A microtiter plate assembly is disclosed that includes a base having a plurality of wells and a lid having a plurality of projections corresponding to the plurality of wells. Each projection contains a radial notch and a canted distal tip, providing bubble free sealing, reduced oxygen back-diffusion, and increased sensitivity even at small sample volumes.

The present disclosure provides a cartridge for use in nucleic acid extraction and a nucleic acid extraction method which can simplify a nucleic acid extraction process and can be applicable to a point-of-care testing (POCT). The cartridge includes a chamber module, an air valve module, and a liquid valve module. The chamber module includes a plurality of chambers for extracting nucleic acids from a sample including a pretreatment chamber in which the sample is crushed and homogenization, cell disruption, and purification are performed. The air valve module is installed on the chamber module to control a pressure required to move a fluid between the plurality of chambers. The liquid valve module is installed below the chamber module to move the fluid between the plurality of chambers.

Disclosed are cartridge components, cartridges, systems, and methods for isolating analytes from biological samples. In various aspects, the cartridge components, cartridges, systems, and methods may allow for a rapid procedure that requires a minimal amount of material from complex fluids.

An operation method of a multiplex slide plate device is provided. First, the multiplex slide plate device is assembled, including a slide plate, a sacrificial layer and a housing. The slide plate has reaction vessels, and the sacrificial layer has a microfluidic channel composed of an injection channel, a main channel and a distal channel. A sample solution is injected to the injection channel, such that the sample solution flows from the injection channel through the main channel to the distal channel, wherein the sample solution loads into the reaction vessels. Afterwards, an oil is injected to the injection channel, such that the oil flows from the injection channel through the main channel to the distal channel, wherein the oil removes the sample solution not loaded into the reaction vessels. Next, the sacrificial layer is heated to melt, and the melted sacrificial layer is mixed with the oil.

A sample holder (10) comprises a sample chamber (33), a gas reservoir (32) and an upper layer (20) covering over the sample chamber (33) and gas reservoir (32), wherein a bottom surface of the upper layer (20) comprises a microstructure array (23) which overlies at least a portion of a top periphery of the sample chamber (33), and wherein the microstructure array (23) is in communication with a gas path which extends to the gas reservoir (32), to allow gas exchange between the sample chamber (33) and the gas reservoir (32).

Disclosed herein are systems and methods for serial flow emulsion processes. Systems and methods as described herein result in reduced cross-contamination.

In an example implementation, a reagent storage system for a microfluidic device includes a microfluidic chamber formed in a microfluidic device. A blister pack to store a reagent includes an electrically conductive membrane barrier adjacent to the chamber. A thinned region is formed in the membrane barrier, and a conductive trace is to supply electric current to heat and melt the thinned region. Melting the thinned region is to cause the membrane barrier to open and release the reagent into the chamber.

The present invention relates to a sampling housing and to a modular controller formed by this sampling housing when it is connected to a control station. This housing comprises a device supporting an assembly (3) consisting of a well plate (4), of a cap adapter (5) comprising as many orifices as there are wells and arranged on said well plate (4), and of caps (6), each cap (6) cooperating with a single well of the plate (4). The invention is applicable in the field of analyzing biological samples.

Disclosed herein are devices, apparatus, systems, methods and kits for collecting and storing a fluid sample from a subject. A device for collecting the fluid sample can include a housing comprising a recess having an opening, a vacuum chamber in the housing and in fluidic communication with the recess, and one or more piercing elements that are extendable through the opening to penetrate skin of the subject. The vacuum chamber can be configured for having a vacuum that draws the skin into the recess. The recess can be configured having a size or shape that enables an increased volume of the fluid sample to be accumulated in the skin drawn into the recess.

A fluid specimen collection, storage, transport, and testing cup contains a removable chromatographic strip-carrying cartridge and an axially moveable liquid specimen preserving caddy which moves between a first, pre-test position and a second, post-test position. During which a caddy drain is temporarily opened allowing an amount of liquid specimen deposited in the caddy to flow into the cup and contact the strips. Once in the second position, the drain is sealed for later confirmatory testing. The caddy is moved between the two positions by screwing a threaded lid more tightly onto the top opening of the cup. The axial range of the screw is limited by a removable obstruction collar. The caddy can include a liquid specimen containing chamber having a lower opening sealed by a frangible barrier.