奖励线索对个体外在动机的影响：基于ERPs的研究

doi:10.19988/j.cnki.issn.2095-1159.2023.02.009

心理研究

2023, Vol. 16

Issue (2): 172-181 DOI: 10.19988/j.cnki.issn.2095-1159.2023.02.009

应用研究

本期目录 | 过刊浏览 | 高级检索

奖励线索对个体外在动机的影响：基于ERPs的研究

倪亚琨¹, 赵冬梅¹, 张镒¹, 郭腾飞²

1 广东金融学院,广州 510521;
2 广东技术师范大学教育科学学院,广州 510665

The impact of reward clues on external motivation: Based on an ERPs study

NI Yakun¹, ZHAO Dongmei¹, ZHANG Yi¹, GUO Tengfei²

1 Guangdong University of Finance, Guangzhou 510521;
2 Guangdong Polytechnic Normal University, Institute of Vocational Education, Guangzhou 510665

摘要
图/表
参考文献
相关文章 (1)

全文: PDF (1890 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要基于金钱激励延迟实验范式,运用事件相关电位技术考察了奖励线索对个体动机的影响,分别对个体在不同奖赏线索任务中的情景线索加工阶段的Cue-FRN成分、任务准备启动阶段的Task-SPN成分、任务绩效监控阶段的dFRN成分和奖励结果期待的Outcome-SPN成分进行分析。结果发现：在四个任务阶段中,低奖励线索下的Cue-FRN波幅显著负于高奖励线索,且高奖励线索下的Task-SPN、dFRN、Outcome-SPN波幅显著负于低奖励线索,说明在高、低奖励线索下,个体的动机水平具有明显的增强和减弱的效应。而在中奖励线索下四个阶段的脑电成分与高、低奖励线索相比均不存在显著差异,即个体的任务动机反应不存在显著的趋近或回避效应。

	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
	倪亚琨
	赵冬梅
	张镒
	郭腾飞

关键词 ：奖励线索, 外在动机, 事件相关电位, 脑电信号

基金资助:广东省普通高校重点科研平台和项目（2019WCXTD005）、教育部人文社会科学研究项目（21YJC630168）、广东省普通高校特色新型智库（2021TSZK012）、广东省教育科学规划课题（高等教育专项2022GXJK245）、广东省基础与应用研究基金（2022A1515140131）

通讯作者: 郭腾飞,男,讲师,博士。Email：guotengfei@gpnu.edu.com

引用本文:

倪亚琨, 赵冬梅, 张镒, 郭腾飞. 奖励线索对个体外在动机的影响：基于ERPs的研究[J]. 心理研究, 2023, 16(2): 172-181.
NI Yakun, ZHAO Dongmei, ZHANG Yi, GUO Tengfei. The impact of reward clues on external motivation: Based on an ERPs study. Psychological Research, 2023, 16(2): 172-181.

链接本文:

http://xlyj.magtech.com.cn/CN/10.19988/j.cnki.issn.2095-1159.2023.02.009 或 http://xlyj.magtech.com.cn/CN/Y2023/V16/I2/172

[1] 白学军, 朱昭红, 沈德立, 刘楠. (2009). 奖惩线索条件下内外倾个体的自主唤醒和行为反应.心理学报, 41(06), 492-500.
[2] 郭婷, 李欢欢, 王湘, 林亦轩, 范乐佳, 张蓓,欧阳紫榕. (2016). 金钱激励和情感激励延迟加工的事件相关电位比较研究.中国临床心理学杂志, 24(6), 963-970.
[3] Anderson, B. A., & Yantis, S. (2013). Persistence of value-driven attentional capture.Journal of Experimental Psychology: Human Perception and Performance, 39(1), 6-9.
[4] Angus D. J., Latham A. J., Harmon‐Jones E., Deliano M., Balleine B., & Braddon‐Mitchell D. (2017). Electrocortical components of anticipation and consumption in a monetary incentive delay task.Psychophysiology, 54(11), 1686-1705.
[5] Banerjee S., Frey H., Molholm S., & Foxe J. J. (2015). Interests shape how adolescents pay attention: The interaction of motivation and top-down attentional processes in biasing sensory activations to anticipated events.European Journal of Neuroscience, 41(6), 818-834.
[6] Bijleveld E., Custers R., & Aarts H. (2010). Unconscious reward cues increase invested effort, but do not change speed-accuracy tradeoffs.Cognition, 115(2), 330-335.
[7] Brunia C. H., van Boxtel G. J., Böcker K. B., Kappenman E. S., & Luck S. J. (2012). Negative slow waves as indices of anticipation: The Bereitschaftspotential, the contingent negative variation, and the stimulus-preceding negativity. The Oxford handbook of event-related potential components, 189-207.
[8] Brunia C. H., Hackley S. A., van Boxtel G. J., Kotani Y., & Ohgami Y. (2011). Waiting to perceive: Reward or punishment? Clinical Neurophysiology, 122(5), 858-868.
[9] Chelazzi L., Perlato A., Santandrea E., & Della Libera C. (2013). Rewards teach visual selective attention.Vision Research, 85, 58-72.
[10] Chiew, K. S., & Braver, T. S. (2013). Temporal dynamics of motivation-cognitive control interactions revealed by high-resolution pupillometry.Frontiers in Psychology, 4, 15.
[11] Chiew, K. S., & Braver, T. S. (2014). Dissociable influences of reward motivation and positive emotion on cognitive control.Cognitive, Affective, & Behavioral Neuroscience, 14(2), 509-529.
[12] Chiew, K. S., & Braver, T. S. (2016). Reward favors the prepared: Incentive and task-informative cues interact to enhance attentional control.Journal of Experimental Psychology: Human Perception and Performance, 42(1), 52-66.
[13] Deci E. L., Koestner R., & Ryan R. M. (1999). A meta-analytic review of experiments examining the effects of extrinsic rewards on intrinsic motivation.Psychological Bulletin, 125(6), 627-626.
[14] Dodd, M. D., & Flowers, J. (Eds.). (2012). The influence of attention, learning, and motivation on visual search. Springer Science & Business Media.
[15] Engelmann J. B., Damaraju E., Padmala S., & Pessoa L. (2009). Combined effects of attention and motivation on visual task performance: Transient and sustained motivational effects.Frontiers in Human Neuroscience, 3(4), 1-17.
[16] Flores A., Münte T. F., & Doñamayor N. (2015). Event-related EEG responses to anticipation and delivery of monetary and social reward.Biological Psychology, 109, 10-19.
[17] Foti, D., & Hajcak, G. (2012). Genetic variation in dopamine moderates neural response during reward anticipation and delivery: Evidence from event‐related potentials.Psychophysiology, 49(5), 617-626.
[18] Fröber, K., & Dreisbach, G. (2014). The differential influences of positive affect, random reward, and performance-contingent reward on cognitive control.Cognitive, Affective, & Behavioral Neuroscience, 14(2), 530-547.
[19] Fuentemilla L., Cucurell D., Marco-Pallarés J., Guitart-Masip M., Morís J., & Rodríguez-Fornells A. (2013). NeuroImage, 78, 135-144.
[20] Greenhouse, I., & Wessel, J. R. (2013). EEG signatures associated with stopping are sensitive to preparation.Psychophysiology, 50(9), 900-908.
[21] Hackley S. A., Valle-Inclán F., Masaki H., & Hebert K. (2014). Stimulus‐preceding negativity (SPN) and attention to rewards.Cognitive Electrophysiology of Attention: Signals of the Mind, 216-225.
[22] Hajcak G., Moser J. S., Holroyd C. B., & Simons R. F. (2007). It's worse than you thought: The feedback negativity and violations of reward prediction in gambling tasks.Psychophysiology, 44(6), 905-912.
[23] Halsband T., Ferdinand N., Bridger E., & Mecklinger A. (2012). Monetary rewards influence retrieval orientations.Cognitive, Affective, & Behavioral Neuroscience, 12(3), 430-445.
[24] Hare T. A., O'Doherty J., Camerer C. F., Schultz W., & Rangel A. (2008). Dissociating the role of the orbitofrontal cortex and the striatum in the computation of goal values and prediction errors.Journal of Neuroscience, 28(22), 5623-5630.
[25] Holroyd C. B., Krigolson O. E., & Lee S. (2011). Reward positivity elicited by predictive cues.Neuroreport, 22(5), 249-252.
[26] Holroyd, C. B., & Yeung, N. (2012). Motivation of extended behaviors by anterior cingulate cortex.Trends in Cognitive Sciences, 16(2), 122-128.
[27] Jin J., Yu L., & Ma Q. (2015). Neural basis of intrinsic motivation: Evidence from event-related potentials.Computational Intelligence and Neuroscience. 7, 698725.
[28] Krebs R. M., Boehler C. N., Appelbaum L. G., & Woldorff M. G. (2013). Reward associations reduce behavioral interference by changing the temporal dynamics of conflict processing.PloS one, 8(1), e53894.
[29] Levy, D. J., & Glimcher, P. W. (2012). The root of all value: A neural common currency for choice.Current opinion in Neurobiology, 22(6), 1027-1038.
[30] Liu X., Hairston J., Schrier M., & Fan J. (2011). Common and distinct networks underlying reward valence and processing stages: A meta-analysis of functional neuroimaging studies.Neuroscience & Biobehavioral Reviews, 35(5), 1219-1236.
[31] Ma Q., Jin J., Meng L., & Shen Q. (2014). The dark side of monetary incentive: How does extrinsic reward crowd out intrinsic motivation.Neuroreport, 25(3), 194-198.
[32] Morie K. P., De Sanctis P., & Foxe J. J. (2014). Reward contingencies and the recalibration of task monitoring and reward systems: A high-density electrical mapping study.Neuroscience, 273, 100-117.
[33] Novak B. K., Novak K. D., Lynam D. R., & Foti D. (2016). Individual differences in the time course of reward processing: Stage-specific links with depression and impulsivity.Biological Psychology, 119, 79-90.
[34] O'Brien, J. L., & Raymond, J. E. (2012). Learned predictiveness speeds visual processing.Psychological Science, 23(4), 359-363.
[35] Osinsky R., Mussel P., hrlein L., & Hewig J. (2013). A neural signature of the creation of social evaluation.Social Cognitive and Affective Neuroscience, 9(6), 731-736.
[36] Oumeziane B. A., Schryer-Praga J., & Foti D. (2017). “Why don't they ‘like'me more?” Comparing the time courses of social and monetary reward processing.Neuropsychologia, 107, 48-59.
[37] Padmala, S., & Pessoa, L. (2011). Reward reduces conflict by enhancing attentional control and biasing visual cortical processing.Journal of Cognitive Neuroscience, 23(11), 3419-3432.
[38] Pornpattananangkul, N., & Nusslock, R. (2015). Motivated to win: Relationship between anticipatory and outcome reward-related neural activity.Brain and Cognition, 100, 21-40.
[39] Proudfit, G. H. (2015). The reward positivity: From basic research on reward to a biomarker for depression.Psychophysiology, 52(4), 449-459.
[40] Raymond, J. E., & O'Brien, J. L. (2009). Selective visual attention and motivation: The consequences of value learning in an attentional blink task.Psychological Science, 20(8), 981-988.
[41] Salamone, J. D., & Correa, M. (2012). The mysterious motivational functions of mesolimbic dopamine.Neuron, 76(3), 470-485.
[42] Sawaki R., Luck S. J., Raymond J. E. (2015). How attention changes in response to incentives.Journal of Cognitive Neuroscience, 27(11), 2229-2239.
[43] Small D. M., Gitelman D., Simmons K., Bloise S. M., Parrish T., & Mesulam M. M. (2005). Monetary incentives enhance processing in brain regions mediating top-down control of attention.Cerebral Cortex, 15(12), 1855-1865.
[44] Smith A.B., Halari R., Giampetro V., Brammer, M. & Rubia, K. (2011) Developmental effects of reward on sustained attention networks.NeuroImage, 56, 1693-1704.
[45] Vol'f, N. V., & Tarasova, I. V. (2014). Electrophysiological parameters and the possibility of increasing imaginal creativity using monetary rewards.Neuroscience and Behavioral Physiology, 44(3), 268-276.
[46] Walsh, M. M., & Anderson, J. R. (2012). Learning from experience: Event-related potential correlates of reward processing, neural adaptation, and behavioral choice.Neuroscience & Biobehavioral Reviews, 36(8), 1870-1884.
[47] Wetherill, G. B., & Levitt, H. (1965). Sequential estimation of points on a psychometric function.British Journal of Mathematical and Statistical Psychology, 18(1), 1-10.
[48] Xu S., Pan Y., Qu Z., Fang Z., Yang Z., Yang F., & Rao H. (2018). Differential effects of real versus hypothetical monetary reward magnitude on risk-taking behavior and brain activity.Scientific Reports, 8(1), 3712.
[49] Zhang X., Lin X., Takagi S., & Sai L. (2017). Electrophysiological Correlates of Cue-Related Processing in a Gambling Task: Early Outcome Evaluation or Outcome Expectation? Frontiers in Psychology, 8, 978.
[50] Zhang Y., Li Q., Wang Z., Liu X., & Zheng Y. (2017). Temporal dynamics of reward anticipation in the human brain.Biological Psychology, 128, 89-97.