Department of Chemistry, University of Florida, Gainesville, Florida 32611-7200, United States.
Inorg Chem. 2021 Feb 1;60(3):1641-1653. doi: 10.1021/acs.inorgchem.0c03133. Epub 2021 Jan 12.
The syntheses, crystal structures, and catalytic radical scavenging activity are reported for four new molecular clusters that have resulted from a bottom-up molecular approach to nanoscale CeO. They are [CeO(OH)(dmb)(HO)] (dmb = 2,6-dimethoxybenzoate), [CeO(OH)(OCPh)(HOCPh)], [CeO(OH)(OCPh)(HO)(py)], and [CeO(OH)(OCPh)(py)]. They represent a major expansion of our family of so-called "molecular nanoparticles" of this metal oxide to seven members, and their crystal structures confirm that their cores all possess the fluorite structure of bulk CeO. In addition, they have allowed the identification of surface features such as the close location of multiple Ce ions and organic ligand binding modes not seen previously. The ability of all seven members to catalytically scavenge reactive oxygen species has been investigated using HO radicals, an important test reaction in the ceria nanoparticle biomedical literature, and most have been found to exhibit excellent antioxidant activities compared to traditional ceria nanoparticles, with their activity correlating inversely with their surface Ce content.
本文报道了四个新的分子簇合物的合成、晶体结构和催化清除自由基活性,这些分子簇合物是通过自下而上的方法合成纳米 CeO 的结果。它们分别是[CeO(OH)(dmb)(HO)](dmb=2,6-二甲氧基苯甲酸)、[CeO(OH)(OCPh)(HOCPh)]、[CeO(OH)(OCPh)(HO)(py)]和[CeO(OH)(OCPh)(py)]。它们代表了我们所谓的这种金属氧化物“分子纳米粒子”的家族的重大扩展,达到了七个成员,它们的晶体结构证实了它们的核心都具有体相 CeO 的萤石结构。此外,它们还确定了以前没有看到的表面特征,如多个 Ce 离子的紧密位置和有机配体的结合模式。使用 HO 自由基研究了所有七个成员催化清除活性氧物种的能力,这是 ceria 纳米粒子生物医学文献中的一个重要测试反应,与传统的 ceria 纳米粒子相比,大多数都表现出优异的抗氧化活性,其活性与表面 Ce 含量成反比。
