踏步任务下动作同步的神经基础
收稿日期: 2022-05-17
网络出版日期: 2023-11-10
基金资助
教育部人文社会科学研究青年基金项目(21YJC890019)
版权
Neural Basis of Motor Coordination in Stepping Tasks
Received date: 2022-05-17
Online published: 2023-11-10
Copyright
动作同步在人际关系的建立过程中起着重要作用。以往的动作同步研究大多涉及单个肢体/物体,本研究设置需要双侧肢体协调的踏步任务,使用近红外超扫描技术同步采集互动双方的大脑活动,探究单人协调与动作同步(同相和反相)的大脑激活方式以及行为方面的差异。结果发现,在双侧下顶叶单人协调的神经激活显著高于同相模式和反相模式,表明下顶叶可能是动作同步的重要神经基础。
关键词: 动作同步; 功能性近红外光学成像技术; 超扫描
刘蕾 , 李亚楠 , 牛若愚 , 于文婷 , 陈玉雪 , 刘莹 . 踏步任务下动作同步的神经基础[J]. 心理与行为研究, 2023 , 21(5) : 600 -607 . DOI: 10.12139/j.1672-0628.2023.05.004
Motor coordination plays a crucial role in the establishment of social interactions. Previous studies have focused on single-limb coordination, neglecting two-limb coordination. The current study adopted a novel experimental paradigm, a bilateral stepping task of different modes (in-phase/anti-phase) when two participants performed the stepping coordination. In addition to behavioral performance, the brain activity of both interacting parties was simultaneously recorded by using the fNIRS hyperscanning. The results revealed stronger neural activity in certain regions of interest (corresponding to the bilateral inferior parietal lobule) during intra-individual coordination as compared to inter-individual coordination for both in-phase and anti-phase patterns. Therefore, the inferior parietal lobule may be potentially the critical neural basis for motor coordination.
Key words: motor coordination; fNIRS; hyperscanning
| Aramaki, Y., Honda, M., Okada, T., & Sadato, N.. Neural correlates of the spontaneous phase transition during bimanual coordination. Cerebral Cortex, 2006, 16 (9): 1338- 1348. | |
| Cope, M., Delpy, D. T., Reynolds, E. O. R., Wray, S., Wyatt, J., & van der Zee, P. (1988). Methods of quantitating cerebral near infrared spectroscopy data. In M. Mochizuki, C. R. Honig, T. Koyama, T. K. Goldstick, & D. F. Bruley (Eds.), Oxygen transport to tissue X (pp. 183–189). New York: Springer. | |
| Crone, C. L., Rigoli, L. M., Patil, G., Pini, S., Sutton, J., Kallen, R. W., & Richardson, M. J.. Synchronous vs. non-synchronous imitation: Using dance to explore interpersonal coordination during observational learning. Human Movement Science, 2021, 76, 102776. | |
| De Pretto, M., Deiber, M. P., & James, C. E.. Steady-state evoked potentials distinguish brain mechanisms of self-paced versus synchronization finger tapping. Human Movement Science, 2018, 61, 151- 166. | |
| Delaherche, E., Chetouani, M., Mahdhaoui, A., Saint-Georges, C., Viaux, S., & Cohen, D.. Interpersonal synchrony: A survey of evaluation methods across disciplines. IEEE Transactions on Affective Computing, 2012, 3 (3): 349- 365. | |
| Dolk, T., & Prinz, W. (2016). What it takes to share a task: Sharing versus shaping task representations. In S. S. Obhi & E. S. Cross (Eds.), Shared representations: Sensorimotor foundations of social life (pp. 3–21). Cambridge: Cambridge University Press. | |
| Ebisch, S. J. H., Ferri, F., Romani, G. L., & Gallese, V.. Reach out and touch someone: Anticipatory sensorimotor processes of active interpersonal touch. Journal of Cognitive Neuroscience, 2014, 26 (9): 2171- 2185. | |
| Feng, X. D., Sun, B. H., Chen, C. S., Li, W. J., Wang, Y., Zhang, W. H., ... Shao, Y. T.. Self-other overlap and interpersonal neural synchronization serially mediate the effect of behavioral synchronization on prosociality. Social Cognitive and Affective Neuroscience, 2020, 15 (2): 203- 214. | |
| Fogassi, L., Ferrari, P. F., Gesierich, B., Rozzi, S., Chersi, F., & Rizzolatti, G.. Parietal lobe: From action organization to intention understanding. Science, 2005, 308 (5722): 662- 667. | |
| Haberstumpf, S., Seidel, A., Lauer, M., Polak, T., Deckert, J., & Herrmann, M. J.. Reduced parietal activation in participants with mild cognitive impairments during visual-spatial processing measured with functional near-infrared spectroscopy. Journal of Psychiatric Research, 2022, 146, 31- 42. | |
| Hu, Y., Hu, Y. Y., Li, X. C., Pan, Y. F., & Cheng, X. J.. Brain-to-brain synchronization across two persons predicts mutual prosociality. Social Cognitive and Affective Neuroscience, 2017, 12 (12): 1835- 1844. | |
| J?ncke, L., Loose, R., Lutz, K., Specht, K., & Shah, N. J.. Cortical activations during paced finger-tapping applying visual and auditory pacing stimuli. Cognitive Brain Research, 2000, 10 (1?2): 51- 66. | |
| Kelso, J. A. S. (1995). Dynamic patterns: The self-organization of brain and behavior. London: MIT Press. | |
| Kim, S. G., Jennings, J. E., Strupp, J. P., Andersen, P., & U?urbil, K.. Functional MRI of human motor cortices during overt and imagined finger movements. International Journal of Imaging Systems and Technology, 1995, 6 (2?3): 271- 279. | |
| Knoblich, G., Butterfill, S., & Sebanz, N.. Psychological research on joint action: Theory and data. Psychology of Learning and Motivation, 2011, 54, 59- 101. | |
| Koike, T., Tanabe, H. C., & Sadato, N.. Hyperscanning neuroimaging technique to reveal the “two-in-one” system in social interactions. Neuroscience Research, 2015, 90, 25- 32. | |
| Kokal, I., Engel, A., Kirschner, S., & Keysers, C.. Synchronized drumming enhances activity in the caudate and facilitates prosocial commitment-if the rhythm comes easily. PLoS One, 2011, 6 (11): e27272. | |
| Lafleur, M. F., Jackson, P. L., Malouin, F., Richards, C. L., Evans, A. C., & Doyon, J.. Motor learning produces parallel dynamic functional changes during the execution and imagination of sequential foot movements. NeuroImage, 2002, 16 (1): 142- 157. | |
| Liu, T., Saito, H., & Oi, M.. Role of the right inferior frontal gyrus in turn-based cooperation and competition: A near-infrared spectroscopy study. Brain and Cognition, 2015, 99, 17- 23. | |
| Ma, Y., Lee, E. W. M., Shi, M., & Yuen, R. K. K.. Spontaneous synchronization of motion in pedestrian crowds of different densities. Nature Human Behaviour, 2021, 5 (4): 447- 457. | |
| Marsh, K. L., Richardson, M. J., & Schmidt, R. C.. Social connection through joint action and interpersonal coordination. Topics in Cognitive Science, 2009, 1 (2): 320- 339. | |
| Mayville, J. M., Jantzen, K. J., Fuchs, A., Steinberg, F. L., & Kelso, J. A. S.. Cortical and subcortical networks underlying syncopated and synchronized coordination revealed using fMRI. Human Brain Mapping, 2002, 17 (4): 214- 229. | |
| Meyer, M., van der Wel, R. P. D., & Hunnius, S.. Higher-order action planning for individual and joint object manipulations. Experimental Brain Research, 2013, 225 (4): 579- 588. | |
| Niu, R. Y., Yu, Y. L., Li, Y. N., & Liu, Y.. Use of fNIRS to characterize the neural mechanism of inter-individual rhythmic movement coordination. Frontiers in Physiology, 2019, 10, 781. | |
| Nozawa, T., Sakaki, K., Ikeda, S., Jeong, H., Yamazaki, S., Kawata, K., ... Kawashima, R.. Prior physical synchrony enhances rapport and inter-brain synchronization during subsequent educational communication. Scientific Reports, 2019, 9 (1): 12747. | |
| Okamoto, M., Dan, H., Sakamoto, K., Takeo, K., Shimizu, K., Kohno, S., ... Dan, I.. Three-dimensional probabilistic anatomical cranio-cerebral correlation via the international 10–20 system oriented for transcranial functional brain mapping. NeuroImage, 2004, 21 (1): 99- 111. | |
| Okamoto, M., Tsuzuki, D., Clowney, L., Dan, H., Singh, A. K., & Dan, I.. Structural atlas-based spatial registration for functional near-infrared spectroscopy enabling inter-study data integration. Clinical Neurophysiology, 2009, 120 (7): 1320- 1328. | |
| Richardson, M. J., Marsh, K. L., Isenhower, R. W., Goodman, J. R. L., & Schmidt, R. C.. Rocking together: Dynamics of intentional and unintentional interpersonal coordination. Human Movement Science, 2007, 26 (6): 867- 891. | |
| Richardson, M. J., Marsh, K. L., & Schmidt, R.. Effects of visual and verbal interaction on unintentional interpersonal coordination. Journal of Experimental Psychology: Human Perception and Performance, 2005, 31 (1): 62- 79. | |
| Rizzolatti, G., Fogassi, L., & Gallese, V.. Neurophysiological mechanisms underlying the understanding and imitation of action. Nature Reviews Neuroscience, 2001, 2 (9): 661- 670. | |
| Schippers, M. B., Roebroeck, A., Renken, R., Nanetti, L., & Keysers, C.. Mapping the information flow from one brain to another during gestural communication. Proceedings of the National Academy of Sciences of the United States of America, 2010, 107 (20): 9388- 9393. | |
| Schmidt, R. C., & Richardson, M. J. (2008). Dynamics of interpersonal coordination. In A. Fuchs, & V. K. Jirsa (Eds.), Coordination: Neural, behavioral and social dynamics (pp. 281–308). Berlin, Germany: Springer. | |
| Sebanz, N., Bekkering, H., & Knoblich, G.. Joint action: Bodies and minds moving together. Trends in Cognitive Sciences, 2006, 10 (2): 70- 76. | |
| Singer, T.. The past, present and future of social neuroscience: A European perspective. NeuroImage, 2012, 61 (2): 437- 449. | |
| Strangman, G., Culver, J. P., Thompson, J. H., & Boas, D. A.. A quantitative comparison of simultaneous BOLD fMRI and NIRS recordings during functional brain activation. NeuroImage, 2002, 17 (2): 719- 731. | |
| Tomasello, M., Carpenter, M., Call, J., Behne, T., & Moll, H.. In search of the uniquely human. Behavioral and Brain Sciences, 2005, 28 (5): 721- 735. | |
| Tsuzuki, D., Jurcak, V., Singh, A. K., Okamoto, M., Watanabe, E., & Dan, I.. Virtual spatial registration of stand-alone fNIRS data to MNI space. NeuroImage, 2007, 34 (4): 1506- 1518. | |
| Tyszka, J. M., Grafton, S. T., Chew, W., Woods, R. P., & Colletti, P. M.. Parceling of mesial frontal motor areas during ideation and movement using functional magnetic resonance imaging at 1.5 tesla. Annals of Neurology, 1994, 35 (6): 746- 749. | |
| van Dijk, J., Kerkhofs, R., van Rooij, I., & Haselager, P. (2008). Special section: Can there be such a thing as embodied embedded cognitive neuroscience? Theory & Psychology, 18(3), 297–316. | |
| van Ulzen, N. R., Lamoth, C. J. C., Daffertshofer, A., Semin, G. R., & Beek, P. J.. Characteristics of instructed and uninstructed interpersonal coordination while walking side-by-side. Neuroscience Letters, 2008, 432 (2): 88- 93. | |
| Wolpert, D. M., Doya, K., & Kawato, M.. A unifying computational framework for motor control and social interaction. Philosophical Transactions of the Royal Society B: Biological Sciences, 2003, 358 (1431): 593- 602. |
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