Enclosures and corresponding magnetic joints. An apparatus includes an enclosure. The enclosure includes a magnetic panel joint formed by: a first panel carrying a magnet and comprising a first pocket; a second panel including a second pocket; and a ferromagnetic shield coupled within the second pocket and couplable within the first pocket via the magnet.

Disclosed here are kits comprising pre-packed stabilizing solutions for stabilizing combinations of biomarkers at room temperature. Such kits can be better adapted for sample collection at a subject's dwelling, thus easing the burdensome requirement of sample collection.

A system for performing biological reactions is provided. The system includes a chip including a substrate and a plurality of reaction sites. The plurality of reaction sites are each configured to include a liquid sample of at most one nanoliter. Further, the system includes a control system configured to initiate biological reactions within the liquid samples. The system further includes a detection system configured to detect biological reactions on the chip. According to various embodiments, the chip includes at least 20000 reaction sites. In other embodiments, the chip includes at least 30000 reaction sites.

The present invention relates to a method for the diagnosis of a disease comprising contacting a donor tissue section with a liquid capable of extracting an antibody from said donor tissue section and contacting said liquid with an acceptor material comprising an antigen, followed by detection of a complex comprising the antibody and the antigen, and a diagnostically useful carrier comprising a donor tissue section and an acceptor material comprising an antigen.

A testing equipment system collects a specimen from a subject and measures the specimen, and includes a first unit portion forming a collection room including equipment to collect the specimen, a second unit portion forming a measurement room including equipment to measure the specimen, separately from the collection room, and a third unit portion including equipment to output a measurement result. The testing equipment system is placed at a moving base for passenger transportation.

A unique cap for an automatic test tube recapper is presented. The cap has a conical body with an upper top flange and lower sections for inserting into standard test tubes. The middle section directly under the upper top flange is about 13 mm in diameter. A bottom section under the middle section has a diameter of about 16 mm. The cap has a rounded bottom. The middle and lower sections have diameters similar to the diameters of most common test tubes. One or more nipples with notches cutout are located inside the conical body. The notches grip the lower part of a hammer drive during the driving process but release the hammer drive once the cap has been seated inside the test tube.

A container and a container engaging member. The container engaging member may include a sample holder or reservoir, a filtration element and collar. In the assembled condition, the sample holder or reservoir is upstream of the filtration element, the container is downstream of the filtration element, and the sample holder or reservoir is attached to the container. The container engagement member is engageable and disengageable from the bottle or container in a quick attach, quick release manner, such as with only a 90 degree, ¼ turn. A tactile and/or audible indication that the engagement is complete is provided.

The present disclosure relates to a fluid analyzing device that includes a sensing device for analyzing a fluid sample. The sensing device includes a microchip configured for sensing the fluid sample, and a closed micro-fluidic component for propagating the fluid sample to the microchip. The fluid sample can be provided to the micro-fluidic component via an inlet of the fluid analyzing device. And a vacuum compartment, which is air-tight connected to the sensing device, can create in the micro-fluidic component a suction force suitable for propagating the fluid sample through the micro-fluidic component.

Vial assemblies comprise a tubular body and a cap, the cap including a first portion configured to abut a lip of an open end of the tubular body, a threaded portion configured to couple to threading on an internal surface of the tubular body, and a second portion protruding from the threaded portion and extending into a cavity of the tubular body. Methods for storing and removing frozen samples from such vial assemblies are also described.

An extraction cell cap assembly allows for toolless disassembly. The assembly includes a cap body having a threaded base releasably engaged with a cell vessel, a support member extending axially upward from the base, and a bore axially extending through the support member. The assembly also includes a locking cap having a plunger slidably received within the bore, a recess disposed within the plunger, and a locking portion that releasably engages the support member. Rotation of the locking cap in a first direction engages the locking portion with the support member, and rotation in an opposite direction disengages the locking portion. A filter is received in the recess and a seal member received in the bore, wherein the seal member forms a fluid-tight seal between the cell vessel and the assembly when the locking portion and the support member are engaged and the assembly is secured to the cell vessel.