差别性释放两种药物的层层组装聚合物膜

基于层层组装技术制备了能够差别性释放2种药物的聚合物复合膜.通过大分子前体药物透明质酸-阿霉素(HA-DOX)与壳聚糖(HACC)的层层组装以及膜内后扩散负载甲氨喋呤二钠盐(MTX)的方法,实现了DOX和MTX 2种药物分子在聚合物膜中的负载.DOX和MTX在癌变组织的酸性环境下具有差别性的释放动力学,MTX在24 h内快速释放,而DOX长效缓释达10 d.细胞实验结果表明,差别性释放的DOX和MTX可有效地抑制癌细胞的增殖.     

聚合物复合物层层组装膜

层层组装是一种基于物质交替沉积而制备复合膜的方法,可以实现膜的结构和组成的精确调控.聚合物复合物是基于各种分子间弱相互作用力而形成的超分子聚集体,其种类包括聚阳离子-聚阴离子复合物、聚电解质-有机小分子复合物、中性聚合物-聚合物复合物以及聚合物-无机杂化复合物等.在本文中,以作者的研究结果为基础,阐明聚合物复合物的层层组装是一种方便、快捷的功能复合膜的构筑方法,具有如下优点:(1)聚合物复合物大的尺度可以实现聚合物复合物层层组装膜的快速构筑;(2)聚合物复合物的结构在组装溶液中和成膜后都容易调控,方便聚合物复合物层层组装膜结构的精细调控.(3)聚合物复合物层层组装膜可以构筑非复合的聚合物层层组装所不能获得的膜结构及功能.     

导尿管表面具有抗菌功能的层层组装微凝胶膜

以化学交联的聚烯丙基胺盐酸盐拟葡聚糖微凝胶和透明质酸为构筑基元,在导尿管表面层层组装构筑了厚度小于500 nm可控释放抗菌药物的聚合物微凝胶膜。 广谱抗菌药物头孢曲松钠通过扩散吸附的方法在2 min内快速负载到聚合物微凝胶膜中,并且在生理盐水中可控释放时间达3 h。 抗菌实验表明,组装有层层组装微凝胶膜并负载广谱抗菌药物的导尿管具有令人满意的抗菌效果,避免感染的发生。     

表面活性剂胶束实现疏水分子在聚合物微凝胶层层组装膜中的高效负载

基于层层组装技术制备了聚烯丙基胺-葡聚糖微凝胶(记作PAH-D)/透明质酸钠(HA)膜, 将包覆有芘分子的十二烷基硫酸钠(SDS)表面活性剂胶束基于静电作用力负载到PAH-D/HA微凝胶膜中, 实现了疏水分子芘在微凝胶膜中的高效负载. 紫外-可见吸收光谱和荧光光谱证实了SDS胶束包覆的芘分子被稳定地负载在PAH-D微凝胶膜中. 透过光谱表明负载有芘分子的(PAH-D/HA)*10微凝胶膜在可见光区仍保持良好光学透过性. 芘在膜中的负载量可以通过改变PAH-D/HA微凝胶膜的沉积周期数和SDS胶束中包覆芘分子的浓度而实现调控. 具有光致变色性质的螺吡喃分子同样可以借助SDS胶束负载到PAH-D/HA微凝胶膜中, 制备具有光致变色性质的层层组装膜. 本工作为疏水有机分子在层层组装聚合物膜中的高效负载提供了一种简便、易行的方法.     

壳聚糖-纤维素硫酸钠聚电解质复合物膜对药物表观渗透系数的测试

药物渗透系数是考察复合物膜的药物释放性能的重要参数. 本文以溶解性不同的两种药物扑热息痛和5-氨基水杨酸(5-ASA)为模型药物研究了其在壳聚糖-纤维素硫酸钠聚电解质复合物膜中的渗透性能. 结果表明：壳聚糖-纤维素硫酸钠聚电解质复合物膜的渗透性能与其溶胀性能密切相关;复合物膜中壳聚糖和纤维素硫酸钠的配比、相对分子量和pH值对膜的渗透性能和溶胀性能影响显著,以扑热息痛作为模型药物研究了壳聚糖-纤维素硫酸钠聚电解质复合物膜在模拟胃肠液中对药物的渗透性能. 通过调整该复合物膜的配方,可以使该膜分别实现胃、小肠和结肠定位释药的目的.     

壳聚糖-纤维素硫酸钠聚电解质复合物膜对药物表观渗透系数的测试(英文)

药物渗透系数是考察复合物膜的药物释放性能的重要参数.本文以溶解性不同的两种药物扑热息痛和5-氨基水杨酸(5-ASA)为模型药物研究了其在壳聚糖-纤维素硫酸钠聚电解质复合物膜中的渗透性能.结果表明:壳聚糖-纤维素硫酸钠聚电解质复合物膜的渗透性能与其溶胀性能密切相关;复合物膜中壳聚糖和纤维素硫酸钠的配比、相对分子量和pH值对膜的渗透性能和溶胀性能影响显著,以扑热息痛作为模型药物研究了壳聚糖-纤维素硫酸钠聚电解质复合物膜在模拟胃肠液中对药物的渗透性能.通过调整该复合物膜的配方,可以使该膜分别实现胃、小肠和结肠定位释药的目的.     

(肝素/壳寡糖/Pluronic(R))静电组装多层膜的构建

以壳寡糖/Pluronic(R)聚合物纳米聚集体(COPNs)、肝素为组装基元构建仿(肝素/壳聚糖)多层膜,验证多层膜负载疏水药物的可行性.Pluronic(R)P123与1,3-丙烷磺内酯反应合成末端磺酸化的Pluronic(R)聚合物,其与Pluronic(R)F127在水溶液中自组装形成表面带负电荷的混合胶束.利用壳寡糖与混合胶束的静电作用,获得COPNs,粒径与表面电位分析、透射电镜表征COPNs为直径(27.61±2.46) nm、表面zeta电位(6.12±1.82)mV、稳定的球形结构.石英晶体微天平(QCM)跟踪检测证明COPNs与肝素可在基材表面实现交替沉积;原子力显微镜(AFM)表征多层膜表面拓扑形貌,证明COPNs在表面沉积过程中稳定.将疏水的荧光探针芘载入COPNs参与多层膜的构建,荧光光谱实验结果表明多层膜可成功包载芘,且多层膜内芘的载入量与组装层数相关.以葛根素为模型药物,载药量测定与体外释药实验结果表明多层膜具有包载和缓释疏水药物的能力.     

层层组装微胶囊的制备及其智能响应与物质包埋释放性能

在胶体微粒模板上进行聚合物间或聚合物和小分子间的交替层层(LBL)组装, 得到核壳微粒, 然后去除胶体微粒得到层层组装微胶囊. 综述了层层组装微胶囊在组装驱动力、智能响应性能和物质包埋与释放等方面的最新研究进展. 首先从组装驱动力和微胶囊结构调控出发, 简述了基于静电和氢键作用的LBL微胶囊的交联方法及交联所引起的微胶囊结构和性能的变化, 介绍了基于新驱动力如共价键作用、 碱基对作用和主客体作用制备LBL微胶囊的技术. 讨论了LBL微胶囊的智能响应性, 包括pH、 温度、 电荷、 光电磁和化学物质响应等. 详细介绍了LBL微胶囊包埋与释放功能物质尤其是药物、 蛋白和酶的方法及其特色, 包括LBL直接包埋与释放、 预吸附或共沉淀包埋与释放、 电荷选择性自沉积包埋与释放及爆释等. 最后, 着眼于微胶囊的靶向传递和功能器件, 介绍了采用静电作用和生物识别作用制备得到的微胶囊阵列.     

聚合物层状组装膜

介绍了近几年来我们研究组在层状组装膜的构筑以及功能化研究方面取得的一些最新进展.包括结合表面溶胶-凝胶技术与静电层状组装技术,实现了二阶非线性基团在层状组装多层膜中的非对称排列,制备了具有二阶非线性效应的膜材料;采用室温压印技术,发展了一种简便、经济和具有普适性的层状组装聚合物膜图案化方法;以轻度交联的聚合物微凝胶为构筑基元,制备了具有高负载量的聚合物层状组装膜;发展了一种基于离子剥离技术的层状组装自支持膜制备方法;基于层状组装技术,制备了具有超疏水和抗反射功能的涂层.     

表面印迹交替层状组装薄膜

在简要概述非常规交替层状组装这一进展后,重点总结了如何利用非常规交替层状组装以实现表面印迹膜的制备.模板分子与聚电解质在溶液中组装形成超分子复合物,然后以此超分子复合物为构筑基元,与感光性高分子,如重氮树脂,通过常规交替层状组装形成聚合物多层膜.利用聚合物多层膜之间的光化学反应形成稳定的多层膜,然后去除模板分子得到分子...     

Controlled loading and release of methylene blue from LbL polyurethane/poly(acrylic acid) film

The layer‐by‐layer (LbL) assembled multilayer films are widely used in the biomedical field for the controlled drug delivery. Here, multilayer films were assembled by LbL technique through alternating deposition of cationic polyurethane (PU) and poly(acrylic acid) (PAA) on glass slides. Methylene blue (MB) was used as a model drug to investigate the loading and release ability of the prepared multilayer film. The results showed that the loading rate and loading amount of MB were greatly influenced by pH value of the dye solution, and the release rate of MB was controlled both by ionic strength and pH value of immersing solution. The result also indicated that the film had a good reversibility of drug loading and release. It suggested that the PU/PAA multilayer film had potential applications in drug delivery and controlled release. Copyright © 2011 John Wiley & Sons, Ltd.     

Layer-by-layer assembly of salt-containing polyelectrolyte complexes for the fabrication of dewetting-induced porous coatings

The layer-by-layer (LbL) assembly of salt-containing nonstoichiometric polyelectrolyte complexes (PECs) with oppositely charged uncomplexed polyelectrolyte for the fabrication of dewetting-induced porous polymeric films has been systematically investigated. Salt-containing poly(allylamine hydrochloride) (PAH) and poly(acrylic acid) (PAA) complexes (noted as PAH-PAA) with a molar excess of PAH were LbL assembled with polyanion poly(sodium 4-styrenesulfonate) (PSS) to produce PSS/PAH-PAA films. The structure of the PAH-PAA complexes is dependent on the concentration of NaCl added to their aqueous dispersions, which can be used to tailor the structure of the LbL-assembled PSS/PAH-PAA films. Porous PSS/PAH-PAA films are fabricated when salt-containing PAH-PAA complexes with a large amount of added NaCl are used for LbL assembly with PSS. In-situ and ex-situ atomic force microscopy measurements disclose that the dewetting process composed of pore nucleation and pore growth steps leads to the formation of pores in the LbL-assembled PSS/PAH-PAA films. The present study provides a facile way to fabricate porous polymeric films by dewetting LbL-assembled polymeric films comprising salt-containing PECs.     

Polymer multilayer film formation studied by in situ ellipsometry and electrochemistry

Polyelectrolyte multilayer films adsorbed on gold surfaces were studied by combined ellipsometric and electrochemical methods. Multilayers were composed of “synthetic” (poly(4-styrenesulfonic acid) ammonium salt (PSS) and poly(allylamine hydrochloride) (PAH) (PSS/PAH)) and “semi-natural” (carboxymethyl cellulose (CMC) and chitosan (CHI) (CMC/CHI)) polyelectrolytes. It was found that only PSS/PAH Layer-by-Layer (LbL) assembled structures result in dense surface confined films that limit permeability of small molecules, such as ferri-/ferrocyanide. The PSS/PAH assemblies can be envisaged as films with pinholes, through which small molecules diffuse. During the LbL deposition process of these films a number of pinholes quickly decay. A representative pinhole diameter was found to be approximately 20 μm, which determines the diffusion of small molecules through LbL films, and yet remains constant when the film consists of a few LbL assembled polyelectrolyte bilayers. CMC/CHI LbL assemblies at gold electrode surfaces give very low density films, which do not limit the diffusion of ferri-/ferrocyanide between the surface of the electrode and the solution.     

The pH stimulated reversible loading and release of a cationic dye in a layer-by-layer assembled DNA/PAH film

Through the layer-by-layer (LbL) deposition method, DNA was assembled into an ultrathin film with a cationic poly(allylamine hydrochloride) (PAH). The loading and release of a typical cationic dye, 5, 10, 15, 20-tetrakis(4-N-methylpyridyl)porphine-tetra-(p-toluenesulfonate) (TMPyP), in the DNA/PAH films were investigated. It has been found that the LbL-assembled DNA/PAH film was very stable in both acidic and alkaline solutions. Stimulated by the pH change of the dye solution, the dye can be easily loaded into or released from the DNA/PAH film. In an alkaline solution, the dye could be rapidly loaded into the DNA/PAH film at room temperature, while in an acidic solution, the dye could be rapidly released. The mechanism of such pH-stimulated loading and release in the DNA/PAH film was discussed. It was further observed that the loading and release of the dye in the DNA/PAH film was reversible upon pH change and the process could be repeated many times.     

Preparation of Highly Loaded PAA/PAH Layer-by-layer Films by Combining Acid Transformation and Templating Methods

Enhancing the molecular loading capability of layer-by-layer(LbL)method holds high importance in environmental and biomedical application.Here,we reported a strategy to prepare highly loaded poly(acrylic acid)(PAA)/poly(allylamine hydrochloride)(PAH)LbL films by combining the particulate templating strategy and acid treatment film transformation and realized tlae efficient loading of hydrophilic small molecules.The loaded molecules can be released in a pH-controlled manner.A slow release speed was observed in the acidic solutions with pH value of 3.Abrupt releases were observed at higher pH values(5 or 7).     

Layer by layer buildup of polysaccharide films: physical chemistry and cellular adhesion aspects

The formation ofpolysaccharide films based on the alternate deposition of chitosan (CHI) and hyaluronan (HA) was investigated by several techniques. The multilayer buildup takes place in two stages: during the first stage, the surface is covered by isolated islets that grow and coalesce as the construction goes on. After several deposition steps, a continuous film is formed and the second stage of the buildup process takes place. The whole process is characterized by an exponential increase of the mass and thickness of the film with the number of deposition steps. This exponential growth mechanism is related to the ability of the polycation to diffuse "in" and "out" of the whole film at each deposition step. Using confocal laser microscopy and fluorescently labeled CHI, we show that such a diffusion behavior, already observed with poly(L-lysine) as a polycation, is also found with CHI, a polycation presenting a large persistence length. We also analyze the effect of the molecular weight (MW) of the diffusing polyelectrolyte (CHI) on the buildup process and observe a faster growth for low MW chitosan. The influence of the salt concentration during buildup is also investigated. Whereas the CHI/HA films grow rapidly at high salt concentration (0.15 M NaCl) with the formation of a uniform film after only a few deposition steps, it is very difficult to build the film at 10(-4) M NaCl. In this latter case, the deposited mass increases linearly with the number of deposition steps and the first deposition stage, where the surface is covered by islets, lasts at least up to 50 bilayer deposition steps. However, even at these low salt concentrations and in the islet configuration, CHI chains seem to diffuse in and out of the CHI/HA complexes. The linear mass increase of the film with the number of deposition steps despite the CHI diffusion is explained by a partial redissolution of the CHI/HA complexes forming the film during different steps of the buildup process. Finally, the uniform films built at high salt concentrations were also found to be chondrocyte resistant and, more interestingly, bacterial resistant. Therefore, the (CHI/HA) films may be used as an antimicrobial coating.