材料科学中的点击化学

近年来,点击(click)化学反应以其高产率、高选择性以及对各种官能团和反应条件优异的耐受性成为材料科学家们手中有力的研究工具.本文综述了点击化学的概念、特点、反应机理及应用.重点介绍了点击化学反应在聚合物、表面修饰、纳米材料方面的研究进展,并分析了点击化学目前存在的不足及今后发展趋势.     

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。     

点击化学简介

点击化学是2001年诺贝尔化学奖获得者美国化学家Sharpless提出的一种快速合成大量化合物的新方法。介绍了点击化学的概念及其主要反应类型,综述了点击化学作为一种新的合成方法在药物开发、聚合物合成和表面修饰等领域的应用,并对其发展前景进行了展望。     

微波促进的点击化学

自2001年Sharpless等提出点击化学概念以来,Cu(I)催化的炔与叠氮之间的1,3-偶极环加成反应(Cue-AAC)已经成为点击化学最成功的范例.Cue-AAC反应由于其良好的立体选择性、模块性以及官能团耐受性等特点迅速成为许多研究领域,例如药物化学、材料科学等领域中的有力工具.同时,微波加热作为一种高效、绿色合成技术已越来越受到人们的重视,相对于传统加热方式,它能大幅缩短反应时间,提高产率和纯度.综述了近十年来利用微波加热与点击化学相结合的策略在合成生物大分子及小分子化合物库中的应用,并对其发展前景作了展望.     

点击化学在拓扑结构聚合物合成中的应用

首先对点击化学进行简述,介绍了点击化学的概况、特征及主要反应类型;随后,重点介绍点击化学在拓扑结构聚合物(包括线形、刷形、星形、环状及树枝状大分子等)合成中的应用,并对这一领域的研究进展进行综述;最后,提出目前点击化学存在的一些问题,并对其发展前景进行展望.     

Diels-Alder环加成点击反应

点击反应由于其高效、高选择性以及可靠等特点迅速成为药物、聚合物以及功能材料等合成的新方法.随着对点击反应研究的深入,其反应类型在不断增多,应用范围也在不断扩大.Diels-Alder(D-A)反应作为一种重要的点击反应,不仅具有简便高效、原料易得以及反应条件温和等优点,而且克服了叠氮/炔间Cu(I)催化的Cue-AAC反应引起的金属污染等缺点,为功能性材料的制备提供更可行的途径.从D-A反应的概念、特征和类型出发,重点介绍了它在合成制备树状分子、功能性聚合物以及表面修饰等方面的应用,并展望了它的发展前景.     

点击化学及其应用

点击化学反应选用易得原料,通过可靠、高效化学反应快速合成大量新化合物,且反应条件温和、产物收率高和不需要专门的分离提纯。本文介绍了点击化学（click chemistry）的一些基本概念,综述了点击化学作为一种新的合成方法在药物中的先导化合物库、糖类化合物、天然化合物、生物大分子和高分子中聚合物上的应用,并对其发展前景进行了展望。     

点击化学及其在化学传感器中的应用进展

本文对点击化学的概念、点击反应分类、化学及生物传感器中点击化学的作用类型及近几年来点击化学在化学传感器中的应用进展作了较为详细的介绍,并展望了点击化学在传感器领域应用的发展趋势.     

利用点击化学反应修饰聚氨酯

合成了2,2-丙炔基-1,3-丙二醇(DPPD),将其作为扩链剂引入聚氨酯(PU)主链分子中,获得了一种主链带有炔基的可降解聚氨酯材料,并通过叠氮基团与炔基间的点击化学反应,将模型分子引入到聚氨酯分子链上.1H NMR图谱中δ2.03的峰及红外图谱中2138 cm-1处的峰证实炔基引入了聚氨酯分子链;1H NMR图谱δ7.91处的峰表明采用点击化学方法将苄基叠氮分子引入了聚氨酯分子主链.当扩链系数分别为1,0.7和1[70%DPPD+30%1,3-丙二醇(PDO)]时,最终产物中炔基含量分别为0.396,0.235和0.197 mmol/g.细胞毒性实验结果表明,炔基的引入对细胞活性没有影响.     

点击化学和生物正交化学中的化学基础概念和前沿思想——2022年诺贝尔化学奖浅析

2022年诺贝尔化学奖授予了Carolyn R. Bertozzi、Morten Meldal和K. Barry Sharpless三位科学家,以表彰他们开创了点击化学和生物正交化学。点击化学源于对有机合成方法学的改进,提供了一种在温和条件下高效快速地偶联化学分子的新方法。生物正交化学的开发则起始于生命体系中糖质生物大分子的特异性标记和成像,发展出一类不干扰生命体系且不受生命体系干扰的连接反应。二者殊途同归、异曲同工,成为了在化学、生物医药和材料科学等领域中应用最为广泛的一类化学反应。本文从点击化学与生物正交化学开发中所涉及的化学基础概念出发,对这两种方法的前沿思想进行简要探讨。     

Calixarene‐Based Chemosensors by Means of Click Chemistry

Click chemistry, a new strategy for organic chemistry, has been widely used in the chemical modification of calixarenes because of its reliability, specificity, biocompatibility, and efficiency. Click‐derived triazoles also play a critical role in sensing ions and molecules. This in‐depth review provides an overview of calixarene‐based chemosensors that incorporate click‐derived triazoles, and their three characteristics (chromogenic, fluorescence, and wettability) are reviewed.     

基于巯基点击反应与RAFT聚合的功能性聚合物合成

可逆加成-裂解链转移聚合(RAFT)由于单体适用面广、聚合条件温和、不受聚合方法的限制等特性, 已经成为活性合成聚合物的有效手段之一。点击化学(click chemistry)由于具有良好的选择性、模块性以及官能团耐受性等特点迅速成为许多研究领域,如药物、聚合物、功能材料等合成的有力工具,同时涌现出了多种基于巯基的点击反应。本文综述了近年来基于巯基的点击反应, 如巯基-烯、巯基-炔、巯基-异氰酸酯、巯基-环氧化物以及巯基-卤代烃等新型点击反应与RAFT聚合相结合在功能性聚合物的制备和修饰中的应用, 相信这两种手段的结合将在其中发挥积极的作用。     

Synthesis of Hydrophobic Polymer Brushes on Silica Nanoparticles Via the Combination of Surface-Initiated ATRP,ROP and Click Chemistry

A fascinating nanoobject, hydrophobic polymer brushes with a hard core of silica nanoparticles and a relatively soft shell of polystyrene-block-poly(? -caprolactone) (PS-b-PCL), was easily constructed by surface-initiated atom transfer radical polymerization (ATRP) of styrene, ring-opening polymerization (ROP) of ?-caprolactone and click reaction. The structure and morphology of the as-prepared hybrid nanomaterials were characterized and confirmed by FTIR, ¹H-NMR, TGA and TEM. We believe that the breakthrough associated with formation of such a complex nanoobject would open a door for the fabrication of novel functional nanomaterials or nanodevices with designable structure and tailor-made properties.     

Directional Materials—Nanoporous Organosilica Monoliths with Multiple Gradients Prepared Using Click Chemistry

The existence of more than one functional entity is fundamental for materials, which are desired of fulfilling complementary or succeeding tasks. Whereas it is feasible to make materials with a homogeneous distribution of two different, functional groups, cases are extremely rare exhibiting a smooth transition from one property to the next along a defined distance. We present a new approach leading to high‐surface area solids with functional gradients at the microstructural level. Periodically ordered mesoporous organosilicas (PMOs) and aerogel‐like monolithic bodies with a maximum density of azide groups were prepared from a novel sol–gel precursor. The controlled and fast conversion of the azide into numerous functions by click chemistry is the prerequisite for the implementation of manifold gradient profiles. Herein we discuss materials with chemical, optical and structural gradients, which are interesting for all applications requiring directionality, for example, chromatography.     

A Ligand System for the Flexible Functionalization of Quantum Dots via Click Chemistry

We present a novel ligand, 5‐norbornene‐2‐nonanoic acid, which can be directly added during established quantum dot (QD) syntheses in organic solvents to generate “clickable” QDs at a few hundred nmol scale. This ligand has a carboxyl group at one terminus to bind to the surface of QDs and a norbornene group at the opposite end that enables straightforward phase transfer of QDs into aqueous solutions via efficient norbornene/tetrazine click chemistry. Our ligand system removes the traditional ligand‐exchange step and can produce water‐soluble QDs with a high quantum yield and a small hydrodynamic diameter of approximately 12 nm at an order of magnitude higher scale than previous methods. We demonstrate the effectiveness of our approach by incubating azido‐functionalized CdSe/CdS QDs with 4T1 cancer cells that are metabolically labeled with a dibenzocyclooctyne‐bearing unnatural sugar. The QDs exhibit high targeting efficiency and minimal nonspecific binding.     

光点击化学修饰石油树脂研究

为改善传统石油树脂改性方法能耗高、效率低等缺陷,本文应用点击化学,在常温下,以甲苯为溶剂,以Darocur1173为光引发剂,在UV-LED灯辐照下,通过3-巯基丙酸与DCPD石油树脂发生巯基-烯加成反应,制备的产物命名为DCPD-COOH。以三苯基膦为催化剂,用甲基丙烯酸缩水甘油酯(GMA)与DCPD-COOH反应,制备了可光固化的丙烯酸酯石油树脂,命名为DCPD-A。固化漆膜的设计配方:DCPD-A(50份)、活性稀释剂甲基丙烯酸羟乙酯(HEMA,50份),光引发剂Darocur1173(5份)。在该配方下制得的固化漆膜其附着力达到0级,铅笔硬度为2H。制备的DCPD-A与极性溶剂或者极性树脂的相容性较好,可应用于光固化涂料和光固化油墨等领域。     

Preparation of Lanthanide‐Polymer Composite Material via Click Chemistry

Covalently attaching lanthanide complexes to the polymer backbone can effectively reduce the clustering of lanthanides and thus become an important strategy to fully unleash their potential. In this Communication, a metal‐free click reaction is used for the first time to link a lanthanide complex to the polymer matrix. A diene‐bearing copolymer with anthracenylmethyl methacrylate as a monomer and a dienophile‐bearing lanthanide complex with 5‐maleimido‐1,10‐phenanthroline as the second ligand are synthesized and coupled together through a Diels–Alder cycloaddition (DA). A comparative investigation demonstrates that the composite material prepared by DA click reaction shows the highest quantum yields in the same lanthanide concentration as compared to materials prepared by widely used “directly doping” and “in situ coordinating lanthanide ions with macromolecular ligand” approaches. This work suggests that the “metal‐free” DA click reaction can be a promising tool in the synthesis of high efficient lanthanide functionalized polymeric materials.