Cross-System Consistency of Working Memory Advantage in Action Video Game Players: A fNIRS Study

doi:10.12139/j.1672-0628.2023.04.004

Abstract

Abstract:

Previous studies have shown that action video game (AVG) players have an advantage in working memory (WM). However, it is uncertain whether this advantage exists in both the visual-spatial and verbal WM subsystems, and the physiological basis for this advantage is unclear. Using the n-back paradigm, this study examined the WM characteristics of AVG players by functional near-infrared spectroscopy (fNIRS), selecting spatial and verbal materials. Results showed that the reaction time of the player group was significantly shorter than that of the non-player group. Furthermore, the difference in reaction time between two groups was more significant in the 2-back condition. As indicated by the fNIRS results, the β values of the player group in channel 4 were significantly smaller than those of the non-player group in both subsystems. Moreover, when the player group was given two loading levels in the verbal WM task, there was no significant difference between the β values in channel 10, suggesting that the dorsolateral prefrontal cortex may be the dominant brain area for players when dealing with high-load tasks. Overall, the WM advantage of AVG players appears to be universal across multiple systems and represents better responses to high-load tasks.

Key words: action video game, working memory, functional near-infrared spectroscopy

摘要：

动作电子游戏玩家可能存在工作记忆优势，但尚不清楚该优势是否在视觉空间工作记忆和言语工作记忆子系统中都存在，其生理基础也不甚明确。研究采用n-back范式，选取空间和言语材料，利用近红外技术探查动作电子游戏玩家的工作记忆特征。结果发现，玩家组的反应时显著短于非玩家组，效率显著高于非玩家组，且在2-back条件下两组的反应时差异更显著。近红外结果显示，玩家组在通道4的β值在两个子系统中均显著小于非玩家组。在言语工作记忆任务中，玩家组在通道10的β值在两个负荷水平条件下差异不显著，背外侧前额叶可能是玩家应对高负荷条件的优势脑区。结果表明，动作电子游戏玩家的工作记忆优势具有跨系统一致性，具体表现为能更好地应对高负荷条件。

关键词: 动作电子游戏, 工作记忆, 功能性近红外光学成像技术

CLC Number:

B842

Wenxin GUO, Wei ZHANG, Yuxi LI. Cross-System Consistency of Working Memory Advantage in Action Video Game Players: A fNIRS Study[J]. Studies of Psychology and Behavior, 2023, 21(4): 454-463.

郭文欣, 张微, 李雨茜. 动作电子游戏玩家工作记忆优势的跨系统一致性：一项近红外研究[J]. 心理与行为研究, 2023, 21(4): 454-463.

Figures/Tables 7

References

	陈一凡. (2018). 双重任务下直立姿势控制与空间工作记忆刷新功能的相互干扰研究: 来自行为和fNIRS的证据(硕士学位论文). 上海体育学院.
	龚辉, 李成军, 李婷, 郑毅, 骆清铭. 前额叶皮层工作记忆作用的近红外光学成像. 中国科学(G辑: 物理学力学天文学), 2007, 37 (S1): 110- 117.
	李嘉莹. (2015). 动作类游戏玩家的视觉工作记忆优势及相关机制(硕士学位论文). 华东师范大学, 上海.
	杨静, 何昊, 张星星, 弋净, 关青, 罗跃嘉, 张浩波. 不同工作记忆训练对认知功能及相关脑电特征的影响. 中国心理卫生杂志, 2021, 35 (7): 599- 605. DOI
	朱一可. (2021). 不同亚型ADHD儿童反应抑制功能和工作记忆功能的功能近红外脑成像研究(硕士学位论文). 首都儿科研究所, 北京.
	Appelbaum, L. G., Cain, M. S., Darling, E. F., & Mitroff, S. R. (2013). Action video game playing is associated with improved visual sensitivity, but not alterations in visual sensory memory. Attention, Perception, & Psychophysics, 75(6), 1161–1167.
	Awh, E., Vogel, E. K., & Oh, S. H.. Interactions between attention and working memory. Neuroscience, 2006, 139 (1): 201- 208. DOI
	Baddeley, A. D. (2002). Is working memory still working? European Psychologist, 7(2), 85–97.
	Baddeley, A. D., & Hitch, G. (1974). Working memory. In G. H. Bower (Ed.), Psychology of learning and motivation (Vol. 8, pp. 47–89). New York: Academic Press.
	Barbey, A. K., Koenigs, M., & Grafman, J.. Orbitofrontal contributions to human working memory. Cerebral Cortex, 2011, 21 (4): 789- 795. DOI
	Bavelier, D., Green, C. S., Pouget, A., & Schrater, P.. Brain plasticity through the life span: Learning to learn and action video games. Annual Review of Neuroscience, 2012, 35, 391- 416. DOI
	Bediou, B., Adams, D. M., Mayer, R. E., Tipton, E., Green, C. S., & Bavelier, D.. Meta-analysis of action video game impact on perceptual, attentional, and cognitive skills. Psychological Bulletin, 2018, 144 (1): 77- 110. DOI
	Bialystok, E.. Effect of bilingualism and computer video game experience on the Simon task. Canadian Journal of Experimental Psychology/Revue canadienne de psychologie expérimentale, 2006, 60 (1): 68- 79.
	Blacker, K. J., & Curby, K. M. (2013). Enhanced visual short-term memory in action video game players. Attention, Perception, & Psychophysics, 75(6), 1128–1136.
	Braver, T. S., Cohen, J. D., Nystrom, L. E., Jonides, J., Smith, E. E., & Noll, D. C.. A parametric study of prefrontal cortex involvement in human working memory. NeuroImage, 1997, 5 (1): 49- 62. DOI
	Cardoso-Leite, P., Kludt, R., Vignola, G., Ma, W. J., Green, C. S., & Bavelier, D. (2016). Technology consumption and cognitive control: Contrasting action video game experience with media multitasking. Attention, Perception, & Psychophysics, 78(1), 218–241.
	Castel, A. D., Pratt, J., & Drummond, E.. The effects of action video game experience on the time course of inhibition of return and the efficiency of visual search. Acta Psychologica, 2005, 119 (2): 217- 230. DOI
	Chen, Y., & Li, C. S. R. (2022). Striatal gray matter volumes, externalizing traits, and N-back task performance: An exploratory study of sex differences using the human connectome project data. Journal of Experimental Psychopathology, 13(1), 20438087221080056.
	Collette, F., & van der Linden, M.. Brain imaging of the central executive component of working memory. Neuroscience & Biobehavioral Reviews, 2002, 26 (2): 105- 125.
	Colzato, L. S., van den Wildenberg, W. P. M., Zmigrod, S., & Hommel, B.. Action video gaming and cognitive control: Playing first person shooter games is associated with improvement in working memory but not action inhibition. Psychological Research, 2013, 77 (2): 234- 239. DOI
	Cui, X., Bray, S., Bryant, D. M., Glover, G. H., & Reiss, A. L.. A quantitative comparison of NIRS and fMRI across multiple cognitive tasks. NeuroImage, 2011, 54 (4): 2808- 2821. DOI
	Dye, M. W. G., Green, C. S., & Bavelier, D.. Increasing speed of processing with action video games. Current Directions in Psychological Science, 2009, 18 (6): 321- 326. DOI
	Ecker, U. K. H., Lewandowsky, S., Oberauer, K., & Chee, A. E. H. (2010). The components of working memory updating: An experimental decomposition and individual differences. Journal of Experimental Psychology: Learning, Memory, and Cognition, 36(1), 170–189.
	Franceschini, S., Trevisan, P., Ronconi, L., Bertoni, S., Colmar, S., Double, K., ... Gori, S.. Action video games improve reading abilities and visual-to-auditory attentional shifting in English-speaking children with dyslexia. Scientific Reports, 2017, 7 (1): 5863. DOI
	Gong, D. K., He, H., Ma, W. Y., Liu, D. B., Huang, M. T., Dong, L., ... Yao, D. Z.. Functional integration between salience and central executive networks: A role for action video game experience. Neural Plasticity, 2016, 2016, 9803165.
	Green, C. S., & Bavelier, D.. Action video game modifies visual selective attention. Nature, 2003, 423 (6939): 534- 537. DOI
	Green, C. S., & Bavelier, D.. Learning, attentional control, and action video games. Current Biology, 2012, 22 (6): R197- R206. DOI
	Hubert-Wallander, B., Green, C. S., & Bavelier, D. (2011). Stretching the limits of visual attention: The case of action video games. WIREs Cognitive Science, 2(2), 222–230.
	Irak, M., Soylu, C., Sakman, Ö. K., & Turan, G. (2020). ERP correlates of working memory load in excessive video game players. In B. Bostan (Ed.), Game user experience and player-centered design (pp. 3–20). Cham, Switzerland: Springer.
	Izzetoglu, K., Bunce, S., Izzetoglu, M., Onaral, B., & Pourrezaei, K. (2003). fNIR spectroscopy as a measure of cognitive task load. Proceedings of the 25th Annual International Conference of the IEEE Engineering in Medicine and Biology Society. Cancun, Mexico.
	Jonides, J., Schumacher, E. H., Smith, E. E., Lauber, E. J., Awh, E., Minoshima, S., & Koeppe, R. A.. Verbal working memory load affects regional brain activation as measured by PET. Journal of Cognitive Neuroscience, 1997, 9 (4): 462- 475. DOI
	Kane, M. J., Conway, A. R. A., Miura, T. K., & Colflesh, G. J. H. (2007). Working memory, attention control, and the N-back task: A question of construct validity. Journal of Experimental Psychology: Learning, Memory, and Cognition, 33(3), 615–622.
	Kowal, M., Toth, A. J., Exton, C., & Campbell, M. J.. Different cognitive abilities displayed by action video gamers and non-gamers. Computers in Human Behavior, 2018, 88, 255- 262. DOI
	Limelight Networks. (2021). The state of online gaming. Retrieved May 3, 2022, from https://www.limelight.com/lp/state-of-online-gaming-2021/
	Lin, L., Leung, A. W. S., Wu, J. H., & Zhang, L.. Individual differences under acute stress: Higher cortisol responders performs better on N-back task in young men. International Journal of Psychophysiology, 2020, 150, 20- 28. DOI
	Lucas, I., Urieta, P., Balada, F., Blanco, E., & Aluja, A.. Differences in prefrontal cortex activity based on difficulty in a working memory task using near-infrared spectroscopy. Behavioural Brain Research, 2020, 392, 112722. DOI
	McDermott, A. F., Bavelier, D., & Green, C. S.. Memory abilities in action video game players. Computers in Human Behavior, 2014, 34, 69- 78. DOI
	Meule, A.. Reporting and interpreting working memory performance in n-back tasks. Frontiers in Psychology, 2017, 8, 352. DOI
	Moisala, M., Salmela, V., Hietajärvi, L., Carlson, S., Vuontela, V., Lonka, K., ... Alho, K.. Gaming is related to enhanced working memory performance and task-related cortical activity. Brain Research, 2017, 1655, 204- 215. DOI
	Molteni, E., Butti, M., Bianchi, A. M., & Reni, G. (2008). Activation of the prefrontal cortex during a visual n-back working memory task with varying memory load: A near infrared spectroscopy study. 2008 30th Annual International Conference of the IEEE Engineering in Medicine and Biology Society. Vancouver, Canada.
	Morris, N., & Jones, D. M.. Memory updating in working memory: The role of the central executive. British Journal of Psychology, 1990, 81 (2): 111- 121. DOI
	Nikolaidis, A., Voss, M. W., Lee, H., Vo, L. T. K., & Kramer, A. F.. Parietal plasticity after training with a complex video game is associated with individual differences in improvements in an untrained working memory task. Frontiers in Human Neuroscience, 2014, 8, 169.
	Oei, A. C., & Patterson, M. D.. Enhancing cognition with video games: A multiple game training study. PLoS One, 2013, 8 (3): e58546. DOI
	Pelegrina, S., Lechuga, M. T., García-Madruga, J. A., Elosúa, M. R., Macizo, P., Carreiras, M., ... Bajo, M. T.. Normative data on the n-back task for children and young adolescents. Frontiers in Psychology, 2015, 6, 1544.
	Perrot, A., Maillot, P., & Hartley, A.. Cognitive training game versus action videogame: Effects on cognitive functions in older adults. Games for Health Journal, 2019, 8 (1): 35- 40. DOI
	Petrides, M.. The orbitofrontal cortex: Novelty, deviation from expectation, and memory. Annals of the New York Academy of Sciences, 2007, 1121 (1): 33- 53. DOI
	Redick, T. S., Calvo, A., Gay, C. E., & Engle, R. W. (2011). Working memory capacity and go/no-go task performance: Selective effects of updating, maintenance, and inhibition. Journal of Experimental Psychology: Learning, Memory, and Cognition, 37(2), 308–324.
	Richlan, F., Schubert, J., Mayer, R., Hutzler, F., & Kronbichler, M.. Action video gaming and the brain: fMRI effects without behavioral effects in visual and verbal cognitive tasks. Brain and Behavior, 2018, 8 (1): e00877. DOI
	Ruocco, A. C., & Wonders, E.. Delineating the contributions of sustained attention and working memory to individual differences in mindfulness. Personality and Individual Differences, 2013, 54 (2): 226- 230. DOI
	Sala, G., Tatlidil, K. S., & Gobet, F.. Video game training does not enhance cognitive ability: A comprehensive meta-analytic investigation. Psychological Bulletin, 2018, 144 (2): 111- 139. DOI
	Sato, H., Yahata, N., Funane, T., Takizawa, R., Katura, T., Atsumori, H., ... Kasai, K.. A NIRS-fMRI investigation of prefrontal cortex activity during a working memory task. NeuroImage, 2013, 83, 158- 173. DOI
	Schecklmann, M., Ehlis, A. C., Plichta, M. M., Dresler, T., Heine, M., Boreatti-Hümmer, A., ... Fallgatter, A. J.. Working memory and response inhibition as one integral phenotype of adult ADHD? A behavioral and imaging correlational investigation. Journal of Attention Disorders, 2013, 17 (6): 470- 482. DOI
	Spence, I., & Feng, J.. Video games and spatial cognition. Review of General Psychology, 2010, 14 (2): 92- 104. DOI
	Sungur, H., & Boduroglu, A.. Action video game players form more detailed representation of objects. Acta Psychologica, 2012, 139 (2): 327- 334. DOI
	Tanida, M., Sakatani, K., & Tsujii, T.. Relation between working memory performance and evoked cerebral blood oxygenation changes in the prefrontal cortex evaluated by quantitative time-resolved near-infrared spectroscopy. Neurological Research, 2012, 34 (2): 114- 119. DOI
	Taurisano, P., Antonucci, L. A., Fazio, L., Rampino, A., Romano, R., Porcelli, A., ... Blasi, G.. Prefrontal activity during working memory is modulated by the interaction of variation in CB1 and COX2 coding genes and correlates with frequency of cannabis use. Cortex, 2016, 81, 231- 238. DOI
	van Rooij, A. J., Kuss, D. J., Griffiths, M. D., Shorter, G. W., Schoenmakers, T. M., & van de Mheen, D.. The (co-) occurrence of problematic video gaming, substance use, and psychosocial problems in adolescents. Journal of Behavioral Addictions, 2014, 3 (3): 157- 165. DOI
	Villringer, A., & Chance, B.. Non-invasive optical spectroscopy and imaging of human brain function. Trends in Neurosciences, 1997, 20 (10): 435- 442. DOI
	Wang, P., Liu, H. H., Zhu, X. T., Meng, T., Li, H. J., & Zuo, X. N.. Action video game training for healthy adults: A meta-analytic study. Frontiers in Psychology, 2016, 7, 907.
	Waris, O., Jaeggi, S. M., Seitz, A. R., Lehtonen, M., Soveri, A., Lukasik, K. M., ... Laine, M.. Video gaming and working memory: A large-scale cross-sectional correlative study. Computers in Human Behavior, 2019, 97, 94- 103. DOI
	Wilms, I. L., Petersen, A., & Vangkilde, S.. Intensive video gaming improves encoding speed to visual short-term memory in young male adults. Acta Psychologica, 2013, 142 (1): 108- 118. DOI
	Zhang, R. Y., Chopin, A., Shibata, K., Lu, Z. L., Jaeggi, S. M., Buschkuehl, M., ... Bavelier, D.. Author Correction: Action video game play facilitates “learning to learn”. Communications Biology, 2021, 4 (1): 1388. DOI

		反应时(ms)		正确率		效率
		非玩家组	玩家组	非玩家组	玩家组	非玩家组	玩家组
空间任务	0-back	536±128	474±94	0.95±0.06	0.96±0.05	1.85±0.42	2.10±0.45
空间任务	2-back	806±257	655±217	0.91±0.09	0.93±0.05	1.25±0.43	1.56±0.50
言语任务	0-back	609±106	553±82	0.95±0.07	0.95±0.05	1.60±0.27	1.76±0.28
言语任务	2-back	855±257	699±186	0.90±0.08	0.88±0.08	1.14±0.33	1.34±0.35

		反应时(ms)		正确率		效率
		非玩家组	玩家组	非玩家组	玩家组	非玩家组	玩家组
空间任务	0-back	536±128	474±94	0.95±0.06	0.96±0.05	1.85±0.42	2.10±0.45
空间任务	2-back	806±257	655±217	0.91±0.09	0.93±0.05	1.25±0.43	1.56±0.50
言语任务	0-back	609±106	553±82	0.95±0.07	0.95±0.05	1.60±0.27	1.76±0.28
言语任务	2-back	855±257	699±186	0.90±0.08	0.88±0.08	1.14±0.33	1.34±0.35

[1]	Xiani CHEN, Peng ZHANG, Shizhen YAN, Lina JIA, Xiaobo MA, Yifan YU, Hua JIN. The Neural Basis of Spatial Contiguity Effect in Chinese Ancient Poetry: Evidence from fNIRS [J]. Studies of Psychology and Behavior, 2022, 20(6): 760-767.
[2]	CHEN Xianglin, ZHANG Junheng, YAN Bihua. Decoding Effect of Objects of Typical Spatial Position Relations in Real-World Scenes [J]. Studies of Psychology and Behavior, 2022, 20(4): 441-449.
[3]	WANG Jiawei, XIAN Meijun, XING Qiang. The Impact of Task Number and Working Memory Capacity on Interleaving Learning [J]. Studies of Psychology and Behavior, 2022, 20(1): 15-21.
[4]	LIU Tuanli, HAO Xingfeng, XING Min, BAI Xuejun. The Influence of Internet Addiction on Reasoning Ability of College Students: The Mediating Role of Working Memory Capacity [J]. Studies of Psychology and Behavior, 2021, 19(5): 642-649.
[5]	WANG Song, LI Su. The Development of Children’s Story Retelling Skills and Their Relationship with Verbal Working Memory [J]. Studies of Psychology and Behavior, 2020, 18(5): 596-602.
[6]	CHE Xiaowei, WANG Kaixuan, SHANGGUAN Mengqi, LI Shouxin. The Representation of Attention Template in Visual Working Memory: An EROS Study [J]. Studies of Psychology and Behavior, 2020, 18(3): 297-303.
[7]	TANG Dandan, FU Yu, WU Yanjing, ZHU Hai. Neural Mechanisms of Group Differences in Visuospatial Working Memory [J]. Studies of Psychology and Behavior, 2020, 18(2): 176-184.
[8]	WU Guolai, ZHANG Jingjing, REN Fangyuan, YANG Jingjing, JIU Yanhong. Association Between Working Memory Capacity and Mind Wandering Frequency: A Systematic Review and Meta-analysis [J]. Studies of Psychology and Behavior, 2019, 17(4): 461-471.
[9]	BAI Xuejun, ZHANG Qihan, ZHAO Guang, SUN Hongjin, CHEN Yixin, SUN Shinan, ZHANG Peng, SONG Lu, YANG Yu, YUAN Sheng. The Cognitive and Neural Mechanisms of Obstacle Affecting Individual Motion in Continuous Reach Motion [J]. Studies of Psychology and Behavior, 2019, 17(2): 145-152.
[10]	ZHANG Xin, SONG Jintao, YING Ronghua, ZHOU Renlai. Is Effectiveness of Working Memory Training the Result of Placebo Effect? [J]. Studies of Psychology and Behavior, 2019, 17(2): 170-177.
[11]	YANG Haibo, NIU Lili, YIN Shasha, BAI Xuejun. Attention Capture was Guided by the Contents of Non-semantic Coding Visual Working Memory: Evidence from ERPs [J]. Studies of Psychology and Behavior, 2019, 17(1): 8-14.
[12]	ZONG Zheng, LI Hongxia, SI Jiwei. Mental Arithmetic Performance of Children with Different Approximate Number System Acuity: Effect of Mental Arithmetic Forms [J]. Studies of Psychology and Behavior, 2018, 16(4): 505-511.
[13]	TAN Ke, MA Jie, LIAN Kunyu, GUO Zhiying, BAI Xuejun. Verbal Working Memory and Reading Ability of Chinese Children with Double-deficit Developmental Dyslexia [J]. Studies of Psychology and Behavior, 2018, 16(3): 308-314,354.
[14]	LIU Hanjunlan, ZHAO Shouying, GUO haihui. The Influence of Visual Working Memory on Attentional Control in Basketball [J]. Studies of Psychology and Behavior, 2018, 16(3): 315-320.
[15]	KONG Haiyan, SUN Yu, SONG Guangwen. Influence of Mind Wandering and Working Memory on Junior High School Students' Reading Comprehension [J]. Studies of Psychology and Behavior, 2018, 16(3): 362-370,377.