刺激响应星形聚合物的合成及其药物可控释放研究

星形聚合物是从一个枝化点呈放射形连接出三条及三条以上线形链的一类具有特殊拓扑结构的聚合物.与组成和分子量相同的线形聚合物相比,星形聚合物具有明确的结构、较窄的分子量分布、较低的黏度和多功能性,已成为高分子领域的研究热点之一.引入刺激响应基团的刺激响应星形聚合物具有随外界环境变化而发生敏感调整的结构特征,并在药物可控释放方面具有重要的应用价值,受到广泛关注.本文总结现阶段刺激响应星形聚合物应用于药物可控释放方面的最新研究成果,主要根据不同的环境刺激信号进行分类,分别介绍了pH、温度、双重或多重刺激响应星形聚合物的合成方法,分析其在溶液中的自组装行为、刺激响应情况和药物可控释放功能,并对相关聚合物体系的改进和发展进行展望.     

光控释药型药物递送系统的研究进展

释药可控的药物递送系统能够在特定刺激条件下,在时间和空间上精确实现在病灶处释放包载的药物分子,具有药物利用率高、毒副作用低等诸多优点,为各种重大疾病,如肿瘤的精准治疗提供了新思路.在众多的可控释药递送系统中,利用特定光照控制药物释放的光控释药型药物递送系统展现出广阔的应用潜力,受到研究者的广泛关注.近年来,基于不同光响应机理的光控释药型药物递送系统被设计开发用于药物的精确可控释放,本文介绍了四种光敏感基团的不同光响应机理,对基于不同光响应机理的光控释药型药物递送系统的研究进展进行了综述,指出现有光控释药型药物递送系统存在的问题及对未来的研究方向进行了展望.     

环境响应性微胶囊及其在农业领域中应用的研究进展

在传统农业中,如何高效率地使用农药,提高其利用率,一直是一大难题。环境响应性微胶囊是一类在外界环境的刺激下,可以相适应地改变其表面结构的物质。这一类微胶囊具有智能、可控、精准、高效等特点。目前,这一项技术已经被广泛地应用于农业生产中。本文主要综述了环境中pH、温度、光以及磁场四大因素对响应性微胶囊的影响,并且简要介绍了该类微胶囊的制备技术、形成机理、主要材料以及在农业领域的应用。     

刺激响应型聚合物刷的研究进展

本文综述了刺激响应型聚合物刷的研究进展,阐述了刺激响应型聚合物刷的分类、与基体表面的连接方式以及常规制备方法,介绍了离子强度、温度、pH值、光、溶剂等刺激响应型聚合物刷及其研究现状,并对相应的刺激响应机理进行了探讨。此外,本文还综述了多重刺激响应型聚合物刷的制备设计思路及其刺激响应特性,概述了聚合物刷在响应外界刺激后对基体的弯曲作用以及利用该作用进行可控三维自组装,并对刺激响应型聚合物刷的应用前景进行了展望。     

氯化钙/三赞胶微胶囊的制备及其对核黄素的控制释放

为实现核黄素在肠道中的可控释放，本研究利用三赞胶的pH响应性，使用滴球法制备三赞胶水凝胶微胶囊，以核黄素为负载药物，氯化钙为调控因子，研究了微胶囊的物性与释放特性。结果表明：0.3%三赞胶在0.06 mol/L盐酸固定液中可以形成稳定的凝胶结构，添加氯化钙后微胶囊的硬度增加但弹性降低。氯化钙添加量由0逐渐增加至10%,三赞胶微胶囊在十二指肠中的释放率无显著变化，空肠释放率由42.5%逐渐降低至24.1%,在氯化钙添加量2%及以上时可在回肠释放，且释放率由21.6%逐渐降低至14.9%。粘度特性与SEM图像分析表明，添加氯化钙提高三赞胶溶液的粘度，降低微胶囊的孔隙度是控制核黄素释放的主要原因。本研究通过调整三赞胶微胶囊中的氯化钙添加量，实现了核黄素在肠道中的可控释放，表明可控释三赞胶微胶囊在口服递送领域具有广阔的应用前景。     

刺激响应型多肽的研究及其在肿瘤诊疗中的应用

多肽因其独特的理化性能,如生物相容性好,合成修饰方法简单易行,功能多样化和生物体内响应性高等优点,已被广泛用于构建刺激响应型肿瘤诊疗体系.这种以刺激响应型多肽为基础构建的药物诊疗体系,能够在到达肿瘤以前保持药物的零释放,而在靶向到达肿瘤组织后,在肿瘤组织特殊微环境或是外源刺激下(如肿瘤特异性表达酶的刺激、p H刺激和氧化还原刺激等),实现药物的精准靶向释放同时释放出各种诊疗信号.这种具有特异性刺激响应型的多肽载体可以最大程度的提高药物的抗肿瘤效果,降低药物的毒副作用,以及提高肿瘤诊断的精准度.本文简要综述了近年来不同刺激响应型多肽在肿瘤诊疗领域的研究进展.     

磁性微胶囊的制备及其药物缓控释性能

用乳液-凝胶法制备了磁性壳聚糖/海藻酸钠微胶囊. 在壳聚糖/海藻酸钠微胶囊中掺入Fe3O4磁性中空球, 使微胶囊具有磁靶向性能. 以头孢拉定作为模型药物研究了载药磁性微胶囊的载药量、包封率及药物缓控释性能等. 结果表明, 提高头孢拉定的初始浓度可以提高载药量, 却不利于提高药物的包封率. 所制备的微胶囊在各种缓冲溶液中长时间内具有显著的缓释效果, 并具有pH 刺激响应释放的性能, 即在模拟胃液中的药物释放率大大降低, 而在模拟体液和肠液中的释放时间大大延长, 可达50 h以上. 另外, 在外加磁场作用下, 微胶囊表现出良好的磁定向运动性能, 为磁靶向药物输送提供基础.     

可控释放一氧化碳的纳米材料及其生物医学应用

一氧化碳（CO）是一种内源性气体信使分子,具有广泛而复杂的生理学功能.CO分子的生理学效应与其浓度、位置和作用时间密切相关.而现有的一氧化碳供体普遍存在着稳定性较差,剂量难以把控,缺乏靶向性以及对正常细胞和组织器官具有潜在的毒副作用等问题,限制了其进一步的应用.随着纳米科学技术的迅速发展,国内外研究者们构建出一系列能够实现可控释放CO的多功能纳米材料,并将其用于生物医学领域.结合纳米材料自身独特的性能优势,分类介绍了多种内源性/外源性刺激响应型CO控释纳米材料,并概述了可控释放CO的纳米药物在抑制炎症反应、抗菌和肿瘤治疗等生物医学领域的应用,最后对CO控释纳米材料在生物医学领域面临的挑战和发展前景进行了总结和讨论.     

智能中空药物载体的门控设计

由于具有独特新颖的结构和广泛的应用领域,中空材料已成为合成化学和材料化学研究的热点;特别是其高的表面体积比、低密度及大空腔等特点,成为药物递送载体的最佳选择.通过对中空结构的精确选择和精准修饰,可赋予中空材料独特的刺激响应行为,从而实现该类药物载体的智能设计和药物的可控释放.目前,构建中空智能载体主有以下两条思路:(1)利用自身可对环境中的物理化学刺激做出响应的中空材料作为载体;(2)在中空载体表面修饰功能性分子,以实现在特定的刺激下精确控制孔道的“开-关”转换.其核心在于分子组成和构型的精准调控.基于此,本文综合评述了中空智能载体的可控释放机制.首先介绍中空药物载体的发展历史,随后阐述药物分子在中空结构中的扩散规律,并总结了中空结构载体的智能响应行为、不同的门控机制、控制释放原理以及应用前景,最后对未来的发展做了展望.     

刺激响应型功能聚合物的合成及应用

刺激响应型聚合物是一类功能性聚合物,它在药物控制释放、基因载体、纳米粒子以及纳米反应器等众多领域具有广阔的应用前景,因此引起了越来越多科学工作者的关注。刺激响应型聚合物多为双亲性聚合物,可通过自组装的方式得到形态各异的聚集体,如胶束、囊泡等。在受到某些外界环境刺激时,它们会产生特异性响应,尤其是功能性聚合物嵌段会发生相应的变化,从而引起整个聚合物结构的相转变和体积相转变。根据环境刺激种类的不同,刺激响应型聚合物可以分成不同类型,本文主要介绍了pH、温度、光、分子、电化学和手性等响应型聚合物,并概括了它们的结构特点以及不同的合成方法,简单说明了它们具有刺激响应功能的作用机理,阐述了结构与性能的联系。另外,还介绍了它们的潜在应用,并对此类聚合物的发展前景作了展望。     

Stimuli-responsive multilayer chitosan hollow microspheres via layer-by-layer assembly

Novel stimuli-responsive multilayer chitosan hollow microspheres with chitosan as the unique component have been fabricated by the sequential layer-by-layer electrostatic assembly technique from the sacrificial templates (polystyrene sulfonate, PSS) with chitosan (CS) as the polycation and carboxymethyl chitosan (CMCS) as the polyanion, respectively. Their hollow structure was confirmed by the TEM analysis. The DLS analysis indicated that the multilayer chitosan microcapsules were pH and ionic strength dual-responsive. Due to the biocompatibility of the single component chitosan used, the multilayer chitosan microcapsules are expected to be used in the controlled release of drugs.     

海藻酸钠和壳聚糖聚电解质微胶囊及其生物医学应用

本文综述了天然多糖聚电解质海藻酸钠和壳聚糖的结构与化学性能（包括凝胶性能、生物相容性、生物可降解性及温和反应性）;微胶囊制备技术及其强度性能和膜渗透性评价方法;微胶囊作为细胞载体在体内分泌治疗性物质（如：胰岛素、多巴胺）或分解代谢毒性物质（如：尿素）,作为三维药物筛选系统、干细胞增殖分化研究工具,以及药物释放载体等生物医学领域的研究进展;最后讨论了天然多糖微胶囊研究与应用中需要解决的问题。     

A general strategy for one-step fabrication of biocompatible microcapsules with controlled active release

Fabrication of biocompatible core-shell microcapsules in a controllable and scalable manner remains an important but challenging task.Here,we develop a one-step microfluidic approach for the highthroughput production of biocompatible microcapsules,which utilizes single emulsions as templates and controls the precipitation of biocompatible polymer at the water/oil interface.The facile method enables the loading of various oils in the core and the enhancement of polymer shell strength by polyelectrolyte coating.The resulting microcapsules have the advantages of controllability,scalability,biocompatibility,high encapsulation efficiency and high loading capacity.The core-shell microcapsules are ideal delivery vehicles for programmable active release and various controlled release mechanisms are demonstrated,including burst release by vigorous shaking,pH-triggered release for targeted intestinal release and sustained release of perfume over a long period of time.The utility of our technique paves the way for practical applications of core-shell microcapsules.     

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.     

Recent advances in stimuli-responsive degradable block copolymer micelles: synthesis and controlled drug delivery applications

(Bio)degradation in response to external stimuli (stimuli-responsive degradation, SRD) is a desired property in constructing novel nanostructured materials. For polymer-based multifunctional drug delivery applications, the degradation enables fast and controlled release of encapsulated therapeutic drugs from delivery vehicles in targeted cells. It also ensures the clearance of the empty device after drugs are delivered to the body. This review summarizes recent development of various strategies to the design and synthesis of self-assembled micellar aggregates based on novel amphiphilic block copolymers having different numbers of stimuli-responsive cleavable elements at various locations. These cleavable linkages including disulfide, acid-labile, and photo-cleavable linkages are incorporated into micelles, and then are cleaved in response to cellular triggers such as reductive reaction, light, and low acid. The well-designed SRD micelles have been explored as controlled/enhanced delivery vehicles of drugs and genes. For future design and development of effective stimuli-responsive degradable micelles toward tumor-targeting delivery applications in vivo, a high degree of control over degradation for tunable release of encapsulated anticancer drugs as well as bioconjugation for active tumor-targeting is required.     

A glucose-responsive controlled release system using glucose oxidase-gated mesoporous silica nanocontainers

A glucose-responsive controlled-release system based on the competitive combination between glucose oxidase, glucosamine and glucose has been described, which exhibits perfect controlled release properties and high selectivity for glucose over other monosaccharides. This paved the way for a new generation of stimuli-responsive delivery systems.     

Pillararene-Based Supramolecular Vesicles for Stimuli-Responsive Drug Delivery

Supramolecular vesicles (SMVs) self-assembled from the supra-amphiphiles, consisting of two scaffolds linked together through noncovalent interactions, can realize stimuli-responsive controlled release of encapsulated drugs for enhanced therapeutic efficacy and minimized side effect of drugs. Pillararenes (PAs), an emerging kind of macrocyclic hosts in 2008, are easy to modify with a variety of functionalities. SMVs from PAs and specific guests mainly based on the host–guest interactions have attracted increasing attention because of their drug delivery and controlled drug release. A great progress in the construction and stimuli-responsive drug delivery of the PA-based SMVs has been made since the first work was reported in 2012. This review summarizes the major achievements of the PA-based SMVs for stimuli-responsive drug delivery over the past 5 years, including the microstructures of SMVs, multiple stimuli-responsive SMVs, prodrug SMVs from prodrug PAs and guests, bola-type SMVs, multifunctional SMVs, glucose-responsive SMVs for insulin delivery, novel SMVs from responsive PAs, thermo-responsive SMVs, and ternary SMVs, for chemotherapy, photothermal therapy, photodynamic therapy, and other biological applications. The future challenges and research directions of PA-based SMVs are also outlined from the points of views of the fundamental research, biological applications, and clinical applications of PA-based SMVs.     

药物控制释放方法

药物控制释放方法是目前药物学发展的一个重要领域，本文从贮库型和基质型两方面较为详细地综述了高分子药物控制释放的方法。     

Stimulated aggregation, rotation, and deformation of magnetite-filled microcapsules in external magnetic fields

Microcapsules are nowadays applied in a wide range of products including food, pharmaceuticals, and cosmetic formulations. Because of their pronounced viscoelastic properties, polymer microcapsules are able to undergo mechanical deformations when they are stimulated by external signals. The elongation of capsule membranes, up to bursting processes, is important for the controlled release of active ingredients under well-defined conditions. Their application as quick and reliable control release systems affords a detailed knowledge of their rheological and mechanical properties. The aims of our work were to prepare new types of magnetic switchable microcapsules and to investigate their deformation behavior in externally imposed magnetic fields. The magnetic sensitivity was achieved by encapsulating magnetic magnetite (Fe₃O₄) particles within a polyorganosiloxane capsule. We investigated the dynamic response of those capsule suspensions and single capsules to external magnetic forces where aggregation processes, rotational movements, and field-induced deformations in static or rotating fields were observed.