电化学方法手性识别的研究进展

目前,色谱法、光谱法、显微技术和电化学方法等已成功用于手性化合物分离分析的定性和定量研究,并取得了一定的研究进展,其中,电分析方法因具有灵敏度高、仪器简单、检测快速等特点而广受关注。本文综述了近几年来电化学方法用于手性识别的研究进展,评述并展望了该领域的发展前景。     

Pillar[5]arene-functionalized nanochannel platform for detecting chiral drugs

Chirality is a fascinating and essential feature of life and highly associated with many significant pharmaceutical,chemical,and biological processes.The construction of chiral recognition platform is a hot research topic and challenging assignment.Herein,we report an electrochemical method by diffe rential pulse voltammetry(DPV) for the enantioselective recognition of chiral drug propranolol(R/SPPL) through a nanochannel platform based on the N-acetyl-L-cysteine functionalized pillar[5]arenes derivative NALC-P5 and the porous polycarbonate membrane.The chiral discrimination depends on the diffe rence in the supramolecular host-guest interaction between the chiral NALC-P5 and the R/S-PPL.The transmission rate of the R/S-PPL can be regulated in the nanochannel and we can achieve the selective transport of the chiral drugs.This simple electrochemical technique has potential applications as a general platform for the recognition of chiral molecules.     

苯丙胺类、氯胺酮、卡西酮类毒品手性分离的研究进展

对映异构体在自然界中普遍存在,在药物化学领域尤为突出。虽然手性药物的对映异构体之间具有相同的化学结构,但它们在药理、毒理、药代动力学、代谢等生物活性方面存在明显差异。苯丙胺类、氯胺酮、卡西酮类毒品也是如此,这3类毒品的手性分离研究在常见毒品中具有代表性。目前常用的手性分离色谱方法有气相色谱法(GC)、高效液相色谱法(HPLC)和毛细管电泳法(CE)。苯丙胺类、氯胺酮、卡西酮类毒品使用以上3种方法进行的手性分离研究具有一定共性:GC较多使用N-三氟乙酰-L-脯胺酰氯和(+)R-α-甲氧基α-三氟甲基苯乙酸两种典型的手性衍生化试剂,HPLC主要应用蛋白质类、多聚糖类和大环抗生素类3种手性固定相,CE中环糊精及其衍生物是最常用的手性选择剂。然而这3种手性分离方法存在各自的不足,GC存在手性衍生化引入杂质、反应温度高影响手性分离等问题,HPLC的应用范围比较有限,成本较高,CE没有明确的方法判断哪种物质是合适的手性选择剂。近年来,这3类毒品的手性分离研究在法医毒物学领域的应用有各自的特点,苯丙胺类毒品的手性分离研究多用于推断市场上毒品的原型及合成路线,氯胺酮的手性分离研究涉及多种生物检材,卡西酮类毒品侧重于手性分离方法的广泛适用性。该文主要遴选近10年国内外核心期刊的文献,对苯丙胺类、氯胺酮、卡西酮类毒品的手性异构体特点及色谱法的手性识别机理进行简单介绍,重点对已有研究的共性以及手性分离在法医毒物学中的应用等内容进行综述。基于以上研究,该文提出未来可以从以下3个方面进行深入研究:一是利用计算机技术建立分子模型深入探究手性识别机理;二是研发新型技术,对超临界流体法进行商用研究;三是将手性分离应用于司法实践、医药研发等实际工作领域。     

分子印迹聚合物在毛细管电色谱拆分手性药物中的研究进展

手性药物通过与生物体内生物大分子之间的手性匹配与分子识别来发挥药理作用。两个对映体与体内手性环境相互作用的不同导致每个对映体表现出不同的药理活性、代谢过程、代谢速率及毒性等药代动力学特征。因此发展手性药物的拆分方法,对于手性药物的开发和生产过程的质量监控具有重要意义。分子印迹聚合物（MIPs）是以目标分子作为模板而制备的高分子聚合物,它具有特定的空间分子结构和官能团,对目标分子具有高度的特异性识别能力。基于该特点,MIPs非常适合于手性药物的拆分和纯化。毛细管电色谱（CEC）可同时基于毛细管电泳和液相色谱的分离机理对目标物进行分离,因此具有高分离效率和高选择性的特点。将MIPs材料作为CEC的固定相,可将这两种技术的优势结合,从而实现对手性药物的高效拆分。MIPs材料在1994年首次应用于CEC手性拆分,此后该研究领域开始获得关注和发展。MIPs材料主要通过4种模式在CEC中实现手性拆分,分别是作为开管柱、填充柱和整体柱的固定相以及分离介质中的准固定相。该综述以这4种模式作为分类基准,根据MIPs制备所需的材料和分离对象对其在CEC手性拆分中的应用进行了总结,揭示了MIPs在CEC手性拆分中的潜力,同时评述了这4种模式各自的优势与不足,并对将来MIPs在CEC手性拆分中的发展进行了展望。     

Apoptosis Evaluation by Electrochemical Techniques

Apoptosis has close relevance to pathology, pharmacology, and toxicology. Accurate and convenient detection of apoptosis would be beneficial for biological study, clinical diagnosis, and drug development. Based on distinct features of apoptotic cells, a diversity of analytical techniques have been exploited for sensitive analysis of apoptosis, such as surface plasmon resonance, electrochemical methods, flow cytometry, and some imaging assays. Among them, the features of simplicity, easy operation, low cost, and high sensitivity make electrochemical techniques powerful tools to investigate electron‐transfer processes of in vitro biological systems. In this contribution, a general overview of current knowledge on various technical approaches for apoptosis evaluation is provided. Furthermore, recently developed electrochemical biosensors for detecting apoptotic cells and their advantages over traditional methods are summarized. One of the main considerations focuses on designing the recognition elements based on various biochemical events during apoptosis.     

Molecularly imprinted polymer based enantioselective sensing devices: A review

Chiral recognition is the fundamental property of many biological molecules and is a quite important field in pharmaceutical analysis because of the pharmacologically different activities of enantiomers in living systems. Enantio-differentiating signal of the sensor requires specific interaction between the chiral compounds (one or a mixture of enantiomers) in question and the selector. This type of interaction is controlled normally by at least three binding centers, whose mutual arrangement and interacting characteristics with one of the enantiomers effectively control the selectivity of recognition. Molecular imprinting technology provides a unique opportunity for the creation of three-dimensional cavities with tailored recognition properties. Over the past decade, this field has expanded considerably across the variety of disciplines, leading to novel transduction approaches and many potential applications. The state-of-art of molecularly imprinted polymer-based chiral recognition might set an exotic trend toward the development of chiral sensors. The objective of this review is to provide comprehensive knowledge and information to all researchers who are interested in exploiting molecular imprinting technology toward the rational design of chiral sensors operating on different transduction principles, ranging from electrochemical to piezoelectric, being used for the detection of chiral compounds as they pose significant impact on the understanding of the origin of life and all processes that occur in living organisms.     

Electrochemical enantiorecognition of tryptophan enantiomers based on graphene quantum dots–chitosan composite film

A graphene quantum dots (GQDs)–chitosan (CS) composite film was prepared via successive electrodeposition of GQDs and CS on the surface of a glassy carbon electrode (GCE). The strong interactions between GQDs and CS resulted in the formation of a regular and uniform film, which can be applied in the electrochemical chiral recognition of tryptophan (Trp) enantiomers. CS in the composite film provides a chiral microenvironment, meanwhile, GQDs can amplify the electrochemical signals and improve the recognition efficiency. Due to the synergetic effect of GQDs and CS, chiral recognition of Trp enantiomers is achieved successfully. Compared with previous reports utilizing GQDs in photoluminescent research, this work opens a new avenue for broadening the applications of GQDs in the electrochemically chiral sensors.     

Retention mechanism of high-performance liquid chromatographic enantioseparation on macrocyclic glycopeptide-based chiral stationary phases

The development of methods for the separation of enantiomers has attracted great interest in the past 20 years, since it became evident that the potential biological or pharmacological applications are mostly restricted to one of the enantiomers. In the past decade, macrocyclic antibiotics have proved to be an exceptionally useful class of chiral selectors for the separation of enantiomers of biological and pharmacological importance by means of high-performance liquid chromatography (HPLC), thin-layer chromatography and electrophoresis. The glycopeptides avoparcin, teicoplanin, ristocetin A and vancomycin have been extensively used as chiral selectors in the form of chiral bonded phases in HPLC, and HPLC stationary phases based on these glycopeptides have been commercialized. In fact, the macrocyclic glycopeptides are to some extent complementary to one another: where partial enantioresolution is obtained with one glycopeptide, there is a high probability that baseline or better separation can be obtained with another. This review sets out to characterize the physicochemical properties of these macrocyclic glycopeptide antibiotics and, through their application, endeavors to demonstrate the mechanism of separation on macrocyclic glycopeptides. The sequence of elution of the stereoisomers and the relation to the absolute configuration are also discussed.     

金纳米棒——从可控制备与修饰到纳米生物学与生物医学应用

金纳米棒因其独特的光学活性(纵向和横向两个等离子体共振吸收峰,可调范围从可见光区到近红外区)、长径比可调,表面易于修饰,生物相容性良好而使得其在纳米生物学和生物医学等领域具有广泛的应用前景。金纳米棒的合成及表面修饰直接决定着其物理化学性质,进而影响其生物相容性及其在生物医学中的应用。本文综述了金纳米棒的可控制备方法(包括模板法、电化学法、光化学法和晶种法)、表面可控修饰方法及其在纳米生物学和生物医学中的应用新进展,重点总结了金纳米棒的表面可控修饰及其在分子探针、生物传感、生物成像、药物载体、基因载体和光热疗法的最新研究进展。最后针对金纳米棒在生物应用过程中的一些瓶颈问题(如:特异性识别能力需要增强和荧光量子产率尚待提高等)提出了将手性分子或智能聚合物引入到金纳米棒表面进行可控修饰,以期增强其特异性识别能力并提高荧光量子产率,为金纳米棒的发展提供了新的思路。     

Polysaccharide- and β-Cyclodextrin-Based Chiral Selectors for Enantiomer Resolution: Recent Developments and Applications

Polysaccharides, oligosaccharides, and their derivatives, particularly of amylose, cellulose, chitosan, and β-cyclodextrin, are well-known chiral selectors (CSs) of chiral stationary phases (CSPs) in chromatography, because they can separate a wide range of enantiomers. Typically, such CSPs are prepared by physically coating, or chemically immobilizing the polysaccharide and β-cyclodextrin derivatives onto inert silica gel carriers as chromatographic support. Over the past few years, new chiral selectors have been introduced, and progressive methods to prepare CSPs have been exploited. Also, chiral recognition mechanisms, which play a crucial role in the investigation of chiral separations, have been better elucidated. Further insights into the broad functional performance of commercially available chiral column materials and/or the respective newly developed chiral phase materials on enantiomeric separation (ES) have been gained. This review summarizes the recent developments in CSs, CSP preparation, chiral recognition mechanisms, and enantiomeric separation methods, based on polysaccharides and β-cyclodextrins as CSs, with a focus on the years 2019–2020 of this rapidly developing field.     

Comparative analysis of chiral drugs in view of chemometrics

With the development of methods for obtaining chiral compounds as potential drugs, there is also need to develop analytical methods for the separation of both enantiomers. Keeping in mind that the physical and chemical properties of both enantiomers are identical, their different nature will only be revealed in a chiral environment that is appropriately designed. Physicochemical systems can be used to predict the differences in biological activity of both enantiomers. The complexity of the problem requires the use of additional tools, which are various chemometric methods. This paper reviews the application of chemometry in the analysis of chiral drugs and discusses the effects of a combination of chromatographic, electrophoretic, and spectroscopic analysis (UV-Vis absorption spectroscopy, and near-IR spectroscopy aided by cyclodextrin inclusion complexes) with chemometrics for improving the methods of enantioseparation (experimental design), explaining the mechanisms of behavior and chiral recognition (quantitative structure-enantioselective retention relationships) and indicating chiral purity (enantiomeric excess).     

Synthetic strategies for chiral metal-organic frameworks

By direct synthesis route, chiral metal-organic frameworks are synthetized with enantiopure ligands or spontaneous resolution; by indirect method, post-synthetic method and chiral inductionare introduced to construct chiral metal-organic frameworks.     

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。     

Electrochemical recognition of tryptophan enantiomers using self-assembled diphenylalanine structures induced by graphene quantum dots,chitosan and CTAB

Molecular self-assembly offers a promising route to the preparation of advanced materials for the construction of novel chiral sensing devices, and the inspiration for the development of such systems is often derived from simple biological models. Diphenylalanine (FF), an extensively studied short peptide, can self-assemble into highly ordered nano-/micro-structures. Here we report the electrochemical recognition of tryptophan enantiomers using three FF self-assembled structures produced in the presence of graphene quantum dots (GQDs), chitosan (CS) and cetyltrimethylammonium bromide (CTAB). Although the difference in the peak potentials of the enantiomers is very small, enantiomeric differences can be detected by the magnitude of the DPV current signals. The recognition efficiencies of the three self-assembled materials are different, due to the different structures formed during the self-assembly process.     

糖基修饰大环化合物的研究进展

糖类分子作为生命过程中多种特殊受体的底物,在生物信息传递中发挥着重要的作用.近年来,已通过各种方法高效率地制备了一些新型的糖基修饰的杯芳烃、环糊精和冠醚等大环分子,它们在生物凝集素特异性识别、选择性离子识别及手性催化等方面的应用引起了研究者的广泛兴趣.本文从糖基修饰大环分子的合成、功能化及其相关应用方面综述了目前糖基功...     

外消旋化合物生物催化去对称化研究进展

手性化合物外消旋体的生物催化去对称化是目前生物与有机合成领域的重点、难点和热点,也是制备光学纯手性化合物的重要途径。我们将近年来发展起来的手性化合物生物催化去对称化的方法归纳为立体转化去对称化法、线性去对称化法、循环去对称化法、对映体收敛去对称化法和一步去对称化法五大类,对这五大类方法的原理、特点及其应用进展分别进行介绍并对其未来发展趋势进行展望。     

Bile Salts in Chiral Micellar Electrokinetic Chromatography: 2000–2020

Bile salts are naturally occurring chiral surfactants that are able to solubilize hydrophobic compounds. Because of this ability, bile salts were exploited as chiral selectors added to the background solution (BGS) in the chiral micellar electrokinetic chromatography (MEKC) of various small molecules. In this review, we aimed to examine the developments in research on chiral MEKC using bile salts as chiral selectors over the past 20 years. The review begins with a discussion of the aggregation of bile salts in chiral recognition and separation, followed by the use of single bile salts and bile salts with other chiral selectors (i.e., cyclodextrins, proteins and single-stranded DNA aptamers). Advanced techniques such as partial-filling MEKC, stacking and single-drop microextraction were considered. Potential applications to real samples, including enantiomeric impurity analysis, were also discussed.     

Synthesis of chiral cyclodextrin metal-organic framework modified with platinum on glassy carbon electrodes: Electrochemical chiral recognition of methionine enantiomers

A platinum nanoparticle-modified chiral cross-linked cyclodextrin MOF (Pt-CLMOF) was synthesized. Then, a chiral electrochemical sensor was constructed using the Pt-CLMOF nanomaterials for the recognition of methionine (Met) enantiomers and the chiral recognition mechanism was revealed by density functional theory calculations. The recognition effect of Pt-CLMOF modified electrode (Pt-CLMOF/GCE) on Met was studied by differential pulse voltammetry. The enantioselectivity coefficient (IL/ID) was 1.98. There is an acceptable linear relationship between peak current and Met enantiomer concentration in the 2–200 μM range, the detection limits of L–Met and D-Met were 0.33 and 0.60 μM which were obtained by this electrochemical sensor, respectively. The synthesized materials were successfully applied to the analysis of Met enantiomers, indicating that Pt-CLMOF materials have good application potentiality.     

Facile enantioseparation and recognition of mandelic acid and its derivatives in self‐assembly interaction with chiral ionic liquids

Mandelic acid and its derivatives are important medical intermediates in the pharmaceutical industry. Different stereoisomers exhibited distinct biological properties to human bodies. Given that, enantioselective recognition and separation of mandelic acid are of great importance. In this study, four novel different types of chiral ionic liquids bearing designed functional groups were synthesized and successful enantioselective precipitation with mandelic acid and its derivatives. That is, (R, R)‐chiral ionic liquid 1 can coprecipitated with S‐mandelic acid and its derivatives was observed. In addition, good correlation coefficient is achieved by using electrospray mass spectrum at negative ion pattern for quick analysis of the enantioselective precipitation, which could be served as a method of enantioselective recognition. The possible intermolecular interactions are established after systematical studies by NMR spectroscopy and DFT calculations.     

Asymmetric Electrochemical Transformations

The field of electrochemical synthesis has developed rapidly over the last decade and has provided alternative synthetic methods with the absence of stoichiometric amounts of chemical oxidants or reductants. Although sustainable electrosynthetic procedures have been developed, relatively few examples of highly enantioselective catalytic electrosynthesis have been reported to date. The development of general strategies for electrochemical enantiocontrol has thus proven to be a considerable challenge. This Minireview highlights the current knowledge and recent advances in the synthetic utility of electrochemical transformations for asymmetric synthesis. Specifically, three major types of catalytic enantioselective strategy in electrosynthesis are outlined, including electrochemical activation of chiral catalyst‐bound substrates, asymmetric cascade electrochemical processes, and chemically modified chiral electrodes.