多重点击反应制备拓扑结构聚合物

点击反应由Sharpless提出,是一类具有高效、可靠、高选择性等特点的反应,被广泛用于各种拓扑结构聚合物的制备.目前,应用较为广泛的点击反应主要有Cu(I)催化的叠氮/炔环加成反应(CuAAC)、Diels-Alder(D-A)反应、巯基-烯及巯基-炔点击反应和氮氧自由基偶合反应.近年来,将多种点击反应结合起来,为高效合成拓扑结构聚合物提供了新的思路.本文综述了近几年来采用多重点击反应策略联用制备拓扑结构聚合物的研究进展,并对其发展趋势进行展望.     

基于无铜点击反应的水凝胶合成

水凝胶是一种交联高分子材料, 在药物传输、传感器技术、组织工程中发挥重要作用。通过高效率和高精确度的点击反应合成水凝胶, 具有快速、模块化以及副反应少等优点, 并且能够得到近乎理想的网络结构。Cu（Ⅰ） 催化的叠氮-炔之间的环加成 （CuAAC） 反应作为点击反应的典型代表, 已广泛应用于水凝胶的制备。但由于该反应在制备水凝胶的过程中使用了Cu（Ⅰ） 催化剂, 导致产品易被金属铜盐污染, 从而使该反应在其制备领域受到限制。基于此, 无铜点击反应,如巯基-烯/炔反应、呋喃/蒽-马来酰亚胺 （MI） 修饰的 Diels-Alder 环加成 （D-A） 反应以及环张力促进的叠氮-炔环加成反应 （SPAAC） 已经被应用到水凝胶的制备以及功能化方面。本文就近年来上述无铜点击反应在水凝胶合成及功能化方面的应用进行综述, 并对其发展趋势进行展望。     

超分子拓扑高分子：合成、组装及功能

超分子拓扑高分子结合了非共价键的动态可逆特性和共价型拓扑高分子的结构特点,是一种具有广泛应用前景的高分子物种.本文从超分子拓扑高分子的合成、组装及功能等三个方面综述了该领域的最新研究进展.首先重点强调了利用直接或间接方法来构筑超支化、树枝状、星形、刷形、交联型和环形等超分子拓扑高分子的策略,其次从内部结构参数和外部环境响应两方面介绍了调控超分子自组装行为的主要方法,然后对其在生物医用材料、光电活性材料以及自修复材料等领域的潜在应用进行了较为全面的总结,最后指出了超分子拓扑高分子研究领域目前存在的关键问题和重要挑战.     

硫醇-烯/炔点击化学合成功能聚合物材料

点击化学具有反应条件温和、产率高、速率快、产物容易分离以及高度选择性等优点,成为国内外研究的热点之一。硫醇-烯/炔光化学反应作为新型高效的点击反应近年来备受关注,通过这种方法制备高性能及功能性聚合物材料也是新材料领域的前沿研究内容。本文综述了近年来硫醇-烯/炔点击化学在功能聚合物材料合成中的研究成果,详细介绍了硫醇-烯/炔点击化学的特点、优势及其反应机理,重点归纳了利用硫醇-烯/炔点击化学合成线型、超支化、交联等分子结构的功能聚合物材料的研究进展,并对由这种方法合成功能聚合物的单体特点、反应路线及产物应用进行了阐述,最后对硫醇-烯/炔点击化学的进一步应用前景做了展望。     

点击化学在生物医用高分子中的应用

点击化学的概念提出不到10年,由于其反应条件温和,反应效率高,产物后处理简单等诸多优点而备受关注。本文概述了点击化学技术应用于生物医用高分子材料的合成,主要介绍了铜催化叠氮炔环加成(copper-catalyzed azide-alkyne cycloaddition)点击化学合成和制备多功能性和智能响应性高分子用于非病毒高分子基因载体、高分子胶束药物载体和水凝胶控制释放体系等的研究和最新进展,提出了点击化学在生物医用高分子材料合成中应用的主要问题,并对其发展前景进行了展望。     

“点击”反应在制备环状聚合物中的应用

环状聚合物具有不同于线性高分子的独特性质,是一类具有应用前景的新型聚合物材料,但复杂的结构导致其合成过程复杂繁琐.＂点击＂化学由于其高效、可靠、高选择性的特点已成为拓扑高分子合成的新方法,活性自由基聚合（ATRP、RAFT和NMP）具有聚合物结构可控等特点,二者联用为环状聚合物的合成拓宽了思路.本文就近几年＂点击＂反应、＂点击＂反应与活性自由基聚合联用以及其他方法联用在环状聚合物中的应用进行综述.＂点击＂反应与这些方法的结合将在功能性环状聚合物的设计与合成中发挥积极的作用.     

巯基-烯点击化学

点击化学自2001年由Sharpless提出后,由于其高效、可靠、高选择性的特点迅速成为药物和高分子材料合成的新方法。随着对点击化学研究的深入,其反应类型在不断增多,应用范围也在不断扩大。自由基或亲核试剂引发的巯基-烯反应作为其中一种新型的点击反应具有点击化学的所有特性。本文从点击化学的概念、特征和类型出发,重点介绍了巯基-烯反应的机理和在合成功能聚合物、制备拓扑结构高分子、表面修饰以及生物药物等方面的应用,并对巯基-烯反应的最新研究成果进行综述,最后展望了巯基-烯的点击化学的发展前景。     

硫醇-烯/炔点击化学制备有机/无机杂化材料

有机/无机杂化材料因其独特、优异的结构和性能已经成为目前材料领域的研究热点,硫醇-烯/炔点击化学是近年发展起来的一类新型点击化学,以其反应条件温和、速率快、产率高、产物容易分离以及高度选择性等优点受到国内外研究者的广泛关注。本文综述了近年来硫醇-烯/炔点击化学制备有机/无机杂化材料的研究进展,重点介绍了利用硫醇-烯/炔点击化学制备硅类、碳类、金属及金属氧化物类有机/无机杂化材料,并归纳了这些有机/无机杂化材料在生物医用、环境保护、光电材料等方面的应用,最后展望了硫醇-烯/炔点击化学制备有机/无机杂化材料未来的发展方向。     

基于双锂法的炔基功能化热塑性弹性体的合成

苯乙烯-异戊二烯-苯乙烯三嵌段聚合物(SIS)是目前广泛使用的一种热塑性弹性体(TPE)材料, 建立高效、 精准、 普适的SIS功能化方法一直是提高TPE材料性能的关键. 首先, 利用双烯单体与单官能度引发剂的反应合成了双官能度的双锂引发剂; 然后采用双锂引发法, 以炔基功能化单体封端, 高效合成了α,ω-端炔基官能化SIS聚合物. 采用叔丁醇锂作为异戊二烯聚合段的调节剂, 叔丁醇钾作为苯乙烯聚合段的调节剂, 合成了低乙烯基结构含量(5.8%)、 窄分子量分布(<1.17)的SIS三嵌段聚合物; 再向SIS三嵌段聚合物中一步加入炔基官能化的1,1-二苯基乙烯(DPE)衍生物进行封端, 以高于90%的收率高效合成了α,ω-端炔基官能化SIS三嵌段模块聚合物, 借助炔基的高效点击反应, 实现了功能化及拓扑化TPE材料的制备.     

含环糊精链节的拓扑高分子

星形、超支化、树枝状、刷状等具有支化拓扑结构的高分子通常具有不同于直链结构高分子的优异性能。将有客体包合功能的环糊精与其结合构筑环糊精拓扑高分子体系,有望在分子识别、基因传输、药控释放等领域得到应用。本文根据高分子拓扑形态的不同,从星形、超支化、树枝状以及其他拓扑形态环糊精聚合物的合成及自组装构筑等方面进行了总结和评述,并在此基础上展望了基于环糊精的拓扑高分子的研究方向和发展趋势。     

Gastroprotective Effects of Biological Macromolecule: Polysaccharides

The large molecular weight of the macromolecules sets them apart from all other components. This may range from 10 000 to over a million. While the molecular weight of other plant metabolites is seldom beyond 1000. Chemically, macromolecules are made up of long chains and little “building pieces,” which are joined covalently in a variety of ways. Biological macromolecules are large, naturally occurring cellular building blocks that play a range of crucial roles in the development and existence of living organisms. Biomacromolecules are essential in the biomedical field and other related professions. They feature a variety of beneficial properties, including excellent biodegradability, suitable mechanical strength, enhanced bioavailability, etc. They also have significant biocompatibility. They display a variety of biological characteristics, such as antimalignant, antidiabetic, antibacterial, antioxidant, and immunomodulatory. The use of essential carbohydrates including alginate, chitosan, pectin, starches, carrageenan, fucoidan, etc. is common in commercial applications. Natural substance-based pharmacotherapy is now considered to be a highly promising future alternative to conventional medicine. Along with proteins and polynucleotides, polysaccharide is a vital biomacromolecule that has a crucial function in the growth and expansion of living things. A crucial element of higher plants, cell membranes of animal, and cell walls of microbes is polysaccharide. It is intimately tied to physiological processes as well. The importance of polysaccharides as a significant class of bioactive natural compounds has received more attention recently. Numerous studies have shown that natural polysaccharides contain bioactivities, which have led to the use of polysaccharides in the treatment of illness. The many parts of the research findings on the bioactivities of polysaccharides in gastro-protection are included in this paper.     

量子点:FRET的新发展

荧光共振能量转移(FRET)技术作为一种高效的光学“分子尺”,在生物大分子相互作用、免疫分析、核酸检测等方面有广泛的应用。但是许多有机染料吸收光谱较窄而发射光谱较宽,并且光漂白现象比较严重,使得FRET的应用受到了限制,因此迫切需要寻找新的能量供-受体对。由于量子点(QDs)相对于有机染料有很多优点,可以较好地应用于FRET,可能成为FRET领域发展的一个有意义的新方向,近来已引起了人们的关注。本文就FRET的原理以及量子点应用于FRET的最新进展情况做了评述。     

Role of Macromolecules in Medical Application: Challenges and Opportunities

The concept of macromolecules, which is applied to synthetic and natural polymers, allows for various contemporary polymeric materials and inventive uses. A dynamic structure of macromolecules called the extracellular matrix (ECM) maintains tissues and organs functioning. The cell therapy procedure known as wound healing involves depositing ECM components such as collagen, fibronectin, and laminin. The clinical assessment and management of wounds remain challenging despite the introduction of numerous therapeutic regimens because of their laboriously prolonged treatment requirements and complex wound-healing mechanisms using macromolecules of a specific type, such as proteins, carbohydrates, lipids, and nucleic acids. Additionally, proteins affect the wound site's mechanical characteristics, such as tensile strength, elasticity, and permeability, which impact the effectiveness and success of wound healing. The main goal of this article is to give a current overview of how therapeutic alternatives have evolved using cutting-edge innovative techniques for the healing and treatment of wounds. In this article, we have covered different types of macromolecules, how diet affects the wound, what causes wounds, and how macromolecules can help, and how to treat wounds.     

大分子自组装特性计算机模拟的研究

包括表面活性剂在内的大分子在溶液中可以形成聚集体的特性,使其在工业和生活领域得到广泛的应用.研究其自组装特性对生命体内两亲大分子的聚集行为以及生物矿化和仿生合成的研究均具有重要意义.本文分别从分子热力学和分子动力学的角度,对以表面活性剂为主的大分子自组装特性计算机模拟的研究进展进行了综述,分析并展望了对大分子溶液体系理论模拟研究的发展前景。     

Models for the Dynamics of Hyperbranched Macromolecules

Summary: We focus on the motion of hyperbranched macromolecules in solution, paying particular attention to the relation between underlying topological structure and dynamics; we consider especially the mechanical moduli. Under the prominent representatives of hyperbranched polymers are both regular structures (such as the dendrimers) as well as disordered structures (such as irregular Cayley-trees). Evidently, batch-prepared hyperbranched macromolecules are closer to the latter. In order to theoretically determine their mechanical moduli we employ the method of generalized Gaussian structures (GGS), which allows us to study the situation including or excluding the hydrodynamic interactions (HI). Disordered hyperbranched structures display a complex dynamics; here we recall several analytical and numerical schemes for determining it and compare our theoretical results to the experimental data.     

Click chemistry strategies for the accelerated synthesis of functional macromolecules

Click chemistry is one of the most powerful strategies for constructing polymeric soft materials with precise control over architecture and functionality. In this review, we provide a comprehensive summary of the state-of-the art for synthesizing functional polymers and their expanding range of applications. The synthetic and mechanistic aspects are discussed for key reactions that fulfill “click” requirements and their applications in construction of macromolecules with linear, branched, and other complex architectures are described.     

A Review on Graphene Oxide Two-dimensional Macromolecules: from Single Molecules to Macro-assembly

Graphene oxide(GO), which consists of two-dimensional(2 D) sp² carbon hexagonal networks and oxygen-contained functional groups, has laid the foundation of mass production and applications of graphene materials. Made by chemical oxidation of graphite, GO is highly dispersible or even solubilized in water and polar organic solvents, which resolves the hard problem of graphene processing and opens a door to wet-processing of graphene. Despite its defects, GO is easy to functionalize, dope, punch holes, cut into pieces, conduct chemical reduction, form lyotropic liquid crystal, and assemble into macroscopic materials with tunable structures and properties as a living building block. GO sheet has been viewed as a single molecule, a particle, as well as a soft polymer material. An overview on GO as a 2 D macromolecule is essential for studying its intrinsic properties and guiding the development of relevant subjects. This review mainly focuses on recent advances of GO sheets, from single macromolecular behavior to macro-assembled graphene material properties. The first part of this review offers a brief introduction to the synthesis of GO molecules. Then the chemical structure and physical properties of GO are presented, as well as its polarity in solvent and rheology behavior. Several key parameters governing the ultimate stability of GO colloidal behavior, including size, p H and the presence of cation in aqueous dispersions, are highlighted. Furthermore, the discovery of GO liquid crystal and functionalization of GO molecules have built solid new foundations of preparing highly ordered, architecture-tunable, macro-assembled graphene materials, including 1 D graphene fibers, 2 D graphene films, and 3 D graphene architectures. The GO-based composites are also viewed and the interactions between these target materials and GO are carefully discussed. Finally, an outlook is provided in this field, where GO is regarded as macromolecules, pointing out the challenges and opportunities that exist in the field. We hope that this review will be beneficial to the understanding of GO in terms of chemical structure,molecular properties, macro-assembly and potential applications, and encourage further development to extend its investigations from basic research to practical applications.     

Chitosan Macromolecules on a Substrate: Deposition from Solutions in sc CO2 and Reorganisation in Vapours

Specially pretreated chitosan macromolecules possess limited solubility in supercritical carbon dioxide. When deposited on mica substrate from such solutions they adopt somewhat extended conformation. The adsorbed macromolecules become mobile on the interface when exposed to water vapour as revealed by environmental scanning force microscopy. During the exposure in the presence of coadsorbed water layer the chitosan strands demonstrate slight tendency to adopt more compact but still two-dimensional conformation on the substrate.     

Polymer-modification of an anti-cancer drug: effects on hydrodynamic properties

Coupling of a hydrophobic pharmaceutical agents with the hydrophilic poly(ethylene oxide) chain can make the drug water soluble which is necessary for some applications. The modification of the polymer chain results in a different solution behaviour of the macromolecules compared with the unmodified polymer. There are strong indications that shape and rigidity of the modified molecule differ significantly from the simple chain. Some results from measurements of the self-diffusion coefficient and solution viscosity are discussed. The results are important for further engineering on active drug systems.     

Dynamics of hyperbranched polymers and dendrimers: theoretical models

Chemical reactions depend in many ways on the dynamics of the underlying reactants, and an important aspect is the distance covered by the reactants before the reaction act occurs. Hence, even diffusion-limited reactions between point particles in confined geometries and in low-dimensional systems display decay forms which are very different from those obtained from simple chemical kinetics. Clearly, even more complex decay forms hold for macromolecules, given their internal degrees of freedom. Here we discuss how the dynamics of macromolecules in solution relates to their topological structure and focus on the motion of macromolecular segments (monomers) under the influence of external fields. After a general survey of the method of generalized Gaussian structures (GGS) we recall the wealth of forms which are observed, depending on the topology and on the microscopic dynamics involved. Paradigmatic are the findings for the class of hyperbranched macromolecules; to these belong the dendrimers. While the dendrimers do not show a typical scaling behavior, as found, say, for linear chains, the situation is different for particular classes of regular hyperbranched polymers which are fractal. We end by discussing their pattern of motion in the GGS-Rouse-Zimm picture.