Tilocca Antonio
Department of Chemistry, University College London, 20 Gordon Street, London WC1H 0AJ, UK.
Phys Chem Chem Phys. 2015 Jan 28;17(4):2696-702. doi: 10.1039/c4cp04711g. Epub 2014 Dec 11.
Molecular dynamics simulations of Na(+)/H(+)-exchanged 45S5 Bioglass® models reveal that a large fraction of the hydroxyl groups introduced into the proton-exchanged, hydrated glass structure do not initially form covalent bonds with Si and P network formers but remain free and stabilised by the modifier metal cations, whereas substantial Si-OH and P-OH bonding is observed only at higher Na(+)/H(+) exchange levels. The strong affinity between free OH groups and modifier cations in the highly fragmented 45S5 glass structure appears to represent the main driving force for this effect. This suggests an alternative direct route for the formation of a repolymerised silica-rich gel in the early stages of the bioactive mechanism, not considered before, which does not require sequential repeated breakings of Si-O-Si bonds and silanol condensations.
对钠/氢交换的45S5生物活性玻璃模型进行的分子动力学模拟表明,引入到质子交换的水合玻璃结构中的大部分羟基最初并未与硅和磷网络形成体形成共价键,而是保持游离状态并由改性金属阳离子稳定,而只有在较高的钠/氢交换水平下才会观察到大量的硅-羟基和磷-羟基键合。在高度碎片化的45S5玻璃结构中,游离羟基与改性阳离子之间的强亲和力似乎是这种效应的主要驱动力。这表明在生物活性机制的早期阶段,存在一种之前未被考虑的形成富含二氧化硅的再聚合凝胶的替代直接途径,该途径不需要硅-氧-硅键的连续重复断裂和硅醇缩合。
