A sample collecting device is provided. The sample collecting device includes a frame, a collect part and a control part. The collect part is disposed in the frame and is provided with a collecting cavity having a collecting port, and the collect part is used to make a sample flow into the collecting cavity from the collecting port. The control part is disposed in the frame, used to make a collecting rod put into a reagent bottle be pulled out and inserted into the collecting cavity to thereby collect the sample, and used to make the collecting rod with the sample be pulled out from the collecting cavity and put back into the reagent bottle. The collecting of sample without manual intervention is realized, effectiveness and consistency of the collected samples are ensured, and the labor cost is reduced.

Devices, systems and methods are disclosed which relate to a prefiltration device that can be used with the concentrating pipette instruments and other devices which draw a sample in through one opening and dispense a concentrated or eluted sample out through the same opening. The device allows the sample to be passed through a prefilter when entering the opening and then bypassed the prefilter when being dispensed through the same opening.

An in-vitro diagnostic analyzer, a reagent card (10), and an installation structure (200) are disclosed. The installation structure (200) includes an installation body (210). The installation body (210) includes an installation hole (212) configured to sleeve a sample tube (70), a hollow needle (220), a sealing portion (240), and an air inlet channel (230). One end of the hollow needle (220) is capable of being inserted into the sample tube (70). The sealing portion (240) is in sealing fit with an outer wall of the sample tube (70). The air inlet channel (230) includes an air outlet hole (234) and an air inlet hole (232). The air outlet hole (234) is configured for communication with the sample tube (70) provided on the installation hole (212). The reagent card (10) is integrated with the installation structure (200), and the in-vitro diagnostic analyzer is integrated with the reagent card (10).

Disclosed is a chemiluminescence measurement apparatus that includes: a support member configured to support a cartridge for measuring a test substance contained in a specimen by chemiluminescence measurement; a motor configured to rotate the support member so as to rotate the cartridge such that a process required for the chemiluminescence measurement proceeds in the cartridge; and a light receiver configured to receive light generated by chemiluminescence in the cartridge that is supported by the support member rotated by the motor. The cartridge supported by the support member and a light receiving surface of the light receiver are disposed inside a dark space surrounded by a light-shielding portion, and the motor is disposed outside the dark space.

A releasing stopper for a container, the stopper including a first body configured to be directly coupled with the container and comprising a coupling element for allowing the removable fastening of the stopper on the container; a second body, axially movable with respect to the first body along a predefined axis of the stopper and cooperating with the first body for defining a reservoir at least temporarily insulated from the outer environment, a membrane or collapsible septum constituting at least a portion of the reservoir wall, openable and/or breakable for allowing the communication of the reservoir with the outer environment. The stopper includes a first closed configuration, wherein the reservoir is insulated from the outer environment, and a second open configuration, wherein the reservoir is in communication with the outer environment, and wherein the membrane or collapsible septum is opened by a perforation or opening element distinct from the stopper.

A device for detecting nucleic acids in a biological sample has a sample port, a lysis station and a sample conduit configured to mix a sample and lysis agent to form a sample-lysis mixture, pass the sample-lysis mixture across a solid-state membrane to capture nucleic acids in the biological sample therein, and receive the remainder of the sample-lysis mixture in a waste chamber. The wash station is configured to introduce the wash solution following the sample-lysis mixture, pass the wash solution across the solid-state membrane to purify nucleic acids captured therein, and receive the wash solution from the solid-state membrane in the waste chamber. The elution station is configured to pass the eluent across the solid-state membrane, elute captured nucleic acids from the solid-state membrane, and pass the captured nucleic acids into one or more reaction chambers for amplifying and detecting the captured nucleic acids.

A collection device for a biological sample to capture target compounds such as viruses or other pathogens or particles for testing from within the sample and move the captured target compound to a separate chamber for subsequent processing. The collection device can include an openable substance blister including capture particles located in a cup interior. Capture particles can attract and bind the target compounds from the sample. An extraction tube extracts any nucleic acid from the target compound for storage or subsequent amplification and testing to confirm presence of known microorganisms. The extraction tube can comprise a heat-deformable material and can be connected to a microfluidic cartridge for further processing of nucleic acid including, amplification and detection. The microfluidic cartridge includes valves and a plurality of chambers for amplification.

The present invention is directed to an apparatus and method of fabricating a sealed storage system for environmentally sensitive aqueous materials with liquid flow control and on-demand distribution. The present invention features a sealed storage apparatus capable of compactly containing a liquid reagent with liquid control capabilities. The apparatus may comprise a liquid-impermeable, air-impermeable, resistant to force-induced tearing pouch body capable of being penetrated through the application of a laser. The apparatus may further comprise a pouch cavity disposed within the pouch body for holding the liquid reagent. The apparatus may further comprise a liquid-impermeable, air-impermeable, and resistant to force-induced tearing sealing adhesive disposed over the pouch cavity to seal the liquid reagent within the pouch body capable of being penetrated through the application of the laser. Thus, the apparatus may allow liquid to flow from any point on the said apparatus by simply directing the laser to the point.

A sample collection device having a sample container, a solid phase binding material, and a container sealing component is presented. The sample container may have a housing that forms an opening for receiving a sample, and that encloses a space for holding the sample. The solid phase binding material may be disposed within the space enclosed by the housing of the sample container and may be adapted, when the sample contains an analyte, to bind specifically to the analyte. The container sealing component may be removably attachable to the sample container at the opening thereof, and may be adapted, when attached to the sample container, to form a seal around the opening of the sample container.

The invention provides a device for detecting an analyte in a liquid sample. The device comprises a receiving chamber for receiving an absorbent element, wherein the absorbent element is used for collecting a liquid sample; and a detection chamber configured to receive a testing element, wherein the testing element is set to test an analyte in a liquid sample, the receiving chamber is provided with a first position and a second position, when the receiving chamber is located at the first position, the receiving chamber is not in fluid communication with the detection chamber, and when the receiving chamber is located at the second position, the receiving chamber is in fluid communication with the detection chamber.