Abstract

Electrochemical biosensors have shown promise in bioanalysis and diagnosis. However, they suffer from the accumulation and adhesion of biomolecules in biofluids on sensing surfaces, while the hiring of potential antifouling is limited by the cost and complexity of the construction methods. Here, an economical three-dimensional (3D) conductive antifouling coating was prepared. This coating was composed of bovine serum albumin (BSA) crosslinked glutaraldehyde (GA) and copper-gold nanowires (CuAu NWs) with excellent electrical conductivity. Furthermore, a dual-targeted aptamer (D-Apt), with a “3-in-1″ structure of two specific binding sequences and a DNA linker, was designed to specifically recognize BSA and the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) spike (S) protein, affording low nanomolar binding affinity. Importantly, the introduction of the D-Apt greatly simplified the functionalization procedure on the electrode surface and the immobilization of the biorecognition element. Then, a simple electrochemical biosensor based on the CuAu/BSA/GA and D-Apt was constructed for the detection of S protein. This sensor exhibited merits of cost-effectiveness, sensitivity and practicality for detection of S protein. The work could provide a facile avenue to construct electrochemical biosensors with low-cost antifouling for the accurate diagnosis of epidemic antigenic disease markers.

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