Dragon and lion dance is an important part of Chinese culture, which plays an important role in carrying forward the excellent traditional culture and implementing the strategy of sports power. The traditional dragon and lion dance equipment in the selection of materials is more casual, there are many deficiencies. At present, under the background of modern sports, higher requirements are put forward for the equipment selection of dragon and lion dance. At present, the mainstream approach is to integrate nano material technology. However, due to the characteristics of nano particles, nano materials pose a potential health threat to human body. Therefore, this paper puts forward the application of nano materials in dragon and lion dance exercise and its biological safety research. Through the study of basic theory and core concepts, this paper believes that the application of nano materials in competitive sports will have a direct impact on sports performance. According to the demand characteristics of dragon and lion dance, nano materials will be widely used in this field, and can effectively improve the comprehensive performance of sports equipment, optimize the experience and comfort. In view of the possible health threat of nano materials to human body, this paper established the corresponding experimental scheme of biological safety detection of nano materials. The experimental scheme adopts the way of animal model, which can better restore the use of human body. A number of comparative experiments including hemolysis rate test, cytotoxicity test, bacteriostatic rate and relative cell proliferation rate were carried out. Through the analysis of experimental data, it can be seen that nano materials have no toxicity, hemolysis and other reactions in the normal use process, and have good biological safety. The research in this paper has achieved ideal results and made a contribution to the biosafety research of nanomaterials.

Manollin Kautish. Application and Biological Safety of Nano Materials in Dragon and Lion Dance. International Journal of Art Innovation and Development (2022), Vol. 3, Issue 4: 14-27. https://doi.org/10.38007/IJAID.2022.030402.

[1] Tao Zhichao. (2018). Status investigation and analysis on dragon and lion dance in secondary vocational schoolsr——take shanghai science and technology management school as an example. Sports Science and Technology Literature Bulletin, 026 (004), 113-115.

[2] Ma Qing. (2017). Chinese dragon and lion dance music athletic investigation issues. Sports Science Research, 021 (002), 73-76.

[3] Li Moutao, & Li Changjun. (2015). A research on the way to cultivate students' learning interest during dragon and lion dance teaching. Journal of Huangshan University, 017 (005), 110-113.

[4] Zhang Shujun. (2018). Research on the status quo and development of dragon dance and lion dance in Wuxi Vocational and Technical College of Commerce. Fight•Martial Arts Science, 003 (010), 104-108.

[5] Chen Aimin. (2018). Visual analysis of dragon and lion dance research based on knowledge graphs. Journal of Gansu Lianhe University (Natural Science Edition), 032 (001), 98-101.

[6] Zhang Ying. (2019). On integration of lion dance and square dance in interactive communication of urban and rural cultures. Journal of Changchun University (Natural Science Edition), 029 (002), 93-96.

[7] Liu Weijun. (2019). Study on the inheritance and development of south lion dance in guangxi from the perspective of national fitness. Journal of Yulin Teachers College, 040 (001), 68-72.

[8] Yang Guangbo, & Mo Fei. (2017). The origins of the traditional lion dance in south fujian and social value of research. Sports Science Research, 021 (004), 8-11.

[9] Wang Xiaochen, Sun Qingbin, Niu Peilin, Song Yongzhong, & Tian Haijun. (2019). Cultural connotation and transmission metaphor of the south lion dance. Journal of Yulin Teachers College, 040 (001), 48-53.

[10] Niu Peilin, Wang Xiaochen, & Sun Qingbin. (2019). Problems and countermeasures in the training of south lion dance talents. Journal of Yulin Normal University, 040 (001), 54-58.

[11] Yin, C., Negreiros, F. R., Barcaro, G., Beniya, A., Sementa, L., & Tyo, E. C., et al. (2017). Alumina-supported sub-nanometer pt10 clusters: amorphization and role of the support material in a highly active co oxidation catalyst. Journal of Materials Chemistry A, 5(10), 4923-4931.https://doi.org/10.1039/C6TA10989F

[12] Hu, Bin, He, Man, & Chen, Beibei. (2015). Nanometer-sized materials for solid-phase extraction of trace elements. Analytical & Bioanalytical Chemistry, 407(10), 2685-2710.https://doi.org/10.1007/s00216-014-8429-9

[13] Li Cuimei, Hou Yuze, Hou Yuyi, Liu Xiuju, & Zhang Hongmin. (2017). Thermal cycling studies of nanometer silver soft liner material properties. Research on Trace Elements and Health, 034 (003), 1-3.

[14] Wang Zhiyuan, Shen Xu, Yu Juan, Gu Heping, Wang Xiaodong, & Huang Pei. (2015). Friction and wear performance of nanometer carbon black/polyimide composite material. Journal of Nanjing University of Technology (Natural Science Edition), 037 (002), 28 -32.

[15] Zhang, B., Cao, X., Jiang, W., Liu, L., & Li, F. (2015). Grey clustering analysis-based tennis racket of nanometer materials kinematic mechanics applied research. Journal of Computational & Theoretical Nanoence, 12(10), 3218-3222.https://doi.org/10.1166/jctn.2015.4104