唤醒定义探析及其认知神经生理基础

doi:10.3724/SP.J.1042.2022.02020

摘要/Abstract

摘要：

唤醒是衡量机体清醒程度和做出反应前准备程度的指标, 其水平可从睡眠到觉醒的连续体上变化, 具有独特的生理机制与神经回路。由于唤醒与情绪关联密切, 唤醒度这个概念常被认为等同于情绪强度, 但情绪强度实际上是唤醒和效价的和向量。受到Lazarus提出的“刺激”定义情绪思想的启发, 对唤醒的内含和心理机制进行了探析, 发现对不符合预期刺激出现的紧急准备是唤醒系统的主要功能, 预期性相关机制是唤醒的重要认知加工机制。其它因素(刺激属性、个体差异等)可能存在以下影响唤醒的原因：改变处理刺激时所需的资源量、影响预期机制。未来研究可从心理唤醒与生理唤醒的关系、唤醒的测量方法、唤醒度与情绪强度的关系、人类临床精神疾病的唤醒特征等角度推动唤醒的基础和应用研究。

关键词: 唤醒, 预期性, 认知机制, 睡眠, 觉醒, 情绪强度

Abstract:

Arousal is an activator for the body's resources, reflecting the strengthened preparation for external stimulus input. As it is introduced into the emotional dimension, arousal is regarded as one of the core characteristics of emotions, which is a measurement of body's wakefulness, and its level changes on the continuum from sleep to provocation. Arousal can be subjectively experienced by individuals, and has a unique physiological mechanism and neural circuit. Its concept contains both psychological arousal and physical arousal. However, as arousal is closely related to emotions, many investigators neglect the original meaning of arousal, taking arousal as a substitute for emotional intensity. The reason for this confusion may be that valence is regarded as the direction of emotions. In fact, valence is only a feature of emotions. It also has different intensities, which affect the emotional intensity. Therefore, arousal cannot be simply equaled with emotional intensity. Instead, emotional intensity should be the vector addition of arousal and valence.

In this paper, we analyze the concept of arousal and its relationship with emotions. Then, inspired by Lazarus' argument that stimuli define emotions, we hold that it may be possible to further understand the connotation and psychological mechanism of arousal from the perspective of anticipation. Specifically, a variety of emotions can be summed up to an objective material or stimulus. In other words, it is stimuli that define emotions; when stimuli appear more unexpectedly, it indicates that the level of previous preparedness is lower, so more resources are needed for the individual to mobilize, and the level of arousal rises in response. Anticipation and its related mechanisms (uncertainty, habitation, etc.) are the major cognitive mechanisms of arousal. As for other factors (stimulus attributes, individual differences, etc.), as the number of resources that the individual needs to process the stimulus changes, the one of the resources required to be mobilized after the stimulus appears(arousal level) changes accordingly. Besides, the degree of individual expectations can be affected. As a result, these factors also affect the level of arousal.

The neural mechanism of arousal mainly involves a “bottom-up” pathway that originates from the brainstem and projects to the thalamus, hypothalamus, and cerebral cortex. The arousal signals in the brainstem and the tail of the hypothalamus mainly come from the areas rich in monoamine neurons and cholinergic neurons. The GABAergic neurons in the preoptic area of ??the hypothalamus, the lateral hypothalamus, and the sub-substantia nigra reticular region play a role in inhibiting arousal. Some key cortical nodes in the default mode network and the salience network and their interconnections also participate in the processing of arousal levels. It is worth noting that the arousal system almost overlaps with the brain area that encodes unexpected signals. Based on this, the anticipatory mechanism is presumably the key factor that induces arousal changes.

This paper suggests that future researchers may further promote the basic and applied research for arousal from the following aspects: FMRI, eye movement, skin conductance and other technical methods may be used to explore the effect of physical arousal on psychological arousal, which is helpful to further clarify the physiological basis of arousal and related processing mechanisms; a model of integrating multimodal data may be used to optimize the measurement of arousal; the arousal characteristics of human mental diseases (especially comorbid problems) may be further evaluated; and it would be better if the discussion of the relationship between arousal and emotional intensity be more in-depth.

Key words: arousal, anticipation, cognitive mechanism, sleep, wakefulness, emotional intensity

中图分类号:

B845

邹迪, 李红, 王福顺. (2022). 唤醒定义探析及其认知神经生理基础. 心理科学进展 , 30(9), 2020-2033.

ZOU Di, LI Hong, WANG Fushun. (2022). An investigation into the definition of arousal and its cognitive neurophysiological basis. Advances in Psychological Science, 30(9), 2020-2033.

图/表 2

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英文缩写	中英文全称	英文缩写	中英文全称
SAM	The Self-Assessment Manikin, 自我评估模型	TS	Tail of striatum, 尾部纹状体
ANS	Autonomic nervous system, 自主神经系统	TMN	Tuberomammillary nucleus, 下丘脑结节乳头核
SNS	Sympathetic nervous system, 交感神经系统	PPT	Pedunculopontine, 脑桥脚
PNS	Parasympathetic nervous system, 副交感神经系统	LDT	Laterodorsal Tegmental Nuclei, 外侧被盖核
HR	Heart rate, 心率	PB	Parabrachial, 臂膀核
SCL	Skin conductance level, 皮肤电导水平	POA	Preoptic area, 下丘脑视前区
PDR	Pupillary dilation response, 瞳孔扩张反应	LH	Lateral hypothalamus, 外侧下丘脑
HRV	Heart rate variability, 心率变异性	SNr	substantia nigra pars reticulata, 黑质下网状部分
BF	Basal Forebrain, 基底前脑	PAG	periaqueductal gray, 中脑导水管周围黑质
LC	locus coeruleus, 蓝斑	MCH	Melanin concentrating hormone, 黑色素浓缩激素
NE	Norepinephrine, 去甲肾上腺素	DMN	Default mode network, 默认模式网络
DRN	Dorsal raphe nuclei, 中缝背核	SN	Salience network, 突显网络
5-HT	5-hydroxytryptamine, 五-羟色胺	AI	Anterior insula, 前脑岛
VTA	Ventral tegmental area, 腹侧被盖区	ACC	anterior cingulate cortex, 前扣带回
DA	Dopaminergic, 多巴胺

英文缩写	中英文全称	英文缩写	中英文全称
SAM	The Self-Assessment Manikin, 自我评估模型	TS	Tail of striatum, 尾部纹状体
ANS	Autonomic nervous system, 自主神经系统	TMN	Tuberomammillary nucleus, 下丘脑结节乳头核
SNS	Sympathetic nervous system, 交感神经系统	PPT	Pedunculopontine, 脑桥脚
PNS	Parasympathetic nervous system, 副交感神经系统	LDT	Laterodorsal Tegmental Nuclei, 外侧被盖核
HR	Heart rate, 心率	PB	Parabrachial, 臂膀核
SCL	Skin conductance level, 皮肤电导水平	POA	Preoptic area, 下丘脑视前区
PDR	Pupillary dilation response, 瞳孔扩张反应	LH	Lateral hypothalamus, 外侧下丘脑
HRV	Heart rate variability, 心率变异性	SNr	substantia nigra pars reticulata, 黑质下网状部分
BF	Basal Forebrain, 基底前脑	PAG	periaqueductal gray, 中脑导水管周围黑质
LC	locus coeruleus, 蓝斑	MCH	Melanin concentrating hormone, 黑色素浓缩激素
NE	Norepinephrine, 去甲肾上腺素	DMN	Default mode network, 默认模式网络
DRN	Dorsal raphe nuclei, 中缝背核	SN	Salience network, 突显网络
5-HT	5-hydroxytryptamine, 五-羟色胺	AI	Anterior insula, 前脑岛
VTA	Ventral tegmental area, 腹侧被盖区	ACC	anterior cingulate cortex, 前扣带回
DA	Dopaminergic, 多巴胺