Abstract: The present invention provides a droplet-based microfluidic device comprising a passivating top surface and methods for producing and using the same. In particular, the passivating surface comprises of a nano-textured superhydrophobic material.

Abstract: A real-time digital cytometer on a chip system utilizing a custom near field CMOS active pixel intelligent sensor that is flip-chip attached to a fluidic microchannel etched in a thin glass substrate. The CMOS active pixel sensor, fabricated using a 0.18 micron process, is a mixed signal chip comprising a sixteen pixel linear adaptive spatial filter coupled to a digital serial interface. This near field hybrid digital sensor topology obviates the need for both high resolution analog to digital conversion as well as conventional microscopy for the realization of real time optical cytometry. The custom sensor based design approach affords efficient scaling into a tiled multi-channel sensing configuration.

Abstract: The invention integrates a two-stage dielectrophoretic (DEP) droplet dispensing and distribution system with particulate DEP to create a novel LOC platform capable of manipulating biological cells based on the varied dielectrophoretic signatures that distinguish cells in a population, for example, healthy from diseased cells. The two-stage DEP droplet transport system acts as the backbone of this application, providing the essential dispensing and distribution function, while particulate DEP provides the critical capability to characterize and analyze the heterogeneous biological cell populations routinely encountered in biotechnology and clinical settings.

Abstract: A swallowable electronic bolus or “pill” that can monitor any one or more of the following parameters in real time as the bolus moves through the esophagus: (i) acceleration of the bolus; (ii) velocity of the bolus; (iii) position of the bolus; and (iv) contractile force on the bolus that pushes it through the gastrointestinal tract.

Abstract: Disclosed is an esophageal catheter that is capable of simultaneously measuring impedance, hydrostatic pressure and contact pressure in an esophagus from peristaltic waves, esophageal fluid and the transit bolus in a single test episode. Circumferential impedance sensors include sensing electrodes that are oppositely disposed on the circumferential impedance sensor, and reference electrodes that are also oppositely disposed on the circumferential impedance sensor and interspersed between the sensing electrodes. Accurate impedance measurements can be made in this fashion in a transverse direction in the esophagus. A hydrostatic pressure sensor is disposed at the distal tip of the esophageal probe that has a rigid cover to protect the hydrostatic pressure sensor from contact pressures of the esophagus. In this manner, the hydrostatic pressure sensor can provide purely hydrostatic pressure data from the fluids in the esophagus.

Abstract: The design, development and fabrication of a DEP microfluidic assembly with an in-built interdigitated microelectrode array is presented. Continuous fractionation of microparticles in a PDMS microfluidic channel is described. Experimental verification of positive and negative DEP of yeast cells and polystyrene latex beads is demonstrated. A microfluidic device with DEP arranged electrodes in a channel has posts extending into the channel for controlling shaping of DEP fields.

Abstract: The lack of safe, reliable, automated and clinically acceptable blood sampling has been the main problem precluding the development of real-time systems for blood analysis and subsequent closed-loop physiological function control. While the analysis of a static blood sample in laboratory conditions has been rapidly advancing in reliability and blood volume reduction, non-invasive real-time blood analysis performed in vivo (while the blood is circulating in the body) has been elusive and unreliable. In this study we propose an innovative idea for semi-invasive blood sampling and analysis, which resembles the operation of a mosquito.