环糊精对手性药物伪麻黄碱分子识别的电喷雾飞行时间质谱研究

用电喷雾正交飞行时间质谱仪分别研究了以α－环糊精、β－环糊精和γ－环 糊精作为手性拆分剂对手性药物伪麻黄碱的分子识别效应,同时还分别研究了 Nozzle电的变化对α－环糊精和γ－环糊精的手性识别的影响。在质谱图中能明显 反映出三种手性拆分剂都具备很强的手性识别能力,随Nozzle电压的改变,三种手 性拆分剂双分别具有各自的手性识别特征。     

环糊精对手性药物伪麻黄碱分子识别的电喷雾飞行时间质谱研究

用电喷雾正交飞行时间质谱仪分别研究了以α－环糊精、β－环糊精和γ－环 糊精作为手性拆分剂对手性药物伪麻黄碱的分子识别效应，同时还分别研究了 Nozzle电的变化对α－环糊精和γ－环糊精的手性识别的影响。在质谱图中能明显 反映出三种手性拆分剂都具备很强的手性识别能力，随Nozzle电压的改变，三种手 性拆分剂双分别具有各自的手性识别特征。     

新型三唑类抗真菌活性化合物毛细管电泳手性拆分及手性识别机理分子模拟研究

研究了7种新型三唑类抗真菌活性化合物的毛细管电泳法手性分离,利用计算机辅助分子模拟技术研究拆分机理。考察了8种中性环糊精手性添加剂,只有2,6-二甲基-β-环糊精对7种活性化合物都有手性识别能力。在30mmol/L NaH2PO4缓冲液中含2,6-二甲基-β-环糊精30mmol/L,用H3PO4调至pH 2.2,温度20℃,电压20kV,在此条件下7种活性化合物都能达到手性分离,其中4种活性化合物能达到基线分离(Rs>1.5)。应用计算机辅助分子模拟软件Discovery Studio 2.5/Sybyl/Gold模拟2,6-二甲基-β-环糊精与7种活性化合物主客体包结过程,并计算相互结合能,探讨手性识别机理,发现拆分结果与结合能的差异有关,结合能差异越大拆分结果越好。     

七-(2,6-二-O-甲基)-β-环糊精对1,1'-联萘酚对映体手性识别的电喷雾质谱研究

利用电喷雾质谱研究了β-环糊精、七-(2,6-二-O-甲基)-β-环糊精作为手性识别试剂对1,1'-联萘酚对映体的手性识别效应. 实验结果表明, 在气相中, β-环糊精与七-(2,6-二-O-甲基)-β-环糊精都可以与联萘酚形成非共价复合物. 对形成的复合物的串联质谱研究表明, β-环糊精不能识别联萘酚对映体, 而七-(2,6-二-O-甲基)-β-环糊精对联萘酚对映体有较强的手性识别效应. 进一步研究表明七-(2,6-二-O-甲基)-β-环糊精与联萘酚对映体混合比例以及CID能量对于手性识别并无影响.     

全衍生化羟丙基-β-环糊精固定相的制备及应用

研究了3, 5-二甲基苯基异氰酸酯对羟丙基-β-环糊精固定相的手性识别影响.通过异氰酸丙基三乙氧基硅烷作偶联剂,将羟丙基-β-环糊精键合到3-氨丙基硅烷化硅胶上,再用3, 5-二甲基苯基异氰酸酯对β-环糊精和硅胶其余羟基进行衍生化,制得一种新型的3, 5-二甲基苯基氨基甲酸酯全衍生化羟丙基-β-环糊精键合硅胶手性固定相.在反相色谱条件下,对9种手性药物进行了拆分,结果表明,3, 5-二甲基苯基氨基全衍生化固定相较之羟丙基-β-环糊精固定相有更好的分离效果.     

双相(O/W)识别手性萃取分离α-环己基扁桃酸对映体

提出一种新的手性分离技术双相(O/W)识别手性萃取. 研究了α-环己基扁桃酸对映体在D(L)-酒石酸异丁酯1,2-二氯乙烷有机相和β-环糊精衍生物水相萃取体系中的分配行为; 考察了β-环糊精衍生物种类和浓度、酒石酸酯构型和浓度、水相pH 值等因素对萃取性能的影响. 实验结果表明, 双相(O/W)识别手性萃取具有很强的手性分离能力, 羟丙基β-环糊精、羟乙基β-环糊精、甲基β-环糊精均对S-α-环己基扁桃酸对映体的识别能力大于对R-α-环己基扁桃酸对映体的识别能力, 其中以羟丙基β-环糊精的识别能力最强; 而D-酒石酸异丁酯的识别能力刚好相反; 在羟丙基β-环糊精和D-酒石酸异丁酯萃取体系中, α-环己基扁桃酸外消旋体一次萃取分离后, 水相中S-对映体e.e.%达到27.6%, R-和S-对映体的分配系数(k_R和k_S)分别为2.44和0.98, 分离因子(α)达2.49; 同时pH值和萃取剂浓度对手性分离能力有显著影响. 双相(O/W)识别手性萃取对外消旋体化合物的制备性分离有着十分重要的意义.     

α－溴丙酸甲酯与β－环糊精衍生物手性识别过程的模 拟研究

应用分子动力学方法,模拟研究了α－溴丙酸甲酯分别与全甲基－β－环糊精(PMBCD)、七(2,6-二-O-丁基-3-O-丁酰基)-β－环糊精(DBBBCD)的手性识别过程。结果表明,α－溴丙酸甲酯对映体与PMBCD,DBBBCD的优先结合点位于环糊精空腔的内部,其对映体与所述环糊精的手性识别机理和形成腔内结合物有关;对映体在环糊精空腔内的结合并非传统意义上的紧密包合,对映体在腔内可以上下运动和转动;从对平衡构象的结构分析发现,所述对映体与环糊精衍生物的手性识别与葡萄糖单元的C(2),C(3)所提供的手性环境密切相关。而且,分子模拟方法得到的对映体保留顺序与气相色谱实验结果是一致的。     

七-(2,6-二-O-甲基)-β-环糊精对薄荷醇对映体手性识别的电喷雾质谱研究

利用电喷雾质谱研究了七-(2,6-二-O-甲基)-β-环糊精(DM-β-CD)作为手性识别试剂对薄荷醇对映体的手性识别效应。实验结果表明,在气相条件下,DM-β-CD可以与薄荷醇形成特异性结合复合物,化学计量比为1∶1。对复合物的串联质谱研究表明,DM-β-CD对薄荷醇对映体有较强的手性识别能力,手性识别率为Rchiral=1.81。DM-β-CD与(-)-薄荷醇形成的复合物比与( )-薄荷醇形成的复合物稳定。     

环糊精对托品烷手性识别的电喷雾傅立叶变换离子回旋共振质谱研究

用电喷雾傅立叶变换离子回旋共振质谱仪分别研究了以α-环糊精、β-环糊精和γ-环糊精作为手性拆分剂对手性托品烷的手性区分效应,实验结果表明β-环糊精具备较α-环糊精和γ-环糊精更强的手性区分能力,β-环糊精和托品烷的二聚体复合物离子的强度随激发能量的变化和托品烷对映体含量值呈现出一定的线性关系.     

以2-O-单取代羟丙基β-环糊精用于毛细管电泳手性分离添加剂

本文研究了一种新的环糊精衍生物2－O－单取代羟丙基β－环糊精做为毛细管电泳手性分离添加剂时，对3种碱性药物对映体；扑尔敏，麻黄碱，心得安的拆分性能。并与β－环糊精，2．6－O－二甲基β－环糊精，多取代2－O－羟丙基β－环糊精的手性识别性能做了对比。     

Combined approach using capillary electrophoresis and NMR spectroscopy for an understanding of enantioselective recognition mechanisms by cyclodextrins

This tutorial review describes the contribution of chiral capillary electrophoresis in combination with other instrumental techniques, especially nuclear magnetic resonance spectroscopy, to a better understanding of the chiral recognition mechanisms by cyclodextrins. Aspects such as affinity pattern of enantiomers towards various cyclodextrins as well as the stoichiometry of the resulting complexes, the equilibrium constants and the structure of complexes are addressed. In addition to the aforementioned techniques, the usefulness of complementary instrumental and molecular modeling techniques for an understanding of the chiral recognition mechanisms of cyclodextrins is also illustrated.     

Gas-Phase Binding of Noncovalent Complexes Between α-cyclodextrin and Amino Acids Investigated by Mass Spectrometry

Noncovalent complexes between cyclodextrins and small molecules have been extensively studied recently because of their widespread application in the pharmaceutical industry for chiral and molecular recognition. To date, gas phase noncovalent binding affinities between α-cyclodextrin and amino acids have not been widely investigated. In this study, gas-phase binding of noncovalent complexes between α-CD and amino acids was investigated by electrospray ionization mass spectrometry (ESI-MS), demonstrating the formation of 1:1 stoichiometric noncovalent complexes. The binding of the complexes were further confirmed by collision-induced dissociation by tandem mass spectrometry. Mass spectrometric titrations between α-cyclodextrin and phenylalanine, glutamic acid, and arginine were performed to provide binding constants (lgK_a) as references for competitive ESI-MS. Calibration curves for the complexes of α-cyclodextrin with phenylalanine, glutamic acid, and arginine were plotted. Through competitive ESI-MS, the lgK_a for the complexes of α-CD with aspartic acid, lysine, proline, glycine, alanine, asparagine, cystine, glutamine, histidine, leucine, isoleucine, methionine, serine, threonine, and valine were measured directly. By comparison, it is seen that the measured binding constants for the complexes of α-cyclodextrin with basic amino acids such as arginine and lysine are lower than those for most complexes of neutral amino acids. The chiral selectivity of α-cyclodextrin for L- and D-isomers of methionine, threonine, asparagine, and phenylalanine determined by ESI-MS revealed its application as a chiral selector.     

Extension of chromatographically derived chiral recognition systems to chiral recognition and enantiomer analysis by electrospray ionization mass spectrometry

Chiral recognition by positive ion electrospray ionization (ESI) mass spectrometry is demonstrated through the adaptation of chromatographically derived chiral recognition systems. Solutions of soluble analogues of chiral selectors used in Pirkle-type chiral stationary phases, when mixed with a chiral analyte, whose enantiomers are known to be resolved on the analogous chiral stationary phase, are shown to afford selector–analyte complexes in the mass spectrum. Pseudo-enantiomeric chiral selectors, where each pseudo-enantiomer has a different mass and a higher affinity for the opposite analyte enantiomer of its pseudo-antipode, were prepared. When mixed with a chiral analyte, solutions of these pseudo-enantiomeric selectors afford selector–analyte complexes in the ESI-mass spectrum where the relative intensities of the selector–analyte complexes are dependent on the enantiomeric composition of the analyte. Additionally, the sense of the observed chiral recognition is in agreement with the sense of chiral recognition observed chromatographically.     

Chiral recognition of functionalized cyclodextrins in capillary electrophoresis

The chiral recognition of hydroxypropylated, dimethylated, and sulfated cyclodextrins was evaluated by utilizing them as chiral additives in capillary electrophoresis. Although each selector yielded enantiomeric separations of most of the target analytes, differences were observed in the electrophoretic results for the different derivatized cyclodextrins and for additives having varying degrees of substitution. The results for the sulfated cyclodextrins also highlighted the importance of knowing the degree of substitution as well as the location of the substituents when comparing chiral selectors.     

Chiral separation by capillary electromigration techniques

This review gives an overview of chiral separation principles and their applications in capillary electromigration techniques. The basic chiral separation principles are explained and the mechanisms discussed. Recent developments and new techniques in CZE and capillary electrochromatography (CEC) are highlighted. New chiral selectors among cyclodextrins, crown ethers, carbohydrates, macrocyclic antibiotics, proteins, chiral ion-pairing reagents, chiral surfactants and chiral metal ion complexes and their chiral recognition ability are discussed. Recent advances in chip technology for chiral separation and new approaches regarding improvement of detection sensitivity are presented. Due to the tremendous number of publications dealing with applications, in this review only recent applications are summarized.     

Enhancement of chiral recognition by formation of a sandwiched complex in capillary electrophoresis

For chiral primary amino compounds not separable by cyclodextrins alone, chiral recognition was successfully achieved by the formation of a sandwiched complex of the non-chiral 18-crown-6, the chiral amine and cyclodextrin (CD) [18-crown-6+amino compound+CD]. The separation of 1-methyl-3-phenylpropylamine and 1,2,3,4-tetrahydro-1-naphthylamine racemates showed the special function of the non-chiral 18-crown-6 on chiral recognition. By formation of the sandwiched complex, the chiral center of 1-methyl-3-phenylpropylamine was successfully recognized, and resolution of 1,2,3,4-tetrahydro-1-naphthylamine dramatically increased. In these studies, the mobility differences of the enantiomers were evaluated as a function of the concentration of cyclodextrins with and without the 18-crown-6, and as a function of the concentration of the 18-crown-6. In addition, the separations by this method were compared to those by the chiral 18-crown-6 reagent.     

环糊精及其衍生物在手性识别中的应用

详细地论述了环糊精及其衍生物在手性识别中的应用,并对环糊精超分子体系手性识别中的进一步研究提供了依据。     

Evaluation of chiral recognition characteristics of metal and proton complexes of di-o-benzoyl-tartaric acid dibutyl ester and L-tryptophan in the gas phase

Chiral recognition of di-o-benzoyl-tartaric acid dibutyl ester (T) was achieved in the gas phase by electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry. In this method two divalent transition metal cations, zinc(II) and copper(II), were used as binding metal ions, and L-tryptophan (A) was used as a chiral reference. Multimeric complexes were readily formed by electrospray ionization of a methanol:water (50:50) solution containing metal ion, L-tryptophan and T. These multimeric complexes included singly charged protonated dimeric [TAH](+), doubly charged copper(II) bound tetrameric [TACu-H](2)(2+) and doubly charged zinc(II) bound tetrameric [TAZn-H](2)(2+), together with other complexes. The mass-selected complex, i.e., [TAH](+), [TACu-H](2)(2+) and [TAZn-H](2)(2+), was used to acquire the second stage mass spectra. The chiral recognition capability of these three complexes was evaluated using the abundance ratios of daughter ion to parent ion. A high degree of chiral recognition ability was observed in [TACu-H](2)(2+) and [TAZn-H](2)(2+). It was found that the type of binding ion played an important role in the chiral recognition. Different binding ions exhibited distinctive dissociation pathways and unique chiral recognition characteristics. The present method is based not only on whole-molecule loss but also on fractional-molecule loss. In addition, the reproducibility of the chiral recognition method was confirmed by several determinations of the abundance ratios of daughter ion to parent ion with a fixed activation energy and with five different activation energies. It was also shown that this chiral recognition method can tolerate acid interference.