超高效液相色谱-线性离子阱/静电场轨道阱高分辨质谱快速筛查化妆品中的24种激素

建立了超高效液相色谱-线性离子阱/静电场轨道阱组合式高分辨质谱联用（UPLC-LTQ/Orbitrap MS）快速筛查、定性识别化妆品中24种激素的分析方法。不同剂型的化妆品样品经甲醇超声提取,用Waters ACQUITY UPLC BEH C18色谱柱（50 mm×2.1 mm,1.7 μm）分离,以乙腈和0.1%（v/v）甲酸水溶液为流动相进行梯度洗脱。通过静电场轨道阱全扫描得到激素化合物的准分子离子的精确质量数,实现对化妆品中激素的快速筛查;再以保留时间和数据依赖扫描（data dependent scan）模式获得的子离子质谱图进行定性确证。24种激素化合物的质量准确度误差小于3×10^-6（3 ppm）;线性良好,相关系数大于0.99;检出限≤10 μg/kg（S/N=3）,能满足实际化妆品样品的分析要求。应用该方法对不同剂型的50余种化妆品样品进行筛查分析,结果良好。该方法是化妆品中激素快速筛查、定性识别的有效方法。     

超高效液相色谱-线性离子阱/静电场轨道阱高分辨质谱法测定纺织品中的游离态致癌芳香胺

建立了超高效液相色谱-线性离子阱/静电场轨道阱高分辨质谱(UPLC-LTQ/Orbitrap MS)同时测定纺织品中24种游离态致癌芳香胺的方法。样品经二氯甲烷超声提取并稀释后,用ZORBAX SB-C₁₈色谱柱(150 mm×2.1 mm, 5 μm)分离,以0.1%甲酸水溶液和甲醇为流动相,电喷雾正离子(ESI⁺)模式电离,以准分子离子峰的精确质量数和保留时间定性,以提取的色谱图峰面积定量。在0.5~500 μg/L范围内,24种芳香胺的线性相关系数(R²) 大于0.99,样品加标回收率为87.8%~105.6%,相对标准偏差为1.6%~3.4%。方法检出限为0.5~1 μg/kg。应用本方法检测山东地区进出口含氨纶纺织品样品14个,在5个样品中检出游离态芳香胺4,4'-二氨基二苯甲烷,含量范围为0.21~25.6 mg/kg。     

超高效液相色谱-线性离子阱/静电场轨道阱质谱快速筛查和确证化妆品中孔雀石绿、结晶紫及其代谢物

采用超高效液相色谱-线性离子阱/静电场轨道阱组合式高分辨质谱联用技术,建立了快速筛查、定性识别化妆品中的孔雀石绿、隐色孔雀石绿、结晶紫和隐色结晶紫的方法。不同剂型的化妆品样品经甲醇提取后,通过静电场轨道阱高分辨质谱全扫描得到目标化合物准分子离子的精确质量数,据此对化妆品进行快速筛查,并用离子阱的二级质谱分析对化合物进行了进一步确认,4种化合物检出限≤5μg/kg。方法适用于化妆品中孔雀石绿、隐色孔雀石绿、结晶紫和隐色结晶紫的快速筛查和确证。     

超高效液相色谱-线性离子阱/静电场轨道阱高分辨质谱鉴别纺织品中禁用芳香胺及其异构体

针对目前纺织品中禁用偶氮染料检测中的假阳性问题,建立了一套应用超高效液相色谱-线性离子阱/静电场轨道阱高分辨质谱（UPLC-LTQ/Orbitrap）同时筛选24种禁用芳香胺及其常见的14种异构体的方法。样品经连二亚硫酸钠还原,叔丁基甲醚提取后,以水/甲醇（9/1,v/v）稀释定容,用ZORBAX SB-C₁₈色谱柱（150 mm×2.1 mm,5 μm）分离,以0.1%甲酸水溶液和甲醇为流动相,电喷雾正离子（ESI⁺）模式电离。以准分子离子峰的精确质量数和保留时间定性,以提取的色谱图峰面积定量。38种芳香胺的线性相关系数大于0.99,方法检出限为0.5~5 μg/kg。该方法可通过一次实验同时对24种禁用芳香胺及其常见的14种异构体准确定性定量,大大缩短检测周期,实际样品检测也进一步验证了其灵敏性和准确性。     

分散液液微萃取/超高效液相色谱-四极杆/静电场轨道阱质谱法快速筛查化妆水中139种药物残留

建立了分散液液微萃取(DLLME)结合超高效液相色谱-四极杆/静电场轨道阱质谱(UPLC-Q Exac-tive Orbitrap MS)同时测定化妆水中抗生素、激素、禁用染料、农药以及真菌毒素5大类共139种药物残留的分析方法。考察了DLLME各条件对萃取效果的影响,确定最佳萃取条件为：取样量5.0 g,萃取剂为四氯乙烷(50μL)、分散剂为乙腈(300μL)、氯化钠用量为0.30 g、超声时间为8 min。样品经萃取后,采用岛津Shimpack XR-ODS II(150 mm×2.0 mm,2.2μm)色谱柱分离,通过Q-Exactive Orbitrap MS以全扫描确定母离子精确质量数的离子丰度,实现多种类目标物的定量,结合保留时间和子离子数据依赖模式扫描(DD-MS2)确定子离子的精确质量数,并配合谱库检索进行快速确证与筛查。结果表明：139种化合物的质量浓度在10～1 000 ng/m L范围内与峰强度呈良好线性关系(r> 0.99),检出限为10～30μg/kg,回收率为63.0%～95.9%,相对标准偏差(RSD)为3.0%～9.5%;各精确质量数偏差小于3×1...     

高效液相色谱-线性离子阱/静电场轨道阱高分辨质谱筛查和确证纺织品中的致癌染料

建立了高效液相色谱-线性离子阱/静电场轨道阱高分辨质谱(HPLC-LTQ/Orbitrap MS)筛查和确证生态纺织品中致癌染料的方法。样品在水浴(95 ℃)中用吡啶/水(1/1, v/v)振荡(150 r/min)提取,上清液过聚四氟乙烯(PTFE)滤膜后,CAPCELL PAK C₁₈色谱柱(100 mm×2.0 mm, 5 μm)分离,以乙腈和5 mmol/L乙酸铵水溶液(含0.01%甲酸)、乙腈和5 mmol/L乙酸铵水溶液分别作为正、负电喷雾离子化(ESI)模式的色谱流动相梯度洗脱。在m/z 200~800范围内进行一级质谱全扫描。以准分子离子峰的精确质量数和提取的色谱图峰面积进行筛查分析和定量,以保留时间和数据依赖扫描(data-dependent scan)模式获得的子离子质谱图进行定性确证。9种染料的质量准确度小于5×10^-6(5 ppm),线性良好,相关系数大于0.99,方法检出限为0.125~25 mg/kg。3个添加水平的回收率范围为62.13%~116.28%,相对标准偏差小于15%。应用该方法检测了棉、涤纶及混纺纤维等20余件纺织品样品中的致癌染料残留。该方法准确、可靠。     

液相色谱/线性离子阱-静电场轨道阱高分辨质谱法快速筛查葡萄酒中的合成色素

基于液相色谱/线性离子阱-静电场轨道阱高分辨质谱(LC/LTQ-orbitrap MS)技术构建了合成色素的质谱数据库,利用精确质量数和该数据库中二级质谱图的匹配度分析筛查,建立了葡萄酒中15种水溶性合成色素的快速筛查方法。葡萄酒样品通过弱阴离子交换柱进行净化后经苯基色谱柱分离,然后用LTQ-orbitrap MS对样品中的色素进行筛查和定量检测。结果显示,葡萄酒中15种色素的检出限在0.00040~0.18 mg/L之间,3个加标水平的回收率在43.1%~127%之间,平均相对标准偏差均小于10%。加标样品的二级质谱图与数据库中标准样品二级质谱图的匹配度均达到98%以上。该方法可在无标准物质的情况下对葡萄酒中的15种合成色素进行筛查检测。     

高效液相色谱-线性离子阱/静电场轨道阱高分辨质谱法快速筛查和确证纺织品中禁用的偶氮染料

建立了高效液相色谱-线性离子阱/静电场轨道阱高分辨质谱(HPLC-LTQ/Orbitrap MS)快速筛查确证纺织品中禁用的偶氮染料的方法。样品在柠檬酸缓冲液中由连二亚硫酸钠还原成芳香胺,经硅藻土提取柱净化后,用Acquity UPLC BEH C18柱(50 mm×2.1 mm, 1.7 μm)分离,以甲醇和0.1%(v/v)甲酸作为流动相进行梯度洗脱,电喷雾正离子(ESI+)模式电离,高分辨质谱一级全扫描用于筛选分析,数据依赖扫描模式的二级碰撞诱导解离(CID)谱图用于确证,对纺织品样品中的偶氮染料进行定性鉴别。在0.05~2.00 mg/L范围内,21种致癌芳香胺的线性相关系数均大于0.99。通过实际样品的加标回收测定,回收率范围为65.5%~111.5%,相对标准偏差(n=6)为0.87%~2.49%。该方法的定量限可以达到0.08 mg/kg,可用于纺织品中禁用偶氮染料的实际检验工作。     

通过式固相萃取-液相色谱-四极杆/静电场轨道阱高分辨质谱快速筛查鱼肉中全氟化合物及其前体物质

采用通过式固相萃取技术去除样品基质中脂肪和磷脂等杂质干扰,利用液相色谱-四极杆/静电场轨道阱高分辨质谱( LC-Q Exactuve Orbutrap MS)的同时定性定量功能,建立了鱼肉中18种全氟化合物( Perfluoru-nated compounds, PFCs)及其21种前体物质的同时分析方法。样品经90%乙腈溶液提取,Oasus PRuME HLB通过式固相萃取柱净化,C18色谱柱分离,同时在液相色谱系统混合器和进样器之间串联一根延迟色谱柱,去除液相色谱系统的背景干扰;质谱数据采集使用Q Exactuve高分辨质谱的Full MS/dd-MS2监测模式,以Full MS一级质谱全扫描提取母离子精确质量数所得的色谱峰面积进行定量,以保留时间和dd-MS2数据依赖子离子扫描所得的二级子离子质谱图进行定性确证。39种目标物的精确质量数偏差不大于3×10-6,浓度与母离子峰面积的线性关系良好,相关系数≥0.99,检出限为0.02~0.50μg/kg。基质加标回收率在61.7%~122%之间,相对标准偏差(RSD)为6.9%~18.8%。本方法实现了18种PFCs及其21种前体物质的同时确证和测定,拓展了生物基质中全氟化合物的检测种类,而且前处理方法更为简化、部分化合物的灵敏度比文献报道方法提高约一个数量级,为全氟化合物前体物质的生物转化研究提供了高效的技术基础。     

基于精确质量数筛选的亲水作用色谱-高分辨质谱法快速鉴别赤潮藻中的麻痹性贝毒素

采用亲水作用色谱-高分辨电喷雾质谱联用技术(HILIC-HR-ESI/MS)结合麻痹性贝毒素(PSP)精确质量数数据库,建立快速筛查、定性识别赤潮藻中各种常见PSP的方法。产毒藻细胞破碎后经0.1 mol/L乙酸溶液提取,通过HILIC-HR-ESI/MS正负离子模式全扫描分析,得到产毒藻粗提物中PSP化合物准分子离子及主要碎片离子精确质量数,结合PSP数据库筛查并辅以商品化软件数据分析,实现产毒藻所含PSP的快速定性识别。所建数据库包含25种常见PSP化合物精确分子质量及碎片离子信息,所发展的HILIC-HR-ESI/MS方法分离度高、灵敏度好,所考察的10种常见PSP化合物检测限在10～80 nmol/L范围内,能满足产毒藻实际样品的分析要求。3种产毒藻实际样品筛查、分析结果良好,说明本方法是赤潮藻中麻痹性贝毒素快速筛选、定性识别的有效方法。     

同位素质谱和无机质谱

本文是《分析试验室》定期评述中“同位素质谱和无机质谱”的第四篇评述，评述的范围是１９９４年１１月至１９９６年１０月我国气体同位素质谱，热电离同位素质谱，加速器质谱，火花源质谱，电感耦合等离子体质谱，辉光放电质谱，同位素稀释质谱，二次离子质谱，激光共振电离子飞行时间质谱，电子探针，质子探针，激光探针和它们在地学，核科学，环境科学，材料学，计理学，医学和生命科学中的应用，引用文献１４９篇。     

Preparative Mass Spectrometry Using a Rotating-Wall Mass Analyzer

The design of functional interfaces is central to both fundamental and applied research in materials science and energy technology. We introduce a new, broadly applicable technique for the precisely controlled high-throughput preparation of well-defined interfaces containing polyatomic species ranging from small ions to nanocrystals and large protein complexes. The mass-dispersive deposition of ions onto surfaces is achieved using a rotating-wall mass analyzer, a compact device which enables the separation of ions using low voltages and has a theoretically unlimited mass range. We demonstrate an efficient deposition of singly charged Au₁₄₄(SC₄H₉)₆₀ ions (33.7 kDa), which opens up exciting opportunities for the structural characterization of nanocrystals and their assemblies using transmission electron microscopy. Our approach also enables the high-throughput deposition of mass-selected ions from multicomponent mixtures, which is of interest to the controlled preparation of surface gradients and rapid screening of molecules in mixtures for a specific property.     

Boundaries of Mass Resolution in Native Mass Spectrometry

Over the last two decades, native mass spectrometry (MS) has emerged as a valuable tool to study intact proteins and noncovalent protein complexes. Studied experimental systems range from small-molecule (drug)–protein interactions, to nanomachineries such as the proteasome and ribosome, to even virus assembly. In native MS, ions attain high m/z values, requiring special mass analyzers for their detection. Depending on the particular mass analyzer used, instrumental mass resolution does often decrease at higher m/z but can still be above a couple of thousand at m/z 5000. However, the mass resolving power obtained on charge states of protein complexes in this m/z region is experimentally found to remain well below the inherent instrument resolution of the mass analyzers employed. Here, we inquire into reasons for this discrepancy and ask how native MS would benefit from higher instrumental mass resolution. To answer this question, we discuss advantages and shortcomings of mass analyzers used to study intact biomolecules and biomolecular complexes in their native state, and we review which other factors determine mass resolving power in native MS analyses. Recent examples from the literature are given to illustrate the current status and limitations.

Mass Defect from Nuclear Physics to Mass Spectral Analysis

Mass defect is associated with the binding energy of the nucleus. It is a fundamental property of the nucleus and the principle behind nuclear energy. Mass defect has also entered into the mass spectrometry terminology with the availability of high resolution mass spectrometry and has found application in mass spectral analysis. In this application, isobaric masses are differentiated and identified by their mass defect. What is the relationship between nuclear mass defect and mass defect used in mass spectral analysis, and are they the same?

Open image in new window

Graphical Abstract ?

     

Mass Determination of Entire Amyloid Fibrils by Using Mass Spectrometry

Amyloid fibrils are self‐assembled protein structures with important roles in biology (either pathogenic or physiological), and are attracting increasing interest in nanotechnology. However, because of their high aspect ratio and the presence of some polymorphism, that is, the possibility to adopt various structures, their characterization is challenging and basic information such as their mass is unknown. Here we show that charge‐detection mass spectrometry, recently developed for large self‐assembled systems such as viruses, provides such information in a straightforward manner.     

A Novel 9.4 Tesla FTICR Mass Spectrometer with Improved Sensitivity,Mass Resolution,and Mass Range

Fourier transform ion cyclotron resonance (FTICR) mass spectrometry provides unparalleled mass measurement accuracy and resolving power. However, propagation of the technique into new analytical fields requires continued advances in instrument speed and sensitivity. Here, we describe a substantial redesign of our custom-built 9.4 tesla FTICR mass spectrometer that improves sensitivity, acquisition speed, and provides an optimized platform for future instrumentation development. The instrument was designed around custom vacuum chambers for improved ion optical alignment, minimized distance from the external ion trap to magnetic field center, and high conductance for effective differential pumping. The length of the transfer optics is 30% shorter than the prior system, for reduced time-of-flight mass discrimination and increased ion transmission and trapping efficiency at the ICR cell. The ICR cell, electrical vacuum feedthroughs, and cabling have been improved to reduce the detection circuit capacitance (and improve detection sensitivity) 2-fold. The design simplifies access to the ICR cell, and the modular vacuum flange accommodates new ICR cell technology, including linearized excitation, high surface area detection, and tunable electrostatic trapping potential.