柱前衍生高效液相色谱法测定四氢噻唑-2-硫酮-4-羧酸的光学纯度

用苯胺对四氢噻唑-2-硫酮-4-羧酸(TTCA)进行柱前衍生,将其衍生物在手性固定相上拆分,通过二极管阵列紫外检测器和在线旋光检测仪对其衍生物进行检测,建立了一种拆分TTCA消旋体、测定TTCA光学纯度的新方法。以正己烷和乙醇或异丙醇为流动相,在DNB-Leucine手性固定相上对TTCA衍生物进行了拆分,并考察了流动相组成和柱温对其衍生物分离的影响,获得较优分析条件,分离因子大于1.2。非手性试剂苯胺柱前衍生化法测定(R)-TTCA的光学纯度与旋光度方法比较,结果一致,相对偏差小于1.34%。     

手性固定相HPLC法拆分3-叔丁基己二酸对映体

用苯胺对3-叔丁基己二酸对映体进行柱前衍生后,在CHIRALCEL OD-H手性固定相上拆分,并通过二极管阵列紫外检测器和在线旋光检测器对其衍生物进行检测,首次建立了一种拆分3-叔丁基己二酸消旋体和测定3-叔丁基己二酸光学纯度的新方法。考察了流动相组成、柱温和流速对该对映体衍生物分离的影响。结果表明,3-叔丁基己二酸衍生物对映体在正己烷-异丙醇(体积比90∶10)为流动相,流速为1.0 mL.min-1,柱温为30℃时,分离效果最佳。在优化的实验条件下,分析在10 min内完成,分离因子和分离度均大于1.5。在质量浓度为2~160 mg/L范围内,(+)-3-叔丁基己二酸衍生物和(-)-3-叔丁基己二酸衍生物的回归方程分别为y1=2 116.4x1-3 541.3(r12=0.999 4)和y2=2 097.6x2-4 774.1(r22=0.999 1)。该方法操作简单、重复性好,可用于3-叔丁基己二酸对映体的质量控制。     

9-蒽醛衍生化-高效液相色谱法拆分α-氨基酸甲酯和几种脂肪胺对映体

采用高效液相色谱法,以9-蒽醛为衍生试剂,在5种多糖衍生物的手性固定相(CSPs)上对几种α-氨基酸甲酯对映体进行了手性分离。色谱条件如下: 流动相为含3%～10%(v/v)异丙醇的正己烷溶液,流速为1.0 mL/min,检测波长为254 nm。结果表明,α-氨基酸甲酯-9-蒽醛亚胺衍生物在Chiralcel OD柱或Chiralcel OD-H柱上的手性分离结果优于其他CSPs,而且在Chiralcel OD柱或Chiralcel OD-H柱上全部得到了基线拆分(α=1.24～5.47, Rs=2.56～13.90), L-对映体在这两种色谱柱上的保留强于D-对映体。同时还考察了几种脂肪胺在5种多糖衍生物手性固定相上的对映体拆分效果,结果表明脂肪胺的9-蒽醛亚胺衍生物在Chiralcel OD柱或Chiralcel OD-H柱上的分离效果良好。该法可用于其他α-氨基酸酯和胺类化合物对映体的分析。     

柱前衍生化高效液相色谱手性固定相法拆分手性氰醇

利用正相高效液相色谱法在多糖衍生物手性固定相(OJ-H、OD-H、AD-H或AS-H)上成功地分离了一系列(31个)氰醇对映体的乙酰化或丙酰化衍生物,并拆分了3个脂肪族氰醇对映体的乙酰化衍生物。探讨了这些外消旋体在这四支手性柱上的色谱行为,通过考察流动相组成、流速、进样浓度和温度等因素对对映体拆分效果的影响,优化了色谱分离条件。方法已应用于脂肪酶催化转酯化拆分反应中手性氰醇衍生物的光学纯度的鉴定。     

衍生化HPLC法测定α-苯乙胺的光学纯度

用4-甲氧基苯甲酸将手性对映体α-苯乙胺衍生化,产生相应的非对映体衍生物.以正己烷、异丙醇或乙醇为流动相,在DNB-pg手性固定相上对α-苯乙胺的对映体衍生物进行了拆分,考察了流动相组成和柱温对该对映体衍生物分离的影响,获得较好的分析条件,分离因子可达1.3以上.该结果进一步与旋光仪方法的测定比较,结果相当一致,相对偏差不超过1.2%.     

柱前衍生化高效液相色谱法测定乳酸的光学纯度

用苯胺将乳酸衍生化,得到的对映体衍生物在DNB-Leucine柱上进行了拆分,建立了一种用柱前手性衍生化结合手性固定相正相高效液相色谱法检测乳酸光学纯度的方法,并考察了流动相组成和柱温对其分离的影响。分离结果经二极管阵列紫外检测器检测,以及与对照品比较得到确认。当流动相为V(正己烷)∶V(乙醇)=90∶10,温度为25℃,流速为1.5 mL/min时,乳酸达到基线分离,分离因子达1.30以上。将此法测定乳酸光学纯度的结果与旋光仪方法测定的结果进行比较,相对偏差不超过2%。本方法可用于乳酸对映体的光学纯度准确检测。     

高效液相手性固定相法拆分1-苯乙烯基-3-己基丙炔醇

以纤维素衍生物为手性固定相,建立药物中间体1-苯乙烯基-3-己基丙炔醇对映体的HPLC手性分析方法。以正己烷与乙醇或异丙醇为流动相,在Chiralcel OD-H手性固定相上对1-苯乙烯基-3-己基丙炔醇进行了拆分,并考察了流动相组成、流速和柱温对该对映体分离的影响,获得较优分析条件,分析时间在15 min内,分离度大于1.5。结果表明,1-苯乙烯基-3-己基丙炔醇对映体在正己烷-异丙醇(体积比90:10)为流动相、流速为1.0 m L/min、柱温为25℃时,分离效果最佳。本方法可用于1-苯乙烯基-3-己基丙炔醇对映体的质量控制。     

Chiralpak AD和Chiralcel OD-H手性固定相拆分3α-酰氧基-6β-乙酰氧基莨菪烷类化合物

采用高效液相色谱法,以不同配比的正己烷-异丙醇为流动相,在正相色谱条件下,考察了6个3α-酰氧基-6β-乙酰氧基莨菪烷对映体在淀粉型手性固定相Chiralpak AD、纤维素型手性固定相Chiralcel OD-H上的分离情况,以建立该类化合物的手性拆分方法。结果表明,在Chiralpak AD手性柱上,对映体6实现完全分离,而对映体1完全不能分离;在Chiralcel OD-H柱上,对映体1、4、3分别实现完全分离、基线分离和基本分离,对映体6只能实现部分分离;对映体5在两种手性柱上都完全不能被分离。说明固定相手性空腔的结构对化合物的拆分结果影响很大。研究发现,C-3α位取代基团的空间位阻效应主导手性固定相对对映体的选择性识别作用,而化合物与固定相之间的分子间作用力对手性拆分也产生重要影响。研究结果为其他莨菪烷类化合物的手性拆分提供了参考。     

柱前衍生高效液相色谱法测定NTCA的光学纯度

用1-萘胺对乙酰四氢噻唑-2-硫酮-4-羧酸进行柱前衍生,产生非对映体衍生物.以正己烷和乙醇或异丙醇为流动相,选择Chiralcel OD-H色谱柱上对NTCA衍生物进行了拆分,考察了流动相组成和柱温对其衍生物分离的影响,获得较好的分析条件,分离因子达到1.3.该结果进一步与旋光仪法相比较,相对偏差不超过1.9%.     

大环抗生素手性固定相拆分盐酸马布特罗对映体

基于三种大环抗生素类手性固定相Chirobiotic V,T和R,利用高效液相色谱法对盐酸马布特罗对映体进行了拆分;考察了洗脱模式、流动相组成、柱温等因素对分离的影响,对分离结果进行了比较,对分离机制进行了探讨.结果表明,盐酸马布特罗对映体在Chirobiotic R手性固定相上不能实现分离,在Chirobiotic V和T手性固定相上均可实现较好的基线分离.最佳色谱条件为:新极性有机相模式,流动相甲醇-冰醋酸-三乙胺(100∶0.01∶0.01,V/V/V),流速1.0mL/min,柱温20℃;相应的分离度分别可达3.08和3.73.与此同时,盐酸马布特罗对映体与大环抗生素类固定相之间的离子相互作用是实现对映体分离的最主要分离机制.     

Separation of enantiomers of deprenyl with various CDs in CE and the effect of enantiomer migration order on enantiomeric impurity determination of selegiline in active ingredients and tablets

Opposite affinity pattern of enantiomers of the antiparkinsonian chiral drug deprenyl (DEP) was observed towards various neutral and charged derivatives of -CD. The effect of the enantiomer migration order on the LOD of enantiomeric impurity of R-DEP (selegiline) was studied for the standard substances and in the tablets from three different suppliers. The influence of injection mode on the LOD of a minor enantiomeric impurity was also studied and the CE method was compared with the pharmacopoeial HPLC method using a commercially available chiral column Chiralcel OD-H. The optimized CE method was more suitable for low-level enantiomeric impurity determination in selegiline compared to the pharmacopoeial HPLC method.     

Optical resolution of asymmetric triacylglycerols by chiral-phase high-performance liquid chromatography

A simple method for direct optical resolution of some asymmetric triacylglycerols (TGs) has been established. The method employs chiral-phase high-performance liquid chromatography (HPLC). An enantiomeric pair of TGs comprising 1-eicosapentaenoyl-2,3-dicapryroyl-sn-glycerol (ECC) and 1,2-dicapryroyl-3-eicosapentaenoyl-sn-glycerol (CCE) was resolved on a CHIRALCEL OF or on a CHIRALCEL OD column. The separation of another pair of asymmetric TGs, 1-docosahexaenoyl-2,3-dicapryroyl-sn-glycerol (DCC) and 1,2-dicapryroyl-3-docosahexaenoyl-sn-glycerol (CCD), was achieved with the CHIRALCEL OD column. The chiral-phase HPLC method in combination with silver-ion HPLC and high-temperature gas chromatography was used for monitoring two interesterification reactions, whose products were chiral TGs. Interesterification of tricapryloylglycerol with ethyleicosapentaenoate or with ethyldocosahexaenoate was performed using Rhizomucor miehei lipase as the catalyst. The products targeted were the asymmetric pair of TGs, ECC and CCE or DCC and CCD. The amounts of sn-1-substituted products (ECC or DCC) were greater than their sn-3-substituted counterparts (CCE or CCD) throughout the reaction period, suggesting that R. miehei lipase had a stereopreference towards the sn-1 position over the sn-3 position.     

Study of the enantiomeric separation of an acetamide intermediate by using supercritical fluid chromatography and several polysaccharide based chiral stationary phases

Four chiral stationary phases, based on the phenylcarbamate derivatives of amylose or cellulose: Chiralcel OD-H, Chiralpak AD, Lux Cellulose-2 and Lux Amylose-2, were evaluated for the enantiomeric separation of an acetamide chiral intermediate, the (4S-trans)-4-(ethylamino)-4-(N-acetamide)-5,6-dihydro-(6S)-methyl-4H-thieno-[2,3-b]thiopyran-7,7-dioxide, using SFC. The effect of the different modifiers and temperatures, on the separation, was also studied. The chiral separation could not be achieved using the Chiralpak AD column, nevertheless the other columns provided excellent results with analysis times close to 6 min and resolutions higher than 2. The highest enantioresolutions and retentions were obtained with the Lux Cellulose-2 column and 2-propanol as organic modifier. The isoelution temperatures were estimated from the van't Hoff plots, and in all the cases they were above the temperature range studied which means that the enantiomeric separation was enthalpy driven.     

Determination of enantiomeric purity of 1-substituted 3-amino-1,2-dicarba-<Emphasis Type="Italic">closo</Emphasis>-dodecaboranes by HPLC on chiral stationary phases

A determination of enantiomeric purity of 1-substituted (Me, Ph, and Prⁱ) 3-amino-1,2dicarba-closo-dodecaboranes by HPLC on chiral Chiralcel OD-H and Chiralpac AD stationary phases involving preliminary phthaloylation of 3-aminocarboranes has been suggested as a general method.     

Determination of the enantiomeric purity of nucleoside analogs related to d4T and acyclovir,new potential antiviral agents,using liquid chromatography on cellulose chiral stationary phases

We reported a method of determination of enantiomeric purity of the new potential antiviral agents by direct analytical HPLC. Those agents are nucleoside analogs, having one chiral center. They are synthesized as a single enantiomer (R or S) by an asymmetric pathway. The chiral stationary phases chosen are silica-based cellulose tris-3,5-dimethylphenylcarbamate (Chiralcel OD-H), or tris-methylbenzoate (Chiralcel OJ). Resolution was achieved using normal-phase chromatography with a mobile phase consisting of n-hexane-alcohol (ethanol or 2-propanol) in various percentages. Furthermore the effects of structural features on retention, selectivity and resolution, as well as on the elution order were thoroughly studied. Differences in the lipophilicity of the compounds were also examined.     

Chiral Separation of 4-Iminoflavan Derivatives on Several Polysaccharide-Based Chiral Stationary Phases by HPLC

The HPLC enantiomeric separation of seven 4-iminoflavans was successfully accomplished in the normal phase mode using six polysaccharide-based chiral stationary phases namely, Chiralcel^®OD-H, Chiralcel^®OD, Chiralcel^®OJ, Chiralpak^®AD, Chiralpak^®IA and Chiralpak^®IB under normal and polar organic phase modes. The resolution depended on nature and concentration of alcoholic modifier. The results demonstrate clearly that the chromatographic system based on the coated and immobilized type Chiralpak^®IB and Chiralcel^®OD-H CSPs provide a powerful analytical tool for enantiomeric separation of all the 4-iminoflavans used in this study.

     

Comparison of Separation Performances of Cellulose-Based Chiral Stationary Phases in LC Enantioseparation of Aminonaphthol Analogues

The enantiomers of 1-(α-aminoarylmethyl)-2-naphthol, 1-(α-aminoalkyl)-2-naphthol and 2-(α-aminoarylmethyl)-1-naphthol analogues were separated on tris(3,5-dimethylphenyl)carbamoyl cellulose-based CelluCoat and Chiralcel OD-H chiral stationary phases, with n-heptane/alcohol or n-hexane/alcohol as mobile phase. The experimental data are utilised to discuss the effects of the mobile phase composition, the nature of the alcoholic modifier and the specific structural features of the analytes (1- or 2-naphthol analogues with aryl or alkyl substituents) on the retention and separation. The separation performances of CelluCoat and Chiralcel OD-H columns were compared. Due to its high resolution ability and its effectivity, CelluCoat proved to be a good choice for the enantiomeric separation of aminonaphthol analogues.     

Enantioselective HPLC resolution of synthetic intermediates of armodafinil and related substances

Armodafinil is a unique psychostimulant recently approved by the US Food and Drug Administration for the treatment of narcolepsy. The chromatographic resolution of its chiral intermediates including related substances in the total synthesis of armodafinil was studied on polysaccharide-based stationary phases, viz. cellulose tris-(3,5-dimethylphenylcarbamate) (Chiralcel OD-H) and amylose tris-(3,5-dimethylphenylcarbamate) (Chiralpak AD-H) by HPLC. The effects of 1-propanol, 2-propanol, ethanol, and trifluoroacetic acid added to the mobile phase and of column temperature on resolution were studied. A good separation was achieved on cellulose-based Chiralcel OD-H column compared to amylose-based Chiralpak AD-H. The effects of structural features of the solutes and solvents on discrimination between the enantiomers were examined. Baseline separation with R(s) >1.38 was obtained using a mobile phase containing n-hexane-ethanol-TFA (75:25:0.15 v/v/v). Detection was carried out at 225 nm with photodiode array detector while identification of enantiomers was accomplished by a polarimetric detector connected in series. The method was found to be suitable not only for process development of armodafinil but also for determination of the enantiomeric purity of bulk drugs and pharmaceuticals.     

Chiral Separation of 4-Iminoflavan Derivatives on Several Polysaccharide-Based Chiral Stationary Phases by HPLC

The HPLC enantiomeric separation of seven 4-iminoflavans was successfully accomplished in the normal phase mode using six polysaccharide-based chiral stationary phases namely, Chiralcel^®OD-H, Chiralcel^®OD, Chiralcel^®OJ, Chiralpak^®AD, Chiralpak^®IA and Chiralpak^®IB under normal and polar organic phase modes. The resolution depended on nature and concentration of alcoholic modifier. The results demonstrate clearly that the chromatographic system based on the coated and immobilized type Chiralpak^®IB and Chiralcel^®OD-H CSPs provide a powerful analytical tool for enantiomeric separation of all the 4-iminoflavans used in this study.