水溶性吡啶萘酰亚胺-聚酰胺-胺荧光树形分子的合成、聚集诱导荧光增强及细胞成像

将具有聚集诱导荧光的4-(2-吡啶乙烯基)-1,8-萘酰亚胺单元通过酰胺化反应连接到聚酰胺-胺(PAMAM)树形分子上,制备了一种水溶性吡啶萘酰亚胺-聚酰胺-胺荧光树形分子PN-PAMAM.结构经核磁共振氢谱、核磁共振碳谱、红外及高分辨质谱表征.吡啶萘酰亚胺-聚酰胺-胺树形分子PN-PAMAM具有明显的聚集诱导荧光增强(AIEE)特性.在固体态时的最大荧光发射波长为532 nm,紫外灯下发出黄绿色荧光.在纯水中的最大荧光发射波长为494 nm,荧光量子产率为4.42%.在水含量为60%的水/四氢呋喃混合溶液中,其荧光强度达到最大,荧光发射波长为485 nm,荧光量子产率增大到17.54%.制备了一种负载聚集诱导荧光染料PN-PAMAM的二氧化硅纳米粒子PN-PAMAM/Si O_2,测得该纳米粒子的荧光发射波长为473 nm,粒径约为40 nm.测定了水溶液中树形分子PN-PAMAM与乳腺癌细胞MCF-7共同孵化后的共聚焦荧光成像,得到清晰的蓝场荧光照片.研究表明,吡啶萘酰亚胺-聚酰胺-胺树形分子PN-PAMAM是一种水溶性荧光分子,具有明显的聚集诱导荧光增强特性,可广泛应用于肿瘤定位、生物追踪及纳米材料等重要领域.     

以聚酰胺-胺树形分子为模板制备AgI纳米簇

本文以聚酰胺-胺(PAMAM)树形分子为模板,原位制备AgI纳米簇.系统地研究了AgI纳米簇制备过程中各种反应条件如树形分子端基、反应时间、Ag⁺与PAMAM摩尔比等对AgI纳米簇粒径的影响,分别用紫外-可见光谱、荧光光谱、透射电镜等对所制备的纳米簇进行表征.在相同的条件下,以G4.5-COOH₃为模板较以G5.0-NH₂为模板制备的AgI纳米簇粒径小、分布均匀,这主要取决于G4.5-COOCH₃PAMAM树形分子所起的“内模板”作用.G4.5-COOH₃树形分子浓度为1×10^-5mol/L,Ag⁺与树形分子摩尔比为30:1时所制备的AgI纳米簇的粒径分布均匀、稳定性好,室温避光可稳定存在两个月以上.     

低代端酯基PAMAM树形分子存在下银纳米颗粒的制备

在低代端酯基PAMAM树形分子(G1.5-COOCH₃)存在时，用氢气还原AgNO₃制备出银纳米颗粒。用透射电子显微镜(TEM)，电子衍射(ED)，紫外-可见吸收光谱(UV-Vis)和红外光谱(FT-IR)对所制备的银纳米颗粒进行了表征。实验结果表明，当用氢气作为还原剂时，以低代树形分子为保护剂，通过优化还原条件，可成功制备尺寸稳定、均一的银纳米颗粒，其粒径为2.9±0.5 nm，且所制备的银纳米颗粒的粒径分布较窄。根据树形分子的理论尺寸与制备的银纳米颗粒的粒径关系，可推断出大多数的银纳米颗粒是由多个树形分子所包围而稳定存在。     

紫外光辐照下以PAMAM树形分子为模板制备Ag纳米簇及光致发光性能研究

以G5.0-OH PAMAM树形分子为模板,用紫外光辐照法制备银纳米簇.用透射电子显微镜、紫外-可见吸收光谱和共振散射光谱等对所制备的银纳米簇进行了表征.结果表明:用紫外光辐照法可以制备尺寸分布均匀、稳定的银纳米簇;且辐照时间、PAMAM树形分子的浓度及Ag⁺/PAMAM树形分子的摩尔比都会对所制备的银纳米簇产生较大的影响.由于所制备的银纳米簇的粒径小于树形分子的流体力学半径,表明树形分子起到了“内模板”作用.同时研究了银纳米簇的尺寸对其光致发光性能的影响,发现通过调节银纳米簇的尺寸可实现其光致发光的可调性.     

以树形分子为模板制备银纳米颗粒

以硝酸银为原料,硼氢化钠为还原剂,PAMAM树形分子为模板兼稳定剂,制备出粒径分布范围在4～7mm的银纳米颗粒．实验发现,其他条件相同时,银纳米颗粒的粒径随着Ag^ ／树形分子摩尔比的增加而增加,并且树形分子代数越高,所起的模板作用越显著．还研究了溶液pH值的影响,发现当溶液pH值在7左右时,可以制得粒径较小、分散性较好的银纳米颗粒．用紫外-可见光谱,透射电镜(TEM)以及原子力显微镜(AFM)等测试手段对所制得的银纳米颗粒进行了表征．     

荧光性聚酰胺-胺树形分子在潜指纹显现中的应用研究

本文系统研究了不同条件(树形分子代数、浓度、浸泡时间等)下荧光性聚酰胺-胺树形分子(PAMAM)水溶液作为荧光探针对锡纸、透明胶带等基底上油印潜指纹的显现效果.结果发现PAMAM树形分子可以和指纹残留物进行靶向结合.结合到指纹纹线上的该荧光性纳米材料在暗室中365 nm紫外光的激发下发出明亮的蓝色荧光,指印纹线与基底反差大、指纹易于辨认,且操作简单,试剂完全环保无污染.这些结果表明PAMAM水溶液是一种潜在的优良的指纹显现试剂.最后,把PAMAM树形分子水溶液对指纹的显现效果进行量化处理,乳突纹与基底间的灰度对比度达到90%以上.     

AgBr纳米簇：PAMAM树形分子模板法制备及光催化性能研究

以酯端基聚酰胺-胺(PAMAM)树形分子为模板，原位制备了AgBr纳米簇。由于酯端基的半代PAMAM树形分子起到“内模板”作用，制得的AgBr纳米簇粒径小、尺寸分布窄、稳定性好，并通过改变Ag⁺∶PAMAM树形分子的物质的量的比可以精确控制纳米簇的尺寸。AgBr纳米簇/树形分子纳米复合材料在光催化降解甲基橙方面具有很好的催化能力，且随纳米簇的尺寸减小，其催化能力增强。     

聚酰胺-胺型树形分子模板法制备Pt纳米簇

利用紫外-可见吸收光谱和红外光谱对Pt2＋与G5.5-COOCH3聚酰胺-胺型树形分子的络合机理进行了研究, 结果表明Pt2＋与G5.5-COOCH3 PAMAM的最外层叔胺基发生络合作用, 但两者之间达到络合平衡需要较长时间, 且平衡时间随Pt2＋与树形分子物质的量比增大而增长; Pt2＋与G5.5-COOCH3树形分子的最大络合数为50～55; 采用硼氢化钠还原法原位制备了G5.5-COOCH3 PAMAM包裹、平均粒径小于2 nm、多晶的球形Pt纳米簇, 并研究了Pt2＋与PAMAM物质的量比对Pt纳米簇形貌的影响, 实验结果表明, Pt2＋与PAMAM物质的量比为10时, 生成尺寸较小分布较窄的内型Pt纳米簇/树形分子复合材料, 而物质的量比为50时, 会生成部分尺寸较大、分布较宽的外型Pt纳米簇/树形分子纳米复合材料.     

PAMAM树形分子与Cd2＋的配位作用研究及CdS/PAMAM纳米复合材料的制备与表征

CdS半导体纳米簇具有独特的光、电性能, 如何制备均匀分散的、能够稳定存在的CdS纳米簇是目前的研究热点之一. 以聚酰胺-胺(PAMAM)树形分子为模板, 原位合成了CdS纳米簇. 首先用UV-Vis分光光度法研究了与树形分子的配位机理, 得出G4.5和G5.0的平均饱和配位数分别为16和34, 并发现在G4.5PAMAM树形分子中Cd^2＋主要与最外层叔胺基配位, 在G5.0PAMAM树形分子中Cd^2＋主要与最外层伯胺基配位. 酯端基的G4.5的模板作用要明显优于胺端基的G5.0. 通过改变Cd^2＋与G4.5树形分子的摩尔比可以得到不同粒径的CdS纳米簇. 溶液的pH值对CdS纳米簇影响很大, pH在7.0左右制备的CdS纳米簇粒径小而均匀, 且溶液稳定性高. 用UV-Vis分光光度计和TEM对CdS纳米簇的大小和形貌进行了表征. 结果表明TEM观测CdS纳米簇的粒径要大于用Brus公式的估算值.     

PAMAM树形分子与Cd2＋的配位作用研究及CdS/PAMAM纳米复合材料的制备与表征

CdS半导体纳米簇具有独特的光、电性能, 如何制备均匀分散的、能够稳定存在的CdS纳米簇是目前的研究热点之一. 以聚酰胺-胺(PAMAM)树形分子为模板, 原位合成了CdS纳米簇. 首先用UV-Vis分光光度法研究了与树形分子的配位机理, 得出G4.5和G5.0的平均饱和配位数分别为16和34, 并发现在G4.5PAMAM树形分子中Cd^2＋主要与最外层叔胺基配位, 在G5.0PAMAM树形分子中Cd^2＋主要与最外层伯胺基配位. 酯端基的G4.5的模板作用要明显优于胺端基的G5.0. 通过改变Cd^2＋与G4.5树形分子的摩尔比可以得到不同粒径的CdS纳米簇. 溶液的pH值对CdS纳米簇影响很大, pH在7.0左右制备的CdS纳米簇粒径小而均匀, 且溶液稳定性高. 用UV-Vis分光光度计和TEM对CdS纳米簇的大小和形貌进行了表征. 结果表明TEM观测CdS纳米簇的粒径要大于用Brus公式的估算值.     

Air and water free solid-phase synthesis of thiol stabilized au nanoparticles with anchored, recyclable dendrimer templates

Solid-phase synthetic templates for Au nanoparticles were developed using Merrifield resins and polyamidoamine (PAMAM) dendrimers. This synthetic scheme affords the opportunity to prepare metal nanoparticles in the absence of air and water, and it does not necessitate phase transfer agents that can be difficult to remove in subsequent steps. Amine-terminated generation 5 PAMAM (G5NH2) dendrimers were grafted to anhydride functionalized polystyrene resin beads and alkylated with 1,2-epoxydodecane to produce G5C12anch. The anchored dendrimers bound both CoII and AuIII salts from toluene solutions at ratios comparable to those of solution phase alkyl-terminated PAMAM dendrimers. The encapsulated AuIII salts could be reduced with NaBH4 to produce anchored dendrimer encapsulated nanoparticles (DENs). Treatment of the anchored DENs with decanethiol in toluene extracted the Au nanoparticles from the dendrimers as monolayer protected clusters (MPCs). After a brief NaCN etch, the anchored dendrimers were readily recycled and a subsequent synthesis of decanethiol Au MPCs was performed with comparable MPC yield and particle size distribution.     

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.     

Synthesis and catalytic activity of gold-silver binary nanoparticles stabilized by PAMAM dendrimer

Gold-silver binary nanoparticles, which feed atomic ratios of gold to silver were 3:1, 1:1, and 1:3, were prepared. These particles were stabilized by amine-terminated (generation (G) 3.0 and 5.0) and carboxyl-terminated (G 3.5 and 5.5) poly(amidoamine) (PAMAM) dendrimers in water. UV-vis spectra indicate that the particles are not mere physical mixtures of monometallic particles or core/shell type but alloy. According to transmission electron microscope (TEM) observation, the mean diameters of the particles were 7-10 nm for silver particles and 3-4 nm for both gold and alloy particles, respectively. Catalytic activities for reduction of p-nitrophenol were investigated by monitoring the absorbance at 400 nm during the reaction. They were proportional to the feed ratio of gold in the particles and showed a maximum at the ratio of Au:Ag=3:1.     

微波法制备3.5 G PAMAM树状大分子保护的金纳米粒子

以3.5 G PAMAM(3.5代聚酰胺-胺型)树状大分子为保护剂,利用微波法还原HAuCl₄溶液制备金纳米粒子.考察了当3.5 G PAMAM与HAuCl₄物质的量的比一定时,微波照射不同时间对金纳米粒子大小及形状的影响;以及同一照射条件下,3.5 G PAMAM与HAuCl₄不同的物质的量比值对金纳米粒子大小及形状的影响.利用紫外可见分光光度计、透射电子显微镜对其进行了表征.结果表明,当3.5 G PAMAM与HAuCl₄物质的量的比值一定时,金纳米粒子的形状和大小受微波照射时间长短的影响不大;适当延长照射时间,制得的金纳米粒子的分散性较好.在相同照射条件下,随着3.5 G PAMAM与HAu-Cl₄物质的量比值的减小,得到的金纳米粒子粒径逐渐变大,且分散性变差.     

两亲性树枝状大分子作为药物缓释载体的研究

利用胆酸对1代聚酰胺-胺树枝状大分子进行修饰,得到两亲性树枝状大分子(PAMAM1-CA6)。采用1H-NMR和酸碱滴定法测得每个1代PAMAM分子上共价键连了6个胆酸分子。PAMAM1-CA6在水相中自组装成纳米粒子,粒径约为273nm。以抗癌药物氨甲喋呤为模型考察了此两亲性树枝状大分子对药物的缓释行为。在碱性条件下(pH=10),PAMAM1-CA6对氨甲喋呤的释放较为缓慢;随着溶液pH的降低,药物的释放速率明显加快。说明PAMAM1-CA6对氨甲喋呤的释放具有环境响应性。体外细胞实验的结果表明,PAMAM1-CA6能够显著地提高氨甲喋呤的疗效。因此,这类由低代树枝状大分子制得的材料有望成为新型的药物控释载体。     

Hydrophobic dendrimers as templates for au nanoparticles

We report the synthesis, characterization, and extraction of Au dendrimer-encapsulated nanoparticles (DENs) prepared in organic solvents. DENs composed of 31 and 55 Au atoms were prepared using organic solvents and poly(amidoamine) (PAMAM) dendrimer templates modified on their periphery with dodecyl groups. The spectral and microscopic properties of the resulting materials were identical to those prepared using water-soluble PAMAM dendrimers. It was possible to extract the organic-soluble DENs into water using the water-soluble thiols tiopronin and glutathione. The properties of the resulting monolayer-protected clusters were nearly identical to those of the precursor DENs. A mechanistic model for the extraction process is discussed. The synthetic methodology reported here provides a convenient method for preparing DENs of non noble metals such as Ni and Fe.     

Morphological change of gold-dendrimer nanocomposites by laser irradiation

Gold-dendrimer nanocomposites are prepared in aqueous solutions in the presence of poly(amidoamine)dendrimers (PAMAM) (generation 3 and 5) or poly(propyleneimine)dendrimers (PPI) (generation 3 and 4) by wet chemical NaBH(4) method. Thus prepared gold-dendrimer nanocomposites are irradiated by laser at 532 nm. UV-vis absorption spectroscopy and transmission electron microscopy reveal that the gold nanoparticles grow with the laser irradiation time as well as the fluence of the laser; in particular, the gold nanoparticles prepared at lower concentrations of PAMAM dendrimer as well as lower generations of PAMAM grow significantly. On the other hand, in the case of PPI dendrimers, the gold nanoparticles hardly grow by irradiation. In addition, dynamic light-scattering measurements show that the laser irradiation markedly promotes the association of the gold-PAMAM G3 dendrimer nanocomposites compared to that of the gold-PAMAM G5 dendrimer nanocomposites, while the sizes of association for the gold-PPI G3, G4 dendrimer nanocomposites hardly change by laser irradiation.     

Effect of the surface functional groups of dendrimer-entrapped gold nanoparticles on the improvement of PCR

PCR has been identified as one of the most important tools in molecular biology and clinical medicine. Improvement of the specificity and efficiency of PCR is often required, and it still remains a great challenge. Here, we introduce the use of dendrimer-entrapped gold nanoparticles (Au DENPs) with different terminal groups prepared using poly(amidoamine) (PAMAM) dendrimers of generation 5 (G5) as a novel class of enhancers to improve the specificity and efficiency of PCR amplification. We show that the optimum concentrations of all the tested Au DENPs are lower than those of the corresponding PAMAM dendrimers without gold nanoparticles (AuNPs). For amine-terminated [(Au(0) )(51.2) -G5.NH(2) ] DENPs, the optimum required concentration is slightly lower than that of G5.NH(2) dendrimers, whereas for glycidol-modified [(Au(0) )(51.2) -G5.NGlyOH] and acetylated [(Au(0) )(51.2) -G5.NHAc] DENPs, the optimum required concentrations are one and three magnitude lower than the corresponding dendrimers, respectively. Our results suggest that the entrapment of AuNPs within the dendrimer interior helps to reserve the 3D spherical morphology of dendrimers, allowing for enhanced interaction with the PCR components. Simultaneously, because of the existence of thermal conductive AuNPs, the enhanced local heat transfer rate may afford decreased chances of mispairing between primers and templates, which is beneficial for enhancing the PCR specificity and efficiency. Therefore, the use of Au DENPs as a novel class of PCR enhancers may enable both improved interaction with the PCR components and the thermal conductivity, which allow them to be used for enhancing different error-prone PCR systems.     

溶剂对聚酰胺-胺树形分子模板法原位制备CdS量子点的影响

为了研究非配位型溶剂对聚酰胺-胺(PAMAM)树形分子的模板法制备CdS量子点的影响, 分别以水、甲醇及二者的混合物( ∶ ＝2∶1)为溶剂, 以4.5代PAMAM树形分子为模板制备了CdS量子点. 结果表明, 相同条件下, 以甲醇为溶剂时制备的CdS量子点为单晶, 平均直径2.7 nm, 尺寸分布窄, 发光强度高; 以水为溶剂制备的CdS量子点为多晶, 平均直径为5.7 nm, 尺寸分布宽, 发光强度低; 在甲醇与水的混合溶剂中制备的CdS量子点为单晶和多晶共存, 平均直径为4.1 nm, 尺寸分布及发光强度都居中. 这主要是由于树形分子的模板作用不同造成的. 树形分子在甲醇中能充分伸展, 起到内模板作用; 树形分子与水之间由双氢键作用而产生交联, 不利于Cd^2＋与树形分子内部基团的配位, 主要起到外模板作用; 在甲醇与水的混合溶剂中, 树形分子则同时起到了内模板和外模板作用.