|
|
|
|
|
|
| Research Progress of Surface-Enhanced Raman Spectroscopy in Pesticide Residue Detection |
| QIU Meng-qing1, 2, XU Qing-shan1*, ZHENG Shou-guo1*, WENG Shi-zhuang3 |
1. Hefei Institutes of Physical Science, Chinese Academy of Sciences, Hefei 230031, China
2. University of Science and Technology of China, Hefei 230026, China
3. National Engineering Research Center for Agro-Ecological Big Data Analysis & Application, Anhui University, Hefei 230601, China |
|
|
|
|
Abstract Pesticides directly pollute the environment and contaminate foods, ultimately being absorbed by the human body. Its residues are highly toxic, which have serious effects on human health. Some methods such as chromatography and gas/liquid chromatography-mass spectrometry have been widely used to detect pesticide residues. However, these methods also have some disadvantages, such as complicated pre-processing steps, time-consuming and labor-intensive. Surface-enhanced Raman spectroscopy (SERS) technology is regarded as a new pesticide residue detection method due to its high sensitivity, good specificity, comprehensive fingerprint information and no damage to the sample. It can realize trace pesticides in liquid or solid samples through simple extraction. In this review, to provide new references in the detection of pesticide residues, we mainly summarized the research progress of SERS detection technology and methods for pesticide residues from the three aspects of the preparation of SERS active substrates, detection methods, and intelligent analysis of spectra. In preparing SERS active substrates, single noble metal sol nanoparticles have poor stability and sensitivity due to random and uncontrollable “hot spots”, which can no longer satisfy trace pesticide residue detection. In order to improve the adsorption capacity of the SERS substrate more target analytes are enriched on the surface of the SERS substrate and the signal does not change significantly. The single noble metal sol nanoparticles are assembled, or its surface is modified by adding chemicals, inert materials, etc., to prepare uniform SERS composite substrate, thereby effectively and specifically capturing the analyte, ensuring good reproducibility and sensitivity of SERS signal. On this basis, in order to achieve the specificity and high sensitivity detection, the detection method of SERS for pesticide residues has gradually evolved from the use of simple nanoparticles such as gold and silver nanoparticles as an enhanced substrate to the optimization of sample pretreatment techniques, the preparation of specific SERS probes by chemical modification, breakthroughs in the physical structure of enhanced substrates, and dynamic SERS(D-SERS) detection. After obtaining the Raman spectrum of the substance, the effective Raman characteristic region is usually within a short wavenumber range, and the spectral data is as high as thousands of dimensions. There is more redundancy, which leads to an increase in the complexity of subsequent analysis. SERS spectrum intelligence analysis often uses chemometrics methods to pre-process the original spectrum, extract features and modeling, realize data dimensionality reduction and main information extraction, and then achieve qualitative and quantitative for pesticide residues. In order to obtain global features and large-scale process data, deep learning methods have also been introduced into SERS spectral intelligent analysis in recent years, which has achieved good analysis results. In summary, SERS has an excellent development prospect for rapid detection of pesticide residues and can provide new ideas for future analysis and testing field.
|
|
Received: 2020-10-22
Accepted: 2021-03-02
|
|
|
|
Corresponding Authors:
XU Qing-shan, ZHENG Shou-guo
E-mail: qshxu@aiofm.ac.cn;zhengsg@hfcas.ac.cn
|
|
[1] Carvalho F P. Food and Energy Security, 2017, 6(2): 48.
[2] Xiao G, Dong D, Liao T, et al. Food Analytical Methods, 2015, 8: 1341.
[3] Guo P, Sikdar D, Huang X, et al. Nanoscale, 2015, 7(7): 2862.
[4] Stamplecoskie K G, Scaiano J C, et al. Journal of Physical Chemistry, C, 2011, 115: 1403.
[5] Xu Q, Guo X, Xu L, et al. Sensors & Actuators B: Chemical, 2017, 241: 1008.
[6] Weng S, Qiu M, Dong R, et al. Nanoscience and Nanotechnology Letters, 2019, 11(3): 354.
[7] Weng S, Qiu M, Dong R, et al. International Journal of Analytical Chemistry, 2018, 2018: 6146489.
[8] Huang T, Meng F, Qi L. Langmuir, 2010, 26(10): 7582.
[9] Zhang W, Li J F, Wu D, et al. Nature, 2010, 464(7287): 392.
[10] Majeed S A. Analyst, 2020, 145(21): 6744.
[11] Zhang Q M, Li D, Cao X K, et al. Analytical Chemistry, 2019, 91(17): 11192.
[12] Tang J, Sun J, Lui R, et al. ACS Applied Materials & Interfaces, 2016, 8(3): 2449.
[13] Chen Z, Dai Z, Chen N, et al. IEEE Photonics Technology Letters, 2014, 26(8): 777.
[14] Gao D, Yang X, Teng P, et al. Optics Letters, 2019, 44(21):5173.
[15] Yang L, Li P, Liu H, et al. Chemical Society Reviews, 2015, 44(10): 2837.
[16] Weng S, Zhu W, Li P, et al. Food Chemistry,2020, 310: 125855.
[17] Zhu J, Agyekum A, Kutsanedzie F, et al. LWT,2018, 97: 760.
[18] HUANG Lin-sheng, WANG Fang, WENG Shi-zhuang, et al(黄林生, 王 芳, 翁士状, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2018, 38(9): 2782.
[19] Jiang B, He J, Yang S, et al. Artificial Intelligence in Agriculture, 2019, 1: 1.
[20] Thrift W J, Ragan R. Analytical Chemistry,2019, 91(21): 13337. |
| [1] |
YANG Lin-yu1, 2, 3, DING Yu1, 2, 3*, ZHAN Ye4, ZHU Shao-nong1, 2, 3, CHEN Yu-juan1, 2, 3, DENG Fan1, 2, 3, ZHAO Xing-qiang1, 2, 3. Quantitative Analysis of Mn and Ni Elements in Steel Based on LIBS and GA-PLS[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(06): 1804-1808. |
| [2] |
FU Qiu-yue1, FANG Xiang-lin1, ZHAO Yi2, QIU Xun1, WANG Peng1, LI Shao-xin1*. Research Progress of Pathogenic Bacteria and Their Drug Resistance
Detection Based on Surface Enhanced Raman Technology[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(05): 1339-1345. |
| [3] |
TAN Yang1, WU Xiao-hong2, 3*, WU Bin4, SHEN Yan-jun1, LIU Jin-mao1. Qualitative Analysis of Pesticide Residues on Chinese Cabbage Based on GK Improved Possibilistic C-Means Clustering[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(05): 1465-1470. |
| [4] |
FU Ying-ying, ZHANG Ping, ZHENG Da-wei , LIN Tai-feng*, WANG Hui-qin, WU Xi-hao, SONG Jia-chen. Preparation and SERS Performance of Au-Nylon Flexible Membrane Substrate[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(03): 692-698. |
| [5] |
SONG Hong-yan, ZHAO Hang, YAN Xia, SHI Xiao-feng, MA Jun*. Adsorption Characteristics of Marine Contaminant Polychlorinated Biphenyls Based on Surface-Enhanced Raman Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(03): 704-712. |
| [6] |
SUN Xue-hui1, ZHAO Bing2, LUO Zhen2, SUN Pei-jian1, PENG Bin1, NIE Cong1*, SHAO Xue-guang3*. Design and Application of the Discrimination Filter for Near-Infrared Spectroscopic Analysis[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(02): 399-404. |
| [7] |
LI Wei, ZHANG Xue-li, SU Qin, ZHAO Rui, SONG Hai-yan*. Qualitative Analysis of Chlorpyrifos Pesticide Residues in Cabbage Leaves Based on Visible Near Infrared Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(01): 80-85. |
| [8] |
ZHANG Lin1, WEN Bao-ying2, LIU Wei-wei1, FU Wen-xiang1, KONG Jing-lin1*, LI Jian-feng2*. Rapidly Detection of Chemical Warfare Agent Simulants by Surface Enhanced Raman Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(01): 110-114. |
| [9] |
XU Yang1, LEI Lei2, YAN Jun1*, CHEN Yu-yun1, TAN Xue-cai1, LIU Yu-qian1, WANG Qi3. Determination of Glutaraldehyde in Water by Surface Enhanced Raman Spectroscopy Based on Metal Organic Framework Composite Substrate[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(01): 115-123. |
| [10] |
SHI Si-qian, YANG Fang-wei, YAO Wei-rong, YU Hang, XIE Yun-fei*. Rapid Detection of Levamisole Residue in Pork by Surface Enhanced Raman Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(12): 3759-3764. |
| [11] |
YU Guo-wei1, MA Ben-xue1,2*, CHEN Jin-cheng1,3, DANG Fu-min4,5, LI Xiao-zhan1, LI Cong1, WANG Gang1. Vis-NIR Spectra Discriminant of Pesticide Residues on the Hami Melon Surface by GADF and Multi-Scale CNN[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(12): 3701-3707. |
| [12] |
CHEN Tao1, GUO Hui1, YUAN Man1, TAN Fu-yuan3*, LI Yi-zhou2*, LI Meng-long1. Recognition of Different Parts of Wild Cordyceps Sinensis Based on Infrared Spectrum[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(12): 3727-3732. |
| [13] |
TAN Ai-ling1, ZHAO Rong1, SUN Jia-lin1, WANG Xin-rui1, ZHAO Yong2*. Detection of Chlorpyrifos Based on Surface-Enhanced Raman Spectroscopy and Density Functional Theory[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(11): 3462-3467. |
| [14] |
ZHANG Yan-jun, KANG Cheng-long, LIU Ya-qian, FU Xing-hu*, ZHANG Jin-xiao, WANG Ming-xue, YANG Liu-zhen. Rapidly Detection of Total Nitrogen and Phosphorus Content in Water by Surface Enhanced Raman Spectroscopy and GWO-SVR Algorithm[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(10): 3147-3152. |
| [15] |
JIN Xiang-peng, LI Xing-jia, ZHANG Chen-jie, YUAN Ya-xian, YAO Jian-lin*. Surface Enhanced Raman Spectroscopic Investigation on SPR Catalyzed Decarboxylation of Ortho-Mercaptobenzoic Acid at Au Nanoparticles Monolayer Film[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(10): 3153-3158. |
|
|
|
|
