Electrochemical biomimetic enzyme cascade amplification combined with target-induced DNA walker for detection of thrombin

Fe-N-doped carbon nanomaterials (Fe-N/CMs) were designed as a novel biomimetic enzyme with excellent peroxidase-like activity to achieve high-efficient enzyme cascade catalytic amplification with the aid of glucose oxidase (GOx), which was further combined with target-induced DNA walker amplification to develop a sensitive electrochemical biosensor for thrombin detection. Impressively, massive output DNA was transformed from small amounts of target thrombin by highly effective DNA walker amplification as protein-converting strategy, which could then induce the immobilization of functionalized nanozyme on the electrode surface to achieve the high-efficient electrochemical biomimetic enzyme cascade amplification. As a result, an amplified enzyme cascade catalytic signal was measured for thrombin detection ranging from 0.01 pM to 1 nM with a low detection limit of 3 fM. Importantly, the new biomimetic enzyme cascade reaction coupled the advantages of natural enzyme and nanozyme, which paved an avenue to construct varied artificial multienzymes amplification systems for biosensing, bioanalysis, and disease diagnosis applications.

Automated summary

Fe-N-doped carbon nanomaterials were designed as a novel biomimetic enzyme with peroxidase-like activity, combined with glucose oxidase for enzyme cascade catalytic amplification, and further combined with target-induced DNA walker amplification to develop a sensitive electrochemical biosensor for thrombin detection. The biomimetic enzyme cascade reaction coupled the advantages of natural enzyme and nanozyme, providing a new approach for constructing artificial multienzyme amplification systems in biosensing, bioanalysis, and disease diagnosis applications.