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: The fluorescence measurement system includes a host apparatus and a self-contained, multichannel optical cartridge. The host apparatus includes a well plate receptacle, and a stage having optical cartridge receptacles that are elongate along one axis of the well plate. The stage and the well plate receptacle are movable relative to one another in the direction of the other axis of the well plate. The optical cartridge engages with the optical cartridge receptacle and includes a linear array of optical assemblies each including an excitation light source, and an emission light detector to generate an intensity signal. The optical cartridge also includes, a memory to store calibration information for each optical assembly. The host apparatus additionally includes a processor to correct the intensity signal from each optical assembly of the optical cartridge using the calibration information received from the optical cartridge for the optical assembly.

Abstract: An apparatus and method to identify at least one component from a plurality of components in a fluid mixture, includes a first input channel containing the fluid mixture of components; at least one buffer input channel, into which at least one additional flow of buffer solution is introduced; a plurality of regions disposed at the other end of the apparatus, which are adapted to receive outputs of at least one selected component of the plurality of components, the selected component which is selectively removed from the first flow to one of the regions; a waste channel through which unselected components are removed from the first flow; a plurality of pumps connected to at least one reservoir, to control flow rates of the first flow and the additional flow(s); and a computer which controls a selection of one of the plurality of components from the fluid mixture.

Abstract: Method and device (1b) for performing the optical analysis of particles (2) contained in suspension in a fluid (3) arranged inside a microfluidic device (4) which maintains it at a temperature significantly lower than the ambient temperature; the formation of humidity on the outer surface (8) of the cover of the microfluidic device is avoided by applying a thermal flow (F) which determines an increase in the temperature of the outer surface (8) of the cover to above the condensation temperature (Td), or a reduction in the ambient temperature (and/or humidity) in the vicinity of the cover (8), so as to bring the condensation temperature (Td) (dew point) to below the temperature of the surface (8) of the cover determined by the internal operating temperature.

Abstract: A filter element (200) and a method are disclosed for retaining particles of a medium, for example (rare) cells of blood. The filter element (200) comprises at least one opening (220) that (i) has an elongate cross section and/or (ii) has a cross section that decreases in flow direction (x) and/or (iii) is bordered by a transparent wall. Preferably, the filter element (100, 200, 300) is provided with a plurality of elongate openings (220) of stepwise decreasing cross section that are arranged on a common transparent slide. Thus high flow rates can be realized throughout the filtering process, and the retained particles are immediately ready for visual inspection without a need for a further transfer.

Abstract: A system and method for measuring at least one bioprocess parameter utilizes a barrier that separates an external sensor from a culture medium. The barrier allows analytes to diffuse in and out of the culture vessel, thereby allowing the bioprocess parameter to be measured non-invasively by the external sensor.

Abstract: The present invention discloses a microinjection apparatus (100) for microinjection of substances into individual substances comprising at least one carrier (120, 130) on which at least one sample is immobilizable. In embodiments, the apparatus comprises at drivable support (110) on which at least one carrier is positioned, wherein the support drives the at least one carrier in a closed loop to a respective plurality of stations along the loop. The plurality of stations constitutes at least one sample-substance-providing station (141), at least one sample-substance microinjection station (142) and at least one sample-extraction station (143).

Abstract: Provided herein are methods and systems for detecting biomolecular binding events using gigahertz or terahertz radiation. The methods and systems use low-energy spectroscopy to detect biomolecular binding events between molecules in an aqueous solution. The detected biomolecular binding events include, for example, nucleic acid hybridizations, antibody/antigen binding, and receptor/ligand binding.

Abstract: A blood cell analyzer comprises a flow cell configured to flow a measurement specimen containing blood cells, a first light source configured to emit light having a first wavelength, a second light source configured to emit light having a second wavelength different from the first wavelength, a first light receiving portion configured to receive first scattered light obtained by irradiating the blood cells passing through the flow cell with light from the first light source, a second light receiving portion configured to receive second scattered light obtained by irradiating the blood cells passing through the flow cell with light from the second light source, and a control section configured to discriminate at least red blood cells from the blood cells contained in the measurement specimen based on detection signals output from the first light receiving portion and the second light receiving portion, respectively.

Abstract: The present invention is comprised of an antibacterial door mat system for cleaning, disinfecting and detection of bacteria and other organisms on footwear to control spread of biological infections and contamination. The present invention is further comprised of an antibacterial door mat that cleans footwear, detects the presence of bacteria and a bio detection clearance door entry system that controls the entry into sterile areas.

Abstract: A test device applies a defined mechanical load to a soft biomaterial such as a cell culture and a microscope forms a volume image data set showing the strain field or displacement field occurring in the medium. The data set is processed to determine fundamental mechanical properties of the cell, its interaction with the surrounding medium, or its responses loading or deformation of its surrounding medium. The device may also be used to calibrate or determine fundamental mechanical properties of the medium. The device includes a linear actuator that bears against the specimen, and adapted for a volume imaging device such as a scanning laser confocal microscope that forms a volume image data set of the specimen. The specimen may be supported in a Petri dish and is preferably imaged from below by an inverted microscope. Preferably the actuator device attaches to or forms the specimen stage of microscope.

Abstract: A blood cell analyzer comprising a flow cell configured to flow a measurement specimen containing blood cells, a first light source configured to emit light having a first wavelength, a second light source configured to emit light having a second wavelength different from the first wavelength, a first light receiving portion configured to receive first scattered light generated by irradiating the blood cells in the measurement specimen with light from the first light source, a second light receiving portion configured to receive second scattered light generated by irradiating the blood cells in the measurement specimen with light from the second light source, and a control section configured to classify at least white blood cells from the blood cells contained in the measurement specimen, based on a detection signal output from the first light receiving portion and a detection signal output from the second light receiving portion.

Abstract: The present invention provides a method for analyzing a cell. The method comprises steps of: regulating a temperature of a medium to a predetermined degree, wherein the cell is preserved in the medium; and obtaining an optical information by irradiating light on the cell.

Abstract: Systems and methods are provided for sample processing. A device may be provided, capable of receiving the sample, and performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing multiple assays. The device may comprise one or more modules that may be capable of performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing the steps using a small volume of sample.

Abstract: Described herein are biosensors for early, pre-symptomatic detection of infectious agents and methods for their use. In particular, this disclosure describes biosensors that utilize toll-like receptor (TLR) binding domains to detect pathogen-associated molecular patterns (PAMPs). Also provided herein are methods of detecting and/or capturing a PAMP from a biological sample using the disclosed biosensors.

Abstract: A measurement apparatus includes: a holding unit that holds at least a specimen to be observed; an illumination unit that emits illumination light to be irradiated to the specimen; a detection unit that is arrangeably provided in the holding unit and detects an intensity of the illumination light on a light irradiation surface of the specimen; a field stop that is formed with an aperture and stops down a field on the light irradiation surface by an image of the aperture that is provided on an optical path of the illumination unit, the aperture through which the illumination light passes and through which an image of the illumination light is projected on the light illumination surface; and a computation unit that computes, based on an area of the aperture and the detected intensity, an intensity of the illumination light per unit area of the light irradiation surface.

Abstract: A self-contained apparatus and methods for detecting the presence of any specified substance in any medium. A sample of the medium is placed in a capsule, along with a solvent and a sensor configured to test for a target analyte. The solvent comes into contact with the medium in the capsule, and the capsule is agitated to create a dispersion in the solvent of a portion of any target analyte present in the medium. A release mechanism configured to cause conduction of the dispersion to the sensor, so that the sensor produces an indication of presence of the target analyte if the target analyte is present in the medium. The apparatus uses a disposable capsule where the medium in question is placed and the disposable capsule is placed inside a reader and analyzed for presence of the harmful substance.

Abstract: The invention generally relates to methods for quantifying an amount of enzyme molecules. Systems and methods of the invention are provided for measuring an amount of target by forming a plurality of fluid partitions, a subset of which include the target, performing an enzyme-catalyzed reaction in the subset, and detecting the number of partitions in the subset. The amount of target can be determined based on the detected number.

Abstract: A particle measuring apparatus comprising a flow cell configured to flow a specimen, a first light source configured to emit light having a first wavelength, a second light source configured to emit light having a second wavelength different from the first wavelength, an irradiation optical system configured to irradiate the flow cell with light emitted from the first light source and the second light source, a first light receiving portion configured to receive scattered light obtained by irradiating a measurement particle passing through the flow cell with light from the first light source, and a second light receiving portion configured to receive scattered light obtained by irradiating a measurement particle passing through the flow cell with light from the second light source.

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: Motion detector comprising a flexible support (1,5) adapted to hold at least one object (6-9), a sensor (4) for measuring the displacement of said support (1) and processing means for differentiating the fluctuations of said support (1) from those induced by said object (6-9).

Abstract: A method for observing stem cells by an observation device 1 comprises, placing stem cells C in a petri dish 11, mounting the petri dish 11 on a waveguide 21 via water 13, emitting illumination light L1 into the waveguide 21 and emitting the illumination light L1 to the stem cells C in the petri dish 11 via the water 13, and detecting scattered light L2, the scattered light L2 being the illumination light L1 emitted to the stem cells C that is scattered by the stem cells C and has passed through the waveguide 21. Then, in the light image detected by means of the scattered light L2, a region that is markedly darker than other regions is identified as being in the state tending toward differentiation.

Abstract: The present invention provides an optical probe apparatus and method for microorganism culture monitoring. The optical probe can be immersed within the microorganisms and include at least one emitter and at least two detectors that excite photosynthetic pigments in the culture medium. The optical probe can measure the culture spectral characteristics, targeting those that are an indication of the healthiness and productivity condition. The optical probe can also include a microcontroller and storage. The microcontroller can compare past measurements of the optical probe with current measurements and determine a health status of the microorganisms. The optical probe is optimized to measure spectral characteristics from the microorganism in real time. The present invention relates to a sensor tune to detect the healthiness condition of photosynthetic microorganisms.

Abstract: A method of fabricating biochip sensor comprising providing a precursor; depositing the precursor on a substrate to form a coating; and rapid melting/quenching treatment of the coating with an energy source to form micro/nanotextured surface with enhanced reflectance for fast chemiluminescence response of E-Coli bacteria.

Abstract: A detection instrument determines whether a specimen container (e.g., blood culture bottle) is positive for presence of microbial agent growth therein. When the container is deemed positive it is made available (e.g, transferred or exposed to) to an automated instrument performing identification and/or characterization of the microbial agent. The identification and/or characterization instrument removes a portion of the sample from the specimen container and places it into a disposable separation and concentration device. The microbial agent is concentrated via optional selective lysis of non-microbial agent cellular material which may be present and centrifugation. A reading module reads the concentrated microbial agent using spectroscopic methods, e.g., measurements of intrinsic fluorescence. Such interrogation may occur while the microbial agent remains concentrated in the disposable device.

Abstract: The invention provides a method of monitoring the response of platelets to a cyclooxygenase-1 (COX1) inhibitor such as aspirin. The method involves collecting platelet-containing mammalian blood treated with a COX1 inhibitor; mixing the blood with a COX1-dependent platelet agonist, such as arachidonic acid, monitoring extracellular ATP in the agonist-activated blood to generate a measurement, and comparing the measurement to a standard value. Devices, systems, and kits for carrying out the method are also provided.

Abstract: Illumination apparatus for illuminating growth plates in a biological growth plate (122) scanner are described herein, the apparatus including one or more illumination modules (140) for illuminating the front surface of the biological growth plate located (122) on a plate support surface (120) in the scanner. The illumination modules may include a plurality of light emitters (142), a homogenization cavity (141), an extraction element and a concentration element to (144), e.g., improve uniformity in the illumination delivered to the biological growth plate (122).

Abstract: Described herein is an apparatus comprising an electrochemical cell that employs a capacitive counter electrode and a faradaic working electrode. The capacitive counter electrode reduces the amount of redox products generated at the counter electrode while enabling the working electrode to generate redox products. The electrochemical cell is useful for controlling the redox products generated and/or the timing of the redox product generation. The electrochemical cell is useful in assay methods, including those using electrochemiluminescence. The electrochemical cell can be combined with additional hardware to form instrumentation for assay methods.

Abstract: Disclosed is a product that includes an optical sensor; a target-responsive hydrogel matrix on a surface of the optical sensor (where the hydrogel matrix comprises one or more target-specific receptors and one or more target analogs), and one or more high refractive index nanoparticles within the hydrogel matrix, where a detectable change occurs in a refractive index of the hydrogel matrix when contacted with one or more target molecules. Sterile packages and detection devices containing the product, and methods of detecting a target molecule using the product, are also disclosed.

Abstract: Systems and methods are provided for imaging at least one eye with optical components and processing the image of the at least one eye to determine radiation exposure. An image of one or more eyes may be received. The systems and methods may distinguish blood cell types in the image; quantify circulating levels of a selected blood cell type; output a number of blood cells per volume of the selected blood cell type; and determine a radiation dose based on the number of blood cells per volume of the selected blood cell type.

Abstract: The present invention provides electrokinetic microfluidic cytometers useful for detecting and/or sorting fluid-borne particles. In some embodiments, the electrokinetic microfluidic flow cytometer apparatus comprises a substrate having a microchannel formed therein, a particle-sensing gate that reduces the cross-sectional area of a portion of the microchannel, a pair of signal- and noise-detection electrodes, and a particle-detection circuit that is electrically connected to the signal- and noise-detection electrodes and is configured to generate a particle-detection signal responsive to differences in resistivity across the particle-sensing gate.

Abstract: A system for imaging captured cells comprising: an illumination module configured to illuminate a target object; a platform configured to position the target object in relation to the illumination module; a filter module configured to filter light transmitted to the target object and/or to filter light received from the target object, an optical sensor configured to receive light from the target object and to generate image data; and a focusing and optics module configured to manipulate light transmitted to the optical sensor. The system can further comprise one or more of: a control system configured to control at least one of the illumination module, the platform, the focusing and optics module, the filter module, and the optical sensor; a tag identifying system configured to identify and communicate tag information from system elements; a thermal control module configured to adjust temperature parameters of the system; and an image stabilization module.

Abstract: The present disclosure relates to an optical fluorescence sensor comprising a probe for sensing glucose, an intra-reference probe, and a matrix. The present disclosure also relates to an optical fluorescence dual sensor comprising a probe for sensing glucose, a probe for sensing oxygen, an intra-reference probe, and a matrix. The present disclosure additionally relates to methods of preparing these sensors and methods of using them.

Abstract: A fine particle measuring apparatus is provided. The fine particle measuring apparatus includes a detection unit configured to detect light emitted from a fine particle and a processing unit having a memory device storing instructions which when executed by the processing unit, cause the processing unit to calculate a corrected intensity value of the detected light and generate spectrum data based on the corrected intensity value.

Abstract: An apparatus sensing two or more reactants or analytes in a sample is provided. The apparatus has an one or more light sources emitting energy with two or more detection targets having an immobilized reagent within the target surface. One or more detectors are provided where the two or more detection targets having immobilized reagent thereon are in communication with the sample and the immobilized reagent interacts with the sample. Energy is incident on the targets from the at least one light source such that the energy is changed by the interaction and the change is in turn detected by the at least one detector and associated with a measurement of the level of the reactant or analyte in the sample. A method of making a sensing apparatus and a method of sensing using the sensing apparatus are also disclosed.

Abstract: The present disclosure relates to apparatus, systems, compositions, and methods for analyzing a sample containing particles. In some aspects the system comprises an analyzer which may be a visual analyzer. In one aspect, this disclosure relates to a particle imaging system comprising a flowcell through which a sample containing particles is caused to flow, and a high optical resolution imaging device which captures images for image analysis of samples. Other compositions, methods and features of this disclosure are disclosed herein.

Abstract: A sensor system in a water treatment system has a housing, controller, one or more light sources, one or more sensors and one or more targets having an immobilized reagent thereon. Light source emits light energy into the housing that is incident upon the target with the immobilized reagent and the reagent being in contact with water from the system. The immobilized reagent interacts with a reactant in the water such that the interaction changes the state of the reagent. When energy from the light source is incident on the target with the immobilized reagent the energy shows a change detectable by the sensor such that the changed energy is detectable by and collected at the sensor and data on the energy is communicated to the controller. The data is then correlated as a representation of a desired variable to be measured for the water in the water treatment system.

Abstract: Devices, systems and methods including a sonicator for sample preparation are provided. A sonicator may be used to mix, resuspend, aerosolize, disperse, disintegrate, or de-gas a solution. A sonicator may be used to disrupt a cell, such as a pathogen cell in a sample. Sample preparation may include exposing pathogen-identifying material by sonication to detect, identify, or measure pathogens. A sonicator may transfer ultrasonic energy to the sample solution by contacting its tip to an exterior wall of a vessel containing the sample. Multipurpose devices including a sonicator also include further components for additional actions and assays. Devices, and systems comprising such devices, may communicate with a laboratory or other devices in a system for sample assay and analysis. Methods utilizing such devices and systems are provided. The improved sample preparation devices, systems and methods are useful for analyzing samples, e.g. for diagnosing patients suffering from infection by pathogens.

Abstract: For analyzing a sample containing particles of at least two categories, such as a sample containing blood cells, a particle counter subject to a detection limit is coupled with an analyzer capable of discerning particle number ratios, such as a visual analyzer, and a processor. A first category of particles can be present beyond detection range limits while a second category of particles is present within respective detection range limits. The concentration of the second category of particles is determined by the particle counter. A ratio of counts of the first category to the second category is determined on the analyzer. The concentration of particles in the first category is calculated on the processor based on the ratio and the count or concentration of particles in the second category.

Abstract: The invention provides a system of heavy metal sequestration by bacteria. The bacteria expresses the ppk, mt, and/or ?-galactosidase (lacZ) genes and can tolerate at least 25 ?M mercury, 1,000 ?M zinc, 250 ?M cadmium, and 3,000 ?M Pb. The system allows for facile determination of the presence of heavy metal contaminants in a liquid and the facile collection of the bacteria that has sequestered large amounts of heavy metal. Further provided is a system of gene expression in bacteria that comprises phage and plastid gene expression elements and delivers a particularly high level of protein expression and heavy metal resistance.

Abstract: An apparatus including at least one of a stainer module and a coverslipper module; an imaging module; a storage module; an automated transport module for transporting at least one slide between at least one of the stainer module and the coverslipper module, the imaging module and the storage module; and a controller. A method including processing at least one slide; determining whether an imaging module is available for imaging of a biological specimen on the at least one slide; transporting the at least one slide to the imaging module using an automated transport module; and transporting the at least one slide to a storage module using the automated transport module when it is determined that the imaging module is not available. A system including a processing module for processing at least one slide including a biological specimen thereon. A machine readable medium.

Abstract: This disclosure relates to a system for sorting sperm cells in a microfluidic chip. In particular, various features are incorporated into the system for aligning and orienting sperm in flow channels, as well as, for determining sperm orientation and measuring relative DNA content for analysis and/or sorting.

Abstract: Particles such as blood cells can be categorized and counted by a digital image processor. A digital microscope camera can be directed into a flowcell defining a symmetrically narrowing flowpath in which the sample stream flows in a ribbon flattened by flow and viscosity parameters between layers of sheath fluid. A contrast pattern for autofocusing is provided on the flowcell, for example at an edge of a rear illumination opening. The image processor assesses focus accuracy from pixel data contrast. A positioning motor moves the microscope and/or flowcell along the optical axis for autofocusing on the contrast pattern target. The processor then displaces microscope and flowcell by a known distance between the contrast pattern and the sample stream, thus focusing on the sample stream. Blood cell images are collected from that position until autofocus is reinitiated, periodically, by input signal, or when detecting temperature changes or focus inaccuracy in the image data.

Abstract: Electrokinetic devices and methods are described with the purpose of collecting assayable agents from a dielectric fluid medium. Electrokinetic flow may be induced by the use of plasma generation at high voltage electrodes and consequent transport of charged particles in an electric voltage gradient. Pulsed DC fields applied to electrodes result in enhanced flow by synchronizing the pulses between successive electrodes. The agents are directed by creation of an electrokinetic potential well, which will effect their capture on to an assay device.

Abstract: Methods, devices, systems, and apparatuses are provided for the image analysis of measurement of biological samples.

Abstract: Aspects of the invention include WBC analysis reagents, systems and methods that can be used for analyzing a sample of whole blood to identify, classify, and/or quantify white blood cells (WBC) and WBC sub-populations in the sample. The WBC analysis reagents of the present disclosure generally include at least one membrane-permeable fluorescent dye, a WBC protecting reagent, and a surfactant. In some embodiments, the WBC reagents include a suitable amount of an osmolality adjusting component to adjust the osmolality of the WBC reagent into a desired range.

Abstract: Aspects of the invention include hematology analysis reagents, systems and methods that can be used to preserve blood cell morphology and integrity as well as provide sample integrity and optical clarity to facilitate optical analysis of blood samples. In some embodiments, the reagents include a non-phosphate organic buffer and a sphering surfactant. The pH and osmolality of the reagents may be adjusted to desired ranges. In addition, the reagents can be simply diluted with de-ionized water prior to use.

Abstract: Screening assays and methods of performing such assays are provided. In certain examples, the assays and methods may be designed to determine whether or not two or more species can associate with each other. In some examples, the assays and methods may be used to determine if a known antigen binds to an unknown monoclonal antibody.

Abstract: A substrate of a target substance-detecting element for detecting a target substance in a specimen based on localized surface plasmon resonance comprises a supporting member and a metal nano-dot group provided on the supporting member, metal nano-dots each of which is comprised in the metal nano-dot group and adjacent to each other are arranged with a gap between the metal nano-dots of not larger than 30 nm.

Abstract: The invention provides devices and methods for isolating one or more sample components of a sample material following separation of the sample material into a plurality of sample components. A device includes a separation channel having a sample loading well. A low-conductivity buffer is disposed in the loading well, the buffer having a conductivity<0.2 mS/cm. In a method, a buffer is loaded into a loading well in fluid communication with a separation channel of a device. A sample material having a conductivity higher than that of the buffer is then loaded into the loading well such that the sample material is disposed beneath the buffer, the buffer disposed over and covering the sample material. The sample material is separated into a plurality of separated components in the separation channel, and a separated component is collected from a collection well disposed in a collection leg of the device.