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.

The present inventive concept relates to a microfluidic system for pressure-assisted capillary-driven flowing of a liquid. The system comprises: a first sub-system comprising a capillary flow channel, having a first flow resistance, arranged to receive the liquid and to flow the liquid along the capillary flow channel; a second sub-system comprising a pressure-assisting flow channel, having a second flow resistance, arranged to receive the liquid from the capillary flow channel, and to provide a pressure-assisted flow of the liquid in a direction away from the capillary flow channel; and a capillary valve, having a third flow resistance, comprising a capillary portion, wherein the capillary portion at a first end is connected to an interface between the capillary flow channel and the pressure-assisting flow channel, and at a second end is communicating with gaseous medium. The first flow resistance is larger than the third flow resistance, and the second flow resistance is larger than the third flow resistance, such that the liquid is flowing predominantly by capillary action in the capillary flow channel until a forefront of the liquid has reached the interface with the pressure-assisting flow channel, and by pressure-assisted capillary action after the forefront of the liquid has reached the interface with the pressure-assisted flow channel The present inventive concept further relates to a diagnostic device and a lab-on-a-chip device, comprising the microfluidic system.

The present disclose provides methods and systems for amplifying and quantifying nucleic acids and for detecting the presence or absence of a target in a sample. The methods and systems provided herein may utilize a device comprising a plurality of partitions separated from an external environment by a gas-permeable barrier. Certain methods disclosed herein involve subjecting nucleic acid molecules in the plurality of partitions to conditions sufficient to conduct nucleic acid amplification reactions. The nucleic acid molecules may be subjected to controlled heating in the plurality of partitions to generate data indicative of a melting point(s) of the nucleic acid molecules.

A device enables a user to detect biomarkers, and includes an element that defines a multiplicity of microfluidic channels that communicate between an inlet duct and an outlet duct, the inlet duct communicating with an inlet port into which a user can introduce a drop of body fluid; the outlet duct communicating with an outlet port. A resilient bladder is connected to the outlet port to provide suction. Each microfluidic channel defines a reaction chamber containing a biomarker-sensitive reagent which provides a color or a change of color in the presence of a biomarker, there being a multiplicity of different biomarker-sensitive reagents, one such biomarker-sensitive reagent being provided in each of the multiplicity of different microfluidic channels. At least part of the element is transparent so the color within the reaction chamber can be seen. The device includes a cover with magnifying lenses above the reaction chambers. The device may be used in conjunction with a smart phone.

The present invention relates to methods and systems for testing for the presence of a material such as one or more analyte types within a sample and more particularly, for improved single enzyme-linked immunosorbent assay (sELISA) testing as well as other variants of single-enzyme linked molecular analysis (SELMA).

There is provided an assembly, useable to screen sample fluids for predefined molecules, the comprising, a needle unit comprising n hollow needles, wherein n is greater than one; a flow cell unit comprising m flow cells, wherein m is greater than one, each flow cell having an input and an output, and a test surface on which ligands can be provided; a first selector valve unit which is fluidly connected between the needle unit and flow cell unit, which is operable to selectively fluidly connect any one of the n hollow needles with the m flow cells in the flow cell unit; a pumping means which is selectively operable to provide negative pressure; a second selector valve unit which is fluidly connected between the pumping means and the output of each flow cell. There are further provided methods of screening sample fluids for predefined molecule.

A blood clotting time measurement cartridge includes: an inlet on one end of a measurement flow channel and through which blood is introduced; a communication opening on the other end of the measurement flow channel and through which air suction or air pressure application or the blood introduced from the inlet is performed; a moving body arranged in the measurement flow channel moves; a clotting accelerator applied on at least one of a flow channel wall surface, which defines the measurement flow channel, and the moving body; and a detection area through which light is transmitted to a predetermined part in the measurement flow channel, and where it is possible to detect with light whether there is the moving body or the blood making a reciprocating motion in the measurement flow channel in association with air suction or air pressure application or the blood from the communication opening.

Embodiments can provide a test tube vacuum retainer system, comprising an outer body comprising a midline plate; one or more side walls, a bottom wall, and a top plate comprising an access hole; a test tube holder comprising a sealant ring; a base; and a vacuum tube comprising an external outlet; wherein the test tube holder is secured within the outer body to the base, which in turn is secured to the midline plate; wherein the vacuum tube is connected to the test tube holder at a first end, and the external outlet is configured to be connected to a vacuum pump configured to apply a vacuum force to the test tube holder when a test tube is inserted into the access hole and placed onto the test tube holder.

Embodiments of the current disclosure are directed to systems, methods and apparatus for evaluating single cell secretion profiles. In some embodiments, the apparatus may be configured to analyze substances expressed by a biological cell and may include a first compressible substrate, and a second substrate configured for removable sealing attachment with the first substrate. In some embodiments, upon attachment of the second substrate with the first substrate, an assembly is formed such that the open side of the plurality of chambers are covered by the second substrate, and a portion of each of the plurality of capture areas are exposed in each of the chambers.

A solid reagent containment unit is formed by a support; a frame body fixed to the support and delimiting internally, together with the support, an analysis volume; a reagent-adhesion structure within the analysis volume; and at least one reagent cavity, which extends within the reagent-adhesion structure. The reagent-adhesion structure is of an adhesion material embossable at temperatures lower by 6-8° C. than its own melting point and has a melting point such as not to interfere with the analysis. The reagent cavity forms a retention wall, laterally surrounding the reagent cavity, and houses dried reagents. The adhesion material is chosen among wax, such as paraffin, a polymer, such as polycaprolactone, a solid fat, such as cocoa butter, and a gel, such as hydrogel or organogel.