温度敏感型树枝状大分子衍生物的合成及药物控制释放

通过加入偶联剂活化末端羧基基团进行酰胺化反应, 将得到的带有羧基末端基团的温敏性聚N-异丙基丙烯酰胺接枝到整代的树枝状大分子聚酰胺-胺(PAMAM)上, 制备了树枝状大分子衍生物PAMAM-g-PNIPAm, 通过FTIR和¹H NMR表征其结构, 通过GPC和¹H NMR测定其分子量, 从而验证了接枝产物的形成; 通过紫外-可见分光光度计测定其在不同pH值缓冲液中的低临界溶胀/溶解温度(LCST)值, 发现产物的LCST值受缓冲液pH值的影响很大, 接枝前后的LCST值也发生了变化. 选用难溶性药物吲哚美辛作为模型药物, 考察了树枝状大分子及其温度敏感性衍生物PAMAM-g-PNIPAm作为载体对药物的包载、增溶和不同温度环境下的释放行为. 结果表明, 树枝状大分子衍生物对吲哚美辛具有增溶和控制释放的性能, 在难溶性药物的控制释放领域具有广阔的应用前景.     

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.     

含树枝状大分子PAMAM的苯乙烯乳液聚合

将树枝状大分子PAMAM (4 5代 )作为种子 ,以苯乙烯为代表性单体进行乳液聚合 .研究结果表明 ,加入树枝状大分子PAMAM时 ,所制得的聚合物乳液粒子平均粒径在 30～ 5 0nm之间 ,小于 10 0nm ,且大小分布均匀 ;所制备的聚合物在 16 70cm- 1 左右处出现酰胺的特征吸收峰 ,在 330 0cm- 1 左右处出现N—H伸缩振动特征峰 ;说明树枝状大分子PAMAM起到种子的作用 ,所制备的聚合物含树枝状大分子PAMAM .     

温度及pH敏感的树枝状高分子衍生物合成及药物控制释放研究

对合成的系列聚酰胺-胺型(PAMAM)树枝状高分子进行端基的羟基化和氯乙酰化两步修饰,使PAMAM最外层接上烷基氯.以修饰产物为引发剂,通过原子转移自由基引发甲基丙烯酸N,N-二甲氨基乙酯(DMAEMA)聚合得到树枝状PAMAM高分子衍生物,并对其结构用FTIR、1H-NMR和粒径分析进行了表征.紫外可见分光光度仪测定证实此高分子具有温度及pH敏感性.通过对小分子药物控制释放研究表明,此树枝状高分子衍生物通过环境pH值可有效地控制小分子药物的释放.     

(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.     

微波辅助合成法制备聚酰胺-胺树枝状分子修饰的开管毛细管电色谱柱

采用微波辅助合成技术,快速制备以聚酰胺-胺(poly(amidoamine),PAMAM)树枝状分子为固定相的开管毛细管电色谱柱.与常规合成方法相比,微波辅助合成法可以提高反应速度,极大地缩短制备周期.在pH 5.7～8.0范围内, 随着PAMAM树枝状分子代数的增加,毛细管电渗流(EOF)逐步下降.对丙氨酸和脯氨酸进行分离的实验结果表明,随着PAMAM树枝状分子代数的增加,分离度逐步增大,3代PAMAM树枝状分子修饰的毛细管柱具有良好的分离效果.以丙酮标记物连续测定10 d,柱效下降3.85%, 表明采用微波辅助合成技术制得的PAMAM树枝状分子修饰的毛细管柱具有良好的稳定性.     

两亲性超支化聚(酯-胺)在染料相转移中的应用

具有树枝状结构的大分子由于其独特的结构、大量的分子内空穴、可修饰的表面端基及良好的溶解性，已被用作主体分子与客体分子进行复合，并在药物释放、纤维染色、印刷、传感器等方面显示良好的应用前景。通过长烷基链或氟碳链改性的两亲性树枝状分子可以将水溶性酸性染料     

以枝形大分子聚酰胺-胺(PAMAM)为键合固定相的开管毛细管电色谱柱的制备及评价

用3-氨丙基三乙氧基硅烷(KH550)作偶联剂, 在毛细管内壁上逐步合成树枝形大分子聚酰胺-胺(PAMAM), 制得了1, 2和3代PAMAM键合的开管毛细管电色谱柱, 并对其性能进行了研究. 结果表明, 随着大分子代数的增加, 毛细管电渗流(EOF)逐步下降. 利用制得的1, 2和3代PAMAM修饰的开管毛细管电色谱柱对丙氨酸和脯氨酸的分离进行对比, 结果显示, 随着大分子PAMAM代数的增加, 分离度逐步增大, 丙氨酸和脯氨酸可在3代树枝状大分子PAMAM修饰的开管毛细管电色谱柱上达到基线分离. 采用非衍生化法和3代PAMAM修饰的开管毛细管电色谱柱成功地分析了精氨酸、 丙氨酸、 脯氨酸、 甲硫氨酸和组氨酸. 结果表明, 键合毛细管柱具有良好的重现性和稳定性.     

树枝状大分子PAMAM合成及对蒙脱土插层改性和应用研究

有机阳离子改性蒙脱土已广泛应用于聚合物改性制备高性能聚合物。本文合成了不同代数G0(零代)、G2(二代)的树枝状大分子聚酰胺-胺(PAMAM),同时对G0、G2代PAMAM进行了季铵化改性,得到了PAMAM季铵盐,进一步用PAMAM季铵盐插层改性钠基蒙脱土(Na+-MMT)得到了PAMAM季铵盐改性蒙脱土(PAMAM/MMT)。XRD分析表明,PAMAM季铵盐己与Na+-MMT中的Na+进行了离子交换,同时提出了G0、G2代PAMAM季铵盐对MMT的双分子和单分子插层模型。进一步研究了PAMAM/MMT对聚碳酸酯(PC)的流变性能的影响规律,结果表明PAMAM/MMT可明显降低聚碳酸酯熔融剪切粘度,有利于提高其加工性能。     

聚酰胺-胺基两亲树枝状大分子与十二烷基硫酸钠混合体系的分子聚集行为

以浊度分析、动态激光光散射(DLS)、透射电子显微镜(TEM)以及原子力显微镜(AFM)等方法研究了以1.0代(G1)聚酰胺-胺(PAMAM)为核心、以聚环氧丙烷-聚环氧乙烷(PPO-PEO)为辐射臂的树枝状大分子与十二烷基硫酸钠(SDS)之间的相互作用.值得注意的是,当树枝状大分子溶液的浓度为1%(质量分数),SDS的浓度远低于临界胶束浓度(cmc)时,体系的浊度值开始明显升高,DLS、TEM以及AFM的研究结果显示出此时聚集体的尺寸逐渐增加,意味着SDS与树枝状大分子有着很强的分子间相互作用,形成了树枝状大分子与SDS构成的复合物.当SDS浓度增高至0.1mmol·L-1(约为cmc的1%)左右时,体系的浊度值随着SDS浓度的增加变化不大,DLS、TEM、AFM的实验结果显示,聚集体尺寸趋于稳定状态.当SDS的浓度继续升高至0.25和0.5mol·L-1时,体系中形成了SDS分子间的自聚集或者存在多个SDS分子与单个树枝状大分子的分子间聚集.     

A structural study of amphiphilic PAMAM (poly(amido amine)) dendrimers in Langmuir and Langmuir-Blodgett films

Two amphiphilic PAMAM dendrimers are synthesized by attaching 12-hydroxydodecanoic acid (HA) chains to a poly(amido amine) (PAMAM) dendrimer core (including generation I and generation II). The limiting molecular area obtained from the surface pressure-area isotherm at the air/water interface suggests the edge-on configuration for both dendrimers in Langmuir films. The edge-on arrangement is also supported by the atomic force microscopic (AFM) studies of the Langmuir-Blodgett films.     

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.     

聚酰胺-胺型树枝状化合物与细胞色素C的结合作用

制备具有分子识别功能的材料 ,特别是设计合成某种分子 ,使其能够识别蛋白质表面 ,并干扰或促进蛋白质的特定生理功能 ,是生物有机化学中一个尚待解决的重要问题 ,也是揭开蛋白质分子识别与相互作用机理的重要问题 .人们对生物大分子———蛋白质分子之间的识别和相互作用进行了广泛的研究 ,总结出了一些规律 .( 1 )蛋白质复合物中最直接相互作用的残基数目共为 2 7～44个 ,相对与总的残基数来说很少 ,但是对分子间的识别和稳定作用却起决定性作用 ;( 2 )蛋白质复合物的接触面积为 6～ 1 0ｎｍ2 ,既需要比较大的接触面积 ,复合物才比较稳定 …     

小肽修饰的PAMAM树枝状化合物的生物活性

合成了甘氨酸 (Gly) 天冬氨酸 (Asp)组成的肽链Gly Asp、Gly Asp Gly Asp、Gly Asp (Gly Asp) 2 .分别将天冬氨酸及上述合成的肽链引入到聚酰胺 胺型树枝状化合物 (PAMAM)的表面 .对所得化合物进行了分子模拟 ,结果表明Gly Asp (Gly Asp) 2 肽链在PAMAM表面可形成接近于 β sheet的构象 .由实验得知 ,经Asp、Gly Asp、Gly Asp Gly Asp、Gly Asp (Gly Asp) 2 修饰的PAMAM树枝状化合物对抗坏血酸还原FeⅢ 细胞色素C(cytc)的反应有干扰作用 ,导致该反应速率下降 .这说明所合成的化合物与cytc有较好的结合能力 .特别是Gly Asp (Gly Asp) 2 修饰的PAMAM ,其与cytc的结合常数为 1 6ⅹ 1 0 5.     

PAMAM树状大分子对酮基布洛芬溶解度的影响

以酮洛芬为模型药物,研究聚酰胺-胺(PAMAM)树状大分子对酮洛芬的增溶作用,并探讨其作用机理.采用紫外光谱法测定了G1.0、G1.5、G2.0、G2.5、G3.0、G3.5PAMAM在不同浓度和不同pH时对酮洛芬的增溶量.并运用计算机模拟方法对PAMAM与酮洛芬相互作用的机理进行了探讨.实验结果表明,酮洛芬的溶解度随溶液pH值变化而变化,在pH4.0～6.0范围内,PAMAM树状大分子对酮洛芬的增溶量随着PAMAM的代数、浓度和溶液pH的增加而增大.整代和半代都具有增溶作用.然而,在同一pH条件下,对于具有相同官能团数目的整代和半代,整代增溶效果要高于半代.计算机模拟结果表明PAMAM与酮洛芬主要靠静电作用力结合.增溶机理可能是酮洛芬的羧基与PAMAM的伯胺和叔胺发生静电作用.     

Polyamidoamine dendrimers surface-engineered with biomimetic phosphorylcholine as potential drug delivery carriers

Biomimetic acryloyloxyethyl phosphorylcholine (APC) was used to react with generation 5 poly(amido amine) (PAMAM) dendrimers (G5) via the Michael addition reaction between primary amino group of PAMAM dendrimers and acrylic functional group of APC. FTIR and (1)H NMR confirmed the success of surface modification of G5. The primary amino and phosphorylcholine (PC) group numbers of the surface engineered PAMAM dendrimers (G5-PC) were calculated to be 56 and 50 via (1)H NMR and potentiometric titration. Cell viability and cell morphology studies indicated that biomimetic phosphorylcholine surface engineering successfully lowered the cytotoxicity of G5 PAMAM dendrimers. The hydrophobic interior of G5-PC was used to incorporate anti-cancer drug Adriamycin (ADR) and the G5-PC showed sustained releasing behavior for ADR. Cell morphology and viability tests indicated that the drug-loaded G5-PC conjugate could effectively enter the cancer cells and inhibit the growth of cancer cells. Biomimetic phosphorylcholine surface engineered PAMAM dendrimers with lowered cytotoxicity and high cellular penetrating ability showed great potential for the biomedical applications as nanocarrier system.     

环糊精修饰聚酰胺-胺树状高分子的合成及其与乳酸左氧氟沙星的作用研究

合成了一系列以环糊精修饰的树状高分子化合物PAMAM(G2,G4)-β-CD,用IR,1H-NMR等手段表征了其结构,并采用荧光光谱法对其在缓冲溶液中与乳酸左氧氟沙星(LFL)的相互作用进行了研究.结果表明,经环糊精修饰树状高分子的增敏率远大于未修饰的和天然环糊精,且随代数和环糊精含量的增加而增大,表明其具有强于相同代数PAMAM的分子键合能力,这些强的键合能力源于环糊精修饰树状高分子化合物中两种结构单元的疏水作用、静电作用和氢键作用的协同效应.     

CE of poly(amidoamine) succinamic acid dendrimers using a poly(vinyl alcohol)-coated capillary

Various generations (G1-G8) of negatively charged poly(amidoamine) (PAMAM) succinamic acid dendrimers (PAMAM-SAH) were analyzed by CE using a poly(vinyl alcohol)-coated capillary. Due to its excellent stability and osmotic flow-shielding effect, highly reproducible migration times were achieved for all generations of dendrimer (e.g., RSD for the migration times of G5 dendrimer was 0.6%). We also observed a reverse trend in migration times for the PAMAM-SAH dendrimers (i.e., higher generations migrated faster than lower generation dendrimers) compared to amine-terminated PAMAM dendrimers reported in the literature. This reversal in migration times was attributed to the difference in counterion binding around these negatively charged dendrimers. This reverse trend allowed a generational separation for lower generation (G1-G3) dendrimers. However, a sufficient resolution for the migration peaks of higher generations (G4-G5) in a mixture could not be achieved. This could be due to their nearly identical charge/mass ratio and dense molecular conformations. In addition, we show that dye-functionalized PAMAM-SAH dendrimers can also be analyzed with high reproducibility using this method.     

Specific binding structures of dendrimers on lipid bilayer membranes

Dissipative particle dynamics simulations are used to study the specific binding structures of polyamidoamine (PAMAM) dendrimers on amphiphilic membranes and the permeation mechanisms. Mutually consistent coarse-grained (CG) models both for PAMAM dendrimers and for dimyristoylphosphatidylcholine (DMPC) lipid molecules are constructed. The PAMAM CG model describes correctly the conformational behavior of the dendrimers, and the DMPC CG model can properly give the surface tension of the amphiphilic membrane. A series of systematic simulations is performed to investigate the binding structures of the dendrimers on membranes with varied length of the hydrophobic tails of amphiphiles. The permeability of dendrimers across membranes is enhanced upon increasing the dendrimer size (generation). The length of the hydrophobic tails of amphiphiles in turn affects the dendrimer conformation, as well as the binding structure of the dendrimer-membrane complexes. The negative curvature of the membrane formed in the dendrimer-membrane complexes is related to dendrimer concentration. Higher dendrimer concentration together with increased dendrimer generation is observed to enhance the permeability of dendrimers across the amphiphilic membranes.     

Synthesis of conjugates of β-cyclodextrin with polyamidoamine dendrimers and their molecular inclusion interaction with levofloxacin lactate

Polyamidoamine (PAMAM) dendrimers of different generations (G2 and G4) conjugated with β-cyclodextrin (β-CD), PAMAM (G2, G4)-CD, were synthesized using substitution reaction from mono-6-iodine-β-cyclodextrin and PAMAM dendrimers. The resulting molecular structures were characterized by NMR, IR. The molecular interaction between various dendrimers and levofloxacin lactate (LFL) were investigated by monitoring the fluorescence of LFL in the presence of dendrimers in buffer solution (pH 7.4) at 25?°C. It was found that the PAMAM (G2, G4)-CD possesses higher sensitizing ability than that of the corresponding parent dendrimers and natural β-CD, and increases concomitantly with the increases of generation and content of β-CD, suggesting that the PAMAM (G2, G4)-CD possesses stronger inclusion ability with LFL. The possible interaction mechanism between PAMAM-CD and LFL was proposed by ¹H NMR analysis and theoretical calculation. The results show that the LFL molecule is located at the amine end of dendrimer molecule and along the side of cyclodextrin cavities to form supramolecular complexes. Furthermore, results indicate that the main driving force of the complex could be attributed to the electrostatic interactions and hydrogen bonding between LFL and PAMAM-CD, as well as the synergistic effect of intermolecular forces.