责任共担促进新手的互动决策获益：超扫描研究

doi:10.3724/SP.J.1041.2022.01391

摘要/Abstract

摘要：

采用基于近红外脑成像的超扫描技术, 考察了责任共担(即共同承担决策结果)对个体(专家和新手)的互动决策获益(即互动决策后个体的能力提升)的影响及脑机制。结果显示, 相比于非责任共担, 责任共担条件下新手的互动决策获益更高, 其与互动同伴在额极区域存在增强的脑间活动同步性; 并且, 额极的脑间活动同步性可预测新手的互动决策获益。综上, 责任共担可以有效促进新手的互动决策获益, 额极脑间活动同步性可能是潜在的脑机制。

关键词: 互动获益, 责任共担, 社会决策, 超扫描, 近红外脑成像

Abstract:

Social interaction is ubiquitous. It is widely accepted that social interaction, such as social decision-making, can promote individual’s ability and performance (the so-called “interaction benefit”). For example, it was reported that individuals gained more when making a joint decision with conspecifics. Little is known, however, whether and how this interaction benefit during decision making can be biased by shared responsibility (i.e., sharing the results of joint decision-making) between the interacting agents.

To address this question, the present study used the dot location estimation task (i.e., an adapted paradigm for social decision-making) and functional near-infrared spectroscopy (fNIRS) hyperscanning (i.e., the measurement of two or more brains simultaneously) technique to investigate the impact of shared responsibility on social decision making. A total number of 70 participants were recruited, forming 35 same-gender dyads. Each dyad included one “expert” and one “novice” (differentiated based on their performance during an initial estimation of dot locations). The fNIRS optodes were placed over prefrontal and right temporo-parietal regions, with 23 channels for each participant.

Our results showed that, on the behavioral level, only the novice in a dyad benefited from interaction; also, compared to the non-shared-responsibility condition, novices obtained a higher level of interaction benefit in the shared-responsibility condition. The dyad tended to adopt a “equality strategy” (i.e., decision-making is based on both one’s own thought and the partner’s suggestion) when sharing responsibility. On the brain imaging level, interpersonal brain synchronization (IBS) within expert-novice dyads in the prefrontal and right temporo- parietal regions were detected during social decision-making. More importantly, novices showed stronger IBS in the frontal pole for the shared-responsibility condition (vs. non-shared-responsibility condition). The enhancement of frontal pole IBS positively predicted interaction benefit during social decision-making. Finally, both interaction benefit and frontal pole IBS were selectively correlated with differential performance between novices and experts during the initial estimation of dot locations.

These results suggest that sharing the results of joint decision-making can promote the benefit of interactive decision-making in novices. Interpersonal synchronization of frontal poles might serve as a potential brain mechanism. These findings have implications for decision-making, social-cognitive processes, and clinical practice.

Key words: interaction benefit, shared responsibility, social decision-making, hyperscanning, fNIRS

中图分类号:

成晓君, 刘美焕, 潘亚峰. (2022). 责任共担促进新手的互动决策获益：超扫描研究. 心理学报, 54(11), 1391-1402.

CHENG Xiaojun, LIU Meihuan, PAN Yafeng. (2022). Shared responsibility promotes the benefit of interactive decision-making in novices: A hyperscanning study. Acta Psychologica Sinica, 54(11), 1391-1402.

图/表 3

图1 实验设置图。(A)实验场景示意图。(B)社会决策任务中独立决策阶段和互动决策阶段的设置。(C)光极的位置。

图2 行为学结果。(A)专家和新手在基线任务时的行为表现。

图3 脑间同步结果。(A)责任共担和非责任共担条件下的脑间同步t值分布图。责任共担条件下, 前额叶大部分通道出现显著的脑间同步; 非责任共担条件下, 前额叶仅通道14显著出脑间同步。(B)脑间同步的条件间差异t值图。其中, 通道5表现出显著的条件间差异, 体现为责任共担条件下的脑间同步显著大于非责任共担条件。责任共担条件下, 通道5的脑间同步与新手进步值呈显著正相关, 与被试对初始能力差异呈显著正相关。注：* p < 0.05。误差线为标准误。

参考文献 60

[1]	Amodio, D. M., & Frith, C. D. (2006). Meeting of minds:The medial frontal cortex and social cognition. Nature Reviews Neuroscience, 7(4), 268-277.
[2]	Arridge, S. R., Cope, M., & Delpy, D. T. (1992). The theoretical basis for the determination of optical pathlengths in tissue: Temporal and frequency analysis. Physics in Medicine Biology, 37(7), 1531-1560. doi: 10.1088/0031-9155/37/7/005 URL
[3]	Astin, A. W. (1999). Student involvement: A developmental theory for higher education. Journal of College Student Development, 40(5), 518-529.
[4]	Bahrami, B., Olsen, K., Latham, P. E., Roepstorff, A., Rees, G., & Frith, C. D. (2010). Optimally interacting minds. Science, 329(5995), 1081-1085. doi: 10.1126/science.1185718 pmid: 20798320
[5]	Balardin, J. B., Zimeo, M., Furucho, R. A., Trambaiolli, L., Vanzella, P., Biazoli, C., & Sato, J. R. (2017). Imaging brain function with functional near infrared spectroscopy in unconstrained environments. Frontiers in Human Neuroscience, 11, 258. doi: 10.3389/fnhum.2017.00258 pmid: 28567011
[6]	Balconi, M., & Fronda, G. (2020). The "gift effect" on functional brain connectivity. Inter-brain synchronization when prosocial behavior is in action. Scientific Reports, 10(1), 5394-5394. doi: 10.1038/s41598-020-62421-0 pmid: 32214218
[7]	Barnett, L., & Seth, A. K. (2014). The MVGC multivariate granger causality toolbox: A new approach to granger- causal inference. Journal of Neuroscience Methods, 223, 50-68. doi: 10.1016/j.jneumeth.2013.10.018 pmid: 24200508
[8]	Benjamini, Y., & Hochberg, Y. (1995). Controlling the false discovery rate: A practical and powerful approach to multiple testing. Journal of the Royal Statistical Society. Series B: Methodological, 57( 1), 289-300.
[9]	Bevilacqua, D., Davidesco, I., Wan, L., Chaloner, K., J, Rowland, & Ding, M., & Dikker, S. (2019). Brain-to-brain synchrony and learning outcomes vary by student-teacher dynamics: Evidence from a real-world classroom electroencephalography study. Journal of Cognitive Neuroscience, 31(3), 401-411. doi: 10.1162/jocn_a_01274 pmid: 29708820
[10]	Christoff, K., & Gabrieli, J. (2000). The frontopolar cortex and human cognition: Evidence for a rostrocaudal hierarchical organization within the human prefrontal cortex. Psychobiology, 28(2), 168-186. doi: 10.3758/BF03331976 URL
[11]	Cui, X., Bray, S., & Reiss, A. L. (2010). Functional near infrared spectroscopy (NIRS) signal improvement based on negative correlation between oxygenated and deoxygenated hemoglobin dynamics. NeuroImage, 49(4), 3039-3046. doi: 10.1016/j.neuroimage.2009.11.050 pmid: 19945536
[12]	Cui, X., Bryant, D. M., & Reiss, A. L. (2012). NIRS-based hyperscanning reveals increased interpersonal coherence in superior frontal cortex during cooperation. NeuroImage, 59(3), 2430-2437. doi: 10.1016/j.neuroimage.2011.09.003 pmid: 21933717
[13]	Daffner, K. R., Mesulam, M. M., Scinto, L., Acar, D., Calvo, V., Faust, R.,... Holcomb, P. (2000). The central role of the prefrontal cortex in directing attention to novel events. Brain, 123(5), 927-939. doi: 10.1093/brain/123.5.927 URL
[14]	Delpy, D. T., Cope, M., van der Zee, P., Arridge, S., Wray, S., & Wyatt, J. (1988). Estimation of optical pathlength through tissue from direct time of flight measurement. Physics in Medicine Biology, 33(12), 1433.
[15]	Fehr, E., & Camerer, C. F. (2007). Social neuroeconomics: The neural circuitry of social preferences. Trends in Cognitive Sciences, 11(10), 419-427. pmid: 17913566
[16]	Fishburn, F. A., Murty, V. P., Hlutkowsky, C. O., MacGillivray, C. E., Bemis, L. M., Murphy, M. E., … Perlman, S. B. (2018). Putting our heads together: Interpersonal neural synchronization as a biological mechanism for shared intentionality. Social Cognitive and Affective Neuroscience, 13(8), 841-849. doi: 10.1093/scan/nsy060 pmid: 30060130
[17]	Ganesh, G., Takagi, A., Osu, R., Yoshioka, T., Kawato, M., & Burdet, E. (2014). Two is better than one: Physical interactions improve motor performance in humans. Scientific Reports, 4, 3824. doi: 10.1038/srep03824 pmid: 24452767
[18]	Green, A., Kraemer, D. J. M., Fugelsang, J. A., Gray, J. R., & Dunbar, K. N. (2010). Connecting long distance: Semantic distance in analogical reasoning modulates frontopolar cortex activity. Cerebral Cortex, 20(1), 70-76. doi: 10.1093/cercor/bhp081 URL
[19]	Hiraoka, M., Firbank, M., Essenpreis, M., Cope, M., Arridge, S. R., van der Zee, P., & Delpy, D. T. (1993). A Monte Carlo investigation of optical pathlength in inhomogeneous tissue and its application to near-infrared spectroscopy. Physics in Medicine Biology, 38(12), 1859-1876. doi: 10.1088/0031-9155/38/12/011 URL
[20]	Hoshi, Y. (2003). Functional near-infrared optical imaging: Utility and limitations in human brain mapping. Psychophysiology, 40(4), 511-520. pmid: 14570159
[21]	Hu, Y., Hu, Y., Li, X., Pan, Y., & Cheng, X. (2017). Brain-to- brain synchronization across two persons predicts mutual prosociality. Social Cognitive and Affective Neuroscience, 12(12), 1835-1844. doi: 10.1093/scan/nsx118 URL
[22]	Hu, Y., Pan, Y., Shi, X., Cai, Q., Li, X., & Cheng, X. (2018). Inter-brain synchrony and cooperation context in interactive decision making. Biological Psychology, 133, 54-62. doi: S0301-0511(17)30353-8 pmid: 29292232
[23]	Jahng, J., Kralik, J. D., Hwang, D. U., & Jeong, J. (2017). Neural dynamics of two players when using nonverbal cues to gauge intentions to cooperate during the Prisoner's Dilemma Game. Neuroimage, 157, 263-274. doi: S1053-8119(17)30493-7 pmid: 28610901
[24]	Jiang, J., Dai, B., Peng, D., Zhu, C., Liu, L., & Lu, C. (2012). Neural synchronization during face-to-face communication. Journal of Neuroscience, 32(45), 16064-16069. doi: 10.1523/JNEUROSCI.2926-12.2012 pmid: 23136442
[25]	Johnson, D. W., & Johnson, R. T. (2005). New developments in social interdependence theory. Genetic, Social, and General Psychology Monographs, 131( 4), 285-358.
[26]	Li, X., Bei, L., Yuan, D., Ding, Y., & Feng, D. (2018). The brain-to-brain correlates of social interaction in the perspective of hyperscanning approach. Journal of Psychological Science, 41(6), 206-213.
	[李先春, 卑力添, 袁涤, 丁雅娜, 冯丹阳. (2018). 超扫描视角下的社会互动脑机制. 心理科学, 41(6), 206-213.]
[27]	Liu, W., Branigan, H. P., Zheng, L., Long, Y., Bai, X., Li, K.,... Lu, C. (2019). Shared neural representations of syntax during online dyadic communication. Neuroimage, 198, 63-72. doi: S1053-8119(19)30427-6 pmid: 31102737
[28]	Lorenz, J., Rauhut, H., Schweitzer, F., & Helbing, D. (2011). How social influence can undermine the wisdom of crowd effect. Proceedings of the National Academy of Sciences of the United States of America, 108(22), 9020-9025. doi: 10.1073/pnas.1008636108 pmid: 21576485
[29]	Lu, K., & Hao, N. (2019). When do we fall in neural synchrony with others? Social Cognitive Affective Neuroscience, 14(3), 253-261. doi: 10.1093/scan/nsz012 URL
[30]	Lu, K., Qiao, X., & Hao, N. (2019). Praising or keeping silent on partner's ideas: Leading brainstorming in particular ways. Neuropsychologia, 124, 19-30. doi: S0028-3932(18)30486-X pmid: 30633875
[31]	Mahmoodi, A., Bang, D., Olsen, K., Zhao, Y. A., Shi, Z., Broberg, K.,... Bahrami, B. (2015). Equality bias impairs collective decision-making across cultures. Proceedings of the National Academy of Sciences, 112(12), 3835-3840. doi: 10.1073/pnas.1421692112 URL
[32]	Mastroeni, L., Vellucci, P., & Naldi, M. (2017). Individual competence evolution under equality bias. In 2017 European Modelling Symposium (EMS) (pp. 123-128). doi: 110.1109/EMS.2017.1131. doi: 110.1109/EMS.2017.1131
[33]	Miller, J. G., Vrticka, P., Cui, X., Shrestha, S., Hosseini, S. M. H., Baker, J. M., & Reiss, A. L. (2019). Inter-brain synchrony in mother-child dyads during cooperation: An fNIRS hyperscanning study. Neuropsychologia, 124, 117-124. doi: S0028-3932(18)30357-9 pmid: 30594570
[34]	Minson, J. A., Liberman, V., & Ross, L. (2011). Two to tango: Effects of collaboration and disagreement on dyadic judgment. Personality & Social Psychology Bulletin, 37(10), 1325-1338.
[35]	Miyamoto, K., Setsuie, R., Osada, T., & Miyashita, Y. (2018). Reversible silencing of the frontopolar cortex selectively impairs metacognitive judgment on non-experience in primates. Neuron, 97(4), 980-989. doi: S0896-6273(17)31208-4 pmid: 29395916
[36]	Montague, P. R., Berns, G. S., Cohen, J. D., Mcclure, S. M., Pagnoni, G., Dhamala, M.,... Fisher, R. E. (2002). Hyperscanning: Simultaneous fMRI during linked social interactions. Neuroimage, 16(4), 1159-1164. pmid: 12202103
[37]	Nguyen, T., Schleihauf, H., Kayhan, E., Matthes, D., Vrticka, P., & Hoehl, S. (2020). The effects of interaction quality on neural synchrony during mother-child problem solving. Cortex, 124, 235-249. doi: S0010-9452(19)30406-X pmid: 31927470
[38]	Nozawa, T., Sakaki, K., Ikeda, S., Jeong, H., Yamazaki, S., Kawata, K.,... Kawashima, R. (2019). Prior physical synchrony enhances rapport and inter-brain synchronization during subsequent educational communication. Scientific Reports, 9(1), 12747.
[39]	Okuda, J., Fujii, T., Yamadori, A., Kawashima, R., Tsukiura, T., Fukatsu, R.,... Fukuda, H. (1998). Participation of the prefrontal cortices in prospective memory: Evidence from a PET study in humans. Neuroscience Letters, 253(2), 127-130. pmid: 9774166
[40]	Pan, Y., Dikker, S., Goldstein, P., Zhu, Y., Yang, C., & Hu, Y. (2020). Instructor-learner brain coupling discriminates between instructional approaches and predicts learning. NeuroImage, 211, 116657. doi: 10.1016/j.neuroimage.2020.116657 URL
[41]	Pan, Y., Novembre, G., Song, B., Li, X., & Hu, Y. (2018). Interpersonal synchronization of inferior frontal cortices tracks social interactive learning of a song. Neuroimage, 183, 280-290. doi: S1053-8119(18)30692-X pmid: 30086411
[42]	Piazza, E., Hasenfratz, L., Hasson, U., & Lew-Williams, C. (2020). Infant and adult brains are coupled to the dynamics of natural communication. Psychological Science, 31(1), 6-17. doi: 10.1177/0956797619878698 pmid: 31845827
[43]	Reindl, V., Gerloﬀ, C., Scharke, W., Konrad, K. (2018). Brain-to-brain synchrony in parent-child dyads and the relationship with emotion regulation revealed by fNIRS-based hyperscanning. Neuroimage, 178, 493-502. doi: S1053-8119(18)30478-6 pmid: 29807152
[44]	Sella, F., Blakey, R., Bang, D., Bahrami, B., & Kadosh, R. C. (2018). Who gains more: Experts or novices? The benefits of interaction under numerical uncertainty. Journal of Experimental Psychology: Human Perception Performance, 44(8), 1228-1239. doi: 10.1037/xhp0000526 URL
[45]	Sella, F., Sader, E., Lolliot, S., & Kadosh, R. C. (2016). Basic and advanced numerical performances relate to mathematical expertise but are fully mediated by visuospatial skills. Journal of Experimental Psychology: Learning Memory Cognition, 42(9), 1458-1472. doi: 10.1037/xlm0000249 URL
[46]	Siegler, R. S., & Opfer, J. E. (2003). The development of numerical estimation: Evidence for multiple representations of numerical quantity. Psychological Science, 14(3), 237-243. pmid: 12741747
[47]	Soll, J. B., & Mannes, A. E. (2011). Judgmental aggregation strategies depend on whether the self is involved. International Journal of Forecasting, 27(1), 81-102. doi: 10.1016/j.ijforecast.2010.05.003 URL
[48]	Sun, B., Xiao, W., Feng, X., Shao, Y., Zhang, W., & Li, W. (2020). Behavioral and brain synchronization differences between expert and novice teachers when collaborating with students. Brain and Cognition, 139, 105513. doi: 10.1016/j.bandc.2019.105513 URL
[49]	Sun, J., Chen, Q., Zhang, Q., Li, Y., Li, H., Wei, D., Yang, W., & Qiu, J. (2016). Training your brain to be more creative: Brain functional and structural changes induced by divergent thinking training. Human Brain Mapping, 37(10), 3375-3387. doi: 10.1002/hbm.23246 pmid: 27159407
[50]	Tang, H., Mai, X., Wang, S., Zhu, C., Krueger, F., & Liu, C. (2016). Interpersonal brain synchronization in the right temporo-parietal junction during face-to-face economic exchange. Social Cognitive Affective Neuroscience, 11(1), 23-32. doi: 10.1093/scan/nsv092 URL
[51]	Torrence, C., & Compo, G. P. (1998). A practical guide to wavelet analysis. Bulletin of the American Meteorological Society, 79(1), 61-78. doi: 10.1175/1520-0477(1998)079<0061:APGTWA>2.0.CO;2 URL
[52]	van Overwalle, F. (2009). Social cognition and the brain: A meta-analysis. Human Brain Mapping, 30(3), 829-858. doi: 10.1002/hbm.20547 pmid: 18381770
[53]	Wahn, B., Kingstone, A., & König, P. (2017). Two trackers are better than one: Information about the co-actor's actions and performance scores contribute to the collective benefit in a joint visuospatial task. Frontiers in Psychology, 8, 669. doi: 10.3389/fpsyg.2017.00669 pmid: 28515704
[54]	Xue, H., Lu, K., & Hao, N. (2018). Cooperation makes two less-creative individuals turn into a highly-creative pair. Neuroimage, 172, 527-537. doi: S1053-8119(18)30095-8 pmid: 29427846
[55]	Yang, J., Zhang, H., Ni, J., de Dreu, C. K. W., & Ma, Y. (2020). Within-group synchronization in the prefrontal cortex associates with intergroup conflict. Nature Neuroscience, 23(6), 754-760. doi: 10.1038/s41593-020-0630-x pmid: 32341541
[56]	Yaniv, I., & Kleinberger, E. (2000). Advice taking in decision making: Egocentric discounting and reputation formation. Organizational Behavior Human Decision Processes, 83(2), 260-281. doi: 10.1006/obhd.2000.2909 URL
[57]	Yu, L., Bao, J., Chen, Q., & Wang, D. (2016). The effect of individual confidence on dyadic decision making. Acta Psychologica Sinica, 48(8), 1013-1025. doi: 10.3724/SP.J.1041.2016.01013 URL
	[余柳涛, 鲍建樟, 陈清华, 王大辉. (2016). 个体自信度对双人决策的影响. 心理学报, 48(8), 1013-1025.]
[58]	Zein, M. E., Bahrami, B., & Hertwig, R. (2019). Shared responsibility in collective decisions. Nature Human Behaviour, 3(6), 554-559. doi: 10.1038/s41562-019-0596-4 pmid: 31011162
[59]	Zhang, M., Liu, T., Pelowski, M., Jia, H., & Yu, D. (2017). Social risky decision-making reveals gender differences in the TPJ: A hyperscanning study using functional near- infrared spectroscopy. Brain and Cognition, 119, 54-63. doi: 10.1016/j.bandc.2017.08.008 URL
[60]	Zhu, Y., Leong, V., Hou, Y., Zhang, D., Pan, Y., & Hu, Y. (2021). Instructor-learner neural synchronization during elaborated feedback predicts learning transfer. Journal of Educational Psychology. Advance Online Publication. DOI: 10.1037/edu0000707 doi: 10.1037/edu0000707