聚多巴胺纳米纤维膜固相萃取-超高效液相色谱-串联质谱检测淡水鱼中四环素类和氟喹诺酮类药物残留

doi:10.3724/SP.J.1123.2020.12026

色谱 ›› 2021, Vol. 39 ›› Issue (6): 624-632.DOI: 10.3724/SP.J.1123.2020.12026

聚多巴胺纳米纤维膜固相萃取-超高效液相色谱-串联质谱检测淡水鱼中四环素类和氟喹诺酮类药物残留

梁思慧¹, 戴海蓉¹, 张铧尹¹, 李建², 张秋萍², 许茜¹^,³^,^*(), 王春民²^,^*()

1.东南大学公共卫生学院营养与食品卫生学系, 江苏南京 210009
2.苏州市疾病预防控制中心, 江苏苏州 215100
3.东南大学环境与医学工程教育部重点实验室, 江苏南京 210009

收稿日期:2020-12-24 出版日期:2021-06-08 发布日期:2021-04-13
通讯作者: 许茜,王春民
作者简介:E-mail: chunminwang@163.com(王春民).
* E-mail: q_xu68@163.com(许茜);
基金资助:
国家自然科学基金(81973098)

Determination of tetracycline and fluoroquinolone residues in fish by polydopamine nanofiber mat based solid phase extraction combined with ultra performance liquid chromatography-tandem mass spectrometry

LIANG Sihui¹, DAI Hairong¹, ZHANG Huayin¹, LI Jian², ZHANG Qiuping², XU Qian¹^,³^,^*(), WANG Chunmin²^,^*()

1. Department of Nutrition and Food Hygiene, School of Public Health, Southeast University, Nanjing 210009, China
2. Suzhou Center for Disease Control and Prevention, Suzhou 215100, China
3. Key Laboratory of Ministry of Education of Environment and Medical Engineering, Southeast University, Nanjing 210009, China

Received:2020-12-24 Online:2021-06-08 Published:2021-04-13
Contact: XU Qian,WANG Chunmin
Supported by:
National Nature Science Foundation of China(81973098)

摘要/Abstract

摘要：

制备聚多巴胺(PDA)修饰的聚苯乙烯纳米纤维膜(PS NFsM)作为固相萃取吸附介质,可快速提取淡水鱼中3种四环素类(四环素、金霉素、土霉素)和3种氟喹诺酮类(恩诺沙星、环丙沙星、诺氟沙星)药物残留,结合超高效液相色谱-串联质谱(UPLC-MS/MS),建立了药物残留检测的新方法。利用静电纺丝法制备了聚苯乙烯纳米纤维膜,将其作为模板,通过自聚合作用,进行聚多巴胺功能化修饰,得到PDA-PS NFsM材料。对制得的PS NFsM和PDA-PS NFsM材料进行傅里叶红外光谱和场发射扫描电镜表征,证明PDA的成功修饰,修饰后的纳米纤维表面粗糙,呈现核-壳形貌,纤维内部为蜂窝状多孔结构。以空白加标样品的回收率为指标,对PDA-PS NFsM材料的用量、离子强度、样品溶液的流速、洗脱液和突破体积等影响SPE的因素进行考察及条件优化,确定了最佳的SPE条件。该方法对6种目标物的检出限为0.3~1.5 μg/kg,定量限为1.0~5.0 μg/kg,低于国家标准和行业标准;在各目标物的线性范围内均有良好的线性关系,决定系数(R²)大于0.999,方法的回收率为94.37%~102.82%,日间和日内的相对标准偏差(RSD)均小于10%,与国家标准和行业标准相当。通过固相萃取前后的基质效应对比,表明PDA-PS NFsM具有优秀的净化能力。最后,通过实际样品分析验证了方法的实际应用可行性。该文建立的基于PDA-PS NFsM材料的SPE方法是一种高效环保的方法,可为淡水鱼中药物残留的常规监测提供技术支持。

关键词: 超高效液相色谱-串联质谱, 固相萃取, 聚多巴胺, 纳米纤维膜, 药物残留, 淡水鱼

Abstract:

Tetracyclines and fluoroquinolones are common antibacterial drugs used in aquaculture, and their residues may pose a risk to human health. The low concentration of drug residues and complex matrixes such as fats and proteins in aquatic products necessitate the urgent development of efficient sample pretreatment methods. Solid phase extraction (SPE) is the most common sample pretreatment method, in which the core is an adsorbent. Compared with traditional SPE adsorbents, nanofiber mat (NFsM) has more interaction sites because of their large specific surface area. Furthermore, NFsMs modified with specific functional groups can significantly improve the extraction efficiency of tetracyclines and fluoroquinolones. Polydopamine (PDA) is spontaneously synthesized by the oxidative self-polymerization of dopamine-hydrochloride in alkaline solutions (pH>7.5). Because of its rich amino and catechol groups, PDA can form π-π stacking, electrostatic attraction, hydrophobic interaction, and hydrogen bonding interactions with target molecules. By exploiting the above advantages, polystyrene (PS) NFsM, as a template, was prepared by the electrostatic spinning method, and PDA-PS NFsM was obtained by functional modification of PDA through self-polymerization. Fourier transform infrared spectroscopy (FT-IR) and field-emission scanning electron microscopy (FESEM) were used to characterize the synthesized PS NFsM and PDA-PS NFsM. It was proved that PDA was successfully modified on the PS NFsM, with the SEM images revealing a rough outer core shell structure and an inner honeycomb structure. Subsequently, the handmade SPE column with PDA-PS NFsM was completed. A novel and efficient screening analytical method based on PDA-PS NFsM for the simultaneous determination of three tetracyclines (tetracycline (TET), chlortetracycline (CTC), and oxytetracycline (OTC)) and three fluoroquinolones (enrofloxacin (ENR), ciprofloxacin (CIP), and norfloxacin (NOR)) in fish by ultra performance liquid chromatography-tandem mass spectrometry (UPLC-MS/MS) was established. The SPE procedure was optimized to develop an efficient method for sample preparation. Evaluate parameters including the amount of NFsM usage, ionic strength, flow rate of the sample solution, composition of eluent, and breakthrough volume were investigated. Only (20±0.1) mg of PDA-PS NFsM was sufficient to completely adsorb the targets, and the analytes retained on NFsM could be eluted by 1 mL of formic acid-ethyl acetate (containing 20% methanol) (1∶99, v/v). The residues were redissolved in 0.1 mL 10% methanol aqueous solution containing 0.2% formic acid. In addition, no adjustment of the pH and ionic strength of the sample solutions was required, and the breakthrough volume was 50 mL. The limits of detection (LODs) and limits of quantification (LOQs) of the six target compounds were measured at 3 times and 10 times the signal-to-noise ratio (S/N), respectively. The LODs and LOQs were 0.3-1.5 μg/kg and 1.0-5.0 μg/kg, respectively. The linear ranges of the six target compounds were LOQ-1000 μg/kg, and the coefficient of determination (R²) was greater than 0.999. To evaluate the accuracy and precision, blank spiked samples at three levels (low, medium, and high) were prepared for the recovery experiments, and each level with six parallel samples (n=6). The recoveries ranged from 94.37% to 102.82%, with intra-day and inter-day relative standard deviations of 2.38% to 8.06% and 4.10% to 9.10%, respectively. To evaluate the purification capacity of PDA-PS NFsM, the matrix effects before and after SPE were calculated and compared. Matrix effects before SPE were -12.98% to -38.68%. After the completion of SPEbased on PDA-PS NFsM, the matrix effect of each target analyte was significantly reduced to -2.15% to -7.36%, which proved the significant matrix removal capacity of PDA-PS NFsM. Finally, the practicality of this method was evaluated by using it to analyze real samples. This SPE method based on PDA-PS NFsM is efficient, practical, and environmentally friendly, and it has great potential for use in the routine monitoring of drug residues in fish.

Key words: ultra performance liquid chromatography-tandem mass spectrometry (UPLC-MS/MS), solid phase extraction (SPE), polyaniline (PDA), nanofiber mat (NFsM), drug residues, fish

中图分类号:

O658

梁思慧, 戴海蓉, 张铧尹, 李建, 张秋萍, 许茜, 王春民. 聚多巴胺纳米纤维膜固相萃取-超高效液相色谱-串联质谱检测淡水鱼中四环素类和氟喹诺酮类药物残留[J]. 色谱, 2021, 39(6): 624-632.

LIANG Sihui, DAI Hairong, ZHANG Huayin, LI Jian, ZHANG Qiuping, XU Qian, WANG Chunmin. Determination of tetracycline and fluoroquinolone residues in fish by polydopamine nanofiber mat based solid phase extraction combined with ultra performance liquid chromatography-tandem mass spectrometry[J]. Chinese Journal of Chromatography, 2021, 39(6): 624-632.

图/表 10

参考文献

[1]	Rana M S, Lee S Y, Kang H J, et al. Food Sci Anim Resour, 2019,39(5):687
[2]	Wang J, James D M, Jack F K. Chemical Analysis of Antibiotic Residues in Food. New York: John Wiley & Sons, Inc., 2011
[3]	Wang H X, Ren L S, Yu X, et al. Food Control, 2017,80:217
[4]	Ministry of Agriculture. No. 235 Bulletin of the Ministry of Agriculture of the People’s Republic of China. (2002-12-24) [2020-12-20]. http://www.eshian.com/laws/17195.html
[4]	农业部. 中华人民共和国农业部公告第235号. (2002-12-24) [2020-12-20]. http://www.eshian.com/laws/17195.html
[5]	European Union. No. 37/2010 on Pharmacologically Active Substances and Their Classification Regarding Maximum Residue Limits in Foodstuffs of Animal Origin. (2009-12-22) [2020-12-20]. http://down.foodmate.net/standard/sort/44/28726.html
[6]	US Food and Drug Administration. Code of Federal Regulations-Code of Federal Regulations Title 21 Part 556 Tolerances for Residues of New Animal Drugs in Food.(2020-04-01) [2020-12-20]. https://www.accessdata.fda.gov/scripts/cdrh/cfdocs/cfCFR/CFRSearch.cfm?CFRPart=556&showFR=1
[7]	Canada Government. List of Maximum Residue Limits (MRLs) for Veterinary Drugs in Foods.(2017-08-02) [2020-12-20]. https://www.canada.ca/en/health-canada/services/drugs-health-products/veterinary-drugs/maximum-residue-limits-mrls/list-maximum-residue-limits-mrls-veterinary-drugs-foods.html
[8]	United States Department of Agriculture. FSIS National Residue Program Scheduled Sampling Plans. (2007-09-25) [2020-12-20]. https://www.fsis.usda.gov/wps/wcm/connect/bba66ce9-5a9f-4f08-bace-b6533b5103e4/2007_Blue_Book.pdf?MOD=AJPERES
[9]	Freitas A, Barbosa J, Ramos F. Food Anal Methods, 2015,9(1):23
[10]	Bousova K, Senyuva H, Mittendorf K. J Chromatogr A, 2013,1274:19
[11]	SC/T 3015-2002
[12]	GB/T 21317-2007
[13]	Ministry of Agriculture. Announcement No.1025 of the Ministry of Agriculture of the People’s Republic of China-14-2008. (2008-04-29) [2020-12-20]. http://down.foodmate.net/standard/yulan.php?itemid=17141
[13]	农业部. 中华人民共和国农业部1025号公告-14-2008. (2008-04-29) [2020-12-20]. http://down.foodmate.net/standard/yulan.php?itemid=17141
[14]	Santos L, Ramos F. Trends Food Sci Technol, 2016,52:16
[15]	Dickson L C. J Chromatogr B Analyt Technol Biomed Life Sci, 2014,967:203
[16]	Gbylik M, Posyniak A, Mitrowska K, et al. Food Addit Contam Part A Chem Anal Control Expo Risk Assess, 2013,30(6):940
[17]	Weng R, Sun L S, Jiang L P, et al. Food Anal Methods, 2019,12(7):1594
[18]	Liu X Y, Tong Y, Zhang L. Food Chem, 2020,303:125369
[19]	Nasir A N M, Yahaya N, Zain N N M, et al. Food Chem, 2019,276:458
[20]	Chu L L, Zheng S L, Qu B, et al. Food Chem, 2017,227:315
[21]	Augusto F, Hantao L W, Mogollón N G S, et al. TrAC-Trends Anal Chem, 2013,43:14
[22]	Chigome S, Torto N. TrAC-Trends Anal Chem, 2012,38:21
[23]	Xu Q, Yin X Y, Wu S Y, et al. Microchim Acta, 2010,168(3/4):267
[24]	Jian N G, Qian L L, Wang C M, et al. J Hazard Mater, 2019,363:81
[25]	Jian N G, Zhao M, Liang S H, et al. J Agric Food Chem, 2019,67(24):6892
[26]	Cao W X, Yang B Y, Qi F F, et al. J Chromatogr A, 2017,1491:16
[27]	Cao J K, Jiang Q, Li R X, et al. Talanta, 2019,204:753
[28]	Cao J K, Li R X, Liang S H, et al. Food Chem, 2020: 310
[29]	Qian L L, Li R X, Gao H T, et al. J Agric Food Chem, 2018,66(40):10588
[30]	Li X Q, Liu J J, Qi F F, et al. Chinese Journal of Analytical Chemistry, 2016,44(3):474
[30]	李晓晴, 刘静静, 祁菲菲, 等. 分析化学, 2016,44(3):474
[31]	Wang J L, Li B C, Li Z J, et al. Biomaterials, 2014,35(27):7679
[32]	Tang S, Zhang H, Lee H K. Anal Chem, 2016,88(1):228
[33]	Wang X Y, Deng C H. Talanta, 2016,148:387
[34]	Che D D, Cheng J, Ji Z Y, et al. TrAC-Trends Anal Chem, 2017,97:1
[35]	Chai W B, Wang H J, Zhang Y, et al. Talanta, 2016,149:13
[36]	Zhang W P, Zhou W, Chen Z L. J Sep Sci, 2014,37(21):3110
[37]	Chen D, Xu H. Mikrochim Acta, 2019,187(1):57
[38]	Hakova M, Havlikova L C, Chvojka J, et al. Mikrochim Acta, 2019,186(11):710
[39]	Zhao S Z, Sheng Y G, Zhang Y, et al. Journal of Isotope, 2020,33(5):312
[39]	赵善贞, 盛永刚, 张旖, 等. 同位素, 2020,33(5):312
[40]	Liang R J, Li X J, Liang G X. Chemical Enterprise Management, 2020,7(1):40
[40]	梁任佳, 李学劲, 梁光纤. 化工管理, 2020,7(1):40
[41]	Zhang G Y, Yang W Q, Lin Z Y. Journal of Fuzhou University (Natural Science Edition), 2019,47(3):424
[41]	张桂云, 杨伟强, 林振宇. 福州大学学报(自然科学版), 2019,47(3):424
[42]	Leslie C. J Chromatogr B, 2014,967:203

Compound	t_R/min	Precursor ion (m/z)	Product ions (m/z)	Collision energies/V	Cone voltage/V
Norfloxacin (NOR)	1.68	320.2	302.2^*, 276.2, 233.2	21, 16, 25	31
Ciprofloxacin (CIP)	1.72	332.2	288.2^*, 314.2	18, 19	31
Oxytetracycline (OTC)	1.74	461.3	426.3^*, 443.3, 201.2	19, 13, 37	26
Enrofloxacin (ENR)	1.78	360.3	316.3^*, 245.2, 342.1	18, 27, 23	41
Tetracycline (TET)	1.83	445.3	410.2^*, 154.1	18, 27	27
Chlortetracycline (CTC)	2.03	479.3	462.2^*, 444.2, 154.1	18, 22, 29	27

Compound	t_R/min	Precursor ion (m/z)	Product ions (m/z)	Collision energies/V	Cone voltage/V
Norfloxacin (NOR)	1.68	320.2	302.2^*, 276.2, 233.2	21, 16, 25	31
Ciprofloxacin (CIP)	1.72	332.2	288.2^*, 314.2	18, 19	31
Oxytetracycline (OTC)	1.74	461.3	426.3^*, 443.3, 201.2	19, 13, 37	26
Enrofloxacin (ENR)	1.78	360.3	316.3^*, 245.2, 342.1	18, 27, 23	41
Tetracycline (TET)	1.83	445.3	410.2^*, 154.1	18, 27	27
Chlortetracycline (CTC)	2.03	479.3	462.2^*, 444.2, 154.1	18, 22, 29	27

Compound	Linear range/ (μg/kg)	Linear equation	R²	LOD/ (μg/kg)	LOQ/ (μg/kg)
TET	2-1000	y=127.0x+128.2	0.9991	0.5	2.0
CTC	5-1000	y=120.0x+102.8	0.9999	1.5	5.0
OTC	5-1000	y=208.5x+29.4	0.9993	1.5	5.0
ENR	5-1000	y=201.2x+48.6	0.9997	1.0	5.0
CIP	2-1000	y=144.5x+48.0	0.9995	0.7	2.0
NOR	1-1000	y=176.8x+25.7	0.9998	0.3	1.0

Compound	Linear range/ (μg/kg)	Linear equation	R²	LOD/ (μg/kg)	LOQ/ (μg/kg)
TET	2-1000	y=127.0x+128.2	0.9991	0.5	2.0
CTC	5-1000	y=120.0x+102.8	0.9999	1.5	5.0
OTC	5-1000	y=208.5x+29.4	0.9993	1.5	5.0
ENR	5-1000	y=201.2x+48.6	0.9997	1.0	5.0
CIP	2-1000	y=144.5x+48.0	0.9995	0.7	2.0
NOR	1-1000	y=176.8x+25.7	0.9998	0.3	1.0

Compound	Spiked level/ (μg/kg)	Intra-day (n=6)/%		Inter-day (n=4)/%
Compound	Spiked level/ (μg/kg)	Recovery±SD	RSD	Recovery±SD	RSD
TET	2	102.13±6.17	6.04	96.58±8.79	9.10
	200	101.51±4.72	4.65	98.40±5.18	5.26
	1000	99.77±2.37	2.38	100.72±4.49	4.46
CTC	5	98.69±7.84	7.94	101.93±8.16	8.01
	200	98.94±6.23	6.30	97.48±5.76	5.91
	1000	101.24±5.97	5.90	98.34±4.76	4.84
OTC	5	94.37±7.61	8.06	97.65±7.37	7.55
	200	95.81±4.92	5.14	98.46±5.91	6.00
	1000	98.36±3.52	3.58	99.04±4.06	4.10
ENR	5	101.63±7.55	7.43	102.68±7.96	7.75
	200	98.23±7.43	7.56	94.99±6.08	6.40
	1000	99.58±4.66	4.68	96.02±4.97	5.18
CIP	2	101.37±6.88	6.79	95.27±7.93	8.32
	200	97.28±4.96	5.10	96.04±5.12	5.33
	1000	99.79±4.79	4.80	97.55±4.28	4.39
NOR	1	102.82±6.50	6.32	95.07±8.35	8.78
	200	98.77±4.35	4.40	98.13±6.21	6.33
	1000	100.43±3.96	3.94	100.24±4.96	4.95

聚多巴胺纳米纤维膜固相萃取-超高效液相色谱-串联质谱检测淡水鱼中四环素类和氟喹诺酮类药物残留

Determination of tetracycline and fluoroquinolone residues in fish by polydopamine nanofiber mat based solid phase extraction combined with ultra performance liquid chromatography-tandem mass spectrometry

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

扫码分享

图/表 10

参考文献

相关文章 15

编辑推荐

Metrics

Detection method	Adsorbents	Linear range/ (μg/kg)		LOD/ (μg/kg)	Recovery/%		RSD/%		Ref.
LC-MS/MS	C18 (50 mg)	-		0.1-10	70-	120	2.56-	17.18	[39]
UPLC-MS/MS	C18 (100 mg)	5-	100	0.1-10	80.1-	124.8	0.87-	20.09	[40]
UPLC-MS/MS	PSA (200 mg) and C18 (50 mg)	0.2-	200	0.1-1.6	81.6-	96.6	3.6-	9.2	[41]
LC-MS/MS	C18 (500 mg)	5-	50	0.5-5.0	47-	99	4-	17	[42]
UPLC-MS/MS	PDA-PS NFsM (20 mg)	1-	1000	0.3-1.5	94.37-	102.82	2.38-	9.10	this method

[1]	赵芮, 黄晴雯, 余智颖, 韩铮, 范楷, 赵志辉, 聂冬霞. QuEChERS-超高效液相色谱-串联质谱法同时测定水果中36种真菌毒素[J]. 色谱, 2023, 41(9): 760-770.
[2]	岳超, 赵超群, 毛思浩, 王展华, 施贝, 徐欣丰, 梁晶晶. 通过式固相萃取净化-超高效液相色谱-串联质谱法测定液体乳中10种氨基甲酸酯类农药残留[J]. 色谱, 2023, 41(9): 807-813.
[3]	孟二琼, 念琪循, 李峰, 张秋萍, 许茜, 王春民. 磺酸化磁性氮化碳固相萃取-超高液相色谱-串联质谱筛检淡水鱼中孔雀石绿和隐色孔雀石绿[J]. 色谱, 2023, 41(8): 673-682.
[4]	高祎阳, 丁亚丽, 陈鲁玉, 杜芳, 辛绪波, 冯娟娟, 孙明霞, 冯洋, 孙敏. 共价有机框架材料在固相萃取中的最新应用进展[J]. 色谱, 2023, 41(7): 545-553.
[5]	秦童童, 高莉, 赵文杰. 超交联多孔有机聚合物在柱固相萃取中的应用进展[J]. 色谱, 2023, 41(7): 554-561.
[6]	陈东洋, 张昊, 张磊, 王一红, 王小丹, 冯家力, 梁静, 钟旋. 固相萃取-超高效液相色谱-串联质谱法测定发酵食品中的曲酸[J]. 色谱, 2023, 41(7): 632-639.
[7]	王秋旭, 冯启言, 朱雪强. 加速溶剂萃取-固相萃取净化结合超高效液相色谱-串联质谱法测定沉积物中双酚类化合物[J]. 色谱, 2023, 41(7): 582-590.
[8]	夏宝林, 汪仕韬, 殷晶晶, 张维益, 杨娜, 刘强, 吴海晶. 自动上样固相萃取-超高效液相色谱-串联质谱法同时测定水中9类43种抗菌药物残留[J]. 色谱, 2023, 41(7): 591-601.
[9]	赵原庆, 胡锴, 杨成, 韩鹏昭, 李立新, 刘晓冰, 张振强, 张书胜. 基于Ti₃C₂T_x/聚酰亚胺复合材料的分散固相萃取-液相色谱法测定尿液中儿茶酚胺类神经递质[J]. 色谱, 2023, 41(7): 572-581.
[10]	童学智, 陈东洋, 冯家力, 范翔, 张昊, 杨胜园. QuEChERS-超高效液相色谱-串联质谱法快速测定水产品中5种卤代苯醌[J]. 色谱, 2023, 41(6): 490-496.
[11]	王园媛, 李璐璐, 吕佳, 陈永艳, 张岚. 固相萃取-超高效液相色谱-三重四极杆质谱法测定饮用水中13种卤代苯醌类消毒副产物[J]. 色谱, 2023, 41(6): 482-489.
[12]	宁晓盼, 姚倩, 许忠祥, 殷耀, 柳菡, 张晓燕, 丁涛, 张勇, 侯玉, 王梦茹, 吴丽娜, 汤奇婷. 固相萃取-高效液相色谱法测定水产调味品中7种对羟基苯甲酸酯类防腐剂[J]. 色谱, 2023, 41(6): 513-519.
[13]	曾永福, 陈美芳, 邵雨, 闫永欢, 张海超, 王敬, 艾连峰, 康维钧. 植物中27种典型药品及个人护理品多残留检测方法的建立及其在芽苗菜中迁移规律的分析[J]. 色谱, 2023, 41(5): 386-396.
[14]	李振环, 胡小键, 陆一夫, 谢琳娜, 朱英. 基于高通量全自动固相萃取的超高效液相色谱-串联质谱法测定人尿中16种抗生素和4种β-受体激动剂[J]. 色谱, 2023, 41(5): 397-408.
[15]	宋新力, 王宁, 何飞燕, 程灿玲, 王飞, 王京龙, 张立华. 碳纳米管复合材料结合分散固相萃取-高效液相色谱-串联质谱法检测环境水样中痕量全氟化合物[J]. 色谱, 2023, 41(5): 409-416.