四棱草环肽C和D的ESIMS-MS分析

利用低能量碰撞诱导解离(CID)技术对四棱草环肽C和四棱草环肽D的电喷雾电离串联质谱(ESIMS-MS)进行了研究.ESIMS可以确定环肽的分子量,根据多级质谱中逐次失去氨基酸残基的碎片离子可以确定环肽中氨基酸残基的连接顺序.氨基酸残基主要从酰氨键C端断裂失去,有时亦会从N端断裂失去氨基酸残基.     

环肽的合成研究进展

对环肽进行了分类, 并对具代表性的经典型、DKP (Diketopiperazine, 哌嗪二酮)型、醚桥型、烯桥型、单硫及多硫醚型、刚性桥型、仲(叔)胺型、Mannich碱型、联苯型及Freidinger型环肽的合成方法逐一进行了描述.     

二茂铁类环肽的合成与分子识别研究

设计并合成了两个系列含二茂铁单元的1+1型和2+2型类环肽,用循环伏安法研究了1+1型二茂铁类环肽与含氧负离子和卤素负离子的包合作用.结果表明,类环肽能很好地识别这些常见的负离子.¹HNMR研究发现,类环肽对负离子的识别作用主要是通过类环肽酰胺键中氢与客体负离子形成分子间氢键实现的.     

新型含二硫键的环肽的合成

本实验设计从Boc-Glu-OH,Boc-Asp-OH的两个羧基出发,最后通过I2氧化两个半胱氨酸的巯基生成二硫键,得到一类新型含二硫键的环肽,该环肽通过1H NMR,MS等确定了其结构.     

骨架环肽的化学合成研究进展

骨架环肽是线性肽的C端和N端通过酰胺键进行首尾环合而形成的环状分子.研究者从细菌、真菌、植物和动物中发现了大量的骨架环肽.这种首尾环合的结构,使得骨架环肽具有很好的酶稳定性、热稳定性和化学稳定性,部分骨架环肽具有细胞膜通透性.骨架环肽分子异常的稳定性和高效的生物活性,使得其成为目前药物领域的研究热点.为了更深入地研究它们的结构和功能,骨架环肽的制备成为一个重要问题.概述了化学合成骨架环肽的一些方法,包括:(1)固相环合策略;(2)液相环合策略;(3)分子内自然化学连接策略,并对这些方法的特点和效率进行了讨论比较.     

细胞穿透环肽

细胞穿透环肽能够穿透细胞膜,特异性地靶向细胞内靶标,并具有较好的体内稳定性,因而具备很好的成药性,并受到研究者越来越多的关注.目前,主要有两种方式获得细胞穿透环肽,即从天然产物中获得和对已有的环肽或线性肽进行化学修饰.本文主要对上述两方面进行简要综述,重点介绍两类细胞穿透环肽天然产物以及通过化学修饰方法得到细胞穿透环肽的策略,并探讨细胞穿透环肽的结构-活性关系及其细胞穿透机理.     

环肽纳米管的应用研究

环肽分子通过主链骨架中C=O和N-H形成分子间网络氢键,以β-片层反平行方式堆积可形成中空管状结构。通过控制环肽的结构和尺寸,或修饰具有不同功能的基团,可获得多种结构和性能的肽纳米管。本文综述了环肽分子自组装成纳米管的应用研究成果。首先介绍了带合适疏水性侧链的环肽纳米管在模拟生物跨膜离子通道方面的实验和理论研究进展,重点论及环肽纳米管的结构、极性和侧链的疏水性等对离子通道传输行为的影响以及分子动力学（MD）模拟研究水通道的进展。进而介绍了环肽纳米管用作生物传感器模板,与功能性（如电性、光学性和磁性）纳米材料合成制备生物传感器的实验研究成果,接着介绍了环肽纳米管作为药物或药物载体潜在的应用前景,特别是在某些抗菌和抗感染药物开发设计中的应用以及环肽在不同极性的环境中自组装过程微观机制的MD模拟研究,最后介绍了环肽纳米管作为模板,制备磁性、电性纳米材料方面的实验和理论研究进展。     

石竹科植物环肽研究进展

本文对石竹科植物环肽的研究概况进行了综述。     

胸腺素α1的C端活性片段环肽类似物的合成与生物活性评价

用硫酯法合成了一系列Tα1的C端活性片段的环肽类似物, 以提高其活性与稳定性. 用促淋巴细胞增殖法测定了环肽类似物的生物活性, 结果表明, 环肽类似物较好地保留或提高了促淋巴细胞增殖活性.     

络合Ca2+的Au/巯基环肽自组装单层膜的交流阻抗研究

环肽在自然界中分布广泛,植物、动物、低等海洋生物、微生物、细菌、病菌等都含有微量的环肽。这些环肽的含量虽然低,但其中不少具有明显的生理活性,因此受到国内外许多化学家、生物学家和药学家的重视[1-2]。自组装单分子层膜(Self-Assembled Monolayer,SAMs)是固液界面通过化     

正丁胺对激光染料荧光谱影响的研究

用正丁胺作为碳源,采用射频辉光放电制备碳膜,选用激光染料R6G和聚乙二醇混合液作为蒸气源,采用单源热蒸发,在蒸发室与染料同时沉积得到混合膜,用拉曼光谱和红外光谱分析了碳膜的结构和键合方式,分析表明:碳膜中存在胺基团和氢原子.混合膜的荧光谱测量结果表明,认为正丁胺对染料荧光谱的影响是因为胺基和氢原子的存在.     

THE EFFECT OF CLAY DISPERSION ON THE CRYSTALLIZATION AND MORPHOLOGY OF POLYPROPYLENE／CLAY COMPOSITES

PP/clay composites with different dispersions, namely, exfoliated dispersion, intercalated dispersion and agglomerates and particle-like dispersion, were prepared by direct melt intercalation or compounding. The effect of clay dispersion on the crystallization and morphology of PP was investigated via PLM, SAXS and DSC. Experimental results show that exfoliated clay layers are much more efficient than intercalated clay and agglomerates of clay in serving as nucleation agent due to the nano-scale dispersion of clay, resulting in a dramatic decrease in crystal size (lamellar thickness and spherulites) and an increase of crystallization temperature and crystallization rate. On the other hand, a decrease of melting temperature and crystallinity was also observed in PP/clay composites with exfoliated dispersion, due to the strong interaction between PP and clay. Compared with exfoliated clay layers, the intercalated clay layers have a less important effect on the crystallization and crystal morphology. No effect is seen for samples with agglomerates and particle-like dispersion, in regard to melting temperature, crystallization temperature, crystal thickness and crystallinity.     

Residue‐centric modeling and design of saccharide and glycoconjugate structures

The RosettaCarbohydrate framework is a new tool for modeling a wide variety of saccharide and glycoconjugate structures. This report describes the development of the framework and highlights its applications. The framework integrates with established protocols within the Rosetta modeling and design suite, and it handles the vast complexity and variety of carbohydrate molecules, including branching and sugar modifications. To address challenges of sampling and scoring, RosettaCarbohydrate can sample glycosidic bonds, side‐chain conformations, and ring forms, and it utilizes a glycan‐specific term within its scoring function. Rosetta can work with standard PDB, GLYCAM, and GlycoWorkbench (.gws ) file formats. Saccharide residue‐specific chemical information is stored internally, permitting glycoengineering and design. Carbohydrate‐specific applications described herein include virtual glycosylation, loop‐modeling of carbohydrates, and docking of glyco‐ligands to antibodies. Benchmarking data are presented and compared to other studies, demonstrating Rosetta's ability to predict glyco‐ligand binding. The framework expands the tools available to glycoscientists and engineers. © 2016 Wiley Periodicals, Inc.     

Tautomeric and conformational isomerism of natural hydroxyanthraquinones

Natural 1,5-di-, 1,4,5-tri-, and 1,4,5,8-tetrahydroxyanthraquinones and their anions and metal complexes were shown to be equilibrium mixtures of tautomers and conformers using quantum-chemical and correlation analysis of elecronic absorption spectra. Solvent effects, ionization, complexation, and the introduction and substitution of substituents were accompanied by shifts of tautomeric and conformational equilibria that determine the color of the compounds. __________ Translated from Khimiya Prirodnykh Soedinenii, No. 3, pp. 224–229, May–June, 2006.     

Selecting polymers for medical devices based on thermal analytical methods

This biomaterials overview for selecting polymers for medical devices focuses on polymer materials, properties and performance. An improved understanding of thermoplastics and thermoset properties is accomplished by thermal analysis for device applications. The medical applications and requirements as well as the oxidative and mechanical stability of currently used polymers in devices are discussed. The tools used to aid the ranking of the thermoplastics and thermosets are differential scanning calorimetry (DSC), thermogravimetry (TG), thermal mechanical analysis (TMA) and dynamic mechanical analysis (DMA) as well as a number of key ASTM polymer tests. This paper will spotlight the thermal and mechanical characterization of the bio-compatible polymers e.g., olefins, nylon, polyacetals, polyvinyl chloride and polyesters.     

乙烷部分氧化制C2氧化物用Fe－Al－P－O催化剂的研究Ⅰ．超细Fe－Al－P－O催化剂的制备与表征

 用溶胶－凝胶法制备了超细Fe－Al－P－O催化剂，并用DTA－TG，BET，TEM，XRD，TPR和IR等技术研究了催化剂的微观组成和结构及其晶格氧活性，探讨了催化剂的制备工艺，考察了溶胶－凝胶的形成机理、凝胶干燥及焙烧条件对催化剂微观组成和结构的影响规律．结果表明，Fe－Al－P－O催化剂呈非晶态，是具有均匀分布的超细粒子（10nm），其比表面积大（238m2／g），晶格氧活性高．FePO4和AlPO4间隔分布在催化剂表面，形成Lewis碱位（P＝O，P－O－Fe）和Lewis酸位（Fe3＋，Al3＋）．     

Recent progress in MXene and graphene based nanocomposites for microwave absorption and electromagnetic interference shielding

There is widespread use of telecommunication and microwave technology in modern society, and raised the electromagnetic interference (EMI) issue to alarming situation due to apprehensive demand and growth of 5G technology undesirably disturbing the human health. The two dimensional (2D) materials including graphene and MXenes are already been used for variety of electronic devices due to their exceptional electrical, mechanical, optical, chemical, and thermal properties. MXene is composed of metal carbides, in which mainly metals are the building blocks for dielectrics, semiconductors, or semimetals. However, the strong interfaces with electromagnetic waves (EM) are variable from terahertz (THz) to gigahertz (GHz) frequency levels and are widely used in EMI and Microwave absorption (MA) for mobile networks and communication technologies. The use of different organic materials with metal, organic, inorganic fillers, polymers nanocomposite and MXene as a novel material has been studied to address the recent advancement and challenges in the microwave absorption mechanism of 2D materials and their nanocomposites. In this concern, various techniques and materials has been reported for the improvement of shielding effectiveness (SE), and theoretical aspects of EMI shielding performance, as well stability of 2D materials particularly MXene, graphene and its nanocomposites. Consequently, various materials including polymers, conducting polymers, and metal–organic frameworks (MOF) have also been discussed by introducing various strategies for improved MA and control of EMI shieling. Here in this comprehensive review, we summarized the recent developments on material synthesis and fabrication of MXene based nanocomposites for EMI shielding and MA. This research work is a comprehensive review majorly focuses on the fundamentals of EMI/MA.  The recent developments and challenges of the MXene and graphene based various structures with different polymeric composites are described in a broader perspective.     

Determination and study on residue and dissipation of benazolin-ethyl and quizalofop-p-ethyl in rape and soil

A QuEChERS (quick, easy, cheap, effective, rugged, and safe) method for the determination of benazolin-ethyl and quizalofop-p-ethyl in rape and soil by high-performance liquid chromatography-tandem mass spectrometry has been developed in this study. The residue and dissipation of benazolin-ethyl and quizalofop-p-ethyl in rape and soil were determined with the developed method. The half-lives of benazolin-ethyl in rape straw and soil were 3.7–5.1 days and 14.3–26.3 days, respectively. The half-lives of quizalofop-p-ethyl in rape straw and soil were 5.0-6.1 days and 0.3–9.7 days, respectively. The residue of benazolin-ethyl and quizalofop-p-ethyl in rapeseed and soil were below the detection limit (i.e., 0.5?mg?kg^?1, the maximum residue level of European Union for quizalofop-p-ethyl).     

Carbenes and Nitrenes: Recent Developments in Fundamental Chemistry

Carbenes and nitrenes can exist in both singlet and triplet states, sometimes equally stable and interconverting either thermally or photochemically. Many carbene and nitrene reactions proceed via tunneling at low temperatures. Numerous singlet and triplet states have been characterized spectroscopically, and a detailed understanding of the chemical and physical properties of carbenes and nitrenes is emerging. There has been significant progress in the direct observation of carbenes, nitrenes, and many other reactive intermediates in recent years through the application of matrix photolysis and flash vacuum pyrolysis linked with matrix isolation at cryogenic temperatures. Our understanding of singlet and triplet states has improved through the interplay of spectroscopy and computations. Bistable carbenes and nitrenes as well as many examples of tunneling have been discovered and numerous rearrangements and fragmentations have been documented. The correlation of the zero‐field splitting parameter D with calculated spin densities on nitrenes and carbenes is discussed. This Minireview gives an overview of some of these developments.     

Two-dimensional Metal-Organic Frameworks and Derivatives for Electrocatalysis

The most important topics in the world today are environmental and resource issues. The development of green and clean energy is still one of the great challenges of social sustainable development. Two-dimensional(2D) metal-organic frameworks(MOFs) and derivatives have exceptional potential as high-efficiency electrocatalysts for clean energy technologies. This review summarizes various synthesis strategies and applications of 2D MOFs and derivatives in electrocatalysis. Firstly, we will outline the advantages and uniqueness of 2D MOFs and derivatives, as well as their applicable areas. Secondly, the synthetic strategies of 2D MOFs and derivatives are briefly classified. Each category is summarized and we list classic representative fabrication methods, including specific fabrication methods and mechanisms, corresponding structural characteristics, and insights into the advantages and limitations of the synthesis method. Thirdly, we separately classify and summarize the application of 2D MOFs and derivatives in electrocatalysis, including electrocatalytic water splitting, oxygen reduction reaction(ORR), CO₂ reduction reaction(CO₂RR), and other electrocatalytic applications. Finally, the development prospects and existing challenges to 2D MOFs and derivatives are discussed.