新型抗菌高分子及其抗菌机理的研究进展

抗菌高分子具有丰富的分子结构和独特的抗菌机制。同时,对微生物具有低耐药性的倾向。这些特点使新型高分子材料在抗菌领域受到人们越来越多的关注。本文首先分析了细菌产生耐药性的原因及由其带来的严峻医学和社会问题;然后系统梳理并探讨了新型抗菌高分子材料如树状大分子、嵌段共聚物、壳聚糖及其衍生物和抗菌高分子/纳米复合材料等的结构特点和抗菌机理;最后展望了未来新型功能高分子在抗菌领域的重点延伸及探索方向。     

模拟天然抗菌多肽高分子抗菌药物的研究进展

由于传统抗生素类药物容易使细菌产生耐药性而成为超级细菌,新型的抗菌药物亟待开发。通过模拟天然抗菌多肽设计合成的高分子抗菌剂,具有很高的抗菌活性和生物选择性,而且由于其合成方法简单,结构易于控制,且可实现大规模工业生产,有望成为代替传统抗生素和抗菌多肽的新一代抗菌药物。本文介绍了天然抗菌多肽的抗菌机理与模拟天然抗菌多肽的...     

载银缓释型抗菌敷料

近10年来,载银缓释型抗菌敷料因其优良特性,在医药、卫生等领域引起科学家们的广泛关注。本文综述了银的抗菌机理和载银缓释型抗菌敷料的缓释机制;重点介绍了目前在国际市场上销售的代表性载银缓释型抗菌敷料的性能,并从不同的载体材料角度(如生物高分子、合成高分子、生物和合成高分子共用、有机硅材料)总结了新型载银抗菌敷料的研究进展;最后,讨论了载银抗菌医用敷料在研究和应用中需要解决的问题。     

新型高分子季鏻盐改性抗菌塑料的制备及性能研究

高分子季鏻盐抗菌剂具有安全、高效的特点,使用过程中不会通过皮肤组织进行渗透。本文将实验室自制的新型高分子季鏻盐抗菌剂粉末与低密度聚乙烯(LDPE)基体材料共混,通过熔融挤出法制备了含梯度浓度抗菌剂的抗菌塑料,研究了不同抗菌剂添加浓度对基体材料熔融性质及其抗菌性能的影响,并探讨了抗菌塑料的生物安全性。结果表明,梯度浓度的抗菌剂改性塑料对金黄色葡萄球菌和大肠杆菌均有良好的抗菌效果;生物安全性测试结果表明,抗菌塑料的细胞毒性为0级,说明抗菌塑料具有较高的生物安全性。     

阳离子抗菌聚合物

阳离子抗菌聚合物, 作为一种新型抗菌材料, 具有独特的抗菌机理和高效的抗菌活性, 并且能有效解决细菌耐药性问题, 引起了人们的广泛关注。阳离子抗菌聚合物具有有效的抗菌活性, 其抗菌活性受到亲疏水平衡、分子质量、烷基链长度和阴离子等因素的影响。抗菌活性是评价抗菌剂优劣的重要因素之一, 了解和掌握影响抗菌活性的因素, 对于优化或开发更安全、更高效的阳离子抗菌聚合物具有重大意义。本文总结了通过不同作用方式作用于细菌的多种抗菌策略, 依据影响阳离子抗菌聚合物抗菌活性的因素, 总结包括天然阳离子抗菌聚合物、季铵盐类聚合物、N-卤代胺类聚合物、膦盐和锍盐类聚合物、胍盐类聚合物和抗菌水凝胶的研究进展。最后, 对阳离子抗菌聚合物面临的挑战和未来发展方向进行了讨论。     

高分子材料接枝抗菌功能改性方法研究现状

近年来,接枝抗菌改性因其可以在不改变高分子材料原本特性的条件下使其具备优异抗菌性能而备受关注,通过接枝抗菌改性的高分子材料被广泛应用于生活中的各个领域。本文综述了目前国内外高分子材料接枝抗菌改性中常用的一些抗菌基团(N-卤代胺结构的物质、带正电的抗菌活性物质等),介绍了这些抗菌基团在高分子材料中起到的抑菌效果及其抑菌机制,并对接枝抗菌改性高分子材料未来的发展趋势进行展望。     

壳聚糖基抗菌型创伤敷料的研究进展

近年来,随着再生医学的快速发展,组织工程技术再造人体组织器官被广泛的关注和研究。其中对加速创伤修复的敷料材料设计非常重要,其结构性质严重影响了再生组织的形态和效果。天然高分子壳聚糖具有广谱抗菌、强效止血作用,无毒性降解物,具有良好的生物相容性、生物活性和生物可降解性良好,能够有效地促进创面愈合和组织修复再生,在生物医用敷料领域具有广阔的应用前景。本文主要综述近年来壳聚糖基创伤敷料设计成型方法,并讨论不同的成型工艺及负载不同抗菌剂的敷料性能及用途差异。以期能够为设计和开发新型壳聚糖基抗菌型创伤敷料材料提供重要参考。     

含胍基抗菌聚合物的合成及应用

开发能与细菌非特异性结合的新型抗菌剂是解决细菌感染难题的方法之一。本文首先介绍了一种具有持久广谱高效抗菌性、无真核细胞毒性和细菌很难产生耐药性的含胍基抗菌聚合物;接着详细介绍了含胍基抗菌聚合物与细菌非特异性静电结合的抗菌机理;然后重点评述了主链含胍基抗菌聚合物、侧链含胍基抗菌聚合物以及表面接枝含胍基抗菌聚合物的设计理念、合成方法和抗菌性能;最后对新型含胍基抗菌聚合物的可控合成策略及应用前景进行了展望。     

有机高分子抗菌剂的制备及抗菌机理

综述了有机高分子抗菌剂的研究进展,分别对带有季铵盐、季鳞盐、有机锡、吡啶类、胍盐类、卤代胺类和壳聚糖衍生物类七种抗菌基团的有机高分子抗菌剂的合成及应用等方面作了评述.重点介绍了季铵盐与季鳞盐两种有机高分子抗菌剂的发展情况,对季铵盐和季鳞盐应用于抗菌剂领域的优劣进行了比较.介绍了近几年发展较快的几种有机高分子抗菌剂的制备...     

有机硅改性纳米银抗菌导尿管的制备

纳米银具备广谱抗菌性、无耐药性、安全和对人体无害的性质。本研究选择了硼氢化钠还原法合成了尺寸为10nm~20nm纳米银,并用r-氨丙基三甲氧基硅烷对纳米银粒子表面进行了有机硅改性。再将经有机硅改性的纳米银粒子涂覆在导尿管内外表面,制备了一种新型纳米银导尿管。通过抗菌实验验证,该方法制备的纳米银导尿管具有显著的抗菌效果。且导尿管抗菌性的时效性研究表明,改性实现了纳米银在导尿管表面的缓慢释放,从而使得导尿管有更为持久的抗菌性。     

温敏性抗菌水凝胶的制备与控释技术研究进展

温敏水凝胶是一类通过感知温度变化使自身发生相变的智能型聚合物凝胶,通过负载抗菌剂或抗菌性单体制备抗菌水凝胶是近年来药物控制释放、组织工程以及生物免疫等领域关注的热点。本文概述了负载抗菌剂型温敏性抗菌水凝胶的物理交联和化学交联制备技术的研究概况,着重阐述了温敏性抗菌水凝胶的孔径调控、制备材料调控、载药模式调控等技术的研究进展,并对温敏性抗菌水凝胶的控释技术应用前景,特别是在生物质材料领域的应用前景进行了展望。     

Surprising Antibacterial Activity and Selectivity of Hydrophilic Polyphosphoniums Featuring Sugar and Hydroxy Substituents

There is currently an urgent need for the development of new antibacterial agents to combat the spread of antibiotic‐resistant bacteria. We explored the synthesis and antibacterial activities of novel, sugar‐functionalized phosphonium polymers. While these compounds exhibited antibacterial activity, we unexpectedly found that the control polymer poly(tris(hydroxypropyl)vinylbenzylphosphonium chloride) showed very high activity against both Gram‐negative Escherichia coli and Gram‐positive Staphylococcus aureus and very low haemolytic activity against red blood cells. These results challenge the conventional wisdom in the field that lipophilic alkyl substituents are required for high antibacterial activity and opens prospects for new classes of antibacterial polymers.     

Synthesis and Antibacterial Action of Poly(DMAEMA-BC)with Various Molecular Weights

Antibacterial polymers of dimethylaminoethyl methacrylate benzyl ammonium chloride(DMAEMA-BC) with various molecular weights(Mws) were prepared under controlling radical polymerization conditions. The Mws of these polymers were determined by means of static multiangle laser light scattering and viscosity method. A Mark-Houwink equation was established to be [η]=0.154M0.764 for the Mw evaluation of poly(DMAEMA-BC)s. The effects of the Mws of these poly(DMAEMA-BC)s on their antibacterial activities against E. coli and S. aureus were investigated by various methods including viable cell counting, electrical conductivity titration, intracellular constituent leakage tests and electron microscopy. Our results indicate that the antibacterial efficiency of DMAEMA-BC was significantly enhanced after the monomers were polymerized into a polymer and increased obviously with the Mws,as a result of the increase of charge density. Further investigation of the molecular basis underlying the anti-bacterial role of these polymers revealed that poly(DMAEMA-BC) promoted the release of potassium ion from the membrane of bacterial cells and the release increased significantly with the Mws of the polymers used.     

Antibacterial Hybrid Hydrogels

Bacterial infectious diseases and bacterial‐infected environments have been threatening the health of human beings all over the world. In view of the increased bacteria resistance caused by overuse or improper use of antibiotics, antibacterial biomaterials are developed as the substitutes for antibiotics in some cases. Among them, antibacterial hydrogels are attracting more and more attention due to easy preparation process and diversity of structures by changing their chemical cross‐linkers via covalent bonds or noncovalent physical interactions, which can endow them with various specific functions such as high toughness and stretchability, injectability, self‐healing, tissue adhesiveness and rapid hemostasis, easy loading and controlled drug release, superior biocompatibility and antioxidation as well as good conductivity. In this review, the recent progress of antibacterial hydrogel including the fabrication methodologies, interior structures, performances, antibacterial mechanisms, and applications of various antibacterial hydrogels is summarized. According to the bacteria‐killing modes of hydrogels, several representative hydrogels such as silver nanoparticles‐based hydrogel, photoresponsive hydrogel including photothermal and photocatalytic, self‐bacteria‐killing hydrogel such as inherent antibacterial peptides and cationic polymers, and antibiotics‐loading hydrogel are focused on. Furthermore, current challenges of antibacterial hydrogels are discussed and future perspectives in this field are also proposed.     

Biodegradable Polypeptide-based Vesicles with Intrinsic Blue Fluorescence for Antibacterial Visualization

Fluorescence imaging has been an indispensable tool to provide dynamic information about the localization and quantity of organisms.Meanwhile,due to the intrinsic hollow structure and modularized biofunctionalities,polymer vesicles have been widely applied in biomedical field.However,most polymer vesicles are embedded with organic fluorophores for fluorescence imaging,which have certain drawbacks such as leakage and possible cytotoxicity.Here,we present a biodegradable polypeptide-based vesicle with intrinsic blue fluorescence without introducing any fluorophore for real-time visualization of antibacterial process.Through modular design to integrate multiple functional fragments,poly(ε-caprolactone)-block-poly(tryptophan)-block-poly(lysine-stat-phenylalanine)[PCL25-b-PTrP2-b-P(Lys13-stat-Phe4)]was synthesized,where PCL chains form the hydrophobic membrane,P(Lys-stat-Phe) and PTrp provide intrinsic fluorescence and broad-spectrum antibacterial activity.It is noteworthy that the fluorescence emission was shifted from invisible ultraviolet range of amino acids to visible range (emission maximum at 436 nm),which makes it possible to visualize the antibacterial process.In addition,through utilizing the intrinsic fluorescence of vesicles,confocal fluorescent imaging of vesicles with bacteria validated the specific adhesion of vesicle towards bacteria,and the bacterial death through membrane disruption.Overall,we provided a novel approach to developing biodegradable fluorescent polypeptide-based vesicles for real-time visualization of antibacterial process.     

基于正电荷和光热协同效应的新型半导体聚合物纳米抗菌材料

由于抗生素的不当使用和细菌多药耐药的出现, 迫切需要开发新的抗菌剂. 本文制备了具有光热转换性能的正电荷半导体高分子材料及具有协同抗菌活性的半导体聚合物纳米粒子(SP-PPh₃ NPs). SP-PPh₃ NPs的光热转化效率为43.8%. 带正电荷的SP-PPh₃ NPs可以附着在细菌上, 有助于将热量有效传递给细菌. 在热和正电荷的协同作用下, SP-PPh₃ NPs对革兰氏阴性大肠杆菌(E. coli)和革兰氏阳性金黄色葡萄球菌(S. aureus)均具有抗菌活性, 其对二者的体外抑菌率分别为99.9%和98.6%. 此外, SP-PPh₃ NPs具有良好的生物相容性, 对小鼠的主要器官几乎无副作用. 对细菌感染的小鼠皮肤伤口用SP-PPh₃ NPs治疗12 d后, 伤口可以很好地愈合.     

咪唑盐类聚离子液体抗菌剂的制备及其在水凝胶敷料中的应用

皮肤伤口的感染严重威胁患者的生命安全,虽然传统的含有银离子或小分子抗生素的抗菌水凝胶伤口敷料具有广谱的杀菌功效,但这些抗菌水凝胶敷料中的抗菌剂存在一定的生物毒性和耐药性风险,无法满足临床长期使用的要求.咪唑盐类聚离子液体由于其含有较强的正电荷效应以及疏水链段,因此其作为新型的聚合物抗菌剂具有较强的抗菌效果.本研究首先通...     

Antibacterial polyethylene - Ethylene vinyl acetate polymeric blend by incorporation of zinc oxide nanoparticles

In this work, a Low-Density Polyethylene (LDPE) - Ethylene Vinyl Acetate (EVA) polymeric blend with antimicrobial activity was obtained. The main objective was to develop an antibacterial LDPE-EVA polymeric blend from the incorporation of antibacterial nanoparticles to increase the antimicrobial and sanitary safety of this polymeric blend when applied in the manufacture of medical products. The antibacterial activity was obtained from the incorporation of zinc oxide nanoparticles (ZnO-NPs) in the LDPE-EVA polymeric blends and the thermal properties were evaluated by differential scanning calorimetry and the mechanical properties by tensile stress tests for different percentages of ZnO-NPs. Scanning electron microscopy was used to study the morphological characteristics of the ZnO-NPs and also the characteristics of the distribution of nanoparticles in the polymer blends. The dispersive energy of x-ray fluorescence spectroscopy was used to study the chemical composition of the nanoparticles. Microbiological tests were performed to evaluate the antibacterial activity of the LDPE-EVA polymeric blends without and with ZnO-NPs against the bacteria Staphylococcus aureus (gram-positive) and Escherichia coli (gram-negative). The results obtained were excellent for the future application of the antibacterial LDPE-EVA polymeric blends to the manufacture of medical products. The Young's modulus values decreased and the tensile strength values showed small reductions and the thermal properties of the LDPE-EVA were not modified. However, the antibacterial activity of LDPE-EVA with 4 wt% of ZnO-NPs was excellent, eliminating the gram-positive bacteria in just 2 h and the gram-negative bacteria in just 2.5 h on their surfaces.     

Reactive TiO2 Nanoparticles Compatibilized PLLA/PBSU Blends:Fully Biodegradable Polymer Composites with Improved Physical,Antibacterial and Degradable Properties

The fully biodegradable polymer blends remain challenges for the application due to their undesirable comprehensive performance.Herein,remarkable combination of superior mechanical performance,bacterial resistance,and controllable degradability is realized in the biodegradable poly(L-lactide)/poly(butylene succinate) (PLLA/PBSU) blends by stabilizing the epoxide group modified titanium dioxide nanoparticles (m-TiO2) at the PLLA-PBSU interface through reactive blending.The m-TiO2 can not only act as interfacial compatibilizer but also play the role of photodegradation catalyst:on the one hand,binary grafted nanoparticles were in situ formed and stabilized at the interface to enhance the compatibility between polymer phases.As a consequence,the mechanical properties of the blend,such as the elongation at break,notched impact strength and tensile yield strength,were simultaneously improved.On the other hand,antibacterial and photocatalytic degradation performance of the composite films was synergistically improved,it was found that the m-TiO2 incorporated PLLA/PBSU films exhibit more effective antibacterial activity than the neat PLLA/PBSU films.Moreover,the analysis of photodegradable properties revealed that that m-TiO2 nanoparticles could act as a photocatalyst to accelerate the photodegradation rate of polymers.This study paves a new strategy to fabricate advanced PLLA/PBSU blend materials with excellent mechanical performance,antibacterial and photocatalytic degradation performance,which enables the potential utilization of fully degradable polymers.     

Review: Antibacterial behavior of carboxylate silver(I) complexes

Since ancient times, silver ions have been known to be effective against a broad range of micro-organisms but in the last decade, this metal has been greatly studied because of their antimicrobial capability against a wide range of bacteria, viruses, and fungi. For the same reason, it is the most extensively studied metal with antibacterial applications in medicine. Besides applications, the antimicrobial activity is associated with high effectiveness, low toxicity, and virtually no resistance of micro-organisms to the presence of this metal. The appearance of new bacterial strains resistant to antibiotics is a serious health problem; so, there is a strong incentive to develop new bactericides. This makes current research in bactericidal silver complexes particularly important. This review summarizes the most important aspect related to coordination chemistry of Ag(I) carboxylate complexes and their influence as antibacterial agents.