基于三维荧光光谱检测水产品中隐性孔雀石绿残留量

doi:10.3964/j.issn.1000-0593(2020)05-1478-05

摘要
参考文献
相关文章 (15)

全文: PDF (2063 KB)
输出: BibTeX | EndNote (RIS)

摘要：孔雀石绿作为一种化学制剂，因其杀菌性较好、价格便宜以及少量添加不易察觉等特点，一些商家将其作为杀菌剂在水产品中使用。然而，因孔雀石绿代谢产物隐性孔雀石绿具有稳定性以及高毒性的化学性质，其已被我国列为禁用药物。该研究深入讨论了如何使用三维荧光光谱法检测水产品中的隐性孔雀石绿，利用三维荧光光谱技术，探究隐性孔雀石绿的三维特征，并进一步分析其荧光强度与pH变化关系，以研究其最佳检测环境。最后针对鱼肉样品进行荧光光谱检测，以讨论三维荧光光谱技术的可行性。为三维荧光光谱法检测水产品中隐性孔雀石绿进行积累数据和奠定基础。经初步实验可以得出：隐性孔雀石绿乙醇溶液荧光强度最高峰值在激发波长324 nm/发射波长355 nm处，隐性孔雀石绿甲醇溶液荧光强度最高峰值在激发波长320 nm/发射波长355 nm处；且在pH 7的环境中检测效果最为明显。针对鱼肉样品的检测结果表明：隐性孔雀石绿浓度和荧光强度呈良好线性关系，经计算得到加标回收率为96.65%，证明实验结果有较好的稳定性。因此水产品中的隐性孔雀石绿可以通过三维荧光光谱技术准确快速的进行检测。

关键词：三维荧光光谱；隐性孔雀石绿；水产品；鱼肉检测

Abstract：As a chemical agent, malachite green is used as a fungicide in aquatic products because of its good bactericidal properties, low price and a small amount are imperceptible. However, because its metabolite in the body——the recessive malachite green has stability and highly toxic chemical properties. Malachite green has been classified as a banned drug in China. This experiment discusses how to use three-dimensional fluorescence spectroscopy to detect recessive malachite green in aquatic products, and use three-dimensional fluorescence spectroscopy to explore the three-dimensional characteristics of recessive malachite green, and further analyze the relationship between fluorescence intensity and pH change. Finally, fluorescence spectroscopy is carried out for fish samples to discuss the feasibility of three-dimensional fluorescence spectroscopy. The accumulation data and foundation of recessive malachite green in aquatic products are detected by three-dimensional fluorescence spectrometry.The experimental results show thatthe highest peak of the recessive malachite green ethanol solution was obtained at the excitation wavelength of 324 nm/the emission wavelength of 355 nm. The highest peak of recessive malachite green methanol solution was obtained at the excitation wavelength of 320 nm/the emission wavelength of 355 nm. The experimental results show that the fluorescence peak strength is strongest in the pH 7.0 environment. According to the experience of fish sample, we can find that the relationship between the concentration of recessive malachite green and the fluorescence intensity showed a good linear relationship. The recovery rate was 96.65%, which proved that the experimental results have good stability. Therefore, the recessive malachite green in aquatic products can be accurately and quickly detected by three-dimensional fluorescence spectroscopy technology.

Key words：Three-dimensional fluorescence spectrum; Recessive malachite green; Aquatic products; Fish detection

收稿日期: 2019-04-09 修订日期: 2019-09-10

中图分类号:

O657.3

基金资助: 国家自然科学基金项目（11505017, 61405189），吉林省教育厅“十三五”科学技术项目（JJKH20190553KJ），吉林省高教科研课题（JGJX2019D61）资助

通讯作者: 刘春宇 E-mail: lcycome@sina.com

作者简介: 李宁驰，1998年生，长春理工大学理学院本科生 e-mail: 1458879202@qq.com

引用本文:

李宁驰，任诺钰，刘春宇，姚治海，蔡红星. 基于三维荧光光谱检测水产品中隐性孔雀石绿残留量[J]. 光谱学与光谱分析, 2020, 40(05): 1478-1482.
LI Ning-chi, REN Nuo-yu, LIU Chun-yu, YAO Zhi-hai, CAI Hong-xing. Determination of Malachite Green Residue in Aquatic Products Based on Three-Dimensional Fluorescence Spectrum. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2020, 40(05): 1478-1482.

链接本文:

https://www.gpxygpfx.com/CN/10.3964/j.issn.1000-0593(2020)05-1478-05 或 https://www.gpxygpfx.com/CN/Y2020/V40/I05/1478

[1] SHENG Rui-tang, QIAO Mei-liang（盛瑞堂，乔美靓）. China Food & Drug Administration Magazine（中国食品药品监管）, 2018, （12): 87.
[2] Yang Ji, Wu Hao, Wu Minghui, et al. Dyes and Pigments, 2018, 155: 171.
[3] Zhou Xinhui, Zhang Jiaran, Pan Zhongli, et al. Critical Reviews in Analytical Chemistry, 2019, 49(1): 1.
[4] HU Hao-guang, LIU Shao-bin, LI Xu-peng, et al（胡浩光，刘少彬，李绪鹏，等）. Agriculture and Technology（农业与技术）, 2016, 36（19): 117.
[5] Zhao Jiao, Wei Daqiao, Yang Yaling. Journal of Seperation Science, 2016, 39(12): 2347.
[6] FENG Gang, PING Wen-hui, ZHU Xia-shi(冯刚, 平文卉, 朱霞石). Spectroscopy and Spectral Analysis（光谱学与光谱分析）, 2016, 36(2): 436.
[7] HUANG Zhi-yong（黄志勇）. Chinese Patent(中国专利），201510274020. 2[P]. 2015-08-12.
[8] YU Wan-song（余婉松）. Metallic Colloids as Surface-Enhanced Raman Scattering Substrate for Analysis of Furazolidone and Malachite Green in Fish Feed and Aquatic Products(基于金属溶胶表面增强拉曼光谱技术检测饲料及水产品中呋喃唑酮和孔雀石绿的研究). Shanghai: Shanghai Ocean University(上海：上海海洋大学), 2015.
[9] DONG Jian-wei, YANG Jun-ting（董建伟, 杨军亭）. Shaanxi Journal Agricultural Science（陕西农业科学）, 2015, 61（7）：67.
[10] JIANG Xiao-lu（姜晓露）. Scientific Fish Farming（科学养鱼）, 2016, （2）: 91.
[11] GAO Na, WANG Wen-lan, GUO Jun, el al(高娜, 王文兰, 郭军, 等). Journal of Food Safety & Quality(食品安全质量检测学报), 2019, 10(3): 653.
[12] HU Jiang-tao, YU Ling-yun, YU Gang, et al（胡江涛, 俞凌云，于刚，等）. China Measurement&Test（中国测试）, 2016, 42（4）：49.
[13] WU Jun-wei, JIANG Yu（吴俊伟, 姜宇）. China Food Safety Magazine（食品安全导刊）, 2017, （27）: 109.
[14] SUN Xie-jun, XIE Tian-yu, GUO Yong-jian, et al（孙协军，谢田雨，郭永健，等）. Packaging and Food Machinery（包装与食品机械）, 2016, 34(2）：52.
[15] YANG Ji(杨吉). Preparation of Fluorescent Probes Based on CdTe Quantum Dots Coated with Molecularly Imprinted Polymers and Their Applications in the Detection of Malachite Green and Iecuomalachite Green in Aquatic Products(CdTe量子点表面分子印迹荧光探针的制备及其在水产品孔雀石绿与隐色孔雀石绿检测中的应用). Fujian: Jimei University(福建：集美大学)，2018.