应激下人类情景记忆巩固的神经重放机制

doi:10.3724/SP.J.1042.2024.01031

摘要/Abstract

摘要：

记忆巩固通常在记忆编码后的休息或睡眠期间缓慢发生。然而, 在应激状态下, 记忆有可能被快速巩固。鉴于长期以来缺乏对人类记忆巩固期神经活动的量化方法, 应激状态下记忆快速巩固的机制尚未明确。本研究拟采用计算神经科学手段, 详细刻画应激状态下人类情景记忆巩固期的神经重放过程。此外, 我们还将整合认知心理学、脑成像技术、机器学习、神经内分泌调控、应激诱发及生理生化检测等跨学科方法, 来验证应激对神经重放的“双刃剑”效应假说: 尽管应激可能会加快神经重放的速度, 促进记忆巩固, 但它同时也可能会降低神经重放的准确性并干扰其顺序。本研究将: (1)比较应激和非应激状态下神经重放的多维特征差异; (2)探寻应激状态下神经重放与记忆提取和编码的交互作用; (3)尝试利用神经内分泌和环境策略来调控人类的应激反应, 进而影响神经重放。本研究能够有助于确定促进记忆巩固的理想大脑状态, 并整合人类和动物的神经重放研究。同时, 本研究还可能为保护应激状态下的情景记忆功能, 以及干预应激类精神疾病中的记忆障碍提供全新策略。

关键词: 记忆巩固, 记忆提取, 应激, 神经重放, 情景记忆

Abstract:

Memory consolidation typically unfolds gradually during rest or sleep following encoding. However, under stress, the consolidation process can significantly accelerate. This phenomenon has been supported by previous studies in both animals and humans, suggesting that stress can enhance memory consolidation. Yet, the mechanisms driving this accelerated consolidation under stress remain elusive, largely due to a historical lack of quantitative methods for probing neural activity during human memory consolidation phases. Contrary to the conventional perspective, our research posits that stress doesn't simply boost or hinder consolidation. Indeed, while stress increases the pace of neural replay, it also introduces memory distortions and diminishes sequential integrity. Our aim is to leverage computational neuroscience techniques to precisely delineate neural replay dynamics during episodic memory consolidation under stress. We advocate an integrated methodology that combines cognitive psychology, neuroimaging, machine learning, neuroendocrine studies, stress induction, and both physiological and neuroendocrine evaluations to investigate the nuanced impacts of stress on memory consolidation and neural replay, embodying the 'double-edged sword' hypothesis: despite stress potentially accelerating neural replay and facilitating consolidation, it may also impair replay accuracy and disrupt sequence.

Our experimental design is meticulously crafted to dissect the multifaceted influence of stress on memory consolidation. The development of a new neural replay index based on rapid EEG/MEG signals aims to assess replay speed, accuracy, and sequentiality in unprecedented detail. This index is a cornerstone of our methodology, enabling the quantification of neural replay's temporal dynamics, fidelity, and order. To complement this, we will apply diverse memory retrieval paradigms to evaluate the functional outcomes of consolidation under stress. These include a durability test, assessing participants' ability to maintain memory traces over extended periods; a specificity test, examining the recall of precise episodic details versus generalized or incorrect information; and a flexibility test, determining the capacity to apply remembered information to novel problem-solving scenarios.

Furthermore, our study will conduct in-depth brain-behavior correlation analyses to link the neural replay index with specific memory outcomes. We hypothesize that rapid neural replay correlates with enduring memories, while compromised replay precision and sequence relate to diminished memory specificity and adaptability. This nuanced exploration will allow us to juxtapose neural replay characteristics under stress versus non-stress conditions and examine the intricate relationship between neural replay and memory processes during stress.

To rigorously test whether retrieval practice before stress exposure can mitigate its negative effects on consolidation, we will implement a pre-stress retrieval practice session in a subset of participants. This approach will enable us to evaluate the protective effects of active recall against stress-induced memory distortion. Additionally, we aim to utilize neuroendocrine and environmental strategies to modulate stress responses, potentially influencing neural replay during consolidation. Specifically, we will explore the efficacy of cortisol blockers to mitigate stress effects and environmental interventions designed to enhance cognitive resilience against stress.

We anticipate that our findings will unveil stress-induced interactions among memory, emotion, and control networks, primarily involving the amygdala, hippocampus, and prefrontal cortex. Neuroendocrine interventions could directly reduce amygdala activity, enhancing prefrontal-hippocampal connectivity, whereas environmental strategies might bolster prefrontal control over the amygdala, thus promoting a neurobiological environment conducive to optimal memory consolidation.

The implications of our research are profound and far-reaching. By identifying conditions that enhance memory consolidation, we aim to bridge significant gaps between human and animal studies on neural replay. Moreover, our findings could illuminate new strategies for maintaining episodic memory function under stress and offer novel intervention approaches for memory deficits observed in stress-associated psychiatric disorders. Ultimately, this research could pave the way for groundbreaking treatments that harness the neuroplasticity of memory systems, offering hope to individuals suffering from memory impairments and contributing to the broader scientific understanding of memory under stress.

Key words: memory consolidation, memory retrieval, acute stress, neural replay, episodic memory

中图分类号:

B845

刘威, 陈瑞欣, 郭金朋. (2024). 应激下人类情景记忆巩固的神经重放机制. 心理科学进展 , 32(7), 1031-1047.

LIU Wei, CHEN Ruixin, GUO JinPeng. (2024). The neural replay mechanisms of episodic memory consolidation under stress in humans. Advances in Psychological Science, 32(7), 1031-1047.

图/表 6

表1 应激下的记忆巩固: 增强还是减弱?

研究	样本量		被试	任务	应激诱发	间隔¹	结果
研究	应激组	控制组	被试	任务	应激诱发	间隔¹	结果
Zinkin & Miller, 1967	40	34	大鼠	a single avoidance learning	electroconvulsive shock	24 h, 48 h, 72 h	增强
Diamond & Rose, 1994	/		大鼠	maze training paradigm	recording chamber	4 h	损害
Dornelles et al., 2007	/		大鼠	a novel object recognition	epinephrine	96 h	增强
Roozendaal et al., 2008	20	13	大鼠	object recognition training	intra-BLA infusions of norepinephrine	24 h	倒U
Campolongo et al., 2009	10-11	10-11	大鼠	inhibitory avoidance	The CB1 receptor agonist	48 h	增强
Bass et al., 2012	9		大鼠	a novel object recognition	direct activation of the BLA	1 d	增强
Barsegyan et al., 2014	39	13	大鼠	object-in-context recognition	intra-BLA infusions of norepinephrine	24 h	倒U
McReynolds et al., 2014	7	6	大鼠	inhibitory avoidance, object recognition	intra-BLA infusions of clenbuterol	48 h	增强
Morena et al., 2014	10-14	10-14	大鼠	inhibitory avoidance	fatty acid amide hydrolase inhibitor	48 h	增强
Siller-Pérez et al., 2019	20	11	大鼠	inhibitory avoidance	WIN55, 212-2 into the dorsal striatum	48 h	增强
Cahill et al., 2003	25	23	人类	slides of varying emotional content	cold pressor stress	1 wk	增强
van Marle et al., 2013	20	19	人类	negative and neutral pictures	administered hydrocortisone during sleep	1 d	增强
Borota et al., 2014	35	38	人类	studied images of objects	200 mg of caffeine	24 h	增强
McCullough et al., 2015	23	24	人类	emotional and neutral pictures	cold-pressor test	24 h	倒U
Krenz et al., 2021	52	52	人类	negative and neutral pictures	α2-adrenoceptor antagonist yohimbine	1 d, 28 d	增强

图1 应激下生理−大脑−认知响应的整合模型。生理层面上, 应激反应开始于交感−副交感系统快速响应, 系统响应导致去甲肾上腺素分泌, 带动心率和瞳孔的相关变化; 而丘脑−垂体−肾上腺系统随后响应, 皮质醇分泌, 反映在唾液和头发皮质醇的相关变化和睡眠改变。大脑层面上, 应激主要影响前额叶−海马−杏仁核环路活动: 应激会增强杏仁核活动, 同时减弱前额叶−海马环路的活动强度和信息交互。认知层面上, 应激会影响多个认知功能(如: 决策, 注意, 创造力), 本研究主要关注其对情景记忆的影响。以往研究发现应激会影响情景记忆的不同属性(如: 形成效率、持久性、灵活性、顺序性等), 本课题拟将神经重放的不同特征与情景记忆的各个方面关联起来。

图2 项目研究框架

图3 结合神经解码和计算模型刻画人类记忆巩固期的神经重放。(A)记忆编码后, 多个记忆信息会进入巩固阶段。此时, 海马和广泛的皮层区域会发生信息交互, 记忆信息会在大脑中以一定顺序(顺序或倒序)重新出现, 这种现象称之为神经重放(Neural Replay)。神经重放被认为是记忆巩固(Memory Consolidation)的关键神经过程。(B)为了在实验数据中捕捉到人类神经重放, 我们首先需要建立神经模式与外界刺激(通常是视觉, 如地点, 物品, 人脸)的关联, 即训练出机器学习算法可以解码记忆内容。然后, 通过把机器学习算法应用到记忆巩固期的自发神经活动, 可以获得在特点时间点, 各类外界刺激在大脑中表征的概率信息。最后, 通过进一步建立不同记忆出现时间点的顺序模型(Liu, Dolan et al., 2021; Liu, Nour et al., 2022), 从而对神经重放进行量化。

图4 应激下脑网络交互模式及其调控机制。(A)应激下的记忆功能主要涉及三大网络: 以海马为核心的记忆网络, 以杏仁核为核心的情绪网络, 和以前额叶为核心的控制网络。(B)神经内分泌策略调控应激响应的可能神经机制在于: 降低杏仁核的神经活动, 以恢复前额叶−海马环路正常的信息交互。(C)环境策略调控应激响应的可能神经机制的可能机制在于: 增强前额叶活动和前额叶对杏仁核的控制, 以恢复前额叶−海马环路的正常活动。

图5 应激对人类记忆巩固的“双刃剑”效应假说。通过采集记忆巩固时的高时间分辨率的脑电图或脑磁图信号, 项目将利用计算神经科学工具分别量化神经重放的速度, 准确性和顺序性。理论假设为: 应激并非只是简单地增强(或削弱)记忆巩固, 而是加速神经重放的速度, 但同时会扰乱其准确性和顺序性。为了探究应激状态下神经重放指标变化的行为后果, 项目将在记忆提取阶段, 采用不同范式对记忆的持久性、特异性和灵活性三方面进行测试。

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