Study on the detection of tetracycline by electrochemical sensors modified with nanomaterials

Authors

WANG Chenyu, School of Food Science and Bioengineering , Changsha University of Science and Technology , Changsha , Hunan 410114 , China
LI Xiaoran, School of Food Science and Bioengineering , Changsha University of Science and Technology , Changsha , Hunan 410114 , China
QUAN Ke, School of Food Science and Bioengineering , Changsha University of Science and Technology , Changsha , Hunan 410114 , China
LIU Miao, School of Food Science and Bioengineering , Changsha University of Science and Technology , Changsha , Hunan 410114 , China
WANG Jianhui, School of Food Science and Bioengineering , Changsha University of Science and Technology , Changsha , Hunan 410114 , China
CHEN Qijie, School of Chemistry and Chemical Engineering , Changsha University of Science and Technology , Changsha , Hunan 410114 , China
ZHANG Bo, School of Food Science and Bioengineering , Changsha University of Science and Technology , Changsha , Hunan 410114 , ChinaFollow

Corresponding Author(s)

张博（1989—），男，长沙理工大学讲师，博士。E-mail：zhangbo0083@126.com

Abstract

Tetracycline (TC) is a typical broad -spectrum antibiotic with extensive applications in fields such as food and medicine.However,its improper use can pose a threat to human health and environmental safety.Therefore,detecting the residue of tetracycline is very important.In recent years,electrochemical sensors modified with nanomaterials have been successfully applied for the detection of tetracycline residues in food and environmental samples due to their high sensitivity and fast response.This review compares the electrochemical sensors modified with different nanomaterials for tetracycline detection,aiming to provide a reference for trace analysis of tetracycline and the development of more efficient detection technology.At the same time,this review also summarizes the existing problems of tetracycline -detecting electrochemical sensors and the prospects for their development.

Publication Date

2-18-2025

First Page

200

Last Page

210

DOI

10.13652/j.spjx.1003.5788.2024.80435

Recommended Citation

Chenyu, WANG; Xiaoran, LI; Ke, QUAN; Miao, LIU; Jianhui, WANG; Qijie, CHEN; and Bo, ZHANG (2025) "Study on the detection of tetracycline by electrochemical sensors modified with nanomaterials," Food and Machinery: Vol. 40: Iss. 11, Article 28.
DOI: 10.13652/j.spjx.1003.5788.2024.80435
Available at: https://www.ifoodmm.cn/journal/vol40/iss11/28

References

[1] ZHANG C,LAI C,ZENG G M,et al.Efficacy of carbonaceous nanocomposites for sorbing ionizable antibiotic sulfamethazine from aqueous solution [J].Water Research,2016,95:103-112.
[2] HUANG D L,WANG X,ZHANG C,et al.Sorptive removal of ionizable antibiotic sulfamethazine from aqueous solution by graphene oxide-coated biochar nanocomposites:influencing factors and mechanism [J].Chemosphere,2017,186:414-421.
[3] YANG W Q,LI J,YAO Z L,et al.A review on the alternatives to antibiotics and the treatment of antibiotic pollution:current development and future prospects [J].Science of the Total Environment,2024,926:171757.
[4] WANG S,YONG W,LIU J H,et al.Development of an indirect competitive assay-based aptasensor for highly sensitive detection of tetracycline residue in honey [J].Biosensors and Bioelectronics,2014,57:192-198.
[5] CONZUELO F,GAMELLA M,CAMPUZANO S,et al.Disposable amperometric magneto-immunosensor for direct detection of tetracyclines antibiotics residues in milk [J].Analytica Chimica Acta,2012,737:29-36.
[6] WU D N,DAI S T,FENG H D,et al.Persistence and potential risks of tetracyclines and their transformation products in two typical different animal manure composting treatments [J].Environmental Pollution,2024,341:122904.
[7] SCARIA J,ANUPAMA K V,NIDHEESH P V.Tetracyclines in |the environment:an overview on the occurrence,fate,toxicity,detection,removal methods,and sludge management [J].Science of the Total Environment,2021,771:145291.
[8] YAO T,ZHANG H Y,FENG C L,et al.Continuous enrichment and trace analysis of tetracyclines in bovine milk using dual-functionalized aqueous biphasic system combined with high-performance liquid chromatography [J].Journal of Dairy Science,2023,106:5 916-5 929.
[9] 刘子雄,谢国丹,谭贵良,等.DES-UPLC-MS/MS 法测定水产品中 4种四环素药物残留 [J].食品与机械,2022,38(2):40-45.LIU Z X,XIE G D,TAN G L,et al.Rapid determination of drug residues of four kinds of tetracyclines using DES-UPLC-MS/MS in aquatic products [J].Food & Machinery,2022,38(2):40-45.
[10] IBARRA I S,RODRIGUEZ J A,MIRANDA J M,et al.Magnetic solid phase extraction based on phenyl silica adsorbent for the determination of tetracyclines in milk samples by capillary electrophoresis [J].Journal of Chromatography A,2011,1 218:2 196-2 202.
[11] WANG G,ZHANG H C,LIU J,et al.A receptor-based chemiluminescence enzyme linked immunosorbent assay for determination of tetracyclines in milk [J].Analytical Biochemistry,2019,564:40-46.
[12] AMALI R K A,LIM H N,IBRAHIM I,et al.Significance of nanomaterials in electrochemical sensors for nitrate detection:a review [J].Trends in Environmental Analytical Chemistry,2021,31:e00135.
[13] CHEN A C,CHATTERJEE S.Nanomaterials based electrochemical sensors for biomedical applications [J].Chemical Society Reviews,2013,42:5 425-5 438.
[14] GUO H,SU Y,SHEN Y L,et al.In situ decoration of Au nanoparticles on carbon nitride using a single-source precursor and its application for the detection of tetracycline [J].Journal of Colloid and Interface Science,2019,536:646-654.
[15] DONG W X,WEN H X,DU X Y,et al.Electrochemical sensing of tetracycline based on Au NPs@MoS2/Ch hybrid structures [J].Journal of Electroanalytical Chemistry,2022,923:116807.
[16] SONG J L,LIN X H,JIANG N,et al.Carbon-doped WO3 electrochemical aptasensor based on Box-Behnken strategy for highly-sensitive detection of tetracycline [J].Food Chemistry,2022,367:130564.
[17] TANG Y F,LIU P P,XU J,et al.Electrochemical aptasensor based on a novel flower-like TiO2 nanocomposite for the detection of tetracycline [J].Sensors and Actuators B:Chemical,2018,258:906-912.
[18] WEI X X,YIN M,ZHANG L,et al.Octahedral Cu2O nanomaterials as electrochemical aptasensor for sensitive detection of tetracycline in milk [J].Spectrochimica Acta Part A:Molecular and Biomolecular Spectroscopy,2024,304:123361.[19] SEBASTIAN N,YU W C,BALRAM D,et al.Ultrasensitive detection and photocatalytic degradation of polyketide drug tetracycline in environment and food samples using dual-functional Ag doped zinc ferrite embedded functionalized carbon nanofibers [J].Chemosphere,2024,348:140692.
[20] ABRAHAM T,MATHEW B.Silver phosphate based flower-like MoS2/BiFeO3 nanocomposite with enhanced activity for the detection of tetracycline [J].Materials Chemistry and Physics,2021,260:124103.
[21] 李微,杨光,姜瑞婷,等.碳基材料应用的研究进展 [J].黑龙江科学,2024,15(4):37-40.LI W,YANG G,JIANG R T,et al.Progress of applied research on carbon-based materials [J].Heilongjiang Science,2024,15(4):37-40.
[22] GONG Q J,HAN H X,YANG H Y,et al.Sensitive electrochemical DNA sensor for the detection of HIV based on a polyaniline/graphene nanocomposite [J].Journal of Materiomics,2019,5:313-319.
[23] KUMAR N,VERMA S,KUMAR P,et al.Efficient one-pot two-step electrochemical synthesis of highly oxidized graphene oxide for enhanced energy and environmental applications:structure elucidation through DFT simulations [J].Carbon,2024,218:118722.
[24] WONG A,SCONTRI M,MATERON E M,et al.Development and application of an electrochemical sensor modified with multi-walled carbon nanotubes and graphene oxide for the sensitive and selective detection of tetracycline [J].Journal of Electroanalytical Chemistry,2015,757:250-257.
[25] XING Y,ZHANG Y N,ZHU X L,et al.A highly selective and sensitive electrochemical sensor for tetracycline resistant genes detection based on the non-covalent interaction of graphene oxide and nucleobase [J].Science of the Total Environment,2024,906:167615.
[26] KESAVAN S,KUMAR D R,LEE Y R,et al.Determination of tetracycline in the presence of major interference in human urine samples using polymelamine/electrochemically reduced graphene oxide modified electrode [J].Sensors and Actuators B:Chemical,2017,241:455-465.
[27] BAI M Y,YUE F L,ZHAI S X,et al.Screening of broad-spectrum aptamers to construct an electrochemical aptasensor for the sensitive detection of tetracycline antibiotic residues in milk [J].Sensors and Actuators B:Chemical,2024,398:134765.
[28] NASERI M,NIAZI A,BAGHERZADEH K,et al.Modified electrochemical aptasensor for ultrasensitive detection of tetracycline:in silico and in vitro studies [J].Food Chemistry,2023,421:136195.
[29] SALAVAGIONE H J,MARTINEZ G,ELLIS G.Recent advances in the covalent modification of graphene with polymers [J].Macromolecular Rapid Communications,2011,32:1 771-1 789.
[30] 王坤,李忠海.碳纳米管改性及其在食品检测中的应用进展[J].食品与机械,2016,32(3):217-221.WANG K,LI Z H.Progress on modification of carbon nanotubes and applications in food detection [J].Food & Machinery,2016,32(3):217-221.
[31] LI J F,LEE E C.Functionalized multi-wall carbon nanotubes as an efficient additive for electrochemical DNA sensor [J].Sensors and Actuators B:Chemical,2017,239:652-659.
[32] BENVIDI A,YAZDANPARAST S,REZAEINASAB M,et al.Designing and fabrication of a novel sensitive electrochemical aptasensor based on poly (L-glutamic acid )/MWCNTs modified glassy carbon electrode for determination of tetracycline [J].Journal of Electroanalytical Chemistry,2018,808:311-320.
[33] JOHN B K,JOHN N,KORAH B K,et al.Nitrogen-doped carbon quantum dots as a highly selective fluorescent and electrochemical sensor for tetracycline [J].Journal of Photochemistry and Photobiology A:Chemistry,2022,432:114060.
[34] CHOU C M,DAI Y D,YUAN C,et al.Preparation of an electrochemical sensor utilizing graphene-like biochar for the detection of tetracycline [J].Environmental Research,2023,236:116785.
[35] MOHAN B,SINGH G,CHAUHAN A,et al.Metal-organic frameworks (MOFs ) based luminescent and electrochemical sensors for food contaminant detection [J].Journal of Hazardous Materials,2023,453:131324.
[36] NARASIMHAPPA P,VARSHNEY R,SINGH S,et al.3D rhombohedral microcrystals metal-organic frameworks for electrochemical and fluorescence sensing of tetracycline [J].Chemosphere,2023,333:138977.
[37] SHAFQAT S S,RIZWAN M,BATOOL M,et al.Metal organic frameworks as promising sensing tools for electrochemical detection of persistent heavy metal ions from water matrices:a concise review [J].Chemosphere,2023,318:137920.
[38] HUANG P S,WU W J,LI M H,et al.Metal-organic framework-based nanoarchitectonics:a promising material platform for electrochemical detection of organophosphorus pesticides [J].Coordination Chemistry Reviews,2024,501:215534.
[39] HU Y L,WANG X P,LI W,et al.Metal-organic frameworks and related materials for nonenzymatic electrochemical glucose sensors [J].International Journal of Electrochemical Science,2024,19:100466.
[40] SONG J L,HUANG M H,LIN X H,et al.Novel Fe-based metal-organic framework (MOF ) modified carbon nanofiber as a highly selective and sensitive electrochemical sensor for tetracycline detection [J].Chemical Engineering Journal,2022,427:130913.
[41] GAO F,ZHAO Y N,DAI X H,et al.Aptamer tuned nanozyme activity of nickel-metal-organic framework for sensitive electrochemical aptasensing of tetracycline residue [J].Food Chemistry,2024,430:137041.
[42] ZHAN F P,ZHAO Y N,DAI X H,et al.Electrochemically synthesized polyanine@Cu-BTC MOF as a bifunctional matrix for aptasensing of tetracycline in aquatic products [J].Microchemical Journal,2024,196:109512.
[43] RAGSDALE S W.Nickel-based enzyme systems [J].Journal of Biological Chemistry,2009,284:18 571-18 575.
[44] HE X C,JI W L,XING S J,et al.Emerging trends in sensors based on molecular imprinting technology:harnessing smartphones for portable detection and recognition [J].Talanta,2024,268:125283.
[45] RAHMAN S,BOZAL-PALABIYIK B,UNAL D N,et al.Molecularly imprinted polymers (MIPs ) combined with nanomaterials as electrochemical sensing applications for environmental pollutants [J].Trends in Environmental Analytical Chemistry,2022,36:e00176.
[46] MOSTAFA A M,BARTON S J,WREN S P,et al.Review on molecularly imprinted polymers with a focus on their application to the analysis of protein biomarkers [J].Trends in Analytical Chemistry,2021,144:116431.
[47] 丁同英,袁航.分子印迹传感器在真菌毒素检测中的应用研究进展 [J].食品与机械,2021,37(12):197-201.DING T Y,YUAN H.Application and progress of molecularly imprinted sensors in mycotoxins detection [J].Food & Machinery,2021,37(12):197-201.
[48] DEVKOTA L,NGUYEN L T,VU T T,et al.Electrochemical determination of tetracycline using AuNP-coated molecularly imprinted overoxidized polypyrrole sensing interface [J].Electrochimica Acta,2018,270:535-542.
[49] CHEN Y R,XIA Y D,LIU Y W,et al.Colorimetric and electrochemical detection platforms for tetracycline based on surface molecularly imprinted polyionic liquid on Mn3O4 nanozyme [J].Biosensors and Bioelectronics,2022,216:114650.
[50] CUI L L,XU H P,AN Y R,et al.N,S co-doped lignin-based carbon microsphere functionalized graphene hydrogel with "sphere-in-layer" interconnection as electrode materials for supercapacitor and molecularly imprinted electrochemical sensors [J].Advanced Powder Technology,2022,33:103571.
[51] ZEB S,WONG A,KHAN S,et al.Using magnetic nanoparticles/MIP-based electrochemical sensor for quantification of tetracycline in milk samples [J].Journal of Electroanalytical Chemistry,2021,900:115713.
[52] SULYM I,CETINKAYA A,YENCE M,et al.Novel electrochemical sensor based on molecularly imprinted polymer combined with L-His-MWCNTs@PDMS- 5 nanocomposite for selective and sensitive assay of tetracycline[J].Electrochimica Acta,2022,430:141102.