不同引发核树枝状大分子的合成

含不同分支官能团树枝状大分子的合成是目前研究的一个热点。文献报道的有两方向引发核、三方向引发核、四方向引发核、六方向引发核等结构新颖的树枝状分子。本文综述了不同引发核及其衍生物在树枝状大分子合成中的应用。     

用三聚氯氰和己二胺合成均三嗪衍生物的研究

树枝状大分子是当前正在蓬勃发展的新型合成高分子[1-2],在传统树枝状大分子的合成过程中,每生成一代就需要对多官能团进行保护和去保护,这大大增加了合成的步骤及难度,且使得产率往往不高[3]。然而以三聚氯氰为原料合成树枝状大分子可以省去保护和解保护的步骤,这主要是由于三     

己二胺为核低代树枝状大分子的合成与性能

以己二胺和丙烯酸甲酯为原料,甲醇为溶剂,采用迈克尔加成和酰胺化缩合反应合成了低代己二胺为核的树枝状大分子。主要考察了反应条件对己二胺为核1.0G树枝状大分子收率的影响,当n(己二胺为核0.5G树枝状大分子)∶n(己二胺)=1∶6,反应温度50℃,反应时间24h,收率为69.36%。研究了以己二胺为核的1.0G树枝状大分子对O/W型模拟乳液的破乳性能。结果表明:在45℃、添加量为200ppm、60min的条件下,己二胺为核的1.0G树枝状大分子的破乳率达到80.28%。     

聚乙二醇嵌段树枝状聚赖氨酸共聚物的合成及其基因载体研究

采用液相多肽合成法制备得到窄分子量分布、结构可控的生物相容性聚乙二醇嵌段共聚树枝状聚赖氨酸阳离子功能大分子(PEG-b-Dendritic PLL). 运用¹H NMR核磁共振、凝胶电泳以及荧光淬灭滴定手段对所得阳离子两嵌段大分子的化学结构及其与质粒DNA (pDNA)结合作用与复合行为进行了研究. 结果表明聚乙二醇嵌段树枝状聚赖氨酸与pDNA分子可以在缓冲溶液中形成稳定的胶束, pDNA与阳离子树枝赖氨酸嵌段通过静电相互作用形成胶束核, 其水溶性聚乙二醇嵌段形成水溶性胶束壳, 提高了阳离子大分子/pDNA复合胶束的稳定性. 同时发现随着阳离子嵌段树枝状赖氨酸代数的增加, 阳离子两嵌段大分子与pDNA的结合作用增强, 有利于其作为基因转染生物功能载体的应用.     

壳聚糖-树枝状大分子杂化物的研究进展

壳聚糖-树枝状大分子杂化物主要包括壳聚糖-(聚酰胺-胺)[CS-PAMAM]、壳聚糖-聚乙烯亚胺[CS-PEI]、壳聚糖-3,4,5-三(p-十二烷氧基苄氧基)苯甲酸[CS-DOBOB酸]、壳聚糖-3,4,5-三(p-十二烷氧基-m-甲氧基苄氧基)苯甲酸(DOVOB酸)、壳聚糖-聚丙三醇(PGLD)等树枝状大分子杂化物。壳聚糖-树枝状大分子杂化物具有良好的水溶性、生物可降解性、抗菌性、吸附性和热致液晶性等性能。壳聚糖-树枝状大分子杂化物的用途广泛,可作为金属离子的吸附剂、治疗高胆红素血症的吸附材料、新型荧光材料、抗菌剂和抗凝血剂等。本文综述了壳聚糖-树枝状大分子杂化物的研究进展,并展望了其未来研究方向和应用前景。     

树枝状大分子催化剂的研究进展

回顾了功能树枝状大分子在催化作用领域的研究成就，重点就活性中心在核附 近的树枝状大分子和表面含催化官能团的树枝状大分子的结构与催化作用进行了讨 论，并对其应用前景进行了展望。     

树枝状大分子在荧光生物成像中的研究进展

树枝状大分子是一种具有精确三维结构的纳米材料。目前,对于树枝状大分子的研究,逐渐从合成和表征各式各样的树枝状大分子转向到对其特殊功能和应用的研究。传统的荧光成像探针大多数为小分子化合物,其发展受到特异性低、稳定性差、停留时间短、可修饰基团少和毒性大等缺点的限制。树枝状大分子具备独特的分子结构如大量可设计性的末端官能团和广阔的分子内空腔以及选择多样化的优势,使其在荧光生物成像领域中有良好的应用前景。本文重点介绍了基于树枝状大分子的有机荧光探针和量子点探针在生物成像方面最新的研究进展。     

POSS基树枝状大分子的合成与应用

树枝状大分子(dendrimer)是一种高度支化、纳米尺度的人工合成大分子,具有独特的物理化学性能和重要的应用前景。利用具有8个可官能化顶点的多面体低聚倍半硅氧烷(POSS)作为树枝状大分子的核心,可在一定程度上简化树枝状大分子繁琐的合成与分离过程,在低代数时就可获得较大的表面官能团密度,并使树枝状分子呈现球形对称结构。POSS基树枝状大分子结合了POSS和树枝状分子结构与性能的优势,是一类极具潜力的有机-无机纳米杂化材料。本文综述了近年来POSS基树枝状大分子的最新研究成果,介绍了具有代表性的POSS基树枝状大分子的合成方法以及它们在催化剂、生物材料、液晶材料和发光材料等领域的应用研究进展,并对该新型材料的发展趋势做了展望。     

新型树枝状大分子载体在药物研究领域的应用进展

本文介绍了树枝状大分子特别是聚酰胺-胺类在药物研究领域中的应用.从树枝状大分子对疏水性药物的增溶以及缓控释作用等方面重点对聚酰胺-胺进行了分析和总结,并简要介绍了其他种类的树枝状大分子.     

4-AHBA为核的聚芳醚树枝状化合物的合成及其光学性能

合成了三个新的以2-(4-氨基-2-羟基苯基)苯并噻唑(4-AHBA)为核的聚芳醚树枝状化合物(1a～1c),其结构由1H NMR,13C NMR,IR,MS和元素分析表征.研究了1和4-AHBA在氯仿中的紫外吸收光谱和荧光发射光谱,结果表明,1与4-AHBA相比,紫外吸收强度大大提高,且最大吸收波长从349 nm红移...     

聚酰胺-胺型树枝状高分子水溶液的表面活性

树枝状化合物是一类三维的、高度有序的新型高分子.与传统高分子相比,这类化合物在合成时,可以在分子水平上严格控制,设计分子大小、形状、结构和功能基团,产物一般高度对称,单分散性好.因而具有广泛的潜在用途^[1,2].近年来,已引起广大化学工作者的重视.     

外端为偶氮苯基团的聚酰胺-胺树枝状分子对光和H~+的响应行为

合成了1到5代外端修饰有偶氮苯基团的聚酰胺-胺(PAMAM)树枝状分子.H-NMR、FTIR和元素分析等表明得到了目标产物,外端接枝率在70%~90%.结构分析表明经修饰的PAMAM分子在3代和4代之间存在一个结构转变.UV-Vis和H-NMR分析结构显示,在中性条件下,Gn-azo表现出类似于小分子偶氮苯基团的光响应行为.而在酸性条件下,偶氮苯基团的顺反异构转化率较质子化前低.包裹及释放实验表明,虽然G4-azo包裹水杨酸分子的能力弱于G4PAMAM,但它对于客体小分子具有缓释作用,光照使偶氮苯基团发生由反式到顺式的异构转化之后,缓释效应更明显.     

端基含4个丁氧基苯介晶基元光致变色液晶树状物的合成、结构及液晶性研究

合成了周边含4个丁氧基偶氮苯介晶基元(M5)端基新的零代光致变色液晶树状物(D0),并用元素分析、核磁共振、基质辅助激光解吸飞行时间质谱、红外、紫外、偏光显微镜、差示扫描量热(DSC)和广角X射线衍射法(WAXD)表征.D0显示向列相,与M5相同,树状物相态由介晶基元相态所决定,D0的相行为:K138N147I145N118K.对零代(D0)、一代(D1)、二代(D2)和三代(D3)液晶树状物的清亮焓、清亮熵、熔化焓和熔化熵进行了比较.     

A simple polyacrylamide gel electrophoresis procedure for separation of polyamidoamine dendrimers

A simple, inexpensive, and rapid electrophoresis technique was developed for use as a routine tool for evaluating purity of polyamidoamine (PAMAM) dendrimers. A variety of factors influencing migration of generations 0-7 dendrimers on nongradient polyacrylamide gels were evaluated. The low generation dendrimers were found to be very sensitive to diffusion during or after electrophoresis. The proposed method incorporates steps that minimize diffusion, in order to obtain improved resolution and sensitivity, especially for the lower-molecular-weight dendrimers. This was accomplished by inclusion of a dendrimer fixation step with glutaraldehyde and performing the electrophoresis separation, fixation, staining, and destaining at 4 degrees C. PAMAM dendrimer separation was studied under basic and acidic conditions. Electrophoresis under acidic conditions gave increased resolution and sensitivity over separation at alkaline pH. Oligomers and trailing generations could be clearly separated and visualized under these conditions. The smallest PAMAM dendrimer, generation 0, was visible at 1.5 microg under the optimized acidic conditions. With slight modifications, this technique should be applicable to separation of other water-soluble dendrimers.     

Low generational polyamidoamine dendrimers to enhance the solubility of folic acid:A‘‘dendritic effect’’investigation

Low generational(G0–G2,G for generation) polyamidoamine(PAMAM) dendrimers were investigated as enhancers to improve the aqueous solubility of folic acid at pH 11 and pH 5.In these two cases,the solubility of folic acid increases with both the dendrimer concentration and generation.However,the solubilization mechanism is different.The electrostatic interaction between the primary amines of dendrimers and the ionized carboxylic groups of folic acid dominates the dissolution process at pH 11 while the increase of the solubility of folic acid at pH 5 is attributed to the hydrophobic encapsulation inside the dendrimer molecules.In addition,for comparison ethylenediamine was used as a small molecule control to examine the ‘‘dendritic effect' in the dendrimer-related solubilization process.Interestingly,PAMAM dendrimers exhibit,at pH 5,a significant superiority over ethylenediamine in enhancing solubility,whereas this ‘‘dendritic effect' cannot be observed under the basic condition.     

Comparison of PAMAM-Au and PPI-Au nanocomposites and their catalytic activity for reduction of 4-nitrophenol

Dendrimer-Au nanocomposites are prepared in aqueous solutions using poly(amidoammine)dendrimers (PAMAM) (generation 2, 3, and 5) and poly(propyleneimine)dendrimers (PPI)(generation 2, 3, and 4) by wet chemical NaBH(4) method. The Au nanoparticles thus obtained are 2-4 nm in diameter for both dendrimers and no generation dependence on the particle size is observed, whereas the generations of the dendrimers are increased as stabilization of Au-nanoparticles is achieved with lower dendrimer concentrations. Studies of the reduction reaction of 4-nitrophenol using these nanocomposites show that the rate constants for the PAMAM dendrimers (generations 2 and 3) are higher than those for the PPI dendrimers (generations 2 and 3), while a distinct difference in the rate constants is not seen for the PAMAM dendrimer (generation 5) or the PPI dendrimer (generation 4). In addition, the rate constants for the reduction of 4-nitrophenol involving all the dendrimers decrease with increases in dendrimer concentrations.     

扇形PAMAM树枝状高分子的合成与表征

树枝状化合物是聚合物合成科学上第一次不采用生物技术合成的结构精确的大分子。它被称为是继线形、交联形、支链形聚合物后的第4种结构类型的高分子。树枝状高分子的合成是通过多官能团基元进行逐步的有机反应而非传统的聚合方法。近年来，除了发散法、收敛法合成以外，     

Preparation of Dendrimers from Macromolecular Cores and Papain Immobilization

Recently,stIJdyonpreparationandpotentialapplicationofdendrimersisquiteactivel-3.StrIJcturally,therearealotoffunctionalgroupsonthesurfaceofadendrimer,whicharepossiblyusedtoconnectwithbiocatalystsuchasenZymeandcell.However,inmostcasesthereporteddendrimerswereviscousandcouldhardlybeusedascarrierforenZymeimmobilization.Inordertoobtainsoliddendrimers,amino-poly(ethyleneglycol)[PEG(NH,),]andamino-propylsilicagel[SG(NH,).]wereselectedastWomacroinitiatorcores(MC)toprepareMC-dendrimers(PEG-den…     

Structural characterization of new defective molecules in poly(amidoamide) dendrimers by combining mass spectrometry and nuclear magnetic resonance

A new side-reaction occurring during divergent synthesis of PAMAM dendrimers (generations G₀–G₂) was revealed by mass spectrometric detection of defective molecules with a net gain of a single carbon atom as compared to expected compounds. Combining MS/MS experiments performed on different electrosprayed precursor ions (protonated molecules and lithiated adducts) with NMR analyses allowed the origin of these by-products to be elucidated. Modification of one ethylenediamine end-group of perfect dendrimers into a cyclic imidazolidine moiety was induced by formaldehyde present at trace level in the methanol solvent used as the synthesis medium. Dendrimers studied here were purposely constructed from a triethanolamine core to make them more flexible, as compared to NH₃- or ethylenediamine-core PAMAM, and hence improve their interaction with DNA. Occurrence of this side-reaction would be favored by the particular flexibility of the dendrimer branches.     

Self-assembly of ionogenic surfactants during their interaction with poly(propylenimine) dendrimers

The structure of complexes formed by poly(propylenimine) dendrimers of five generations and anionic micelle-forming surfactants is studied by X-ray diffraction. It is shown that, in complexes of lower generation dendrimers, the lamellar packing of surfactants is dominant. In complexes formed by dendrimers of the fourth and fifth generations, packing typical of compact dendrimer molecules prevails. This packing can be attributed to the distorted dense packing of ball-like complex species. Structural models of complexes that allow for penetration of surfactants into the dendrimer molecule and the size ratio of the aliphatic radical of a surfactant and a dendrimer are advanced.