Abstract: This disclosure is directed to an apparatus and method for spreading a fluid across a substrate. A spreader for spreading a fluid across a substrate includes a wiper and a frame. The wiper and the frame may mate to permit translation of the wiper across, and with respect to, the frame. The wiper spreads the fluid across the substrate and the frame supports the wiper and the substrate. The frame may also include a ramp to cause a portion of the wiper to lift away from the substrate.

Abstract: The present invention provides integrated sample preparation systems and stabilized enzyme mixtures. In particular, the present invention provides microfluidic cards configured for processing a sample and generating DNA libraries that are suitable for use in sequencing methods (e.g., next generation sequencing methods) or other suitable nucleic acid analysis methods. The present invention also provides stabilized enzyme mixtures containing an enzyme (e.g., an enzyme used in whole genome amplification), BSA, and a sugar. Such enzyme mixtures may be lyophilized and stored at room temperature without significant loss of enzyme activity for months.

Abstract: The present invention provides a bilayer membrane produced using a microchannel capable of easily forming bilayer membranes such as planar lipid bilayer membranes in large quantities, and a production method thereof. A process for producing a bilayer membrane of the present invention comprises forming a state where two liquid phases or liquid and gaseous phases each containing amphipathic molecules are alternately arranged in a microchannel, discharging one of the two liquid phases or the gaseous phase of the liquid and gaseous phases through branch minichannels formed in the wall on one side or in the walls on both sides to contact the remaining liquid phases adjacent to each other, and thereby forming a side-by-side arrangement of bilayer membranes comprising the amphipathic molecules.

Abstract: A microfluidic passive device and a method for determining clotting time are described, of a fluid medium such as blood, of low production cost which can therefore be disposable. When optimised to determine blood clotting time, it requires a minimal whole blood sample (<5 ?L) and it is particularly suited to INR or PT determination, which can be used autonomously by patient without venipuncture. Monitoring, and processing means to interpret the results are comprised in an external coagulometer device. A production method for the manufacture of the microfluidic device is also provided.

Abstract: A microfluidic system having a microchannel for the capillary transport of a liquid, in particular a body fluid for analytical purposes. The microchannel is provided with a surface coating comprising at least one hydrophilic substance selected from the group consisting of polyacrylic acid, polyacrylate, dextran sulfate and chondroitin sulfate. The invention also concerns a coating method that is suitable for this.

Abstract: Described is a biological sample carrier based on a rigid hydrophilic object fabricated from a non-absorbing inert porous material. A biological fluid sample applied to the surface of the object is absorbed into the pores and constituents of the biological fluid sample remain in the pores after drying. Unlike a disc punched from a conventional dried blood spot (DBS) card, the object is easily handled. In contrast to DBS cards containing glass fiber structures that interact with basic analytes and other DBS card having adsorbing fibers that tend to separate blood constituents as the sample spreads through the fibers, the biological sample carrier is substantially inert to drug analytes.

Abstract: A microwell device is provided. The device includes a plate having a upper surface. The upper surface has first and second recesses formed therein. Each recess has an outer periphery. First and second portions of microwells are formed in upper surface of the plate. The first portion of microwells are spaced about the outer periphery of the first recess and the second portion of microwells spaced about the outer periphery of the first recess. A first barrier is about a first portions of the microwells for fluidicly isolating the first portion of the microwells and a second barrier about a second portions of microwells for fluidicly isolating the second portion of the microwells.

Abstract: A kit comprising a carrier and vessels arranged on the carrier, wherein different reagents are contained in different vessels, the vessels are arranged with an openable closing device on top of the carrier, the carrier has a footprint on the bottom side for being placed on a base, and the carrier has bottom positioning means for being positioned on at least one workplace of an automated laboratory system for microtiter plates according to the SBS standard.

Abstract: The present invention relates to a method of continuously conveying a liquid which is used as starting material in a chemical reaction by means of a displacement pump having physically separate forward-transport valves and a liquid-filled bidirectional flow line between displacement pump and forward-transport valves, wherein an auxiliary liquid which is a product or a starting material of the chemical reaction and has a melting point which is below the melting point or below the saturation temperature of the liquid to be conveyed is present in the bidirectional flow line. The present invention additionally provides for the use of a product formed by hydrogenation of an aromatic compound as auxiliary liquid for conveying an aromatic compound and also the use of an alcohol or an ester derived from alcohol and carboxylic acid as auxiliary liquid for conveying carboxylic acids or carboxylic acid derivatives.

Abstract: A device for passing a biopolymer molecule includes a nanochannel formed between a surface relief structure, a patterned layer forming sidewalls of the nanochannel and a sealing layer formed over the patterned layer to encapsulate the nanochannel. The surface relief structure includes a three-dimensionally rounded surface that reduces a channel dimension of the nanochannel at a portion of nanochannel and gradually increases the dimension along the nanochannel toward an opening position, which is configured to receive a biopolymer.

Abstract: A blood coagulation analyzer includes a detector and a controller. The detector includes a light source for emitting light to a prepared measurement sample and a light-receiving section for receiving light transmitted through the measurement sample. The controller is configured to performs operations comprising acquiring, based on the light detected by the detector, ratio information reflecting a ratio between a first value reflecting the intensity of the light transmitted through the measurement sample of a clotting reaction starting stage and a second value reflecting the intensity of the light transmitted through the measurement sample of a clotting reacting ending stage, and acquiring, based on the ratio information, a fibrinogen concentration in the blood sample.

Abstract: Provided is a cell adhesion inhibitor which exhibits low cytotoxicity and an excellent cell adhesion prevention effect; a tool and an apparatus each having a surface modified through application of the cell adhesion inhibitor thereto; a method for producing each of the surface-modified tool and apparatus; a biomedical structure and a production method therefor; and a microchannel device and a production method therefor. The invention provides a cell adhesion inhibitor comprising, as an active ingredient, a polymer comprising a repeating unit having a sulfinyl group in a side chain thereof.

Abstract: Systems and methods for processing and analyzing samples are disclosed. The system may process samples, such as biological fluids, using assay cartridges which can be processed at different processing locations. In some cases, the system can be used for PCR processing. The different processing locations may include a preparation location where samples can be prepared and an analysis location where samples can be analyzed. To assist with the preparation of samples, the system may also include a number of processing stations which may include processing lanes. During the analysis of samples, in some cases, thermal cycler modules and an appropriate optical detection system can be used to detect the presence or absence of certain nucleic acid sequences in the samples. The system can be used to accurately and rapidly process samples.

Abstract: A device for transporting magnetic or magnetizable beads over a transport surface includes a chamber holding magnetic or magnetizable beads in a fluid, a transport element including the transport surface within the chamber, and a current wire structure including at least two sets of meandering current wires arranged on a side of the transport element opposite to the transport surface. The at least two sets are displaced with respect to each other in at least two directions. A switching unit switches currents individually applied to the sets of current wires according to a current driving scheme resulting in a transport of the beads over the transport surface.

Abstract: A computer includes a number of hard disk drives (HDDs), a number of Serial Advanced Technology Attachment (SATA) connectors correspondingly connected to the HDDs, and a number of jumpers. Each SATA connector includes a power supply pin, a spin-up pin, a ground pin, and a pin base with first to third pins. The first to the third pins are respectively connected to the power supply pin, the spin-up pin, and the ground pin. The second pin of each SATA connector is connected to either the first pin or the third pin by a corresponding jumper, thereby the corresponding HDD starts up with the computer or starts up at a preset time after the computer has started up.

Abstract: A valve unit and an apparatus having the same include a plug which includes a phase change material in a solid state at a room temperature and a plurality of fine heat-dissipating particles dispersed in the phase change material. The fine heat-dissipating particles dispersed in the phase change material dissipate heat by absorbing an electromagnetic wave energy generated by electromagnetic wave radiation from the outside and block fluid flow in a path formed by a channel. As an external energy source irradiates an electromagnetic wave on the plug, the plurality of fine heat-dissipating particles dissipate heat and the phase change material becomes molten, thus opening the path to allow the fluid to flow.

Abstract: The present invention relates to a biochip with a piezoelectric element for ultrasonic standing wave generation. The biochip comprises an upper module, a lower module, and a chemical sensor. The piezoelectric element is integrated within the upper module of the biochip. The piezoelectric element can generate ultrasonic standing waves (USW) in the reaction chamber of the biochip by manipulating the operation frequency so the particles being detected can effectively move toward the QCM sensing surface. Hence, the biochip significantly increases the sensitivity and reduces the time required to reach equilibrium when undergoing USW excitation. The biochip of the present invention can be broadly applied to the bio-detection in medical and pharmaceutical fields.

Abstract: A vial and particles for distributing reagent bound particles in a fluid, a kit, and methods for distributing particles in a fluid.

Abstract: The invention relates to a miniaturized fluid container with microchannels (11, 12) which are bordered by ridges (13, 14), wherein the crests of the ridges (13, 14) are glued to a cover plate (20). Additional stability may be achieved by distributing glue (33) in cavities between the microchannels (11, 12), the spreading of said glue being driven by capillary forces.

Abstract: A microfluidic element for analyzing a bodily fluid sample for an analyte contained therein is provided, the element having a substrate, a channel structure that is enclosed by the substrate, and a cover layer, and is rotatable around a rotational axis. The channel structure of the microfluidic element includes a feed channel having a feed opening, a ventilation channel having a ventilation opening, and at least two reagent chambers. The reagent chambers are connected to one another via two connection channels in such a manner that a fluid exchange is possible between the reagent chambers, one of the reagent chambers having an inlet opening, which has a fluid connection to the feed channel, so that a liquid sample can flow into the rotational-axis-distal reagent chamber. At least one of the reagent chambers contains a reagent, which reacts with the liquid sample.

Abstract: A method and apparatus are provided for forming high-yield tissue microarray blocks capable of producing 1,000 or more replicate slides. In one embodiment, a plurality of donor tissue samples are minced and suspended in separate molten liquid carriers to form a plurality of separate two-phase mixtures of solid minced tissue and molten wax. Each of the two-phase mixtures is preferably formed into elongated columns and transferred into a separate well of a microarray block. A method and apparatus are provided for forming the elongated molten wax columns with minced tissue evenly distributed along the length of each column. The apparatus for forming the array includes an extrusion mechanism for transferring the columns of two-phase mixtures into the deep wells of the microarray block. The two-phase mixture may alternately be cooled and allowed to solidify before being transferred into the microarray block.

Abstract: A hematology analyzer is provided. In certain embodiments, the hematology analyzer comprises: a) a flow cell; b) a light source for directing light to the flow cell; c) a plurality of detectors for detecting a plurality of optical characteristics of a blood cell passing through the flow cell; and d) a data analysis workstation programmed to: i. enumerate test blood cells passing through the flow cell; and ii. flag a blood sample as containing lysis-resistant red blood cells or fragile white blood cells.

Abstract: A cuvette comprising a cuvette wall for limiting a sample reception space for receiving a fluid sample is disclosed. The cuvette wall is adapted to allow a traversal of measurement radiation through the fluid sample situated within the sample reception space. An information presenter is fixed at the cuvette wall. The information presenter wirelessly provides data to be transferred to an external data reception module. The data to be transferred relates to the cuvette. Further, an optical measurement apparatus is described.

Abstract: A disc-shaped analysis chip has an internal space. The internal space includes: a first reservoir for accommodating a first liquid; a second reservoir and a third reservoir arranged nearer to an outer peripheral portion of the analysis chip than the first reservoir; a fourth reservoir, a fifth reservoir and a sixth reservoir for accommodating a second liquid, a third liquid and a fourth liquid, respectively, and being arranged nearer to the outer peripheral portion of the analysis chip than the second and the third reservoir; a seventh reservoir arranged nearer to the outer peripheral portion of the analysis chip than the fourth to the sixth reservoir; an eighth reservoir arranged nearer to the outer peripheral portion of the analysis chip than the seventh reservoir; and a first to an eighth flow path for appropriately interconnecting the first to the eighth reservoir.

Abstract: The invention discloses a blood analyzing device (100) comprising a holder (110) arranged for carrying a container (10) having a cuvette (20) containing a blood sample (30). The container (10) is positioned in the holder (110) so that a longitudinal axis (60) of the cuvette (20) is angled relative a horizontal axis (70). A light source (120) provides light (40) into the sample (30) and a detector (130) detects the output light (50) from a sub-portion of the blood sample (30). Kinetic information indicative of the change in hemoglobin concentration in a measuring volume (32, 34) is determined by a Hb processor (145) from the detected output light (50). An ESR processor (140) determines the erythrocyte sedimentation rate of the sample (30) based on the kinetic information.

Abstract: A parallel processing system for processing samples is described. In one embodiment, the parallel processing system includes an instrument interface parallel controller to control a tray motor driving system, a close-loop heater control and detection system, a magnetic particle transfer system, a reagent release system, a reagent pre-mix pumping system and a wash buffer pumping system.

Abstract: The invention related to a method of making a dried reagent preparation, comprising the steps of: providing an aqueous solution of at least one buffered biological reagent; mixing a glass forming filler material with the buffered reagent solution to form a mixture wherein the concentration of the filler material is sufficient to facilitate formation of a glassy, porous composition; dispensing the mixture in the form of substantially uniform droplets into wells of a multi-well container, wherein a single droplet is dispensed into each well; drying the droplets in the container to form the reagent preparation. The reagent preparation is water soluble and has a Tg sufficient for room temperature stability.

Abstract: Trays comprising a base have a plurality of axial slots adapted to receive buffer or other medical solution containers within the slots. A spring or other compression element at the bottom of the slot is configured to engage a plunger at the bottom of the solution container when present in the slot so that pressure is applied to the contents of the container in order to stabilize the contents while the containers are sterilized at an elevated temperature.

Abstract: A support unit for a microfluidic system includes a first support; a first adhesive layer provided on a surface of the first support; and a hollow filament laid on a surface of the first adhesive layer to have an arbitrary shape and functioning as a flow channel layer of the microfluidic system.

Abstract: Polyamide sample preparation tubes with a hollow polyamide tube and an extraction medium contained within the tube are utilized in the sample preparation devices. The sample preparation tubes are substantially inert and show little tendency to dissolve or leach contaminants into nonaqueous liquids. The polyamide tubes may be used in preparing samples for analytical procedures such as GC, GC/MS, LC or LC/MS.

Abstract: A support unit for a microfluidic system includes a first support; a first adhesive layer provided on a surface of the first support; and a hollow filament laid on a surface of the first adhesive layer to have an arbitrary shape and functioning as a flow channel layer of the microfluidic system.

Abstract: An assay cartridge has a base member (26) that defines at least two wells (30, 32, 34, 36, 38), a pipette (108, 110) positionable in at least one of the wells and a cap member (86) arranged to carry the pipette. The cap member can be releasably fastened to the base member. An extension member (28) defines at least one further well (40, 42, 44) and can be fastened to the base member such that the pipette is then positionable in at least one of the wells of the base and in the further well of the extension member.

Abstract: To be adapted to various types of latex reagents for detecting scattered light and thereby measuring agglutination reactions with high sensitivity while sufficiently ensuring integration time. To be adapted to various types of latex particles of different particle sizes, a plurality of light receivers are arranged in a plane perpendicular to the direction of cell movement by rotation of a cell disk. To ensure sufficient integration time, the angle between the optical axis of the irradiation light and each of a plurality of optical axes of scattered light viewed from above the cell is made equal to or less than 17.7° including a mounting error.

Abstract: Cells in a suspension are counted in a hemocytometer slice with a chamber of controlled depth and one or more reservoirs along one or more side edges of the chamber. The suspension is fed to a reservoir to first fill the reservoir, and then to overflow into the chamber. The result is an even distribution of the cells in the chamber.

Abstract: This invention relates to a cartridge for an immunoassay test. The cartridge comprises (a) a probe well comprising a probe and a cap, the cap being in a closed position to enclose the probe in the probe well, wherein the probe has a bottom tip coated with analyte-binding molecules, (b) a sample well to receive a sample, (c) one or more reagent wells, (d) a plurality of wash wells each containing a first aqueous solution, and (e) a measurement well having a light transmissive bottom, the measurement well containing a second aqueous solution, wherein the openings of the sample well, reagent well, measurement well and wash wells are sealed. The present invention also relates to an apparatus for loading and releasing a probe. The apparatus comprises a push pin and a groove to load and transfer the probe to a plurality of locations, such as different wells in the above-mentioned cartridge, to conduct the immunoassay test.

Abstract: A device for volumetric metering a liquid biologic sample is provided. The device includes an initial chamber, a second chamber, a third chamber, a first valve, a second valve and a third valve. The chambers are each configured so that liquid sample disposed in the respective chamber is subject to capillary forces. Each chamber has a volume, and the volume of the initial chamber is greater than the volume of either the second or the third chambers. The valves each have a burst pressure. The burst pressure of the first valve is greater than the third burst pressure. The first valve is in fluid communication with the second chamber. The second valve is disposed between, and is in fluid communication with, the initial chamber and the third chamber. The third valve is in fluid communication with the third chamber.

Abstract: There is described a heating system for independently heating at least one sample recipient containing a sample, the sample recipient provided in a sample holder, comprising: a heating chamber having at least one opening and adapted to receive the sample holder; at least one microwave generator for generating microwaves; at least one microwave applicator inside the heating chamber connected to the at least one microwave generator, the at least one microwave applicator comprising an oven cavity portion for creating a mini microwave cavity around a single sample recipient in the sample holder, and for applying microwaves generated by the at least one microwave generator directly to the single sample recipient; and a control unit for controlling the at least one microwave generator.

Abstract: The invention provides a permeation device (2) comprising a receiving vessel (6) having an aperture adapted for receiving an insert well (4). Both the vessel (6) and well (4) are used as either donor or acceptor compartments for permeability assays. The vessel (6) or well (4) comprises a porous suppor (8)t, which may comprise biological or biomimetic materials, adapted for a molecular entity to permeate therethrough. In one embodiment, a stirring member (24) disposed in the vessel (6) can provide solution agitation to reduce aqueous boundary layer thickness adjacent to the support (8). Boundary layer thicknesses can be reduced by a device (2) of the invention to less than about 15 um such that a molecular entity permeating the support closely approximates in vivo absorption and transport conditions.

Abstract: Example apparatus including septums and related methods are disclosed. An example apparatus includes a septum that includes a first surface and a membrane coupled to at least a portion of the first surface. In addition, the example septum includes a second surface and ribs extending between the membrane and the second surface.

Abstract: A reactor comprises a main body having a flow path substrate and a crystal substrate chemically bonded to the flow path substrate to form a flow path for running a sample to be measured and a reactor tank connected to the flow path. An adsorption film is disposed in the reactor tank for adsorbing a specific substance contained in the sample to be measured. A measuring device measures a physical quantity of the specific substance contained in the sample and adsorbed by the adsorption film.

Abstract: A microfluidic device including a platform and a cartridge is disclosed. The platform includes a chamber containing a fluid. The reagent cartridge is mounted to the platform. and contains a solid reagent for detecting material contained in the fluid.

Abstract: A system for managing treatment of a particular health condition afflicting a patient includes a health management application program that prompts a user for entry of health condition data, including patient physiological data, subjective patient health condition data, and medication delivery data, compiles the health condition data into a data summary, and transmits the data summary through a communication unit. A drop-down list related to subjective symptoms is provided, which includes stress and depression. A touch screen is provided for a graphical user interface. The health management program also provides prompts for the entry of diet data, and further displays drop-down lists related to daily activities and alerts for medication delivery.

Abstract: The invention relates to a device and method for non-invasive detection of an analyte in a fluid sample. In one embodiment, the device comprises: a collection chamber containing an absorbent hydrogel material; a fluidic channel connected to the collection chamber; a sensing chamber connected to the fluidic channel, wherein the device is comprised of a compressible housing that allows transfer of fluid collected by the collection chamber to be transferred to be extracted and withdrawn to the sensing chamber upon compression of the device, wherein the sensing chamber contains a material that specifically detects the analyte and wherein the sensing chamber is operably linked to a processor containing a potentiostat that allows detection of the analyte using electrochemical sensing.

Abstract: A holding unit pivotally holds a plurality of reagent bottles which store reagents. A reagent case houses the holding unit and has an edge higher than at least the housed holding unit. The reagent cover is a cover for closing the reagent case. A cooling unit is mounted on one outer surface of the reagent case and cools air in the reagent case closed by the reagent cover through one outer surface. A circulating unit is mounted on the holding portion and circulates the cooled air in the reagent case closed by the reagent cover.

Abstract: A delivery apparatus for selectively delivering one or more liquid reagents into a reaction or test chamber (2), especially of an assay apparatus, the apparatus comprising: one or more respective storage chambers (5,6) for containing the one or more liquid reagents and arranged generally above the reaction or test chamber (2); and a plunger element (4) arranged and operable for insertion into the mouth of a selected storage chamber so as to displace a selected reagent from therewithin into the reaction or test chamber (2) generally therebelow by gravitational liquid overflow from the mouth of the chamber. The apparatus may conveniently be provided as a discrete delivery unit, with the storage chambers (5,6) pretilled with the selected reagents.

Abstract: The invention provides structures and methods that allow polymers of any length, including nucleic acids, to be stretched into a long, linear conformation for further analysis.

Abstract: In a microfluidic assembly, a microfluidic device is provided with a body in which at least a first inlet for loading a fluid for analysis, and a buried area in fluid communication with the first inlet are defined. An analysis chamber is in fluid communication with the buried area and an interface cover is coupled in a fluid-tight manner above the microfluidic device. The interface cover is provided with a sealing portion in correspondence to the analysis chamber, operable to assume a first configuration, in which it leaves the analysis chamber open, and a second configuration, in which it closes the analysis chamber in a fluid-tight manner.

Abstract: A biological substrate, e.g., microfluidic chip. The substrate includes a rigid substrate material, which has a surface region capable of acting as a handle substrate. The substrate also has a deformable fluid layer coupled to the surface region. One or more well regions are formed in a first portion of the deformable fluid layer and are capable of holding a fluid therein. The one or more channel regions are formed in a second portion of the deformable fluid layer and are coupled to one or more of the well regions. An active region is formed in the deformable fluid layer. At least three fiducial markings are formed within the non-active region and disposed in a spatial manner associated with at least one of the well regions. A control layer is coupled to the fluid layer.

Abstract: Herein provided are fluidics platform and method for sample preparation and analysis. The fluidics platform is capable of analyzing DNA from blood samples using amplification assays such as polymerase-chain-reaction assays and loop-mediated-isothermal-amplification assays. The fluidics platform can also be used for other types of assays and analyzes. In some embodiments, a sample in a sealed tube can be inserted directly. The following isolation, detection, and analyzes can be performed without a user's intervention. The disclosed platform may also comprises a sample preparation system with a magnetic actuator, a heater, and an air-drying mechanism, and fluid manipulation processes for extraction, washing, elution, assay assembly, assay detection, and cleaning after reactions and between samples.

Abstract: A cap having a core structure dimensioned to receive a pipette therethrough. The cap includes two axially aligned frangible seals that are affixed to the core structure in a spaced-apart relationship. The frangible seals are constructed so that air passageways are formed between the frangible seals and a pipette tip when the pipette tip penetrates the frangible seals. The cap optionally includes a filter interposed between the first and second frangible seals.