持续性注意低频波动的机制与干预

doi:10.3724/SP.J.1042.2025.1091

摘要/Abstract

摘要：

持续性注意是个体在一段时间内将注意保持在某个客体或活动上的能力, 是顺利完成日常活动和工作、学习的关键。然而, 随着时间的推移, 注意水平会不断波动, 对正在进行的活动产生负面影响。持续性注意的正常发展及其在神经、精神类疾病患者中的异常波动发生在多个亚慢波频率。现有研究把持续性注意的波动简化为有限认知资源的权衡和分配, 难以涵盖其多种认知成分、多个波动频率的复杂特征。本研究旨在探究持续性注意低频波动的认知神经机制, 包括: (1)探究持续性注意核心认知成分波动的脑时空特征, 建构持续性注意的认知成分波动假说; (2)通过亚慢波经颅电刺激, 从频率(时间)和靶点(空间)两方面探索基于持续性注意成分低频波动特征的干预机制, 并验证提出的持续性注意的认知成分波动假说; (3)考察持续性注意和注意网络之间的交互作用, 探索持续性注意的成分波动假说的外延。本研究有助于深化对持续性注意认知结构和神经波动时空特征的理解, 并为持续性注意波动的精准干预提供重要参考。

关键词: 持续性注意, 脑时空特征, 低频脑活动, 亚慢波经颅电刺激, 注意网络

Abstract:

Sustained attention refers to the ability to maintain attention on particular stimuli or cognitive tasks over time. However, attention levels fluctuate over time, which can impede ongoing cognitive processes. Even an ephemeral lapse in attention can lead to numerous negative effects，such as dropped academic performance, work-related errors, and even safety hazards. The typical development of sustained attention, along with its abnormal fluctuations in patients with neurological and psychiatric disorders, occur across multiple infra-slow frequencies. Several theoretical models, including resource-depletion theory, mindlessness theory, and resource-control theory, have been proposed to explain the mechanism of fluctuations in sustained attention. However, current research within these models oversimplifies the fluctuations as a mere trade-off and allocation of limited cognitive resources, thereby impeding the analysis of the complex array of cognitive components and diverse characteristics of multiple frequency fluctuations in sustained attention.

This study aims to elucidate the cognitive and neural mechanisms underlying low-frequency fluctuations in sustained attention, by combining multi-modal techniques and noninvasive brain stimulation methods such as behavioral experiments, electroencephalogram (EEG), and functional magnetic resonance imaging (fMRI). The research comprises three specific studies.

In Study 1, we utilized the classic gradual-onset continuous performance task (GradCPT) to integrate behavioral, physiological, and neural fluctuation characteristics in order to distinguish between different cognitive components involved in sustained attention. Our hypotheses regarding cognitive component fluctuations were formulated based on an examination of the brain's spatiotemporal characteristics linked to different cognitive component fluctuations.

Based on the conclusions of Study 1, Study 2 delved into interventions based on low-frequency fluctuations of sustained attention components. This was achieved through the application of infra-slow wave transcranial electrical stimulation (TES) to corroborate the proposed hypotheses concerning frequency, timing, and targeted brain regions. The convergence of Study 1 and Study 2 may offer causal evidence supporting the notion that "different cognitive components exhibit distinct fluctuation characteristics. Together, these studies have collaboratively established and refined the proposed hypotheses.

Study 3 investigated the interaction between sustained attention and attentional networks by using the High Reliability-Composite Attention Test (HR-CAT) to explore differences in sustained attention fluctuations across alerting, orienting, executive control and baseline conditions. This research aimed to extend the proposed hypotheses and improve the ecological validity and practical significance of the study.

This study highlights several significant innovations. First of all, the study expanded the theory of attention and filled the gap in the current theory by elucidating how different components of sustained attention contribute to its slow fluctuating process. Through systematic separation of core components of sustained attention and analysis of their internal structure, we explored fluctuation characteristics driven by different cognitive components, leading to the development of the theory of sustained attentional fluctuations.

Secondly, this study shed insight into the theory of brain function by establishing connections between specific cognitive components and the spatiotemporal structure of brain function. It established a coherent pathway from neural oscillation to cognitive fluctuation to overall fluctuation in sustained attention, unveiling the cognitive neural mechanism behind sustained attention fluctuation. By exploiting behavioral, EEG, and fMRI techniques as well as infra-slow wave TES and global spatiotemporal topology analysis, this study explored the cognitive neural mechanisms of sustained attention fluctuations from the perspective of physiological-psychological-neural coupling. In terms of methods, the study advanced research on the spatiotemporal structure of brain regions and brain networks involved in cognitive function, and contributed to the refinement of current theories of brain function. In terms of content, the study focused on infra-slow brain activity instead of traditional neural rhythms, which promotes a better understanding of the “macro fluctuation” and “slow process” of psychological activity.

Lastly, the study enriches the field of non-invasive brain intervention by indentifying precise spatiotemporal targets for sustained attentional fluctuations. Infra-slow wave TES leverage these fluctuation characteristics to enhance sustained attention, while minimizing potential harm from fluctuations.

To sum up, this study advances our understanding of the cognitive and spatiotemporal aspects of sustained attention, offering insights that can inform precise interventions for managing fluctuations in sustained attention. It offers novel insights into sustained attention mechanisms and brain function theories, laying the theoretical groundwork for non-invasive brain intervention strategies and mitigating attention fluctuations in clinical applications.

Key words: sustained attention, brain-spatiotemporal characteristics, low-frequency brain activity, infra-slow wave transcranial electrical stimulation, attentional network

中图分类号:

B842

王一峰, 唐雨竹, 肖坤辰, 荆秀娟. (2025). 持续性注意低频波动的机制与干预. 心理科学进展 , 33(7), 1091-1103.

WANG Yifeng, TANG Yuzhu, XIAO Kunchen, JING Xiujuan. (2025). The mechanism and intervention of low-frequency fluctuations of sustained attention. Advances in Psychological Science, 33(7), 1091-1103.

图/表 5

图1 研究框架图(蓝色部分为本研究创新之处。彩图见电子版, 下同)

图2 基于认知频谱指纹假说的全局时空拓扑分析技术。(A) 脑功能的时空关系。越整合的认知功能消耗的能量越多, 对应的脑活动越具有低频、全局性质。(B) 根据认知的频谱指纹建立考察全局脑信号与局部信号之间同步性的全局相干拓扑图(Ao et al., 2023)。(C) 根据认知的频谱指纹建立考察全脑功能连接的全脑网络拓扑图。全局时空拓扑分析技术能够衡量特定认知功能对应的脑功能时空结构。频率(时间)和脑区(空间)特征共同构成特定认知成分波动的时空特征。

图3 无探针的gradCPT刺激呈现方式及流程。刺激包括10张城市图片, 图片大小和灰度保持一致。图片随机呈现, 但不允许相同的图片连续呈现。通过调整透明度, 图片逐渐从一张过渡到另一张：前一张图片的透明度从0%更改为100%的同时, 下一张图片的透明度从100%更改为0%。要求被试在城市场景最清晰时以右手食指快速按键。

图4 有探针的gradCPT刺激呈现方式及流程。城市图片出现的概率为80%, 山区图片(探针)出现的概率为20% (实验2a)。图片的呈现顺序随机, 但不允许相同类别的图片连续呈现。要求被试确信看到城市图片时以右手食指按键, 看到山区图片时不按键。对山区图片按键被认定为虚报, 对城市图片未做反应则认定为漏报。

图5 HR-CAT任务流程图。B: 基线组块, A: 警觉组块, O: 定向组块, E: 执行控制组块, RT: 反应时。每个试次均以中心注视点(黑色短线“-”)开始; 然后呈现线索(红色代表有警觉线索, 黑色代表没有); 间隔200 ms后呈现目标刺激, 含有定向的组块目标出现在屏幕上方或下方, 不含有定向的组块目标出现在屏幕中央, 含有执行控制的组块中央箭头的方向与其余箭头的方向不一致, 不含执行控制的组块中央箭头的方向与其余箭头的方向一致; 要求被试在保证正确的基础上尽快反应, 按键反应后或到1500 ms仍无反应则刺激消失; 并以中心注视点呈现400 ms (未按键反应时)或 (1900 ms-RT) ms结束, 以使每个试次长度为2500 ms。

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