生物可降解聚膦腈材料的功能化及研究进展

聚膦腈是一类主链由磷氮原子交替组成,每个磷原子带有两个有机官能团侧基的有机-无机杂化高分子,其化学结构强大的可设计性赋予了材料丰富的理化性能。作为生物学用途的聚膦腈材料,生物相容性、生物可降解性和功能化改性是实现其应用的关键因素。本文从数种功能化聚膦腈(如光致荧光、导电、聚膦腈-聚酯共聚物)的制备、聚膦腈的降解机理和降解行为调控,以及生物可降解聚膦腈作为组织工程支架材料、药物载体材料和基因转染材料等几个方面,较为全面地综述了聚膦腈生物医用高分子的研究进展。     

可生物降解聚[(对羟基苯甲酸甲酯/甘氨酸乙酯)膦腈]的合成及其体外降解

以PCl5和NH4Cl为原料,利用一锅法制备了聚二氯膦腈,通过两步亲核取代反应,分别以甘氨酸乙酯和对羟基苯甲酸甲酯为亲核试剂,合成了混合取代可生物降解聚[(对羟基苯甲酸甲酯/甘氨酸乙酯)膦腈].用核磁共振波谱及红外光谱等对产物结构进行了表征.研究了甘氨酸乙酯和对羟基苯甲酸甲酯的比例及外界环境对所制备的聚膦腈降解性能的影响,并进行了体外降解实验.研究结果表明,通过改变甘氨酸乙酯和对羟基苯甲酸甲酯的比例,可获得一种降解速率可调节的生物降解膦腈聚合物.     

聚膦腈在药物控释系统中的应用

聚膦腈由于其具有良好的生物相容性，可生物降解性及易于功能化的特性而成为一类独特的药物控释材料。本文就疏水性线型聚膦腈，聚膦腈水凝胶及聚膦腈高分子药物在药物控释系统中的应用作一简要综述。     

聚膦腈-g-聚己内酯共聚物的合成与表征

通过三甲基碘硅烷与聚二(2-甲氧基乙氧基)膦腈侧链上的醚键反应后水解得到侧链含部分羟基的聚膦腈,然后利用聚膦腈的侧链羟基在异辛酸亚锡催化作用下,引发己内酯单体开环聚合制备了聚膦腈-g-聚己内酯共聚物.该共聚物中聚己内酯链段的接枝率和侧链长度可通过改变三甲基碘硅烷和己内酯单体的投料来控制.     

化学交联葡萄糖基取代聚膦腈水凝胶制备和胰岛素释放研究

在合成了葡萄糖基和甲氧乙氧基共取代聚膦腈的基础上,进一步通过向聚膦腈主链引入一定量带自由氨基的取代基,与戊二醛反应交联后,获得了具有化学交联点的聚膦腈水凝胶.该水凝胶与伴刀豆球蛋白(Con A)结合后,水凝胶的溶涨平衡性能表现出对葡萄糖浓度的依赖性.将负载有胰岛素的聚膦腈水凝胶交替置于含不同葡萄糖浓度(4 mg/mL和1 mg/mL)的介质中,可检测到在高浓度葡萄糖环境下,胰岛素的释放明显加快,而当葡萄糖的浓度降低后,在一段时间内几乎检测不到胰岛素的释放,但随着浸泡时间的延长,仍会逐渐出现胰岛素从凝胶缓慢扩散释放的现象.以上研究表明,化学交联的葡萄糖基取代聚膦腈水凝胶可用于对胰岛素的葡萄糖响应释放.     

温敏性聚膦腈及其在药物释放体系中的应用

温敏性聚合物能通过感知温度而实现环境响应,作为药剂可依靠对此类信号的自反馈响应而释放药物或中止释放,极大地增强了释药的持续性和专一性,从而提高了药物的药效和安全性.温敏性聚膦腈是一类新型的温敏材料,它具有良好的生物可降解性质,优良的生物相容性.因此,温敏性聚膦腈作为药物载体用于药物释放体系具有很好的应用前景,近年来备受关注.本文对聚膦腈的温敏性质、生物降解性质进行了评述,并探讨了LCST的影响因素,以及在药物释放体系的应用进展.     

直链淀粉交联氨基酸酯取代聚膦腈杂化材料的制备

利用直链淀粉与甘/丙氨酸乙酯共取代聚膦腈交联, 制得了一种具有网络结构的新型杂化材料. 实验结果表明, 淀粉衍生物上的羟基转变为醇钠后, 可与聚膦腈分子链上的P-Cl键发生亲核取代反应; 所得聚合物膜无明显相分离, 力学性能优于具有相似组成的直链淀粉/聚膦腈共混膜, 表面亲水性和吸水率与对应的共混膜接近, 且均高于纯聚膦腈膜. 因此, 该聚合物可作为杂化生物材料用于药物控制释放和组织工程方面的研究.     

聚[(甲氧基乙氧基乙氧基)1.0(乙氧基吡咯烷酮)1.0]膦腈的合成及性能研究

用三氯化铝催化六氯三聚膦腈开环聚合制得线性聚二氯膦腈(PDCP), 通过PDCP磷原子上的亲核取代反应, 合成了新的水溶性高分子聚[(甲氧基乙氧基乙氧基)_1.0(乙氧基吡咯烷酮)_1.0]膦腈(P3), 用³¹P NMR, ¹H NMR, ¹³C NMR和IR对其结构进行了确证, 用DSC测定了其玻璃化转变温度T_g和熔融温度T_m, 用蒸汽压渗透法(VPO)测定了其数均分子量. 改进了聚二(乙氧基吡咯烷酮)膦腈(P2)的合成方法. 体外降解实验表明, P3具有和P2类似的pH响应性降解行为, 降解速率在pH=5.0时最快, 而在pH=7.4和8.0时较慢. P3在所测试的3个pH缓冲溶液中均比P2降解慢. 用³¹P NMR、薄层色谱(TLC)和滴定法对降解产物进行了检测, 初步推断了P3在不同pH介质中的水解机理, 其在pH=5.0的缓冲溶液中的降解, 除侧链断裂外, 聚膦腈的骨架也裂解; 而在pH=7.4和8.0时的降解仅为侧链的断裂. 用噻唑蓝(MTT)比色法进行的体外细胞毒性评价实验表明, P3及其在pH=5.0的缓冲溶液中降解49 d后的产物均对细胞表现出了很好的生物相容性, 而且其降解产物在浓度为800 μg/mL时还表现出一定的促进细胞增殖作用.     

以环三膦腈为核的非线性聚磷腈高分子

综述了近十多年来以环三膦腈为核的非线性聚膦腈高分子的合成、性能及其应用。重点介绍了直接亲核取代法与多官能团引发剂法在合成以环三膦腈为核的星形高分子中的应用,以及发散法与收敛法在合成以环三膦腈为核的树形高分子中的应用。简要阐述了以环三膦腈为核的星形、树形高分子在光电材料、生物医用材料等方面的应用,并展望了以环三膦腈为核的非线性聚膦腈高分子的发展趋势和方向。     

氨基酸酯-烷基醚混合取代聚膦腈的合成与表征

聚膦腈高聚物,因其良好的生物相容性而用作生物医用材料。若在其侧链引入对热(如烷氧基醚)或对pH值敏感和可生物降解的基团(如氨基酸酯),则可得到具有环境敏感性和可生物降解性能的高聚物,这些高聚物可望作为药物载体,用于药物的控制释放。     

Application of pyrolysis-capillary gas chromatography with NPD detection in thermal degradation of polyphosphazenes study

Polyphosphazenes represent a unique class of polymers with a backbone composed of alternating phosphorous and nitrogen atoms. The thermal behaviour and decomposition of a variety of polyphosphazenes depends on the type of side groups present. Especially those that bear aryloxy side groups, possess a high temperature stability as well as excellent flame resistance. Pyrolysis-capillary gas chromatography has been used in a study of three polyphosphazene samples for thermal stability characterisation. Degradation products were detected with three single detectors for flame ionisation (FID), nitrogen-phosphorous sensitivity (NPD) and mass spectrometry (MSD) at different pyrolysis temperatures ranging from 300°C up to 800°C. The NPD responses for phosphorous or nitrogen fragments of polyphosphazenes have been used for the construction of degradation product schemes and the examination of the thermal stability of the polyphosphazene’s backbone. Partial identification of the degradation products present in the gaseous phase was achieved by MSD. The polyphosphazenes thermal degradation conversion rates were at a maximum at 450–500°C. At various pyrolysis temperatures, the calculated N/P peak area ratio is a function of the degree of polyphosphazene-N=P-chain degradation, and reflective of the nitrogen — phosphorous detector sensitivity. NPD proved to be suitable tool for characterization of polyphospazene thermal stability.     

聚磷腈功能材料研究进展

聚磷腈是一类具有特殊性能的无机高分子功能材料。本文对聚磷腈的结构、性能、制备方法、反应性及应用进行了综述，并对其发展前景作了预测。     

Biodegradable polyphosphazenes for drug delivery

Polyphosphazene derivatives having amino acid ester side groups were prepared by reaction of poly(dichlorophosphazene) with ethyl esters of amino acids. The in vitro degradation studies demonstrated that the rate of degradation depends on the nature of the amino acids. Introducing small amounts of hydrolytically sensitive groups such as depsipeptide ester or hydrolysis-catalysing moieties, such as histidine ethyl ester co-substituents, resulted in an increase of the degradation. The rate of hydrolytic degradation of the polyphosphazene material could be controlled by the content of the hydrolytically sensitive side groups or by blending hydrolysis-sensitive polymers with more stable derivatives. The results obtained from the in vivo implantation of biodegradable polyphosphazenes in mice indicate that the materials are very well tolerated by the animal body. Biodegradable polyphosphazenes have been used as matrix for the design of drug delivery systems. The rate of the in vitro release of mitomycin C from biodegradable polyphosphazenes can be controlled by changing the chemical composition of the polymer or by blending polymers of different chemical compositions.     

Hetero and homo α,ω-chain-end functionalized polyphosphazenes

The control of chain-ends is fundamental in modern macromolecular chemistry for directed one-to-one bioconjugation and the synthesis of advanced architectures such as block copolymers or bottlebrush polymers and the preparation of advanced soft materials. Polyphosphazenes are of growing importance as elastomers, biodegradable materials and in biomedical drug delivery due to their synthetic versatility. While controlled polymerization methods have been known for some time, controlling both chain-ends with high fidelity has proven difficult. We demonstrate a robust synthetic route to hetero and homo α,ω-chain-end functionalized polyphosphazenes via end-capping with easily accessible, functionalized triphenylphosphine-based phosphoranimines. A versatile thiol-ene “click”-reaction approach then allows for subsequent conversion of the end-capped polymers with various functional groups. Finally, we demonstrate the utility of this system to prepare gels based on homo α,ω-chain-end functionalized polyphosphazenes. This development will enhance their progress in various applications, particularly in soft materials and as degradable polymers.     

聚磷腈高分子

简要综述了聚磷腈高分子的合成、结构与物理性能及在新型功能材料方面的应用,包括高分子电解质、光导电材料、非线性光学材料以及生物医用材料。     

Synthesis and characterization of new biodegradable thermosensitive polyphosphazenes with lactic acid ester and methoxyethoxyethoxy side groups

<正>Two novel biodegradable thermosensitive polyphosphazenes with lactic acid ester and methoxyethoxyethoxy side groups were synthesized via the macromolecular substitution reactions of poly(dichlorophosphazene) with the sodium salt of lactic acid ester and sodium methoxyethoxyethoxide.Their structures were confirmed by ~(31)p NMR,~1H NMR,~(13)C NMR,IR,DSC,and elemental analysis.The lower critical solution temperature(LCST) behavior in water and in vitro degradation property of the polymers was investigated.The results indicated that two polymers showed LCST phase transition over a range of concentrations from 0.13 to 15 wt%and pH-sensitive degradation properties.     

Metabolically Active,Fully Hydrolysable Polymersomes

The synthesis and aqueous self‐assembly of a new class of amphiphilic aliphatic polyesters are presented. These AB block polyesters comprise polycaprolactone (hydrophobe) and an alternating polyester from succinic acid and an ether‐substituted epoxide (hydrophile). They self‐assemble into biodegradable polymersomes capable of entering cells. Their degradation products are bioactive, giving rise to differentiated cellular responses inducing stromal cell proliferation and macrophage apoptosis. Both effects emerge only when the copolymers enter cells as polymersomes and their magnitudes are size dependent.     

Metabolically Active,Fully Hydrolysable Polymersomes

The synthesis and aqueous self‐assembly of a new class of amphiphilic aliphatic polyesters are presented. These AB block polyesters comprise polycaprolactone (hydrophobe) and an alternating polyester from succinic acid and an ether‐substituted epoxide (hydrophile). They self‐assemble into biodegradable polymersomes capable of entering cells. Their degradation products are bioactive, giving rise to differentiated cellular responses inducing stromal cell proliferation and macrophage apoptosis. Both effects emerge only when the copolymers enter cells as polymersomes and their magnitudes are size dependent.     

Characterization of gas transport in selected rubbery amorphous polyphosphazene membranes

Gas permeabilities for six different gases have been evaluated for a series of closely related polyphosphazenes. Polyphosphazenes are attractive polymers for use as gas separation membranes due to their inherent chemical, thermal, and radiation stability. Additionally, polyphosphazenes may be tailored for specific chemical affinities. In this report, polyphosphazenes with three different pendant groups with varied hydrophilicity were characterized for gas permeation. All polymers were characterized as having modest permeabilities for methane, oxygen, nitrogen, helium, and hydrogen. These gases were not observed to have a significant interaction with the polymer structure and transport is attributed to segmental chain motion. Carbon dioxide was found to have a significant intermolecular interaction with the polymer and the permeability was observed to be proportional to the percentage of hydrophilic 2-(2-methoxyethoxy)ethanol on the backbone. Thus, we report a promising method for the development of CO₂ selective membranes.     

Synthesis, characterization and hydrolytic degradation of linear and crosslinked poly[(glycino ethyl ester)(allyl amino)phosphazene]

Polyorganophosphazenes substituted by glycino ethyl ester and allylamine with different ratios were synthesized and their structures were characterized by ¹H NMR, ³¹P NMR and FTIR. Via the crosslink reaction, a novel biodegradable crosslinked polyorganophosphazene material was obtained. DSC and FTIR spectra indicated the occurrence of crosslink. Hydrolysis studies were also performed to compare the crosslinked polymers with linear ones. The co-substituted polyorganophosphazenes with more allylamine at pendant groups exhibited a lower degradation rate than poly[bis(glycino ethyl ester)phosphazene] and crosslinked polyphosphazenes had an even lower degradation rate. SEM photographs characterized the surface of polyphosphazenes films after hydrolytic degradation, confirming that uncrosslinked ones had outstanding hydrolytic evidences at the surface while the crosslinked ones only had sporadic small erosion holes, remaining much smoother.