A magnetic bead separation method includes: storing, in a container, a mixed liquid containing a magnetic bead and a liquid containing target molecules, and adsorbing the target molecules on the magnetic bead, the magnetic bead containing a Fe-based metal soft magnetic particle and a coating film with which the Fe-based metal soft magnetic particle is coated, and having a saturation magnetization of 50 emu/g or more and 250 emu/g or less; applying an external magnetic field to the container and magnetically attracting at least a part of the magnetic bead by the external magnetic field; and applying an acceleration to the container while the magnetic bead is magnetically attracted by the external magnetic field and desorbing the liquid adhering to the magnetic bead.

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.

A fluidic chip comprising: a sealing layer having an upper surface and a lower surface; and a formed part comprising a generally planar body having a lower surface sealed with the upper surface of the sealing layer, the generally planar body having a number of through holes and a number of wells in fluid communication with the number of through holes, wherein together with the upper surface of the sealing layer, the number of through holes and the number of wells respectively define a number of fluid inlets and a number of fluid chambers in fluid connection with each other in the fluidic chip.

A diagnostic sample tube, comprising a tube body having a tube cavity to receive a test sample; and a tube body lid; the tube body and the tube body lid are formed as a single piece; a mechanical fastening mechanism formed with the single piece, the mechanical fastening mechanism comprising an engagement protrusion and an engagement protrusion receiver; wherein, when the mechanical fastening mechanism is fastened, the mechanical fastening mechanism holds the tube body and the tube body lid in a closed position relative to one another with the cavity closed; and wherein, when the mechanical fastening mechanism is fastened, the engagement protrusion receiver surrounds a longitudinal length of the engagement protrusion.

This disclosure relates to an apparatus for simultaneously filling a plurality of sample chambers. In one aspect, the apparatus comprises a common fluid source and a plurality of independent, continuous fluidic pathways. Each independent, continuous fluidic pathway comprises a sample chamber and a pneumatic compartment. The sample chamber is connected to the common fluid source, and the pneumatic compartment is connected to the sample chamber. The sample chamber comprises, in part, an assay chamber. The assay chamber comprises a monolithic substrate and a plug having optically transmissive properties. In some embodiments, the assay chamber contains a magnetic mixing element. In some embodiments, the assay chamber is a double tapered chamber. In some embodiments, a ratio of a volume of the sample chamber to a volume of the pneumatic compartment is substantially equivalent for each fluidic pathway of the plurality of fluidic pathways.

A sample assembly includes a vial, a vial insert, and a sealing arrangement. The vial insert could be any combination of a sample chamber, a matrix, or a swab breaker configured to be positioned within the vial. The sealing arrangement includes a coupling portion and a cap assembly. The coupling portion defines a mounting channel sized to receive a portion of the vial. The coupling portion is configured to slidably couple to the vial. The cap assembly includes a desiccant cap. The desiccant cap is configured to couple to the vial to selectively form a sterile barrier between the sealing arrangement and the vial.

There is disclosed a fluid distribution system for distributing fluid from a single source to a plurality of downstream receptacles. The system has a distribution manifold with a single inlet and a plurality of outlets arrayed around a circumferential outer periphery. The outlets may be directed to the different receptacles which each have their own vent filter, or each receptacle connects back to the distribution manifold for common venting.

Provided is an automatic analyzer in which a lid of a reagent vessel does not hinder the dispensing of the reagent.

An automatic analyzer for analyzing a specimen includes a reagent dispensing unit for dispensing a reagent from a reagent bottle in which a plurality of reagent vessels storing reagents used for the analysis of the specimen are arranged in one direction, and a reagent rack in which reagent bottles are stored, in which the reagent rack includes a lid opening unit for opening a lid corresponding to an upward opening of the reagent vessel along an arrangement direction of the reagent vessels, and a lid fixing unit for fixing the lid to the outside of a path in which the reagent dispensing unit is inserted into the opening.

Various systems for the containment or delivery of a product are provided. The systems allow for the storage of products at low temperatures and include a container closure inserted into a container (10). The container closure may have an elastomeric body (12) and include a material (14) having a negative coefficient of thermal expansion. In other systems, the material having a negative coefficient of thermal expansion may be inserted between the elastomeric container closure and a seal. Other systems may include an insert at least partially embedded within the elastomeric body of a container closure, an actuator having a distal end movably attached to the insert, and a resilient element between the distal end of the actuator and the insert, wherein the resilient material expands radially upon displacing the distal end of the actuator toward the insert.