表面光接枝原理,方法及应用前景

介绍了表面光接枝的原理,方法和应用前景,表面光接枝主要是用芳酮引发有机材料产生表面自由基,从而引发单体聚合生成表面接枝链。实施方法有气相法,液相法和连续液相法。表面光接枝应用领域广泛,可用于聚合材料的表面改性以及表面功能化。     

生物医用材料表面光引发活性接枝聚合研究新进展

表面接枝聚合改性已经成为提升生物医用材料性能的最重要方法之一.参比其他活性接枝聚合方法,光引发活性接枝聚合因其独特的优势已被越来越广泛地应用于生物医用材料表面改性.根据光引发剂的类型,目前应用最多的光引发活性接枝聚合的引发体系主要有3种:光引发-转移-终止剂介导的聚合引发体系、二苯甲酮及其衍生物引发体系、硫杂蒽酮类引发体系.本文首先简要介绍了上述3种光引发活性接枝聚合体系的发展历程、接枝机理以及特点.同时结合本课题组相关研究工作,重点论述了光引发接枝聚合技术在3个不同生物医用领域的主要应用:(1)抗菌表面,利用光活性接枝的特点构建层状功能高分子刷,实现表面抗菌功能的阶段性需求.(2)免疫检测表面,使用光活性接枝方法构建层状功能高分子刷,解决检测灵敏度低以及蛋白干扰问题.(3)生物活性分子表面固定,利用可见光活性接枝聚合体系,实现酶在表面的固定化使用以及细胞表面修饰以提高细胞稳定性.最后展望了生物医用材料表面光引发活性接枝聚合研究的发展趋势.     

表面引发接枝聚合法制备凹凸棒土/聚甲基丙烯酸甲酯杂化粒子的研究

将γ-氨丙基三乙氧基硅烷(APTES)接枝到凹凸棒土(AT)表面,制得表面键合伯氨基的改性粒子AT-APTES;通过AT-APTES表面的伯氨基和过硫酸铵(APS)构成氧化-还原引发体系,采用无皂乳液法实现甲基丙烯酸甲酯(MMA)在AT表面接枝聚合,制得最高接枝率为29.4%的杂化粒子AT-g-PMMA;采用红外光谱(FTIR)、拉曼光谱(Raman)、透射电镜(TEM)以及热失重分析(TGA)等方法对杂化粒子AT-g-PMMA进行了表征;研究了主要配方及工艺条件对表面引发接枝聚合接枝率的影响.结果表明,伯氨基-过硫酸铵引发体系可以有效引发MMA在AT表面接枝聚合,由于引发点位于AT表面,故接枝率较高.本研究体系适宜的温度为65℃,单体MMA用量为水质量的6%,APS用量为单体质量的1%,此工艺条件下可有效减小均聚反应对接枝聚合反应的影响.先接枝到AT表面的聚合物对后续的接枝聚合反应产生抑制作用,接枝率越高,抑制作用越大.     

纳米SiO2锚固光敏基团引发MMA光接枝聚合研究

对纳米SiO2进行了锚固光引发剂的表面修饰,进而引发甲基丙烯酸甲脂(MMA)光接枝聚合制备有机/无机复合粒子.纳米SiO2粒子首先用氯化亚砜进行表面氯化,再与光引发剂2-羟基-4-(2-羟基乙氧基)-2-甲基苯丙酮(Irgacure2959)反应从而锚固上光引发剂.通过紫外光引发MMA在经过修饰过的纳米SiO2表面上进行表面光接枝聚合.采用IR、TGA和TEM等方法表征了接枝前后纳米粒子的变化,证明了表面接枝物的存在,并研究了不同反应条件对单体转化率、接枝率和接枝效率的影响.研究结果表明,搅拌对接枝过程的影响比较显著.TGA结果显示未搅拌聚合时接枝率只能达到比较小的程度,而在搅拌条件下180min内MMA的接枝率可达到110%.     

乙烯基单体在炭黑表面上的接枝聚合

讨论了分别在铈离子体系，正丁基锂体系，过渡金属离子乙酰丙酮铜（Ⅱ）以及焦磷酸络锰（Ⅲ）体系的作用下，炭黑与乙烯基单体的接枝聚合．研究了引发剂浓度、单体浓度、反应时间对接枝聚合反应的影响．利用ＦＴ ＩＲ分析确证了炭黑表面的接枝反应，利用ＴＥＭ表征了接枝炭黑的形态．结果表明，在所研究的多种炭黑表面接枝聚合体系中，正丁基锂体系的接枝率最高，可达２００％．而各种氧化还原体素的接枝率只能达到３０％左右．表面接枝后的炭黑在介质中的分散稳定性明显改善．     

RAFT链转移剂存在下凹凸棒土表面甲基丙烯酸甲酯接枝聚合

将γ-(甲基丙烯酰氧)丙基三甲氧基硅烷(MPS)接枝到凹凸棒土(AT)表面,制得表面带有可聚合碳碳双键的改性粒子AT-MPS;以二硫代苯甲酸氰基异丙酯(CPDB)为链转移剂,采用可逆加成断裂链转移(RAFT)聚合技术,在AT表面进行甲基丙烯酸甲酯(MMA)接枝聚合.通过红外(FTIR)、热失重(TGA)等方法进行了表征,考察了引发剂以及RAFT链转移剂用量对聚合反应动力学和AT表面接枝聚合接枝率的影响.结果表明,PMMA通过RAFT聚合成功接枝在AT表面;基于RAFT过程的接枝聚合比传统自由基接枝聚合具有更长的反应时间和较高的接枝率.本体系相对适宜条件:温度为70℃,[MMA]/[CPDB]/[AIBN]为400/1/0.5.此条件下聚合反应具有很好的可控性,溶液中的聚合物分子量分布指数为1.2~1.3,AT表面PMMA接枝率为16.33%.引发剂和RAFT链转移剂用量过大均会造成接枝率降低.     

脂肪酶催化合成纤维素-甲基丙烯酸丁酯接枝聚合吸油材料

以棉浆粕为基材,硝酸铈铵/HNO3为引发剂,甲基丙烯酸丁酯(BMA)为接枝单体,脂肪酶为催化剂,N,N′-亚甲基双丙烯酰胺为交联剂,采用悬浮震荡接枝聚合反应制备了纤维素-BMA接枝聚合吸油材料.采用红外光谱、X射线衍射、扫描电镜、热重、差热等手段对产物结构进行了表征,考察了棉浆粕的引发及其后的接枝聚合反应,得到脂肪酶催...     

电晕放电引发丙烯酸表面接枝LDPE薄膜的研究

本文采用接枝量测定、ATRIR和ESCA研究了电晕放电引发丙烯酸表面接枝LDPE薄膜,实验结果表明:电晕放电能有效地引发丙烯酸在LDPE薄膜表面的接枝聚合反应,随反应时间延长、反应温度提高和丙烯酸单体浓度增大,表面接枝量增大。当丙烯酸浓度为20%、聚合温度为70℃、反应15小时时,经电晕放电处理72秒后的LDPE薄膜表面接枝量高达22055μgcm2。     

多官能单体TMPTA在LDPE表面光接枝聚合研究

以二苯甲酮(BP)为光引发剂、丙酮和水的混合物为溶剂,研究了室温下多官能单体三羟甲基丙烷三丙烯酸酯(TMPTA)在低密度聚乙烯(LDPE)表面的光接枝聚合(λ>300nm).研究表明,多官能单体的接枝速率较快,接枝聚合易产生交联结构,聚合后仍残留双键;延长聚合反应时间、增加单体用量有利于单体接枝转化率的提高;随引发剂用量增加,单体接枝转化率出现一峰值;在研究范围内,混合溶剂中水含量增加可使单体接枝转化率明显提高.扫描电镜观察到接枝膜表面形成了许多小球,表面粗糙度增加,疏水性提高.     

电火花引发HEMA 接枝LDPE 薄膜及其血液相容性

采用接枝量、ATR－IR、SEM、与水接触角、溶血试验和再钙化时间等测试手段研究了电火花引发甲基丙烯酸β－羟乙酯(HEMA)表面接枝低密度聚乙烯(LAPE)薄膜的接枝聚合反应影响因素、表面结构和血液相容性。结果表明,电火花能有效引发HEMA在LDMA薄膜表面接枝聚合反应,随接枝聚合反应时间延长、单体浓度的增大。接枝量增大。随反应温度升高,接枝量增大到一最大值后,进一步升高反应温度,接枝量下降,最佳接枝聚合温度为60℃当在60℃单体φ=5％水溶液是反应2h时,经空气气氛和1.5kV电火花预处理72s和LDPE薄膜表面接枝量可达169ug/cm^2。接枝改性后LDPE薄膜与水的接触下降,亲水性增加,溶血程度减小,再钙化时间延长,血液相容性得到改善。     

Electroless deposition of nickel on fluoropolymers modified by surface graft copolymerization

Surface modification of Ar plasma-pretreated poly(tetrafluoroethylene) (PTFE) and poly(vinylidene fluoride) (PVDF) films via UV-induced graft copolymerization with 4-vinylpyridine (4VP), 2-vinylpyridine (2VP) or 1-vinylimidazole (VIDz) was carried out. Electroless deposition of nickel could be carried out on these graft-modified fluoropolymer surfaces after PdCl₂ activation. The surface compositions of the graft-modified films were studied by X-ray photoelectron spectroscopy. The adhesion strength between the surface graft-copolymerized fluoropolymer film and the electrolessly deposited nickel was affected by the type of monomers used for graft copolymerization and the graft concentration. The optimum T-peel adhesion strengths of the electrolessly deposited Ni on the 4VP graft-copolymerized PTFE and PVDF surfaces were about 7 and 13 N/cm, respectively. The metal/fluoropolymer assemblies delaminated by cohesive failure inside the fluoropolymer substrates. The enhanced adhesion between the electrolessly deposited Ni and the surface-modified fluoropolymers is attributable to the interfacial charge transfer interactions between the grafted polymer chains and the deposited metals (Pd and Ni), the spatial distribution of the graft chains into the metal matrix and the covalent tethering of the graft chains on the fluoropolymer surface.     

表面引发聚合反应研究进展

表面引发聚合反应作为一种新的聚合反应可广泛应用于固体基底的表面修饰与改性。结合分子自组装技术,几乎各种类型的聚合反应都有可能在固体基底表面进行。本文对表面引发聚合反应的研究进展进行了综述,对反应类型、实验方法、研究动向以及在合成聚合物刷、形成图案化聚合物薄膜等方面的应用与发展前景作了介绍与讨论。     

Surface modification and functionalization through the self-assembled monolayer and graft polymerization

The modification of a surface at the molecular level with precise control of the building blocks generates an integrated molecular system. This field has progressed rapidly in recent years through the use of self-assembled monolayer (SAM) interfaces. Recent developments on surface-initiated chemical reactions, functionalization, and graft polymerization on SAM interfaces are emphasized in the present review. A number of surface modifications by grafting are reviewed. The grafting of polyaniline on a glass surface, previously modified with a silane self-assembled monolayer (SAM), is examined in detail for both planar and 3-D systems, such as fibers, nanoparticles, and even polymer patterned surfaces. We also discuss the graft polymerization of water-soluble polymers on the surface of silicon nanoparticles, which generate stable aqueous colloidal solutions and have numerous applications. Finally, we compare and review some surface-modification techniques on the surfaces of polymers, such as two-solvent entrapment, polymer blending, and chemical grafting, which improve their biocompatibility.     

Synthesis and Application of Tailored Graft Copolymers from Polystyrene Macromonomer

Comb graft copolymers prepared by macromonomer technique has become applicable for permanent modification of polymer surfaces. In this paper the association and adsorption behavior in solution of the well designed graft copolymer prepared from polystyrene macromonomer and various hydrophilic comonomer was studied and the mechanism of surface accumulation of hydrophilic segment was clarified by surface analysis of polystyrene containing the graft copolymers. Wetting of modified polymer surfaces and the permeability of gases through the film was also discussed.     

In situ fabrication of macroporous polymer networks within microfluidic devices by living radical photopolymerization and leaching

Novel fabrication techniques and polymer systems are being explored to enable mass production of low cost microfluidic devices. In this contribution we discuss a new fabrication scheme for making microfluidic devices containing porous polymer components in situ. Contact lithography, a living radical photopolymer (LRPP) system and salt leaching were used to fabricate multilayer microfluidic devices rapidly with various channel geometries and covalently attached porous polymer plugs made of various photopolymerizable substrates. LRPP systems offer the advantages of covalent attachment of microfluidic device layers and facile surface modification via grafting. Several applications of the porous plugs are also explored, including a static mixer, a high surface area-to-volume reactor and a rapidly responding hydrogel valve. Quantitative and qualitative data show an increase in mixing of a fluorescein and a water stream for channels containing porous plugs relative to channels with no porous plugs. Confocal laser scanning microscopy images demonstrate the ability to graft a functional material onto porous plug surfaces. A reaction was carried out on the grafted pore surfaces, which resulted in fluorescent labelling of the grafted material throughout the pores of the plug. Homogenous fluorescence throughout the depth of the porous plug and along pore surfaces indicated that the porous plugs were surface modified by grafting and that reactions can be carried out on the pore surfaces. Finally, porous hydrogel valves were fabricated which swelled in response to contact with various pH solutions. Results indicate that a porous hydrogel valve will swell and close more rapidly than other valve geometries made with the same polymer formulation. The LRPP-salt leaching method provides a means for rapidly incorporating porous polymer components into microfluidic devices, which can be utilized for a variety of pertinent applications upon appropriate selection of porous plug materials and surface treatments.     

Surface modification of silica nanoparticles by UV-induced graft polymerization of methyl methacrylate

In this study we modified the surface of silica nanoparticles with methyl methacrylate by UV-induced graft polymerization. It is a surface-initiated polymerization reaction induced by ultraviolet irradiation. The resulting organic-inorganic nanocomposites were near-monodisperse and fabricated without homopolymerization of the monomer. Substantial increase in mean particle size was observed by SEM image analysis after UV-induced grafting of methyl methacrylate onto pure silica particles. FT-Raman spectroscopy and X-ray photoelectron spectroscopy studies of these materials revealed the successful grafting of methyl methacrylate onto the silica surface. The formation of a covalent bond between the grafted PMMA chains and silica surface was indicated by FT-Raman spectra. Thermogravimetric analysis of the PMMA-grafted silica particles indicated the polymer contents in good agreement with SEM photographs.     

有机聚合物材料表面受限光感应C–H键转换反应研究进展

有机聚合物材料普遍具有表面能低和反应惰性的特点,限制了其在光、电、分离、生物医用等高端领域的应用.表面改性是有机高分子材料高性能化的重要手段,其涉及的核心科学问题是表面C–H键的活化/转换化学.光化学反应具有快速高效、化学选择性高、环境友好、可低温反应、时间/空间精确可控等特点,在有机聚合物材料表面改性上具有突出优势.本文介绍了本课题组多年来在有机聚合物材料表面受限光感应C–H键转换反应方面的研究进展,系统介绍了此类反应的机理,以及在生长/固定无机、导电材料、生物分子等方面的应用,并展望了光感应C–H键转换反应今后的发展方向.     

Swelling, functionalization, and structural changes of the nanoporous layered silicates AMH-3 and MCM-22

Nanoporous layered silicate materials contain 2D-planar sheets of nanoscopic thickness and ordered porous structure. In comparison to porous 3D-framework materials such as zeolites, they have advantages such as significantly increased surface area and decreased diffusion limitations because the layers can potentially be exfoliated or intercalated into polymers to form nanocomposite materials. These properties are particularly interesting for applications as materials for enhancing molecular selectivity and throughput in composite membranes. In this report, the swelling and surface modification chemistry of two attractive nanoporous layered silicate materials, AMH-3 and MCM-22, were studied. We first describe a method, using long-chain diamines instead of monoamines, for swelling of AMH-3 while preserving its pore structure to a greater extent during the swelling process. Then, we describe a stepwise functionalization method for functionalizing the layer surfaces of AMH-3 and MCM-22 via silane condensation reactions. The covalently attached hydrocarbon chain molecules increased the hydrophobicity of AMH-3 and MCM-22 layer surfaces and therefore allow the possibility of effectively dispersing these materials in polymer matrices for thin film/membrane applications.     

生物多糖进行医用高分子材料表面修饰的研究进展

综述了国内外应用生物多糖进行医用高分子材料表面修饰的研究状况,其中重点介绍了葡聚糖、肝素及类肝素类物质、壳聚糖等多糖在高分子材料表面修饰的研究近况.多糖是自然界中含量最为丰富的生物大分子,几乎存在于所有的生命体中,具有很好的生物相容性,而且某些生物多糖还具有特殊的生物活性,因此用生物多糖进行医用高分子材料的表面修饰受到了国内外研究学者的关注.大量研究表明,经过生物多糖表面修饰的高分子材料可获得良好的生物相容性和某些优良的医学应用性能.