超高效液相色谱-串联质谱法测定尿液中7种苯系物代谢物

doi:10.3724/SP.J.1123.2022.05016

摘要/Abstract

摘要：

建立了同时测定人体尿液中7种苯系物代谢物的超高效液相色谱-串联质谱检测方法。0.5 mL尿液经盐酸水解、EVOLUTE^®EXPRESS ABN固相萃取板(10 mg)净化、洗脱、稀释后测定。使用ACQUITY UPLC HSS T3色谱柱(100 mm×2.1 mm, 1.8 μm),以0.1%甲酸水溶液和甲醇作为流动相进行梯度洗脱,分离目标化合物,负离子电喷雾多反应监测模式下测定含量。7种目标化合物在各自范围内线性关系良好,相关系数(r²)>0.995;方法检出限为马尿酸(HA)0.9 mg/L,其余目标化合物0.02~4 μg/L,定量限为HA 3 mg/L,其余目标化合物0.05~12 μg/L;在实际尿液中低、中、高3个水平的加标回收率为84%~123%,日内精密度为1.8%~8.6%,日间精密度为1.9%~21.4%。应用该方法测定吸烟和非吸烟人群尿液样品各16份,吸烟人群中7种目标化合物检出率均为100%;非吸烟人群中反-反式黏糠酸(MU)、苄基巯基尿酸(BMA)、HA和2-甲基马尿酸(2MHA)的检出率为100%, (S)-苯巯基尿酸(PMA)的检出率为75%, 3-甲基马尿酸(3MHA)+4-甲基马尿酸(4MHA)的检出率为81%; MU、PMA、2MHA和3MHA+4MHA在吸烟和非吸烟人群尿液中的浓度具有统计学差异(p<0.001)。该方法样品用量少,可进行高通量测定,结果可靠,适用于人体尿液中7种苯系物代谢物的含量测定。

关键词: 超高效液相色谱-串联质谱, 苯系物代谢物, 生物监测, 尿液

Abstract:

Monoaromatic hydrocarbons (MAHs) such as benzene, toluene, and xylene are important anthropogenic pollutants in the urban atmosphere. The detection of urinary MAH metabolites are included in human biomonitoring programs in several countries, including Canada, the United States, Italy, and Germany, because their evaluation is vital to monitor the exposure of humans to MAHs. To this end, herein, a method was developed for the determination of seven MAH metabolites through ultra performance liquid chromatography-tandem mass spectrometry (UPLC-MS/MS). An aliquot of 0.5 mL urine was fortified with an isotopic labeled internal standard solution before being hydrolyzed by 40 μL of 6 mol/L HCl solution, followed by extraction using a 96-well EVOLUTE^®EXPRESS ABN solid-phase extraction plate. The samples were washed with 1.0 mL of methanol-water (10∶90, v/v) and eluted with 1.0 mL methanol. The eluate was diluted four times with water prior to use in instrumental analysis. Chromatographic separation was achieved using an ACQUITY UPLC HSS T3 column (100 mm×2.1 mm, 1.8 μm), with gradient elution using 0.1% formic acid as mobile phase A and methanol as mobile phase B. The detection of seven analytes was performed using a triple-quadrupole mass spectrometer equipped with a negative electrospray ionization source in the multiple reaction monitoring mode. The linear ranges of the seven analytes varied from 0.1-20 μg/L to 2.5-500 mg/L, with correlation coefficients greater than 0.995. The method detection limits were 1.5, 0.02, 0.1, 900, 0.6, and 4 μg/L for trans,trans-muconic acid (MU), S-phenylmercapturic acid (PMA), S-benzylmercapturic acid (BMA), hippuric acid (HA), 2-methyl hippuric acid (2MHA), and 3-methyl hippuric acid (3MHA)+4-methyl hippuric acid (4MHA), respectively. The limits of quantification were 5, 0.05, 0.4, 3000, 2, and 12 μg/L for MU, PMA, BMA, HA, 2MHA, and 3MHA+4MHA, respectively. The method was verified by spiking urine samples at three different concentration levels, with recovery rates ranging from 84% to 123%. The intra- and inter-day precisions were 1.8%-8.6% and 1.9%-21.4%, respectively. The extraction efficiencies were 68%-99%, and the matrix effects ranged from -11% to -87%. The urine samples obtained from the German external quality assessment scheme (round 65) were used to assess the accuracy of this method. Both high and low concentrations of MU, PMA, HA, and methyl hippuric acid were within the tolerance range. All analytes in the urine samples were found to be stable for up to seven days at room temperature (20 ℃, absence of light), with less than 15% change in concentration. Analytes in urine samples were found to be stable for at least 42 d at 4 ℃ and -20 ℃, or for six freeze-thaw cycles and up to 72 h in an autosampler (8 ℃). The method was applied to the analysis of 16 non-smokers’ and 16 smokers’ urine samples. The detection rates of MU, BMA, HA, and 2MHA were 100% in both non-smokers’ and smokers’ urine samples. PMA was detected in 75% non-smokers’ and 100% smokers’ urine samples. 3MHA+4MHA was detected in 81% non-smokers’ urine and in all smokers’ urine samples. Statistical differences were found for MU, PMA, 2MHA, and 3MHA+4MHA between the two groups (p<0.001). The established method has good robustness and can provide reliable results. The experiments were carried out in a high-throughput manner with large sample sizes, owing to the small sample volume, and allowed the successful detection of the seven MAH metabolites in human urine.

Key words: ultra performance liquid chromatography-tandem mass spectrometry (UPLC-MS/MS), monoaromatic hydrocarbon metabolites, biomonitoring, urine

中图分类号:

O658

邱天, 张续, 杨艳伟, 胡小键, 罗嵩, 朱英. 超高效液相色谱-串联质谱法测定尿液中7种苯系物代谢物[J]. 色谱, 2023, 41(4): 366-375.

QIU Tian, ZHANG Xu, YANG Yanwei, HU Xiaojian, LUO Song, ZHU Ying. Determination of seven monoaromatic hydrocarbon metabolites by ultra performance liquid chromatography-tandem mass spectrometry[J]. Chinese Journal of Chromatography, 2023, 41(4): 366-375.

图/表 12

参考文献

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Analyte	Formula	CAS No.	Median level
trans, trans-Muconic acid (MU)	C₆H₆O₄	3588-17-8	52	μg/L^[22]
S-Phenylmercapturic acid (PMA)	C₁₁H₁₃NO₃S	4775-80-8	0.097	g/g crea (non-smokers), 1.1 μg/g crea (smokers)^[12]
S-Benzylmercapturic acid (BMA)	C₁₂H₁₅NO₃S	19542-77-9	6.1	μg/L^[10]
Hippuric acid (HA)	C₉H₉NO₃	495-69-2	180	mg/g crea^[23]
2-Methyl hippuric acid (2MHA)	C₁₀H₁₁NO₃	42013-20-7	30	μg/L^[22]
3-Methyl hippuric acid (3MHA)	C₁₀H₁₁NO₃	27115-49-7	194	μg/L^[10]
4-Methyl hippuric acid (4MHA)	C₁₀H₁₁NO₃	27115-50-0

Analyte	Formula	CAS No.	Median level
trans, trans-Muconic acid (MU)	C₆H₆O₄	3588-17-8	52	μg/L^[22]
S-Phenylmercapturic acid (PMA)	C₁₁H₁₃NO₃S	4775-80-8	0.097	g/g crea (non-smokers), 1.1 μg/g crea (smokers)^[12]
S-Benzylmercapturic acid (BMA)	C₁₂H₁₅NO₃S	19542-77-9	6.1	μg/L^[10]
Hippuric acid (HA)	C₉H₉NO₃	495-69-2	180	mg/g crea^[23]
2-Methyl hippuric acid (2MHA)	C₁₀H₁₁NO₃	42013-20-7	30	μg/L^[22]
3-Methyl hippuric acid (3MHA)	C₁₀H₁₁NO₃	27115-49-7	194	μg/L^[10]
4-Methyl hippuric acid (4MHA)	C₁₀H₁₁NO₃	27115-50-0

Analyte	Retention time/min	Ion pairs (m/z)	Declustering potentials/V	Collision energies/eV
MU	4.7	141>53^*, 141>97, 141>59	-20, -20, -20	-16, -12, -15
PMA	7.7	238>109^*, 239>110	-10, -20	-13, -13
BMA	7.8	252>123^*, 253>124	-20, -20	-17, -22
HA	6.6	178>160^*, 178>133	-20, -20	-10, -20
2MHA	7.0	192>91^*, 192>148, 192>174	-20, -20, -20	-20, -15, -10
3MHA & 4MHA	7.4	192>91^*, 192>148, 192>174	-20, -20, -20	-15, -15, -10
MU-d4	4.7	145>100	-10	-11
PMA-d2	7.7	240>109	-20	-27
BMA-d3	7.8	255>123	-20	-20
HA-d5	6.6	183>139	-20	-17
2MHA-d7	7.0	199>155	-65	-16
3MHA-d7 & 4MHA-d7	7.3	199>155	-20	-16

Analyte	Retention time/min	Ion pairs (m/z)	Declustering potentials/V	Collision energies/eV
MU	4.7	141>53^*, 141>97, 141>59	-20, -20, -20	-16, -12, -15
PMA	7.7	238>109^*, 239>110	-10, -20	-13, -13
BMA	7.8	252>123^*, 253>124	-20, -20	-17, -22
HA	6.6	178>160^*, 178>133	-20, -20	-10, -20
2MHA	7.0	192>91^*, 192>148, 192>174	-20, -20, -20	-20, -15, -10
3MHA & 4MHA	7.4	192>91^*, 192>148, 192>174	-20, -20, -20	-15, -15, -10
MU-d4	4.7	145>100	-10	-11
PMA-d2	7.7	240>109	-20	-27
BMA-d3	7.8	255>123	-20	-20
HA-d5	6.6	183>139	-20	-17
2MHA-d7	7.0	199>155	-65	-16
3MHA-d7 & 4MHA-d7	7.3	199>155	-20	-16

Compound	Spiked/ (μg/L)	Recovery/ %	Intra-day precision/%	Inter-day precision/%
MU	10.0	113	3.5	7.1
	100	106	2.0	5.7
	1000	104	3.9	4.5
PMA	0.2	105	4.9	7.9
	2.0	101	6.3	3.3
	20	108	8.6	1.9
BMA	2.0	104	2.8	7.6
	20.0	103	1.8	3.0
	200	105	3.2	3.5
HA	1000	86	5.0	21.4
	10000	84	3.6	14.5
	100000	85	2.8	6.1
2MHA	2.0	111	2.9	4.1
	20.0	103	3.3	3.1
	200	106	4.7	3.2
3MHA+4MHA	2.0	109	8.2	4.1
	20.0	123	4.2	5.4
	200	119	7.3	4.7