A microfluidic cartridge, configured to facilitate processing and detection of nucleic acids, comprising: a top layer comprising a set of cartridge-aligning indentations, a set of sample port-reagent port pairs, a shared fluid port, a vent region, a heating region, and a set of Detection chambers; an intermediate substrate, coupled to the top layer comprising a waste chamber; an elastomeric layer, partially situated on the intermediate substrate; and a set of fluidic pathways, each formed by at least a portion of the top layer and a portion of the elastomeric layer, wherein each fluidic pathway is fluidically coupled to a sample port-reagent port pair, the shared fluid port, and a Detection chamber, comprises a turnabout portion passing through the heating region, and is configured to be occluded upon deformation of the elastomeric layer, to transfer a waste fluid to the waste chamber, and to pass through the vent region.

Described here is a composition comprising amphiphilic silica nanoparticles, wherein the silica nanoparticles are partially fluorinated. Also described here is a method for droplet-based assay, comprising dispersing at least one aqueous droplet in a continuous fluorous phase in a microfluidic channel, wherein at least one amphiphilic silica nanoparticle is absorbed to the interface of the continuous fluorous phase and the aqueous droplet, and wherein the silica nanoparticle is partially fluorinated. Further described here is a method for droplet-based assay, comprising dispersing at least one aqueous phase droplet in a continuous fluorous phase in a microfluidic channel, wherein the continuous fluorous phase comprises at least one partially fluorinated amphiphilic particle adsorbed to an interface of the continuous fluorous phase and the aqueous phase droplet, and wherein the aqueous phase droplet comprises at least one hydrophilic polymer adsorbed to the amphiphilic particle at the interface.

A closure for protectively sealing a biological fluid collection device is disclosed. The closure includes a cap and an adapter or connector. The closure of the present disclosure allows for connection to multiple different blood collection devices. In a first configuration, with the cap connected to the adapter, the closure may be connected to a first blood collection device. In a second configuration, with the cap disconnected from the adapter, the closure may be connected to a second blood collection device. An advantage of the closure of the present disclosure is that it enables a single closure device to accommodate a variety of connection options, hi one embodiment, the closure includes a barrier in communication with a portion of the cap, and the barrier protectively shields a portion of the stopper and/or protectively shields a portion of the cap.

The invention relates to a method, a computer program and a system for operating a hand-held, computer-controlled piston-stroke pipette as well as a corresponding piston-stroke pipette as well a data processing device cooperating with that, wherein a precise pipetting of liquid with a vapor pressure higher than that of water is rendered possible by means of a sequence of prewettings of the pipette tip.

In various implementations, a dropper for a bottle may include a bulb with a flange and an extended leg. The dropper may be used as a cap, in some implementations, with or without a skirt. The dropper may inhibit leaks from a bottle when the dropper is used as a cap for the bottle.

A sample container holding mechanism is for holding a sample container 6, and includes a hook member 9 and a stopper member 10. The hook member 9 suspends and holds the sample container 6 in a state where the sample container 6 is inclined with respect to a vertical direction. The stopper member 10 restricts the rotation of the sample container 6 when the sample container 6 is rotated around the hook member 9.

Liquid dispensers for bottles comprise a dispensing chamber having small portals at either end. Dropwise addition of flavoring or coloring liquids, such as vermouth or bitters, to alcoholic beverages using those liquid dispensers is also disclosed.

A method of cleaning an aspiration tube in a specimen measuring apparatus includes: moving the aspiration tube while discharging a cleaning liquid onto an outer side surface of the aspiration tube; stopping the aspiration tube in a state where a tip of the aspiration tube or a droplet attached to the tip contacts a surface of a flow of the cleaning liquid; and moving the stopped aspiration tube in a direction away from the surface of the flow of the cleaning liquid.

A washing apparatus includes a stage, a suction nozzle, and a control unit. On the stage, an analytical unit is mounted. In the analytical unit, a well having a hole shape including a bottom surface and an inner peripheral surface is formed. The suction nozzle sucks a solution in the well. The control unit, after controlling the suction nozzle to sucks the solution in the well, controls the stage to rotate the stage on which the analytical unit is mounted at a predetermined speed of rotation, and controls the suction nozzle to suck a residue of the solution existing in the well.

The present invention provides a substrate analysis nozzle that reliably prevents a leakage (release) of analysis solution from the nozzle even in the case of a highly hydrophilic substrate and that collects the analysis solution with a high collection ratio after scanning. The present invention is directed to a substrate analysis nozzle configured to discharge an analysis solution from a tip of the substrate analysis nozzle onto a substrate, configured to scan a surface of the substrate using the discharged analysis solution, and configured to suck the analysis solution. The substrate analysis nozzle has a triple-tube structure made up of: a pipe through which the analysis solution is discharged and sucked; a first outer tube surrounding the pipe and surrounding the analysis solution used for scanning; and a second outer tube surrounding the first outer tube. The substrate analysis nozzle includes: first exhausting means including an exhaust path defined between the pipe and the first outer tube; and second exhausting means including an exhaust path defined between the first outer tube and the second outer tube.