Ratiometric electrochemical biosensor based on silver nanoparticles coupled with walker amplification for sensitive detection of microRNA

A novel ratiometric electrochemical biosensor for sensitive detection of microRNA was developed by using walker amplification technique. Ag nanoparticles (NPs) and methylene blue (MB) were used as signal probe and as reference, respectively. Firstly, the present target (miR-155) hybridized with DNA2 to release walker (DNA1), and then the walker hybridized with DNA3 to form activated DNA enzyme, inducing cycling shearing of DNA3 in the presence of Mn2+, thus a large number of product chains (S1) were produced. Then, S1 opened hairpin DNA (HP1) labeled with MB on the electrode, initiating enzyme-assisted cyclic clipping to generate abundant capture DNA. Thus numerous signal probes (DNA HP2-Ag NPs) were linked for electrochemical detection of target. As the electrochemical signal of MB at capture DNA was constant, so it was used as internal reference. Thus the signal ratio of Ag NPs to MB was used for detection, which can greatly reduce the background. The relation between the IAg/IMB and the concentration of target was 10-13-10-6 M, showing wide linear detection range. The biosensor displayed simple design, excellent sensitivity and high specificity for microRNA, showing enormous application prospect in bioanalysis and disease diagnosis fields.

Automated summary

A novel ratiometric electrochemical biosensor was developed for sensitive detection of microRNA using walker amplification technique. The biosensor showed excellent sensitivity and high specificity, with a wide linear detection range of target concentration. The internal reference signal of MB and ratio of Ag NPs to MB greatly reduced background noise, making it a promising tool for bioanalysis and disease diagnosis.