Abstract: The present disclosure provides a method of separating cellular particles from a tissue sample and then sorting the cellular particles into two or more cellular particle populations.

Abstract: Mesofluidic devices for culturing cell aggregates and methods of using the same are disclosed. An exemplary mesofluidic device comprises at least one fluid inlet, at least one fluid outlet, a plurality of fluid channels, and a plurality of culture chambers. Each culture chamber can comprise at least one chamber inlet and at least one chamber outlet. The at least one chamber inlet can be in fluid communication with the at least one fluid inlet via at least one of the plurality of fluid channels. The at least one chamber outlet can be in fluid communication with the at least one fluid outlet via at least one of the plurality of fluid channels. The mesofluidic device can be configured to contain a cell aggregate in each of the plurality of culture chambers.

Abstract: Techniques for quantitative colorimetric liquid analysis with color and turbidity correction are provided. In one aspect, an optical detector includes: a vessel for containing a liquid sample; a light source on a first side of the vessel; a first sensor on a second side of the vessel opposite the first side and along a light path of the light source; and a second sensor on a third side of the vessel at an angle ? with respect to the light path. A method for quantitative measurement of an analyte is also provided, as is a method for color and turbidity analysis.

Abstract: There is provided a composition for separating blood serum or blood plasma that can inhibit bubbling during sterilization, and can inhibit the occurrence of phase separation during storage. The composition for separating blood serum or blood plasma according to the present invention comprises a (meth)acrylic acid ester-based polymer, a silica fine powder, and a silicone oil, wherein the (meth)acrylic acid ester-based polymer has fluidity at room temperature, and has a weight average molecular weight of 15000 or more and 100000 or less.

Abstract: There is a described a patch-clamp chip for making electrical measurements on a biological sample. The patch-clamp chip comprising a plurality of layers comprising poly-dimethylsiloxane (PDMS) forming a stack. It comprises at least a chip surface layer comprising an aperture formed therethrough and which upwardly opens on the surface, where the biological sample is provided. A microfluidic channel layer comprising PDMS extends below the plane of the chip surface layer and comprises a microfluidic channel formed therein. The aperture of the chip surface layer downwardly opens on the microfluidic channel. Electrophysiological measurements are made between an internal solution in the microfluidic channel and the external solution on the chip surface. The measurements can be performed via a bottom electrode. A plurality of apertures and corresponding microfluidic channels can be provided to perform simultaneous measurements on a plurality of samples, independently.

Abstract: Provided is a microfluidic device capable of removing microbubbles in a channel by using a porous thin film, the microfluidic device comprising: an upper panel comprising a microfluidic channel through which a fluid passes; a porous thin film attached to the bottom surface of the microfluidic channel so as to remove microbubbles included in the fluid that passes through the microfluidic channel; a lower panel contacting the bottom surface of the porous thin film and the upper panel, a path being provided in the lower panel so as to discharge microbubbles, which pass through the porous thin film, to the outside; and a vacuum-suctioning means for vacuum-suctioning the upper panel and the lower panel such that the microfluidic channel, to which the porous thin film is attached, is attached to the lower panel in a vacuum state.

Abstract: The present invention provides an indicator useful in confirming successful sterilisation and/or nucleic acid decontamination by ethylene oxide (EtO) treatment. The invention also provides a label comprising said indicator and methods for use of the indicator and label in a method of EtO treatment.

Abstract: A fluid handling system includes a fluid handling device including an opening for introducing a fluid or discharging the fluid; a tube including a flange, where one end of the tube is for connection to the opening, and the other end of the tube is for connection to an introduction device for supplying the fluid or to a discharge device for discharging the fluid; a support member including a first through hole into which the tube is inserted, and movably supporting the tube; and a first elastic member including a second through hole into which the tube is inserted, and holding a part of the tube while the first elastic member is in contact with the flange and the fluid handling device or the support member.

Abstract: Microfluidic network device (2) configured to supply reagents to a biological tissue sampling device (1), comprising a plurality of microfluidic inlet channels (12) connected to respective sources of said reagents, at least one common outlet channel (22), and a plurality of valves (36) interconnecting an outlet end (14) of each of said plurality of inlet channels to said at least one common outlet channel.

Abstract: A cartridge assembly, and method of using the same, is provided. The assembly includes a sample processing card and a substrate attached thereto. The card has an injection port for receiving a test sample; at least one metering chamber; a mixing material source for introducing mixing material(s) to the metering chamber; fluid communication channels fluidly connecting the injection port and the mixing material source to the metering chamber; and at least one output port for delivering the test sample to a sensor (e.g., GMR sensor). The substrate has associated therewith: the sensor for sensing analytes in the test sample; electrical contact portions for an electrical connection with a reader unit; and a memory chip. The assembly further includes a pneumatic interface with port(s) and corresponding communication channel(s) fluidly connected to card.

Abstract: The present application concerns in-situ intrusive probe systems and methods. The probe systems described herein can be installed flush to a hydrocarbon containing structure, such as a pipeline, vessel, or other piping system carrying crude, gas or sour products. The probe systems include hydrogen induced cracking (HIC)-resistant microstructure such that as atomic hydrogen permeates the probe surface, the probe captures recombined hydrogen gas. The pressure of the resultant hydrogen gas buildup is measured and predictions as to the HIC activity of that area can be made.

Abstract: The disclosure is directed to a device that includes an upper container configured to receive a fluid sample collected from a mammal into a first opening, the first opening opposite a second opening and a membrane covering at least a portion of the second opening, the membrane configured to allow transmission of a portion of the fluid sample through the membrane.

Abstract: Novel reaction media for electron donating and electron accepting components in colour-change compositions are described. The compound is of formula (VI); R1, and R2 are independently selected from an optionally substituted linear or branched alkyl group, alkenyl group, alkoxy group, aryl group and an alkylene aryl group having from 5 to 22 carbon atoms; X1 and X2 are independently selected from —OC(O)—, —CO2— and O; Y1, and Y2 are independently selected from hydrogen, halogen, R1, —OR1; y is independently 0 or 1; and suitably the groups R1X1— and —X2R2 are independently in the ortho or meta position. The compounds are useful in ink compositions, writing implements containing the compound and medical and industrial applications in which temperature sensitive colour change may be required.

Abstract: The invention is directed towards dielectric materials, BaTiO3, BaZrO3, and/or BaTi1-xZrxO3, such that 0?x?1, for detecting, sensing, filtering, reacting, or absorbing toxic chemicals, such as chemical warfare agents (“CWAs”) and their structural analogs, toxic industrial chemicals and narcotics, wherein the dielectric material is incorporated into a sensor for detecting, sensing, filtering, reacting, or absorbing the toxic chemicals.

Abstract: The present disclosure relates to a sampling and sensing device and a method of using the sampling and sensing device for collecting and sensing chemical or biological analytes. The sampling and sensing device comprises a handle and a foldable head having a sampling region and a sensing region. A sensor chip may be disposed in the sensing region and a sampling wipe may be disposed in the sensing region. The sampling region is configured to collect an analyte. After the analyte is collected on the sampling region, the sampling and sensing device can be folded to make the sampling region in contact with or face the sensing region to transfer the analyte to the sensing region for analysis.

Abstract: A molecular detection apparatus of an embodiment includes: a first detector which includes a first sensor containing a MOF having a fluorescence emitting property, a light source which irradiates the MOF with light, and a light receiver which receives fluorescence from the MOF; a second detector which includes a sensor layer electrodes electrically connected with the sensor layer; and a type discrimination and concentration calculation part which discriminates a type of the molecules to be detected based on a measurement result measured by the first detector, and calculates a concentration of the molecules a measurement result measured by the second detector based on a discrimination result of a type of the molecules.

Abstract: A method of manufacturing a microfluidic system or microfluidic device having at least one channel includes providing a base sheet, providing a deformable intermediate layer, providing a cover film, and laminating the base sheet, the intermediate layer and the cover film so that a back surface of the intermediate layer is attached to a front surface of the base sheet and a back surface of the cover film is attached to a front surface of the intermediate layer opposite to the back surface thereof, thereby forming a laminate comprising the base sheet, the intermediate layer and the cover film. Further, the method includes applying pressure to the front surface of the intermediate layer through the cover film so as to deform the intermediate layer, thereby forming the at least one channel. The invention also relates to a microfluidic system or microfluidic device) manufactured by this method.

Abstract: A fluid processing system may include a flow control cassette comprising at least one interface sensor chamber in fluid communication with at least one of a plurality of separate channels, the at least one interface sensor chamber defined at least in part by a wall, and at least one capacitive sensor disposed on the wall of the at least one interface sensor chamber. The fluid processing system may include, in the alternative or in addition, at least one syringe comprising a wall defining a barrel having a first end and a second end, the barrel having a bore with or without a piston or plunger disposed therein, and at least one capacitive sensor disposed on an outer surface of the wall of the syringe.

Abstract: The present invention relates to a biosensor, including: a blood cell separation membrane which separates blood cells from blood and allows plasma components to pass through; a microfluid channel through which the plasma components that have passed through the blood cell separation membrane flow; a lower substrate which allows the plasma components that have passed through the blood cell separation membrane to flow along the microfluid channel; and a pillar which connects the blood cell separation membrane and the lower substrate, in which an electrode is disposed in the pillar, and the pillar pushes and lifts the blood cell separation membrane by a predetermined distance. The biosensor of the present invention allows plasma, which is difficult to pass through the blood cell separation membrane due to surface tension, to easily pass through.

Abstract: Embodiments of the invention provide a microfluidic chip having microfluidic structures formed on a surface. The structures form an input channel, an output channel, auxiliary channels, and a hydraulic resistor structure connecting the input channel to the output channel via the auxiliary channels. The resistor structure includes N flow resistor portions (N?2), which are connected to the auxiliary channels. The chip further includes at least N?1 actuatable valves, which are arranged in respective ones of the auxiliary channels. The actuation state of the valves can determine the effective hydraulic resistance of the resistor structure. The valves can be electrogates, each including a liquid-pinning trench arranged in a respective one of the auxiliary channels that define a flow path for a liquid introduced therein, so as to form an opening that extends across said flow path. Each electrogate can further include an electrode extending across the flow path.