顶空固相微萃取-气相色谱-质谱法快速筛查油性基质中化学武器公约相关化合物

doi:10.3724/SP.J.1123.2022.07007

摘要/Abstract

摘要：

《化学武器公约》核查的化合物范围广泛,数量庞大,而核查样品通常来源复杂多样,且目标化合物含量很低,极易发生漏检和误检。鉴于核查结果的政治、军事敏感性,建立快速、有效的筛查方法对于准确鉴定复杂环境样品中公约相关化合物十分重要。针对油性基质样品前处理费时费力,低沸点化合物易漏检等问题,研究建立了顶空固相微萃取(HS-SPME)结合全扫描模式下气相色谱-质谱(GC-MS)检测,快速筛查油性基质中化学武器公约相关化合物的分析方法。为模拟筛查过程,选取24种性质各异的重要公约清单物为代表性化合物,并根据性质将所选化合物分为3组分别进行研究。对HS-SPME的工作条件进行了优化,包括萃取纤维涂层种类、萃取温度、萃取时间、解吸时间、衍生化方法等。对极性较低的挥发性和半挥发性公约相关化合物,采用二乙烯基苯/碳分子筛/聚二甲基硅氧烷(DVB/CAR/PDMS)纤维提取,以分流模式(分流比10∶1)进样分析,检出限为0.5~100 ng/mL。对中等极性和较高极性化合物,衍生化后采用聚二甲基硅氧烷/二乙烯基苯(PDMS/DVB)纤维提取,以不分流模式进样分析,检出限为20~300 ng/mL。所建方法简单、快速、灵敏,特别是可避免样品浓缩导致的低沸点化合物的损失和漏检,可用于复杂油性基质中痕量化学武器公约相关化合物的快速筛查与鉴定,并已多次成功应用于国际禁止化学武器组织效能水平测试中。

关键词: 顶空固相微萃取, 气相色谱-质谱联用, 化学武器公约相关化合物, 油性基质, 快速筛查

Abstract:

The Chemical Weapons Convention (CWC) requires verification of a large number of compounds with different types and properties. The results of the verification are of great political and military sensitivity. However, the sources of verification samples are complex and diverse, and the contents of the target compounds in these samples are usually very low. These issues increase the likelihood of missed or false detection. Thus, establishing rapid and effective screening methods for the accurate identification of CWC-related compounds in complex environmental samples are of great importance. In this study, a fast and simple procedure based on headspace solid-phase microextraction (HS-SPME) followed by gas chromatography-electron ionization mass spectrometry (GC-EI/MS) in full-scan mode was developed to determine CWC-related chemicals in oil matrix. A total of 24 CWC-related chemicals with different chemical characteristics were selected to simulate the screening procedure. The selected compounds were divided into three groups based on their properties. The first group included volatile and semi-volatile CWC-related compounds with relatively low polarity, which could be extracted by HS-SPME and directly analyzed by GC-MS. The second group included moderately polar compounds with hydroxyl or amino groups; such compounds are related to nerve, blister, and incapacitating agents. The compounds in the third group included non-volatile CWC-related chemicals with relatively strong polarity, such as alkyl methylphosphonic acids and diphenyl hydroxyacetic acid. These compounds must be derivatized into vaporizable derivatives prior to extraction by HS-SPME and analysis by GC-MS. Variables that influence the SPME process, such as fiber type, extraction temperature and time, desorption time, and derivatization protocol, were optimized to improve the sensitivity of the method. The screening procedure for CWC-related compounds in the oil matrix samples included two main steps. First, low-polarity volatile and semi-volatile compounds (i. e. the first group) were extracted by HS-SPME with divinylbenzene/carboxen/polydimethylsiloxane (DVB/CAR/PDMS) fibers and analyzed in split-injection mode (split ratio, 10∶1) using GC-MS. The use of a large split ratio can reduce the solvent effect, which is conducive to the detection of low-boiling-point compounds. If necessary, the sample could be extracted once more and analyzed in splitless mode. The derivatization agent bis(trimethylsilyl)trifluoroacetamide (BSTFA) was then added to the sample. Mid- and high-polarity compounds (i. e. the second and third groups) were extracted with polydimethylsiloxane/divinylbenzene (PDMS/DVB) fibers after derivatization and analyzed in splitless mode using GC-MS. The established method exhibited good repeatability and sensitivity. The detection limits for the compounds in the first group ranged from 0.5 ng/mL to 100 ng/mL, whereas the detection limits for the compounds in the second and third groups ranged from 20 ng/mL to 300 ng/mL. Except for compounds with extremely high boiling points and a few compounds that are not suitable for derivatization with BSTFA, the method can be used to analyze most CWC-related compounds in oil matrix samples. In particular, it greatly shortened the preparation time of the oil matrix samples and reduced the loss of low-boiling-point compounds owing to the sample concentration process, thereby avoiding missed detection. The method was successfully applied to the Organization for the Prohibition of Chemical Weapons (OPCW) proficiency tests and proved to be a useful technique for the rapid screening of trace levels of CWC-related chemicals in oil matrix.

Key words: headspace solid-phase microextraction (HS-SPME), gas chromatography-mass spectrometry (GC-MS), Chemical Weapon Convention (CWC)-related chemicals, oil matrix, rapid screening

中图分类号:

O658

陈佳, 刘玉龙, 徐斌, 刘勤, 谢剑炜. 顶空固相微萃取-气相色谱-质谱法快速筛查油性基质中化学武器公约相关化合物[J]. 色谱, 2023, 41(4): 348-358.

CHEN Jia, LIU Yulong, XU Bin, LIU Qin, XIE Jianwei. Rapid screening of Chemical Weapons Convention-related chemicals in oil matrix by headspace solid-phase microextraction and gas chromatography-mass spectrometry[J]. Chinese Journal of Chromatography, 2023, 41(4): 348-358.

图/表 10

表1 所选择的代表性公约相关化合物

Table 1 Selected Chemical Weapons Convention (CWC) related chemicals

Group			No.	Compound		CWC schedule
Ⅰ			1	pinacolyl alcohol (片呐醇)		2.B.14
			2	chloropicrin (氯化苦)		3.A.04
			3	dimethyl phosphite (DMP) (亚膦酸二甲酯)		3.B.10
			4	sarin (GB) (沙林)		1.A.01
			5	1,4-oxathiane (1,4-噻烷)		N.S.^*
			6	diethyl methylphosphonate (DEMP) (甲基膦酸二乙酯)		2.B.04
Group	No.	Compound			Structure		CWC schedule
	7	1,4-dithiane (1,4-二噻烷)					N.S.^*
	8	sulfur mustard (SM) (芥子气)					1.A.04
	9	cyclopentyl methyl methylphosphonate (CPMMP) (甲基膦酸甲基环戊基酯)					2.B.04
	10	2-methyl-1,3,2-dithiaphosphinane 2-sulfide (2-甲基-1,3,2-二硫代膦-2-硫化物)					2.B.04
Ⅱ	11	N-ethyl N-methylaminoethanol (EMAE) (甲基乙基乙醇胺)					2.B.11
	12	N-methyl N-propylaminoethanol (MPAE) (甲基丙基乙醇胺)					2.B.11
	13	methyldiethanolamine (MDEA) (甲基二乙醇胺)					3.B.15
	14	ethyldiethanolamine (EDEA) (乙基二乙醇胺)					3.B.15
	15	triethanolamine (TEA) (三乙醇胺)					3.B.17
	16	thiodiglycol (TDG) (硫二苷醇)					2.B.13
	17	quinuclidin-3-ol(喹咛醇)					2.B.09
Ⅲ	18	methylphosphonic acid (MPA) (甲基膦酸)					2.B.04
	19	ethyl methylphosphonic acid (EMPA) (乙基甲基膦酸)					2.B.04
	20	isopropyl methylphosphonic acid (IMPA) (异丙基甲基膦酸)					2.B.04
	21	isobutyl methylphosphonic acid (i-BuMPA) (异丁基甲基膦酸)					2.B.04
	22	pinacolyl methylphosphonic acid (PMPA) (片呐基甲基膦酸)					2.B.04
	23	cyclohexyl methylphosphonic acid (CHMPA) (环己基甲基膦酸)					2.B.04
	24	2,2-diphenyl-2-hydroxyacetic acid (BZA) (二苯羟乙酸)					2.B.08

图1 不同纤维涂层对所选择的公约相关化合物提取效果

Fig. 1 Extraction efficiency of selected CWC-related chemicals with different fiber coatings

图2 萃取温度对萃取效果的影响

Fig. 2 Effect of extraction temperature on the extraction efficiency

图3 萃取时间对萃取效果的影响

Fig. 3 Effect of extraction time on the extraction efficiency

表2 HS-SPME-GC-MS分析的检出限和精密度(n=6)

Table 2 Limits of detection (LODs) and precisions of HS-SPME and GC-MS analysis (n=6)

Compound	t_R/ min	Extracted ion (m/z)	LOD^*/ (ng/mL)	RSD^**/ %
Pinacolyl alcohol	4.61	57	5	4.3
Chloropicrin	5.46	117	100	11.6
Dimethyl phosphite	5.90	80	30	8.4
Sarin	6.14	99	1	3.9
1,4-Oxathiane	7.13	104	2	4.2
Diethyl	8.77	97	0.5	1.7
methylphosphonate
1,4-Dithiane	9.52	120	1	3.3
Sulfur mustard	10.68	109	1	4.5
Cyclopentyl methyl	11.60	111	0.5	2.8
methylphosphonate
2-Methyl-1,3,2-dithia-	15.28	184	30	7.7
phosphinane 2-sulfide

表3 衍生化HS-SPME-GC-MS分析方法的检出限和精密度(n=6)

Table 3 LODs and precisions of HS-SPME and GC-MS analysis after derivatization (n=6)

Compound	t_R/ min	Extracted ion (m/z)	LOD^*/ (ng/mL)	RSD^**/ %
EMAE (TMS)	8.14	72	50	8.5
MPAE (TMS)	9.06	86	50	7.3
MDEA (2TMS)	11.66	160	30	6.8
EDEA (2TMS)	12.13	174	30	3.9
TEA (3TMS)	14.45	262	100	10.7
TDG (2TMS)	12.70	116	20	8.3
Quinuclidin-3-ol (TMS)	11.28	200	20	14.3
MPA (2TMS)	10.04	225	50	6.7
EMPA (TMS)	9.34	153	20	4.6
IMPA (TMS)	9.64	153	20	5.9
i-BuMPA (TMS)	10.78	153	30	9.6
PMPA (TMS)	11.73	153	50	11.2
CHMPA (TMS)	13.27	153	50	8.8
BZA (2TMS)	16.47	255	300	19.4

图4 HS-SPME-GC-MS分析泵油加标样品中第一组10种公约相关化合物的总离子流图

Fig. 4 TIC of the ten CWC-related chemicals (the first group) spiked in a pump oil sample by HS-SPME and GC-MS Peak identifications: 1. pinacolyl alcohol; 2. chloropicrin; 3. dimethyl phosphite; 4. sarin; 5. 1,4-oxathiane; 6. diethyl methylphosphonate; 7. 1,4-dithiane; 8. sulfur mustard; 9. cyclopentyl methyl methylphosphonate; 10. 2-methyl-1,3,2-dithiaphosphinane 2-sulfide.

图5 衍生化HS-SPME-GC-MS分析泵油加标样品中第二组和第三组公约相关化合物的总离子流图

Fig. 5 TICs of CWC-related chemicals (the second group and the third group) spiked in pump oil samples by HS-SPME and GC-MS after derivatization a. the second group; b. the third group.Peak identifications: 1. EMAE (TMS); 2. MPAE (TMS); 3. quinuclidin-3-ol (TMS); 4. MDEA (2TMS); 5. EDEA (2TMS); 6. TDG (2TMS); 7. TEA (3TMS); 8. EMPA; 9. IMPA (TMS); 10. MPA (2TMS); 11. i-BuMPA (TMS); 12. PMPA (TMS); 13. CHMPA (TMS); 14. BZA (2TMS).

图6 OPCW第38次水平测试中生物柴油基质样品的HS-SPME-GC-MS检测总离子流图

Fig. 6 TICs of biodiesel samples from the 38th OPCW Proficiency Test analyzed by HS-SPME-GC-MS a. Sample 385 (with 5 μg/mL dimethyl methylphosphonate), diluted 10 times with pump oil (the actual concentration for detection was 0.5 μg/mL); b. Sample 386 (with 20 μg/mL chloropicrin), diluted 10 times with pump oil (the actual concentration for detection was 2 μg/mL).Peak identifications: 1. dimethyl methylphosphonate; 2. chloropicrin.

图7 采用不同方法分析OPCW第42次水平测试泵油样品421的GC-MS总离子流图

Fig. 7 TICs of GC-MS analysis for pump oil sample 421 from the 42nd OPCW Proficiency Test using different methods a. HS-SPME method, 0.1 mL sample, sample preparation time<1 h; b. OPCW ROP method, 1 mL sample, preparation time>5 h, temperature program: 50 ℃ (2 min) to 290 ℃ (4 min) increased at 10 ℃/min, split ratio 10∶1. Divinylsulfide was not detected with OPCW ROP method.Peak identifications: 1. divinylsulfide; 2. bis(2-chloroethyl)-disulfide.

[1]	张权, 毕珊, 吴玉田, 李磊, 周贻兵, 刘利亚, 刘文政, 陈庆园, 周雪, 郭华. Sin-QuEChERS Nano净化柱结合气相色谱-串联质谱法快速筛查石斛中84种农药残留[J]. 色谱, 2022, 40(6): 565-575.
[2]	徐红斌, 张申平, 杜茹芸, 周静, 翁史昱. 超高效液相色谱-Orbitrap高分辨质谱用于减肥和壮阳类保健食品中32种非法添加药物的快速筛查和确证[J]. 色谱, 2022, 40(6): 531-540.
[3]	柯庆青, 李诗言, 王鼎南, 周钦, 周凡, 贝亦江, 陈小明, 王扬. 超高效液相色谱-四极杆-飞行时间质谱法快速筛查和确证渔药中86种非法添加化学品[J]. 色谱, 2022, 40(6): 520-530.
[4]	薛高旭, 王沁怡, 曹玲, 孙晶, 杨功俊, 冯有龙, 方方. 固相萃取-离子迁移谱法快速筛查祛痘类化妆品中14种抗菌药物[J]. 色谱, 2022, 40(12): 1119-1127.
[5]	张虹艳, 石晓峰, 邱国玉, 王小乔, 张彩霞, 张晓萍, 吴福祥, 许晓辉, 李晨曦, 潘秀丽. 热解吸-电喷雾离子源-三重四极杆质谱法快速筛查火锅底料和肉汤中非法添加罂粟壳[J]. 色谱, 2020, 38(7): 861-867.
[6]	张文敏, 冯遵梅, 黄川辉, 高佳, 张兰. 原位溶剂热聚合法制备金属有机骨架/碳化氮纳米片涂覆的固相微萃取纤维用于红茶中农药残留的高灵敏检测[J]. 色谱, 2020, 38(3): 332-340.
[7]	郭项雨, 翟俊峰, 马龙华, 吴青, 白桦, 马强. 热解吸-电晕放电电离-离子迁移谱法现场快速筛查化妆品中5种禁用组分[J]. 色谱, 2019, 37(2): 233-238.
[8]	邓波, 王维维, 张小涛, 童福强, 姬厚伟, 刘与铭, 张丽. 顶空固相微萃取-气相色谱/质谱联用法结合化学计量学分析白肋烟烘焙前后挥发性、半挥发性成分[J]. 色谱, 2019, 37(12): 1373-1382.
[9]	唐祥凯, 冯德建, 史谢飞, 李怀平. 气相色谱-质谱联用法测定农药制剂中29种助剂[J]. 色谱, 2019, 37(11): 1221-1227.
[10]	胡巧茹, 曹鹏, 丛中笑, 梁君妮, 沙美兰, 李晓玉, 尹大路, 鲁闽. 超高效液相色谱-四极杆/静电场轨道阱高分辨质谱对粮谷产品中20种真菌毒素的快速筛查和确证[J]. 色谱, 2019, 37(11): 1241-1248.
[11]	芦智远, 王冰, 田娜, 张耀武, 张新宇, 刘佳, 吕岩. 离子交换固相萃取-气相色谱-质谱联用法测定方便面皮复合包装袋中2,4-二氨基甲苯的迁移量[J]. 色谱, 2019, 37(10): 1053-1058.
[12]	郭蕾蕾, 李莹, 李海山, 连增斌. 顶空-气相色谱-质谱联用法同时测定紫外光固化胶印油墨中27种溶剂残留[J]. 色谱, 2018, 36(12): 1342-1348.
[13]	张茜, 刘炜伦, 路亚楠, 吕运开. 顶空气相色谱-质谱联用技术的应用进展[J]. 色谱, 2018, 36(10): 962-971.
[14]	周秀锦, 陈宇, 杨赛军, 邵宏宏, 沈飚, 詹舜安. 超高效液相色谱-四极杆飞行时间质谱法非靶向快速筛查进口粮谷中未知的农药残留[J]. 色谱, 2017, 35(8): 787-793.
[15]	云环, 刘鑫, 崔杰, 杨婧, 刘影. 离子色谱-高分辨质谱法快速筛查乳制品中的酸度调节剂[J]. 色谱, 2017, 35(8): 886-890.