This is a demo store. No orders will be fulfilled.
DNA walker induced “signal off” electrochemical cytosensor strategy for ultrasensitive detection of tumor cells
The fragments of molecular motors can be transported and operated autonomously along a track. Most molecular walker systems are assembled from DNA building modules, exhibiting great potential applications in biocomputing, drug transport, sensing, etc. Hereby, we report a DNA walker driven by endonuclease Nt.BbvC I that can autonomously induce “signal off” sensing platform for highly sensitive detection of tumor cells. DNA density and trajectory conformation can affect DNA walker properties. Molybdenum selenide@gold nanoparticles (MoSe 2 @AuNPs) are modified on the electrode surface as a scaffold to accommodate more hairpin probe (H1) and provide a good interface for DNA walking. Magnetic beads are used to enrich target tumor cells, release single-stranded DNA (S1) and trigger DNA walker-based amplification strategy. Upon addition of tumor cells, more DNA-methylene blue (DNA-MB) is cracked from the electrode surface. Benefiting from efficient electrode modification, magnetic enrichment, DNA walker and enzyme-assisted amplification, an ultra-high sensitivity electrochemical cell analysis is realized, with a detection limit of 2 cells mL −1 . More importantly, this DNA walker strategy is available for tumor cell analysis in clinical samples, suggesting the potential diagnostic applications.