氨基甲酸酯型脱氧胆酸分子钳对氨基酸甲酯的手性识别 研究

以脱氧胆酸为spacer,通过三光气桥连各种芳胺,合成了新的氨基甲酸酯型分子钳受体1～4,这些化合物的结构经IR,^1HNMR和元素分析所证实。利用差光谱滴定法考察了其与D/L氨基酸甲酯的对映选择性识别性能。结果表明,分子钳1～4对所考察的氨基酸甲酯均具有识别能力,其对D-氨基酸甲酯的识别优于对L-氨基酸甲酯的识别。从主客体间的大小形状匹配及几何互补关系等方面对这些受体的识别能力及对映选择性进行了讨论。     

新型脱氧胆酸类手性不对称脲分子钳的设计合成

以刚性的脱氧胆酸甲酯为隔离基, 在其3位连接苯甲酰基, 12位连接手性不对称脲, 设计合成了一类新型的手性分子钳. 其结构均经1H NMR, IR, MS和元素分析确证, 并且考察了其对中性分子和D/L-氨基酸甲酯的识别性能. 实验结果表明, 这类分子钳人工受体不仅对中性有机小分子具有良好的识别能力, 而且对D/L-氨基酸甲酯亦具有优良的对映选择性识别性能.     

酯键型鹅去氧胆酸分子钳对氨基酸甲酯的手性识别

利用紫外可见光谱差光谱滴定法考察了新型鹅去氧胆酸分子钳1～6对D／L氨基酸甲酯的对映选择性识别性能。结果表明,分子钳1～6对所考察的氨基酸甲酯均具有识别能力,其对D-氨基酸甲酯的识别优于对L-氨基酸甲酯的识别。受体与底物间的大小、形状匹配,微环境效应等对识别性能均有重要影响。识别作用的主要推动力来自受体与底物之间的互补氢键,受体与底物芳环之间的π-π堆叠作用等非共价键作用力的协同作用。     

微波促进α-猪去氧胆酸类分子钳的合成

在微波辐射条件下,以α-猪去氧胆酸为隔离基,芳香族化合物为手臂合成了一类新型手性分子钳,其结构经1H NMR,IR、MS和元素分析确证,并且考察了其对D/L-氨基酸甲酯的对映选择性识别性能。实验结果表明,这类手性分子钳对L-氨基酸甲酯有较好的识别性能。     

新型鹅去氧胆酸分子钳的设计合成和分子识别性质研究

以鹅去氧胆酸为隔离基, 芳香族化合物为手臂设计合成了一类新型的分子钳, 其结构经¹H NMR, IR, MS及元素分析确证. 利用紫外光谱滴定法考察了其与D/L氨基酸甲酯的对映选择性识别性能. 结果表明, 分子钳3a～3e对所考察的氨基酸甲酯均具有识别能力, 其对L-氨基酸甲酯的识别优于对D-氨基酸甲酯的识别. 从主客体的大小形状匹配及几何互补关系等方面对这些受体的识别能力及对映选择性进行了讨论.     

α-猪去氧胆酸类分子钳的设计合成

以α-猪去氧胆酸为隔离基，芳香族化合物为手臂设计合成了一类新型的酯键 型分子钳，结构均经^1H NMR，IR,MS及元素分析所确证，并且考察了其对芳香胺类 化合物和D／L-氨基酸甲酯的识别性能．初步研究结果表明，这类分子钳受体不但 对中性小分子具有识别性能，而且对D／L-氨基酸甲酯具有对映选择性识别性能．     

胆甾类分子钳对氨基酸衍生物的对映选择性识别

用差紫外光谱滴定法考察了以脱氧胆酸作spacer的手性分子钳1～3对一系列α-氨基酸甲酯的对映选择性识别性能。结果表明,分子钳1和2与客体氨基酸甲酯形成1:1型超分子配合物,并显示较好的手性识别能力。分钳3对所考察的氨基酸甲酯均没有明显的识别作用。讨论了主-客体间尺寸/形状匹配、几何互补等因素对形成超分子配合物的影响,并利用计算机模拟作辅助手段对实验结果和现象进行了解释。     

新的手性芳酰胺分子钳的微波干法合成

在微波辐射无溶剂条件下, 以1,3-二苯氧乙酸为隔离基, L-氨基酸甲酯为手臂设计合成了9个新的分子钳人工受体. 所有化合物的结构均经1H NMR, IR, MS及元素分析所确证. 同传统方法相比, 该法具有简单、快速、有效、对环境友好等优点. 初步的实验结果表明, 这类分子钳受体对D/L-氨基酸甲酯具有良好的对映选择性识别性能.     

微波促进无溶剂条件下酯键型猪去氧胆酸分子钳的快速有效合成

在微波辐射无溶剂条件下, 以固体K2CO3为载体, 猪去氧胆酸甲酯与芳酰氯反应合成了11个猪去氧胆酸分子钳人工受体. 所有化合物的结构均经1H NMR, IR, MS及元素分析所确证. 同传统方法相比, 该法具有简单、快速、 有效、 对环境友好等优点. 同时考察了这类受体对芳胺和手性分子的识别性能. 结果表明, 这类分子钳受体不但对芳胺具有优良的识别性能, 而且对D/L-氨基酸甲酯具有对映选择性识别性能.     

新型酯键型鹅去氧胆酸分子钳的设计合成

以鹅去氧胆酸为隔离基、芳香族化合物为手臂设计合成了一类新型的分子钳, 其结构经¹H NMR, IR, MS和元素分析确证, 并且考察了其对D/L-氨基酸甲酯的对映选择性识别性能. 初步的结果表明, 这类手性分子钳对D-氨基酸甲酯有较好的识别性能.     

酸催化的二芳基甲醇脱水环化氧化芳构化直接构筑4-芳基喹啉

我们发展了酸催化的二芳基甲醇的脱水环化氧化芳构化的方法,直接高产率（高达81%）的合成轴手性的4-芳基喹啉.而且,Lewis酸Zn（OTf）₂和手性膦酸都能催化这个反应,初步的不对称研究可以用er 71：29得到产物.     

双手性选择单元手性固定相的研究进展

手性固定相（chiral stationary phase,CSP）作为手性色谱分离的核心技术,在手性化合物的识别和分离中得到广泛应用。以双手性选择单元结合作为CSP是近些年的研究热点,研究表明,两种手性选择单元相结合的CSP可增加手性识别位点,显著提高分离效果。本文介绍了近几年双手性选择单元手性固定相在手性分离中的研究进展,并对其发展前景进行了展望。     

16种手性化合物在不同自制手性固定相上的拆分比较

采用高效液相色谱法,在自制的纤维素-三(3,5-二甲基苯基氨基甲酸酯)(ATEO-OD)、纤维素-三(4-甲基苯基氨基甲酸酯)(ATEO-OG)和纤维素-三(4-甲基苯基甲酸酯)(ATEO-OJ)3种手性柱上对16种不同结构的手性化合物进行了拆分和比较.试验结果表明:16个手性样品在这3种手性固定相上分别获得了不同程度的拆分,A TEO-OD对所分析样品具有更好的手性识别能力,ATEO-OG和ATEO-OJ的手性识别能力相当.     

Simultaneous chiral analyses of multiple analytes: case studies, implications and method development considerations

The field of chiral separations had a modest beginning some two decades ago. However, due to rapid technological advancement coupled with simultaneous availability of innovative chiral stationary phases and novel chiral derivatization agents, the field of chiral separations has now totally outpaced many other separation fields. Keeping pace with rapid changes in the field of chiral separations, investigators continue to add stereoselective pharmacokinetic, pharmacodynamic, pharmacologic and toxicological data of new and/or marketed racemic compounds to the literature. Examination of the evolution of chiral separations suggests that in the beginning many investigators attempted to separate and quantify a single pair of enantiomers, adopting either direct (separation made on a chiral stationary phase) or indirect (separation made following precolumn conversion of enantiomers to corresponding diastereomers) approaches. However, more recent trends in chiral separations suggest that investigators are attempting to separate and quantify multiple pairs of enantiomers with available technologies. Added to this, some interesting trends have been observed in many of the recently reported chiral applications, including preferences regarding internal standard selection, mobile phase contents and composition, sorting out issues with mass spectrometric detection, determination of elution order, analytical manipulations of metabolite(s) without reference standards and addressing some specificity-related issues. This review mainly focuses on chiral separations involving multiple chiral analytes and attempts to justify the need for such chiral separations involving multiple analytes. In this context, several cases studies are described on the utility and applicability of such chiral separations under discrete headings to provide an account to the readership on the implications of such tasks. The topics of case studies covered in this review include: (a) therapy markers--differentiation from drug abuse and/or applicability in forensics; (b) role in pharmacogenetic/polymorphic evaluation; (c) monitoring and understanding the role of parent and active metabolite(s) in clinical and preclinical investigations; (d) exploration on the pharmacokinetic utility of an active chiral metabolite vis-a-vis the racemic parent moiety; (e) understanding the chirality play in delineating peculiar toxic effects; (f) exploration of chiral inversion phenomenon, and understanding the role of stereoselective metabolism. For the further benefit of readership, some select examples (n = 19) of the separation of multiple chiral analytes with appropriate information on chromatography, detection system, validation parameters and applicable conclusion are also provided. Finally, the review covers some useful considerations for method development involving multiple chiral analytes.     

Last ten years (2008–2018) of chiral ligand‐exchange chromatography in HPLC: An updated review

Chiral ligand‐exchange chromatography is one of the elective strategies for the direct enantioresolution of small chelating compounds: amino acids, diamines, amino alcohols, diols, small peptides, etc. Unlike other methods, the interaction between chiral selector and analyte enantiomers is mediated by a cation, thus producing diastereomeric ternary complexes. Two main approaches are conventionally applied in chiral ligand‐exchange chromatography. The first relies upon chiral stationary phases where the chiral selector is either covalently immobilized or physically adsorbed onto suitable packing materials (coated phases). In the second approach, chiral molecules are added to the eluent, thus generating chiral eluent systems. Among the advantages of chiral ligand‐exchange chromatography, the generation of UV/vis‐active metal complexes, and the use of commercially available or easy‐to‐synthesize chiral selectors, in combination to rather inexpensive achiral columns for coated phases and chiral eluents, are noteworthy. Besides amino acids and amino alcohols, other species have proven suitable for chiral ligand‐exchange chromatography applications. Recently, the use of either chiral ionic liquids or micellar liquid chromatography systems as well as the successful off‐column formation of diastereomeric complexes have expanded the selectivity profiles and application fields. All of these issues are touched in the review, shedding light to the contributions appeared in the last decade.     

环境中手性污染物对映体分析方法的研究进展

手性污染物对映体尽管具有相似的物理化学性质,但在环境中的吸附、转移、降解等过程往往存在一定差异。生态安全问题与人类健康密切相关,因此,对手性环境污染物进行对映体水平上的分离分析是十分重要的研究课题。目前,国内外对环境中的手性污染物已开展了相关研究,然而全面评述相关分析测定方法的新进展鲜有报道。本文主要对环境中手性污染物的种类以及近5年环境中手性污染物的分析检测技术如液相色谱-质谱联用法、气相色谱-质谱联用法、毛细管电泳法、超临界流体色谱-质谱联用法等进行了归纳、综述和展望,为后续手性污染物的分析检测提供依据和参考。     

手性2-(口恶)唑烷酮的无溶剂合成法

在无溶剂条件下,手性的β-氨基醇和脲在160-180℃反应0．5-1 h,在200℃反应0．5 h,高产率地获得手性噁唑烷酮。     

手性2-噁唑烷酮的无溶剂合成法

手性2-噁唑烷酮的无溶剂合成法;手性氨基醇;脲;手性噁唑烷酮     

Methods of studies on quantitative structure–activity relationships for chiral compounds

Chiral compounds are very important in drug development, organic synthesis, materials science, toxicology, or environmental chemistry. Therefore, for creating new drugs, several methods have been suggested in recent years. In several laboratories in the world, some new methods for the derivations of the parameters were constructed and used for studies on quantitative structure–activity/property relationships of chiral molecules. The algorithms reviewed in this paper involve Zargeb group chiral indices, chiral molecular connectivity index, chiral topological charge index, chiral A_m index, chiral indices based on the matrixes, chiral indices based on chiral product, conformation‐independent chirality code, conformation‐dependent chirality code, quantitative two‐dimensional chirality degrees of benzenoids, and so on. Copyright © 2012 John Wiley & Sons, Ltd.