Abstract: Systems and methods of using the same for functional fluorescence imaging of live cells in suspension with isotropic three dimensional (3D) diffraction-limited spatial resolution are disclosed. The method-live cell computed tomography (LCCT)-involves the acquisition of a series of two dimensional (2D) pseudo-projection images from different perspectives of the cell that rotates around an axis that is perpendicular to the optical axis of the imaging system. The volumetric image of the cell is then tomographically reconstructed.

Abstract: Systems and methods of using the same for functional fluorescence imaging of live cells in suspension with isotropic three dimensional (3D) diffraction-limited spatial resolution are disclosed. The method-live cell computed tomography (LCCT)-in-volves the acquisition of a series of two dimensional (2D) pseudo-projection images from different perspectives of the cell that rotates around an axis that is perpendicular to the optical axis of the imaging system. The volumetric image of the cell is then tomographically reconstructed.

Abstract: Systems and methods of using the same for functional fluorescence imaging of live cells in suspension with isotropic three dimensional (3D) diffraction-limited spatial resolution are disclosed. The method-live cell computed tomography (LCCT)-in-volves the acquisition of a series of two dimensional (2D) pseudo-projection images from different perspectives of the cell that rotates around an axis that is perpendicular to the optical axis of the imaging system. The volumetric image of the cell is then tomographically reconstructed.

Abstract: Systems and methods of using the same for functional fluorescence imaging of live cells in suspension with isotropic three dimensional (3D) diffraction-limited spatial resolution are disclosed. The method-live cell computed tomography (LCCT)-involves the acquisition of a series of two dimensional (2D) pseudo-projection images from different perspectives of the cell that rotates around an axis that is perpendicular to the optical axis of the imaging system. The volumetric image of the cell is then tomographically reconstructed.

Abstract: A microfluidic device useable for performing live cell computed tomography imaging is fabricated with a cover portion including a first wafer with at least one metal patterned thereon, a base portion including a second wafer with at least one metal patterned thereon and negative photoresist defining recesses therein, and a diffusive bonding layer including a negative photoresist arranged to join the cover portion and the base portion. A composition useful in live cell computer topography includes a long-chain polysaccharide at a concentration of from about 0.01% to about 10.0% in cell culture medium for supporting cell life while enabling cell rotation rate to be slowed to a speed commensurate with low light level imaging.

Abstract: Microfluidic devices for 3D hydrodynamic microvortical rotation of at least one live single cell or cell cluster, systems incorporating the devices, and methods of fabricating and using the devices and systems, are provided. A microfluidic chip rotates at least one live single cell or cell cluster in a microvortex about a stable rotation axis perpendicular to an optical axis within a chamber having a trapezoidal cross-sectional shape located below a flow channel. An optical trap may be used to position the cell or cells with the microvortex, and the cell or cells may be subject to live-cell or cell cluster computer tomography imaging.

Abstract: Microfluidic devices for 3D hydrodynamic microvortical rotation of at least one live single cell or cell cluster, systems incorporating the devices, and methods of fabricating and using the devices and systems, are provided. A microfluidic chip rotates at least one live single cell or cell cluster in a microvortex about a stable rotation axis perpendicular to an optical axis within a chamber having a trapezoidal cross-sectional shape located below a flow channel. An optical trap may be used to position the cell or cells with the microvortex, and the cell or cells may be subject to live-cell or cell cluster computer tomography imaging.

Abstract: A microfluidic device useable for performing live cell computed tomography imaging is fabricated with a cover portion including a first wafer with at least one metal patterned thereon, a base portion including a second wafer with at least one metal patterned thereon and negative photoresist defining recesses therein, and a diffusive bonding layer including a negative photoresist arranged to join the cover portion and the base portion. A composition useful in live cell computer topography includes a long-chain polysaccharide at a concentration of from about 0.01% to about 10.0% in cell culture medium for supporting cell life while enabling cell rotation rate to be slowed to a speed commensurate with low light level imaging.

Abstract: Microplate assemblies and methods for using same are provided. In accordance with some embodiments, microplate assemblies are provided, the assemblies comprising a microplate well portion that forms a microplate well and that includes at least one sensor in the microplate well that responds to analyte in the well. In accordance with some embodiments, methods for determining a cell consumption rate of an analyte are provided, the methods comprising: positioning a cell in a microplate well having at least one sensor located within the well; providing analyte to the microplate well at a controlled rate; detecting a response of the sensor to the analyte in the microplate well; and determining a cell consumption rate of the analyte based on the response of the sensor to the analyte.