Point-of-care testing (POCT) devices show great advantages over conventional diagnostic tests in being accessible to patients and providing timely diagnostic information. The global POCT market has grown remarkably over the past few decades. Distance-based devices are attracting great interest due to their simplicity, affordability, and ease of application.
Researchers at the Suzhou Institute of Biomedical Engineering and Technology (SIBET) of the Chinese Academy of Sciences have proposed a distance-based visual miRNA biosensor based on a DNA hydrogel system. The results of the study, titled "Distance-Based Visual miRNA Biosensor with Strand Displacement Amplification-Mediated DNA Hydrogel Assembly," were published in ACS Materials Letters.
The target miRNA-initiated strand displacement amplification process will produce abundant single-stranded DNA, which are essential probes for the linking of the three-way junction scaffold of the hydrogel.
The phase transition of the solution is confirmed by elastic and electrochemical techniques. A distance-based paper biosensing method is thus set up by establishing the relationship between the seepage flow distance along the strip and the initial miRNA concentration.
Due to the strand displacement amplification, the biosensor is not only simple but also highly sensitive with a detection limit down to 1 fM.
Since the three-dimensional DNA hydrogel provides abundant binding sites, the detection range is quite wide, according to the researchers.
The biosensor is shown to be highly selective, and the results of human serum analysis are consistent with standard quantitative reverse transcription-PCR.
"This approach has the advantages of convenient operation and low cost, which meets the requirements of point-of-care testing," said Miao Peng, lead author of the study. "It is promising as a convenient tool for miRNA-related biological studies and clinical diagnosis."
More information: Chengyu Yan et al, Distance-Based Visual miRNA Biosensor with Strand Displacement Amplification-Mediated DNA Hydrogel Assembly, ACS Materials Letters (2024). DOI: 10.1021/acsmaterialslett.4c00650
Provided by Chinese Academy of Sciences