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| Application of Fluorescent Probe Tetraphenyl-1,3-Butadiene in the Detection of Antibiotics |
| WANG Rui1, ZHENG Lu-ying1, HU Bo1, ZHANG Xin-yu2, ZHAO Si-si1*, ZHANG Hang1* |
1. College of Chemistry and Chemical Engineering, Shenyang Normal University, Shenyang 110034, China
2. Center for Intelligent and Biomimetic Systems, Shenzhen Institute of Advanced Technology, Chinese Academy of Sciences, Shenzhen 518055, China
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Abstract Antibiotics have the advantages of strong antibacterial activity and low cost and have been widely used in production and daily life. However, the abuse of antibiotics may lead to their accumulation in the human body or food, causing public health problems such as ototoxicity, nephrotoxicity, allergic reactions, and bacterial resistance. Therefore, this article selects fluorescence detection techniques with advantages such as high sensitivity, good selectivity, simple preparation, fast speed, and practical sample detection, which are significant for improving food safety and rational drug use. Based on the application of fluorescence technology in detecting antibiotics, this article selects tetraphenyl-1,3-butadiene (TPB), a typical representative with AIE effect, which has advantages such as stable chemical properties, good luminescence performance and is not limited by solution conditions. It is made into a fluorescence probe to explore the photochemical properties of TPB and the impact of antibiotics on its quenching effect. The research results show that the maximum excitation wavelength of TPB is 365 nm, and the maximum emission wavelength is 435 nm. TPB has strong fluorescence characteristics. At an excitation wavelength of 365 nm, the quantum yield of TPB is 51.9%. When the water volume fraction is 80%, the fluorescence effect of TPB is the best. The fluorescent probe TPB has high selectivity and strong anti-interference ability to tetracycline antibiotics. Tetracycline antibiotics have a high quenching effect on TPB, which meets the condition of fluorescence internal filtering effect, while sulfonamides and quinolones have a poor quenching effect on TPB. The fluorescence intensity of the system decreases with the increase of tetracycline hydrochloride concentration, and there is a strong correlation. The linear regression equation is y=-1.338x+984.20, and the detection limit is 0.042 7 mmol·L-1; When pH≤7, the quenching effect is better; After adding tetracycline hydrochloride solution, the fluorescence intensity of the lake water, sea water and milk system was significantly weakened, and the change of the fluorescence intensity could indirectly reflect the change of the concentration of tetracycline antibiotics solution. This article explores the quenching of TPB by antibiotics, and the detection of antibiotic residues in the environment and food is of great significance, providing a reference for human governance of residual antibiotics in the food and environment.
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Received: 2023-01-28
Accepted: 2023-04-26
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Corresponding Authors:
ZHAO Si-si, ZHANG Hang
E-mail: zhaoss0905@163.com;zhangh1711@163.com
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[1] Liu P, Zhang Y, Zhang Z Y, et al. Genes, 2023, 14: 1423.
[2] Rusu A, Buta E L. Pharmaceutics, 2021, 13(12): 2085.
[3] Alnassrallah M N, Alzoman N Z, Almomen A. Scientific Reports, 2022, 12(1): 14502.
[4] Xu L S , Wang W Z, Deng J B, et al. Environmental Geochemistry and Health, 2023, 45: 7.
[5] Liu L, Chen Q, Lv J, et al. Inorganic Chemistry, 2022, 61(20): 8015.
[6] Cui M L, Lin Z X, Xie Q F, et al. Food Chemistry, 2023, 412: 135554.
[7] Zhang S, Liu D, Wang G. Molecules, 2022, 27(8): 2586.
[8] Liang J F, Peng C, Li P Y, et al. Bioinorganic Chemistry and Applications, 2023, 5: 100821.
[9] YUE Xiao-yue, LI Yan, ZHOU Zi-jun, et al(岳晓月, 李 妍, 周子君, 等). Journal of Light Industry(轻工学报), 2022, 37(4): 41.
[10] Zhou Y, Mahapatra C, Chen H, et al. Current Opinion in Biomedical Engineering, 2020, 13: 16.
[11] Yang J, Fang M, Li Z. Aggregate, 2020, 1(1): 6.
[12] Jie M S, Lan S K, Lu C R, et al. Journal of Food Measurement and Characterization, 2023, 17: 3173.
[13] Chowdhury P, Banerjee A, Saha B, et al. ACS Biomaterials Science & Engineering, 2022, 8(10): 4207.
[14] HAN Peng-bo, XU He, AN Zhong-fu, et al(韩鹏博, 徐 赫, 安众福, 等). Progress in Chemistry(化学进展), 2022, 34(1): 1.
[15] ZHAO Si-si, ZHANG Xin-yu, QU Hong-yu, et al(赵思思, 张新宇, 曲宏宇, 等). Experimental Technology and Management(实验技术与管理), 2022, 39(5): 148.
[16] Lin X, Wang X L, Li R F, et al. ACS Omega, 2022, 7(13): 10994.
[17] Yuan B, Wang D X, Zhu L N, et al. Chemistry Science, 2019, 10(15): 4220.
[18] Pan X, Lu Y J, Zhou W X, et al. Journal of the Chinese Chemical Society, 2023, 70(3): 737.
[19] Qin W, Alifu N, Lam J W Y, et al. Advanced Materials, 2020, 32(23): 2000364.
[20] Panigrahi S K, Mishra A K. Journal of Photochemistry and Photobiology C: Photochemistry Reviews, 2019, 41: 100318.
[21] Loftin K A, Adams C D, Meyer M T, et al. Journal of Environmental Quality, 2008, 37(2): 378.
[22] Mayr H, Ofial A R. Pure and Applied Chemistry, 2005, 77(11): 1807.
[23] LI Na, LI Zhuo-ran, LIU Cong, et al(李 娜, 李卓然, 刘 聪, 等). Applied Chemical Industry(应用化工), 2015, 44(3): 580.
[24] TANG Kun(唐 琨). Tianjin Science & Technology(天津科技), 2017, 44(7): 56.
[25] FU Hao, LI Xue-bing, WANG Jun(付 浩, 李雪冰, 汪 隽, 等). China Water & Wastewater(中国给水排水), 2017, 33(17): 64.
[26] LUO Kan, SUN Run-tai, SUN Xiao-hong(罗 侃, 孙润泰, 孙晓红, 等). Chinese Journal of Health Laboratory Technology(中国卫生检验杂志), 2006,(9): 1077.
[27] CHENG Jia-xing, ZHAO Qi-yue, LI Ling-jun, et al(程家兴, 赵起越, 李令军, 等). Journal of Instrumental Analysis(分析测试学报), 2018, 37(3): 275.
[28] SUN Hui-jing, LI Pei-wen, ZHANG Bei-bei, et al(孙慧婧, 李佩纹, 张蓓蓓, 等). Chinese Journal of Chromatography(色谱), 2022, 40(4): 333.
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