色氨酸在自制牛血清白蛋白手性柱上的拆分

利用三氯聚氰活化的氨丙基硅胶与牛血清白蛋白反应,快速而经济地制得牛血清白蛋白手性固定相。在反相模式下,将该手性固定相用于色氨酸的拆分,系统探讨了流动相pH值、柱温、有机修饰剂的种类及含量等对手性拆分的影响。色氨酸在自制牛血清白蛋白手性柱上得到了理想的拆分,分离因子可达4.33。     

刷型手性固定相及其在手性化合物分离中的应用

对映体的分离在有机合成、动力学、药理学、药效学及农业化学等许多学科领域内具有重要的意义,液相色谱手性固定相法拆分对映体的方法被认为最准确、方便的方法之一,刷型手性固定相是液相色谱中非常重要的一类手性固定相。本文介绍了目前常用的几种刷型手性固定相及其在手性化合物分离中的应用情况。     

酰胺类手性固定相的研究进展

近年来手性拆分成为新的研究热点,手性固定相的研究发展异常迅速.立足于国内外手性固定相的研究成果,介绍了手性固定相的分类及其应用,并重点综述了基于酰胺的手性固定相的发展及其制备方法.同时简要介绍了作为手性固定相对不同异构体的识别机理,并对该领域未来的发展方向进行了展望.     

淀粉苯基氨基甲酸酯类手性固定相的制备及用于HPLC手性体分离性能的研究

合成了含有3,5-二甲基和3,5-二氯取代基团的混合型淀粉(苯基氨基甲酸酯)衍生物(CSP-2),并作为手性体分离材料涂敷在氨丙基化多孔硅胶表面,制得新型高效液相色谱(HPLC)用手性固定相;通过1H核磁共振(1H NMR)和红外光谱(IR)表征衍生物结构;以正己烷-异丙醇(9∶1,v/v)为流动相,对多种手性对映体进行了拆分;结果表明,CSP-2综合了单一取代基团淀粉(苯基氨基甲酸酯)衍生物的手性拆分性能,具有优越的手性分离能力,同时固定相的稳定性大大增强。     

无载体手性固定相拆分对映体

本文介绍了无载体纤维素三—(4—甲基苯甲酸酯)手性固定相对外消旋药物酮洛芬的拆分且就不同的柱尺寸及装填方式作了比较。为了反映无载体手性固定相的拆分能力,还将无载体柱与有载体柱、自制柱与日本柱作了比较。结果表明:无载体手性固定相对外消旋药物是有拆分能力的,只是其能力低于有载体的。若无载体手性固定相能与高新分离技术(如模拟移动床)相结合,将有望实现外消旋药物的低成本拆分。     

基于甲壳素的手性分离材料

甲壳素是一种丰富的可再生资源,将甲壳素在碱性条件下脱去乙酰基得到壳聚糖,甲壳素和壳聚糖分子骨架有大量的手性碳原子存在,且含有较多的羟基、乙酰氨基或氨基活性官能团,容易进行化学改性得到有较好手性识别能力的衍生物,且它们能以膜、纤维、凝胶及微球等不同形式出现,可作为各种手性分离介质。概述了近年来甲壳素衍生物作为手性分离介质的重要研究进展,主要包括甲壳素及其衍生物的色谱手性固定相、手性分离膜、分子印迹聚合物。重点介绍了这些手性分离介质的结构、制备及性能,并展望了甲壳素衍生物手性分离介质的研究前景。     

手性最新分离技术研究方法及进展综述

色谱成为对映体拆分的重要工具。近几年各种手性源的积极研发使色谱在对映体分离工作中所起的作用越来越高效。因此,对色谱在对映体拆分的机制,分离模式及近几年新型手性源做一综述。     

手性最新分离技术研究方法及进展综述

色谱成为对映体拆分的重要工具。近几年各种手性源的积极研发使色谱在对映体分离工作中所起的作用越来越高效。因此,对色谱在对映体拆分的机制,分离模式及近几年新型手性源做一综述。     

有机相模式下华法令等在氯代淀粉衍生手性固定相上的拆分

利用涂敷型直链淀粉三-(5-氯-2-甲基苯基氨基甲酸酯)手性固定相Lux Amylose-2,有机相模式下考察了其对黄烷酮、氢化安息香、安息香及华法令等的拆分。乙腈作为流动相的主体,探讨了流动相中甲醇含量、醋酸添加剂、柱温等对手性拆分的影响。黄烷酮、氢化安息香及华法令得到了良好的分离,分离度分别可达11.39、12.15及6.33。在0.005 mg/mL-4.0 mg/mL区间,华法令峰面积与浓度之间呈良好的线性关系,检测限可达0.0001 mg/mL,可用于华法令异构体含量的分析。     

HPLC用苯基氨基甲酸酯类手性固定相的制备及分离性能

合成了同时含有3,5-二甲基和3,5-二氯取代基团的纤维素(苯基氨基甲酸酯)衍生物(CSP-1),作为手性体分离材料涂敷在氨丙基化硅胶表面,制得新型高效液相色谱(HPLC)用手性固定相;利用1H核磁共振(1H-NMR)和红外光谱(IR)表征了衍生物结构;以正己烷-异丙醇(体积比9∶1)为流动相,对多种手性对映体进行了拆分。结果表明,CSP-1具有很好的手性体分离能力,综合了单一取代基团纤维素(苯基氨基甲酸酯)衍生物的手性拆分性能。     

Chiral stationary phase based on a biostable L-RNA aptamer

An immobilized anti-L-arginine d-RNA aptamer, used as a target-specific chiral stationary phase (CSP), was found to be very quickly degraded by RNases under usual chromatographic utilization and storage. To overcome this severe limitation for a practical use, a CSP based on the L-RNA aptamer, that is, the mirror image of the D-RNA aptamer, was created. It was shown that this mirror-image approach was a very simple and powerful strategy to develop a highly stable stationary phase due to the intrinsic insensitivity of l-RNA to the RNase degradation. In addition, such an approach allowed one to reverse the enantiomer elution order relative to that obtained with the corresponding d-RNA CSP.     

R-1-苯基乙基氨基甲酸酯-β-环糊精键合手性固定相的制备与应用研究

利用R-1-苯基乙基异氰酸酯对β-环糊精键合固定相进行衍生,合成了R-1-苯基乙基氨基甲酸酯-β-环糊精手性固定相,填充后在反相条件下考察其对氢化安息香、安息香和α-苯乙醇的手性拆分,探讨了流动相中乙腈含量、缓冲盐类型等对手性拆分的影响。氢化安息香获得了基线分离,分离因子可达1.214,安息香得到了部分分离,α-苯乙醇未能拆开。结合线性溶剂强度(LSS)模型和计量置换理论(SDM-R)对色谱保留机理进行了探讨,认为水分子和乙腈分子一起参与了溶质的置换。     

Adsorption equilibria of benzodiazepines on a hybrid polymeric chiral stationary phase

The chromatographic behavior of a series of racemic benzodiazepines was evaluated under linear and nonlinear conditions on a new hybrid polymeric (DACH-ACR) chiral stationary phase (CSP). Differently substituted benzodiazepines were employed as probes to make hypotheses concerning possible molecular interaction mechanisms originating between target compounds and active sites on the CSP. Hydrogen bonds were found to be pivotal for chromatographic retention and chiral selectivity. The competitive effect from a mobile-phase (MP) modifier able to interact with the CSP through H-bonds was investigated. The performance of the polymeric DACH-ACR CSP for preparative purposes was also evaluated. The competitive adsorption isotherms of two benzodiazepines, lorazepam and temazepam, were measured at different MP compositions through the so-called inverse method. The adsorption data were fitted with a competitive bi-Langmuir adsorption isotherm. Enantiomeric separations under nonlinear conditions were modeled by using the equilibrium dispersive (ED) model of chromatography. Theoretical overloaded band profiles (obtained by solving the system of partial differential equations described by the ED model) matched, in a significantly accurate way, the profiles experimentally measured.     

Combining the enantioselectivities of L-valine diamide and permethylated beta-cyclodextrin in one gas chromatographic chiral stationary phase

An L-valine diamide chiral selector was attached to a polysiloxane through a long hydrocarbon spacer giving rise to a chiral stationary phase (CSP), Chirasil-Val-C11. The enantioselective properties of this readily accessible diamide CSP under gas chromatographic conditions were found to be similar to that of the commercially available Chirasil-Val CSP prepared by a polymer-analogous route. A new binary CSP, Chirasil-DexVal-C11, was synthesized by means of simultaneous attachment of both the L-valine diamide and permethylated beta-cyclodextrin selectors to a polysiloxane using platinum-catalyzed hydrosilylation, thereby overcoming the immiscibility problem known for Chirasil-Val and Chirasil-Dex. This binary CSP retained both the enantioselectivity of Chirasil-Val-C11 toward alpha-amino acid derivatives and the unsurpassed enantioselectivity of Chirasil-Dex toward underivatized chiral alcohols, ketones, and hydrocarbons. Furthermore, it was shown that the presence of the cyclodextrin selector in Chirasil-Val-C11 significantly improved the enantioseparation of proline, which represented a problematic amino acid on diamide CSPs.     

Empirical procedure that uses molecular structure to predict enantioselectivity of chiral stationary phases.

A total of 121 racemic compounds were separated in the normal-phase mode on a (S)-(1-naphthylethyl)carbamoylated beta-cyclodextrin (S-NEC-beta-CD) bonded phase and 74 on the R equivalent (R-NEC) chiral stationary phase (CSP). All compounds are of the type that have four substituents on a stereogenic center, rather than an "axis of chirality". It is shown that the binary solvent pair used as the mobile phase has a significant influence on chiral recognition. However, the proportions of the components of a specific pair have little effect. From the results, the individual contributions to chiral recognition by these CSPs were estimated for 81 different substituents of the stereogenic center. Varying the arrangement of these 81 substituents could produce over 1.6 million compounds. Hydrogen was chosen as the reference substituent and was assigned a 0 cal/mol free energy. The chiral recognition increased when sp2-hybridized carbons were connected to the stereogenic center. Conversely, sp3-hybridized carbons decreased the enantioselectivity. Amido groups increased the chiral recognition, especially when associated with pi-acid (3,5-dinitrobenzoyl) or pi-basic (naphthyl) groups. This approach does not allow one to know which enantiomer elutes first. However, the "substituent energy" list for chiral compounds can be used to obtain an estimated value for the enantioselectivity of a compound by adding the energy contributions of the four substituents connected to the stereogenic center. In this way one can predict a priori whether or not a compound will separate on a CSP and estimate its separation factor (alpha). Theoretically, this approach can be used for most CSPs, provided a sufficient data base is generated on them.     

Characterization of a thermally induced irreversible conformational transition of amylose tris(3,5-dimethylphenylcarbamate) chiral stationary phase in enantioseparation of dihydropyrimidinone acid by quasi-equilibrated liquid chromatography and solid-state NMR

A thermally induced irreversible conformational transition of amylose tris(3,5-dimethylphenylcarbamate) (i.e., Chiralpak AD) chiral stationary phase (CSP) in the enantioseparation of dihydropyrimidinone (DHP) acid racemate was studied for the first time by quasi-equilibrated liquid chromatography with cyclic van't Hoff and step temperature programs and solid-state ((13)C CPMAS and (19)F MAS) NMR using ethanol and trifluoroacetic acid (TFA)-modified n-hexane as the mobile phase. The conformational transition was controlled by a single kinetically driven process, as evidenced by the chromatographic studies. Solid-state NMR was used to study the effect of the temperature on the conformational change of the solvated phase (with or without the DHP acid enantiomers and TFA) and provided some viable structural information about the CSP and the enantiomers.     

Enantioselective interactions at the solid-liquid interface of an HPLC column under working conditions

A technique is presented which allows studying the enantioselective interactions occurring at the solid-liquid interface of a chiral stationary phase (CSP) and a racemate relevant to high performance liquid chromatography (HPLC). A conventional chiral column (Chiralpak AS) was mounted on an attenuated total reflection-infrared (ATR-IR) cell mimicking an HPLC setup equipped with an ATR-IR detector. Racemic pantolactone (PL) was used as the selectand. This setup in combination with modulation excitation spectroscopy (MES) allows for the identification of inter- and intramolecular hydrogen bonds being crucial for enantioseparation under HPLC operation conditions. The method is based on a two step strategy. In a first step, the enantiomers are separated by the chiral column similar to a standard HPLC experiment and upon adsorption on the identical CSP deposited on the internal reflection element (IRE), they are detected by ATR-IR spectroscopy. This experiment provides a retention time for each enantiomer. From the difference in retention, a suitable frequency is calculated which is used in a second experiment where the racemate concentration is varied alternately (modulation) in a way that the pulses of ( R)-PL and ( S)-PL exhibit a phase lag of 90 degrees after elution through the column. This procedure allows one to gain separate information of the enantioselective selectand-CSP interaction after performing a demodulation similar to a phase sensitive detection (PSD). A further benefit of this method is the strong enhancement of the signal-to-noise ratio. The effectiveness of the method is demonstrated by investigating the observed faster decrease in retention time of the later-eluted ( R)-PL, as compared to ( S)-PL, when separating at higher temperatures (from 12 to 36 degrees C). The origin is attributed to a weakening of a specific hydrogen bond between the C=O of ( R)-PL and the N-H of the CSP.     

Investigation of Enantiomer Bonding on a Chiral Stationary Phase by FT-Raman Spectrometry

The bonding of serine, phenylalanine, and mandelic acid enantiomers on an N-3,5-dinitrobenzoyl-l-leucine chiral stationary phase (on zeolite A support) has been investigated by FT-Raman spectrometry. It was found that retention is due to hydrogen bonds and π-stacking interactions between the stationary phase and the analyte. The involvement of the two different amide groups (as donor and/or acceptor) in the complexation reaction can be followed based on spectral data. A correlation was found between the ratio of the amide I and the ring stretching (1532 cm(-)(1)) bands and retention data.