Specific and robust hybridization based on double-stranded nucleic acids with single-base resolution.

Nucleic acid hybridization plays a critical role in medical diagnostics and nanotechnology, but its selectivity and robustness remain to be improved. Here, focusing on double-stranded nucleic acid-based hybridization, we present a series of related strategies. Above all, two simple strategies for enriching toehold-included double-stranded nucleic acids have been proposed. On this basis, two universal hybridization methods with higher selectivity than typical toehold exchange reaction and a long target detection method using short probes to extend the detectable length range are realized. We also provide a double-stranded nucleic acids-catalyzed cycle amplification reaction to improve sensitivity, which has superior interference resistance and excellent discrimination for single-base mismatches. Besides, double-stranded nucleic acids with forked toeholds are used as essential elements to construct a series of logic gates that can evaluate different input combinations. Given the unique advantages of double-stranded nucleic acids, we expect the current work to advance the application of double-stranded nucleic acid-based hybridization in medical diagnostics and nanotechnology. [Display omitted] • Two methods for enriching double-stranded nucleic acids that possess toeholds. • Two universal hybridization methods and a long targets detection method were provided. • A double-stranded nucleic acids-catalyzed cycle amplification reaction for improving sensitivity. • Double-stranded nucleic acids for robust logic computation. [ABSTRACT FROM AUTHOR]