Abstract: A centrifugal force-based microfluidic device for the detection of a target biomolecule and a microfluidic system including the same are provided. The device includes a body of revolution; a microfluidic structure disposed in the body of revolution including chambers, channels connecting the chambers, and valves disposed in the channels to control fluid flow, the microfluidic structures transmitting fluid using centrifugal force due to rotation of the body of revolution; and beads disposed in the microfluidic structures, the beads having capture probes on the surfaces thereof which are selectively bonded with target protein; and a detection probe disposed in the microfluidic structures and selectively bonded to the target protein, and which includes a material required to express an optical signal, wherein the microfluidic structure mixes the beads, biological samples, and the detection probe to react and washes and separates the beads after the reaction.

Abstract: The invention concerns a method which consists in determining ageing an ageing index of a blood bag (11, 62), to determine whether the blood bag is or not suitable for transfusion to a patient. The ageing index is calculated by connecting a silicon chip provided with a loop antenna integral with the blood bag (11, 62) with an electronic communication device (2, 8, 17, 12, 20, 24), itself equipped with a loop antenna, connected to a computer (9, 13) containing appropriate computing software elements. Said ageing index is regularly calculated at the blood transfusion center (16) from the sample (1), until it is removed from storage (7) to be sent to the health-care institution (18) and to the operating theatre (19).

Abstract: A method and apparatus for separating and concentrating a selected component from a multi-component material. The multi-component material may include a whole sample such as adipose tissue, whole blood, or the like. The apparatus generally includes a moveable piston positioned within a separation container and a withdrawal tube that is operable to interact with a distal end of the collection container past the piston. Material can be withdrawn through the withdrawal tube.

Abstract: Modular sample processing apparatus kits that can provide a user with the flexibility to customize a disk-based assay in view of a variety of factors are disclosed. The sample processing apparatus kits of the present invention include one or more process modules that can be retained within openings in a frame. The frame and process modules of the sample processing apparatus kits are preferably adapted for use in sample processing systems that compress the apparatus. The process modules may contain different reagents to perform different tests on the same sample materials or a variety of sample materials. As a result, a single sample processing apparatus can be used to perform a variety of different tests and may include a quality control module capable of providing feedback to the user as to the accuracy of the processes run using the sample processing apparatus. Methods of using the sample processing apparatus that include deforming the process modules and frame are also disclosed.

Abstract: A cytocentrifuge sample chamber includes a sample receiving well to receive and hold a sample to be centrifuged and a sedimentation chamber adjacent a microscope slide upon which cells and/or other sediment material in the sample is to be deposited. A passage, such as a spillway, connects the sample receiving well and the sedimentation chamber, so that sample flows from the sample well under the influence of centrifugal force as centifugation begins into the sedimentation chamber where the sample is forced by centrifugal force against the microscope slide leaving a vacant space at the inner end of the sedimentation chamber. Sedimentation of the sample takes place against the microscope slide. When centrifugation ends, the liquid components of the sample flow back into the vacant space in the sedimentation chamber and can be removed from the vacant space at the inner end of the sedimentation chamber through a removal chamber.

Abstract: A microscale method for the characterization of one or more reaction variables that influence the formation or dissociation of an affinity complex comprising a ligand and a binder, which have mutual affinity for each other.

Abstract: Provided is a centrifugal force based microfluidic system including: a microfluidic device including a rotatable platform and an optical path formed to extend horizontally in a straight line from a circumference of the platform; a motor rotating so as to control the microfluidic device; a light emitting unit emitting light towards the microfluidic device; a light receiving unit detecting the light emitted from the light emitting unit; and a controller determining a home position to be the position of the microfluidic device at a point of time when the light emitted from the light emitting unit is detected by the light receiving unit, wherein the light emitted from the light emitting unit passes through the optical path to be incident on the light receiving unit only when the microfluidic device is located in a predetermined position.

Abstract: Herein disclosed is a liquid homogenizer for mixing two or more liquids, comprising: a rotator (1) rotatable around a rotation axis; at least two liquid-mixing chambers (6, 10) formed in the rotator, and being different from each other in distance from the rotation axis; and at least two channels (8) through which one of the liquid-mixing chambers is communicated with the other of the liquid-mixing chambers (6, 10), wherein the liquid-mixing chambers (6, 10) include an outer liquid-mixing chamber (10) and an inner liquid-mixing chamber (6) close to the rotation axis in comparison with the outer liquid-mixing chamber, when the rotator (1) is rotating around the rotation axis, the liquids are shifted by a centrifugal force to the outer liquid-mixing chamber from the inner liquid-mixing chamber through the channels (8), and agitated to be mixed by turbulent flows in the outer liquid-mixing chamber.

Abstract: A measuring chip is configured for separating and measuring a target component in a sample by rotation around first and second axes of rotation. The measuring chip includes a centrifugal separation tube that centrifugally separates the target component from the sample by rotating the measuring chip around the first axis of rotation; a first holding section installed in the bottom of the centrifugal separation tube, wherein non-target components other than the target component in the sample are introduced therein by rotation around the first axis of rotation, and the first holding section holds the non-target components during rotation around the second axis of rotation; and a measuring section connected to one end of the centrifugal separation tube that measures the non-target components introduced from the centrifugal separation tube by rotation around the second axis of rotation.

Abstract: A device is provided that can include at least one gas trap that can be arranged in fluid communication with a sample-containment feature formed in or on the device. The gas trap can be arranged to trap gas or air displaced from the sample-containment feature as the sample-containment feature is loaded with a liquid. The trapped gas in the gas trap can assist in breaking-up and expelling the liquid from the sample-containment feature during a subsequent liquid transfer operation, for example, to an adjacent sample-containment feature. Systems for processing such a device and methods using such a device are also provided.

Abstract: A method and an apparatus for enumerating one or more specific elements within a biologic fluid sample are provided. An embodiment of the method includes the steps of: a) providing a chamber formed between a first planar member that is transparent and a second planar member, which members are separated from one another by a substantially uniform height; b) introducing the biologic fluid sample into the chamber, wherein the chamber height is sized such that the sample extends between the first and second members, and sized relative to the specific elements within the sample such that the specific elements non-uniformly distribute within the sample upon introduction into the chamber; c) examining substantially all of the sample within the chamber and enumerating all of at least one of the specific elements; d) determining the volume of sample contained within the chamber; and e) determining the number of the at least one of the specific elements per unit volume.

Abstract: A chemical analysis apparatus comprises a motor, a holding disk that can be rotated by the motor, a plurality of examination cartridges arranged on the holding disk, a perforator that perforates the examination cartridges, a heating device, and a detection device. The examination cartridge comprises a substrate including a vessel and a flow channel, which are defined by recesses, and a cover that covers the vessel and the flow channel. A centrifugal force generated by rotation of the holding disk is made use of to move a solution from a vessel on an inner peripheral side relative to an axis of rotation to a vessel on an outer peripheral side relative to the axis of rotation through the flow channel.

Abstract: Both application of centrifugal force to a biosensor and electrical connection with an electrode of the biosensor can be achieved with a simple structure. The electrode of the biosensor and a measuring part are connected without aligning a rotational position of the rotary table. The centrifugal measuring apparatus 1 is provided with a rotary table 2 that is driven by a motor, a retainer 3 to hold a biosensor accommodating a sample inside on the rotary table, an urged contact part 4 that establishes electrical connection with the electrode of the biosensor in such a manner as being elastically biased to abut against the electrode, a measuring part 8 that measures a signal from the electrode of the biosensor, and a connector part 7 that selectively establishes electrical connection between the urged contact part 4 and the measuring part 8.

Abstract: A reaction disk provides a compact and inexpensive design of an automatic analyzer so that the constituents in a suspension, such as blood sampled from a patient at a sick room or other place in a hospital, can be analyzed immediately and quantitatively. A separation cell and a determination cell are formed in a same reaction disk so as to maintain an upright position even during rotation of the both cells. The separation cell is formed to prevent poured suspension therein from flowing out during centrifugal separation, and a supernatant separated by centrifugation from the suspension contained in the separation cell is dispensed to the determination cell to analyze a target substance in the supernatant.

Abstract: A newborn transfusion cell washing device generally comprising a disposable, graduated test tube shaped container having a cap with an inlet port, an injection/sampling port, a suction port, and a vent. The container is capable of being inserted into a conventional clinical centrifuge. The device requires a relatively small volume to operate, 25 ml or less per procedure, and can be performed easily by any hospital blood bank technologist without any special skills. Washed RBCs can be provided to the patient in a timely manner, without the need for “fresh blood.” Any in-dated RBCs can be washed to remove excessive potassium and other toxins. The main RBC aliquot can be saved and repeatedly sampled until the unit is expired or exhausted. This provides a cost savings to the hospital and more importantly, minimizes the recipient's donor exposure.

Abstract: The present invention includes a device comprising a lid and a vessel forming an interface that allows transfer of waste from a purification chamber to a waste chamber and method for purification of an analyte are disclosed wherein a supernatant is separated from a solid phase to which an analyte is bound by centrifugation via the lid of the device. The present invention also includes methods for use of the device.

Abstract: An immunological or immunohematological assay system is disclosed that includes a filter vessel capable of containing an assay sample, an incubator, a sample separation system, an image acquisition system, and a robotic pipettor. The immunological assay system may also include a washer. Also disclosed is an immunological assay method that includes the steps of placing a immunological assay sample in a filter vessel, which includes a filter, adding testing reagents to the filter vessel, incubating the sample and reagent mixture in the filter vessel, separating the sample and reagent mixture in the filter vessel into components above and below the filter, and analyzing the filter vessel to determine the presence of interactions between the sample and reagents.

Abstract: A method and apparatus for obtaining various components of a multi-component material. Generally, a component of a whole blood sample may be concentrated from a patient and re-introduced to the same patient. For example, a clotting component, such as thrombin, from a whole blood sample may be extracted and concentrated in an apparatus and collection to be reapplied or reintroduced into a patient.

Abstract: An object of the invention is to provide a test chip which allows efficient and convenient separation and measurement. This invention provides a measuring chip for separating and measuring a target component in a sample by rotation around first and second axes of rotation. The measuring chip includes a centrifugal separation tube that centrifugally separates the target component from the sample by rotating the measuring chip around the first axis of rotation; a first holding section installed in the bottom of the centrifugal separation tube, wherein non-target components other than the target component in the sample are introduced therein by rotation around the first axis of rotation, and the first holding section holds the non-target components during rotation around the second axis of rotation; and a measuring section connected to one end of the centrifugal separation tube that measures the non-target components introduced from the centrifugal separation tube by rotation around the second axis of rotation.

Abstract: A corpuscle/plasma separating part is disposed at the lower end of the substrate, and a sensor part connected to the corpuscle/plasma separating part is disposed at the upper end of the substrate, with a calibration solution reservoir being disposed on the lower side of the sensor part, and a calibration solution waste reservoir being disposed on the upper side of the sensor part. A first centrifugal axis is located upper to the corpuscle fraction storing part and lower to the plasma fraction storing part of the corpuscle/plasma separating part, while a second centrifugal axis is located within or close to the sensor part. Conveyance and discharge of the calibration solution can be carried out by performing centrifugation around the first centrifugal axis which is distant from the sensor part at a low speed of rotation, so that the centrifugal force exerted on the sensors would be small.

Abstract: The invention provides a chemical analysis apparatus which easily agitates and warms up. A chemical analysis apparatus has a motor, a retaining disc which can be rotated by the motor, a plurality of inspection cartridges which are arranged on the retaining disc, a punching machine for punching the inspection cartridges, a warming apparatus and a detection apparatus. The inspection cartridge includes a container formed by a concave portion and a base plate having a flow path. A cover covering the container and the flow path is installed to the base plate. A liquid solution is moved to the container in an outer peripheral side with respect to a rotation axis from the container in an inner peripheral side with respect to the rotation axis via the flow path, by utilizing a centrifugal force generated on the basis of the rotation of the retaining disc.

Abstract: A centrifuge has a bucket for receiving the product to be centrifuged, and a support which is configured to be inserted in the bucket and receive microtiter plates and the like. The support has substantial stability and comprises a generally planar base and four upstanding lateral walls which are integrally formed with the base and which are coupled together at their upper edges to form a substantially self-contained enclosure.

Abstract: The present invention provides a bar-code driven, completely automated, microplate-based analyzer system for performing chemical, biochemical or biological assays. The analyzer is a modular, bench-top instrument that compactly integrates subsystems for sample dispensing, liquid handling, microplate transport, thermal incubation, vortexing, solid phase separation and optical reading. An internal processor is included for automating the instrument, and a user interface to facilitate communication with the operator via a touch-sensitive liquid-crystal display (LCD), and communicating with a remote network via multiple protocols. The analyzer includes firmware resident within the processing system and the user interface allows the operator to select pre-defined assay batch protocols and the user interface is configured in such as way so as to restrict an operator from programming the firmware.

Abstract: The invention is achieved by feeding a reagent using centrifugal force, without providing a valve for controlling the flow rate of the reagent in the reagent flow path. A chemical analyzer is used which comprises a structure that is supported so as to be rotatable, said structure comprising a capturing section for capturing specific chemical substances from a specimen, specimen containers and reagent containers including washing solution containers.

Abstract: A device for separating at least part of the liquid component of a blood sample and methods thereof are disclosed. Generally, the device includes a container body for receiving the blood sample, a layer of retaining porous material, a layer of separating permeable material. The retaining porous material retains non-liquid components of the blood sample after the non-liquid components have been subjected to centrifugal force which forces them through the separating permeable material into the retaining porous material.

Abstract: Disclosed is a thin film chemical analysis apparatus and an analysis method using the same, which can solve the sealing problem caused by environmental factors (e.g. impact, temperature) for long circulation and storage periods, as well as can detect an analyte quickly and easily. The thin film chemical analysis apparatus includes at least one chamber adapted to store a fluid necessary for biological or biochemical analysis or to conduct a biological or biochemical reaction; channels for fluid-connection of the chambers; holes arranged between or inside the channels and connected to the channels; a rotatable body having the chambers, the channels, and the holes integrated into the body; and a burst valve having a sealing means for closing the hole and sealing a fluid in the chamber, the sealing means being torn away from the hole by centrifugal force resulting from rotation of the body and opening the hole.

Abstract: An analytical device for analysis of chemical or biological samples, a method of using such a device, based on rotation of the device, integrated sample dosing and optical detection, and a system comprising such a device are disclosed. The analytical device comprises a device body having a liquid processing unit. The liquid processing unit comprises a mixing chamber for mixing a sample with a reagent, a sample dosing chamber for delivering a defined volume of the sample to the mixing chamber, and a reagent channel for delivering the reagent to be mixed with the sample, wherein the mixing chamber also serves as a detection chamber.

Abstract: A tube and float system for use in separation and axial expansion of the buffy coat includes a transparent or semi-transparent, flexible sample tube and a rigid separator float having a specific gravity intermediate that of red blood cells and plasma. The float includes a main body portion of reduced diameter to provide a clearance gap between the inner wall of the sample tube and the float. One or more protrusions on the main body portion serve to support the flexible tube. During centrifugation, the centrifugal force causes the diameter of the flexible tube to expand and permit density-based axial movement of the float in the tube. The float further includes a pressure relief system to alleviate pressure build up in the trapped red blood cell blood fraction below the float, thereby preventing red blood cells from being forced into the annular gap containing the buffy coat layers.

Abstract: A centrifugation device comprising a combined sample chamber and slide holder adapted to be mounted, with a microscope slide (26), in a centrifuge in a predetermined position, after placing a fluid biological sample containing cells in the sample chamber. The device comprises an integrally moulded body (10) affording a base (14) which engages the microscope slide, and also affording a back plate (14) connected with the base plate by an integral hinge (22) a latch mechanism formed integrally with the remainder of the device is arranged, when the back plate (14) is closed against the rear of a microscope slide (26) engaged with the base (14), to locate the slide between the base and the back plate and to hold the back plate in this closed position until fracture of a retaining element from the integrally moulded body. Thus the device can be used once only.

Abstract: An analytical system includes a working fluid, a uniform dividing unit and a separating unit. The working fluid includes a first component and a second component with different characteristics. The uniform dividing unit is utilized to uniformly divide the working fluid and relatively rotated with respect to a reference axis. Under a capillarity force as well as the result of Coriolis force and siphon force, the first component can be separated from the second component by the separating unit.

Abstract: The capture rate of a target such as antigen and antibody in a sample is improved and the concentration of reaction product of a recognition substance is uniformized regardless of the position of a reaction field. By contacting microparticles and the sample using centrifugal force, the contact time of the target and the recognition substance is equalized regardless of the position in mixing chamber The microparticles and the sample are mixed evenly in the mixing chamber by changing the rotation direction and the concentration of reactant in a liquid mixture is uniform regardless of the position of the mixing chamber. When the liquid mixture having a uniform concentration is obtained, it is enough to extract a part of the liquid mixture and use the same for a process subsequent to a mixing process without the need of using all the liquid mixture.

Abstract: A reaction of a sample mixture liquid is detected accurately, by allowing a solid reagent to be dissolved and reacted in a liquid sample quickly and accurately. A disc main body, and at least one sample mixing unit provided at the disc main body are provided, and the sample mixing unit is provided with: a liquid sample reserve unit; a reagent chamber capable of disposing a plurality of the solid reagents; and a measurement chamber to which a sample mixture liquid containing a liquid sample and a solid reagent mixed in the reagent chamber is supplied. The reagent chamber has a form which allows a plurality of the solid reagents to be disposed in the direction substantially parallel to the radial direction of the disc in which centrifugal force is generated, or in the direction substantially perpendicular to the radial direction of the disc.

Abstract: This invention directs to an optical disc assembly configured to receive an analyte which can be detected by a standard optical disc reader or an optical disc reader modified therefrom. The optical disc assembly may preferably be designed so that the optical disc reader can track the disc and detect the analyte concurrently and discriminably. The optical disc assembly contains or encodes optically readable features which are trackable by the optical disc reader and which have encoded speed information enabling the optical disc reader to rotate the optical disc assembly at a determinable speed. The optical disc assembly also includes an analyte section capable of receiving the analyte that can be detected by the optical disc reader.

Abstract: An analyzer, preferably a desktop analyzer, includes: a stationary probe capable of dispensing or aspirating a liquid; one or more of a movable test element or movable liquid source; and a conveyor for moving the movable test element or liquid source with respect to the stationary probe. In a preferred embodiment, the conveyor includes a dual rotor conveyor. A method of dispensing or aspirating a liquid into a test element includes: providing a movable test element having identifying marks, such as a barcode, thereon and a movable sample liquid supply; providing a stationary probe; reading the identifying marks to determine which test is to be performed and the dimensions of the test element; moving the movable sample liquid supply into registration with the probe; aspirating sample into the stationary probe; and moving the movable test element into registration with the probe, wherein the registration of the test element with the probe is controlled by the test to be performed.

Abstract: An analysis device comprises a separation chamber for separating a sample solution into a solution component and a solid component, a holding channel for holding a predetermined amount of the separated solid component, a mixing chamber connected to the holding channel, an overflow channel connected between the holding channel and the separation chamber, a sample overflow chamber into which the sample solution remaining in the separation chamber is discharged, and a joint channel connecting the separation chamber and the sample overflow chamber. After the separated solution component fills the overflow channel with priority by a capillary force, the separated solid component is transferred to the holding channel via the overflow channel, and a predetermined amount of the solid component is measured.

Abstract: A rotatable sample disk configured for samples of biological material. The sample disk may include a fill chamber for storing a first biological material, a plurality of first sample chambers positioned in the sample disk farther from the rotational axis of the sample disk than the fill chamber, a plurality of second sample chambers, and a plurality of circumferential fill channels. Each of the second sample chambers may be configured to permit fluid communication with a respective first sample chamber. The plurality of circumferential fill conduits may be configured to permit transfer of the first biological material from the fill chamber to the plurality of first sample chambers upon a first rotation of the sample disk about the rotational axis. Methods of loading a plurality of sample chambers in a sample disk are also provided.

Abstract: This invention provides rotors and methods of precisely metering a sample fluid and mixing the sample with a reagent. The rotors have a metering tube of defined volume that fills until sample flow is stopped by surface tension of a meniscus at a capillarity port, while excess sample is stripped from the metering tube inlet by centripetal force of the spinning rotor. By spinning the rotor at a higher speed, a reagent can be forced from a reagent chamber to contact the meniscus, breaking the surface tension and allowing the metered sample to mix with the reagent.

Abstract: A blood analysis device for centrifugally separating plasma in a channel, wherein conveyance of blood, plasma and calibration liquid is effected within the device without using a pump or the like. The calibrator solution is reliably discharged from a sensor portion so as to make high precision analysis possible. A sensor section is provided in a plasma separating section and disposed on the side associated with a first centrifugal pressing direction as seen from a blood reservoir and a calibrator solution reservoir, while a calibrator solution waste reservoir is disposed in a second centrifugal pressing direction as seen from the plasma separating section (sensor section). The calibrator solution is conveyed to the sensor section by centrifugal operation in the first centrifugal direction. After sensor calibration, the calibrator solution can be reliably discharged from the sensor section by effecting centrifuging in the second centrifugal direction.

Abstract: A device and method is provided for separating heavier and lighter fractions of a fluid sample. The device includes a plurality of constituents comprising a container and a composite element in the container. The composite element is a separator comprising at least two components and more particularly an elastic portion and a plug member. A fluid sample is delivered to the container and the device is subjected to centrifugation whereby the centrifugal load causes the elastic portion of the separator to deform so that the separator migrates into the fluid sample and stabilizes between the heavier and lighter fractions of the fluid sample. The elastic portion of the separator will resiliently return to its initial configuration upon termination of the centrifugal load such that the elastic portion sealingly engages the container and separates the heavier and lighter fractions of the fluid sample.

Abstract: A centrifugation device comprising a combined sample chamber and slide holder adapted to be mounted, with a microscope slide, in a centrifuge in a predetermined position, after placing, in the sample chamber, a fluid biological sample containing cells, the centrifugation device comprising a body (10) affording a base (14) adapted for engagement with a microscope slide, structure on one side of the base defining a chamber for a fluid sample, with an opening (15) for the introduction of fluid to said chamber, the base (14) including an aperture (18) and carrying a means for sealing the edges of such aperture with respect to the surface of a microscope slide placed across the base (14), or for allowing the passage of liquid but obstructing the passage of cells, the centrifugation device further including a back plate (12) arranged, when the back plate (12) is closed against the rear of a microscope slide engaged with the base (14), to locate the slide between the base and the cover plate and to hold the cover pl

Abstract: Sample processing systems for processing sample materials located in sample processing devices that are separate from the system are disclosed. The sample processing systems include a rotating base plate with raised and/or non-planar thermal structures on which the sample processing devices are located during operation of the systems. The systems may also include structure to urge the sample processing devices against the base plate and thermal structures.

Abstract: A test element and method for detecting an analyte with the aid thereof is provided. The test element is essentially disk-shaped and flat, and can be rotated about a preferably central axis which is perpendicular to the plane of the disk-shaped test element. The test element has a sample application opening for applying a liquid sample, a capillary-active zone, in particular a porous, absorbent matrix, having a first end that is remote from the axis and a second end that is near to the axis, and a sample channel which extends from an area near to the axis to the first end of the capillary-active zone that is remote from the axis.

Abstract: A panel for analyzing a sample liquid by which an exactly fixed quantity of sample liquid can be dripped conveniently, and convenience of measuring operation and accuracy of measurements can be ensured even for a sample liquid containing solid components. The panel for analyzing a sample liquid comprises a first channel-like chamber which is rotated about the center of rotation and into which the sample liquid flows by capillarity, a first channel connected to the first chamber and having a cavity the width or the height of which is increased discontinuously, a second chamber connected to the first channel, an opening for supplying the sample liquid to the first chamber, and an opening for discharging gas from the first chamber as the sample liquid flows in.

Abstract: Disclosed herein is a modular test tube rack. The rack contains multiple sub-racks that can be coupled together to form the test tube rack. The sub-rack can be designed to fit into a variety of scientific instrumentation including a fixed rotor centrifuge. The assembled test tube rack can be of a format and size that allows use of standard array pipetters. Thus, a system is provided allowing use of standard array pipetters and high g centrifugation.

Abstract: The present invention provides test devices for detecting an analyte suspected of being present in a liquid sample. The devices contain a reservoir compartment, a test compartment, and a port for a sample collection well. The devices also have a rotatable sample collection well located in the port. The device has an upper chamber for insertion of a sample applicator, an expression plate for wringing out the sample applicator and applying sample to the device, a lower chamber, and an aliquot outlet and a reservoir outlet for the movement of sample through the device. The device also contains test elements for detecting the analyte of interest. By rotating the sample collection well, the operator is able to direct distribution of collected sample in the device. Methods of using the devices and kits containing the devices are also provided.

Abstract: The present invention provides a microchip which is made by bonding a first substrate having a groove provided at the substrate surface and a second substrate together, and has a fluid circuit therein, the fluid circuit having a separation portion for separating a first component, and a groove which constitutes the separation portion including an approximately V-shaped region surrounded by prescribed flow channel walls. At a top of the separation portion, a flow rate limiting portion limiting a flow rate of a fluid is preferably provided.

Abstract: Systems and methods for fractionating components of a sample are disclosed herein. A method of fractionating components of a sample includes establishing a solution density gradient in a capillary channel, applying the sample to the capillary channel, and centrifuging the sample in the capillary channel, thereby separating the components of the sample by density.

Abstract: Methods for applying sensor materials to optical storage media substrates are disclosed. After exposure to a sample of interest, the resulting sensors may be read in optical storage media drives for quantitative analysis of physical, chemical and biological parameters of the sample.

Abstract: Rare cells are separated from a sample fluid by a positive selection or negative selection antibody by centrifuging in a tube containing a harvesting float. The harvesting float has an axial passage and a density to settle in the sample fluid and expand the layer of the target component. The positive selection antibody is preferably coupled to a particulate carrier, such as a microbead, to attach to the target component. The negative selection antibody forms a complex or conjugate with a contaminating component. In the positive separation, the particulate carrier is recovered in the axial passage of the float.

Abstract: A microchip having a fluid circuit therein for passing a liquid is provided, wherein the fluid circuit has a first reservoir and a second reservoir for storing at least a part of the liquid, a first path connecting the first reservoir and the second reservoir, and a second path connecting the first reservoir and the second reservoir at a position different from the first path, and the first reservoir, the second reservoir, the first path, and the second path constitute a circular path capable of circulating the liquid.