1.Laboratory of Biomedical Engineering,Chongqing Medical University,Chongqing,China
Abstract:
The authors have investigated (a) the self-assembly of single-stranded DNA (ssDNA) on glass surfaces, and (b) the interaction of DNA with liquid crystals (LCs) on solid surfaces. The results suggest that ssDNA (compared to dsDNA) on the solid interface causes particularly different orientations in LCs. The LC molecules assume a uniform homeotropic orientation on the surface with a typical surface ssDNA coverage of ~2.4 × 1012 molecules per square cm. Once complementary DNA is hybridized on the surface, the homotropic orientation of the LCs becomes disrupted. This orientation transition can be visually observed by using a crossed polarizer. The findings were exploiting to design an assay for target DNA (= analyte DNA) that has an ~0.1 nM detection limit. The assay is highly selective and can easily differentiate target DNA from single-base mismatch and non-complementary DNA. In our perception, it represents a powerful, label-free and portable DNA detection scheme.
Graphical abstract Schematic illustration of the mechanism for orientation behavior of a liquid crystal film supported on different surfaces. The homeotropic orientation of LC molecules was induced by ssDNA with appropriate surface coverage and was disrupted by ssDNA with lower or higher surface coverage or P1/T1 complex. 5CB: 4-Cyano-4′-pentylbiphenyl. TEA: Triethoxysilylbutyraldehyde.
