AI Article Synopsis
- - The study investigates a method for detecting trace levels of miRNA21 using a rolling circle amplification (RCA)-based DNA nanoscaffold combined with RNA-cleaving DNAzyme, aiming to improve molecular diagnosis for diseases.
- - The hybridization chain reaction (HCR) on the DNA nanoscaffold, triggered by the target miRNA21, efficiently restores fluorescence signals, allowing detection at levels as low as 0.76 pM while maintaining specificity and accuracy.
- - This approach demonstrates the versatility of the DNA nanoscaffold and DNAzyme as a robust platform for sensitive nucleic acid detection, which can be adapted for other miRNAs with minor modifications.
Article Abstract
Cascaded amplification showed promising potential for detection of trace target miRNAs in molecular diagnosis and prevention of many diseases. In this study, miRNA21 was chosen as the target, and rolling circle amplification (RCA)-based DNA nanoscaffold was integrated with target triggered RNA-cleaving DNAzyme for sensitive detection of miRNA21. That is, the H1 probe was bound with the long-chain product of RCA to self-assemble into DNA nanoscaffold. Target miRNA21 triggered the hybridization chain reaction (HCR) located on the nanoscaffold, and led to rapid proximity of DNAzyme fragments modified at both ends of the H2 probe, which realized the cyclic cleavage of self-quenching substrate probe efficiently, and the fluorescence signal was restored. The results demonstrated that the proposed assay was sensitive, 0.76 pM of miRNA21 can be detected. The proposed assay was specific; only one-base mismatched miRNA21 can be effectively recognized, other nucleic acid sequence and the serum matrix did not cause any interference. The proposed assay was accurate; recoveries from 82.1 to 115.0% can be obtained in the spiked fetal bovine serum (FBS). The flexible and programmable characteristics of DNA nanoscaffold and DNAzyme provide a confident and robust strategy for more sensitive nucleic acid detection, and can be developed to be a universal sensing platform for detecting other miRNAs just needing modification on the corresponding sequence of H1 probe in HCR.
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Article Synopsis
- - The study investigates a method for detecting trace levels of miRNA21 using a rolling circle amplification (RCA)-based DNA nanoscaffold combined with RNA-cleaving DNAzyme, aiming to improve molecular diagnosis for diseases.
- - The hybridization chain reaction (HCR) on the DNA nanoscaffold, triggered by the target miRNA21, efficiently restores fluorescence signals, allowing detection at levels as low as 0.76 pM while maintaining specificity and accuracy.
- - This approach demonstrates the versatility of the DNA nanoscaffold and DNAzyme as a robust platform for sensitive nucleic acid detection, which can be adapted for other miRNAs with minor modifications.
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