This work reports the inherent peroxidase-like properties of Ruthenium (Ru) nanoframes. After templating with Palladium (Pd) seeds, Ru nanoframes with an octa- hedral shape, average edge length of 6.2 nm, and thic...This work reports the inherent peroxidase-like properties of Ruthenium (Ru) nanoframes. After templating with Palladium (Pd) seeds, Ru nanoframes with an octa- hedral shape, average edge length of 6.2 nm, and thickness of 1.8 nm were synthesized in high purity (〉95 %) and good uniformity. Using the oxidation of 3,3t,5,5'-tetram- ethylbenzidine (TMB) by H202 as a model catalytic reac- tion, the Ru frames were demonstrated to be approximately three times more active than natural peroxidases in cat- alyzing the formation of colored products. As compared to their natural counterparts, Ru frames have a stronger binding affinity to TMB as well as a weaker binding affinity to hydrogen peroxide during the catalysis. The Ru frames as peroxidase mimics proved to be chemically and thermally stable. This work represents the first demonstration of Ru nanostructure-based peroxidase mimics and is therefore expected to inspire future research on bio-applications of Ru nanomaterials.展开更多
基金supported by startup funds from Michigan Technological Universitythe Michigan Translational Research & Commercialization Fund (MTRAC)+1 种基金Grant Case-48161 of the 21st Century Jobs Trust Fund received through the Michigan Strategic Fund from the State of MichiganThe MTRAC program is funded by the Michigan Strategic Fund with program oversight by the Michigan Economic Development Corporation
文摘This work reports the inherent peroxidase-like properties of Ruthenium (Ru) nanoframes. After templating with Palladium (Pd) seeds, Ru nanoframes with an octa- hedral shape, average edge length of 6.2 nm, and thickness of 1.8 nm were synthesized in high purity (〉95 %) and good uniformity. Using the oxidation of 3,3t,5,5'-tetram- ethylbenzidine (TMB) by H202 as a model catalytic reac- tion, the Ru frames were demonstrated to be approximately three times more active than natural peroxidases in cat- alyzing the formation of colored products. As compared to their natural counterparts, Ru frames have a stronger binding affinity to TMB as well as a weaker binding affinity to hydrogen peroxide during the catalysis. The Ru frames as peroxidase mimics proved to be chemically and thermally stable. This work represents the first demonstration of Ru nanostructure-based peroxidase mimics and is therefore expected to inspire future research on bio-applications of Ru nanomaterials.
