Abstract: A cell culture apparatus includes: an isolator in which a sterile space accommodating a cell incubator filled with a culture solution containing cells to be cultured is disposed; a sampling unit configured to sample the culture solution in the cell incubator; a delivery flow path through which an inside of the sterile space and an outside of the sterile space communicate with each other, the delivery flow path configured to limit a flow in the delivery flow path to a direction that is directed from the inside of the sterile space toward the outside of the sterile space; and a culture solution delivering section configured to deliver the sampled culture solution to the outside of the sterile space via the delivery flow path.

Abstract: A liquid testing assembly for testing a liquid, the assembly comprising a test vessel and a stopper adapted to fit into a free end of the vessel. The stopper substantially hermetically seals the test vessel from the ambient. Further, the assembly includes a support coated with one or more identifying materials for identifying one or more constituents of the liquid. The support is fixed in the stopper and/or the vessel and extends into its interior for a predetermined distance. The liquid testing assembly when assembled is pre-evacuated to a predetermined vacuum sufficient to draw a predetermined volume of liquid to be sampled into the test vessel. The predetermined volume is of such an amount that it wets the one or more identifying materials ensuring identification of one or more constituents present in the liquid. A kit employing the liquid testing assembly is also discussed.

Abstract: A microfluidic separation system, which comprises a magnetic separator, which itself comprises a magnetic energy source; first and second magnetically conductive members leading from the magnetic energy source and having respective terminal ends that are separated by a gap over which a magnetic field is applied due to the magnetic energy source. The separation system further comprises a microfluidic chip for insertion into the gap, which comprises a body defining channels on respective faces of the body; and an exterior lining that seals the plurality of channels to allow separate test sample volumes to circulate in at least two of the channels. Upon insertion of the chip into the gap, a first test sample volume is confined to circulating closer to the terminal end of the first member and a second test sample volume is confined to circulating closer to the terminal end of the second member.

Abstract: A perifusion device includes at least one sample container for cells, the sample container having an inlet and an outlet. The container receives test liquid through the inlet and discharges the liquid through the outlet. A manifold having a plurality of liquid inlets, control valves, and liquid outlets can be provided so that the flow of liquids from source containers to the sample containers can be varied and controlled. A receptacle housing has a plurality of receptacles for receiving fluid from the outlet of the sample container. A drive is connected to the receptacle housing for moving the receptacle housing such that liquid samples are collected sequentially from the outlet of the sample containers. A programmable controller can be provided to control movement of the receptacle housing at predetermined times, and to record data identifying liquid samples in the receptacles.

Abstract: A biological material fixed carrier enclosing tip, a biological material fixed carrier treatment apparatus, and a treatment method thereof. An object is to obviate attachment control and suction control for storing and retaining the carrier in the tip form vessel, to simplify complex reaction processes, and to make processing of the biological material fixed carrier to be easily executed as a result of a small-scale device configuration.

Abstract: The disclosure provides for reagent compositions for biosensors comprising release polymers, methods of making such biosensors and films of reagent compositions comprising release polymers. The reagent compositions comprise a release polymer and an effective analyte detecting amount of an enzyme an enzyme cofactor and a redox compound capable of acting in a biosensor as (i) a redox mediator associated with a working electrode (ii) a redox couple associated with a reference electrode or (iii) the redox mediator associated with the working electrode and the redox couple for the reference electrode.

Abstract: An analyzer comprising: a first specimen holder configured to hold a plurality of first specimen containers; a conveying assembly for conveying the first specimen containers held in the first specimen holder; a second specimen holder arranged at a position higher than an upper end of the first specimen containers held in the first specimen holder; a holder moving assembly for moving the second specimen holder so as to pass the upper side of at least one of the first specimen containers held in the first specimen holder; a container transferring assembly for transferring at least one of the first specimen containers from the first specimen holder to the second specimen holder; and a controller for controlling the holder moving assembly and the container transferring assembly, is disclosed.

Abstract: The present invention concerns an apparatus (1) for staining tissue samples, said apparatus (1) including a reagent section (2) or reagent containers (3); at least one staining section or tissue samples, a robotic head (22) or robotic element (20) that may move reagent to a predetermined tissue sample, said robotic element (20) being moveable above the reagent and the staining sections, a control element (85) that may manage a staining process, a 2-D optical sensor (86) to detect two-dimensional image data of a relevant property and that can feed the captured image data to the control element (86). By providing the robotic element (20) with a 2-D optical sensor (86), a common image processor may be provided having multiple functions. By using a 2-D optical image processing system, the control system of the apparatus may easily be adapted to read various types of data presentations, just as actual images for sections of the apparatus may be identified in order to assess the condition of the apparatus.

Abstract: In certain embodiments, a method of maintaining health of a patient uses an analyte detection system. The analyte detection system is coupled to the patient such that a bodily fluid of the patient is accessible to the analyte detection system. The method includes automatically initiating and conducting a measurement of an analyte in the bodily fluid using the analyte detection system. The method further includes determining a treatment dose for the patient based on the measurement using the analyte detection system.

Abstract: The invention relates to a method for selecting charged particles possessing a predetermined property from a population of a multiplicity of different particles, and also to a device which is suitable for implementing the method.

Abstract: A thermal cycling device for thermally cycling samples of biological material contained in a microcard having a top and bottom surface. The thermal cycling device can include a sample block having an upper surface configured for engaging the bottom surface of a microcard, a vacuum device, and a temperature control system operatively connected with the sample block. The upper surface of the sample block may include a plurality of channels, the channels defining spaces between the sample block and the bottom surface of a microcard that may be positioned thereon. The vacuum device may be in fluid communication with the sample block for drawing gas out of the spaces defined by the channels in the sample block. The vacuum device may be configured for substantially maintaining a vacuum between the sample block and microcard so that a retention force is imparted on the microcard to urge the microcard toward the sample block.

Abstract: The present invention pertains to an apparatus for holding cells. The apparatus comprises a mechanism for incubating cells having a dynamically controlled environment in which the cells are grown, which are maintained in a desired condition and in which cells can be examined while the environment is dynamically controlled and maintained in the desired condition. The apparatus also comprises a mechanism for determining the state of the cells. The determining mechanism is in communication with the incubating mechanism. The present invention pertains to a method for holding cells. The method comprises the steps of incubating the cells in a dynamically controlled environment which is maintained in a desired condition and in which the cells can be examined while the environment is dynamically controlled and maintained in the desired condition. Additionally, there is the step of determining the state of the cells.

Abstract: A whispering gallery mode resonator based optical sensor assembly comprises a flow channel permeable to optical energy and first and second optical waveguides adjacent to a section of the flow channel and adapted to be in first and second evanescent field couplings respectively with the section such that the section forms a whispering gallery mode resonator. The resonator is responsive to an optical signal conveyed in the first optical waveguide and communicates a second optical signal to the second optical waveguide indicative of a resonance wavelength of the whispering gallery mode resonator. A detector optically coupled to the second optical waveguide detects the output signal. A signal processor detects a shift in the output signal responsive to an analyte fluid flowing through the flow channel. The shift is indicative of the identity of at least one constituent of the analyte fluid.

Abstract: A device for identifying infection by the malaria parasite includes a microfluidic device having an inlet and an outlet and a diagnostic channel interposed between the inlet and the outlet. The diagnostic channel includes a contact surface and a sample pump configured to pump a RBC-containing sample into the inlet. The contact surface may be at least one of hydrophilic and roughened. Malaria infected RBCs (miRBCs) interact with the contact surface and become immobilized thereon whereas non-infected RBCs continue to flow downstream in the diagnostic channel.

Abstract: Disclosed is a disk based system for separating at least two types of particulates contained in a sample fluid. The system includes a disk-like carrier board and a magnetic attraction unit. The disk-like carrier board forms at least one flow channel structure, which includes an inner reservoir, at least one separation chamber, and at least one outer reservoir arranged in sequence from a geometric center of the disk-like carrier board to an outer circumferential rim of the disk-like carrier board. A method of separation carried out with the system includes introducing the sample fluid into the inner reservoir and then rotating the disk-like carrier board to induce a centrifugal force. The sample fluid contains particulates that are labeled with immunomagnetic beads and the labeled particulates are attracted by the magnetic force generated by the magnetic attraction unit to retain in the inner reservoir or the separation chamber.

Abstract: Methods and apparatuses for performing assays involving binding material elements with a plurality of bonds over a substantial area of a surface of a resonant device establishing a normalized exposure. The methods and apparatuses also involve controlling an external influence applied to the material elements over a first period of time and measuring a signal during a second period of time that is indicative of the change in the amount of material elements bound to the surface relative to the normalized exposure. In some cases, the measured signals are integrated with respect to time to determine the time averaged amount of material elements bound to the surface.

Abstract: A method of separating a cell-containing sample into a substantially cell-depleted portion, and a cell-containing portion comprising at least one of a stem cell, a lymphocyte, and a leukocyte comprises a step in which the sample is received in a vessel with at least one flexible wall. In another step, an additive and particles are added to the sample, wherein the additive substantially binds to the at least one of the stem cell, lymphocyte, and leukocyte, and the particles and wherein the particles substantially bind to the at least one of the stem cell, lymphocyte, and leukocyte, and the additive, thereby producing a cell-containing network. In a further step, the network is separated from the substantially cell-depleted portion by applying a magnetic force.

Abstract: Magnetic handling structure (1a) comprising a retractable magnet (4) and a probe (3) for the manipulation of magnetic particles in biological samples and methods of handling magnetic particles in biological samples.

Abstract: Some embodiments of the invention provide a system comprising a meter and a disposable cartridge for analyzing a fluid sample typically blood that is drawn into the cartridge by capillary action, negative pressure, positive pressure, or a combination thereof. The cartridge has at least one flow path, and includes at least one optical chamber for spectroscopic measurement, and at least one biosensor for biosensor measurement. The meter has a sample slot for receiving the disposable cartridge. The cartridges have electrical output contacts, and the meter slot has electrical input contacts. When the output contacts mate with the input contacts, the optical chamber becomes positioned for spectroscopic measurement. The present invention can provide joint-diagnostic spectroscopic and biosensor measurements.

Abstract: The information processing unit receives input of a user ID and a password when the operator carries out log-in, and executes user authentication process. When the log-in process is carried out by the user, the information processing unit outputs test results together with a patient attribute information including patient ID, name of the patient, attending physician, medical wards, comments regarding patient, and the like. When the log-in process is carried out by the maintenance technician, the information processing unit outputs the test result only.

Abstract: A method and a microfluidic device are provided to regulate fluid flow by equalization of channel pressures. The fluid flow is regulated by way of valve-actuated channel pressures.

Abstract: One or more embodiments of the invention are directed to sample tubes comprising a cylindrical elongate tube having a gripping section with at least one discontinuity extending radially about the outside surface of the elongate tube. Methods of making sample tubes and their use in sample handlers are also described.

Abstract: In embodiments of the present invention, a system and method of cytometry may include presenting a single sperm cell to at least one laser source configured to deliver light to the sperm cell in order to induce bond vibrations in the sperm cell DNA, and detecting the signature of the bond vibrations. The bond vibration signature is used to calculate a DNA content carried by the sperm cell which is used to identify the sperm cell as carrying an X-chromosome or Y-chromosome. Another system and method may include flowing cells past at least one QCL source one-by-one using a fluid handling system, delivering QCL light to a single cell to induce resonant mid-IR absorption by one or more analytes of the cell, and detecting, using a mid-infrared detection facility, the transmitted mid-infrared wavelength light, wherein the transmitted mid-infrared wavelength light is used to identify a cell characteristic.

Abstract: An automated micro-well plate handling device for removing a micro-well plate from within a vertically stacked plurality of micro-well plates and transferring the removable micro-well plate to a receiving area. A vertical storage device for storing the vertically stacked plurality of micro-well plates creates a vertical clearance space between the vertically stacked micro-well plates. A shovel slides into the vertical clearance space underneath the micro-well plate that is being removed. The shovel then removes the micro-well plate from the vertical storage device and places the micro-well plate at a transfer station. A gripper then grabs the micro-well plate from the transfer station and transfers the micro-well plate to a receiving area. In a preferred embodiment, the automated micro-well plate handling device is controlled via a computer network.

Abstract: A device for preparing an undifferentiated cell, the device comprises means for contacting a more committed cell with an agent that causes the more committed cell to retrodifferentiate into an undifferentiated cell.

Abstract: An embodiment of the invention relates to a device for detecting an analyte in a sample. The device comprises a fluidic network and an integrated circuitry component. The fluidic network comprises a sample zone, a cleaning zone and a detection zone. The fluidic network contains a magnetic particle and/or a signal particle. A sample containing an analyte is introduced, and the analyte interacts with the magnetic particle and/or the signal particle through affinity agents. A microcoil array or a mechanically movable permanent magnet is functionally coupled to the fluidic network, which are activatable to generate a magnetic field within a portion of the fluidic network, and move the magnetic particle from the sample zone to the detection zone. A detection element is present which detects optical or electrical signals from the signal particle, thus indicating the presence of the analyte.

Abstract: A sample processing device may include an opening, a sample pretreatment unit, a thermal cycling reaction unit, and a detection unit.

Abstract: One embodiment of the present invention is directed to methods for ionophorically screening pore forming bacterial protein toxins and receptors. The method includes: a) forming a membrane comprising a lipid and a receptor, b) contacting the membrane with the pore forming bacterial protein toxin and an ion solution, and c) measuring ion flow through the membrane.

Abstract: A chemical or biochemical analysis apparatus includes: a computer processor; at least one controller electrically coupled to the computer processor; at least one first base configured with a plurality of dispensing tube assemblies arranged in alignment and electrically coupled to the at least one controller, independently; at least one second base configured with a plurality of the detectors arranged in alignment and electrically coupled to the at least one controller; and a stage, for carrying the at least one multi-well strip having a plurality of wells arranged in alignment and for transporting the multi-well strip to pass through and underneath the plurality of dispensing tube assemblies and the plurality of the detectors arranged in order, electrically coupled to the at least one controller.

Abstract: Provided are a cell culture compartment unit and an array including the same. The cell culture compartment unit includes: a cell culture region and a bio material emission region including a cell culture fluid, which are separated with a porous membrane therebetween; a piezoelectric device on the porous membrane of the cell culture region; a thin layer for cell attachment being on the piezoelectric device and having at least one surface on which cells are attachable; and a first power supply applying a first electric field to the piezoelectric device.

Abstract: A bioreactor (200) for cultivating living cells in a liquid medium. In one embodiment, the bioreactor (200) has a substrate (230) having a first surface and an opposite second surface, defining a channel (202) therein, and a plurality of chambers (204) formed in the substrate, wherein each of the plurality of chambers (204) is adapted for receiving cells in a liquid medium and formed with an open end (262), an opposite closed end (264) and side walls, the open end (262) and the closed end (264) defining a depth, d, therebetween for the corresponding chamber (206), the sidewalls defining a width, w, therebetween for the corresponding chamber (206). As such formed, each chamber (206) is in fluid communication with the channel (202) through the open end of the chamber (206), and at least two of the plurality of chambers (206) have depths or widths the same or different form each other.

Abstract: A centrifugal microfluidic device includes a substrate configured for rotation about an axis, the substrate having a start chamber disposed therein, the start chamber configured to hold a liquid. The device includes an output chamber disposed in the substrate and located radially outward of the start chamber. A fluid transfer channel connects the start chamber to the output chamber. A ventilation channel connects the output chamber to the start chamber, the ventilation channel connecting at one end to a radially inward portion of the start chamber and at an opposing end to a junction point on the output chamber. A vent hole is provided in the substrate that is operatively connected to the output chamber. The location of the junction between the ventilation channel and the output chamber is located radially outward with respect to the level of fluid in the start chamber so as to prevent cross-contamination.

Abstract: A disposable cartridge for use in assaying an analyte in an automated water quality monitoring analyzer comprising: (a) a platform; (b) array of containers for separately containing at least one reagent, a buffer and a so freeze dried preparation of luminescent bacteria, said containers being mounted on said platform; (c) reaction chamber mounted on said platform and configured for being moved between said containers, such that said reagent, said buffer and said freeze dried preparation of luminescent bacteria are conveyed to said reaction chamber in a predetermined sequence such that light detectable by said analyzer is emitted; (d) fluid transferring means for fluid transfer and mixing between said containers, reaction chamber, and analyzer; (e) conveying means for moving said cartridge to predetermined positions within said automated water quality monitoring analyzer for enabling analysis of said analyte.

Abstract: A method for determining a concentration of an analyte is disclosed. The method includes applying a potential excitation to a fluid sample containing an analyte and determining if a current decay curve associated with the fluid sample has entered an analyte depletion stage. The method also includes measuring a plurality of current values associated with the fluid sample during the analyte depletion stage and calculating an analyte concentration based on at least one of the plurality of current values.

Abstract: A system that is suitable for extracting plasma from blood received from a blood supply is provided. The system comprises a housing, an inlet opening for receiving the blood, a filtration chamber comprising a membrane, and a plasma compartment. The membrane forms a barrier between the blood and the plasma extracted from the blood, and the plasma compartment collects the plasma extracted from the blood. In some embodiments, the system comprises a plasma flow path compression chamber for pulling plasma across the membrane. In some embodiments, the system comprises a blood flow path compression chamber for facilitating blood flow. Some embodiments of the system further comprise means for measuring plasma and blood analytes using spectroscopic and biosensor techniques.

Abstract: The application relates to a method, system and device for performing biological assays. The method, system and device allow more accurate and specific detections of biomolecules in multiplex assays, such as immunoassays and DNA microarray assays. More specifically, the embodiments of the invention allow the detection of labels after their detachment or disassociation from a binding situation wherein interference from other labels or the background may reduce the accuracy of specificity of the detection. The embodiments of the invention further allow detection of individual labels.

Abstract: The present technology provides for a heater substrate that contains networks of heater elements configured to controllably and selectively deliver heat to one or more PCR reaction chambers in a microfluidic substrate with which the heater substrate makes contact. In exemplary embodiments, the heater substrate can deliver heat to 12, 24, 48, or 96 chambers independently of one another, or simultaneously. The heater substrate is located in a heater unit that may be introduced into a diagnostic apparatus that can receive and position a microfluidic substrate, such as in a cartridge, in contact with the heater unit, receive one or more polynucleotide containing samples into one or more lanes in the microfluidic substrate, and cause amplification of the polynucleotides to occur, and detect presence of absence of specified polynucleotides in the amplified samples.

Abstract: This invention is a method for determining a concentration of an analyte. The steps include applying a potential excitation to a fluid sample containing an analyte, and measuring a current associated with the potential excitation at a plurality of time-points. The method also includes calculating an analyte concentration based on the measured current and a calibration curve, wherein the calibration curve is selected from a plurality of calibration curves and each calibration curve is associated with a time-segment selected from a plurality of time-segments.

Abstract: Sample processing systems and methods of using those systems for processing sample materials located in sample processing devices are disclosed. The sample processing systems include a rotating base plate on which the sample processing devices are located during operation of the systems. The systems also include a cover and compression structure designed to force a sample processing device towards the base plate. The preferred result is that the sample processing device is forced into contact with a thermal structure on the base plate. The systems and methods of the present invention may include one or more of the following features to enhance thermal coupling between the thermal structure and the sample processing device: a shaped transfer surface, magnetic compression structure, and floating or resiliently mounted thermal structure. The methods may preferably involve deformation of a portion of a sample processing device to conform to a shaped transfer surface.

Abstract: An integrated device for diagnostic analyses used to verify the presence of bacteria in at least a biological sample mixed with a eugonic culture medium in liquid form, to classify at least the type of bacteria, and to test a series of antibiotics, selected from a group of characteristic antibiotics at least for the type of bacteria identified, identifying those effective to determine the antibiotic therapy. The device comprises, inside an integrated structure, first containing means provided with containing elements in which the biological samples to be analyzed are distributed, second containing means comprising recipients or micro-plates thermostated with wells containing a eugonic culture medium in liquid form in which a first fraction of the biological samples to be analyzed is dispensed, and a first recipient and second recipients or plates with a relative first well and second wells in which a further fraction of the biological samples which resulted positive to the analysis is dispensed.

Abstract: An apparatus for transporting sample well trays with respect to a heating device is provided. The apparatus includes a sample well tray holder, a rotational actuator, and a biasing mechanism. The sample well tray holder includes a plate in which a sample well tray may be positioned. The sample well tray holder is configured to rotate about a first rotational axis. The rotational actuator is configured to rotate the sample well tray holder about the first rotational axis. The biasing mechanism is configured to urge the sample well tray holder in a generally upward direction along the first rotational axis.

Abstract: An analysis apparatus includes a first analysis unit which collects samples by utilizing a first nozzle to analyze the sample, a second analysis unit which collects samples by utilizing a second nozzle to analyze the sample, and a transport apparatus which transports a plurality of sample vessels along a predetermined transport route. When a predetermined waiting state is provided such that the transport of the plurality of sample vessels is interrupted or stopped, then the sample collecting position is changed for at least one of the first and second nozzles, and the samples are collected from the plurality of sample vessels by means of the nozzle having the changed position. Accordingly, it is possible to enhance the efficiency of the analysis process performed by the analysis apparatus, while suppressing the transport apparatus from being large-sized and suppressing the structure from being complicated.

Abstract: The invention concerns test elements, in particular diagnostic test elements, for determining the presence or concentration of biological, medical or biologically or medically effective substances including nucleic acids, proteins, viruses, microorganisms and cells, characterized in that these test elements contain nanofibers.

Abstract: The invention refers to a handling kit for analyzing a liquid sample, especially by nucleic acid amplification, comprising a disposable sample holding and processing device (1) dimensioned for use in an apparatus for analyzing a liquid sample, and a sample transfer tip (12) for transferring liquid into the disposable device (1), the disposable device (1) having a sample preparation chamber (10) which has an outlet (9) and an insertion opening (16) which is adapted to receive the sample transfer tip (12), the insertion opening and the sample transfer tip (12) being dimensioned in such a way that inserting the sample transfer tip (12) into an insertion position in the sample preparation chamber (10) causes a tight seal between an outer wall (40) of the sample transfer tip (12) and an inner wall (41) of the sample preparation chamber (10), the disposable device (1) having a vent (31) for venting the sample preparation chamber (10).

Abstract: A biosensor containing ruthenium, measurement using the same, and the application thereof. The biosensor comprises an extended gate field effect transistor (EGFET) structure, including a metal oxide semiconductor field effect transistor (MOSFET), a sensing unit comprising a substrate, a layer comprising ruthenium on the substrate, and a metal wire connecting the MOSFET and the sensing unit.

Abstract: A method for extracting proteins from heterogeneous fluids by precipitation using microfluidics. The method uses an automated protocol for precipitation of proteins onto surfaces, rinsing the precipitates to remove impurities, and resolubilization in buffer for further analysis. The method is compatible with proteins representing a range of different physicochemical properties, as well as with complex mixtures such as fetal bovine serum and cell lysate. In all cases, the quantitative performance (measured using a fluorescent assay for % recovery) was comparable to that of conventional techniques, which are manual and require more time.

Abstract: The present invention relates to methods and devices for the rapid assessment of saliva for the presence of varicella zoster virus (VZV) particles. The methods and devices permit rapid, simple and cost-effective diagnosis of primary VZV infection.

Abstract: Disclosed is a disk based platform for separating and detecting cells that are labeled with immunomagnetic beads. A disk-like carrier board forms therein at least one flow channel structure, which includes an inner reservoir for receiving a sample fluid, an outer reservoir, and a plurality of micro flow channels arranged between and in fluid communication with the inner and outer reservoirs. When the disk-like carrier board spins, cells labeled with immunomagnetic beads are attracted by a magnetic attraction unit that is arranged above the disk-like carrier board and adjacent to the inner reservoir to thereby remain in the inner reservoir, and cells that are not so labeled are acted upon by a centrifugal force induced by the spinning of the disk-like carrier board to flow with the sample fluid from the inner reservoir through the micro flow channels into the outer reservoir.

Abstract: Disclosed herein are compositions, methods, and devices related to bilayer and monolayer membranes, their encapsulation in a hydrogel, and their formation. Methods of using the disclose compositions and devices are also disclosed.

Abstract: A method of detecting a presence of bio-molecules, or a concentration of the target bio-molecules using a field effect transistor, includes allowing a first sample including a first target bio-molecule to contact a sensing surface of the field effect transistor and measuring a change in an electric signal of the field effect transistor, the field effect transistor including a substrate, a source region and a drain region, the source region and the drain region formed apart from each other on the substrate, the source region and the drain region each doped to having an opposite polarity than a polarity of the substrate, a channel region disposed between the source region and the drain region and an insulating layer including the sensing surface, the insulating layer disposed on the channel region.