Abstract: Methods of performing fast polymerase mediated reactions are provided. These reactions can be used in an inefficient fashion in the cycles of the polymerase mediated reactions to produce product at a much faster rate than conventional polymerase mediated reaction methods. Integrated systems for performing these methods are also provided.

Abstract: A method is provided for identifying components of a mixture by labeling the individual components with fluorescent agents having different fluorescence lifetimes. The components are subsequently separated, fluorescent labels detected and their lifetimes measured. Based on the measured fluorescent lifetimes, the components of mixtures of small organic molecules, polymers, peptides, saccharides and nucleic acids can be identified.

Abstract: Microfluidic devices and systems having enhanced detection sensitivity, particularly for use in non-fluorogenic detection methods, e.g., absorbance. The systems typically employ planar microfluidic devices that include one or more channel networks that are parallel to the major plane of the device, e.g., the predominant plane of the planar structure, and a detection channel segment that is substantially orthogonal to that plane. The detection system is directed along the length of the detection channel segment using a detection orientation that is consistent with conventional microfluidic systems.

Abstract: The present invention is generally directed to improved microfluidic devices, systems and methods of using same, which incorporate channel profiles that impart significant benefits over previously described systems. In particular, the presently described devices and systems employ channels having, at least in part, depths that are varied over those which have been previously described. These varied channel depths provide numerous beneficial and unexpected results.

Abstract: The present invention provides systems, devices and methods for performing fast and efficient separation and collection of components of a sample mixtures. The present invention provides integrated systems for performing separation using a multi port control system to sort and collect components of sample mixtures.

Abstract: Microfluidic devices are provided for the performance of chemical and biochemical analyses, syntheses and detection. The devices of the invention combine precise fluidic control systems with microfabricated polymeric substrates to provide accurate, low cost miniaturized analytical devices that have broad applications in the fields of chemistry, biochemistry, biotechnology, molecular biology and numerous other fields.

Abstract: Microfluidic devices and systems that include keying, registration or indication elements that communicate a functionality of the microfluidic device to the instrumentation which is used in conjunction with these devices. Indicator elements include structural indicators, electrical indicators, optical indicators and chemical indicators. Different indicator elements are indicative of different functionalities, e.g., applications, new vs. used, and the like.

Abstract: Throughput rates for microfluidic serial analysis systems are optimized by maximizing the proximity and speed with which multiple different samples may be serially introduced into a microfluidic channel network. Devices are included that include optimized parameters based upon desired throughput rates for a given set of reagents, reaction times and the like.

Abstract: A method of characterizing a polypeptide, comprising providing a first capillary channel having a separation buffer disposed within, wherein the separation buffer comprises a non-crosslinked polymer solution, a buffering agent, a detergent, and a lipophilic dye. The separation buffer is provided such that, at the time of detection, the detergent concentration in the buffer is not above the critical micelle concentration. The polypeptide is introduced into one end of the capillary channel. An electric field is applied across a length of the capillary channel, which transports polypeptides of different sizes through the polymer solution at different rates. The polypeptide is then detected as it passes a point along the length of the capillary channel.

Abstract: The present invention provides methods and systems for aligning detection optics with a device by obtaining an optical profile of the system and comparing it with a preprogrammed layout of the various optical features of the device. The invention also provides methods of identifying devices by comparing the optical profile with a library of preprogrammed optical profiles of multiple devices.

Abstract: The invention provides improved systems, devices, and methods for analyzing a large number of sample compounds contained in standard multi-well microtiter plates or other array structures. The multi-well plates travel along a conveyor system to a test station having a microfluidic device. At the test station, each plate is removed from the conveyor and the wells of the multi-well plate are sequentially aligned with an input port of the microfluidic device. After at least a portion of each sample has been input into the microfluidic channel system, the plate is returned to the conveyor system. Pre and/or post testing stations may be disposed along the conveyor system, and the use of an X-Y-Z robotic arm and novel plate support bracket allows each of the samples in the wells to be input into the microfluidic network through a probe affixed to a microfluidic chip.

Abstract: Laminates having microfluidic structures disposed between sheets of the laminate are provided. The microfluidic structures are raised on a sheet of laminate, typically by printing the structure on the sheet. Printing methods include Serigraph, ink-jet, intaligo, offset printing and thermal laser printing.

Abstract: Hydrophilic protein adsorption resistant coatings for microfluidic devices are provided. Additionally, microfluidic devices and methods of manufacturing microfluidic devices that include the coatings are provided.

Abstract: A microfluidic controller and detector system and method for performing screening assays are disclosed. The microfluidic controller and detector system comprises a fluidic chip that includes at least two intersecting channels and a detection zone, a fluid direction system comprising an electrical interface configured for electrical contact with the at least two intersecting channels, an optics block having an objective lens disposed adjacent the detection zone, and a control system coupled to the optics block and adapted to receive and analyze data from the optics block. The electrical interface generally includes electrodes configured for electrical contact with the intersecting channels and coupled to electrode channels for supplying electrical input to the electrodes. A reference channel is optionally provided to calibrate the electrode channels.

Abstract: Methods and systems for particle focusing to increase assay throughput in microscale systems are provided. The invention includes methods for providing substantially uniform flow velocity to flowing particles in microfluidic devices. Methods of sorting members of particle populations, such as cells and various subcellular components are also provided. Integrated systems in which particles are focused and/or sorted are additionally included.

Abstract: Systems and methods for analyzing a sample are disclosed. The system may include a light source operable to transmit light onto the sample, a detector operable to detect intensity of the light emitted from the sample, and a power modulator. The power modulator modulates the light source power such that light is emitted from the light source in more than one mode to reduce changes in the emitted light due to temperature changes in the light source.

Abstract: An analytical or preparatory microfluidic system is disclosed which generally comprises a base unit comprising a first adapter interface array; a first adapter plate selected from a set of a plurality of different adapter plates, wherein the first adapter plate comprises a base unit interface array that is complementary to the first adapter interface array, and a first substrate interface array, wherein the first adapter plate is removably coupled to the base unit such that energy passes from the base unit to the adapter plate through the first adapter and base unit interface arrays. The system further comprises a first microfluidic substrate selected from a set of a plurality of different microfluidic substrates, the first microfluidic substrate comprising a plurality of mesoscale channels disposed therein and a second adapter interface array, wherein the second adapter interface array is complementary to the first substrate interface array.

Abstract: The present invention generally provides microfluidic devices and systems that utilize electrokinetic material transport systems to selectively control and direct the transport of materials through and among complex arrangements of integrated, interconnected microscale channels disposed within integrated body structures.

Abstract: Methods and systems for designing optimized fluidic channel networks for performing different analytical operations, which include the steps of selecting a driving force, identifying at least a first reaction parameter, and designing the channel network by determining channel lengths and cross-sectional dimensions that are optimized for the reaction requirements in view of the selected driving force. Preferred methods are used to design integrated microscale fluidic systems.

Abstract: Methods, systems, kits for carrying out a wide variety of different assays that comprise providing a first reagent mixture which comprises a first reagent having a fluorescent label. A second reagent is introduced into the first reagent mixture to produce a second reagent mixture, where the second reagent reacts with the first reagent to produce a fluorescently labeled product having a substantially different charge than the first reagent. A polyion is introduced into at least one of the first and second reagent mixtures, and the fluorescent polarization in the second reagent mixture relative to the first reagent mixture is determined, this fluorescent polarization being indicative of the rate or extent of the reaction.