固有手性杯芳烃的研究

固有手性杯芳烃是指在杯芳烃三维骨架上引入数个非手性基团使之不再具有对称面或反转中心而呈现出整体手性。本文综述了固有手性杯芳烃的合成、光学拆分及其在手性识别和不对称催化领域的应用。     

固有手性杯芳烃的研究

固有手性杯芳烃是指在杯芳烃三维骨架上引入数个非手性基团使之不再具有对称面或反转中心而呈现出整体手性。本文综述了固有手性杯芳烃的合成、光学拆分及其在手性识别和不对称催化领域的应用。     

固有手性杯芳烃的研究

固有手性杯芳烃是指在杯芳烃三维骨架上引入数个非手性基团使之不再具有对称面或反转中心而呈现出整体手性.本文综述了固有手性杯芳烃的合成、光学拆分及其在手性识别和不对称催化领域的应用.     

超分子凝胶:结构多样性与超分子手性

超分子凝胶作为一种重要的软物质材料,在构建多重刺激响应性、光电功能,以及生物相容材料等功能软物质方面表现出了独特的优越性。超分子凝胶在形成过程中往往得到比较均一的纳米结构,且具有结构多样性;而另一方面,超分子凝胶的构筑单元大部分是手性分子,超分子凝胶也是实现手性在超分子层次/纳米层次表达的重要途径,尤其是手性传递、手性放大、不对称催化方面,同时超分子凝胶也是构筑手性纳米结构的重要手段。本文主要对超分子凝胶形成中的纳米结构以及形貌的多样性和超分子手性进行介绍,并展望该领域未来的发展方向。     

杯芳烃手性识别在核磁中的检测

杯芳烃是一类重要的主体化合物,在主-客体识别分析中有着广泛的用途.手性杯芳烃因其良好的手性识别、对映体分离和不对称催化等特点,成为杯芳烃化学中最令人瞩目的研究热点之一.在手性识别的研究中,核磁因其检测方便、直观、效果显著等优点,成为检测手性化合物的对映体ee值和绝对构型中最为广泛的方法.综述了近年来以杯芳烃为分子骨架的手性受体的合成及其在核磁中的手性识别,最后对手性杯芳烃的发展前景作了展望.     

基于杯[4]芳烃的手性识别*

手性杯芳烃是一类重要的主体化合物,在手性识别、对映体分离和不对称催化等方面有着广泛的用途。[4]芳烃引其稳定的构象和易于修饰的特点,成为研究最为广泛的杯芳烃分子,其中大量的文献报道了能够用于对映体识别和检测的手性[4]芳烃。在手性识别的研究中,荧光、紫外和核磁是3中最常见的研究方法,本文根据这3种方法进行分类,综述了近年来以杯[4]芳烃为分子骨架的手性受体的合成及其在手性识别中的应用。最后对手性[4]芳烃的发展前景作了展望。     

超分子凝胶的手性功能应用:手性分子识别与不对称催化

超分子凝胶通过形成三维空间网络结构将溶剂液体相固定化,是一类重要的软物质材料。由于超分子凝胶能快速形成,自组装形成的纳米结构均一、可调,且可大规模制备,因此成为超分子化学、纳米技术以及材料科学研究的重要研究方向之一,并在诸多领域得到广泛的功能研究和应用拓展,如在材料模板、光电开关、药物释放、分子识别和超分子催化等方面已有大量研究报道。由于超分子凝胶具有固-液相可逆转变、可控组装等特性,成为了超分子手性和分子手性研究的重要载体。近年来超分子凝胶在超分子手性催化、手性分子识别等方面取得了一系列重要突破,为超分子凝胶功能应用开辟了新的空间,为手性科学研究提供了新的手段和方法。     

非手性液晶聚合物中超分子手性结构的诱导与光照固定

超分子手性结构由于其形成所需的非共价相互作用力较弱，因此极易在外界条件刺激下发生解离，从而导致手性消失。在绝大多数情况下，以非手性单元为组装模块的组装体系中超分子手性结构在外部环境刺激下被破坏后无法恢复。为了提高超分子手性结构的稳定性，克服其对原有手性源的依赖性，设计合成了一种侧链型非手性苯甲酸苯酯液晶聚合物，在聚合物侧链末端引入肉桂酸结构作为交联基团。将手性柠檬烯的手性诱导与简单的光照交联结合即可实现超分子手性的共价键固定，极大地简化了交联过程，为手性材料的制备与手性信息存储提供了新的策略。     

含有喹啉-2-甲醇单元的光学纯固有手性杯[4]芳烃衍生物：合成与在二乙基锌对苯甲醛催化不对称加成中的应用

合成并表征了一系列由含有喹啉-2-甲醇单元的具有锥式或部分锥式构象的光学纯固有手性杯[4]芳烃衍生的新型N,O-型手性配体,并且研究了这些手性配体在二乙基锌对苯甲醛催化不对称加成反应中的应用,这是首例有关固有手性杯芳烃作为手性配体用于催化不对称合成.     

杯[4]脯氨酸衍生物的合成及其对扁桃酸对映异构体的手性识别

以氨基杯[4]芳烃为原料,合成了五种手性杯[4]脯氨酸衍生物,其结构经1H NMR,13C NMR,IR,ESI-MS及元素分析表征.运用核磁共振技术研究它们对扁桃酸对映异构体的手性识别性能,结果表明5,11-二脯氨酰胺取代杯[4]芳烃2b对两种不同构型的扁桃酸异构体具有较好的选择性识别作用(KL/KD≈94).提出可能的识别机理为分子间多种超分子相互协同作用,包括酸碱作用、氢键和π···π堆积作用.     

不含手性碳的手性化合物及其绝对构型——剑桥结构数据库实例分析

利用英国剑桥结构数据库中的实例并结合相关三维可视化软件,介绍了含有氮/磷等手性杂原子、轴手性、平面手性、螺旋手性、超分子手性等手性因素的手性化合物及其绝对构型,以加深对手性概念的认识和理解。     

手性溶剂诱导非手性物质手性的研究进展

手性溶剂诱导非手性物质产生手性是目前合成手性物质的主流方法之一。与传统的手性物质合成方法相比,手性溶剂诱导法不仅避免了使用昂贵的手性试剂,还能扩大合成手性物质的结构范围,具有潜在的应用前景。目前,手性溶剂诱导方法适用范围已经涵盖了有机小分子、低聚物和聚合物体系。本文主要对手性溶剂诱导方法发展的历史背景,手性溶剂诱导小分子及低聚物的手性,手性溶剂诱导非手性聚合物产生超分子手性,主要包括π-共轭聚合物和σ-共轭聚合物这几个方面展开了综述。     

Exploring the Synthesis of a New Group of Chiral Ammonium Salts with Specific Configurations at the Stereogenic Nitrogen Centers

A group of new chiral dications with a fixed, specific configuration at the stereogenic nitrogen center was created. Stereoselective synthesis and recrystallization give the diastereomerically and enantiomerically pure dications, including a chiral amphiphile with surface‐active properties.     

Enantioselectivity in Drug Pharmacokinetics and Toxicity: Pharmacological Relevance and Analytical Methods

Enzymes, receptors, and other binding molecules in biological processes can recognize enantiomers as different molecular entities, due to their different dissociation constants, leading to diverse responses in biological processes. Enantioselectivity can be observed in drugs pharmacodynamics and in pharmacokinetic (absorption, distribution, metabolism, and excretion), especially in metabolic profile and in toxicity mechanisms. The stereoisomers of a drug can undergo to different metabolic pathways due to different enzyme systems, resulting in different types and/or number of metabolites. The configuration of enantiomers can cause unexpected effects, related to changes as unidirectional or bidirectional inversion that can occur during pharmacokinetic processes. The choice of models for pharmacokinetic studies as well as the subsequent data interpretation must also be aware of genetic factors (such as polymorphic metabolic enzymes), sex, patient age, hepatic diseases, and drug interactions. Therefore, the pharmacokinetics and toxicity of a racemate or an enantiomerically pure drug are not equal and need to be studied. Enantioselective analytical methods are crucial to monitor pharmacokinetic events and for acquisition of accurate data to better understand the role of the stereochemistry in pharmacokinetics and toxicity. The complexity of merging the best enantioseparation conditions with the selected sample matrix and the intended goal of the analysis is a challenge task. The data gathered in this review intend to reinforce the importance of the enantioselectivity in pharmacokinetic processes and reunite innovative enantioselective analytical methods applied in pharmacokinetic studies. An assorted variety of methods are herein briefly discussed.     

An Inherent Chiral Calix[4]arene Bearing Chiral Groups without Forming Sub-ring

Parent calixarenes are inherently highly symmetrical and are, therefore, achiral molecules. Hence, two strategies have been developed to prepare chiral calixarenes. The first method involves the construction of the asymmetric calixarene frame by introduci…     

Catalytic Enantioselective Simultaneous Control of Axial Chirality and Central Chirality in Allenes

Chiral molecules, which may contain one or more different type(s) of stereocentres, such as central, axial, planar, and helical chiralities, etc., are indispensable in chemistry, pharmaceutical industry, and life science. Despite many advances for the preparation of chiral molecules usually with a single type of chirality have been realized, simultaneous construction of different types of chiralities is still a significant challenge. Here, we wish to report a protocol for preparation of chiral allenes with both central and axial chiralities via a catalytic asymmetric allenylation of different biologically or synthetically useful fluorinated or non‐fluorinated nucleophiles with readily available racemic allenes by using a single chiral ligand. An echoing between the central chirality and axial chirality for the enantioselectivity was observed. This strategy provides a general and practical approach to functionalized optically active allenes bearing both central and axial chiralities with an excellent enantioselectivity under mild conditions.     

Chiral polymer-based biointerface materials

Chirality is a unique phenomenon in nature. Chiral interactions play an important role in biological and physiological processes, which provides much inspiration for scientists to develop chiral materials. As a breakthrough from traditional materials, biointerface materials based on chiral polymers have attracted increasing interest over the past few years. Such materials elegantly combine the advantages of chiral surfaces and traditional polymers, and provide a novel solution not only for the investigation of chiral interaction mechanisms but also for the design of biomaterials with diverse applications, such as in tissue engineering and biocompatible materials, bioregulation, chiral separation and chiral sensors. Herein, we summarize recent advances in the study of chiral effects and applications of chiral polymer-based biointerface materials, and also present some challenges and perspectives.