DOI: 10.3724/SP.J.1041.2017.01370

Acta Psychologica Sinica (心理学报) 2017/49:11 PP.1370-1382

Right hemispheric dominance in forming novel semantic associations

Forming novel associations is one of the key subprocesses in creative thinking. According to the generation-selection model of creativity and the theory of coarse semantic coding in right hemisphere, the right brain may play a dominating role in forming novel associations. However, this inference is only supported by half of the neuroimaging studies, and the others emphasize the role of left hemisphere or both. The disagreement among previous studies might result from different materials and different task requirements they used. The right hemispheric dominance in forming novel semantic associations may be more easily detected in the tasks of comprehending creative language. In the current study, the Chinese two-part allegorical sayings as well as fMRI and ERPs were used to explore the temporal and spatial features of neural processing in forming novel semantic associations.
Two experiments were conducted in this study. In Experiment 1, participants were asked to read silently some Chinese two-part allegorical sayings and keep them in mind. For half of the experimental materials, the semantic association between the two parts was novel, while for the other half, it was normal. The neural activity was recorded by fMRI. In Experiment 2, the experimental materials were similar with those in Experiment 1, except for some filling materials in which there was not semantic association between the two parts. Participants were asked to judge whether the first part was associated with the second part in meaning, and the neural activity was recorded by ERP.
The result of Experiment 1 showed that compared with normal semantic association, novel semantic association activated more in right superior temporal gyrus, which was related to the retrieval of novel semantic information. Results of Experiment 2 showed that novel semantic association induced a more positive late positive component (650~900 ms after the onset of target words) over the right temporal sites and right frontal sites, which might reflect the retrieval as well as selection and integration of novel semantic information respectively.
In summary, the current results support the right hemispheric dominance in forming novel semantic associations, and indicate that its timing may be at the late period of processing.

Key words:novel semantic association,creative thinking,Chinese two-part allegorical sayings,Right hemispheric dominance,late positive component

ReleaseDate:2017-12-29 15:49:10

Abraham, A., Pieritz, K., Thybusch, K., Rutter, B., Kröger, S., Schweckendiek, J.,... Hermann, C. (2012). Creativity and the brain:Uncovering the neural signature of conceptual expansion. Neuropsychologia, 50, 1906-1917.

Ahrens, K., Liu, H. L., Lee, C. Y., Gong, S. P., Fang, S. Y., & Hsu, Y. Y. (2007). Functional MRI of conventional and anomalous metaphors in Mandarin Chinese. Brain and Language, 100, 163-171.

Aziz-Zadeh, L., Liew, S. L., & Dandekar, F. (2013). Exploring the neural correlates of visual creativity. Social Cognitive and Affective Neuroscience, 8, 475-480.

Beeman, M., Friedman, R. B., Grafman, J., Perez, E., Diamond, S., & Lindsay, M. B. (1994). Summation priming and coarse semantic coding in the right hemisphere. Journal of Cognitive Neuroscience, 6, 26-45.

Beeman, M. J., & Bowden, E. M. (2000). The right hemisphere maintains solution-related activation for yet-to-be-solved problems. Memory & Cognition, 28, 1231-1241.

Benedek, M., Beaty, R., Jauk, E., Koschutnig, K., Fink, A., Silvia, P. J.,... Neubauer, A. C. (2014). Creating metaphors:The neural basis of figurative language production. NeuroImage, 90, 99-106.

Bink, M. L., & Marsh, R. L. (2000). Cognitive regularities in creative activity. Review of General Psychology, 4, 59-78.

Bookheimer, S. (2002). Functional MRI of language:New approaches to understanding the cortical organization of semantic processing. Annual Review of Neuroscience, 25, 151-188.

Brouwer, H., Fitz, H., & Hoeks, J. (2012). Getting real about semantic illusions:Rethinking the functional role of the P600 in language comprehension. Brain Research, 1446, 127-143.

Brouwer, H., & Hoeks, J. C. J. (2013). A time and place for language comprehension:Mapping the N400 and the P600 to a minimal cortical network. Frontiers in Human Neuroscience, 7, 758

Galuske, R. A. W., Schlote, W., Bratzke, H., & Singer, W. (2000). Interhemispheric asymmetries of the modular structure in human temporal cortex. Science, 289, 1946-1949.

Giora, R. (1997). Understanding figurative and literal language:The graded salience hypothesis. Cognitive Linguistics, 8, 183-206.

Hagoort, P., Hald, L., Bastiaansen, M., & Petersson, K. M. (2004). Integration of word meaning and world knowledge in language comprehension. Science, 304, 438-441.

Huang, F. R., Fan, J., & Luo, J. (2015). The neural basis of novelty and appropriateness in processing of creative chunk decomposition. NeuroImage, 113, 122-132.

Hutsler, J., & Galuske, R. A. W. (2003). Hemispheric asymmetries in cerebral cortical networks. Trends Neurosciences, 26, 429-435.

Jung-Beeman, M. (2005). Bilateral brain processes for comprehending natural language. Trends in Cognitive Sciences, 9, 512-518.

Jung-Beeman, M., Bowden, E. M., Haberman, J., Frymiare, J. L., Arambel-Liu, S., Greenblatt, R.,... Kounios, J. (2004). Neural activity when people solve verbal problems with insight. PLoS Biology, 2, e97.

Kaping, D., Vinck, M., Hutchison, R. M., Everling, S., & Womelsdorf, T. (2011). Specific contributions of ventromedial, anterior cingulate, and lateral prefrontal cortex for attentional selection and stimulus valuation. PLoS Biology, 9, e1001224.

Kenett, Y. N., Anaki, D., & Faust, M. (2015). Processing of unconventional stimuli requires the recruitment of the non-specialized hemisphere. Frontiers in Human Neuroscience, 9, 32.

Knutson, K. M., Wood, J. N., & Grafman, J. (2004). Brain activation in processing temporal sequence:An fMRI study. NeuroImage, 23, 1299-1307.

Kröger, S., Rutter, B., Stark, R., Windmann, S., Hermann, C., & Abraham, A. (2012). Using a shoe as a plant pot:Neural correlates of passive conceptual expansion. Brain Research, 1430, 52-61.

Luks, T. L., Simpson, G. V., Feiwell, R. J., & Miller, W. L. (2002). Evidence for anterior cingulate cortex involvement in monitoring preparatory attentional set. NeuroImage, 17, 792-802.

Luo, J., & Niki, K. (2003). Function of hippocampus in "insight" of problem solving. Hippocampus, 13, 316-323.

Luo, J., & Niki, K. (2005). Does hippocampus associate discontiguous events? Evidence from event-related fMRI. Hippocampus, 15, 141-148.

MacDonald, A. W., Cohen, J. D., Stenger, V. A., & Carter, C. S. (2000). Dissociating the role of the dorsolateral prefrontal and anterior cingulate cortex in cognitive control. Science, 288, 1835-1838.

Mai, X. Q., Luo, J., Wu, J. H., & Luo, Y. J. (2004). "Aha!" effects in a guessing riddle task:An event-related potential study. Human Brain Mapping, 22, 261-270.

Mashal, N., Faust, M., Hendler, T., & Jung-Beeman, M. (2007). An fMRI investigation of the neural correlates underlying the processing of novel metaphoric expressions. Brain and Language, 100, 115-126.

Mashal, N., Faust, M., Hendler, T., & Jung-Beeman, M. (2008). Hemispheric differences in processing the literal interpretation of idioms:Converging evidence from behavioral and fMRI studies. Cortex, 44, 848-860.

Mayseless, N., & Shamay-Tsoory, S. G. (2015). Enhancing verbal creativity:Modulating creativity by altering the balance between right and left inferior frontal gyrus with tDCS. Neuroscience, 291, 167-176.

Mednick, S. (1962). The associative basis of the creative process. Psychological Review, 69, 220-232.

Miller, E. K., & Cohen, J. D. (2001). An integrative theory of prefrontal cortex function. Annual Review of Neuroscience, 24, 167-202.

Ohlsson, S. (2011). Deep learning:How the mind overrides experience. New York:Cambridge University Press.

Pobric, G., Mashal, N., Faust, M., & Lavidor, M. (2008). The role of the right cerebral hemisphere in processing novel metaphoric expressions:A transcranial magnetic stimulation study. Journal of Cognitive Neuroscience, 20, 170-181.

Qiu, J., Li, H., Jou, J., Liu, J., Luo, Y. J., Feng, T. Y.,... Zhang, Q. L. (2010). Neural correlates of the "Aha" experiences:Evidence from an fMRI study of insight problem solving. Cortex, 46, 397-403.

Qiu, J., Li, H., Luo, Y. J., Chen, A. T., Zhang, F. H., Zhang, J. M.,... Zhang, Q. L. (2006). Brain mechanism of cognitive conflict in a guessing Chinese logogriph task. Neuroreport, 17, 679-682.

Qiu, J., & Zhang, Q. L. (2008). "Aha!" effects in a guessing Chinese logogriph task:An event-related potential study. Chinese Science Bulletin, 53, 384-391.

Ragland, J. D., Ranganath, C., Phillips, J., Boudewyn, M. A., Kring, A. M., Lesh, T. A.,... Carter, C. S. (2015). Cognitive control of episodic memory in Schizophrenia:Differential role of dorsolateral and ventrolateral prefrontal cortex. Frontiers in Human Neuroscience, 9, 604.

Redish, A. D. (2001). The hippocampal debate:Are we asking the right questions? Behavioural Brain Research, 127, 81-98.

Shen, W. B., Liu, C., Yuan, Y., Zhang, X. J., & Luo, J. (2013). Temporal dynamics of mental impasses underlying insight-like problem solving. Science China Life Sciences, 56, 284-290.[沈汪兵, 刘昌, 袁媛, 张小将, 罗劲. (2013). 顿悟类问题解决中思维僵局的动态时间特性. 中国科学:生命科学, 43, 254-262.]

Shen, W. B., Liu, C., Zhang, X. J., & Chen, Y. L. (2011). The time course and hemispheric effect of "insight" in three-character Chinese riddles task:An ERP study. Acta Psychologica Sinica, 43, 229-240.[沈汪兵, 刘昌, 张小将, 陈亚林. (2011). 三字字谜顿悟的时间进程和半球效应:一项ERP研究. 心理学报, 43, 229-240.]

Shen, W. B., Liu, C., Zhang, X. J., Zhao, X. J., Zhang, J., Yuan, Y., & Chen, Y. L. (2013). Right hemispheric dominance of creative insight:An event-related potential study. Creativity Research Journal, 25, 48-58.

Shen, W. B., Yuan, Y., Liu, C., Zhang, X. J., Luo, J., & Gong, Z. (2016). Is creative insight task-specific? A coordinate-based meta-analysis of neuroimaging studies on insightful problem solving. International Journal of Psychophysiology, 110, 81-90.

Subramaniam, K., Kounios, J., Parrish, T. B., & Jung-Beeman, M. (2009). A brain mechanism for facilitation of insight by positive affect. Journal of Cognitive Neuroscience, 21, 415-432.

Tang, X. M., Qi, S. Q., Wang, B. T., Jia, X. J., & Ren, W. (2017). The temporal dynamics underlying the comprehension of scientific metaphors and poetic metaphors. Brain Research, 1655, 33-40.

Vandenberghe, R., Price, C., Wise, R., Josephs, O., & Frackowiak, R. S. J. (1996). Functional anatomy of a common semantic system for words and pictures. Nature, 383, 254-256.

Wagner, A. D., Paré-Blagoev, E. J., Clark, J., & Poldrack, R. A. (2001). Recovering meaning:Left prefrontal cortex guides controlled semantic retrieval. Neuron, 31, 329-338.

Wang, X. L. (2007). Neural mechanism of Chinese metaphorial cognition (Unpublished doctorial dissertation). Zhejiang University.[王小潞. (2007). 汉语隐喻认知的神经机制研究(博士学位论文). 浙江大学.]

Whitman, R. D., Holcomb, E., & Zanes, J. (2010). Hemispheric collaboration in creative subjects:Cross-hemisphere priming in a lexical decision task. Creativity Research Journal, 22, 109-118.

Wu, L., Knoblich, G., & Luo, J. (2013). The role of chunk tightness and chunk familiarity in problem solving:Evidence from ERPs and fMRI. Human Brain Mapping, 34, 1173-1186.

Xing, Q., Zhang, Z. L., Wang, M. R., Zhang, J. L., Wang, J., Yao, Y. F., & Zhan, D. L. (2013). The electrophysiological mechanisms of constraint relaxation studied with a Chinese logogriph task. Acta Psychologica Sinica, 45, 508-516.[邢强, 张忠炉, 王梦偌, 张金莲, 王菁, 姚艳芬, 占丹玲. (2013). 汉字字谜任务中限制解除的电生理机制. 心理学报, 45, 508-516.]

Yang, J. (2014). The role of the right hemisphere in metaphor comprehension:A meta-analysis of functional magnetic resonance imaging studies. Human Brain Mapping, 35, 107-122.

Zhang, M., Tian, F., Wu, X., Liao, S., & Qiu, J. (2011). The neural correlates of insight in Chinese verbal problems:An event related-potential study. Brain Research Bulletin, 84, 210-214.

Zhang, Q. L., Qiu, J., & Cao, G. K. (2004). A review and hypothesis about the cognitive mechanism of insight. Psychological Science, 27, 1435-1437.[张庆林, 邱江, 曹贵康. (2004). 顿悟认知机制的研究述评与理论构想. 心理科学, 27, 1435-1437.]

Zhao, Q. B., Ke, W., Tong, B., Zhou, Z. J., & Zhou, Z. K. (2017). Creative processing of internet language:Novel N400 and LPC. Acta Psychologica Sinica, 49, 143-154.[赵庆柏, 柯娓, 童彪, 周治金, 周宗奎. (2017). 网络语言的创造性加工过程:新颖N400与LPC. 心理学报, 49, 143-154.]

Zhao, Q. B., Li, S. Q., Chen, S., Zhou, Z. J., & Cheng, L. (2015). Dynamic neural processing mode of creative problem solving. Advances in Psychological Science, 23, 375-384.[赵庆柏, 李松清, 陈石, 周治金, 成良. (2015). 创造性问题解决的动态神经加工模式. 心理科学进展, 23, 375-384.]

Zhao, Q. B., Li, Y., Shang, X. L., Zhou, Z. J., & Han, L. (2014). Uniformity and nonuniformity of neural activities correlated to different insight problem solving. Neuroscience, 270, 203-211.

Zhao, Q. B., Zhou, Z. J., Xu, H. B., Chen, S., Xu, F., Fan, W. L., & Han, L. (2013). Dynamic neural network of insight:A functional magnetic resonance imaging study on solving Chinese ‘chengyu’ riddles. PLoS One, 8, e59351.

Zhao, Q. B., Zhou, Z. J., Xu, H. B., Fan, W. L., & Han, L. (2014). Neural pathway in the right hemisphere underlies verbal insight problem solving. Neuroscience, 256, 334-341.

Zhu, Z. D., Feng, G. Y., Zhang, J. X., Li, G. C., Li, H., & Wang, S. P. (2013). The role of the left prefrontal cortex in sentence-level semantic integration. NeuroImage, 76, 325-331.