树状大分子接枝型聚合物色谱分离材料研究进展

随着色谱固定相制备技术和材料科学领域的不断发展,目前已经有大量修饰方法和新型材料被用于固相萃取、高效液相色谱以及离子色谱聚合物固定相填料的功能化修饰。其中聚酰胺-胺(PAMAM)树状大分子由于其独特的结构和性质,在色谱分离材料结构完善和性能提升中也发挥了重要的作用。该文主要综述了PAMAM树状大分子在以聚合物为基质的色谱分离材料修饰中的应用,并对其今后的发展进行了展望。     

生物材料聚酰胺-胺树状大分子在医学领域研究进展

聚酰胺－胺（PAMAM）树状大分子是一类新型纳米生物材料，这类分子可通过有机合成的方法精确控制分子的结构和相对分子质量，其独特的分子结构使之在许多领域获得广泛应用，本文着重介绍了PAMAM树状大分子作为基因载体，药物载体，磁共振造影剂和硼中子俘获治疗试剂等在医学领域中的研究进展。     

(聚酰胺-胺)树状大分子对甲氨蝶呤的复合和释放研究

以甲氨蝶呤(MTX)为模型药物,研究了PAMAM与MTX的复合及体外释放.1H-,13C-NMR数据表明MTX与PAMAM树状大分子形成复合物是由于MTX羧基和PAMAM树状大分子外端氨基之间的相互作用.该复合物在pH=7.4,10 mmol/L Tris-HCl中非常稳定,表现出明显的缓释效果.当溶液中的离子强度增加时,会破坏PAMAM-MTX复合物的稳定性,缓释作用部分或全部失去,说明PAMAM树状大分子与MTX之间的相互作用属于静电作用.UV测得每个G5.0 PAMAM、G4.0 PAMAM树状大分子分别能复合271、4个MTX分子.     

不同代PAMAM树状大分子与牛血清白蛋白的相互作用研究

采用发散法合成了以乙二胺为核的聚酰胺-胺型(PAMAM)树状大分子,并应用荧光光谱法研究了生理条件下(pH=7.4)3.0代(G3.0)、3.5代(G3.5)和4.0代(G4.0)PAMAM树状大分子与牛血清白蛋白(BSA)的相互作用.结果表明,三种PAMAM树状大分子都能引起牛血清白蛋白荧光猝灭,其程度主要取决于各自末端基团的性质,猝灭机制属于静态猝灭.G4.0PAMAM,G3.5PAMAM和G3.0PAMAM与BSA的猝灭常数分别为2.73,1.69,1.55L·mmol-1.同时考察了体系pH值及离子强度的变化对PAMAM与BSA相互作用的影响.此外,同步荧光和紫外光谱法(UV)以及红边激发荧光位移(REES)等方法的研究结果表明,PAMAM树状大分子的存在改变了BSA的构象.     

聚酰胺-胺(PAMAM)树状大分子对甲氨蝶呤的包合及缓释研究

以甲氨蝶呤(MTX)为模型药物,研究了G5.0PAMAM树状大分子对其包合和释放,并用13^CNMR对PAMAM-MTX包合物进行了表征.UV-Vis研究结果表明,1个G5.0PAMAM树状大分子能包合27个MTX分子,体外释放研究表明,在37℃,pH=7.4的10mmol/LTris-HCl缓冲溶液中G5.0PAMAM树状大分子对MTX具有明显的缓释作用.     

Cu2+对树状大分子PAMAM-FCD荧光性能的影响

以小分子2-芴醛(FCD)修饰树状大分子聚酰胺-氨PAMAM, 合成了1~3代树状大分子PAMAM-FCD, 用IR, 1H NMR和MALDI-TOF-MS等手段表征了化合物结构, 研究了Cu2+浓度对其荧光及紫外性能的影响. 结果表明, Cu2+可使其荧光强度和紫外吸收不同程度地增强. 在紫外光谱中, Cu2+自身的吸收峰消失, 表明Cu2+参与配位. PAMAM-FCD有望成为蓝光区荧光材料及树状大分子-铜杂化材料.     

肽类树状大分子的合成及其在药物传输系统中的应用

树状大分子是近年来蓬勃发展的一类新型高分子材料, 其表面存在大量的官能团, 分子内部存在空腔且分子尺寸可控, 因此, 树状大分子已被广泛应用于众多的领域. 肽类树状大分子是指在树状大分子结构中含有肽键的一类大分子, 因其具有类似蛋白质一样的球状结构, 且具有优异的水溶性、生物相容性、生物降解性和细胞低毒性等特点, 所以, 肽类树状大分子可以作为药物传输的载体. 此外, 肽类树状大分子的疏水空腔可以装载疏水性药物, 对其起到增溶和缓释作用. 综述了肽类树状大分子的合成方法, 并对其与药物分子的结合机制及其在药物传输系统中的应用进行了总结与展望.     

树状大分子PAMAM(1G)-FCD的合成及荧光性能

合成了外围由小分子2-芴醛修饰的树状大分子PAMAM(1G)-FCD, 用IR, 1H NMR, MALDI-TOF-MS等手段表征了其结构, 并对其荧光性能及Sn2+对该性能的影响进行了研究, 结果表明, Sn2+能使化合物荧光显著增强. 紫外光谱表明, 随着PAMAM(1G)-FCD溶液中Sn2+浓度的增加, 体系在360 nm处出现了新的吸收峰, 表明二者之间存在化学反应. 故该树状分子有望作为难得的蓝光区荧光材料及金属-树状大分子杂化材料.     

聚酰胺-胺树形大分子吸附分离材料的构筑及应用研究进展

聚酰胺-胺(PAMAM)树形大分子具有高度支化的分子结构和丰富的叔胺、酰胺和氨基等功能基团,且各功能基团随树形大分子代数增加呈规律性增加和排布,为吸附位点的集中、层次性分布提供了理想的模板。同时,PAMAM树形大分子具有良好的水溶性、稳定性和pH响应性,可通过调控树形大分子的代数、中心核、外层端基以及溶液pH等提升其对不同水体环境的适应性及对目标物的选择性吸附分离性能,因此,以PAMAM树形大分子构筑吸附分离材料在金属离子、染料、生物分子和药物分子以及CO2的吸附分离领域具有重要应用。本文对PAMAM树形大分子吸附分离材料的构筑及应用研究进展进行了全面总结,并展望了该类材料未来的应用前景和发展方向。     

树状大分子包裹金纳米颗粒的制备、尺寸控制和稳定性研究

作者以氨基封端的第五代聚酰胺胺(PAMAM)树状大分子为模板,借助静电相互作用将氯金酸盐吸引进入树状大分子内部,再由外加还原剂硼氢化钠将金盐原位还原,得到了树状大分子包裹的金纳米颗粒(Dendrimer-Entrapped Gold Nanoparticles,Au DENPs),并应用紫外、表面电势法、透射电镜和能量色散谱等手段对其结构进行表征。通过改变氯金酸与树状大分子的投料比,平均尺寸在1.9~2.8nm的Au DENPs被成功制备。制得的Au DENPs不仅在水、PBS缓冲液以及生理环境下稳定存在,还在较宽的pH(pH=5~8)与温度(4~50℃)范围内稳定,为其应用于生物医学领域提供了可能。     

Interaction of water-soluble polypyridylphenylene dendrimers with a polymethacrylate anion

Cationic water-soluble dendrimers have been prepared by the alkylation of pyridyl groups in polypyridylphenylene dendrimers of the first four generations, and their interaction with a polymethacrylate anion has been studied. The stability of polyelectrolyte complexes in aqueoussaline solutions has been studied by fluorimetric titration with the use of the pyrenyl-tagged polyanion, and it has been shown that the stability of these complexes significantly increases with the dendrimer generation number and the content of hydrophobic phenylene groups. Based on sedimentation analysis and turbidimetric titration, it is inferred that a significant part of charged groups of dendrimers are inaccessible to interaction with the polyanion and that water-soluble nonstoichiometric polyelectrolyte complexes develop in mixtures of higher generation dendrimers. Modeling results of this study may be useful for designing efficient cationic dendrimer carriers of genetic material and hydrophobic physiologically active compounds.     

Two Decades of Triazine Dendrimers

For two decades, methods for the synthesis and characterization of dendrimers based on [1,3,5]-triazine have been advanced by the group. Motivated by the desire to generate structural complexity on the periphery, initial efforts focused on convergent syntheses, which yielded pure materials to generation three. To obtain larger generations of dendrimers, divergent strategies were pursued using iterative reactions of monomers, sequential additions of triazine and diamines, and ultimately, macromonomers. Strategies for the incorporation of bioactive molecules using non-covalent and covalent strategies have been explored. These bioactive materials included small molecule drugs, peptides, and genetic material. In some cases, these constructs were examined in both in vitro and in vivo models with a focus on targeting prostate tumor subtypes with paclitaxel conjugates. In the materials realm, the use of triazine dendrimers anchored on solid surfaces including smectite clay, silica, mesoporous alumina, polystyrene, and others was explored for the separation of volatile organics from gas streams or the sequestration of atrazine from solution. The combination of these organics with metal nanoparticles has been probed. The goal of this review is to summarize these efforts.     

Hydrozirconation of first-generation allyl-functionalized dendrimers and dendrimer model compounds

Several allyl-functionalized dendrimers and mono-functional model compounds have been prepared. These have been hydrozirconated using [Cp₂ZrHCl]_x to give zirconocene terminated dendrimers. These dendrimers have been characterized using spectroscopic techniques, particularly NMR.     

Size and branching effects on the fluorescence of benzylic dendrimers possessing one apigenin fluorophore at the core

Different generations of dendrimers incorporating one fluorescent core of apigenin and three Fréchet benzylic dendrons have been prepared. The chief geometric features of these dendrimers have been obtained by Molecular Dynamics simulations. These computational data suggest that the asphericities of dendrimers belonging to the third and fourth generations are considerably larger than those associated with lower radii of gyration. Fluorescence spectra of high generation dendrimers evolve along time and quantum yields show an appreciable lowering for the fourth generation dendrimer. All these data suggest aggregation phenomena and lower quantum yields for nonspheric dendrimers in solution.     

含萘酰亚胺基树枝状化合物的研究进展

含萘酰亚胺基的树枝状化合物具有特殊的发光性能和电学性质,其中一个重要特征是它还具有优异的光诱导电子转移性能,从而引起了人们的广泛关注.近年来科学家们已经合成了多种新型的含萘酰亚胺基树枝状化合物,它们在众多领域具有潜在的应用价值.综述了近年来含萘酰亚胺基的树枝状化合物的研究进展,介绍了部分树枝状萘酰亚胺基化合物的合成及其应用,这些化合物由于其独特的结构特点而具有特殊的性能,在化学传感器、光捕获天线材料、有机电致发光器件、药物传输、环境污染检测等领域具有重要的应用价值.最后,展望了此类化合物良好的应用前景.     

New-generation biomedical materials: Peptide dendrimers and their application in biomedicine

Peptide dendrimers are attractive synthetic polymers and have been widely used as a new generation of biomaterials in recent years. Peptide dendrimers, as well as general dendrimers, may be synthesized to reach nano sizes, and display well-defined architectures, highly-branched structures, high density of functional terminal groups, and controllable molecular weights. On the other hand, peptide dendrimers have properties similar to proteins and some special characteristics, such as good biocompatibility, water solubility and resistance to proteolytic digestion. Due to these advantages, peptide dendrimers have received considerable attention in biomedicine. This review focuses on the development of peptide dendrimers with emphasis on their applications both in diagnostics and in therapy.     

α-环糊精/聚乙二醇自组装超分子纳米药物载体

研究了一种新型超分子纳米药物载体的制备方法及其药物释放性能. 将α-环糊精(α-CD)穿入肉桂酸改性的PEG分子链形成包含复合物(inclusion complex, IC), 通过超分子自组装成为纳米粒子. 将抗肿瘤药物阿霉素负载到纳米粒子中, 研究药物释放行为及其对肿瘤细胞的抑制效果. 以核磁共振(1H NMR)、X射线衍射(XRD)、紫外吸收光谱(UV)、动态光散射(DLS)、扫描电镜(SEM)、透射电镜(TEM)和原子力显微镜(AFM)表征了纳米粒子的结构和形貌, 用激光共聚焦显微镜(Confocal)研究了载药纳米粒子在细胞内的分布及其对肿瘤细胞的抑制效果. 结果显示超分子纳米粒子具有很好的生物相容性和药物缓释作用, 载药纳米粒子对肿瘤细胞具有很好的杀伤效果.     

Cobaltocenium-functionalized poly(propylene imine) dendrimers: redox and electromicrogravimetric studies and AFM imaging

The first four generations of cobaltocenium-functionalized, diaminobutane-based poly(propylene imine) dendrimers DAB-dend-Cb,(PFb)x (x = 4, 8, 16, and 32; Cb=[Co(eta5-C5H4CONH)(eta5-C5H5)] (1-4) have been synthesized and characterized. The redox activity of the cobaltocenium centers in 1-4 has been characterized by using cyclic voltammetry and the electrochemical quartz-crystal microbalance (EQCM). All of the dendrimers exhibit reversible redox chemistry associated with the cobaltocenium/cobaltocene redox couple. Upon reduction. the dendrimers exhibit a tendency to electrodeposit onto the electrode surface, which is more pronounced for the higher generations. Pt and glassy carbon electrodes could be modified with films derived from 1-4,exhibiting a well-defined and persistent electrochemical response. EQCM measurements show that the dendrimers adsorb, at open circuit, onto platinum surfaces at monolayer or submonolayer coverage. Cathodic potential scanning past -0.75 V at which the cobaltocenium sites are reduced, gave rise to the electrodeposition of multilayer equivalents of the dendrimers. The additional material gradually desorbs upon re-oxidation so that only a monolayer equivalent remains on the electrode surface. Changes in film morphology as a function of dendrimer generation and surface coverage were studied by using admittance measurements of the quartz-crystal resonator on the basis of its electrical equivalent circuit, especially in terms of its resistance parameter. In general, we find that films of the lower dendrimer generation 1 behave rigidly, whereas those of the higher generation 4 exhibit viscoelastic behavior with an intermediate behavior being exhibited by 2 and 3. Using tapping-mode atomic force microscopy (AFM). we have been able to obtain molecularly resolved images of dendrimer 4 adsorbed on a Pt(111) electrode.     

New-generation biomedical materials:Peptide dendrimers and their application in biomedicine

Peptide dendrimers are attractive synthetic polymers and have been widely used as a new generation of biomaterials in recent years.Peptide dendrimers,as well as general dendrimers,may be synthesized to reach nano sizes,and display well-defined architectures,highly-branched structures,high density of functional terminal groups,and controllable molecular weights.On the other hand,peptide dendrimers have properties similar to proteins and some special characteristics,such as good biocompatibility,water solubil...     

新型生物医用材料: 肽类树枝状大分子及其生物医学应用

肽类树枝状大分子是近年来发展起来的一类新型生物医用高分子材料, 它在具有普通树枝状大分子的特征如规整性、高度支化、表面呈现高密度功能团、尺度为纳米级、通过可控制备可得到单一分子量等之外, 同时还具有类似蛋白一样的球状结构、好的生物相容性、水溶性、耐蛋白酶水解、生物降解等独特的性能. 肽类树枝状大分子的上述特点, 使其在生物医学应用中显示出诱人的前景. 本综述从肽类树枝状大分子的制备出发、详尽介绍了肽类树枝状大分子的功能化及其在疾病诊断和治疗中的应用等方面的研究进展, 籍此推动肽类树枝状大分子在生物医学领域的研究与开发.