高通量自动化免疫磁珠净化-超高效液相色谱法检测饲料中4种黄曲霉毒素

doi:10.3724/SP.J.1123.2022.09006

摘要/Abstract

摘要：

黄曲霉毒素(AFT)是一种毒性极强的剧毒物质,具有致癌性。饲料原料及产品在生产、运输和储藏等过程存在被黄曲霉毒素污染的风险。该文建立了高通量自动化免疫磁珠净化-超高效液相色谱法测定饲料中4种黄曲霉毒素(黄曲霉毒素B₁(AFB₁)、黄曲霉毒素B₂(AFB₂)、黄曲霉毒素G₁(AFG₁)和黄曲霉毒素G₂(AFG₂))的分析方法。饲料样品用乙腈-水(70∶30, v/v)提取,经免疫磁珠自动净化后,使用超高效液相色谱进行分析测试。对磁珠与抗体的偶联比例、免疫磁珠与黄曲霉毒素的反应时间、样品提取液和稀释液等关键实验条件进行了优化,考察了不同饲料样品的净化效果。在优化条件下,豆粕、玉米干酒糟及其可溶物、猪饲料和鸡饲料等4种常见饲料样品在3个水平(5、20和40 μg/kg,以AFB₁计)下的加标回收率在91.1%~119.4%之间,相对标准偏差小于6.9%;日间精密度为4.5%~7.5%,该方法具有良好的重复性。采用该法检测质量控制样品中AFB₁的含量,平均值为18.6 μg/kg(n=3),准确度为110.3%,测试结果满意。使用该法测试了21种随机购买的饲料样品,其中有4份样品测出含有AFB₁。本方法所使用的自动净化系统能够自动净化饲料中的4种黄曲霉毒素,并实现样品的批量处理,每批可最多同时净化24个样品,批处理总用时约为30 min;超高效液相色谱法分析速度快,准确性高,可用于检测饲料中黄曲霉毒素的含量。

关键词: 免疫磁珠, 自动净化, 超高效液相色谱, 黄曲霉毒素, 饲料

Abstract:

Aflatoxin (AFT) is an extremely toxic and highly toxic carcinogenic substance. This is particularly problematic due to the risk of aflatoxin contamination in raw feed materials and products during production, transportation, and storage. In this study, immunoaffinity magnetic beads (IMBs) were prepared for the purification of four aflatoxins (aflatoxin B₁ (AFB₁), aflatoxin B₂ (AFB₂), aflatoxin G₁ (AFG₁) and aflatoxin G₂ (AFG₂)). The aflatoxin contents were then determined rapidly and accurately using ultra performance liquid chromatography (UPLC). More specifically, the coupling ratio of magnetic beads (MBs) to the aflatoxin monoclonal antibody was initially optimized, wherein an MB volume of 1 mL and an antibody content of 2.0 mg was found to meet the purification requirements of this method. The magnetic properties of the MBs and the IMBs were then investigated using a vibrating sample magnetometer (VSM) at room temperature. As a result, the maximum saturation super magnetizations of the MBs and the IMBs were determined to be 28.61 and 23.22 emu/g, respectively, indicating that the saturation magnetization intensity of the IMBs was reduced by coupling with a non-magnetic antibody. However, the saturation magnetization intensity remained sufficiently high to permit magnetic separation from the solution. In addition, the appearance of the IMBs was examined using a biomicroscope, and it was clear that the magnetic cores were wrapped in agarose gel. Furthermore, the reaction time between the IMBs and the aflatoxins was investigated, and the optimal reaction time for meeting the purification requirements was determined to be 2 min. The stability of the IMBs was then evaluated under refrigerated storage conditions at 4 ℃. It was found that the prepared IMBs maintained a high aflatoxin enrichment capacity for at least eight months. Through the examination of three different extraction solutions, a mixture of acetonitrile and water (70∶30, v/v) was found to be optimal for the extraction of aflatoxins from the feed samples. Moreover, five sample dilutions and purification effects were also examined, and phosphate-buffered saline (containing 0.5% Tween-20) was selected as the preferred sample dilutant. With the optimized conditions, the effectiveness of using IMB for the purification of different feed samples was investigated.

The resulting UPLC chromatogram showed no spurious peaks close to the target peaks, demonstrating a good purification performance. Following matrix spiking (5, 20, and 40 μg/kg, calculated based on AFB₁) of the four feed samples (i. e., soybean meal, distillers dried grains with solubles, pig feed, and chicken feed), the spiked recoveries of the four aflatoxins ranged from 91.1% to 119.4% with a relative standard deviation (RSD) of <6.9%. In addition, the inter-day precision was 4.5% to 7.5%, and the method exhibited a good reproducibility. Subsequently, the developed method was used to detect AFB₁ using reference materials. The test value was 18.6 μg/kg with an accuracy of 110.3%, thereby constituting satisfactory results. Upon testing 21 randomly purchased feed samples using this method, four of these samples contained AFB₁, and the test results obtained using the developed method and stable isotope dilution LC-MS/MS were comparable. It was therefore apparent that the IMB purification method combined with UPLC analysis exhibited a good accuracy for aflatoxin determination. Thus, an automatic purification system was established to facilitate the operation and use of IMBs. This system was able to purify 24 samples simultaneously in 30 min. An IMB purification kit for was also designed and produced for aflatoxin detection in feed samples. The kit contained the sample dilutant, IMBs, the washing solution, and the eluent. After extraction of the feed sample, the extraction solution was added to the sample wells provided in the kit, and the purification system automatically completed the steps of aflatoxin enrichment, impurity washing, and elution of the target toxin. It should be noted that the purification process does not require the operator to manually add the solution, thereby simplifying operation. Overall, the purification method established in this study achieved the high-throughput and automatic purification of the four aflatoxins in feed samples.

Key words: immunoaffinity magnetic beads (IMB), automatic purification, ultra performance liquid chromatography (UPLC), aflatoxins, feeds

中图分类号:

O658

陈金男, 王蒙, 董泽民, 叶金, 李丽, 吴宇, 刘洪美, 王松雪. 高通量自动化免疫磁珠净化-超高效液相色谱法检测饲料中4种黄曲霉毒素[J]. 色谱, 2023, 41(6): 504-512.

CHEN Jinnan, WANG Meng, DONG Zemin, YE Jin, LI Li, WU Yu, LIU Hongmei, WANG Songxue. Determination of four aflatoxins in feeds by high throughput automated immunoaffinity magnetic beads purification-ultra performance liquid chromatography[J]. Chinese Journal of Chromatography, 2023, 41(6): 504-512.

图/表 9

图1 (a)黄曲霉毒素免疫磁珠的制备示意图和(b)免疫磁珠自动净化系统工作流程示意图

Fig. 1 (a) Schematic diagram of preparation of IMB-AFTs and (b) work flow diagram of automatic purification system for IMB

图2 (a)磁珠与不同量的抗体偶联的AFTs加标回收率(n=3)及最大吸附量、(b)MB和IMB的常温VSM图和(c)IMB的显微镜图

Fig. 2 (a) Recoveries (n=3) and maximum adsorption capacities of AFTs of MB coupled with different amounts of antibodies, (b) VSM diagrams at room temperature of MB and IMB and (c) microscope diagram of IMB AFB1: aflatoxin B1; AFB2: aflatoxin B2; AFG1: aflatoxin G1; AFG2: aflatoxin G2; MB: magnetic bead; VSM: vibrating sample magnetometer. Agarose-modified microsphere and MB core are located inside the red and blue circles, respectively.

图3 黄曲霉毒素免疫磁珠的稳定性测试结果(n=3)

Fig. 3 Stability test results of IMB-AFTs (n=3)

图4 在不同反应时间下免疫磁珠与黄曲霉毒素的结合效率(n=3)

Fig. 4 Binding efficiencies of IMB with AFTs under different reaction time (n=3)

图5 不同提取液对黄曲霉毒素回收率的影响(n=3)

Fig. 5 Effect of different extraction solutions on the recoveries of AFTs (n=3)

图6 (a)不同稀释液对AFTs回收率的影响(n=3)和(b)免疫磁珠净化的不同饲料样品的UPLC色谱图

Fig. 6 (a) Effect of different dilution solutions on the recoveries of AFTs (n=3) and (b) UPLC chromatograms of different feed samples purified by IMB DDGS: distillers dried grains with solubles.

表1 不同饲料样品中黄曲霉毒素的加标回收率和RSD(n=3)

Table 1 Recoveries and RSDs of AFTs in different feed samples (n=3)

Substrate	Spiked level/ (μg/kg)	AFB₁		AFB₂		AFG₁		AFG₂
Substrate	Spiked level/ (μg/kg)	Recovery/%	RSD/%	Recovery/%	RSD/%	Recovery/%	RSD/%	Recovery/%	RSD/%
Soybean	5	99.7	4.8	108.8	2.4	100.1	6.6	104.7		3.2
meal	20	98.3	1.2	109.9	1.4	98.4	0.5	104.8		2.0
	40	95.4	1.4	107.0	0.9	95.2	1.7	99.8		1.3
DDGS	5	119.4	5.4	113.2	1.5	94.7	1.4	103.7		0.8
	20	99.1	0.7	105.5	0.4	92.8	1.6	100.6		0.5
	40	94.7	0.6	103.1	1.4	92.2	2.4	97.6		1.4
Pig feed	5	116.0	3.9	116.8	2.0	112.3	1.9	107.2		4.9
	20	112.3	1.4	114.0	1.8	105.8	2.2	112.9		1.9
	40	110.7	3.3	113.8	2.7	110.2	2.0	113.8		1.6
Chicken	5	91.9	6.9	112.5	1.9	93.2	2.0	105.9		1.7
feed	20	97.9	3.1	114.8	1.1	94.8	1.0	105.6		1.5
	40	92.1	0.8	110.2	1.0	91.1	2.1	99.3		0.2

表2 两种检测方法对21种饲料样品的测试结果

Table 2 Determination results of 21 feed samples by two methods

No.	Feed	AFB₁/(μg/kg)		No.	Feed	AFB₁/(μg/kg)		No.	Feed	AFB₁/(μg/kg)
No.	Feed	This method	Ref. [32]	No.	Feed	This method	Ref. [32]	No.	Feed	This method	Ref. [32]
1	chicken feed	18.0	20.6	8	sheep feed	<LOD	<LOD	15	cattle feed	<LOD		<LOD
2	chicken feed	38.6	41.9	9	cattle feed	<LOD	<LOD	16	cattle feed	5.1		6.2
3	chicken feed	<LOD	<LOD	10	cattle feed	<LOD	<LOD	17	cattle feed	<LOD		<LOD
4	sheep feed	<LOD	<LOD	11	cattle feed	<LOD	<LOD	18	cattle feed	<LOD		<LOD
5	sheep feed	7.3	9.5	12	cattle feed	<LOD	<LOD	19	pig feed	<LOD		<LOD
6	sheep feed	<LOD	<LOD	13	cattle feed	<LOD	<LOD	20	soybean meal	<LOD		<LOD
7	sheep feed	<LOD	<LOD	14	cattle feed	<LOD	<LOD	21	DDGS	<LOD		<LOD

图7 采用(a)本方法和(b)稳定同位素稀释-LC-MS/MS 检测阳性样品及阳性加标样品时的色谱图

Fig. 7 Chromatograms of positive and positive spiked samples detected by (a) this method and (b) stable isotope dilution-LC-MS/MS

参考文献

[1]	Medina M L J, Lafarga T, Frenich A G, et al. Food Rev Int, 2021, 37(1-4): 244
[2]	Beheshti H R, Asadi M. Food Addit Contam B, 2014, 7(1): 40
[3]	Twaruek M, Skrzydlewski P, Kosicki R. Toxicon, 2021, 202: 27
[4]	Gao P, Huang Z W, Zhao P P. Cereal & Feed Industry, 2019, 387(7): 62
[4]	高平, 黄志伟, 赵盼盼. 粮食与饲料工业, 2019, 387(7): 62
[5]	Wang X K, Park S G, Ko J H, et al. Small, 2018, 14(39): e1801623
[6]	Hou Z Z, Feng Z Q, Lin D. Cereal & Feed Industry, 2016, 349(5): 62
[6]	侯真真, 冯志强, 林丹. 粮食与饲料工业, 2016, 349(5): 62
[7]	Wang J, Wang G Q, Li F, et al. Journal of Food Safety & Quality, 2021, 12(15): 6275
[7]	王娟, 王改琴, 李钒, 等. 食品安全质量检测学报, 2021, 12(15): 6275
[8]	International Agency for Research on Cancer IARC. IARC Monographs on the Evaluation of Carcinogenic Risks to Humans. Lyon: IARC Press, 2002
[9]	Hove M, Van Poucke C, Njumbe-Ediage E, et al. Food Control, 2016, 59: 675
[10]	Li L, Li R, Xie G, et al. Journal of Instrumental Analysis, 2017, 36(6): 800
[10]	李丽, 黎睿, 谢刚, 等. 分析测试学报, 2017, 36(6): 800
[11]	GB 13078-2007
[12]	Iqbal S Z, Asi M R, Jinap S. Food Control, 2014, 43: 163
[13]	Wang W G, Qiang M, Duan L Q. Chinese Journal of Chromatography, 2018, 36(12): 1330
[13]	王韦岗, 强敏, 端礼钦. 色谱, 2018, 36(12): 1330
[14]	Wang Q, Liu H, Li Q X, et al. Journal of Food Safety & Quality, 2018, 9(22): 5888
[14]	王勤, 刘辉, 李秋霞, 等. 食品安全质量检测学报, 2018, 9(22): 5888
[15]	Liu F, Ren A S, Ge P, et al. Journal of Instrumental Analysis, 2018, 37(6): 696
[15]	刘飞, 任安书, 葛萍, 等. 分析测试学报, 2018, 37(6): 696
[16]	Fan Z C, Han Z, Guo W B, et al. Chinese Journal of Chromatography, 2017, 35(6): 627
[16]	范志辰, 韩铮, 郭文博, 等. 色谱, 2017, 35(6): 627
[17]	Karaseva N M, Amelin V G, Tret’yakov A V. J Anal Chem, 2014, 69(5): 461
[18]	Liu H M, Xuan Z H, Ye J, et al. Toxins, 2022, 14(2): 93
[19]	Chen J N, Ye J, Guo X G, et al. Food Science, 2021, 42(22): 318
[19]	陈金男, 叶金, 郭旭光, 等. 食品科学, 2021, 42(22): 318
[20]	Liu C M, Yang X, Chen X Y, et al. Cereal & Feed Industry, 2019, 385(5): 61
[20]	刘成模, 杨曦, 陈小燕, 等. 粮食与饲料工业, 2019, 385(5): 61
[21]	Liao X F, Jia B Y, Sun C N, et al. Microchem J, 2020, 157: 105007
[22]	Xie G, Wang S X, Zhang Y. Chinese Journal of Analytical Chemistry, 2013, 41(2): 223
[22]	谢刚, 王松雪, 张艳. 分析化学, 2013, 41(2): 223
[23]	Li L, Wu Y, Wang H B, et al. Journal of the Chinese Cereals and Oils, 2020, 35(7): 157
[23]	李丽, 吴宇, 王海波, 等. 中国粮油学报, 2020, 35(7): 157
[24]	Li X H, Lu Y Y, Dong Y Z, et al. Chinese Journal of Chromatography, 2022, 40(8): 694
[24]	李晓晗, 路莹莹, 董永贞, 等. 色谱, 2022, 40(8): 694
[25]	Wei Y J, Feng M, Zhu Z Y, et al. Chinese Journal of Chromatography, 2017, 35(8): 891
[25]	魏云计, 冯民, 朱臻怡, 等. 色谱, 2017, 35(8): 891
[26]	Wu Y, Ye J, Xuan Z H, et al. Food Addit Contam A, 2021, 38(1): 148
[27]	Wu Y, Xin Y Y, Ye J, et al. Food Science, 2017, 38(18): 297
[27]	吴宇, 辛媛媛, 叶金, 等. 食品科学, 2017, 38(18): 297
[28]	Meng F L, Song Z F, Tan L, et al. Feed Industry, 2019, 40(6): 50
[28]	孟繁磊, 宋志峰, 谭莉, 等. 饲料工业, 2019, 40(6): 50
[29]	Oulkar D, Goon A, Dhanshetty M, et al. J Environ Sci Heal B, 2018, 53: 255
[30]	Ye J, Xuan Z H, Zhang B, et al. Food Control, 2019, 104: 57
[31]	Shang Q Q, Xiong P W, Liang Q, et al. Feed Research, 2015(22): 55
[31]	尚沁沁, 熊平文, 梁权, 等. 饲料研究, 2015(22): 55
[32]	Ye J, Wu Y, Xin Y Y, et al. Journal of Instrumental Analysis, 2017, 36(4): 449
[32]	叶金, 吴宇, 辛媛媛, 等. 分析测试学报, 2017, 36(4): 449