A hermetically sealable container for liquids has a container body and a cap for closing a mouth of the container body. The cap has a main gripping body and a coupling appendage for insertion in the container body. An inner surface of a tubular container wall has a conical guide surface and an intermediate surface connecting the conical guide surface to a shoulder and defining a first annular prominence. The coupling appendage may be in contact with a head end against the shoulder to create a first sealing zone. When the head end abuts against the shoulder, the head end interferes with the first annular prominence, creating a second sealing zone. The coupling appendage has a second annular prominence protruding from a lateral coupling surface near a base of the coupling appendage. When the head end abuts against the shoulder, the second annular prominence interferes with the conical guide surface, creating a third sealing zone.

A safety cabinet includes an enclosure and at least one door to selectively seal the enclosure. The safety cabinet can be used to store, for example, flammable liquids, flammable waste, corrosives, pesticides, or combustible waste. The safety cabinet incorporates a thermally-actuated damper that includes a body, a valve plate, and a pivot assembly. The valve plate is disposed within the passage of the body such that the valve plate is movable between an open position and a closed position. The pivot assembly includes a biasing system adapted to bias the valve plate to the closed position and a fusible link interconnected between the body and the biasing system to constrain the valve plate from moving from the open position to the closed position. The fusible link is configured to melt at a predetermined temperature to thereby allow the biasing system to move the valve plate to the closed position.

An object of the present invention is to provide an analysis apparatus in which local analysis of a substrate with ICP-MS is automated. The present invention relates to an automatic analysis apparatus for a local region of a substrate, including: a nozzle for local analysis having: analysis-liquid supply means that ejects analysis liquid onto a substrate; analysis-liquid discharge means that takes the analysis liquid including an object to be analyzed from the substrate into the nozzle to feed the analysis liquid to a nebulizer; and exhaust means including an exhaust channel in the nozzle; automatic liquid-feed means that automatically feeds the collected analysis liquid to ICP-MS; flow adjustment means that adjusts the flow of the analysis liquid; and automatic control means that simultaneously performs local analysis and analysis of the object to be analyzed with the ICP-MS to perform automatic analysis to a plurality of adjacent predetermined regions, successively.

The present disclosure generally relates to a method and device for inactivation and dry storage, under ambient conditions, of a biological sample containing RNA virus. Methods for collecting and recovering RNA from a biological sample and subsequent analysis for a virus are also provided.

Systems, methods, and collection devices are disclosed for rapid, local PCR testing. The PCR testing system may be configured for use with a disposable sample collection device that includes a swab configured for collecting a biological sample from a patient; and a sample container configured to receive the swab and separate a bulk quantity of the biological sample from the swab for containment in a bulk collection chamber, which is located with the sample container, wherein the sample container is configured to meter a selected volume of the biological sample into a PCR sample tube, which contains a lyophilized master mix, releasably attachable to the sample container.

A microfluidic device includes an inlet port configured to receive a sample, a first reaction chamber fluidically coupled to the inlet port, a first pump fluidically coupled to the inlet port, a second pump fluidically coupled to a mixing chamber, a metering channel fluidically coupled to the first reaction chamber and to the mixing chamber, and one or more second reaction chambers fluidically coupled to the mixing chamber. The first pump is configured to move fluid from the inlet port to the first reaction chamber and from the first pump to the inlet port. The second pump is configured to move fluid from the second pump to the mixing chamber, from the first reaction chamber to the mixing chamber, and from the mixing chamber to the one or more second reaction chambers.

The invention relates to a portable containment device for manipulating organic and/or chemical substances, which includes:

a transporting case including two half-cases (2, 3) connected by a hinged structure (4) such as to be movable between a closed position (F), in which the half-cases (2, 3) are against one another and define a stowing space for at least the hinged structure (4), and an open position (0), in which the half-cases (2, 3) are spaced apart from one another by being maintained vertical by the hinged structure (4) and in which the half-cases (2, 3) and the hinged structure (4) form a supporting structure for a flexible containment enclosure (20);

and a plastic, removable and flexible containment enclosure (20) that is at least partially transparent, for forming a generally parallelepiped foldable isolation chamber provided with means (31, 32) for accessing the inside of the enclosure and with means (21) for attachment to the supporting structure. The containment enclosure (20) is collapsible inside the transporting case in the closed position (F). The invention also relates to a removable, flexible enclosure for such a device.

A flow cell including inlet and outlet ports in fluid communication with each other through a flow channel that extends therebetween. The flow channel includes a diffuser region and a field region that is located downstream from the diffuser region. The field region of the flow channel directs fluid along reaction sites where desired reactions occur. The fluid flows through the diffuser region in a first flow direction and through the field region in a second flow direction. The first and second flow directions being substantially perpendicular.

With respect to a clean air device, in order to provide a device structure and an air cleaning unit inspecting method capable of supplying clean air through a filter and also capable of measuring the amount of dust in a workroom space in which blown air forms a laminar flow such that an increase in the amount of dust can be accurately detected, the clean air device comprises an air cleaning unit, a rectifying unit arranged downstream of the air cleaning unit configured to rectify air blown from the air cleaning unit and form a laminar flow, and a workroom arranged downstream of the rectifying unit, wherein at least one suction port is provided on a wall surface in a space formed between the air cleaning unit and the rectifying unit, configured to draw out the air in the space to an exterior.

Reagent delivery systems, which can include a reagent trough and a pump system, are useful for delivering liquids to a laboratory workbench. Processing samples on the laboratory workbench can result in a large amount of liquid waste. Described herein are reagent troughs, pump systems, reagent delivery systems, waste management systems, and methods of using the same.