Photoelectrochemical and visual dual-mode sensor for efficient detection of Cry1Ab protein based on the proximity hybridization driven specific desorption of multifunctional probe

Currently, the development of sensitive and visual strategy for Cry1Ab detection, particularly using a switchable dual-mode detection system based on a single component, remains a great challenge. Here, a photo -electrochemical (PEC) and visual dual-mode sensor was designed for Cry1Ab detection based on a proximity hybridization driven multifunctional probe. In the presence of Cry1Ab, specific desorption of the antibody-DNA conjugate was achieved via sufficient proximity hybridization, leading to the selective release of the multi-functional signal probe, i.e., antibody-labeled single-stranded DNA-gold nanoparticles (Ab(1)-S1-AuNPs). The released Ab(1)-S1-AuNPs reduced the photocurrent signal and produced a colored response, thereby achieving PEC and visual dual-mode detection based on a single component. Owing to the different signal generation mechanisms, two independent signals were obtained simultaneously, which provided self-verification to improve reliability and accuracy. Taking advantage of the PEC sensitive detection and visual prediction, the dual-mode sensor achieved efficient detection of the Cry1Ab protein. The developed sensor was successfully used to determine Cry1Ab in corn, wheat, and soil samples with satisfactory results. This method offers a promising biosensing platform for the on-site detection of Cry1Ab protein.

Automated summary

In this study, a photo-electrochemical and visual dual-mode sensor based on a proximity hybridization driven multifunctional probe was designed for Cry1Ab protein detection. The sensor achieved efficient detection by generating two independent signals simultaneously, providing improved reliability and accuracy. The combination of PEC and visual detection offered a promising approach for on-site detection of Cry1Ab protein.