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| Rapid Detection of Patent Blue V Based on Surface Enhanced Raman Spectroscopy |
| WANG Xin1, HE Jian1*, FANG Xian-guang1, 2, CHEN Qi-zhen3, ZENG Yong-ming3, LAI Fu-long3, CHEN Hong-ju3, TIAN Zhong-qun4 |
1. School of Aerospace Engineering, Xiamen University, Xiamen 361102,China
2. Fujian Key Laboratory of Universities and Colleges for Transducer Technology , Xiamen 361102, China
3. Xiamen Perser Technology Co. Ltd.,Xiamen University, Xiamen 361102,China
4. College of Chemistry and Chemical Engineering,Xiamen University,Xiamen 361102,China |
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Abstract Food safety has been the focus problem concerned by the society and the general public whose current state is serious, so it is of great practical significance to realize the rapid detection of harmful substances in food. Synthetic pigment is a common food additive whose excessive and illegal addition is still one of the important problems in food safety, which greatly endangers the health of the people and the healthy development of food industry. Common synthetic pigment detection methods have the disadvantages of long time consumption and high cost, which are not suitable for real-time monitoring and rapid screening of synthetic pigments. In order to overcome the shortcomings of the traditional methods, this paper proposes the use of surface-enhanced Raman spectroscopy to detect synthetic pigments. This method has the advantages of fast detection speed and high detection sensitivity, and can achieve real-time detection in the field. In addition, since Raman detection methods often rely on complex sample preparation operations, and common solid phase extraction techniques rely on manual operations, which are complicated and time consuming, and seriously restrict the rapid detection efficiency of food. Therefore, in this paper, the automatic solid phase extraction device, including mechanical, electrical and software modules, was designed, and by precise control of peristaltic pump flow rate and multi-way valve switch in four steps of activation, loading, rinsing and elution, the device realized the automatic fast solid phase extraction of food samples. In the experimental part, the juice drink with different patent blue V concentrations was prepared, and then the device was used to pre-treat the patent blue V in the juice, in which the extraction column packing and the time and parameters of each step were rationally selected, and then the Raman spectra of patented blue V were successfully detected. The experimental results showed that, compared with traditional manual extraction, the automatic solid phase extraction device has saved nearly half of the extraction time (10 minutes down to 5 minutes) and can process five samples at the same time. The extraction time was not easy to be affected by human factors which significantly improved the efficiency and stability of the sample pretreatment. Meanwhile, because it was relatively less interfered by the external environment, a stronger Raman spectral signal (about 50% enhancement) could be obtained, so the extraction effect was also satisfactory. The results of different concentrations of patented blue V samples show that the method can achieve a detection concentration of 0.5 mg·L-1, which can effectively meet the needs of on-site monitoring, and is characterized by fast, convenient and high sensitivity.
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Received: 2018-08-29
Accepted: 2018-12-20
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Corresponding Authors:
HE Jian
E-mail: jianhe98@xmu.edu.cn
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[1] SUN Ya-na, ZHU Lei, CUI Fang(孙亚娜,朱 蕾,崔 方). Food Science and Technology(食品科技), 2011,36(12):310.
[2] ZHOU Fa-dong, LIU Xian-jun, LAI Chuang-ye, et al(周法东,刘宪军,来创业,等). Meat Research(肉类研究), 2013, 27(6): 19.
[3] GONG Qiang, DING Li, XIAO Jia-yong, et al(龚 强,丁 莉,肖家勇,等). Food & Machinery(食品与机械), 2014, 30(1): 75.
[4] Xie Yunfei, Chen Ting, Guo Yahui,et al. Food Chemistry, 2019, 270: 173.
[5] Sun Huanhuan, Gao Renxian, Zhu Aonan,et al. Superlattices and Microstructures, 2018, 115: 59.
[6] Patrick W Fedick, Brandon J Bills, Nicholas E Manicke,et al. Anal. Chem., 2017, 89(20): 10973.
[7] Kang Yan, Wu Ting, Chen Wanchao,et al. Food Chemistry, 2019, 270: 494.
[8] Chamuah N, Bhuyan N, Das P P,et al. Sensors and Actuators B-Chemical, 2018, 273: 710.
[9] ZHAI Chen, LI Yong-yu, PENG Yan-kun, et al(翟 晨,李永玉,彭彦昆,等). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报), 2017, 33(7): 275.
[10] LIU Da-xing, FU Liu-jie, ZHAO Huai-long(刘大星,付留杰,赵怀龙). Chinese Journal of Health Laboratory Technology(中国卫生检验杂志), 2012, 22(4): 942.
[11] ZHANG Yu-ping(张玉萍). Quality and Safety of Agro-Products(农产品质量与安全), 2013,(5): 44.
[12] NHFPC,National Health and Family Planning Commission of China(国家卫生和计划生育委员会). GB2760—2011 National Food Safety Standard for Used of Food Additives(GB2760—2011食品安全国家标准食品添加剂使用标准). Beijing: Standards Press of China(北京:中国标准出版社),2011. |
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