高效液相色谱的4种商品手性柱对38种手性化合物的拆分研究

采用纤维素-三(3,5-二甲基苯基氨基甲酸酯)涂敷型手性固定相(Chiralcel OD柱)、直链淀粉-三(3,5-二甲基苯基氨基甲酸酯)涂敷型手性固定相(Chiralpak AD柱)、直链淀粉-三(3,5-二甲基苯基氨基甲酸酯)键合型手性固定相(Chiralpak IA柱)和Pirkle型的(S,S)-Whelk-01手性固定相对38种外消旋体化合物进行手性拆分。实验结果表明,4种固定相的手性识别能力为:OD>AD>IA>(S,S)-Whelk-01,OD固定相的手性识别率达到60%,并且它们之间的手性识别性能还具有一定的互补性。本研究对4种常用手性固定相的拆分能力进行了对比,为拆分手性化合物时有的放矢地选择手性固定相提供了参考。     

异噁唑啉及异噁唑烷类化合物在多糖衍生物类柱上的手性拆分

在ＣｈｉｒａｌｃｅｌＯＤ，ＣｈｉｒａｌｃｅｌＯＪ及ＣｈｉｒａｌｐａｋＡＤ等３种多糖类手性固定相上，以各种配比的正己烷－异丙醇为洗脱剂，对７种异口恶唑啉及异口恶唑烷类化合物的对映体进行了手性拆分。考察了这些外消旋物在这些手性柱上的色谱行为。实验结果表明，手性固定相上葡萄糖片段构型的差异和它们高级结构的不同以及手性固定相上的二甲基苯基氨基甲酸酯或对甲基苯甲酸酯等功能团与样品的极性基团之间的相互作用，可能是支配手性拆分的主要原因。方法已用于不对称１，３－偶极环加成反应产物的光学纯度鉴定。     

在多糖衍生物类色谱柱上手性拆分β-氨基醇及β-羟基 硫醚类化合物

在以正己烷-异丙醇为移动相的体系中,用ChiralcelOD,ChiralcelOJ及ChiralpakAD作为手性固定相对13种β-氨基醇及β-羟基硫醚类化合物对映体进行HPLC手性拆分,这些化合物至少能在一支柱上得到基线级分离。考察了它们于不同浓度配比的这类洗脱体系中在柱上的色谱行为。实验表明化合物取代基的性质明显影响它们在手性柱上的拆分。手性固定相与外消旋样品上的极性基团之间的氢键作用和π-π作用可能是进行手性识别的主要原因。方法已用于非手性环氧化合物不对称开环反应产物β-氨基醇及β-羟基硫醚类化合物的光学纯度鉴定。     

在多糖衍生物类色谱柱上手性拆分乙炔基氮杂环丙烷类化合物

在以正己烷－异丙醇为移动相的体系中，用ＣｈｉｒａｌｐａｋＡＤ和ＣｈｉｒａｌｃｅｌＯＤ作为手性固定相对１５种乙炔基氮杂环丙烷类化合物对映体进行了ＨＰＬＣ手性拆分。这些化合物至少在一支柱上能基线级分离。     

Liquid chromatographic enantiomer resolution of N-fluorenylmethoxycarbonyl alpha-amino acids and their ester derivatives on polysaccharide-derived chiral stationary phases

The liquid chromatographic enantiomer separation of N-fluorenylmethoxycarbonyl (FMOC) protected alpha-amino acids and their ethyl ester derivatives was performed on polysaccharide-derived chiral stationary phases, Chiralcel OD, Chiralpak AD, and Chiralpak AS. In general, Chiralcel OD and Chiralpak AD showed good performance for resolution of N-FMOC alpha-amino acids and their ethyl esters, respectively. All investigated N-FMOC alpha-amino acid enantiomers were baseline separated on Chiralcel OD or Chiralpak AD, whereas N-FMOC alpha-amino acid ethyl ester enantiomers were baseline resolved (alpha = 1.15-3.03) on Chiralpak AD, except for two analytes. The L-enantiomers of all examined FMOC alpha-amino acid ethyl ester derivatives are preferentially retained on Chiralpak AD, while the elution orders of the other enantiomer separations are not consistent.     

Comparative Chiral Separation of Thalidomide Class of Drugs Using Polysaccharide-Type Stationary Phases with Emphasis on Elution Order and Hysteresis in Polar Organic Mode

The enantioseparation of four phthalimide derivatives (thalidomide, pomalidomide, lenalidomide and apremilast) was investigated on five different polysaccharide-type stationary phases (Chiralpak AD, Chiralpak AS, Lux Amylose-2, Chiralcel OD and Chiralcel OJ-H) using neat methanol (MeOH), ethanol (EtOH), 1-propanol (PROP), 2-propanol (IPA) and acetonitrile (ACN) as polar organic mobile phases and also in combination. Along with the separation capacity of the applied systems, our study also focuses on the elution sequences, the effect of mobile phase mixtures and the hysteresis of retention and selectivity. Although on several cases extremely high resolutions (R_s > 10) were observed for certain compounds, among the tested conditions only Chiralcel OJ-H column with MeOH was successful for baseline-separation of all investigated drugs. Chiral selector- and mobile-phase-dependent reversals of elution order were observed. Reversal of elution order and hysteresis of retention and enantioselectivity were further investigated using different eluent mixtures on Chiralpak AD, Chiralcel OD and Lux Amylose-2 column. In an IPA/MeOH mixture, enantiomer elution-order reversal was observed depending on the eluent composition. Furthermore, in eluent mixtures, enantioselectivity depends on the direction from which the composition of the eluent is approached, regardless of the eluent pair used on amylose-based columns. Using a mixture of polar alcohols not only the selectivities but the enantiomer elution order can also be fine-tuned on Chiralpak AD column, which opens up the possibility of a new type of chiral screening strategy.     

Chiral Separation of Organic Phosphonate Compounds on Polysaccharide-Based Chiral Stationary Phases

Four polysaccharide-based chiral stationary phases have been used to separate the enantiomers of fourteen O,O-dialkyl-1-benzyloxycarbonyl-aminoarylmethyl phosphonates. These polysaccharide-based chiral stationary phases are Chiralpak AD, Chiralpak AS, Chiralcel OG and Chiralcel OJ. The data obtained indicate that the chiral separation ability for these organophosphonate compounds are in the order Chiralpak AD > Chiralcel OG > Chiralcel OJ > Chiralpak AS. With Chiralpak AD, all of the studied compounds could be easily baseline separated. Those two polysaccharides possess different chiral discrimination mechanism due to of the difference of the conformational structures of amylose and cellulose. The chiral discrimination of derivatized amylose chiral stationary phases were based on the stereogenic fit of the analytes in the helical structures of amylose and the transient diastereomeric complex formation between the analyte and the amylose CSP through π–π interaction H-bond interactions and induced dipole interactions exerted by the substituents on the analyte molecules. The chiral discrimination, in case of derivatized cellulose chiral stationary phase is based on the stereogenic fit of the analytes in the grooves of cellulose followed by interactions mentioned above between the analytes and the cellulose CSP.     

Separation of the enantiomers of 4-aryl-7,7-dimethyl- and 1,7,7-trimethyl-1,2,3,4,5,6,7,8-octahydroquinazoline-2,5-diones by chiral HPLC

Summary Analytical HPLC methods using derivatized cellulose chiral stationary phases have been developed for separation of the enantiomers of 25 racemic 4-aryl-7,7-dimethyl- or 1,77-trimethyl-1,2,3,4,5,6,7,8-octahydroquinazoline-2,5-diones, condensed derivatives of dihydropyrimidines. The enantiomers of the compounds were resolved by normal-phase chromatography on silica-based cellulose tris(3,5-dimethylphenylcarbamate) (Chiralcel OD) and amylose tris(3,5-dimethylphenylcarbamate) (Chiralpak AD) columns with mobile phases consisting of mixtures ofn-hexane and an alcohol (2-propanol, ethanol, or methanol) in different proportions. The mobile phase and the chiral stationary phase were varied to achieve the best resolution. The effect of the concentration of alcohol in the mobile phase was studied. The resolution obtained on the two columns was complementary.     

多糖衍生物手性固定相上采用酸性或碱性添加剂的流动相拆分β受体阻滞剂对映体

考察了多糖类手性固定相在含有酸性或碱性添加剂的流动相下高效液相色谱法拆分β受体阻滞剂对映体的效果。色谱条件: 流动相为10%～30%(体积分数,下同)乙醇-正己烷(含0.1%三氟乙酸)和10%～30%乙醇-正己烷(含0.1%三乙胺),流速1.0 mL/min,紫外检测波长254 nm。结果表明,在直链淀粉-三(3,5-二甲基苯基氨基甲酸酯)衍生物手性固定相(Chiralpak AD和Chiralpak IA)上拆分β受体阻滞剂对映体,酸性添加剂的流动相体系与碱性添加剂的流动相体系相比,碱性添加剂的流动相的拆分效果比酸性添加剂的流动相要好。而在纤维素-三(3,5-二甲基苯基氨基甲酸酯)衍生物的手性固定相(Chiralcel OD和Chiralpak IB)上分离β受体阻滞剂,比较酸性添加剂的流动相与碱性添加剂的流动相的拆分效果,发现酸性添加剂的流动相条件下对映体的保留减弱,但对映体的选择性增大,特别是在Chiralcel OD上,酸性添加剂的流动相体系对对映体的选择性非常理想,而且随着流动相中酸性添加剂含量的增加,β受体阻滞剂对映体的分离效果更佳。     

Application and comparison of derivatized cellulose and amylose chiral stationary phases for the separation of enantiomers of pharmaceutical compounds by high-performance liquid chromatography.

The direct high-performance liquid chromatographic separation of three pairs of structurally related enantiomers on derivatized cellulose and amylose chiral stationary phases (Chiralcel OD, Chiralpak AD and Chiralpak AS) was studied using hexane as the mobile phase with 2-propanol or ethanol as modifiers. The separation, retention and elution order of the enantiomers on the different columns using different alcohol modifiers were compared. The effect of structural variation of the solutes on their k' was noted. A reversal of elution order of one enantiomeric pair upon changing the mobile-phase modifier was observed. Chiralcel OD and Chiralpak AD columns provided different elution orders of the enantiomers, including a fourth pair of enantiomers that were not structurally related to the other three pairs.     

Direct resolution of the enantiomers of new diphosphine and diphosphine oxide ligands by high-performance liquid chromatography

Summary Resolution of the enantiomers of new racemic diphosphines, which are very useful ligands for stereoselective catalysts, and of the corresponding phosphine oxides has been investigated by high-performance liquid chromatography (HPLC) on four different chiral stationary phases (CSP)—Chiralpak AD, Whelk-01, and Supelcosil naphthylurea and phenylurea columns. The mobile phases were optimized to achieve separation of the enantiomers. α andR _S values ranged from 1.05 to 5.17 and from 0.37 to 6.57, respectively, for the Chiralpak AD and (R,R)-Whelk-01 columns. For the Supelcosil LC-(R)-phenylurea and Supelcosil LC-(S)-naphthylurea columns α values ranged from 1.05 to 1.62 andR _S from 0.35 to 3.61.     

Enantioselective HPLC analysis of propafenone and of its main metabolites using polysaccharide and protein-based chiral stationary phases

HPLC on chiral stationary phases has been used for the enantioselective assay of propafenone (PPF), 5-hydroxypropafenone (PPF-50H) and N-despropylpropafenone (PPF-NOR) enantiomers. The results obtained on Chiralpak AD column showed that it is useful for the resolution of PPF and of its main metabolites, although the peaks obtained for PPF-NOR were not symmetrical under the conditions investigated. This column and circular dichroism-based detection system were used to determine the absolute configuration of the eluates. Furthermore, the influence of the mobile phase composition on the resolution of PPF and of its main metabolites was investigated on cellulose derivatives (Chiralcel OD-H and Chiralcel OD-R) and protein (Chiral AGP and Ultron ES-OVM)-based chiral stationary phases. The enantiomers of PPF were resolved on all the columns, except for the Ultron ES-OVM. This column, the Chiralpak AD and the Chiralcel OD-H columns were suitable for the resolution of the PPF-50H enantiomers. The PPF-NOR enantiomers were resolved on the Chiralpak AD, Chiral AGP and Chiralcel OD-R columns.     

Direct separation of the enantiomers of reboxetine by liquid chromatography on different cellulose- and amylose-based chiral stationary phases

Summary Racemic reboxetine, (R,S)-2[(R,S)-α-(2-ethoxyphenoxybenzyl] morpholine methane sulfonate, is a mixture of the (R,R) and (S,S) enantiomers. Separation of the enantiomers of reboxetine by liquid chromatography has been investigated on three chiral stationary phases—cellulose tris-(3,5-dimethylphenylcarbamate) (Chiralcel OD), cellulose tris-(phenylcarbamate) (Chiralcel OC), and amylose tris-(3,5-dimethylphenylcarbamate) (Chiralpak AD). On these stationary phases the resolution of the (R,R) and (S,S) enantiomers was highly dependent on mobile-phase composition. When Chiralcel OD and OC were used, addition of diethylamine to the mobile phase greatly improved the separation of the enantiomers. On Chiralpak AD enantio-separation was achieved without the use of additives. Solute-mobile phase-stationary phase interactions which might participate in the mechanism of enantiorecognition are discussed.     

环氧酰胺类化合物在OD和AD柱上手性拆分的比较

在ChiralcelOD和ChiralpakAD等二支多糖类手性固定相上,以各种不同配比的正己烷-异丙醇为洗脱剂对十三种带有不同取代基的环氧酰胺类化合物的对映体进行了手性拆分。考察了这些外消旋体在这二支手性柱上的色谱行为。实验表明,环氧酰胺与手性固定相之间的手性作用(例如:偶极-偶极作用、氢键作用、π-π作用)和非手性作用(例如:空间效应)等的综合因素是支配手性拆分过程的主要原因。方法已用于环氧酰胺不对称反应产物的光学纯度鉴定。     

Enantiomeric analysis of simendan on polysaccharide‐based stationary phases by polar organic solvent chromatography

Herein, the enantiomeric separation of simendan by high‐performance liquid chromatography with ultraviolet detection using polysaccharide‐based chiral stationary phases in polar organic mode is described. Three chiral columns (Chiralpak AD‐H, Chiralcel OD‐H, and Chiralpak AS) were screened using pure methanol and acetonitrile without additives under isocratic conditions. A reversed elution order was observed on the Chiralpak AD‐H column when the methanol content in the mobile phase (methanol–acetonitrile mixtures) was above 10%, whereby levosimendan eluted prior to dextrosimendan. Further, it was found that increasing temperature effectively improved the enantioresolution on the Chiralpak AD‐H column. Van't Hoff analysis was performed to evaluate the contribution of enthalpy and entropy to the chiral discrimination process. The best enantioseparation (α = 3.00, Rs = 12.85) was obtained on the Chiralpak AD‐H column with methanol as the mobile phase at 40°C. Thus, a quantitative method for the resolution of dextrosimendan was established and validated, which could be used as a reference for the determination of dextrosimendan in levosimendan products.     

Enantiomeric separations of chiral polychlorinated biphenyls on three polysaccharide-type chiral stationary phases by supercritical fluid chromatography

Enantiomeric separations of 18 chiral polychlorinated biphenyls (PCBs) were investigated on three polysaccharide-type chiral stationary phases (CSPs; Sino-Chiral OJ, Chiralpak IB, and Chiralcel OD) by supercritical fluid chromatography (SFC). With these commonly used polysaccharide CSPs, 17 PCBs except PCB 135 (R(S) = 0.81) were well resolved (R(S) > 1.5) under appropriate mobile phases and temperatures. Using Sino-Chiral OJ, 14 PCBs could be baseline-separated, while only one and nine PCBs could be completely separated using Chiralpak IB and Chiralcel OD, respectively. The influence of column temperature was studied for the optimization of resolution, as well as for the type and percentage of organic modifier in the mobile phase. The resolution decreased as the temperature increased in the range of 26-40 °C in which the enantiomeric separations were an enthalpy-driven process. The addition of modifiers in the mobile phase decreased the resolution of the PCB enantiomers, but it clearly shortened their retention time. These separation results indicate that SFC is a promising chromatographic technique for chiral separation and enantiopure standard preparation.     

Exploring solvent versatility in immobilized cellulose-based chiral stationary phase for the enantioselective liquid chromatographic resolution of racemates

Chiralpak IB, a new chiral stationary phase (CSP) containing cellulose tris(3,5-dimethylphenylcarabamate) immobilized onto silica gel, is investigated for the direct enantioselective separation of a set of racemic N-alkylated barbiturates and analogs of thalidomide alkylated in position 3 of the piperidin-2,6-dione ring using different nonstandard solvents such as dichloromethane (DCM), ethyl acetate, THF, methyl tert-butyl ether as an eluent and diluent, respectively, in HPLC. The separation, resolution, and elution order of the investigated compounds were compared on both immobilized and coated cellulose tris(3,5-dimethylphenylcarbamate) CSPs (Chiralpak IB and Chiralcel OD, respectively) using a mixture of n-hexane/2-propanol (90:10 v/v) as mobile phase with different flow-rates and fixed UV detection at 254 nm. The effect of the immobilization of the cellulose tris-(3,5-dimethylphenylcarbamate) CSP on silica (Chiralpak IB) on the chiral recognition ability was noted as the coated phase (Chiralcel OD) possesses a higher resolving power in some cases than the immobilized one (Chiralpak IB). However, a few racemates, which were not or poorly resolved on the immobilized Chiralpak IB or the coated Chiralcel OD when using standard solvents were most efficiently resolved on the immobilized Chiralpak IB upon using nonstandard solvents. Furthermore, the immobilized phase withstands the nonstandard (prohibited) HPLC solvents mentioned previously when used as eluents or as a dissolving agent for the analyte itself. An example of inversion or apparent inversion of elution order on Chiralpak IB is reported. The direct analysis of a spiked plasma sample extracted using DCM on Chiralpak IB is also shown.     

Comparative LC Enantioseparation of Novel PPAR Agonists on Cellulose- and Amylose-Based Chiral Stationary Phases

The LC enantiomeric separation of several dual PPARα/γ agonists on the commercially available Chiralcel OD and Chiralpak AD columns has been evaluated in normal phase mode using a mobile phase consisting in a mixture of n-hexane, 2-propanol and trifluoroacetic acid at constant volume ratio. Most compounds were separated as underivatized acids without requiring time consuming analysis. Some complementary selectivity was evidenced on the two investigated chiral stationary phases related to the different accessibility of the active sites of the helical cavities. Additional information on the chiral recognition mechanism were deduced from the chromatographic behaviour of some selected methyl esters.     

Applications of the Chiralpak AD and Chiralcel OD chiral columns in the enantiomeric separation of several dioxolane compounds by supercritical fluid chromatography

Two chiral columns based on polysaccharide derivatives (Chiralpak AD and Chiralcel OD) have been tested for the chiral separation of several dioxolane compounds, using supercritical fluid chromatography. The compounds studied included ketoconazole and some of its precursors. The effect of the different modifiers and the pressure, on the chromatographic parameters was also evaluated. In general, the alcohol modifiers provided better results than acetonitrile, and all the compounds could be separated with these two columns, but the selection of the column depends on the kind of compound.     

Enantioseparations in non-aqueous capillary electrochromatography using polysaccharide type chiral stationary phases

Enantioseparations of chiral compounds with different structures were studied in non-aqueous capillary electrochromatography (NAQ CEC). Three different polysaccharide derivatives, cellulose tris(3,5-dimethylphenylcarbamate) (Chiralcel OD), amylose tris(3,5-dimethylphenylcarbamate) (Chiralpak AD) and cellulose tris(4-methylbenzoate) (Chiralcel OJ) were used as chiral stationary phases (CSPs). Methanolic or ethanolic ammonium acetate solutions served as a mobile phase. The effect of the type of the CSP, the loading of the chiral selector on wide-pore aminopropyl derivatized silica gel and operational parameters such as apparent pH, applied voltage, etc. on the EOF and chromatographic characteristics (alpha, N, Rs) were studied. NAQ CEC represents a valuable alternative and an extension to chiral separations by HPLC with common-size columns as well as to capillary LC and CEC in aqueous buffers.