丁香酚键合硅胶液相色谱固定相的制备和色谱性能

采用固液相表面连续反应法,先将偶联剂γ-[(2,3)-环氧丙氧]丙基三甲氧基硅烷(KH-560)键合到球形硅胶表面,然后再将植物有效成分丁香酚与硅胶上的KH-560活性基团反应,合成了丁香酚键合硅胶液相色谱固定相(EGSP)。采用元素分析、热重分析和红外光谱对该固定相的结构进行了表征。以萘作为溶质探针,乙腈-水(35:65, v/v)为流动相,流速为0.8 mL/min,测得EGSP柱的柱效。以一系列的中性、碱性和酸性化合物为溶质探针,C₁₈柱和苯基柱作参比,对该固定相的色谱性能及保留机理进行了研究。结果表明,硅胶表面成功键合上了丁香酚配体,键合量为0.28 mmol/g, EGSP柱理论塔板数约为24707 N/m。该固定相不仅具有良好的反相色谱性能,同时由于配体结构中含有芳环、烯基和甲氧基,还能与溶质发生π-π电荷转移、偶极-偶极和氢键作用。与传统的反相C₁₈柱和苯基柱相比,EGSP在极性芳香族化合物的快速、简便分离中占优势。     

氮杂冠醚键合固定相的RP-HPLC色谱性能研究

报道在硅胶表面进行固-液相反应合成的3-(氮杂-18-冠-6)丙基键合固定相对金属离子的络合能力和色谱性能,研究了流动相组成、pH值、金属离子对极性二取代苯保留值的影响,探讨色谱分离机理。这种键合相通过对金属离子的络合,显示多种色谱分离机理,对极性二取代苯异构体分离选择性、分析速度均优于对比的C₁₈键合固定相反相色谱。     

基于二醛微晶纤维素功能化C18的反相/亲水色谱固定相的制备

通过十八烷基胺的氨基与二醛微晶纤维素的醛基共价键合,制备了基于二醛微晶纤维素(DMCC)官能化C₁₈的新型反相/亲水色谱固定相(C₁₈-DMCC/SiO₂),该色谱固定相被用于反相色谱(RPLC)和亲水相互作用色谱(HILIC)模式。C₁₈-DMCC/SiO₂色谱柱展现了良好的疏水选择性和芳香选择性,在反相色谱模式下可分离烷基苯和多环芳烃(PAHs)。苯胺类、酚类和糖苷类等极性化合物被用于评估该色谱柱在反相色谱模式下的极性选择性,商品C₁₈柱作对照柱,色谱评价结果令人满意。核酸碱基被用于评估C₁₈-DMCC/SiO₂色谱柱的亲水色谱性能。通过考察有机溶剂含量对分析物保留的影响,发现该新型色谱固定相具有反相/亲水色谱的典型特征。     

生物碱在十八烷基膦酸改性锆-镁复合氧化物固定相上的色谱行为

研究了某些生物碱在十八烷基膦酸改性锆-镁复合氧化物固定相(C18PZM)上的色谱行为。通过考察流动相参数如甲醇含量、缓冲液pH值和离子强度对生物碱保留的影响,对这类化合物在该固定相上的保留机理进行了探讨。结果表明,在实验色谱条件下,生物碱在C18PZM上表现出反相和阳离子交换的混合保留模式机理。锆-镁基质上化学吸附的十八烷基膦酸和其对流动相中路易斯碱的吸附以及锆羟基本身均有可能是该固定相的离子交换作用位点的来源。高pH值流动相,溶质大部分以分子状态使用形式存在,因此其保留以疏水作用为主。在甲醇-pH 10.1 Tris缓冲液,生物碱的分离取得了满意的结果。与传统的烷基键合硅胶反相固定相相比,C18PZM表现出了更优越的化学稳定性,对于碱性化合物,尤其是具有高pKa值的碱性化合物的分离分析有着广泛的应用前景,有望发展为与硅胶键合固定相互补的一类反相HPLC的固定相。     

纳米氧化锆沉积硅胶色谱固定相的制备及亲水作用色谱行为

采用液相沉积法(LPD)制备了纳米氧化锆沉积硅胶色谱固定相(ZrO₂/SiO₂), 并将其应用于亲水作用色谱分离中. 考察并比较了ZrO₂/SiO₂、 硅胶(SiO₂)和氧化锆(ZrO₂) 3种色谱固定相在不同有机调节剂比例、 不同pH值及不同盐浓度的流动相条件下的色谱行为. 结果表明, 制备的ZrO₂/SiO₂色谱柱不仅具有SiO₂色谱柱高柱效的优点, 表面沉积的纳米氧化锆还能有效屏蔽硅羟基, 有利于碱性物质的保留和分离, 表现出良好的亲水作用色谱性能. 将ZrO₂/SiO₂色谱柱用于4种脱氧核苷和5种碱性化合物的分离, 均得到了较好的效果, 展现出其作为色谱固定相良好的应用前景.     

大黄素键合硅胶高效液相色谱柱的制备和应用

采用中间体法,先将大黄素配体与γ-[（2,3）-环氧丙氧]丙基三甲氧基硅烷（KH-560）偶联剂反应制备含配体的硅氧烷试剂,然后再与硅胶键合,最终制得大黄素键合硅胶液相色谱固定相（以下简称ESP）。通过红外光谱、元素分析和热重分析表征固定相的结构。以萘作为溶质探针,甲醇-水（60：40,v/v）为流动相,流速为0.8 mL/min,测得ESP柱的柱效。采用传统的反相C₁₈和苯基柱作参比,将ESP应用于系列中性、碱性和酸性芳香族化合物以及实际样品风油精的分离分析,并探讨相关的色谱分离机理。结果表明,配体大黄素被成功地键合到球形硅胶表面,测得配体键合量为0.23 mmol/g,ESP柱理论塔板数约为19874 N/m。ESP的偶联剂链和蒽醌环提供了疏水性的结构基础,大黄素配体还能为溶质提供π-π或p-π、电荷转移、氢键、偶极-偶极等作用点。多位点的协同作用使得ESP柱具有独特和优秀的色谱分离选择性,并且无需调节pH值,采用简单而廉价的甲醇-水流动相就能实现胺类、酚类等极性样品的基线分离,实验条件简单、方便。     

ATRP技术制备Sil-LMA反相作用色谱固定相及其性能研究

以5μm大孔硅胶为基质,CuBr/Bpy为催化体系,采用原子转移自由基聚合(Atom transfer radical polymerization,ATRP)技术将甲基丙烯酸月桂酯(LMA)键合到硅胶表面,制得Sil-LMA反相作用色谱固定相。采用元素分析对该固定相进行表征,以芳香族化合物为溶质,甲醇-水为流动相,对该键合相的疏水选择性进行了考察。详细研究了甲醇浓度和温度对溶质保留行为的影响,以胺类、酚类化合物为溶质,评价了其色谱性能,并计算了溶质保留过程的热力学参数。经元素分析测得该填料的接枝量高达2.323 3 mg/m2。实验结果表明,在反相模式下该固定相可基线分离5种胺类化合物和5种酚类化合物。与C18反相柱相比,该合成柱的分离时间缩短且分离效果较好。该固定相具有很好的反相色谱性能,符合反相保留机理。     

双阳离子型离子液体和十八烷基修饰的混合模式硅胶固定相的制备及色谱性能

通过分步键合反应制备了一种咪唑基双阳离子型离子液体和十八烷基共同修饰的混合模式硅胶色谱固定相(Sil-C18-IL-C4); 采用元素分析和红外光谱对其进行了表征. 分别评价了该固定相在反相色谱模式(RPLC)、 亲水色谱模式(HILIC)和RPLC/HILIC混合色谱模式下的色谱分离性能, 并在HILIC模式下对6种碱基核苷类化合物进行分离, 考察了流动相中有机相体积分数和水相中甲酸铵浓度对分离效果的影响. 此外, 还考察了该固定相的分离重复性. 制备的Sil-C18-IL-C4固定相的元素分析结果表明, 氮元素含量为1.65%, 碳元素含量为11.16%, 氢元素含量为2.44%. 该固定相的红外光谱中, 2928和2856 cm^?1处出现了—CH的不对称和对称伸缩振动峰, 1440 和660 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, 说明十八烷基和1,5-双(咪唑-1-基)戊烷均已接枝到硅胶表面. 色谱性能评价结果表明, Sil-C18-IL-C4固定相可表现出反相色谱模式和亲水色谱模式分离性能, 对6种碱基核苷类物质能够实现完全分离, 而且在一定的色谱条件下可以在单根色谱柱单次运行中实现RPLC/HILIC混合模式色谱分离, 对于处理复杂样品中的碱基核苷类化合物等亲水物质具有良好的应用潜能.     

L-异亮氨酸键合色谱固定相的制备及其性能

利用异氰酸丙基三乙氧基硅烷与L-异亮氨酸反应合成了一种新型的硅烷偶联剂,并进一步将其与硅胶反应制得键合有L-异亮氨酸的亲水色谱固定相。 通过核磁共振氢谱表明亮氨酸功能化硅烷偶联剂的成功合成、元素分析表征证明亮氨酸已成功键合到硅胶表面。 将其作为亲水模式下的固定相填料填装在150 mm×4.6 mm不锈钢色谱柱中,以一系列经典的极性小分子作为探针,考察了这些探针分子在固定相上的色谱行为。 极性化合物的保留时间随着流动相中有机溶剂含量提高而逐渐增大,表现出典型的亲水保留特征。 进一步研究了流动相中乙腈含量、缓冲盐pH值及缓冲盐浓度等因素对分析物在固定相上的保留的影响。 在优化了相关参数后,将固定相应用于碱性化合物、水溶性维生素以及核苷类极性物质的分离当中。 在等度洗脱下,5种碱性化合物、6种水溶性维生素和8种核苷类物质分别在8、18及25 min内被成功分离。 分离结果表明了合成的L-异亮氨酸键合亲水色谱固定相具有较好的色谱性能,在极性化合物的分离上具有良好的应用前景。     

聚硅氧烷包夹聚合硅基高效液相色谱固定相的表征及其色谱性能

利用元素分析、红外光谱、扫描电镜及汞压吸附法对制备的聚硅氧烷包夹硅基反相高效液相色谱固定相进行了表征,给出了该固定相的结构信息及其与色谱性能的关系;用滴定法测定了该固定相表面硅羟基数目;考察了该固定相对碱性化合物的分离性能;由表征和色谱性能考察结果可知,该固定相表面的羟基基本被覆盖,因此,可在碱性流动相中长期使用。     

Separation behavior of basic compounds on unbonded silicon oxynitride and silica high‐performance liquid chromatography stationary phases with reversed‐phase eluents

Unbonded silicon oxynitride and silica high‐performance liquid chromatography stationary phases have been evaluated and compared for the separation of basic compounds of differing molecular weight, pK_a, and log D using aqueous/organic mobile phases. The influences of percentage of organic modifier, buffer pH, and concentration in the mobile phase on base retention were investigated on unbonded silicon oxynitride and silica phases. The results confirmed that unbonded silicon oxynitride and silica phases demonstrated excellent separation performance for model basic compounds and both the unbonded phases examined possessed a hydrophobic/adsorption and ion‐exchange character. The silicon oxynitride stationary phase exhibited high hydrophilicity compared with silica with a reversed‐phase mobile phase. An ion‐exclusion‐type mechanism becomes predominant for the separation of three aimed bases on the silicon oxynitride column at pH 2.8. Different from silicon oxynitride stationary phase, no obvious change for the retention time of three model bases on silica stationary phase at pH 2.8 can be observed.     

Automated screening of reversed‐phase stationary phases for small‐molecule separations using liquid chromatography with mass spectrometry

There are various reversed‐phase stationary phases that offer significant differences in selectivity and retention. To investigate different reversed‐phase stationary phases (aqueous stable C₁₈, biphenyl, pentafluorophenyl propyl, and polar‐embedded alkyl) in an automated fashion, commercial software and associated hardware for mobile phase and column selection were used in conjunction with liquid chromatography and a triple quadrupole mass spectrometer detector. A model analyte mixture was prepared using a combination of standards from varying classes of analytes (including drugs, drugs of abuse, amino acids, nicotine, and nicotine‐like compounds). Chromatographic results revealed diverse variations in selectivity and peak shape. Differences in the elution order of analytes on the polar‐embedded alkyl phase for several analytes showed distinct selectivity differences compared to the aqueous C₁₈ phase. The electron‐rich pentafluorophenyl propyl phase showed unique selectivity toward protonated amines. The biphenyl phase provided further changes in selectivity relative to C₁₈ with a methanolic phase, but it behaved very similarly to a C₁₈ when an acetonitrile‐based mobile phase was evaluated. This study shows the value of rapid column screening as an alternative to excessive mobile phase variation to obtain suitable chromatographic settings for analyte separation.     

Separation of Free Amiimo Acids on Reverse Stationary Phases Using an Alkyl Sulfonate Salt as a Mobile Phase Additive

Abstract

Alkylsulfonate (RSO₃ ^?) salts were evaluated as mobile phase additives for the separation of free amino acids on reverse stationary phases using an acidic mobile phase where the amino acids are cations. The enhanced amino acid retention is the result of two major interactions, one being retention of the RSO₃ ^? salt on the stationary phase and the other an ion exchange selectivity between the amino acid analyte cation and the RSO₃ ^? countercation, or other countercations in the mobile phase. Major mobile phase variables are: type and concentration of RSO₃ ^? salt (the studies focused on C₈SO₃ ^? salts), presence of organic modifier, type of countercation present, and mobile phase pH and ionic strength. Alkyl modified silica and polystyrenedivinyl-benzene copolymeric reverse stationary phases were compared. A mobile phase gradient, increasing per cent organic modifier was shown to be best, is necessary for separating complex mixtures of polar and nonpolar or basic amino acids. The procedure is applicable to the identification and/or determination of amino acids in mixtures or in peptides after hydrolysis.     

Further investigations of the effect of pressure on retention in ultra-high-pressure liquid chromatography

In this study, we investigated further the large increases in retention with pressure that we observed previously in RP-LC especially for ionised solutes. These findings were initially confirmed on a conventional silica C₁₈ column, which gave extremely similar results to the hybrid C₁₈ phase originally used. Large increases in retention factor of ∼50% for a pressure increase of 500 bar were also shown for high MW polar but neutral solutes. However, experiments with the same bases in ionised and non-ionised forms suggest that somewhat greater pressure-induced retention increases are found for ionised solutes. Retention increases with pressure were found to be considerably smaller for a C₁ column compared with a C₁₈ column; decreases in retention with increasing pressure were noted for ionised bases when using a bare silica column in the hydrophilic interaction chromatography (HILIC) mode. These observations are consistent with the partial loss of the solvation layer in RP-LC as the solute is forced into the hydrophobic environment of the stationary phase, and consequent reduction in the solute molar volume, while the water layer on the surface of a HILIC packing increases the hydration of a basic analyte. Finally, retention changes with pressure in RP-LC can also be observed at a mobile phase pH close to the solute pK_a, due to changes in pK_a with pressure. However, this effect has no influence on the results of most of our studies.     

Preparation and evaluation of n-octadecylphosphonic acid-modified magnesia-zirconia stationary phases for reversed-phase liquid chromatography

Three n-octadecylphosphonic acid-modified magnesia-zirconia reversed stationary phases (C₁₈PZM) are prepared via the strong Lewis base interactions between organophosphonate and magnesia-zirconia composite. And two of them are end-capped by using trimethylchlorosilane as end-capping agent in different procedures. Stability studies at extreme high pH conditions (pH 9-12) show that both the non-endcapped and endcapped columns are quite stable at pH 12 mobile phase. The reversed-phase liquid chromatographic behavior of three C₁₈PZM stationary phases are comparatively investigated in detail using a variety of basic compounds as probes. The retention of basic compounds on the three phases is studied over a wide range of pHs. And the possible retention mechanisms of basic compounds on the three stationary phases are discussed. The results show that the basic solutes retain by a hydrophobic and cation-exchange interaction mixed mechanism on three stationary phases when they are operated in eluents at pH values near to the pK_a of the Brönsted conjugate acid form of the analyte, suggesting that inherent zirconol groups on ZM are not expected to interact with bases via cation-exchange interaction at lower pH. Nonetheless, the non-endcapped phase differs markedly from the edncapped ones in retention and selectivity of basic solutes using eluents at pH 4.1, implying a complex retention mechanism at this pH. The cation-exchange sites under such conditions are more likely due to the adsorbed Lewis base anionic buffer constituents (acetate) on accessible ZM surface sites than the chemisorbed phosphonate. Although the three phases exhibit very similar chromatographic behavior with eluents at pH 10.1, and show in general satisfactory separation of basic compounds and alkaloids studied, the performance for a specific analyte, however, differs largely from column to column.     

Optimization of chromatography to overcome matrix effect for reliable estimation of four small molecular drugs from biological fluids using LC–MS/MS

The article describes a systematic study to overcome the matrix effect during chromatographic analysis of gemfibrozil, rivastigmine, telmisartan and tacrolimus from biological fluids using LC–ESI–MS/MS. All four methods were thoroughly developed by the appropriate choice of analytical column, elution mode and pH of mobile phase for improved chromatography and overall method performance. Matrix effect was assessed by post-column analyte infusion, slope of calibration line approach and post-extraction spiking. The best chromatographic conditions established were: Acquity BEH C₁₈ (50 × 2.1 mm, 1.7 μm) column with 5.0 mm ammonium acetate, pH 6.0–methanol as the mobile phase under gradient program for gemfibrozil; Luna CN (50 × 2.0 mm, 3 μm) column with a mobile phase consisting of acetonitrile–10 mm ammonium acetate, pH 7.0 (90:10, v/v) for rivastigmine; Inertsustain C₁₈ (100 × 2.0 mm, 5 μm) column using methanol–2.0 mm ammonium formate, pH 5.5 (80: 20, v/v) as the mobile phase for isocratic elution of telmisartan; and Acquity BEH C₁₈ (50 × 2.1 mm, 1.7 μm) with methanol–10 mm ammonium acetate, pH 6.0 (95:5, v/v) as mobile phase for tacrolimus. The methods were thoroughly validated as per European Medicines Agency and US Food and Drug Administration guidance and were successfully applied for pharmacokinetic studies in healthy subjects.     

Synthesis of a stationary phase based on silica modified with branched octadecyl groups by Michael addition and photoinduced thiol–yne click chemistry for the separation of basic compounds

A novel silica‐based stationary phase with branched octadecyl groups was prepared by the sequential employment of the Michael addition reaction and photoinduced thiol–yne click chemistry with 3‐aminopropyl‐functionalized silica microspheres as the initial material. The resulting stationary phase denoted as SiO₂‐N(C18)₄ was characterized by elemental analysis, FTIR spectroscopy and Raman spectroscopy, demonstrating the existence of branched octadecyl groups in silica microspheres. The separations of benzene homologous compounds, acid compounds and amine analogues were conducted, demonstrating mixed‐mode separation mechanism on SiO₂‐N(C18)₄. Baseline separation of basic drugs mixture was acquired with the mobile phase of acetonitrile/H₂O (5%, v/v). SiO₂‐N(C18)₄ was further applied to separate Corydalis yanhusuo Wang water extracts, and more baseline separation peaks were obtained for SiO₂‐N(C18)₄ than those on Atlantis dC18 column. It can be expected that this new silica‐based stationary phase will exhibit great potential in the analysis of basic compounds.     

Preparation of Cyclodextrin Type Stationary Phase Based on Graphene Oxide and Its Application in Enantioseparation and Hydrophilic Interaction Chromatography

Graphene oxide (GO) was covalently coupled to the surface of amino silica gel by amide bond. β-cyclodextrin (β-CD) was further chemically bonded with GO to prepare a novel chiral stationary phase. The resulting material was characterized by Fourier transform-infrared (FT-IR) spectra, scanning electron microscopy (SEM), transmission electron microscopy (TEM), elemental analysis and thermogravimetric analysis (TGA). The separation of seven enantiomers was improved in varying degrees. Meanwhile, the stationary phase showed typical characteristics of hydrophilic interaction chromatography (HILIC), and four small nucleoside molecules were separated with the mobile phase of methanol-acetonitrile-water (45:45:10, V/V) in the HILIC mode. In addition, the separation mechanism of the stationary phase was further explored by studying the effects of mobile phase composition, temperature and pH value on the analyte retention. The low temperature was conducive to the separation of analytes at 20–60 °C. The addition of protonated solvent methanol significantly decreased the retention time of the four analytes. The change of pH affected the degree of protonation of the analyte, the interaction between analytes and the stationary phase, and retention time of analytes. The results showed that GO and β-CD played a synergistic effect in the chiral resolution of the chromatographic stationary phase. The retention of analytes in HILIC was attributed to their mixed-mode retention mechanisms including hydrophilic interaction, electrostatic interaction, hydrogen bonding, π-π stacking and so on.     

Evaluation of an amide‐based stationary phase for supercritical fluid chromatography

A relatively new stationary phase containing a polar group embedded in a hydrophobic backbone (i.e., ACE ® C18‐amide) was evaluated for use in supercritical fluid chromatography. The amide‐based column was compared with columns packed with bare silica, C₁₈ silica, and a terminal‐amide silica phase. The system was held at supercritical pressure and temperature with a mobile phase composition of CO₂ and methanol as cosolvent. The linear solvation energy relationship model was used to evaluate the behavior of these stationary phases, relating the retention factor of selected probes to specific chromatographic interactions. A five‐component test mixture, consisting of a group of drug‐like molecules was separated isocratically. The results show that the C₁₈‐amide stationary phase provided a combination of interactions contributing to the retention of the probe compounds. The hydrophobic interactions are favorable; however, the electron donating ability of the embedded amide group shows a large positive interaction. Under the chromatographic conditions used, the C₁₈‐amide column was able to provide baseline resolution of all the drug‐like probe compounds in a text mixture, while the other columns tested did not.     

Study of RP HPLC Retention Behaviours in Analysis of Carotenoids

For determination of selected carotenoids, various types of columns for high-performance liquid chromatography (HPLC) with different properties have been used. The characteristics of the laboratory-used packing material containing monomeric alkyl-bonded phases (C₁₈, C₃₀) and phenyl as well as phenyl-hexyl stationary phases were studied. The retention data of the examined compounds were used to determine the hydrophobicity and silanol activity of stationary phases applied in the study. The presence of the polar and carboxyl groups in the structure of the bonded ligand strongly influences the polarity of the stationary phase. Columns were compared according to methylene selectivity using a series of benzene homologues. The measurements were done using a methanol–water mobile phase. Knowledge of the properties of the applied stationary phase provided the possibility to predict the RP HPLC retention behaviours in analysis of carotenoids including lutein, lycopene and β-carotene. The composition of the mobile phase, the addition of triethylamine and the type of stationary phase had been taken into account in designing the method of carotenoid identification. Also a monolithic column characterised by low hydrodynamic resistance, high porosity and high permeability was applied. The presented results show that the coverage density of the bonded ligands on silica gel packings and length of the linkage strongly influence the carotenoid retention behaviours. In our study, the highest retention parameters for lutein, lycopene and β-carotene were observed for C₃₀ and C₁₈ stationary phase. This effect corresponds with pore size of column packing greater than 100 Å and carbon content higher than 11 %.