气相色谱-三重四极杆质谱法同时测定纺织品中11种挥发性全氟化合物前体物

doi:10.3724/SP.J.1123.2021.01043

摘要/Abstract

摘要：

以甲醇为提取溶剂,超声辅助提取纺织品中的全氟化合物前体物,建立了一种气相色谱-三重四极杆质谱(GC-MS/MS)法同时测定纺织品中11种挥发性全氟化合物前体物:4种氟调聚物醇(FTOHs)、3种氟调聚丙烯酸酯(FTAs)、2种全氟辛基磺酰胺(FOSAs)和2种全氟辛基磺酰胺乙醇(FOSEs)。考察了超声提取溶剂、提取温度和提取时间对提取效率的影响,最终确定用甲醇为提取溶剂,70 ℃下超声提取60 min,目标物经VF-WAXms毛细管柱(30 m×0.25 mm×0.25 μm)程序升温分离,GC-MS/MS多反应监测(MRM)模式检测,外标法定量。实验结果表明:11种挥发性全氟化合物前体物在10~500 μg/L范围内线性关系良好,相关系数(r)均不低于0.9984;以信噪比为3计算,检出限(LOD)为0.002~0.04 mg/kg;以信噪比为10计算,定量限(LOQ)为0.006~0.1 mg/kg;不同材质纺织品中,11种挥发性全氟化合物前体物在高、中、低3个添加水平下的回收率为73.2%~117.2%,相对标准偏差(RSD)为0.1%~9.4%(n=6)。该方法前处理简单,定性、定量准确,灵敏度高,重现性好,可有效用于纺织品中11种挥发性全氟化合物前体物的同时检测。实际样品分析发现,当前全氟化合物前体物已被应用于纺织品整理当中。该方法的建立对我国纺织品中全氟化合物前体物风险物质的管控和检测标准的制定具有一定的理论和现实意义。

关键词: 气相色谱-串联质谱法, 全氟化合物前体物, 纺织品

Abstract:

Perfluorinated compounds (PFCs) are persistent organic compounds. PFCs are artificially prepared hydrocarbons in which hydrogen atoms are completely replaced by fluorine. PFCs have excellent thermal stability and chemical stability, high surface activity, and hydrophobic and/or oleophobic properties owing to their exceptionally strong C-F bonds, low polarizability, and weak intermolecular van der Waals interactions. Currently, PFCs and their precursors are widely used in textile production as finishing agents and surfactants. In recent years, increasing attention has been devoted to PFCs and their precursors. In many countries and regions, such as the European Union, Canada, Denmark, and the United States, directives and regulations have been issued to restrict the use of PFCs and their precursors; the number of these compounds in such lists is increasing continuously. Studies have shown that PFCs are hepatotoxic, embryotoxic, reproductive-toxic, neurotoxic, and carcinogenic, and can interfere with the endocrine system, change animal instinct behavior, and potentially induce developmental neurotoxicity in humans, especially in young children. However, there are few established methods for the simultaneous detection of multiple PFC precursors, necessitating the same particularly for textiles. In this study, a method was developed for the simultaneous determination of 11 volatile PFC precursors in textiles using gas chromatography-triple quadrupole tandem mass spectrometry (GC-MS/MS). The target compounds included four fluorotelomer alcohols (FTOHs), three fluorotelomer acrylates (FTAs), two fluorooctane sulfonamides (FOSAs), and two fluorooctane sulfonamide-ethanols (FOSEs). Studies have shown that FTOHs and FTAs are precursors of perfluorocarboxylic acid, and FOSAs are precursors of perfluorooctanesulfonic acid. Some PFC precursors are converted into perfluorocarboxylic acid and perfluoroalkyl sulfonic acid, which threaten human health and ecological security. In this study, an effective ultrasonic-assisted extraction method for the 11 target compounds was established. The effects of the extraction solvent, extraction temperature, and extraction time on the extraction efficiency were investigated. The optimum extraction conditions for the developed method were carrying out ultrasonic extraction at 70 ℃ for 60 min with methanol as the extraction solvent. Separation was performed on a VF-WAXms capillary column (30 m×0.25 mm×0.25 μm) with temperature programming, following which the target compounds were detected by GC-MS/MS in the multiple reaction monitoring (MRM) mode and quantified using the external standard method. The matrix effects of three textile matrices were also investigated. The calibration curves of the 11 volatile PFC precursors showed good linearity in the concentration range of 10-500 μg/L with correlation coefficients not less than 0.9984. The limits of detection were 0.002-0.04 mg/kg (S/N=3), and limits of quantification were 0.006-0.1 mg/kg (S/N=10). The recoveries for the 11 analytes in different textile matrix samples at three spiked levels ranged from 73.2% to 117.2% with relative standard deviations (RSDs) of 0.1%-9.4% (n=6). Through actual sample analysis, four PFC precursors were detected in the textile product samples. The method has the advantages of simple pretreatment, accurate qualitative and quantitative analysis, high sensitivity, and good reproducibility. It can be effectively used for the simultaneous determination of 11 volatile PFC precursors in textiles. The establishment of this method has theoretical and practical significance for controlling PFC precursor levels in textiles. This study offers a new testing method for mitigating risk to safety and controlling textile products. It also provides a reference for establishing testing standards for PFC precursors in textiles and other similar consumer goods.

Key words: gas chromatography-tandem mass spectrometry (GC-MS/MS), perfluorinated compound precursors, textiles

中图分类号:

O658

王春兰, 张海煊, 朱丽, 胡望霞, 林紫威. 气相色谱-三重四极杆质谱法同时测定纺织品中11种挥发性全氟化合物前体物[J]. 色谱, 2021, 39(11): 1239-1246.

WANG Chunlan, ZHANG Haixuan, ZHU Li, HU Wangxia, LIN Ziwei. Simultaneous determination of 11 volatile perfluorinated compound precursors in textiles using gas chromatography-triple quadrupole mass spectrometry[J]. Chinese Journal of Chromatography, 2021, 39(11): 1239-1246.

图/表 9

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Compound	CAS No.	t/ min	MRM ion pairs (m/z)		CEs/ eV
6:2FTA	17527-29-6	7.31	55.0>27.0^*;	418.1>99.0	25;42
4:2FTOH	2043-47-2	8.05	95.0>69.0^*;	196.1>127.0	25;18
8:2FTA	27905-45-9	8.87	55.0>27.0^*;	518.1>99.0	18;48
6:2FTOH	647-42-7	9.01	95.0>69.0^*;	296.1>127.0	25;35
8:2FTOH	678-39-7	10.18	95.0>69.0^*;	131.0>68.9	28;46
10:2FTA	17741-60-5	10.76	55.0>27.0^*;	618.0>99.1	20;58
10:2FTOH	865-86-1	11.35	95.0>69.0^*;	131.0>68.9	30;42
N-Et-FOSA	4151-50-2	15.75	108.0>80.0^*;	131.0>68.9	10;44
N-Me-FOSA	31506-32-8	16.23	94.0>30.0^*;	131.0>68.9	22;48
N-Me-FOSE	24448-09-7	17.30	526.0>462.0^*;	131.0>68.9	52;39
N-Et-FOSE	1691-99-2	17.36	540.0>169.0^*;	131.0>68.9	41;39

Compound	CAS No.	t/ min	MRM ion pairs (m/z)		CEs/ eV
6:2FTA	17527-29-6	7.31	55.0>27.0^*;	418.1>99.0	25;42
4:2FTOH	2043-47-2	8.05	95.0>69.0^*;	196.1>127.0	25;18
8:2FTA	27905-45-9	8.87	55.0>27.0^*;	518.1>99.0	18;48
6:2FTOH	647-42-7	9.01	95.0>69.0^*;	296.1>127.0	25;35
8:2FTOH	678-39-7	10.18	95.0>69.0^*;	131.0>68.9	28;46
10:2FTA	17741-60-5	10.76	55.0>27.0^*;	618.0>99.1	20;58
10:2FTOH	865-86-1	11.35	95.0>69.0^*;	131.0>68.9	30;42
N-Et-FOSA	4151-50-2	15.75	108.0>80.0^*;	131.0>68.9	10;44
N-Me-FOSA	31506-32-8	16.23	94.0>30.0^*;	131.0>68.9	22;48
N-Me-FOSE	24448-09-7	17.30	526.0>462.0^*;	131.0>68.9	52;39
N-Et-FOSE	1691-99-2	17.36	540.0>169.0^*;	131.0>68.9	41;39

Compound	Regression equation	r	LOD/ (mg/kg)	LOQ/ (mg/kg)
6:2FTA	Y=1514X-7845	0.9996	0.02	0.06
4:2FTOH	Y=632.5X-3116	0.9992	0.01	0.04
8:2FTA	Y=1062X-3652	0.9991	0.03	0.01
6:2FTOH	Y=812.3X-4550	0.9991	0.01	0.03
8:2FTOH	Y=740.1X-1409	0.9987	0.002	0.006
10:2FTA	Y=833.2X-5348	0.9989	0.04	0.1
10:2FTOH	Y=642X-3177	0.9987	0.002	0.006
N-Et-FOSA	Y=1923X-12060	0.9986	0.004	0.01
N-Me-FOSA	Y=1179X-6168	0.9990	0.002	0.006
N-Me-FOSE	Y=2493X-17390	0.9987	0.003	0.01
N-Et-FOSE	Y=1557X-12250	0.9984	0.005	0.02

Compound	Regression equation	r	LOD/ (mg/kg)	LOQ/ (mg/kg)
6:2FTA	Y=1514X-7845	0.9996	0.02	0.06
4:2FTOH	Y=632.5X-3116	0.9992	0.01	0.04
8:2FTA	Y=1062X-3652	0.9991	0.03	0.01
6:2FTOH	Y=812.3X-4550	0.9991	0.01	0.03
8:2FTOH	Y=740.1X-1409	0.9987	0.002	0.006
10:2FTA	Y=833.2X-5348	0.9989	0.04	0.1
10:2FTOH	Y=642X-3177	0.9987	0.002	0.006
N-Et-FOSA	Y=1923X-12060	0.9986	0.004	0.01
N-Me-FOSA	Y=1179X-6168	0.9990	0.002	0.006
N-Me-FOSE	Y=2493X-17390	0.9987	0.003	0.01
N-Et-FOSE	Y=1557X-12250	0.9984	0.005	0.02

Compound	Recoveries/% (RSDs/%)
	Cotton fabric			Synthetic fabric			Synthetic leather
	0.2 μg	1 μg	8 μg	0.2 μg	1 μg	8 μg	0.2 μg	1 μg	8 μg
6:2FTA	85.2 (8.3)	78.4 (6.3)	77.3 (5.4)	99.6 (6.2)	80.7 (6.4)	75.5 (6.2)	81.7 (4.5)	75.8 (6.7)	87.3 (9.3)
4:2FTOH	99.8 (5.2)	99.8 (3.8)	112.6 (8.4)	98.1 (5.6)	96.0 (1.3)	95.2 (2.0)	93.7 (7.4)	90.7 (1.6)	94.4 (6.0)
8:2FTA	114.0 (3.5)	115.2 (1.2)	114.6 (6.4)	108.3 (7.0)	115.3 (9.1)	105.9 (3.2)	73.2 (5.4)	81.5 (1.7)	76.0 (5.2)
6:2FTOH	105.2 (3.5)	99.6 (2.5)	103.3 (1.5)	100.7 (1.4)	95.7 (2.4)	93.2 (1.3)	100.6 (1.7)	117.2 (9.2)	101.0 (2.0)
8:2FTOH	106.5 (2.1)	94.4 (5.8)	105.4 (3.6)	111.7 (4.3)	90.6 (4.6)	93.5 (2.1)	92.5 (4.4)	95.4 (4.2)	101.3 (5.0)
10:2FTA	99.7 (3.8)	97.3 (3.7)	102.6 (5.9)	101.8 (3.8)	100.9 (4.1)	101.3 (3.3)	95.6 (2.5)	98.6 (3.0)	98.0 (5.2)
10:2FTOH	116.2 (4.0)	96.3 (6.5)	100.1 (4.0)	99.1 (0.1)	90.8 (5.4)	90.4 (3.5)	78.8 (4.1)	86.5 (3.7)	99.3 (5.4)
N-Et-FOSA	92.8 (7.8)	84.7 (6.3)	91.0 (8.7)	95.3 (7.0)	81.3 (5.6)	90.2 (3.4)	105.9 (8.2)	92.5 (7.3)	98.5 (1.0)
N-Me-FOSA	94.5 (7.4)	80.5 (6.3)	87.4 (6.2)	86.6 (9.0)	79.4 (5.9)	91.7 (4.8)	96.4 (7.0)	90.3 (4.7)	101.9 (2.6)
N-Me-FOSE	114.6 (3.3)	102.5 (7.7)	104.8 (7.9)	95.1 (8.5)	93.0 (7.6)	99.6 (8.9)	110.1 (6.3)	94.5 (9.2)	100.5 (9.4)
N-Et-FOSE	103.6 (6.5)	102.3 (8.3)	105.9 (9.1)	100.5 (5.5)	97.4 (9.2)	98.7 (8.9)	107.4 (8.7)	97.8 (4.2)	101.8 (5.8)