Abstract: A point of care testing assay system for determining the presence and/or amount of an analyte of interest in a sample, and methods for using such assay system, are disclosed. The system comprises a microfiuidic means capable of performing testing with low sample volume in a sample matrix, and having high sensitivity and substantially a 5-log wide dynamic range and capable of performing an assay in approximately fifteen minutes, and in which the microfiuidic means comprises a microfiuidic testing cartridge with associated electronics, a precision pipettor, a high sensitivity detection module, a motion stage, and an on-board electronics display means that can be read by a user as an indication of the presence and/or amount of the analyte in the sample.

Abstract: This invention discloses novel improvements to conventional microtiter plates, involving integrating microfluidic channels with such microtiter plates to simplify the assay operation, Increase operational speed and reduce reagent consumption. The present invention can be used in place of a conventional microliter plate and can be easily substituted without any changes to the existing instrumentation systems designed for microtiter plates. The invention also discloses a microfluidic device integrated with sample loading wells wherein the entire flow process is capillary driven.

Abstract: A point of care testing assay system for determining the presence and/or amount of an analyte of interest in a sample, and methods for using such assay system, are disclosed. The system comprises a microfluidic means capable of performing testing with low sample volume in a sample matrix, and having high sensitivity and substantially a 5-log wide dynamic range and capable of performing an assay in approximately fifteen minutes, and in which the microfluidic means comprises a microfluidic testing cartridge with associated electronics, a precision pipettor, a high sensitivity detection module, a motion stage, and an on-board electronics display means that can be read by a user as an indication of the presence and/or amount of the analyte in the sample.

Abstract: This invention discloses novel improvements to conventional microtiter plates, involving integrating microfluidic channels with such microtiter plates to simplify the assay operation, Increase operational speed and reduce reagent consumption. The present invention can be used in place of a conventional microliter plate and can be easily substituted without any changes to the existing instrumentation systems designed for microtiter plates. The invention also discloses a microfluidic device integrated with sample loading wells wherein the entire flow process is capillary driven.

Abstract: A method for biosensing that includes passing, via convective flow, a sample believed to contain one or more target biomarkers through a microfluidic channel and over the surface of an optical waveguide that has been prepared to bind the one or more target biomarkers, and sensing for an emission output from the optical waveguide at a wavelength that is characteristic of the binding of the target biomarker. A biosensor device that includes a module defining at least one microfluidic channel, an optical waveguide exposed along at least a portion of its length to fluid flow within the microfluidic channel, where a surface of the optical waveguide being prepared to bind a target biomarker, and an excitation source to couple an excitation wavelength of light into the optical waveguide. The device also includes a sensor for detecting emission light from the optical waveguide at an emission wavelength characteristic of binding of the target biomarker.

Abstract: A novel CEC column preparation method for various forms of CEC separation using selectively or fully packed microchannels with self-assembled silica colloidal particles is disclosed. The method relies on the three dimensional uniform silica colloidal packing through selective regions or whole channels resulting in uniform EOF and reproducibility. The fully packed capillary electrophoretic separation microchip is inherently suited for a handheld system since it exploits uniquely fully packed separation channels to achieve better separation efficiency and stability. The fully packed capillary electrophoretic separation microchip can be easily fabricated using low-cost, rapid manufacturing techniques, and can provide high performance for CEC separation with various chromatographic stationary support packing, functionalized surface of packed beads. The fully packed microchannels with self-assembled silica colloidal particles can be applied for preparation of a built-in submicron filter.

Abstract: A functional on-chip pressure source using a solid propellant chemical material is disclosed which, upon heating to a critical temperature, liberates a precise amount of gas which, when liberated within an enclosed cavity coupled to a liquid in a microfluidic channel, raises the pressure and causes precise displacement of the liquid. The functional on-chip pressure source may be easily integrated with a disposable biochip, may be fabricated using low-cost, high volume manufacturing techniques, uses very low power, and may provide a dynamically variable output pressure across a broad spectrum of pressures. Embodiments of the present invention address significant challenges in the development of disposable microfluidic biochips including providing a reliable solution for pumping liquids in a microfluidic system and immediately applying the solution to a variety of microfluidic biochip applications.

Abstract: A catheter for insertion into a body cavity, duct, or vessel for diagnostic purposes, the catheter including a flexible conduit having a microsensor device mounted thereto that generates output data from a sensed condition. The microsensor device is operatively coupled to a data acquisition device to communicate the output data to the data acquisition device. The microsensor device is mounted to a flexible dielectric substrate carrying a lead, and the flexible dielectric substrate is separate from and carried by the flexible conduit.

Abstract: Disclosed herein is a fully-integrated, disposable biochip for point-of-care testing of clinically relevant parameters. Specifically, in accordance with an embodiment of the present invention, the biochip is designed for POCT (point-of-care-testing) of an array of metabolic parameters including partial pressure of oxygen, Glucose, and Lactate concentration from venous blood samples. The biochip is fabricated on a low-cost plastic substrate using mass manufacturing compatible fabrication processes. Furthermore, the biochip contains a fully-integrated metallic micro-needle for blood sampling. The biochip also uses smart passive microfluidics in conjunction with low-power functional on-chip pressure generators for microfluidic sequencing. The design, configuration, assembly and operation of the biochip are ideally suited for a disposable biochip specifically targeted towards POCT applications.

Abstract: Techniques for the fabrication of fully-integrated lab-on-a-chips (or biochips) specifically oriented towards point-of-care detection of biomolecules using immunoassay based detection techniques are disclosed. A primary task for the development of such biochips is the development of techniques to precisely deposit and localize the capture antibody on pre-determined locations over the biochip. The use of selective surface modification, specifically control over the surface energy, to achieve localized adsorption of the capture antibody is disclosed. Another approach, also disclosed, describes the use of smart passive microfluidics to confine the flow of the capture antibody along certain paths of the biochip and thereby control the locations over which the capture antibody is adsorbed. Furthermore, the use of an integrated microlens array as means of enhancing the detection sensitivity of the biochip is also disclosed.

Abstract: Various techniques for the fabrication of highly accurate master molds with precisely defined microstructures for use in plastic replication using injection molding, hot embossing, or casting techniques are disclosed herein. Three different fabrication processes used for master mold fabrication are disclosed wherein one of the processes is a combination of the other two processes. In an embodiment of the first process, a two-step electroplating approach is used wherein one of the metals forms the microstructures and the second metal is used as a sacrificial support layer. Following electroplating, the exact height of the microstructures is defined using a chemical mechanical polishing process. In an embodiment of the second process, a modified electroforming process is used for master mold fabrication.

Abstract: A novel filter-less separation technique for separating suspended particles from a solution is disclosed. More specifically, an on-chip bioparticle separator is disclosed, which relies on the differential force exerted by application of a series of high magnitude, short duration pressure pulses on bioparticles in suspension within microchannels, resulting in separation of suspended bioparticles. The filter-less separation technique is inherently suited to ?TAS (Micro Total Analysis System) since it exploits uniquely microscale phenomena to achieve separation. The on-chip bioparticle separator can be easily integrated with a disposable biochip, can be fabricated using low-cost, rapid manufacturing techniques, and can provide high performance for separation of bioparticles without the use of specialized or expensive equipment.