萘普生及其衍生物的手性固定相法直接拆分机理

用不同的酰氯化合物与萘普生反应,制备了一系列萘普生衍生物。在正相色谱条件下,对萘普生及其衍生物系列在(R,R)-Whelk-O 1手性固定相(chiral stationary phase,CSP)上进行了对映体拆分研究。实验考察了流动相组成、分离温度等因素对手性分离的影响,并根据相应热力学参数对萘普生及其衍生物在该手性固定相上的手性识别机理进行了初步探讨。研究结果表明:萘普生及其衍生物在Whelk-O 1 CSP上的对映体分离有着与一般正相色谱明显不同的特征,其分离因子α值与流动相组成关系曲线出现了峰值,且分离因子极大值所对应的流动相组成分别为极性较大的20%(V/V,下同)异丙醇/正己烷混合溶剂体系和40%异丙醇/正己烷混合溶剂体系。     

手性固定相HPLC法直接拆分奈他地尔对映体EI北大核心CSCD

以纤维素衍生物为手性固定相,建立药物奈他地尔的HPLC手性分析方法。以正己烷与乙醇或异丙醇为流动相,在Chiralpak AD-H手性固定相上对奈他地尔对映体进行了拆分,并考察了流动相组成、柱温和流速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1.7。结果表明,奈他地尔对映体在正己烷-异丙醇-二乙胺(80:20:0.1,V:V:V)为流动相、流速为1.0 m L/min、柱温为30℃时,分离效果最佳。本方法操作简单、重现性好,可用于奈他地尔对映体的质量控制。     

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。     

3种碱性药物在手性柱上的对映体分离

在(S,S)-Whelk-O 1手性柱上对去甲羟基安定、扁桃酰胺和氯噻酮3种碱性药物进行了对映体分离研究。考察了流动相正己烷体系中不同种类和浓度的醇类添加剂、不同浓度乙酸对3种碱性药物对映体分离的影响,并初步探讨了其手性分离机理。结果表明,去甲羟基安定和扁桃酰胺在正己烷异丙曩蔓／乙酸为80：20：0．1(V/V)条件下都获得了很好的分离,其最佳分离度分别为2．59和3．63,氯噻酮则未获得分离。     

非甾体抗炎药对映体在多糖衍生物手性固定相上的拆分

在共价键合多糖类衍生物的手性固定相(Chiralpak IA,Chiralpak IB,Chiralpak IC)和涂敷型多糖衍生物的手性固定相(Chiralpak AD,Chiralcel OD)上,对非甾体抗炎药物(non-steroidal anti-inflammatory drugs,NSAIDs)进行了对映体拆分.色谱条件:流动相为10%异丙醇/正己烷(V/V)含0.1%三氟乙酸(Chiralpak AD,2%异丙醇/正己烷(V/V)含0.1%三氟乙酸(Chiralpak OD),异丙醇(四氢呋喃、乙酸乙酯、二氯甲烷)/正己烷/0.1%三氟乙酸(Chiralpak IA,Chiralpak IB,Chiralpak IC);流速为1.0 mL/min;紫外检测波长为254 nm.比较了非甾体抗炎药在直链淀粉-三(3,5-二甲基苯基氨基甲酸酯)衍生的手性固定相Chiralpak IA和 Chiralcel AD,纤维素-三(3,5-二甲基苯基氨基甲酸酯)衍生的手性固定相Chiralpak IB和Chiralcel OD上的对映体拆分.结果表明,非甾体抗炎药在Chiralpak IA和Chiralpak IB上的分离效果普遍低于Chiralpak AD和Chiralcel OD.     

酸糖蛋白手性柱分离6种手性化合物

通过考察缓冲液种类、浓度及其pH值对对映体在手性柱上的保留和分离行为的影响,以及流动相中加入不同种类、不同浓度的不带电荷的有机溶剂乙腈、甲醇、正丙醇、异丙醇、流动相流速和柱温对对映体分离能力的影响,优化了含碳手性中心的碱性药物苯丙哌林、酸性化合物MT-A5及MT-酸和含硫手性中心的质子泵抑制剂奥美拉唑、泮托拉唑、雷贝拉唑对映体分离条件,最佳手性分离条件为:苯丙哌林,0.05 mol/L磷酸二氢铵缓冲液(pH 3.0)-乙腈(95∶5,V/V)为流动相,流速为0.7 mL/m in,柱温为20℃;MT-A5及MT-酸,流动相为0.01 mol/L醋酸铵缓冲液(pH 5.0)-乙腈(74∶26,V/V),流速为0.9 mL/m in,柱温为20℃;泮托拉唑,流动相为10 mmol/L醋酸铵缓冲液(pH 5.5)-乙腈(93∶7,V/V),流速为0.9 mL/m in;柱温为20℃;奥美拉唑和雷贝拉唑,流动相为0.01 mol/L醋酸铵缓冲液(pH 3.0)-乙腈(95∶5,V/V),流速为0.7 mL/m in,柱温为20℃。实现了应用高效液相色谱法在α1-酸糖蛋白手性柱上对上述化合物的对映体分离,并成功用于手性药物合成中的对映体过量百分率的测定。     

高效液相色谱法拆分α-氨基酸的邻苯二甲酰衍生物对映体

建立用高效液相色谱拆分α-氨基酸的邻苯二甲酰衍生物对映体的方法。用多糖类手性固定相ChiralcelOD,ChiralpakAD,ChiralpakAS柱;5%异丙醇/正己烷(V/V)含0.1%三氟醋酸溶液为流动相;流速为1mL/min;检测波长:UV=254nm。考察了α-氨基酸的邻苯二甲酰衍生物在不同手性固定相(ChiralcelOD,ChiralpakAD,ChiralpakAS柱)上的对映体的手性分离。结果表明,α-氨基酸的邻苯二甲酰衍生物对映体在ChiralcelOD柱上的分离效果最佳(α=1.34~2.11),并且全部得到了基线分离。     

高效液相色谱手性固定相法拆分尼拉帕尼对映体

建立了测定药物尼拉帕尼对映体纯度的HPLC分析方法。以正己烷与乙醇或异丙醇为流动相,在Chiralpak AD-H手性固定相上对尼拉帕尼对映体进行了拆分,并考察了流动相组成、柱温和流速对该对映体分离的影响。尼拉帕尼对映体在正己烷-异丙醇-二乙胺(85:15:0.1,V/V/V)为流动相、流速为1.0 m L/min、检测波长260 nm、柱温为30℃时,分析时间在15 min内,分离度大于2。本方法操作简单、重现性好,可用于尼拉帕尼对映体的质量控制。     

纤维素键合手性固定相拆分6种萘满酮衍生物对映体

使用Chiralpak IC（纤维素-三（3,5-二氯苯基氨基甲酸酯）共价键合硅胶）手性柱,建立了采用手性固定相高效液相色谱拆分6种 α -芳基萘满酮类衍生物对映体的方法。考察了流动相中有机改性剂的种类和比例、柱温和流速对对映体分离的影响。结果显示6种化合物在异丙醇为改性剂的条件下均可获得较高的对映体分离度。热力学研究表明6种化合物对映体的手性拆分过程均受焓驱动影响,且低温有利于对映体分离。最终推荐分离化合物Ⅰ对映体的流动相是正己烷-异丙醇（90：10,v/v）;分离化合物Ⅱ、Ⅲ、Ⅳ对映体的流动相是正己烷-异丙醇（99：1,v/v）;分离化合物Ⅴ对映体的流动相是正己烷-异丙醇（85：15,v/v）;分离化合物Ⅵ对映体的流动相是正己烷-异丙醇（80：20,v/v）。柱温为25℃,流速为1.0 mL/min。6种化合物对映体均可在Chiralpak IC手性固定相上得到完全分离,证明该色谱柱对6种化合物具有较高的对映体选择性。     

以β-环糊精及其衍生物为手性选择剂毛细管电泳拆分几种药物的旋光对映体

在毛细管电泳中，采用β－环糊精（β－ＣＤ）及其衍生物为手性选择剂对扑尔敏、异丙嗪、二氧异丙嗪和氧氟沙星对映体进行了分离。优化了分离条件；讨论了环糊精空腔边缘与溶．质分子作用的基团的种类和分离效果的联系，通过计算手性分离的热力学常数比较了不同手性选择剂对扑尔敏对映体的分离能力。最后，讨论了乙腈在手性分离中的作用。     

纤维素-三(3,5-二甲基苯基氨基甲酸酯)涂敷手性固定相的制备、表征及评价

 以纤维素和 3,5 二甲基苯基异氰酸酯为原料合成了纤维素 三 (3,5 二甲基苯基氨基甲酸酯 ) ,并采用两种不同的方法将其涂敷于小粒径 (平均粒径 5 μm ,平均孔径 13nm ,比表面积 110m2 / g)的氨基丙烷化硅胶 (APS)上 ,制得了在纤维素 三 (苯基氨基甲酸酯 )类衍生物涂敷的硅基手性固定相中具有较佳手性识别能力的固定相。通过元素分析、扫描电子显微镜对两种手性固定相进行了表征 ,用高效液相色谱法对两种固定相的手性拆分能力进行了评价和比较。     

手性固定相Chirex 3001对安息香和联萘酚及其类似物的分子识别

利用分子力学方法, 建立了苯基甘氨酸型手性固定相Chirex 3001的简化模型, 并探讨了手性固定相Chirex 3001与安息香和联萘酚及其类似物的识别机制. 模拟结果表明, 固定相主体与手性客体分子识别作用的推动力主要来自于它们之间的π-π堆积、氢键和范德华等作用. 主体与(S)-构型的客体1～3结合能力强于(R)-构型的客体, 而对于客体4～6, 则是与(R)-构型的结合强于(S)-构型, 这与高效液相色谱拆分实验结果相符. 客体1～3对映体在Chirex 3001柱上的分离因子分别为1.02, 1.04和1.11, (R)-构型先被洗脱; 客体4～6对映体的分离因子分别为1.23, 1.26和1.09, (S)-构型先被洗脱.     

Analytical and semi-preparative HPLC enantioseparation of novel pyridazin-3(2H)-one derivatives with α-aminophosphonate moiety using immobilized polysaccharide chiral stationary phases

The direct HPLC enantioseparation of a novel series of chiral pyridazin-3(2H)-one derivatives with α-aminophosphonate moiety was performed on two immobilized polysaccharide chiral stationary phases (Chiralpak IA, Chiralpak IC) using n-hexane (n-Hex)/dichloromethane (DCM) mobile phase with 5% alcohol additive. Good baseline separation of the enantiomers was achieved using amylose tris-(3,5-dimethylphenylcarbamate) chiral stationary phases (Chiralpak IA) on analytical scale. The analytical method was further scaled up to semi-preparative loading to obtain small amounts of both the enantiomers of pyridazin-3(2H)-one derivative. The semi-preparative resolution of all compounds was successfully achieved with n-hexane/dichloromethane/ethanol (EtOH) as mobile phase using a semi-preparative Chiralpak IA column. The first fractions were isolated with purities of >99.9% (enantiomeric excess (e.e.), and the second fractions were obtained with purities of >98.2% (enantiomeric excess). The assignment of the absolute configuration was established for the F1 fraction of compound a-2 by single-crystal X-ray diffraction method.     

大分子键合型手性固定相的研究进展

高效液相色谱（HPLC）被广泛认为是分离制备光学纯单一对映体最有效的方法。在高效液相色谱手性拆分中,手性固定相的性能直接影响到色谱柱的手性分离能力。在众多手性固定相中,键合型手性固定相具有溶剂耐受性好,分离模式灵活等优点,是很重要的一大类手性固定相。本文主要针对大分子键合型手性固定相,包括多糖衍生物键合型手性固定相、蛋...     

Enantioseparation of Novel Chiral Tetrahedral Clusters on an Amylose Tris-(3,5-dimethylphenylcarbamate) Chiral Stationary Phase by Normal Phase HPLC

Introduction In recent years, chiral transition metal cluster has at-tracted a great deal of interests due to its potential ap-plication in asymmetric catalytic reaction.1-3 Producing catalysis for asymmetric induction using a rigid chiral framework would not only bring a basically conceptual breakthrough in the asymmetric catalysis, but also en-rich the methodology in the design of new chiral cata-lysts.4 So far, a lot of chiral clusters have been re-ported,5-9 but only a few of them have bee…     

Preparation of two new liquid chromatographic chiral stationary phases based on diastereomeric chiral crown ethers incorporating two different chiral units and their applications

Two new liquid chromatographic chiral stationary phases based on diastereomeric chiral crown ethers incorporating two different chiral units such as optically active 3,3'-diphenyl-1,1'-binaphthyl and tartaric acid unit were prepared. Between the two CSPs, one was much superior to the other especially in the resolution of tocainide and its analogues (for example, in the resolution of tocainide the separation factor, alpha, was 4.26 vs. 1.00 on the two CSPs). From these results, the two chiral units composing the two diastereomeric chiral crown ether moieties of the stationary phases were expected to show "matched" or "mismatched" effect on the chiral recognition according to their stereochemistry. The different chiral recognition abilities of the two CSPs were rationalized by the different three-dimensional structures of the two diastereomeric chiral crown ethers.     

合成高分子作为手性固定相在高效液相色谱中的应用

具有旋光活性的合成高分子基于它的手性结构而具有广泛的应用,其中最实际和广泛的应用是在高效液相色谱中作为手性固定相来拆分对映异构体,目前已成为合成化学、分析化学以及制药化学领域必不可少的分离材料.本文简要介绍了高效液相色谱手性固定相拆分法,综述了合成高分子,包括加聚物特别是聚甲基丙烯酸酯类和聚甲基丙烯酰胺类聚合物、聚酰胺...     

Immobilized versus coated amylose tris(3,5-dimethylphenylcarbamate) chiral stationary phases for the enantioselective separation of cyclopropane derivatives by liquid chromatography

The solvent versatility of Chiralpak IA, a new chiral stationary phase (CSP) containing amylose tris(3,5-dimethylphenylcarabamate) immobilized onto silica gel, is investigated for the enantioselective separation of a set of cyclopropane derivatives using ethyl acetate or dichloromethane (DCM) as non-standard mobile phase eluent and diluent, respectively in high-performance liquid chromatography (HPLC). A comparison of the separation of cyclopropanes on both immobilized and coated amylose tris(3,5-dimethylphenylcarbamate) chiral stationary phases (Chiralpak IA and Chiralpak AD, respectively) in HPLC using a mixture of n-hexane/2-propanol (90/10 and 99/1, v/v) as mobile phase with a flow rate of 0.5 ml/min and UV detection at 254 nm, is demonstrated. The optimized method of separation is used for an online HPLC monitoring for the Rh(II)-catalyzed asymmetric intermolecular cyclopropanations in dichloromethane. Direct analysis techniques without further purification, workup or removal of dichloromethane were summarized. The method provides an easy and direct determination of the enantiomeric excess of the cyclopropanes and selectivity of the catalyst used without any further work up.     

Synthesis and application of mono-6-(3-methylimidazolium)-6-deoxyperphenylcarbamoyl-beta-cyclodextrin chloride as chiral stationary phases for high-performance liquid chromatography and supercritical fluid chromatography

The synthesis of mono-6-(3-methylimidazolium)-6-deoxyperphenylcarbamoyl-beta-cyclodextrin chloride (MPCCD) and its application in chiral stationary phases (CSPs) for high-performance liquid chromatography (HPLC) and supercritical fluid chromatography (SFC) are being reported. This chiral selector is coated onto silica gel in different weight percentages (15, 20 and 35%, w/w) to obtain CSPs having different loading content. These new chiral stationary phases are tested using normal-phase HPLC for enantioseparation of racemic aromatic alcohols. Indeed, the enantiodiscrimination abilities of these CSPs are found to be influenced by the loading content of the chiral selector. Among the three columns (MPCCD-C15, MPCCD-C20 and MPCCD-C35), the best enantioseparation results are obtained using a column containing 20% (w/w) of MPCCD (MPCCD-C20). The resolution (R(s)) obtained for p-fluorophenylethanol, p-chlorophenylethanol, p-bromophenylethanol, p-iodophenylethanol and p-fluorophenyl-3-buten-1-ol using MPCCD-C20 ranges from 3.83 to 5.65. Good enantioseparation results are obtained for these analytes under SFC separation conditions using the MPCCD-C20 column.     

A novel stability-indicating HPLC method for the determination of enantiomeric purity of eluxadoline drug: Amylose tris(3,5-dichlorophenyl carbamate) stationary phase

A simple and sensitive stability-indicating chiral HPLC method has been developed and validated per International Conference on Harmonization guidelines for the determination of enantiomeric purity of eluxadoline (Exdl). The impact of different mobile phase compositions and chiral stationary phases on the separation of Exdl enantiomer along with process- and degradation-related impurities has been studied. Homogeneity of Exdl and stable results of Exdl enantiomer in all degraded samples reveal the fact that the proposed method was specific (stability indicating). Amylose tris(3,5-dichlorophenyl carbamate) stationary phase column Chiralpak IE-3 (150 × 4.6 mm, 3 μm) provided better resolution with polar organic solvents than cellulose derivative, crown ether, and zwitterion stationary phases and nonpolar solvents. The mobile phase consisted of acetonitrile, tetrahydrofuran, methanol, butylamine, and acetic acid in the ratio of 500:500:20:2:1.5 (v/v/v/v/v). Isocratic elution was performed at a flow rate of 1.0 mL/min, column temperature of 35°C, injection volume of 10 μL, and UV detection of 240 nm. The United States Pharmacopeia (USP) resolution of the Exdl enantiomer was found to be more than 4.0 within a 65-min run time. Exdl enantiomer detector response linearity over the concentration range of 0.859–4.524 μg/mL was found to be R² = 0.9985. The limit of detection, limit of quantification, and average percentage recovery values were established as 0.283 μg/mL, 0.859 μg/mL, and 96.0, respectively.