联合脑电信号与虚拟技术的大脑情绪状态的半球不对称性研究

doi:10.3969/j.issn.0258-8021.2021.03.02

摘要
图/表
参考文献
相关文章 (10)

全文: PDF (6770 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要为区分大脑的情绪状态以及研究在不同情绪状态下的大脑半球不对称性,征选20名健康视听无障碍的受试作为实验对象,联合虚拟现实(VR)技术和脑电(EEG)监测,在不同的VR影片刺激下,采集受试脑电信号,提取各频段的平均功率谱密度,并计算大脑半球不对称性的参考指数,对比在不同情绪状态下各频段与各脑区下的参考指数。结果显示,相较于中性情绪,积极情绪与消极情绪在额区的半球不对称性指数均偏小,但在alpha频段,额区出现积极(0.130±0.227)、中性(0.058±0.240)、消极(0.006±0.130)依次递减的指数趋势,表明积极情绪下左侧额区更加活跃,且积极情绪与消极情绪两组间有具显著差异(P<0.05);而在其他频段中,额区的半球不对称性指数较为平均。此结果可为不同情绪的区分提供新思路,也为脑功能疾病以及心理疾病的判断和治疗提供新方法。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	蓝文威
	陈晨
	张金
	张家琦
	黎峰
	高军峰

关键词 ：情绪状态, 半球不对称性指数, EEG, 功率谱密度, 虚拟现实技术

Abstract：In order to distinguish the emotional state of the brain and study the hemispheric asymmetry in different emotional states,20 healthy audiovisual barrier-freesubjects with an average age of 23.9 years were selected as experimental subjects, virtual reality technology and EEG technology were combined to collect EEG signals of subjects under different VR film stimulation, and then the average power spectral density of each frequency band was extracted for uses in the calculation of the index of cerebral hemisphere asymmetry on each frequency band and each brain region. Results show that the asymmetry index of positive emotion and negative emotion in frontal region hemisphere were smaller than that of neutral emotion, whereas in alpha band, the trend of asymmetry index on positive (0.130±0.227), neutral (0.058±0.240) and negative (0.006±0.130) decreased in sequence, indicating that the left frontal region was more active under positive emotion, and there was significant difference between positive emotion and negative emotion group (P < 0.05). While in other bands, the asymmetry index of frontal hemisphere had less difference between the three states. These results provided a new way to distinguish different emotions, and also provided a new method for the judgment and treatment of brain function diseases and psychological diseases.

Key words： emotional state hemispheric asymmetry index EEG power spectral density virtual reality technology

收稿日期: 2020-07-30

PACS:

R318

基金资助:国家自然科学基金(81271659, 61773408);中央高校基本科研业务费专项资金(CZZ19004, CZY20039)

通讯作者: * E-mail: junfengmst@163.com

引用本文:

蓝文威, 陈晨, 张金, 张家琦, 黎峰, 高军峰. 联合脑电信号与虚拟技术的大脑情绪状态的半球不对称性研究[J]. 中国生物医学工程学报, 2021, 40(3): 266-271.
Lan Wenwei, Chen Chen, Zhang Jin, Zhang Jiaqi, Li Feng, Gao Junfeng. Asymmetry of Brain Emotional State Based on EEG and VR Techniques. Chinese Journal of Biomedical Engineering, 2021, 40(3): 266-271.

链接本文:

http://cjbme.csbme.org/CN/10.3969/j.issn.0258-8021.2021.03.02 或 http://cjbme.csbme.org/CN/Y2021/V40/I3/266

[1] Schmidt LA, Trainor LJ. Frontal brain electrical activity (EEG) distinguishes valence and intensity of musical emotions [J]. Cognition & Emotion, 2001, 15(4): 487-500.
[2] Sammler D, Grigutsch M, Fritz T, et al. Music and emotion: Electrophysiological correlates of the processing of pleasant and unpleasant music[J]. Psychophysiology, 2010, 44(2): 293-304.
[3] Boytsova JA, Danko SG, Gratcheva LV, et al. Local EEG synchronization during internal and external induction of human emotions[J]. International Journal of Psychophysiology, 2012, 3: 408-408.
[4] Canli T. Hemispheric asymmetry in theexperience of emotion: A perspective from functional imaging [J]. Neuroentist, 1999, 5(4): 201-207.
[5] Zibman S, Daniel E, Alyagon U, et al. Interhemispheric cortico-cortical paired associative stimulation of the prefrontal cortex jointly modulates frontal asymmetry and emotional reactivity [J]. Brain Stimulation, 2019, 12(1): 139-147.
[6] Crawford HJ, Clarke SW, Kitner-Triolo M. Self-generated happy and sad emotions in low and highly hypnotizable persons during waking and hypnosis: laterality and regional EEG activity differences [J]. International Journal of Psychophysiology, 1996, 24(3): 239-266.
[7] Lu Yun, Wang Mingjiang, Wu Wanqing, et al. Dynamic entropy-based pattern learning to identify emotions from EEG signals across individuals[J]. Measurement, 2020,150:107003.
[8] Liang Z, Oba S, Ishii S. An unsupervised EEG decoding system for human emotion recognition [J]. Neural Networks, 2019, 116: 257-268.
[9] Yin Zhong, Zhang Jianhua. Subject-generic EEG feature selection for emotion classification via transfer recursive feature elimination[C]//2017 36th Chinese Control Conference. Dalian: IEEE, 2017: 11005-11010.
[10] 彭丝雨, 周到, 张家琦,等. 基于互信息的脑网络及测谎研究[J]. 电子学报, 2019, 47(7): 1551-1556.
[11] Yang Yuxuan, Gao Zhongke, Wang Xinmin, et al. A recurrence quantification analysis-based channel-frequency convolutional neural network for emotion recognition from EEG [J]. Chaos, 2018, 28(8): 085724.
[12] Hinrikus H, Suhhova A, Bachmann M, et al. Electroencephalographic spectral asymmetry index for detection of depression [J]. Medical & Biological Engineering & Computing, 2009, 47(12): 1291-1299.
[13] Parsons TD, Rizzo AA. Affective outcomes of virtual reality exposure therapy for anxiety and specific phobias: A meta-analysis[J]. Journal of Behavior Therapy & Experimental Psychiatry, 2008, 39(3): 250-261.
[14] Bartolic EI, Basso MR, Schefft BK, et al. Effects of experimentally-induced emotional states on frontal lobe cognitive task performance[J]. Neuropsychologia, 1999, 37(6): 677-683.
[15] Dixon ML, Thiruchselvam R, Todd R, et al. Emotion and the Prefrontal Cortex: An integrative review[J]. Psychological Bulletin, 2017, 143(10): 1033-1081.
[16] Salzman CD, Fusi S. Emotion, cognition, and mental state representation in amygdala and prefrontal cortex [J]. Annual Review of Neuroence, 2010, 33(1): 173-202.
[17] Davidson RJ. What does the prefrontal cortex “do” in affect: Perspectives on frontal EEG asymmetry research [J]. Biological Psychology, 2004, 67(1-2): 219-234.