Stabilized and Controlled Release of Radicals within Copper Formate-Based Nanozymes for Biosensing
Yue Zhou, Xiaohua Chen, Shaoqi Zhan, Qiang Wang, Feng Deng, Qingzhi Wu, Jian Peng
Abstract
High Resolution Image Download MS PowerPoint Slide Fenton-like radical processes are widely utilized to explain catalytic mechanisms of peroxidase-like nanozymes, which exhibit remarkable catalytic activity, cost-effectiveness, and stability. However, there is still a need for a comprehensive understanding of the formation, stabilization, and transformation of such radicals. Herein, a copper formate-based nanozyme (Cuf-TMB) was fabricated via a pre-catalytic strategy under ambient conditions. The as-prepared nanozyme shows comparable catalytic activity ( K m, 1.02 × 10 –5 mM –1; K cat, 3.09 × 10 –2 s –1 ) and kinetics to those of natural peroxidase toward H 2 O 2 decomposition. This is attributed to the feasible oxidation by *OH species via the *O intermediate, as indicated by density functional theory calculations. The key ·OH radicals were detected to be stable for over 52 days and can be released in a controlled manner during the catalytic process via in situ electron spin-resonance spectroscopy measurements. Based on the understanding, an ultrasensitive biosensing platform was constructed for the sensitive monitoring of biochemical indicators in clinic settings.