Bacterial infection arised from multipathogenic bacteria is a tricky issue that attracts worldwide attentions.In this paper,a highly accessible copper single-atom catalyst(Cu SAC)supported by biocompatible N-doped mes...Bacterial infection arised from multipathogenic bacteria is a tricky issue that attracts worldwide attentions.In this paper,a highly accessible copper single-atom catalyst(Cu SAC)supported by biocompatible N-doped mesoporous carbon nanospheres was synthesized with the emulsion-template method.The tightly anchored copper single-atom of the catalyst could effectively transform O_(2) into O_(2)−•under ambient conditions by the ultra-large pore size(~23.80 nm)and small particle size(~97.71 nm).Due to multiple synergistically oxidative damages to biomolecules,the Cu SAC could be employed to eliminate different bacteria in vitro without the generation of multidrug resistance(MDR).Moreover,the Cu SAC could also promote wound healing in vivo by eradicating the propagation of bacteria at wound.It is envisioned that the Cu SAC with superior antibacterial performance could be applied in the treatment of related bacterial infection in future.展开更多
基金This work was supported by National Key R&D Program of China 2017YFA(Nos.0208300 and 0700104)the National Natural Science Foundation of China(No.21671180)We thank the funding support from CAS Fujian Institute of Innovation.This work was financially supported by the Cooperation Fund(No.DNL201918)。
文摘Bacterial infection arised from multipathogenic bacteria is a tricky issue that attracts worldwide attentions.In this paper,a highly accessible copper single-atom catalyst(Cu SAC)supported by biocompatible N-doped mesoporous carbon nanospheres was synthesized with the emulsion-template method.The tightly anchored copper single-atom of the catalyst could effectively transform O_(2) into O_(2)−•under ambient conditions by the ultra-large pore size(~23.80 nm)and small particle size(~97.71 nm).Due to multiple synergistically oxidative damages to biomolecules,the Cu SAC could be employed to eliminate different bacteria in vitro without the generation of multidrug resistance(MDR).Moreover,the Cu SAC could also promote wound healing in vivo by eradicating the propagation of bacteria at wound.It is envisioned that the Cu SAC with superior antibacterial performance could be applied in the treatment of related bacterial infection in future.
