"DE - Spolkov\u00E1 republika N\u011Bmecko" . "1616-301X" . "1" . "8"^^ . . "Loh, K. P." . . . "[7F6AB4E6F1CD]" . . "344740" . . . . . . "Advanced Functional Materials" . . "Van Hove, E." . . "Supported lipid bilayer on nanocrystalline diamond: dual optical and field-effect sensor for membrane disruption" . "RIV/68378271:_____/09:00328844!RIV10-AV0-68378271" . . "19" . . "Supported lipid bilayer on nanocrystalline diamond: dual optical and field-effect sensor for membrane disruption" . "Nesl\u00E1dek, Milo\u0161" . "1"^^ . "RIV/68378271:_____/09:00328844" . . "Z(AV0Z10100520)" . . "It is demonstrated that a good biomimetic model lipid membrane with dynamic fluidity can be established on optically transparent nanocrystalline diamond (OTND) with surface roughness below 10nm. Maigainin II, an antimicrobial peptide, is chosen to investigate the permeation of artificial bacterial membranes constructed on OTND. Due to the unique combination of optical transparency and highly sensitive surface conducting channel, intrinsic OTND affords the possibility of dual-mode sensing based on optical and field effect properties. This opens up new possibilities for making integrated biomolecule\u2013semiconductor microdevices, or sensors where the binding of biomolecules can be tracked using confocal microscopy whilst the associated changes in charge density during membrane perforation can be tracked using the space charge effect in the semiconductor." . "nanocrystalline diamond; biocompatibility; supported lipid bilayers; biosensors; solution gate field effect transistor"@en . "Ang, P. K." . "5"^^ . . "Supported lipid bilayer on nanocrystalline diamond: dual optical and field-effect sensor for membrane disruption"@en . "Wohland, T." . . "000262584800010" . "It is demonstrated that a good biomimetic model lipid membrane with dynamic fluidity can be established on optically transparent nanocrystalline diamond (OTND) with surface roughness below 10nm. Maigainin II, an antimicrobial peptide, is chosen to investigate the permeation of artificial bacterial membranes constructed on OTND. Due to the unique combination of optical transparency and highly sensitive surface conducting channel, intrinsic OTND affords the possibility of dual-mode sensing based on optical and field effect properties. This opens up new possibilities for making integrated biomolecule\u2013semiconductor microdevices, or sensors where the binding of biomolecules can be tracked using confocal microscopy whilst the associated changes in charge density during membrane perforation can be tracked using the space charge effect in the semiconductor."@en . "Supported lipid bilayer on nanocrystalline diamond: dual optical and field-effect sensor for membrane disruption"@en .