“一锅法”制备聚(苯乙烯-丙烯酸)共聚物改性的硅基固定相及其在混合模式液相色谱中的应用

聚合物作为一种来源广泛、功能基团丰富、生物相容性良好的修饰配体,被广泛用作硅基色谱固定相。本工作以苯乙烯和丙烯酸为聚合单体,乙烯基三甲氧基硅烷为硅烷偶联剂,通过自由基聚合反应一锅法制备了聚(苯乙烯-丙烯酸)共聚物改性的硅基固定相(SiO_(2)@P(St-b-AA))。傅里叶红外光谱、热重分析、扫描电镜、N_(2)吸附-脱附、Zeta电势分析等表征手段证明了该固定相已成功合成,且保持了良好的介孔球形结构。在固定相性能评价中,分别采用疏水性分析物、极性分析物和离子型化合物作为探针,对固定相的分离性能和保留机理进行了考察。其中,由于苯环提供的疏水和π-π相互作用,烷基苯和多环芳香烃在固定相上的保留随着流动相中甲醇含量的增加而减弱;由于羧酸基团可以为固定相与核苷碱基等极性溶质之间提供亲水相互作用,随着流动相中乙腈含量的增加,极性分析物的保留逐渐增强;与自制的C18和Amide固定相相比,SiO_(2)@P(St-b-AA)固定相在反相和亲水模式下均表现出良好的分离性能。此外,通过探究流动相pH对离子型化合物保留的影响,证明了该固定相还具有弱阳离子交换能力。多种分离模式表明SiO_(2)@P(St-b-AA)固定相可提供多种相互作用,并在不同极性组分分析物的分离中具有良好的应用前景。通过考察制备方法的重复性,证明了该方法具有良好的制备批次稳定性,简便的“一锅法”为新型聚合物改性硅基固定相的发展提供了一种新思路。

酰胺和咪唑基离子液体双极性基团共嵌入式亲水C18硅胶固定相的制备与应用

利用分步键合法制备了酰胺和咪唑基离子液体双极性基团共嵌入的十八烷基修饰硅胶色谱固定相,并通过离子交换制备了2种具有不同阴离子配位的固定相(Sil-IL-AMC18-Cl和Sil-IL-AMC18-Tf2N).采用红外光谱和元素分析对2种固定相进行了表征,发现红外光谱中均在1460和661 cm^(-1)处出现了咪唑环上C=C的伸缩振动峰和C=N的弯曲振动峰,在2927和2856 cm^(-1)处出现了─CH的不对称和对称伸缩振动峰,证明氨基咪唑离子液体键合成功;而原有919 cm^(-1)处的伯胺N─H面外变形振动峰消失,说明十八烷基酰氯与氨基已键合.元素分析结果表明,Sil-IL-AMC18-Cl的氮元素含量为3.07%,碳元素含量为16.73%,氢元素含量为3.07%,Sil-IL-AMC18-Tf2N的氮元素含量为2.88%,碳元素含量为15.98%,氢元素含量为2.95%,说明确已制得Sil-ILAMC18-Cl和Sil-IL-AMC18-Tf2N色谱固定相.考察了2种固定相的色谱分离模式与分离性能,结果表明:(1)在反相色谱模式(RPLC)下,相较于商品化C18色谱柱,两种固定相均具有更高的柱效;(2)由于具有双极性基团,相较于传统亲水改性C18硅胶固定相具有更强的亲水能力,因此可以实现亲水色谱模式(HILIC);(3)在反相/亲水(RPLC/HILIC)混合色谱模式下,可同时分离亲水性和疏水性物质.通过考察发现,Sil-IL-AMC18-Cl固定相比Sil-IL-AMC18-Tf2N固定相有更强的亲水性能,因此在HILIC色谱模式下将Sil-IL-AMC18-Cl固定相应用于8种碱基核苷类物质的分离,可实现该类强亲水性物质的基线分离,进样重复性RSD=0.03%~0.25%(n=9);在RPLC色谱模式下将Sil-IL-AMC18-Tf2N固定相应用于6种苯胺类物质的分离,不仅可以实现基线分离,而且可明显改善苯胺类物质的峰拖尾现象,进样重复性RSD=0.05%~0.10%(n=9).

Combination of reversed phase liquid chromatography and zwitterion exchange-reversed phase-hydrophilic interaction mixed-mode liquid chromatography coupled with mass spectrometry for the analysis of antibiotics and their impurities

In this study, a system involving two-dimensional, column-switching high-performance liquid chromatography （HPLC） coupled with tandem mass spectrometry （LC-MS/MS） was developed and optimized for the analysis of antibiotics and their related substances. In the first-dimensional chromatography, the analytes were separated on a zwitterion exchange-reversed phase-hydrophitic interaction （ZIC-RP-HILIC） mixed-mode column coupled with tandem mass spectrometry （LC-MS/MS）. A commonly used reversed phase LC column was employed in the second-dimensional chromatography. The mobile phase for the ZIC-RP-HILIC mixed-mode chromatography consisted of a volatile buffer that was compatible with LC-MS/MS, which enhanced the efficiency of ionization for structure elucidation. The antibiotic impurities eluted in the ion-pairing reversed phase chromatography were directly characterized by the ZIC-RP-HILIC-MS system, and the orthogonal separation of ZIC-RP-HILIC mixed-mode chromatography and reversed phase LC provided extra confidence that no impurity was missed. The efficiency of this method was demonstrated in the analysis of penicillin V potassium, oxacillin sodium, ceftriaxone sodium, and their impurities. In addition, this method is convenient for impurity profiling of antibiotics, and may be used for the analysis of other pharmaceutical ingredients.