Click-response-driven high-speed and ultrasensitive electrochemical sensing interface: Addressing its accuracy challenge

Abstract

For electrochemical sensors, maintaining accuracy while achieving sensitive detection is of paramount importance. The fixation of the signal substance as one of the main steps in the construction process of a sensor has a significant impact on the accuracy. Currently, physical and chemical methods are the primary approaches for the fixation of the signal substance, which have the following issues. The accuracy of a sensor may be affected by the instability resulting from the physical immobilization of the signal substance and the chemical immobilization process is typically time-consuming. To overcome these obstacles, the ultra-sensitive electrochemical sensing interface is constructed by click reaction to achieve accurate and rapid detection of tumor biomarkers. After the formation of immune-sandwich structure in a test tube, a large amount of ethynylferrocene (EFc) molecules in the Zeolitic imidazolate frameworks (ZIF-8) immunoprobe are released under acidic conditions, followed by covalently linking to the substrate within 6 minutes through a click reaction. Under optimal conditions, the electrochemical sensor had an ultralow detection limit of 32.90 fg mL−1 for the model analyte (CEA) with a wide detection range from 100 fg mL−1 to 100 ng mL−1. This work provides a new perspective for designing electrochemical sensors with excellent performance.