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Spatial engineering of single-atom Fe adjacent to Cu-assisted nanozymes for biomimetic O 2 activation.

Ying WangVinod K PaidiWeizhen WangYong WangGuangri JiaTingyu YanXiaoqiang CuiSonghua CaiJingxiang ZhaoKug-Seung LeeLawrence Yoon Suk LeeKwok-Yin Wong
Published in: Nature communications (2024)
The precise design of single-atom nanozymes (SAzymes) and understanding of their biocatalytic mechanisms hold great promise for developing ideal bio-enzyme substitutes. While considerable efforts have been directed towards mimicking partial bio-inspired structures, the integration of heterogeneous SAzymes configurations and homogeneous enzyme-like mechanism remains an enormous challenge. Here, we show a spatial engineering strategy to fabricate dual-sites SAzymes with atomic Fe active center and adjacent Cu sites. Compared to planar Fe-Cu dual-atomic sites, vertically stacked Fe-Cu geometry in FePc@2D-Cu-N-C possesses highly optimized scaffolds, favorable substrate affinity, and fast electron transfer. These characteristics of FePc@2D-Cu-N-C SAzyme induces biomimetic O 2 activation through homogenous enzymatic pathway, resembling functional and mechanistic similarity to natural cytochrome c oxidase. Furthermore, it presents an appealing alternative of cytochrome P450 3A4 for drug metabolism and drug-drug interaction. These findings are expected to deepen the fundamental understanding of atomic-level design in next-generation bio-inspired nanozymes.
Keyphrases
  • aqueous solution
  • metal organic framework
  • electron transfer
  • molecular dynamics
  • tissue engineering
  • adverse drug
  • amino acid
  • carbon nanotubes