分子印迹电化学传感器

分子印迹电化学传感器能够选择性识别并检测特定目标化合物,因其设计简单、灵敏度高、价格低廉、携带方便、易于微型化和自动化等优点,在临床诊断、环境监测、食品分析等方面越来越受到人们的关注.本文作者主要论述分子印迹技术与电化学技术相结合构建分子印迹电化学传感器,包括分子印迹电化学传感器的种类,以及电化学方法制备分子印迹聚合物膜的常用单体等.对分子印迹电化学传感器领域新出现的分子印迹聚合物-纳米材料复合物以及纳米结构分子印迹聚合物也一并做了评述.     

分子印迹技术研究进展

分子印迹技术是制备对特定目标分子具有特异性识别能力的高分子材料的技术,所制备的高分子材料被称为分子印迹聚合物.分子印迹聚合物因具有预定性、识别性和实用性三大优点已广泛应用于分离、模拟抗体与受体、催化剂以及仿生传感器等方面和领域,显示出了广泛的应用前景.作者对分子印迹技术的发展历史、基本原理、分类、应用现状以及一些新的研究热点进行了综述.     

分子印迹聚合物的制备及其传感器应用研究

分子印迹技术于近十年内得到了飞速的发展,已经成为当前研究的热点之一.本文主要介绍了分子印迹聚合物的原理以及一些常用制备方法.分子印迹聚合物的一个重要应用是在化学传感器中作为识别元件,研制稳定、低成本的分子印迹传感器.分子印迹聚合物在传感器领域的应用是分子印迹技术的一个重要方面,本文综述了分子印迹聚合物在化学传感器方面的应用研究现状,并对分子印迹传感器的发展前景进行了评述.     

分子印迹技术研究进展

分子印迹是制备具有分子特异识别功能聚合物的一种技术。本文从分子印迹聚合物的识别机理、分子印迹聚合制备条件和制备技术三个方面综述了分子印迹的研究进展,最后展望了分子印迹发展前景。引用文献66篇。     

分子印迹技术在蛋白质识别中的应用进展

分子印迹技术是一种制备具有分子识别能力的聚合物的有效技术,已经广泛应用于制备对小分子具有选择性的分子印迹聚合物,但制备能够特异性识别生物大分子--蛋白质的分子印迹聚合物的研究仍然具有挑战性。本文讨论了制备蛋白质分子印迹聚合物的难点,评述了目前印迹蛋白质的方法及各自的优缺点,展望了蛋白质印迹技术的发展趋势。     

分子印迹技术在毛细管电色谱中的应用

分子印迹技术是制备具有分子识别功能聚合物，即分子印迹聚合物（MIPs)的一种新技术；毛细管电色谱（CEC）是一个具有发展前途的色谱新技术。将分子印迹技术和毛细管电色谱两种新技术相结合，优势互补，具有极大的发展潜力。本文对分子印迹技术在毛细管电色谱中的应用，以及各类MIPs-CEC毛细管柱的制备方法进行了较为全面的综述，引用文献52篇。     

环丙沙星分子印迹聚合物的合成及识别性能研究

采用分子印迹技术合成了以环丙沙星为印迹分子,以甲基丙烯酸和4-乙烯基吡啶同时为功能单体的分子印迹聚合物。运用平衡结合实验研究了印迹聚合物的吸附特性和选择识别能力。Scatchard分析表明,在所研究的浓度范围内,分子印迹聚合物中形成了两类不同的结合位点。底物选择实验表明,这种聚合物对环丙沙星呈现高的选择结合能力。     

分子印迹-仿生传感器的研究进展

分子印迹技术是制备具有选择性分子识别能力聚合物(分子印迹聚合物)的新兴化学合成技术。分子印迹聚合物的一个重要应用是在生物传感器中取代生物分子作为识别元件,研制耐受性强、低成本的分子印迹仿生传感器。综述了分子印迹技术的基本原理及其在仿生传感器方面的应用研究现状,并对分子印迹仿生传感器的发展前景进行了评述。引用文献24篇。     

疾病标记物分子印迹技术在分离传感分析中的应用

疾病标记物分子印迹聚合物以疾病标记物为模板分子,可实现低浓度和基底复杂的疾病标记物的高效分离和富集。以疾病标记物分子印迹聚合物为敏感元件构建的传感器,可用于对威胁人类健康的高发病率和高死亡率疾病进行筛查和诊断。本文介绍了分子印迹技术的原理和方法,重点介绍了疾病标记物分子印迹中常用的印迹方法、印迹材料、以及疾病标记物分子印迹聚合物在疾病标记物分离及传感中的应用。     

分子印迹聚合物微球的制备及应用研究进展

球形分子印迹聚合物具有制备简单、使用方便；分子识别效率高且便于功能设计等优点，近年来成为分子印迹技术领域研究的热点之一。对球形分子印迹聚合物微球的制备及其应用研究进展作了较为详细的介绍。     

Artificial enzymes with thiazolium and imidazolium coenzyme mimics

Hydrophobic thiazolium and imidazolium coenzyme mimics in the presence of modified-polyethylenimine enzyme mimics catalyze the benzoin condensation 2300-3300 times faster than the coenzyme mimics alone. Polycationic enzyme mimics provide not only a hydrophobic binding domain for coenzyme and substrate, but also electrostatic stabilization of anionic species that arise along the reaction pathway of the benzoin condensation.     

Enzyme Mimics: Advances and Applications

Enzyme mimics or artificial enzymes are a class of catalysts that have been actively pursued for decades and have heralded much interest as potentially viable alternatives to natural enzymes. Aside from having catalytic activities similar to their natural counterparts, enzyme mimics have the desired advantages of tunable structures and catalytic efficiencies, excellent tolerance to experimental conditions, lower cost, and purely synthetic routes to their preparation. Although still in the midst of development, impressive advances have already been made. Enzyme mimics have shown immense potential in the catalysis of a wide range of chemical and biological reactions, the development of chemical and biological sensing and anti‐biofouling systems, and the production of pharmaceuticals and clean fuels. This Review concerns the development of various types of enzyme mimics, namely polymeric and dendrimeric, supramolecular, nanoparticulate and proteinic enzyme mimics, with an emphasis on their synthesis, catalytic properties and technical applications. It provides an introduction to enzyme mimics and a comprehensive summary of the advances and current standings of their applications, and seeks to inspire researchers to perfect the design and synthesis of enzyme mimics and to tailor their functionality for a much wider range of applications.     

SOD模拟及其抗氧化和抗炎症功能的研究进展*

超氧化物歧化酶(superoxide dismutase, 简称SOD) 作为生物体内超氧离子自由基的清除剂, 具备有效抗氧化、抗炎症、抗衰老之功效, 并用于临床, 其化学模拟引起了人们的广泛研究兴趣。本文将简要介绍近年来SOD 人工模拟酶及其生物医学活性研究所取得的重要进展, 特别是Cu,Zn-SOD 模拟物结构与功能的相互关系、Mn-SOD 模拟物的生物活性及其医学应用。     

小分子α-螺旋模拟物

本文综述了近年来小分子α-螺旋模拟物的研究进展,介绍了α-螺旋结构在蛋白质相互作用中的重要性以及小分子α-螺旋模拟物在药物化学领域的应用。概括了联苯结构、酰胺结构、哒嗪结构及其他杂环结构小分子α-螺旋模拟物的最新进展,并介绍了小分子α-螺旋模拟物在蛋白质相互作用抑制剂方面的应用。总结了目前已有的小分子α-螺旋模拟物存在的一些不足之处,并对今后该研究领域的发展方向进行了展望。     

Recent Advances on Nanozyme-based Electrochemical Biosensors

Nanozymes are nanomaterials with enzyme-like catalytic activities. The unique features of nanozymes (such as high stability, low cost, large surface area for bioconjugation, ease of storage, and multi-functionalities) offer unprecedented opportunities for designing electrochemical biosensors. Recent years have witnessed the rapid development of nanozyme-based electrochemical biosensors. To highlight these achievements, this review first discusses the representative nanozymes including peroxidase mimics, oxidase mimics, hydrolase mimics, and superoxide dismutase mimics used in electrochemical biosensors. Then, it summarizes the bioanalytical applications for the detection of various analytes. Finally, current challenges and future research directions are summarized.     

Functional Cellular Mimics for the Spatiotemporal Control of Multiple Enzymatic Cascade Reactions

Next‐generation therapeutic approaches are expected to rely on the engineering of biomimetic cellular systems that can mimic specific cellular functions. Herein, we demonstrate a highly effective route for constructing structural and functional eukaryotic cell mimics by loading pH‐sensitive polymersomes as membrane‐associated and free‐floating organelle mimics inside the multifunctional cell membrane. Metabolism mimicry has been validated by performing successive enzymatic cascade reactions spatially separated at specific sites of cell mimics in the presence and absence of extracellular organelle mimics. These enzymatic reactions take place in a highly controllable, reproducible, efficient, and successive manner. Our biomimetic approach to material design for establishing functional principles brings considerable enrichment to the fields of biomedicine, biocatalysis, biotechnology, and systems biology.     

Mimics of peptide turn backbone and side-chain geometry by a general approach for modifying azabicyclo[5.3.0]alkanone amino acids

Peptide mimics with constrained backbone and side-chain geometry are important tools for studying structure activity relationships of biologically active candidates. A general method for creating β-turn mimics possessing side-chain diversity has been developed featuring diastereoselective S(N)1 displacements of an iodide precursor. In particular, 6-iodo-pyrroloazepin-2-one amino ester 10 has served as a common precursor in reactions with a variety of alcohol, phenol, nitrate, and azide nucleophiles to provide an array of constrained peptide mimics.     

Structural and energetic effects in the molecular recognition of protonated peptidomimetic bases by 18-crown-6

Absolute 18-crown-6 (18C6) affinities of nine protonated peptidomimetic bases are determined using guided ion beam tandem mass spectrometry techniques. The bases (B) included in this work are mimics for the n-terminal amino group and the side chains of the basic amino acids, i.e., the favorable sites for binding of 18C6 to peptides and proteins. Isopropylamine is chosen as a mimic for the n-terminal amino group, imidazole and 4-methylimidazole are chosen as mimics for the side chain of histidine (His), 1-methylguanidine is chosen as a mimic for the side chain of arginine (Arg), and several primary amines including methylamine, ethylamine, n-propylamine, n-butylamine, and 1,5-diamino pentane as mimics for the side chain of lysine (Lys). Theoretical electronic structure calculations are performed to determine stable geometries and energetics for neutral and protonated 18C6 and the peptidomimetic bases, as well as the proton bound complexes comprised of these species, (B)H(+)(18C6). The measured 18C6 binding affinities of the Lys side chain mimics are larger than the measured binding affinities of the mimics for Arg and His. These results suggest that the Lys side chains should be the preferred binding sites for 18C6 complexation to peptides and proteins. Present results also suggest that competition between Arg or His and Lys for 18C6 is not significant. The mimic for the n-terminal amino group exhibits a measured binding affinity for 18C6 that is similar to or greater than that of the Lys side chain mimics. However, theory suggests that binding to n-terminal amino group mimic is weaker than that to all of the Lys mimics. These results suggest that the n-terminal amino group may compete with the Lys side chains for 18C6 complexation.     

以透明质酸为骨架的新型谷胱甘肽过氧化物酶(GPX)模拟酶的制备及性质研究

用修饰法合成以透明质酸为骨架的两种新型GPX模拟酶: 硒化透明质酸SeHA及碲化透明质酸TeHA. 用红外光谱和核磁共振波谱对模拟酶的结构进行研究, 证明其修饰位点位于透明质酸的N-乙酰氨基葡萄糖的—CH2OH. 用二硫代双硝基苯甲酸(DTNB)法测定模拟酶的硒含量为1.2%. 通过模拟酶对3种不同底物过氧化氢(H2O2)、过氧化氢正丁烷(t-BuOOH)和过氧化氢异丙苯(CuOOH)的催化活性的研究结果表明CuOOH为该反应的最佳底物. 研究模拟酶催化谷胱甘肽(GSH)还原3种过氧化物的动力学发现, 反应速率与底物浓度的双倒数曲线均为平行的直线, 说明模拟酶反应的动力学机制与天然GPX相同, 为乒乓机制. 用2,4-二叔丁基甲基苯酚(BHT)法证明了该催化反应为非自由基机理, 且模拟酶不易被碘乙酸抑制.     

A NMR and computational study of Smac mimics targeting both the BIR2 and BIR3 domains in XIAP protein

In this paper we report an extensive NMR analysis of small ligands (Smac mimics) complexed with different constructs of XIAP. The mimics-binding site of XIAP is known as the BIR3 domain - primary, and the linker BIR2 region - secondary site. Interactions between the BIR3 domain and Smac mimics have been extensively studied by X-ray but, as of today, there are scarce data about the interaction between BIR2, or the whole linker-BIR2-BIR3 construct, and Smac mimics. In order to characterize our Smac mimics, we performed a STD NMR study between our 4-substituted, 1-aza-2-oxobicyclo[5.3.0]decane scaffold-based molecules and three different XIAP fragments: single BIR2 and BIR3 domains, and bifunctional linker-BIR2-BIR3. The results were integrated with docking calculations and molecular dynamics simulations. NMR data, which are consistent with biological tests, indicated that the two BIR subunits interact differently with our Smac mimics and suggest that the ligands enter into more intimate contact with the linker-BIR2-BIR3. In conclusion, we observe that the SMAC mimics showed with the construct linker-BIR2-BIR3 a series of NOE contacts that were not observed in the mono-domain ligand:BIR2 or :BIR3 complexes. So, in agreement with the computational models we believe that the linker moieties of the binding site play a key role in the stability of the protein complex.