Abstract: A specimen collection container having a separation chamber includes a first chamber, a second chamber, and a valve located between the first chamber and the second chamber. In an open position, the valve permits fluid communication between the first chamber and the second chamber. In a closed position, the valve maintains fluid isolation between the first chamber and the second chamber. A fluid stream passes from the first chamber to the second chamber through the valve permitting a predetermined volume of fluid to pass from the first chamber to the second chamber. When the predetermined volume of fluid passes to the second chamber, the valve transitions from the open position to the closed position so that additional fluid of the fluid stream received by the first chamber is maintained in the first chamber in fluid isolation from the predetermined volume of fluid contained in the second chamber.

Abstract: A method of operating a tissue processor for processing tissue samples. The tissue processor includes at least one retort for receiving tissue samples, at least one container for storing a reagent, and at least one sensor arranged for fluid communication with one or both of the at least one container and the at least one retort for measuring a measured purity level of a reagent. The method includes conducting reagent from the at least one container or the at least one retort to the at least one sensor, automatically measuring a measured purity level of the reagent, checking whether the measured purity level meets a predetermined purity level of the reagent associated with the at least one container, and thereby automatically determining whether the reagent is suitable for processing tissue samples in the tissue processor. Also, a tissue processor for processing tissue samples and a container for storing tissue samples.

Abstract: The present invention relates to excision of explant material comprising meristematic tissue from seeds, and storage of such material prior to subsequent use in plant tissue culture and genetic transformation. Methods for tissue preparation, storage, and transformation are disclosed, as is transformable meristem tissue produced by such methods, and apparati for tissue preparation.

Abstract: A DNA or genome sequencing structure is disclosed. The structure includes an electrode pair, each electrode having a tip-shaped end, the electrodes separated by a nanogap defined by facing tip-shaped ends; at least one conductive island deposited at or near each tip-shaped end; and a biomolecule having two ends, each end attached to the conductive islands in the electrode pair such that one biomolecule bridges over the nanogap in the electrode pair, wherein nucleotide interactions with the biomolecule provides electronic monitoring of DNA or genome sequencing without the use of a fluorescing element.

Abstract: An impeller includes a hub and a plurality of blades. The blades are connected with the hub. Each blade includes a base part connected with the hub and a tip part opposed to the base part. The thickness of the tip part of the blade is greater than that of the base part of the blade. In addition, an airflow-guiding part is disposed at the tip part of the blade.

Abstract: A method of drying a biological sample disposed on a substrate is provided. The method comprises providing the substrate comprising a sample loading area and a heat source; activating the heat source for generating heat; heating the substrate at least above 65° C.; and drying the biological sample. A device for storing sample is also provided, wherein the device comprises a substrate for biological sample-storage; and a heating component that generates heat to maintain a temperature of at least above 65° C. The heating component may contain one or more reagents, wherein the reagents generate heat to maintain a temperature of at least above 65° C.

Abstract: The present invention provides methods for preventing clumping of cells in microfluidic devices by addition of diazolidinyl urea (DU). DU can be added to samples at the time of collection or can be added to samples post-collection. DU can also be pre-added to sample collection devices.

Abstract: A method for the storage of biological samples is disclosed. The method includes the steps of coupling a storage device to a biological sample collection apparatus capable of collecting a biological sample from a subject, introducing a biological sample from the biological sample collection apparatus to the storage device, and drying the biological sample on the storage device. In another embodiment, the storage device used by the method may include a collection medium having a top surface, a bottom surface, and a predetermined size and shape, the top surface comprising a position marker and at least one binding site operable to bind a biological sample; and a protective facing substantially impermeable to the biological sample, the protective facing coupled to the top surface of the collection medium and having a size and shape substantially similar to the predetermined size and shape of the collection medium.

Abstract: Disclosed is a method of providing a risk evaluation and diagnosis of human cancer, by examining the presence, in the volatile fraction of a human saliva sample, of a combination of particulate biochemical volatile organic compounds, which is indicative of an increased risk of developing cancer.

Abstract: Provided is a system and method for staining of one or more samples, including providing one or more self-contained sample processing receptacles, each of the one or more self-contained sample processing receptacles configured to be inserted into an auto-staining instrument; and enabling one of one or more staining procedures appropriate for the one or more samples as a function of a choice of self-contained sample processing receptacle, each of the one or more self-contained sample processing receptacles configured to process each inserted sample of the one or more samples within the self-contained sample processing receptacle.

Abstract: A sample collection device having a sample tube, funnel, and cap having a capsule and a piercing insert, the capsule having a stabilization solution. After depositing the sample into the tube via the funnel, the cap is screwed onto the tube, piercing the capsule and releasing the stabilization fluid into the tube. The device can be used at home without clinicial supervision for collecting a saliva sample and transporting the sample to an analysis location for DNA analysis.

Abstract: Nanoporous materials can be used to enrich samples for subsequent analysis of substances contained in the sample. The method is shown to enrich the yield of species in the low molecular weight proteome, allowing detection of small peptides in the low nanomolar range.

Abstract: Provided herein is an all-in-one saliva collection apparatus that collects saliva to allow for the filtration of saliva in order to separate saliva components, such as extracellular proteins and nucleic acids that are not present in intact cells, from the intact cells and debris remaining in the extracted sample. The filtered saliva samples can be aliquoted into two fractions for protein and/or nucleic acid analysis. The present invention further describes long term storage at ambient temperatures of filtered salivary nucleic acids, and long term storage at ambient temperatures of filtered salivary proteins added to an ethanol solution. The filtered cell-free saliva samples have diagnostic usefulness.

Abstract: Methods, systems and their components for monitoring fluorescent signals and particularly transient fluorescent signals from reaction mixtures of interest, which methods and systems employ modulated excitation light sources to reduce impacts of excessive illumination on the reaction components or the data obtained therefrom.

Abstract: The invention relates to a method for treating a biological sample, comprising the following method steps: i) preparation of a biological sample and ii) bringing the biological sample into contact with a composition, comprising: (1) 1 to 100 wt. % of at least one polyol and (2) 0 to 99 wt. % of at least one additive, wherein the total amount of components (1) and (2) is 100 wt. %. The invention further relates to biological samples obtained by said method, a method for analysis of a treated biological sample, devices for treating a biological sample, use of said devices, various kits and use of a composition.

Abstract: A method for providing a dried reagent in a microfluidic system is provided, the method comprising the following steps: providing a microfluidic system having a microfluidic structure, introducing a flowable carrier medium containing a reagent in the microfluidic structure, and drying the reagent in the microfluidic structure by lyophilization.

Abstract: Various aspects of the present invention relates to the control and manipulation of fluidic species, for example, in microfluidic systems. In one aspect, the invention relates to systems and methods for making droplets of fluid surrounded by a liquid, using, for example, electric fields, mechanical alterations, the addition of an intervening fluid, etc. The invention also relates to systems and methods for fusing droplets according to another aspect of the invention, for example, through charge and/or dipole interactions. In some cases, the fusion of the droplets may initiate or determine a reaction. In still another aspect, the invention relates to systems and methods for sorting droplets, e.g., by causing droplets to move to certain regions within a fluidic system. Examples include using electrical interactions (e.g., charges, dipoles, etc.) or mechanical systems (e.g., fluid displacement) to sort the droplets.

Abstract: Automated sample processing systems may include onboard efficient high-speed mixing of at least two components with an automatic vertical force fluidic turbulent component mixer of which a mixed component may be aspirated and high-speed dispensed in a mixing vial. Other aspects may include single sweep applying a multi-treatment cleaning cycle to at least one slide. A multi-treatment cleaning cycle may include a washing treatment and a drying treatment. In yet other aspects the present invention may include an automated recovery sample processing system with the capability of detecting at least one immediate condition of a fortuitously terminated automatic sample processing run and perhaps even an automatic terminated sample processing run reconstruction calculator.

Abstract: Chlorine dioxide solutions are stabilized and prepared for storage, transportation, and testing. Each solution is separated into two samples. Chlorine dioxide is removed from one sample and then each sample is stabilized and prepared such that each sample contains only oxidized and/or reduced forms of chlorine dioxide. The stable samples may be stored, transported, and tested for chlorine dioxide. The samples are tested for the oxidized and/or reduced forms of chlorine dioxide by known methods, and mass balance equations are used to determine the concentration of chlorine dioxide in the original sample before stabilization and preparation.

Abstract: A method of drying a biological sample disposed on a substrate is provided. The method comprises providing the substrate comprising a sample loading area and a heat source; activating the heat source for generating heat; heating the substrate at least above 65° C.; and drying the biological sample. A device for storing sample is also provided, wherein the device comprises a substrate for biological sample-storage; and a heating component that generates heat to maintain a temperature of at least above 65° C. The heating component may contain one or more reagents, wherein the reagents generate heat to maintain a temperature of at least above 65° C.

Abstract: This invention concerns a sampling procedure for an aqueous hydrosoluble polymer solution flowing in a main circuit, enabling a sample to be collected to undergo at least one analysis under ambient air giving at least one property of the hydrosoluble polymer characterised in that a stabilizing solution is added to the aqueous hydrosoluble polymer solution, according to a discontinuous addition method, before or after sampling from the main circuit, so as to obtain a sample comprising a mixture of aqueous hydrosoluble polymer solution and stabilizing solution in which the hydrosoluble polymer is protected against attacks it may undergo in an atmosphere containing at least 10% by volume of oxygen.

Abstract: The present invention concerns a contamination barrier 5 that permits an efficient and reproducible processing of a high number of samples with the prevention of contamination of aqueous solutions 3 in open and/or automated systems, especially in the ppm range, in that it comprises at least one water immiscible hydrocarbon compound. In addition a method for the prevention of contamination during the processing of aqueous solutions 3 in open and/or automated systems is disclosed.

Abstract: An automated sample processing system having a sample input adapted to simultaneously receive a number of sample containers, a reagent input adapted to receive one or more new reagent supplies, a consumable input adapted to receive one or more new consumable supplies, a solid waste output adapted to receive used consumable supplies, a liquid waste output adapted to receive one or more used reagent supplies, and a processing center. The processing center includes a decapper adapted to remove a lid from at least one sample container, an aspirator adapted to remove a specimen from the at least one sample container and transfer the specimen to an output vessel, and a capper adapted to replace the lid on the at least one sample container.

Abstract: The invention relates to an arrangement for drying of biological samples on a sample storage substrate, comprising at least one sample storage substrate holder and at least one chemical heat pad.

Abstract: A method of cryopreserving sperm cells which may include cooling the quantity of sperm cells to a holding temperature, maintaining the sperm cells substantially at the holding temperature for a period, and supercooling the sperm cells by cooling the sperm cells at a first cooling rate to a temperature that approaches a critical temperature zone at which ice crystal formation and changes in osmotic pressure damage sperm cells and then cooling the sperm at a second cooling rate faster than said first cooling rate through said critical temperature zone.

Abstract: Methods for the preparation of cell compositions based on fluorescence following excitation at wavelength of or about 488 nm and isolated cell compositions obtained therefrom wherein isolated cells exhibit (i) autofluorescence at or about 520 nm or (ii) absence of fluorescence at or about 520 nm and a positive shift in the fluorescence detected at >630 nm. These methods provide for enrichment of immature or stem cancer-initiating cells from tumors (notably, cancers of the central and peripheral nervous system and metastasis to the brain) and methods for screening antitumor agents using the same. Also provided are methods of detecting immature or stem cancer-initiating cells in a cell sample and methods of detecting recurrence of cancer stem cells in a cancer stem cell sample following treatment with an agent.

Abstract: A method for transporting in a microfluidic conduit an aliquot of a liquid, possibly containing a substance I, which is dissolved in the liquid and typically exhibits charged groups and/or hydrophobic groups. The method is characterized in that the liquid contains an amphiphilic macromolecular substance.

Abstract: The present invention concerns a method for the detection of an analyte in a droplet of fluid comprising the steps of providing a solid phase with a hydrophobic surface comprising at least one capture zone on which at least one binding agent with affinity for the analyte is immobilized, applying said droplet to the surface of said solid phase, applying a force that makes the droplet travel along the surface of said solid phase along a predetermined path thereby allowing the droplet to repeatedly contact said binding agent on the capture zone, applying conditions wherein said analyte is allowed to bind to said binding agent and detecting a complex of analyte and binding reagent at the position of the capture zone. The effect of a moving droplet is that the reactants in the droplet are well mixed which eliminates the risk of diffusion limitation. Such advantageous mixing is not obtained with conventional assays in which the surface is continuously exposed to the liquid.

Abstract: Hemoglobin in a sample solution is quickly and reliably denatured; at the same time, quick and accurate measurement of hemoglobin and a hemoglobin derivative is realized. In a method for measuring hemoglobin and a hemoglobin derivative, and a reagent composition, a measurement kit, an analysis device, and an analysis system used in the method, a sample solution containing a blood component is treated with a nonionic surfactant, an oxidizing agent, and a metal salt to denature hemoglobin in the sample solution to measure the hemoglobin, and thereafter the amount of a hemoglobin derivative in the sample is measured by an immunological method using an antibody specifically binding to a denatured site of the denatured hemoglobin derivative.

Abstract: The present invention relates to fluidic devices for preparing, processing, storing, preserving, and/or analyzing samples. In particular, the devices and related systems and methods allow for preservation or storage of samples (e.g., biospecimen samples) by using one or more of a bridge, a membrane, and/or a desiccant.

Abstract: An automatic method for identifying biological samples that are collected using the wrong blood preservative for subsequent analytical testing. The method also provides for identification and/or suppression of certain analytical test results that are substantially or partly adversely affected. The invention is particularly suited for use in point-of-care medical diagnostic testing.

Abstract: An interface is provided for storing microfluidic samples in a nanoliter sample chip. A fluid access structure provides a fluid access region to a selected subset of sample wells from an array of sample wells. A fluid introduction mechanism introduces a sample fluid to the fluid access region so that the sample wells in the selected subset are populated with the sample fluid without the unselected sample wells being populated with the sample fluid.

Abstract: The present invention relates to a buffering composition, more closely a composition comprising porous matrix-enclosed buffering agent(s) giving a stabilisation of pH when applied in for example aqueous environment. The composition comprises buffering agent(s) enclosed in a first porous matrix with an impenetrability corresponding to a fractionation range for globular proteins and peptides of <10000 g/mol, preferably <5000 g/mol, more preferably <700 g/mol.

Abstract: This invention relates, inter alia, to detecting and/or measuring succinylacetone and one or more additional biological analytes using mass spectrometry, e.g., tandem mass spectrometry, by derivatizing succinylacetone in a sample by contacting the sample with an extraction solution comprising a C1-3 linear or branched chain monoalcohol and a strong base selected from the group consisting of hydrazine, a modified hydrazine, and hydroxylamine.

Abstract: A sample handling method may include drawing an encapsulating liquid from an encapsulating-liquid input; discharging the drawn encapsulating liquid (a) onto a free surface of a carrier liquid in a carrier-liquid conduit comprising a stabilisation feature and (b) proximate to the stabilisation feature, the encapsulating liquid being immiscible with the carrier liquid, so that the discharged encapsulating liquid does not mix with the carrier liquid, floats on top of the carrier liquid, and is immobilised by the stabilisation feature; drawing a sample liquid from a sample-liquid input; and discharging the drawn sample liquid, the sample liquid being immiscible with the encapsulating liquid and with the carrier liquid, so that the sample liquid does not mix with the encapsulating liquid or with the carrier liquid.

Abstract: A filter assembly is provided for collecting samples in a fluid environment, the assembly utilizing a laminar convective flow to cause the flow of a preservative/fixative and a filtrate through a filter. A substantially concave dead space around the filter is flushed free of the preservative and the differential in density of the preservative and filtrate causes the more dense fluid to collect in the reservoir and preserve the collected specimen.

Abstract: The present invention relates to methods for the collection of a sample from faecal material and, further, the detection of occult blood in or on the faecal material via the testing of the sample collected from the faecal material. The present invention also relates to collection methods comprising the use of a brush-like device having flexible or semi-flexible bristles wherein the brush-like device is contacted to the faecal material. The present invention also relates to detection of occult blood from the sample collected from the faecal material by means of a guaiac test or immunochromatographic test. The present invention additionally relates to the detection of one or more indicators of a pathological condition in or on the faecal material from which the sample is derived.

Abstract: A method for operating a tissue processor is described. During the operation of a tissue processor a reagent is fed from a container into a retort of the tissue processor, which retort does not contain any tissue samples. Thereafter, the reagent is returned into the container. During feeding, returning and/or in between feeding and returning a measured value is detected by a sensor of the tissue processor. This value is representative of a concentration of the reagent. During this feeding, this returning and/or in between no tissue sample is placed in the retort.

Abstract: A synthetic urine solution is described. The synthetic urine solution is a shelf stable, food grade composition formed of water having a pH between 3 and 10. A thickening agent is dissolved within the water to form a solution having a specific gravity between 1.025 g/cm3 and 1.225 g/cm3. To provide a realistic appearance and odor, a coloring agent and urea are dissolved within the solution. Finally, to provide a shelf stable product, a preservative is also dissolved within the solution.

Abstract: A new type of asymmetric flow field flow fractionator, A4F, is described permitting improved sample fractionation means by providing a range of available channel lengths within the same A4F unit. With such an apparatus, samples may be optimally separated by performing such fractionations as a function of channel length. The ability to vary channel length within the same A4F unit has heretofore been unavailable.

Abstract: An automated assay processing method including transferring a first number of samples from respective sample containers to a first intermediary vessel, determining the testing adequacy of a second number of samples in a second intermediary vessel, preparing a third number of samples in a third intermediary vessel for downstream testing; and transferring a fourth number of samples from a fourth intermediary vessel to an output sample tray. These steps are all performed essentially simultaneously within the duration of a single clock cycle and are repeated during one or more subsequent clock cycles. The clock cycle may be relative to each intermediary vessel. The clock cycle also may be universal to the first, second, third and fourth intermediary vessels.

Abstract: A container for use in processing a biopsy sample. Biopsy sample and materials are received within a sample processing area of the container. A semi-permeable barrier is positioned at a downstream portion of the sample processing area and prevents the prevent passage of the biopsy sample. A cap is positioned at the downstream side of the barrier, and holds fluids within the container.

Abstract: Systems and methods of biomarker analysis. In at least one embodiment of a system for determining the therapeutic potential of a therapeutic compound the present disclosure, the system comprises a detection platform, a computer database capable of receiving a plurality of binding characteristics, a processor operably coupled to the computer database and the detection platform. In at least one embodiment, the processor has and executes a software program operational to determine a binding characteristic of the detection agent and a stabilized diagnostic agent in each of the plurality of detection sites, compare the binding characteristic among each of the plurality of detection sites, wherein the comparison of binding characteristics is capable of determining the stabilizing agent with the greatest effect on the binding characteristic between the detection agent and the diagnostic agent, generate a binding record using the compared binding characteristics, and deliver the binding record to a recipient.

Abstract: The present invention relates in one aspect to a method for determining the cell culture history of a cell unit labelled with more than one type of tag comprising the steps of: (a) measuring one or more parameters of each tag that is used to label the cell unit; (b) identifying each tag in the cell unit; and (c) correlating the identity of each tag to the identity of the cell unit and/or the specific cell culture conditions to which the cell unit has been exposed.

Abstract: At least one embodiment of a stabilizing system includes a stabilizing agent present in an amount or concentration sufficient to completely or substantially prevent or reduce degradation or inactivation of a glycosylated hemoglobin (HbA1c) in a body fluid and a detection agent capable of detecting the HbA1c.

Abstract: The embodiments of the invention described herein relate to systems and methods for the vitrification of biological samples. Vitrification is achieved by generating nanodroplets of a solution comprising the biological sample with a means that can be automated and adapted to high-throughput applications.

Abstract: A microfluidic system and method for sorting cell clusters, and for the continuous and automated encapsulation of the clusters, once sorted, in capsules of sizes suitable for those of these sorted clusters is provided. The microfluidic system comprises a substrate in which a microchannel array comprising a cell sorting unit is etched and around which a protective cover is bonded, and the sorting unit comprises deflection means capable of separating, during the flow thereof, relatively noncohesive cell clusters, each of size ranging from 20 ?m to 500 ?m and of 20 to 10 000 cells approximately, such as islets of Langerhans, at least two sorting microchannels arranged in parallel at the outlet of said unit being respectively designed so as to transport as many categories of sorted clusters continuously to a unit for encapsulation of the latter, also formed in said array.

Abstract: Tempering of sample (58) in test strip (37) is carried out by temperature regulating unit (40) and heating/cooling unit (92). The sample is fed to the test strip by a developer fluid (57) and a metering unit (55). The result of the detection reaction becomes visible by a change in color (36), which is detected optically and analyzed. The data of a control chart (52) with the measured values of first and second temperature sensors (41, 42) are used to set the control parameters for tempering. Code (86) on the test sample holder (35) is read in a sequence of steps. Parameters for phases of the measurement are determined from measured values of first and second temperature sensors, values of the control chart and the code of the test sample holder. These parameters are used by the temperature regulating unit during the measurement.

Abstract: An automatic method for identifying biological samples that are collected using the wrong blood preservative for subsequent analytical testing. The method also provides for identification and/or suppression of certain analytical test results that are substantially or partly adversely affected. The invention is particularly suited for use in point-of-care medical diagnostic testing.

Abstract: The invention discloses a method and apparatus for forming the doped cryo-biology specimen of electron microscope. The invention applies rapid cryogenic freezing to the biology specimen, and dopes certain concentration of protons and electrons into the cryo-biology specimen for conducting the observation using electron microscope. The invention reduces the radiation damage of cryogenic biology specimen and amorphous ice caused by the electron radiation, and observes the prototype of biomolecules and biomaterials clearly.