Abstract: Nanofluidic flow cells and systems for single-molecule nanoconfinement and imaging of molecules in a fluid are described. The nanofluidic flow cell comprises a bottom substrate bonded to a top substrate, microchannels and a central chamber carved in the bottom or top substrate. The microchannels and the central chamber define an empty space into which a fluid can flow. The microchannels extend on opposite side of the central chamber, each microchannel comprising a central portion crossing the central chamber and a pair of arms extending outside the central chamber, these arms comprising a fluid port positioned at opposite ends of the microchannel and outside the central chamber. The central chamber comprises a nanoconfinement and imaging area including carved nanostructures configured for single-molecule nanoconfinement. Also described are nanofluidic chips, methods of confinement, pneumatic-based nanofluidic systems and manifold assembly for the nanofluidic flow cell.

Abstract: Nanofluidic flow cells and systems for single-molecule nanoconfinement and imaging of molecules in a fluid are described. The nanofluidic flow cell comprises a bottom substrate bonded to a top substrate, microchannels and a central chamber carved in the bottom or top substrate. The microchannels and the central chamber define an empty space into which a fluid can flow. The microchannels extend on opposite side of the central chamber, each microchannel comprising a central portion crossing the central chamber and a pair of arms extending outside the central chamber, these arms comprising a fluid port positioned at opposite ends of the microchannel and outside the central chamber. The central chamber comprises a nanoconfinement and imaging area including carved nanostructures configured for single-molecule nanoconfinement. Also described are nanofluidic chips, methods of confinement, pneumatic-based nanofluidic systems and manifold assembly for the nanofluidic flow cell.

Abstract: Provided herein are devices for manipulating and visualizing molecular interactions in customized nanoscale spaces.

Abstract: A curved surface is placed tangent to a slide and displaces a sample liquid from the point or line of contact outward. Imaging indicates a region where fluorescence is observed, and the location of the fluorescence indicates the molecular size. The radius of curvature of the lens is known, the distance from the (center) point of contact of the observed fluorescence is measured with a microscope and the distance of the lens surface to the slide's surface can then be calculated. This distance represents the size of the molecule or ensemble of molecules emitting. Similarly, absorbance, etc. could be measured with a light source below the slide.

Abstract: A curved surface is placed tangent to a slide and displaces a sample liquid from the point or line of contact outward. Imaging indicates a region where fluorescence is observed, and the location of the fluorescence indicates the molecular size, The radius of curvature of the lens is known, the distance from the (center) point of contact of the observed fluorescence is measured with a microscope and the distance of the lens surface to the slide's surface can then be calculated. This distance represents the size of the molecule or ensemble of molecules emitting. Similarly, absorbance, etc. could be measured with a light source below the slide.

Abstract: A curved surface is placed tangent to a slide and displaces a sample liquid from the point or line of contact outward. Imaging indicates a region where fluorescence is observed, and the location of the fluorescence indicates the molecular size. The radius of curvature of the lens is known, the distance from the (center) point of contact of the observed fluorescence is measured with a microscope and the distance of the lens surface to the slide's surface can then be calculated. This distance represents the size of the molecule or ensemble of molecules emitting. Similarly, absorbance, etc. could be measured with a light source below the slide.