气相色谱-负离子化学电离质谱法分析深海鱼油 食品中的五种多溴联苯醚残留

建立了气相色谱-负离子化学电离质谱法(GC-NCI/MS)同时分析深海鱼油食品中5种多溴联苯醚残留的分析方法。深海鱼油食品用正己烷超声提取、中性与酸性硅胶色谱柱净化和正己烷洗脱后,以PCB103为内标物,采用GC-NCI/MS的选择离子监测方式(SIM)分析;同时探讨了5种多溴联苯醚的NCI/MS特征离子的断裂机理。当空白深海鱼油食品的加标浓度为20.0和100.0 μg/kg时,加标回收率为88.6%～111.3%,相对标准偏差为3.8%～13.5%,方法的检测限为0.77～1.34 μg/kg,线性范围为1.0～500.0 μg/kg,相关系数均大于0.9992。此方法已成功地应用于深海鱼油食品中5种痕量多溴联苯醚残留的同时分析。     

气相色谱-负离子化学源/质谱法(GC-NCI/MS)分析鱼类和贝类样品中多溴联苯醚和多溴联苯

将气相色谱-负离子化学源/质谱法(GC-NCI/MS)应用于分析鱼类和贝类样品中5种多溴联苯醚(PBDEs)和5种多溴联苯(PBBs)残留.鱼类和贝类样品以正己烷/丙酮(1∶1,V/V)作为提取剂,采用超声萃取法,提取液经酸性硅胶和中性硅胶层析柱净化和正己烷洗脱后,以PCB-103为内标物和GC-NCI-MS的选择离子...     

气相色谱-负离子化学源-质谱法分析茶叶中5种多溴联苯醚

将气相色谱-负离子化学源-质谱法(GC-NCI-MS)应用于快速分析茶叶中5种多溴联苯醚残留量.茶叶样品以正己烷作为提取剂,采用超声辅助提取法,提取液经中性氧化铝和Florisil硅藻土层析柱净化和正己烷洗脱后,以PCB-103为内标物和GC-NCI-MS的选择离子监测方式(SIM)进行定性与定量分析.5种多溴联苯醚的平均加标回收率为70.9%～81.7%,相对标准偏差为6.9%～11.0%,方法检出限小于0.12 μg/kg,线性范围为0.1～500 μg/kg,相关系数都大于0.9990.所分析的8种茶叶样品中6种含有微量的PBDE-47,1种茶叶样品含有微量的PBDE-99.     

海产品中九种多溴联苯醚残留的气相色谱-负化学离子源／质谱法分析

建立了海产品中九种多溴联苯醚(PBDEs)残留的气相色谱-负化学离子源/质谱(GC-NCI/MS)分析方法.采用正己烷提取剂超声提取、Florisil硅藻土净化柱净化和正己烷洗脱剂洗脱的样品前处理方法,以PCB-103作为内标物,以GC-NCI/MS的选择离子监测方式(S1M)对海产品中九种PBDEs残留进行了定性与定量分析.分析方法的线性相关系数均≥0.9988,九种PBDEs两种添加浓度水平时的平均加标回收率为88.1%～97.3%,相对标准偏差为2.0%～6.6%,方法检出限均小于0.106 ng/g.线性范围除PBDE-183为0.60～300.0 ng/g外,其余八种PBDEs为0.50～250.0 ng/g.同时分析了紫菜、海带、鲜海带、鱼干和花蛤干等海产品,在这些海产品干货中都检出了较多种的PBDEs残留.     

食品中多溴联苯醚残留的气相色谱-串联质谱分析方法研究

建立了食品中8种多溴联苯醚(PBDEs) 残留的气相色谱-串联质谱分析方法,初步解析了PBDEs的电子轰击串联质谱(EI MS/MS)图,为各种目标物的准确定性分析提供依据.以BDE-28、BDE-47、BDE-66、BDE-85、BDE-99、BDE-100、BDE-153、BDE-154为研究对象,对EI MS/MS各分析参数进行了优化.用超声提取-酸性硅胶层析柱净化的前处理方法制备样品,当空白样品的加标水平为10.0、25.0 μg/kg时,8种PBDEs的平均加标回收率为82% ～112%,相对标准偏差为3.1% ～15%,方法检出限均低于1.5 μg/kg;8种PBDEs的线性范围为10.0 ～500 μg/kg,相关系数均大于0.994 7.     

超声辅助萃取气相色谱-质谱法测定松针中的多溴联苯醚

建立了测定松针样品中多溴联苯醚(PBDEs)的分析方法。松针样品经过正己烷-丙酮(体积比为1∶1)混合溶液超声萃取、浓硫酸和氧化铝柱净化后,采用气相色谱-负化学电离源质谱(GC-NCI-MS)选择离子监测(SIM)模式检测,内标法定量。结果表明,方法的加标回收率为83.8%~107.5%,三溴~七溴代联苯醚的仪器检出限为0.152~ 0.770 pg,十溴代联苯醚(BDE-209)的检出限为11.1 pg;三溴~七溴代联苯醚的方法检出限(湿重)为3~15 pg/g,BDE-209的方法检出限(湿重)为222 pg/g。方法具有良好的重现性、较高的灵敏度和良好的回收率。实际样品分析表明,松针中BDE-209是主要的同类物,约占8种PBDEs总量的82.3%,低溴代联苯醚以2,2′,4,4′-四溴联苯醚(BDE-47)为主。     

QuEChERS—气相色谱—串联质谱测定食品中的多溴联苯和多溴二苯醚类阻燃剂

建立了QuEChERS-气相色谱-串联质谱(GC-MS/MS)法测定食品的多溴联苯和多溴二苯醚类物质。采用正己烷或乙腈提取并浓缩目标物后，用无水MgSO₄、乙二胺-N-丙基硅烷(PSA)和十八烷基硅烷键合硅胶(C18)净化，以DB-5HT色谱柱(15 m×0.25 mm×0.1μm)进行分离，质谱采用电子轰击电离源，在多反应监测模式下进行检测，外标法定量。实验优化了提取条件，比较了提取溶剂的种类和体积、酸的体积对检测结果的影响。结果表明，12种多溴联苯和13种多溴二苯醚共25种目标物均呈现良好线性关系，相关系数(r²)≥0.999,方法的检出限为3～180μg/kg,定量限为10～600μg/kg,平均加标回收率为60.23%～106.97%,相对标准偏差(RSDs,n=6)为0.20%～11.96%。该测定方法操作简单，灵敏度高，适用于食品中多溴联苯和多溴二苯醚类物质的高效分析检出。     

动物肝脏中九种多溴联苯醚残留量的GC—NCI／MS分析

建立了动物肝脏中9种PBDEs残留量的气相色谱-负化学离子源/质谱(GC-NCI/MS)的分析方法。动物肝脏样品经V(正己烷)∶V(丙酮)=1∶1超声辅助提取,中性与酸性硅胶层析柱净化和V(正已烷)∶V(CH2Cl2)=1∶1洗脱和浓缩后,以PCB-103为内标物,采用GC-NCI/MS的选择离子监测方式(SIM)对其中的9种PBDEs残留量进行了定性与定量分析。当动物肝脏空白样品的加标质量浓度为5.0、20.0μg/kg(PBDE-183为6.0、24.0μg/kg)时,9种PBDEs的平均加标回收率为75.1%~88.2%,相对标准偏差为3.3%~7.9%,方法检出限均小于0.07μg/kg;线性范围除PBDE-183为0.12~600.0μg/kg外,其余8种PBDEs为0.1~500.0μg/kg,相关系数都大于0.9993。所建立的分析方法已用于5种动物肝脏的8个样品中9种PBDEs残留量的分析。     

厦门近海沉积物中PBDEs与PBBs残留的GC-NCI/MS和GC-ECD分析

将气相色谱-负离子化学源.质谱法(GV-NcI/Ms)和气相色谱-电子捕获检测法(GC-ECD)应用于分析沉积物中6种多溴联苯醚(PBDE8)和5种多溴联苯(PBBs)残留.沉积物样品以V(正己烷):V(丙酮)=1:1作为提取剂,采用索式提取法,提取液经酸性硅胶和中性硅胶层析柱净化和正己烷洗脱后.以PCB-103为内标物和GC-NCI-MS的选择离子监测方式(SIM)进行定性与定量分析,PBDE-209则采用GC-ECD法分析.平均加标回收率为93.3%～110.8%,相对标准偏差为1.2%～8.6%,方法检测限均小于0.20 μg/kg(PBDE-209的方法检测限是7.74 μg/kg),相关系数都大于0.9990.所分析沉积物样品中均含有微量的PBDE-99、PBB-49和PBDE-209.     

同位素稀释-高分辨气相色谱/高分辨质谱法测定大气中多溴联苯醚和多溴联苯153

针对环境监测的特点和要求,建立了同位素稀释-高分辨气相色谱/高分辨质谱测定大气中多溴联苯醚(PBDEs)和多溴联苯153(BB153)的方法。采用正己烷/二氯甲烷(1:1, v/v)及正己烷分别对PBDEs和BB153进行快速溶剂萃取,并通过复合硅胶柱净化。在校准曲线最高浓度的10%和90%加标水平下得到的天然内标的平均回收率分别为100%和104%,平均相对标准偏差(n=7)分别为5%和6%;二至十溴代联苯醚和BB153相应的¹³C同位素标准物质回收率在36.5%~133%之间;而一溴代联苯醚¹³C同位素标准物质回收率较差,可能是由于物化性质与其他化合物不同。在实际采样体积为300 m³的情况下,未发生污染物穿透现象;分析物检出限低于2×10^-4 ng/Nm³,提取内标回收率在56%~126%之间(一溴代联苯醚除外)。实验结果表明该方法能对化合物准确定量,适用于大气中二至十溴代联苯醚和BB153的分析。     

Microwave-assisted extraction (MAE) for the determination of polybrominated diphenylethers (PBDEs) in sewage sludge

An efficient microwave-assisted extraction (MAE) method has been developed and evaluated for the quantification of eight major polybrominated diphenylethers (PBDEs) in sewage sludge. The PBDEs were extracted from wet and dry sludge in a microwave extraction unit using a hexane/acetone mixture for 35 min at a controlled temperature of 130 °C. The extract was concentrated, cleaned up on a silica gel column, and analyzed by gas chromatography/mass spectrometry (GC/MS) in the negative chemical ionization (NCI) mode. The MAE procedure exhibited higher extraction efficiency, specifically for BDE (brominated diphenylether) 209, than the conventional Soxhlet extraction. The test congeners were clearly separated under specific instrumental operating conditions, at a source temperature of 230 °C and a column length of 20 m. The present analytical method showed recovery efficiencies ranging from 80 to 110% when applied to the PBDE-free sludge spiked with eight PBDE congeners. The efficiency of the MAE method was confirmed using sludge obtained from four sewage treatment plants (STPs). The results indicate that BDE 47, 99, and 209 are the most abundant congeners present in these sewage sludges, which is consistent with previous reports.     

Gas chromatography and mass spectrometry of methoxylated polybrominated diphenyl ethers (MeO-PBDEs)

Twenty-six methoxylated polybrominated diphenyl ethers (MeO-PBDEs) were characterized by gas chromatography (GC) on four different GC columns with different lengths and polarities, as well as by mass spectrometry using three ionization techniques, electron ionization (EI), electron capture negative ionization (ECNI) and positive ion chemical ionization (PICI). MeO-PBDE congeners with similar retention times on a nonpolar GC column were separated when analyzed on a polar GC column. EI can be used to determine the position of the methoxy substituent (ortho, meta or para) relative to the diphenyl ether oxygen in the MeO-PBDEs. The PICI ionization technique is shown to be valuable to generate structural information of the MeO-PBDEs, i.e. the degree of bromination on both the methoxy-substituted ring and the entirely brominated phenyl ring can be obtained. This structure information can also be achieved for certain MeO-PBDEs with the methoxy group in ortho position to the diphenyl ether bond in ECNI mode. Like other brominated compounds ECNI is preferable when analyzing environmental samples for quantification of MeO-PBDEs because of the formation of bromide ions, which enables low detection limits.     

分子电性距离矢量用于多溴联苯醚分子结构表达及色谱保留时间预测

应用分子电性距离矢量(MEDV)对多溴联苯醚(PBDEs)的209种同系物进行结构表征.通过多元线性回归的方法,建立了PBDEs定量结构-色谱保留(QSRR)关系的6个变量和5个变量的两种模型.两种模型的建模计算值复相关系数R均为0.995;用留一法(LOO)进行了交互检验,其复相关系数(R2cv)分别为0.987和0...     

Supercritical fluid extraction of polybrominated diphenyl ethers (PBDEs) from house dust with supercritical 1,1,1,2-tetrafluoroethane (R134a)

The extraction of polybrominated diphenyl ethers (PBDEs) from SRM 2585 (Organic Contaminants in House Dust) was investigated using supercritical fluid R134a as an extraction solvent. Three methods of dust extraction were studied: (1) extraction of dry dust, (2) extraction of dry dust dispersed on Ottawa sand and (3) extraction of dust wet with dichloromethane. For each of the three sample preparation methods, extracts at three temperatures (110, 150, and 200 °C) above the critical temperature of R134a were performed. Eight PBDE congeners (BDE-28, -47, -99, 100, -153, -154, -183, and -209) in the SFE extracts were analyzed by liquid chromatography negative-ion atmospheric pressure photoionization tandem mass spectrometry (LC/NI-APPI/MS/MS). The optimum extraction of PBDEs from house dust using supercritical R134a is obtained when the dust is pre-wet with dichloromethane prior to extraction to swell the dust. For all sample preparation methods, higher temperatures afforded higher percent recoveries of the eight PBDE congeners. Only a combination of high-temperature (200 °C) and pre-wetting the dust with dichloromethane produced high recovery of the environmentally important, fully brominated PBDE congener, BDE-209.     

Predicting gas chromatographic retention times of 209 polybrominated diphenyls (PBBs) for different temperature programs

A method has been developed to predict the retention times of 209 individual polybrominated diphenyl congeners for different temperature programs. The retention equations lnk=A+B/T of five PBBs in gas chromatography (GC) were used to evaluate the properties of the regression coefficients A and B, which are widely accepted as being highly reliable chromatographic retentions. The quantitative relationships between the A and B values of PCBs and those of PBBs were found. The regression equations derived have coefficients of determination greater than 0.999. The A, B values of any PBB can be predicted by using the A, B values of the PCB according to these relationships. Using these predicted A and B values, the retention times of all PBBs can be predicted. This is an important advance in the identification of PBBs because at present there are only a few PBB standards available.     

Results of an interlaboratory comparison on the determination of polybrominated flame retardants in poly(ethyleneterephthalate)

An intercomparison to establish the performance of routine laboratories in the determination of polybrominated flame retardants in polymers was organised. Commercial poly(ethyleneterephthalate) was fortified with technical pentabromodiphenyl ether, octabromodiphenyl ether and decabromodiphenyl ether mixtures and with a decabromobiphenyl technical mixture at 0.4–0.8 g/kg. Homogeneity and stability of the total Br content in the material was confirmed. Thirty-seven laboratories from Europe, Asia and the Americas submitted results. Relative repeatability standard deviations for individual congeners ranged from 7 to 17%. Relative between-laboratory standard deviations ranged from 22 to 61%. No significant influence of a common standard, application of a standard method or method parameters could be identified. The quality and uncertainty of the results of this study are significantly worse than those reported in the environmental field and indicate a clear need for a learning process among the laboratories involved. Figure Mandel’s h (between labs): critical level: 1.91     

Unusual polybrominated polypyrazolylborates and their copper(I) complexes: synthesis, characterization, and catalytic activity

Five new homoscorpionate ligands were prepared and structurally characterized as their Tl complexes, three of which, Tl[TpBr,Ph,Br] (1) (Tp = hydrotris(pyrazolyl)borate, Tl[TpBr,p-Tomicronl,Br] (2), and Tl[TpBr,p-ClPh,Br] (3), are unique in being the first examples of an "atypical" B-N bond to the most sterically hindered pyrazole nitrogen. They contain bromine atoms on the central and outer carbons of the pyrazole ring, with all aryl substituents in the 5-position of the ligand, forming a protective pocket around the B-H bond. These complexes display a rather high B-H stretch frequency (above 2 600 cm-1) in the IR region. Two other ligands, Tl[Tpp-ClPh,4Br] (4) and Tl[TpPh,Me,Br] (5), containing no outer bromine substituents, have normal B-N bonding to the least-hindered nitrogen. These new ligands have been employed to prepare the series of complexes TpxCu(NCMe) (6-10), for which X-ray studies of two of them (7 and 10) have shown that the atypical or normal geometry of the ligands is maintained when complexed to the copper center. The new complexes have also been tested as the catalysts in carbene and nitrene transfer reactions providing moderate to high yields in the expected products.     

Determination of polybrominated diphenylethers (PBDEs) in biological tissues with special emphasis on QC/QA measures

This paper gives an overview on the determination of PBDEs in biological tissues, such as human blood and milk, cow’s milk and fish with special emphasis on quality control and assurance measures which are mandatory and a prerequisite for a reliable determination of environmental pollutants at trace levels. First experiences in the determination of PBDEs have been gained nearly 20 years ago. Due to great progress in the development of analytical instrumentation, the applied GC/MS methods resulted in very low detection limits. Furthermore, because of unexpected findings in biological tissues, the determination of PBDEs became of growing importance in the past few years. The analysis of hundreds of samples demonstrated the need for extensive quality control/quality assurance (QC/QA) measures which will be reported in detail in the following.     

The use of copper(II) isonicotinate-based micro-solid-phase extraction for the analysis of polybrominated diphenyl ethers in soils

A micro-solid-phase extraction (μ-SPE) device was developed by filling copper(II) isonicotinate coordination polymer (Cu(4-C₅H₄N-COO)₂(H₂O)₄) into a porous polypropylene envelope, and the μ-SPE, coupling with gas chromatography (GC) with a micro-cell electron capture detector (μ-ECD), was used for extraction and determination of PBDEs in soils. Variables affecting extraction procedures, including temperature, water volume, extraction time, and desorption time, were investigated in a spiked soil, and the parameters were optimized. Under the optimal experimental conditions, the method detection limits for seven PBDEs (BDE-28, 47, 99, 100, 153, 154, and 183) were in the range of 0.026–0.066 ng g⁻¹, and the reproducibility was satisfactory with the relative standard deviation in range of 1.3–10.1%. Good linear relationship between PBDEs concentrations and GC signals (defined as peak area) was obtained in the range between 0.1 and 200 ng g⁻¹. The recovery of the seven PBDEs by μ-SPE varied from 70 to 90%, which was comparable to that determined by accelerated solvent extraction method. Finally, the proposed method was used to determine PBDEs in several field-contaminated soils, and it was suggested that the μ-SPE is a promising alternative microextraction technique for the detection of PBDEs in soils.