Abstract: The invention provides a system that can process a raw biological sample, perform a biochemical reaction and provide an analysis readout. For example, the system can extract DNA from a swab, amplify STR loci from the DNA, and analyze the amplified loci and STR markers in the sample. The system integrates these functions by using microfluidic components to connect what can be macrofluidic functions. In one embodiment the system includes a sample purification module, a reaction module, a post-reaction clean-up module, a capillary electrophoresis module and a computer. In certain embodiments, the system includes a disposable cartridge for performing analyte capture. The cartridge can comprise a fluidic manifold having macrofluidic chambers mated with microfluidic chips that route the liquids between chambers. The system fits within an enclosure of no more than 10 ft3. and can be a closed, portable, and/or a battery operated system. The system can be used to go from raw sample to analysis in less than 4 hours.

Abstract: The invention provides for devices and methods for interfacing microchips to cartridges and pneumatic manifolds. The cartridges, microchips, and pneumatic manifolds can be integrated with downstream preparation devices, such as thermal regulating devices and separation and analysis devices.

Abstract: The invention provides for devices and methods for interfacing microchips to cartridges and pneumatic manifolds. The cartridges, microchips, and pneumatic manifolds can be integrated with downstream preparation devices, such as thermal regulating devices and separation and analysis devices.

Abstract: The present invention discloses the integration of programmable microfluidic circuits to achieve practical applications to process biochemical and chemical reactions and to integrate these reactions. In some embodiments workflows for biochemical reactions or chemical workflows are combined. Microvalves such as programmable microfluidic circuit with Y valves and flow through valves are disclosed. In some embodiments microvalves of the present invention are used for mixing fluids, which may be part of an integrated process. These processes include mixing samples and moving reactions to an edge or reservoir for modular microfluidics, use of capture regions, and injection into analytical devices on separate devices. In some embodiments star and nested star designs, or bead capture by change of cross sectional area of a channel in a microvalve are used. Movement of samples between temperature zones are further disclosed using fixed temperature and movement of the samples by micropumps.

Abstract: The present invention discloses the integration of programmable microfluidic circuits to achieve practical applications to process biochemical and chemical reactions and to integrate these reactions. In some embodiments workflows for biochemical reactions or chemical workflows are combined. Microvalves such as programmable microfluidic circuit with Y valves and flow through valves are disclosed. In some embodiments microvalves of the present invention are used for mixing fluids, which may be part of an integrated process. These processes include mixing samples and moving reactions to an edge or reservoir for modular microfluidics, use of capture regions, and injection into analytical devices on separate devices. In some embodiments star and nested star designs, or bead capture by change of cross sectional area of a channel in a microvalve are used. Movement of samples between temperature zones are further disclosed using fixed temperature and movement of the samples by micropumps.

Abstract: The invention provides a system that can process a raw biological sample, perform a biochemical reaction and provide an analysis readout. For example, the system can extract DNA from a swab, amplify STR loci from the DNA, and analyze the amplified loci and STR markers in the sample. The system integrates these functions by using microfluidic components to connect what can be macrofluidic functions. In one embodiment the system includes a sample purification module, a reaction module, a post-reaction clean-up module, a capillary electrophoresis module and a computer. In certain embodiments, the system includes a disposable cartridge for performing analyte capture. The cartridge can comprise a fluidic manifold having macrofluidic chambers mated with microfluidic chips that route the liquids between chambers. The system fits within an enclosure of no more than 10 ft3. and can be a closed, portable, and/or a battery operated system. The system can be used to go from raw sample to analysis in less than 4 hours.

Abstract: This invention provides microfluidic devices that comprise a fluidics layer having microfluidic channels and one or more regulating layers that regulate the movement of fluid in the channels. The microfluidic devices can be used to mix one or more fluids. At least a portion of the fluidics layer can be isolated from the regulating layer, for example in the form of a shelf. Such isolated portions can be used as areas in which the temperature of liquids is controlled. Also provided are instruments including thermal control devices into which the microfluidic device is engaged so that the thermal control device controls temperature in the isolated portion, and a movable magnetic assembly including magnets with shields so that a focused magnetic field can be applied to or withdrawn from the isolated portion or any other portion of the microfluidic device. Also provided are methods of mixing fluids.

Abstract: The present invention discloses a high-density parallel channel design for a microfabricated capillary array electrophoresis chip, with vertical T or double T design for sample injection. An alternative embodiment of the invention includes a closed buffer reservoirs with integrated electrodes and buffer feeding ports. Also disclosed are novel sample loading and injection methods, including the use of using either a capillary array connected to an electrode, or an array of metal pens as the loader/electrode.

Abstract: The invention provides for devices and methods for interfacing microchips to cartridges and pneumatic manifolds. The cartridges, microchips, and pneumatic manifolds can be integrated with downstream preparation devices, such as thermal regulating devices and separation and analysis devices.

Abstract: The present invention discloses a high-density parallel channel design for a microfabricated capillary array electrophoresis chip, with vertical T or double T design for sample injection. An alternative embodiment of the invention includes a closed buffer reservoirs with integrated electrodes and buffer feeding ports. Also disclosed are novel sample loading and injection methods, including the use of using either a capillary array connected to an electrode, or an array of metal pens as the loader/electrode.

Abstract: A mold for use in die casting aluminum parts is made from an underaged Ni—Be alloy containing about 1.0 to 2.0 wt. % Be.

Abstract: An unwrought continuous cast Cu—Ni—Sn spinodal alloy and a method for producing the same is disclosed. The Cu—Ni—Sn spinodal alloy is characterized by an absence of discontinuous &ggr;′ phase precipitate at the grain boundaries, ductile fracture behavior during tensile testing, high strength, excellent wear and corrosion resistance, superior bearing properties, and contains from about 8-16 wt. % nickel, from about 5-8 wt. % tin, and a remainder copper.

Abstract: A shot block for use in a die casting machine for die casting molten and semi-molten metal parts is formed from a metal or metal alloy having a thermal conductivity of at least about 25 Btu/ft.hr.° F., a Rockwell C hardness of at least about 25 and a 0.2% Yield Strength of at least about 90 ksi.

Abstract: A mold for use in die casting aluminum parts is made from an underaged Ni—Be alloy containing about 1.0 to 2.0 wt. % Be.

Abstract: A shot block for use in a die casting machine for die casting molten and semi-molten metal parts is formed from a metal or metal alloy having a thermal conductivity of at least about 25 Btu/ft.hr.° F., a Rockwell C hardness of at least about 25 and a 0.2% Yield Strength of at least about 90 ksi.

Abstract: A fluid powered drilling motor adapted for drilling oil wells and other subterranean bore holes. The motor having a rotor and a stator wherein the iron content of the whole motor is less than 0.1% wt. In one embodiment the motor is made of an alloy having a base metal comprising one of copper, nickel, and aluminum plus about 0.05-10 wt % Beryllium. In another embodiment, the motor is made of either 15Ni-8SN—Cu or 9Ni-6Sn—Cu.

Abstract: An improved mud motor for drilling bore holes in subterranean formations is formed from a non-magnetic alloy containing no more than 0.1 wt. % iron.

Abstract: An improved thin walled threaded spacer for use in preventing thread galling in adjacent sections of drill pipe in a drill string is formed by mechanically deforming a strip of copper/beryllium alloy containing 2% beryllium to form a preform having a hollow, truncated conical section and then mechanically deforming the conical section to impart helical grooves therein.

Abstract: An unwrought continuous cast Cu—Ni—Sn spinodal alloy and a method for producing the same is disclosed. The Cu—Ni—Sn spinodal alloy is characterized by an absence of discontinuous &ggr;′ phase precipitate at the grain boundaries, ductile fracture behavior during tensile testing, high strength, excellent wear and corrosion resistance, superior bearing properties, and contains from about 8-16 wt. % nickel, from about 5-8 wt. % tin, and a remainder copper.

Abstract: Method and apparatus used for continuous casting of copper alloy rods and tubes for obtaining a fine grain size therein. Liquidus copper alloy material flows from a reservoir area or crucible into a continuous casting die through spaced apart feed slots disposed in the casting die cap, thereby effecting agitation of the liquidus material, which prevents the formation of thermal gradients large enough to produce gross directional solidification of the alloy at the liquid-solid state transition zone. The desired agitation is effected by altering the number, location, size and angle of the feed slots in accordance with formulas provided for that purpose.