Ratiometric Electrochemical Biosensor for the Sensitive Determination of DNA by a Hairpin DNA Probe

Ratiometric signal detection has been widely used in bioelectrochemical sensors because of the good stability and selectivity. A novel biosensor is reported for nucleic acid detection based on the ratio of the oxidation peak current ratio between ferrocene (Fc) and methylene blue (MB) (I-Fc/I-MB) using a proximity-dependent surface hybridization strategy. The design of hairpin capture was shown to reduce the possibility of the hybridization with the detection probe in the absence of the target which improved the specificity. Moreover, this approach improved the signal stability. Additionally, a linear relationship was observed between the ratio of I-Fc/I-MB and the logarithm of the absolute value of DNA concentration from 1.0 x 10(-12) M to 1.0 x 10(-16) M. This biosensor possessed high sensitivity with a detection limit as low as 0.64 x 10(-16) M. Moreover, good selectivity was obtained for the biosensor by identifying the target of the single-base mismatch. Therefore, this ratiometric electrochemical biosensor has great potential applications for nucleic acid detection and medical clinical diagnosis.

Automated summary

A novel biosensor for nucleic acid detection based on ratiometric signal detection using the oxidation peak current ratio between ferrocene and methylene blue has been developed, showing high stability, good selectivity, and improved specificity. This biosensor demonstrated a linear relationship between the ratio of I-Fc/I-MB and DNA concentration, with a high sensitivity and low detection limit. Additionally, the biosensor exhibited good selectivity by identifying single-base mismatch targets, indicating great potential for applications in nucleic acid detection and medical clinical diagnosis.