三氯生抗菌聚合物。

IF 0.7 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY
AIMS Molecular Science Pub Date : 2016-01-01 Epub Date: 2016-03-29 DOI:10.3934/molsci.2016.1.88
Richard C Petersen
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引用次数: 46

摘要

用构象计算化学分析方法综述了三氯生抗菌分子中氧原子非键电子对在醚键旋转下的波动能。随后对三氯生交替醚键旋转的理解能够帮助解释聚合物科学中的几种材料性质。三氯生和聚合物链之间独特的键旋转纠缠增加了聚合物的韧性和强度的机械性能,通过二级键关系可以更好地增强。此外,由于相似的分子关系和极性,聚合物共混增容被考虑。由于三氯生在聚合物中的增容作用,非极性三氯生在聚合物固体状态下的稳定性更加均匀,抗菌剂在水溶液中的溶解度极低,释放量极低。因此,三氯生作为一种抗菌聚合物添加剂预计将有很长的使用寿命。此外,三氯生快速交替醚键旋转破坏树脂状态下链单体之间的二级键,以降低粘度并增强聚合物共混。因此,三氯生被认为是一种具有多种特性的聚合物添加剂,作为非极性增韧剂和疏水润湿剂具有额外的好处。通过一种完全不同形式的介质,与已知的通过快速波动的机械分子能量扰乱细菌细胞膜的抗菌特性进行比较,描述了三氯生材料与交替醚键旋转的关系。此外,三氯生键与二级键的缠结会在薄弱的细菌脂质膜上产生结构缺陷,需要柔韧性,从而干扰细胞分裂。对于聚合物的应用,三氯生可以在固化前混合到树脂系统中,与热塑性聚合物混合,冷却成固体,或者通过几种不同的方法作为涂层使用,溶解到有机溶剂中并通过蒸发干燥作为常见方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Triclosan antimicrobial polymers.

Triclosan antimicrobial polymers.

Triclosan antimicrobial polymers.

Triclosan antimicrobial polymers.

Triclosan antimicrobial molecular fluctuating energies of nonbonding electron pairs for the oxygen atom by ether bond rotations are reviewed with conformational computational chemistry analyses. Subsequent understanding of triclosan alternating ether bond rotations is able to help explain several material properties in Polymer Science. Unique bond rotation entanglements between triclosan and the polymer chains increase both the mechanical properties of polymer toughness and strength that are enhanced even better through secondary bonding relationships. Further, polymer blend compatibilization is considered due to similar molecular relationships and polarities. With compatibilization of triclosan in polymers a more uniform stability for nonpolar triclosan in the polymer solid state is retained by the antimicrobial for extremely low release with minimum solubility into aqueous solution. As a result, triclosan is projected for long extended lifetimes as an antimicrobial polymer additive. Further, triclosan rapid alternating ether bond rotations disrupt secondary bonding between chain monomers in the resin state to reduce viscosity and enhance polymer blending. Thus, triclosan is considered for a polymer additive with multiple properties to be an antimicrobial with additional benefits as a nonpolar toughening agent and a hydrophobic wetting agent. The triclosan material relationships with alternating ether bond rotations are described through a complete different form of medium by comparisons with known antimicrobial properties that upset bacterial cell membranes through rapid fluctuating mechanomolecular energies. Also, triclosan bond entanglements with secondary bonding can produce structural defects in weak bacterial lipid membranes requiring pliability that can then interfere with cell division. Regarding applications with polymers, triclosan can be incorporated by mixing into a resin system before cure, melt mixed with thermoplastic polymers that set on cooling into a solid or alternatively applied as a coating through several different methods with dissolving into an organic solvent and dried on by evaporation as a common means.

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来源期刊
AIMS Molecular Science
AIMS Molecular Science BIOCHEMISTRY & MOLECULAR BIOLOGY-
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审稿时长
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