固: 来自脑电和功能磁共振的证据. 心理科学进展 , 33(5), 729-743.

LEI Xu, WENG Linman, YU Jing. (2025). Memory consolidation during wakeful rest: Evidence from EEG and fMRI. Advances in Psychological Science, 33(5), 729-743.

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