畜禽粪便中氮磷及抗生素的高效检测方法研究进展

Abstract
Figure/Table
References
Related Citation (15)

Download: PDF (605 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS)

Abstract In this article, conventional detection methods and emerging detection techniques for nitrogen, phosphorus, and antibiotics in feces have been systematically reviewed to identify the bottlenecks and future research directions. For the conventional feces detection methods, they are of high accuracy and sensitivity, but often carried out in professional laboratories or require the use of large instruments. It is quite challenging to meet the need of rapid detection in in-situ or online monitoring situations. Therefore, new detection technologies for nitrogen, phosphorus, and antibiotics in feces are highly needed. Nitrogen, phosphorus, and antibiotics in feces can be extracted by pretreatment, and then be analyzed with simple and convenient electrochemical or fluorescence methods to achieve rapid measures in in-situ analysis or online monitoring settings. Given current technologies, highly efficient detection technologies for pollutants in feces have great potentials and demand in the future. The applications of electrochemical and fluorescence methods in nitrogen, phosphorus, and antibiotics detection in feces need continuous support in fundamental research and technological innovations.

Key words： livestock and poultry manure nitrogen phosphorus antibiotic highly-efficient detection method

Received: 31 August 2020

PACS:	X713
	O657

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	HAO Si-bei
	LIU Cheng-bin
	CHEN Xiao-yan
	MAO Shun

Cite this article:

HAO Si-bei,LIU Cheng-bin,CHEN Xiao-yan等. Research advances in highly-efficient detection methods for nitrogen, phosphorus and antibiotics in livestock and poultry manure[J]. CHINA ENVIRONMENTAL SCIENCECE, 2021, 41(4): 1746-1755.

URL:

http://www.zghjkx.com.cn/EN/ OR http://www.zghjkx.com.cn/EN/Y2021/V41/I4/1746

[1]	第二次全国污染源普查公报[R]. 北京:中华人民共和国生态环境部, 2020. Communique on the second national survey of pollution sources[R]. Beijing:Ministry of Ecology and Environment of the People's Republic of China, 2020.
[2]	王莉.畜禽粪便对环境的污染及解决途径[J]. 当代畜牧, 2015, (5):31-32. Wang L. Environmental pollution caused by livestock and poultry manure and its solutions[J]. Contemporary Animal Husbandry, 2015, (5):31-32.
[3]	程芬.畜牧业生产带来的生态环境问题探析[J]. 现代农业科技, 2020,(9):189-192. Chen F. Analysis of ecological environment problems brought by animal husbandry production[J]. Modern Agricultural Science and Technology, 2020,(9):189-192.
[4]	祖民会.畜禽生产中抗生素使用及应对措施[J]. 畜牧兽医科学(电子版), 2020,(1):55-56. Zu M H. Use of antibiotics in livestock and poultry production and countermeasures[J]. Graziery Veterinary Sciences(Electronic Version), 2020,(1):55-56.
[5]	王何中.养殖业抗生素使用现状及应对措施[J]. 现代农业科技, 2019,(22):164-166. Wang H Z. Current situation and countermeasures of antibiotic use in aquaculture industry[J]. Modern Agricultural Science and Technology, 2019,(22):164-166.
[6]	NY 525-2012有机肥料[S]. NY 525-2012 Organic fertilizer[S].
[7]	Chen L, Xing L, Han L. Review of the application of near-infrared spectroscopy technology to determine the chemical composition of animal manure[J]. Journal of Environmental Quality, 2013,42(4):1015-1028.
[8]	杨硕.畜禽养殖废水的抗生素污染现状及检测方法[J]. 农业与技术, 2020,40(21):107-108. Yang S. Current status and detection methods of antibiotic contamination in livestock and poultry wastewater[J]. Agriculture and Technology, 2013,42(4):1015-1028.
[9]	郑颜,赵善仓,杨发斌,等.畜禽粪污中抗生素残留检测方法及消减技术研究进展[J]. 山东畜牧兽医, 2019,40(8):89-92. Zheng Y, Zhao S C, Yang F B, et al. Research progress in detection methods and abatement techniques of antibiotic residues in livestock and poultry manure[J]. Shandong Journal of Animal Science and Veterinary Medicine, 2019,40(8):89-92.
[10]	Chen X, Zhou G, Mao S, et al. Rapid detection of nutrients with electronic sensors:A review[J]. Environmental Science:Nano, 2018, 5(4):837-862.
[11]	Duffy G, Regan F. Recent developments in sensing methods for eutrophying nutrients with a focus on automation for environmental applications[J]. Analyst, 2017,142(23):4355-4372.
[12]	Robati R Y, Arab A, Ramezani M, et al. Aptasensors for quantitative detection of kanamycin[J]. Biosensors & Bioelectronics, 2016,82:162-172.
[13]	Joshi A, Kim K H. Recent advances in nanomaterial-based electrochemical detection of antibiotics:Challenges and future perspectives[J]. Biosensors & Bioelectronics, 2020,153:112046.
[14]	Sáez-Plaza P, Navas M J, Wybraniec S, et al. An Overview of the Kjeldahl method of nitrogen determination. Part Ⅱ. sample Preparation, working scale, instrumental finish, and quality control[J]. Critical Reviews in Analytical Chemistry, 2013,43(4):224-272.
[15]	郭建凤,王诚,张印,等.规模猪场不同阶段猪粪便特性检测[J]. 养猪, 2012,(2):62-64. Guo J F, Wang C, Zhang Y, et al. Characteristics detection of pig feces at different stages in large-scale pig farms[J]. Swine Production, 2012,(2):62-64.
[16]	黄红卫,吴彦虎,李晓梅,等.宁夏规模养殖场畜禽粪便养分含量和重金属、抗生素残留量测定及安全性评估[J]. 农业科学研究, 2018, 39(2):1-8. Huang H W, Wu Y H, Li X M, et al. Determination and safety assessment of nutrient content, heavy metal and antibiotic residues in livestock and poultry manure from large-scale livestock farms in Ningxia[J]. Journal of Agricultural Sciences, 2018,39(2):1-8.
[17]	范志影,周陈维.杜马斯燃烧定氮法在农产品品质检测中的应用[J]. 现代科学仪器, 2006,(1):45-46. Fan Z Y, Zhou C W. Application of dumas combustion method for nitrogen analysis on agricultural products[J]. Modern Scientific Instruments. 2006,(1):45-46.
[18]	陈丽萍.杜马斯燃烧法与凯氏定氮法的比较[J]. 黑龙江粮食, 2018,(10):48-49. Chen L P. Comparison of Dumas combustion method and Kjeldahl method for nitrogen determination[J]. Heilongjiang Grain, 2018,(10):48-49.
[19]	沈秀丽,杨增玲,薛俊杰,等.杜马斯燃烧法与凯氏法测定畜禽粪便中氮含量的比较[J]. 农业工程学报, 2012,28(17):205-209. Shen X L, Yang Z L, Xue J J, et al. Comparison of Kjeldahl and Dumas combustion methods for determination of nitrogen content in animal[J]. Transactions of the Chinese Society of Agricultural Engineering, 2012,28(17):205-209.
[20]	王樱洁,周博,孙海霞,等.近红外光谱分析技术在畜禽粪样成分检测中的应用[J]. 中国畜牧杂志, 2017,53(12):13-16. Wang Y J, Zhou B, Sun H X, et al. Application of near infrared spectroscopy in the detection of fecal components in livestock and poultry[J]. Chinese Journal of Animal Science, 2017,53(12):13-16.
[21]	樊霞,韩鲁佳,皇才进,等.基于近红外光谱技术的牛粪成分含量测定方法[J]. 农业机械学报, 2006,(3):76-79. Fan X, Han L J, Huang C J, et al. Determination of nutrient contents in beef manure with near infrared reflectance spectroscopy[J]. Transactions of the Chinese Society for Agricultural Machinery, 2006, (3):76-79.
[22]	Saeys W, Mouazen A M, Ramon H. Potential for onsite and online analysis of pig manure using visible and near infrared reflectance spectroscopy[J]. Biosystems Engineering, 2005,91(4):393-402.
[23]	Bastianelli D, Bonnal L, Juin H, et al. Prediction of the chemical composition of poultry excreta by near infrared spectroscopy[J]. Journal of Near Infrared Spectroscopy, 2010,18(1):69-77.
[24]	Chen L J, Xing L, Han L J. Quantitative determination of nutrient content in poultry manure by near infrared spectroscopy based on artificial neural networks[J]. Poultry Science, 2009,88(12):2496-2503.
[25]	Tamburini E, Castaldelli G, Ferrari G, et al. Onsite and online FT-NIR spectroscopy for the estimation of total nitrogen and moisture content in poultry manure[J]. Environmental Technology, 2015,36(18):2285-2294.
[26]	Chen X, Pu H, Fu Z, et al. Real-time and selective detection of nitrates in water using graphene-based field-effect transistor sensors[J]. Environmental Science:Nano, 2018,5(8):1990-1999.
[27]	Wang Q H, Yu L J, Liu Y, et al. Methods for the detection and determination of nitrite and nitrate:A review[J]. Talanta, 2017,165:709-720.
[28]	Jiang C, He Y, Liu Y. Recent advances in sensors for electrochemical analysis of nitrate in food and environmental matrices[J]. The Analyst, 2020,145(16):5400-5413.
[29]	Li D, Wang T, Li Z, et al. Application of graphene-based materials for detection of nitrate and nitrite in water-A review[J]. Sensors, 2020,20(1):54.
[30]	Ribeiro J A, Silva F, Pereira C M. Electrochemical sensing of ammonium ion at the water/1,6-dichlorohexane interface[J]. Talanta, 2012,88:54-60.
[31]	Jin S, Lee JS, Kang Y, et al. Voltammetric ion-channel sensing of ammonium ion using self-assembled monolayers modified with ionophoric receptors[J]. Sensors and Actuators B-Chemical, 2015,207:1026-1034.
[32]	Essousi H, Barhoumi H, Bibani M, et al. Ion-imprinted electrochemical sensor based on copper nanoparticles-polyaniline matrix for nitrate detection[J]. Journal of Sensors, 2019,2019:1-14.
[33]	Gumpu M B, Nesakumar N, Ramachandra B L, et al. Zinc oxide nanoparticles-based electrochemical sensor for the detection of nitrate ions in water with a low detection limit-a chemometric approach[J]. Journal of Analytical Chemistry, 2017,72(3):316-326.
[34]	Moorcroft M J, Nei L, Davis J, et al. Enhanced electrochemical detection of nitrite and nitrate at a Cu-30Ni alloy electrode[J]. Analytical Letters, 2000,33(15):3127-3137.
[35]	Soropogui K, Sigaud M, Vittori O. Alert electrodes for continuous monitoring of nitrate ions in natural water[J]. Electroanalysis, 2006,18(23):2354-2360.
[36]	Wang Z, Liao F, Guo T, et al. Synthesis of crystalline silver nanoplates and their application for detection of nitrite in foods[J]. Journal of Electroanalytical Chemistry, 2012,664:135-138.
[37]	Wang X, Li H, Wu M, et al. Simultaneous electrochemical determination of sulphite and nnitrite using a gold nanoparticle/graphene-chitosan modified electrode[J]. Chinese Journal of Analytical Chemistry, 2013,41(8):1232-1237.
[38]	Zhao X, Li N, Jing M, et al. Monodispersed and spherical silver nanoparticles/graphene nanocomposites from gamma-ray assisted in-situ synthesis for nitrite electrochemical sensing[J]. Electrochimica Acta, 2019,295:434-443.
[39]	Aoki H, Hasegawa K, Tohda K, et al. Voltammetric detection of inorganic phosphate using ion-channel sensing with self-assembled monolayers of a hydrogen bond-forming receptor[J]. Biosensors & Bioelectronics, 2003,18(2/3):261-267.
[40]	Cinti S, Talarico D, Palleschi G, et al. Novel reagentless paper-based screen-printed electrochemical sensor to detect phosphate[J]. Analytica Chimica Acta, 2016,919:78-84.
[41]	He J, Sun H, Dai J, et al. In situ growth of nanoflake and nanoflower-like Ni hydrated hydroxide on the surface of Ni foam as a free-standing electrode for high-performance phosphate detection[J]. J Hazard Mater, 2020,392:122313.
[42]	Sun S, Chen Q, Sheth S, et al. Direct electrochemical sensing of phosphate in aqueous solutions based on phase transition of calcium phosphate[J]. ACS Sens, 2020,5(2):541-548.
[43]	GB/T 32951-2016有机肥料中土霉素、四环素、金霉素与强力霉素的含量测定高效液相色谱法[S]. GB/T 32951-2016 Determination of oxytetracyline, tetracyline, chlortetracycline and doxycycline contnet for organic fertilizers-HPLC method[S].
[44]	Jansen L J M, van de Schans M G M, de Boer D, et al. A new extraction procedure to abate the burden of non-extractable antibiotic residues in manure[J]. Chemosphere, 2019,224:544-553.
[45]	夏天骄,夏训峰,徐东耀,等.基于固相萃取-高效液相色谱法的畜禽粪便中四环素类抗生素残留量检测[J]. 安全与环境学报, 2013, 13(2):121-125. Xia T J, Xia X F, Xu D Y, et al. Determination of the residual tetracycline antibiotics in the manures of livestock via the solid-phase extraction-high performance liquid chromatography method[J]. Journal of Safety and Environment, 2013,13(2):121-125.
[46]	李艳霞,李帷,张雪莲,等.固相萃取-高效液相色谱法同时检测畜禽粪便中14种兽药抗生素[J]. 分析化学, 2012,40(2):213-217. Li Y X, Li W, Zhang X L, et al. Simultaneous determination of 14veterinary antibiotics in animal manure by solid phase extraction and high performance liquid chromatography[J]. Chinese Journal of Analytical Chemistry, 2012,40(2):213-217.
[47]	罗庆,孙丽娜,胡筱敏.固相萃取-高效液相色谱法测定畜禽粪便中罗红霉素和3种四环素类抗生素[J]. 分析试验室, 2014,33(8):885-888. Luo Q, Sun L N, Hu X M. Simultaneous determination of roxithromycin and three tetracyclines in manure by high-performance liquid chromatography with a diode-array detector[J]. Chinese Journal of Analysis Laboratory, 2014,33(8):885-888.
[48]	王丽,钟冬莲,陈光才,等.固相萃取-高效液相色谱-串联质谱法测定畜禽粪便中的残留抗生素[J]. 色谱, 2013,31(10):1010-1015. Wang L, Zhong D L, Chen G C, et al. Determination of antibiotic residues in manure by liquid chromatography-tandem mass spectrometry coupled with solid phase extraction[J]. Chinese Journal of Chromatography, 2013,31(10):1010-1015.
[49]	钟冬莲,丁明,汤富彬,等.高效液相色谱-电喷雾串联质谱法测定畜禽粪便中四环素类抗生素[J]. 分析科学学报, 2014,30(3):433-436. Zhong D L, Ding M, Tang F B, et al. Determination of tetracyclines antibiotics residues in animal manure by liquid chromatography with tandem mass spectrometry[J]. Journal of Analytical Science, 2014, 30(3):433-436.
[50]	何金华,丘锦荣,贺德春,等.高效液相色谱-荧光检测法同时测定畜禽粪便中4种磺胺类药物残留[J]. 环境化学, 2012,31(9):1436-1441. He J H, Qiu J R, He D C, et al. Simultaneous determination of four sulfonamide residue in the manure of livestock and poultry by HPLC with fluorescence detection[J]. Environmental Chemistry, 2012,31(9):1436-1441.
[51]	Zhou Q, Wang N, Zhu L, et al. A fully automatic HPLC-CAD-DAD method coupled with ASE and online SPE for simultaneous determination of seven antibiotics in bio-Matrices[J]. chromatographia, 2015,78(23/24):1475-1484.
[52]	刘博,薛南冬,杨兵,等.高效液相色谱-荧光检测法同时分析鸡粪中六种氟喹诺酮类抗生素[J]. 农业环境科学学报, 2014,33(5):1050-1056. Liu B, Xue N D, Yang B, et al. Simultaneous determination of six fluoroquinolones in chicken manures by high performance liquid chromatography with fluorescence detection[J]. Journal of Agro-Environment Science, 2014,33(5):1050-1056.
[53]	Gonçalves L M, Callera W F A, Sotomayor M D P T, et al. Penicillinase-based amperometric biosensor for penicillin G[J]. Electrochemistry Communications, 2014,38:131-133.
[54]	Li F, Wang X, Sun X, et al. Multiplex electrochemical aptasensor for detecting multiple antibiotics residues based on carbon fiber and mesoporous carbon-gold nanoparticles[J]. Sensors and Actuators B:Chemical, 2018,265:217-226.
[55]	Chen X, Liu Y, Fang X, et al. Ultratrace antibiotic sensing using aptamer/graphene-based field-effect transistors[J]. Biosensors & Bioelectronics, 2019,126:664-671.
[56]	Chen X, Hao S, Zong B, et al. Ultraselective antibiotic sensing with complementary strand DNA assisted aptamer/MoS2field-effect transistors[J]. Biosensors & Bioelectronics, 2019,145:111711.
[57]	Jafari S, Dehghani M, Nasirizadeh N, et al. An azithromycin electrochemical sensor based on an aniline MIP film electropolymerized on a gold nano urchins/graphene oxide modified glassy carbon electrode[J]. Journal of Electroanalytical Chemistry, 2018,829:27-34.
[58]	Ayankojo A G, Reut J, Ciocan V, et al. Molecularly imprinted polymer-based sensor for electrochemical detection of erythromycin[J]. Talanta, 2020,209:120502.
[59]	Feng C, Dai S, Wang L. Optical aptasensors for quantitative detection of small biomolecules:a review[J]. Biosensors & Bioelectronics, 2014,59:64-74.
[60]	Tarannum N, Hendrickson O D, Khatoon S, et al. Molecularly imprinted polymers as receptors for assays of antibiotics[J]. Critical Reviews in Analytical Chemistry, 2020,50(4):291-310.
[61]	Yuphintharakun N, Nurerk P, Chullasat K, et al. A nanocomposite optosensor containing carboxylic functionalized multiwall carbon nanotubes and quantum dots incorporated into a molecularly imprinted polymer for highly selective and sensitive detection of ciprofloxacin[J]. Spectrochim Acta A Mol Biomol Spectrosc, 2018,201:382-391.
[62]	Wang J, Cheng R, Wang Y, et al. Surface-imprinted fluorescence microspheres as ultrasensitive sensor for rapid and effective detection of tetracycline in real biological samples[J]. Sensors and Actuators B:Chemical, 2018,263:533-542.
[63]	Zhao H M, Gao S, Liu M, et al. Fluorescent assay for oxytetracycline based on a long-chain aptamer assembled onto reduced graphene oxide[J]. Microchim Acta, 2013,180:829-835.
[64]	Ramezani M, Danesh N M, Lavaee P, et al. A selective and sensitive fluorescent aptasensor for detection of kanamycin based on catalytic recycling activity of exonuclease Ⅲ and gold nanoparticles[J]. Sensors and Actuators B:Chemical, 2016,222:1-7.