Biocompatible or biodegradable hyperbranched polymers: from self-assembly to cytomimetic applications

Self-assembly of amphiphilic hyperbranched polymers (HBPs) is a newly emerging research area and has attracted increasing attention due to the great advantages in biomedical applications. This tutorial review focuses on the self-assembly of biocompatible or biodegradable amphiphilic HBPs and their cytomimetic applications, and specialities or advantages therein owing to the hyperbranched structure have also been summarized. As shown here, various supramolecular structures including micelles, vesicles, tubes, fibers and films have been prepared through the primary self-assembly processes. The primary self-assemblies can be further assembled into more complex structures through hierachical self-assembly processes. Besides, the hyperbranched polymer vesicles have demonstrated great potential to be used as model membranes to mimic cellular behaviors, such as fusion, fission and cell aggregation. Other biomedical applications of HBPs as well as their self-assemblies are also briefly summarized.     

Crystallization-driven self-assembly of semicrystalline block copolymers and end-functionalized polymers: A minireview

Self-assembly has been a powerful method to fabricate the polymer materials with well-defined structures and morphologies. Such assembled materials have shown wide potential applications in many fields such as nanomaterial, nanomedicine, lithography, and microelectronic. Crystallization has been a general behavior of stereoregular polymers. Besides the various noncovalent interactions, crystallization of polymer blocks or end groups can be an efficient way to manipulate the self-assembly pathway and assembled structures of polymers in both solid and solution. Crystallization-driven self-assembly has been widely implemented for the semicrystalline block copolymers (BCPs) and end-functionalized polymers. This minireview briefly presents the recent progresses in the crystallization-driven self-assembly of BCPs and end-functionalized polymers in both solid and solution states. Formation process, mechanism, and hierarchical structure of the crystallization-induced assemblies for BCPs and end-functionalized polymers are highlighted.     

多肽分子自组装

源于自然界中广泛存在的蛋白质自组装现象,近年来多肽的自组装逐渐成为材料学和生物医学等领域的研究热点.通过合理调控多肽的分子结构以及改变外界的环境,多肽分子可以利用氢键、疏水性作用、π-π堆积作用等非共价键力自发或触发地自组装形成形态与结构特异的组装体.由于多肽自身具有良好的生物相容性和可控的降解性能,利用多肽自组装技术构建的各种功能性材料在药物控制释放、组织工程支架材料以及生物矿化等领域内有着巨大的应用前景.本文总结了近年来多肽自组装研究的进展,介绍了多肽自组装技术常见的几种结构模型,概括了多肽自组装的机理,并进一步阐述多肽自组装形成的组装体形态及其在材料学和生物医学等领域里的应用.     

共聚物的自组装研究进展

自组装是分子间通过非共价键相互作用自发组合形成的一类结构明确、稳定,同时具有某种特定功能或性能的分子聚集体或超分子结构的现象。利用共聚物自组装技术可以制备高度有序介观形貌的功能材料,这些材料有望在生物医学、药物释放、智能材料等领域得到广泛的应用。研究表明,不同结构的共聚物的自组装行为和功能一般不同,同时环境条件,如温度、pH值等也对共聚物自组装行为有很大影响。本文从共聚物结构及外部环境条件两个方面综述了近几年来共聚物的自组装行为规律,并分析了相关自组装结构应用的研究进展。     

中国嵌段共聚物受限自组装的研究进展

近年来,嵌段共聚物在受限空间中的自组装已成为高分子科学领域一个新的关注点.在受限条件下,嵌段共聚物展现出更多的可调控性,可获得复杂多样的微相分离结构.这些新颖的结构为实现嵌段共聚物更加丰富的功能奠定了材料基础.中国的学者们在嵌段共聚物受限自组装的理论模拟和实验研究方面取得了一系列重要创新成果,有力地推动了该领域的发展.本文总结和评述了中国学者在该领域的研究进展,并展望了嵌段共聚物受限自组装研究未来发展的机遇与挑战.     

Understanding on the Surfactants Engineered Morphology Evolution of Block Copolymer Particles and Their Precise Mesoporous Silica Replicas

Surfactant-directed block copolymer(BCP) particles have gained intensive attention owing to their attractive morphologies and ordered domains. However, their controllable fabrication suffers several limitations including complex design and synthesis of multiple surfactant systems, limited choices of block copolymers, and time-consuming post-processes, etc. Herein, a surfactant size-dependent phase separation route is proposed to precisely manipulate the architectures of the anionic block copolymer particles in the binary co-assembly system of BCP and surfactants. In the system of polystyrene block polyacrylic acid (PS-b-PAA) and quaternary ammonium surfactants, it is verified that facile control on the ordered phase separation structures and morphologies of BCP particles can be achieved via simply varying the alkyl lengths of the surfactants. The cationic surfactants are demonstrated participating in the fabrication of the internal structures of BCP particles. Especially, it is found that the cationic surfactants are integrate into the anionic polyacrylic acid(PAA) domain of BCP particles of PS-b-PAA to influence the volume fraction of PAA blocks, so that varied architectures of BCP particles are constructed. Based on these understandings, spherical or ellipsoidal BCP particles are obtained as expected, as well as their precisely inorganic mesoporous silica replicas through the block copolymer nanoparticle replicating route. More interestingly, the ellipsoidal mesoporous silica exhibits higher cellular internalization capability due to its lower energy expenditure during the internalization process, which presents promising potentials in biomedical applications, especially for high-efficient drug delivery systems. These findings may provide valuable insights into the confinement assembly of anionic block copolymers and the creation of special nanocarriers for high-efficiency biomacromolecule delivery in the biomedical community.     

Fabrication of functional nano-objects via self-assembly of nanostructured hybrid materials

A simple route to fabricate functional nano-objects via self-assembly of block copolymer-based hybrid materials is described. In water–toluene mixtures, spheres, rod-like morphologies, and ring-like morphologies as well as vesicles of metal loaded block copolymers micelles are fabricated. The concept is generic to realize different functionalities by incorporating various inorganic components (Au, Ag, Pt, Co…) into the block copolymer matrix. A mechanism describing the formation of micellar aggregates with different morphologies is presented based on a simple force balance approach. Moreover, the composition of the solvent mixture is modified to gain control over the morphology of micellar aggregates. It was found that swelling of the micelle core with a selective cosolvent is the driving force to induce morphology transitions from spherical to rod- and ring-like structures as well as vesicles. These nano-objects can be further used as building blocks to construct well-defined structures via self-assembly in spin coated thin films. © 2010 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 48: 1642–1650, 2010     

Engineering the Morphologies of Block Copolymer Particles from the Confined Self-assembly within Emulsion Droplets†

Block copolymers (BCPs) can automatically assemble into various regulated nanoparticles when they are confined within the emulsion droplet because of the structural frustration of polymer chains and the soft template effect of the oil/water interface. In the past few years, great efforts have been made to regulate the morphologies of the resulting BCP particles. In this review article, various strategies for tuning oil/water interfacial properties to engineer the as-formed BCP particles were summarized. Then, the comprehensive scenarios of the applications of the resulting BCP particles were discussed. Finally, the future tendency and challenge of the self-assembly of BCPs confined in emulsion droplet were suggested.     

Hierarchical Self-Assembled Photo-Responsive Tubisomes from a Cyclic Peptide-Bridged Amphiphilic Block Copolymer

Typically, the morphologies of the self-assembled nanostructures from block copolymers are limited to spherical micelles, wormlike micelles and vesicles. Now, a new generation of materials with unique shape and structures, cylindrical soft matter particles (tubisomes), are obtained from the hierarchical self-assembly of cyclic peptide-bridged amphiphilic diblock copolymers. The capacity of obtained photo-responsive tubisomes as potential drug carriers is evaluated. The supramolecular tubisomes pave an alternative way for fabricating polymeric tubular structures, and will expand the toolbox for the rational design of functional hierarchical nanostructures.     

基于多重氢键的寡聚芳酰胺自组装囊泡

六重氢键的异互补寡聚芳酰胺双股分子链在自组装过程中表现出极高的顺序专一性.本文借助扫描电镜(SEM)、透射电镜(TEM)和动态光散射(DLS)等实验手段,研究了氢键编码顺序为DADDAD-DADDAD的寡聚芳酰胺分子1及异互补分子2(ADAADA-ADAADA)存在下的自组装行为.实验结果表明,分子1在四氢呋喃/甲醇(体积比为85/15)和单一溶剂丙酮中都能组装成大小均匀的囊泡结构,并且囊泡的尺寸随着溶液浓度的增加而增大;当加入异互补分子2后,囊泡则转变成实心球.利用荧光显微镜,发现该囊泡能很好地包裹荧光分子(罗丹明B),通过进一步分子结构修饰有可能实现药物包埋和缓释方面的应用.     

Guided self-assembly of diblock copolymer thin films on chemically patterned substrates

We study the guided self-assembly of symmetric/asymmetric diblock copolymer (BCP) films on heterogeneous substrates with chemically patterned surface by using a coarse-grained phase-separation model. During the procedure, the free energy employed for the BCP films was modeled by the Ginzburg-Landau free energy with nonlocal interaction, and the flat, chemically patterned surface was considered as a heterogeneous surface with short-range interaction with the BCP molecules. The resulting Cahn-Hilliard equation was solved by means of an efficient semi-implicit Fourier-spectral algorithm. Effects of pattern scale, surface chemical potential, and BCP asymmetry on the self-assembly process were explored in detail and compared with those without chemically patterned substrate surfaces. It was found that the morphology of both symmetric and asymmetric BCP films is strongly influenced by the commensurability between the unconstrained natural period lambda* of the bulk BCP and the artificial pattern period. Simulation shows that patterned surface with period close to lambda* leads to highly ordered morphology after self-assembly for both symmetric and asymmetric BCP films, and it also dramatically accelerates the guided self-assembly process. The present simulation is in a very good agreement with the recent experimental observation in BCP nanolithography. Finally, the present study also expects an innovative nanomanufacturing method to produce highly ordered nanodots based on the guided self-assembly of asymmetric BCP films on chemically patterned substrates.     

Block copolymer solution self-assembly: Recent advances,emerging trends,and applications

The self-assembly process of block copolymers (BCPs) in solution has been at the focus of extended scientific research over the past several decades owing to the astonishing morphological diversity and attainable complexity of the resulting nanoassemblies, including spheres, cylinders, lamellae, vesicles, and many other complex, bicontinuous or even hierarchical structures. The ever-increasing sophistication in the development of synthetic chemistry methods and techniques has led to a myriad of available macromolecules with varying chemical compositions, architectures, features, and properties. This assortment of characteristics has led in turn to a plethora of intriguing self-organized polymeric nanostructures, with countless possible applications in several nanotechnological fields relevant to physics, chemistry, material science, nanomedicine, and biomaterials. The present review aims to illuminate the importance and fascinating potential of BCPs solution self-assembly by highlighting recent advances and emerging trends in the field, as well as significant application-oriented progress, through characteristic contemporary examples.     

三维宏观网络状囊泡薄膜的分级自组装研究

分别合成以疏水性超支化聚醚(HBPO)为核,以亲水性聚环氧乙烷(EO)和聚甲基丙烯酸N,N-二甲氨基乙酯(DMAEMA)为臂的两亲性超支化多臂共聚物HBPO-star-PEO和HBPO-star-PDMAEMA.通过两者在水溶液中的复合自组装制备得到具有pH响应性的巨型聚合物囊泡(1~10μm),并用zeta电位仪,激光共聚焦显微镜及光学显微镜对囊泡的自组装行为进行了研究.结果表明,在等电点以前,复合囊泡始终以单个囊泡形式存在;随着溶液pH的升高,囊泡逐步线型缔合成串珠结构;在更高的pH下,囊泡进一步二次聚集形成具有宏观尺度的三维蜘蛛网状超分子结构,这是一类新的自组装体.     

Thermosensitive polymeric vesicles self-assembled by PNIPAAm-b-PPG-b-PNIPAAm triblock copolymers

PNIPAAm-b-PPG-b-PNIPAAm triblock copolymers were prepared by redox polymerization. The self-assembly behavior and thermosensitive property of the copolymers in water were studied using ¹H-NMR, TEM and a UV spectrophotometer. The results showed that the LCST of the copolymers was 32 °C, which was consistent with that of pure PNIPAAm. The copolymers could form a vesicular structure in an aqueous solution by self-assembly. The hollow structure of the PNIPAAm-b-PPG-b-PNIPAAm vesicles combined with the temperature-sensitive property may enable many potential applications of the vesicles.     

Precise modulation of spatially distributed inorganic nanoparticles in block copolymers-based self-assemblies with diverse morphologies

Block copolymers (BCPs)-based self-assemblies with various morphological and compartmental structures can serve as universal polymeric scaffolds for the incorporation of diverse inorganic nanoparticles (NPs) within the disparate polymer domains of the formed aggregates. The properties and performance of the resulting BCPs–NPs hybrids depend not only on the organic and inorganic building moieties, but also on the spatial distribution of inorganic NPs within organic aggregates. However, few publications have so far made a systematical clarification of the effect of the critical parameters on the morphological control of BCPs–NPs hybrids and the spatial localization of NPs within the BCPs-based aggregates as well as their properties for potential applications. For this purpose, we summarized the co-operative assembly of BCPs and NPs in solution and emulsion with an emphasis on the precisely modulated localization of NPs in different domains of BCP aggregates with various morphologies. Specifically, we made detailed discussion on the effect of size, shape and surface property of NPs on the loading number and selective localization of NPs within BCP aggregates. The important guidelines drawn herein on the precise modulation of spatially distributed NPs in BCP aggregates are believed to inspire the generation of more novel hybrid materials for various applications.     

Pincushion of Tubule Discovery and Tubular Morphology Landscape Establishment of Block Copolymer Self‐Assemblies

Block copolymer (BCP) self‐assembly is a versatile technique in the preparation of polymeric aggregates with varieties of morphologies. However, its morphology library is limited. Here, the discovery of pincushion of tubules is reported for the first time, via BCP self‐assembly of poly(4‐vinylpyridine)‐b‐polystyrene (P4VP‐b‐PS) with very high molecular weight (500 kDa) and asymmetry (2 mol% P4VP). The investigation confirms the importance of core‐forming block length on morphology control of BCP self‐assemblies, especially with respect to tubular structures. The morphology landscape of tubular structures is successfully established, where dumbbell of tubule, tubule, loose clew of tubules, tight clew of tubules, and pincushion of tubules can be prepared by adjusting the core‐forming block length. This work therefore expands the structure library of BCP self‐assemblies and opens up a new avenue for the further applications of these tubular materials.     

Self-assembly and morphology control of new L-glutamic acid-based amphiphilic random copolymers: giant vesicles, vesicles, spheres, and honeycomb film

New amphiphilic random copolymers containing hydrophobic dodecyl (C12) chain and hydrophilic L-glutamic acid were synthesized, and their self-assembly in solution as well as on the solid surfaces was investigated. The self-assembly behavior of these polymers are largely dependent on their hydrophilic and hydrophobic balances. The copolymer with a more hydrophobic alkyl chain (～90%) self-assembled into giant vesicles with a diameter of several micrometers in a mixed solvent of ethanol and water. When the hydrophobic ratio decreased to ca. 76%, the polymer self-assembled into conventional vesicles with several hundred nanometers. The giant vesicles could be fused in certain conditions, while the conventional vesicles were stable. When the content of the hydrophilic part was further increased, no organized structures were formed. On the other hand, when the copolymer solutions were directly cast on solid substrates such as silicon plates, films with organized nanostructures could also be obtained, the morphology of which depended on solvent selection. When ethanol or methanol was used, spheres were obtained. When dichloromethane was used as the solvent, honeycomb-like morphologies were obtained. These results showed that through appropriate molecular design, random copolymer could self-assemble into various organized structures, which could be regulated through the hydrophobic/hydrophilic balance and the solvents.     

由嵌段共聚物制备有形状的核壳结构聚合物纳米颗粒

嵌段共聚物可自发组装形成形貌丰富的纳米粒子和有序纳米结构的材料,为纳米材料和纳米技术领域提供了很重要的新材料和新手段.该领域的进一步发展提出了对嵌段共聚物的自组装体赋予功能性的要求,即需要通过可控聚合反应合成反应性嵌段共聚物,并且对其自组装的纳米粒子进行结构、形状及功能性的调控.本文针对以上研究目标,结合本课题组在该领...     

基于多重氢键的寡聚芳酰胺自组装囊泡

六重氢键的异互补寡聚芳酰胺双股分子链在自组装过程中表现出极高的顺序专一性. 本文借助扫描电镜（SEM）、透射电镜（TEM）和动态光散射（DLS）等实验手段,研究了氢键编码顺序为DADDAD-DADDAD的寡聚芳酰胺分子1及异互补分子2（ADAADA-ADAADA）存在下的自组装行为. 实验结果表明,分子1在四氢呋喃/甲醇（体积比为85/15）和单一溶剂丙酮中都能组装成大小均匀的囊泡结构,并且囊泡的尺寸随着溶液浓度的增加而增大;当加入异互补分子2后,囊泡则转变成实心球. 利用荧光显微镜,发现该囊泡能很好地包裹荧光分子（罗丹明B）,通过进一步分子结构修饰有可能实现药物包埋和缓释方面的应用.     

新型介孔二氧化硅囊泡结构的调变

本文采用水热合成法,利用非离子表面活性剂聚环氧乙烷-聚环氧丙烷-聚环氧乙烷(P123)对有机溶剂均三甲苯(TMB)的增容作用,合成了大孔径介孔二氧化硅囊泡材料,首次通过控制有机溶剂TMB与无机硅源正硅酸四乙酯(TEOS)的投料时间间隔t,实现对介孔二氧化硅囊泡材料结构的调变。通过小角X射线衍射和高分辨透射电镜(HTEM)检测技术对酸性P123模板体系中的材料结构转变过程进行了表征。结果表明,改变TMB与TEOS的投料时间间隔,能够实现介孔囊泡结构的调变,同时提出"协同囊泡模板"(cooperative vesicle templating,CVT)和"协同作用机制"(cooperative formation mechanism,FM)共存。通过简单合理的设计合成不同结构的介孔材料,以期开拓其在催化、分离以及医学等领域的潜在应用,也为合成其他介孔材料提供简单合理的设计思路。