This work describes the on-line hyphenation of a packed capillary electrochromatography (CEC) column with an internally tapered tip coupled to electrospray ionization-mass spectrometry (ESI-MS) and atmospheric pressure chemical ionization-mass spectrometry (APCI-MS) for the analysis of betaine-type amphoteric or zwitterionic surfactants (Zwittergent). A systematic investigation of the CEC separation and MS detection parameters comparing ESI and APCI is shown. First, a detailed and optimized manufacturing procedure for fabrication of the CEC-MS column with a reproducible internally tapered tip (7-9 (mu)m) is presented. Next, the optimization of the separation parameters by varying the C_(18) stationary-phase particle size (3 versus 1.5 (mu)m), as well as mobile-phase composition including acetonitrile (ACN) volume fraction, ionic strength, and pH is described. The optimized separation is achieved using 3-(mu)m C_(18) packing with 75percent ACN (v/v), 5 mM Tris at pH 8.0. Optimization for on-line CEC-ESI-MS detection is then done varying both the sheath liquid and spray chamber parameters while evaluating the use of random versus structured factorial table experimental designs. The more structured approach allows fundamental analysis of individual ESI-MS parameters while minimizing CEC and MS equilibration time between settings. A comparison of CEC-ESI-MS to CEC-APCI-MS using similar sheath and spray chamber conditions presents new insight for coupling of CEC to APCI-MS. The sheath liquid flow rate required to maintain adequate sensitivity is much higher in APCI source (50 (mu)L/min) as compared to the ESI source (3 (mu)L/min). The on-line mass spectra obtained in the full scan mode show that fragmentation in the two sources occurs at different positions on the Zwittergent molecules. For ESI-MS, the protonated molecular ion is always highest in abundance with minor fragmentation occurring due to the loss of the alkyl chain. In contrast, the APCI-MS spectra show that the highest abundant ion resulted by elimination of propane sulfonate from the Zwittergent molecule. A comparison of the sensitivity between the two sources in positive ionization SIM mode shows that CEC-ESI-MS provides an impressive limit of detection (LOD) of 5 ng/mL, which is at least 3 orders of magnitude lower than CEC-APCI-MS (LOD 100 (mu)g/mL). Finally, the optimized CEC-MS methods comparing ESI and APCI are applied for separation and structural characterization of a real industrial zwittergent sample, Rewoteric AM CAS.
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机译:这项工作描述了填充毛细管电色谱(CEC)色谱柱的在线联用,该色谱柱的内部锥形尖端与电喷雾电离质谱(ESI-MS)和大气压化学电离质谱(APCI-MS)耦合进行分析甜菜碱型两性或两性离子表面活性剂(两性离子)。显示了比较ESI和APCI的CEC分离和MS检测参数的系统研究。首先,提出了用于制造具有可再现的内部锥形尖端(7-9μm)的CEC-MS色谱柱的详细和优化的制造程序。接下来,通过改变C_(18)固定相粒径(3对1.5μm)以及包括乙腈(ACN)体积分数,离子强度和pH的流动相组成来优化分离参数描述。使用3-μmC_(18)填料和75%ACN(v / v),5 mM Tris在pH 8.0下可实现最佳分离效果。然后,通过评估鞘液和喷雾室参数,进行在线CEC-ESI-MS检测的优化,同时评估随机与结构化因子表实验设计的使用情况。更加结构化的方法允许对单个ESI-MS参数进行基础分析,同时最大程度地减少设置之间的CEC和MS平衡时间。使用相似的鞘管和喷雾室条件对CEC-ESI-MS与CEC-APCI-MS进行比较,为CEC与APCI-MS的耦合提供了新的见解。与ESI源(3μL/ min)相比,APCI源(50μL/ min)所需的维持适当灵敏度的鞘液流速要高得多。在全扫描模式下获得的在线质谱表明,两个离子源中的碎片发生在两性离子分子上的不同位置。对于ESI-MS,由于烷基链的丢失,质子化的分子离子总是丰度最高的,而产生的碎片很少。相反,APCI-MS光谱表明,最高的丰度离子是由两性离子分子中的丙烷磺酸盐消除所致。对两种离子源在正电离SIM模式下的灵敏度进行的比较显示,CEC-ESI-MS提供了5 ng / mL的出色检测限(LOD),比CEC-APCI-低至少3个数量级。 MS(LOD100μg/ mL)。最后,将比较ESI和APCI的优化CEC-MS方法应用于真实的工业两性杀菌剂样品Rewoteric AM CAS的分离和结构表征。
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