A transport assembly with an upper part including a plurality of sleeves, each sleeve extending along a sleeve axis between a top opening and a bottom opening, wherein the plurality of sleeves are arranged with their respective axes in parallel to one another, and a lower part including a plate with a plurality of apertures that each extend through the plate. The upper part and the lower part can be coupled such that each bottom opening is arranged adjacent to one of the plurality of apertures, and the upper part and the lower part can be moved relative to one another between a closed configuration in which a perimeter of each bottom opening intersects a perimeter of a corresponding aperture at two or more points, and an open configuration in which the perimeter of each bottom opening is aligned with or is enclosed by the perimeter of a corresponding aperture.

A transport tray with a plurality of sleeves each configured to receive a substantially cylindrical container having a cylindrical container wall and a container bottom surface arranged orthogonally to the container wall. Each sleeve includes a top opening, a bottom opening, a sleeve wall that extends along a sleeve axis between the top opening and the bottom opening and is configured to abut at least a portion of the container wall of a respective container, and one or more support feet adjacent to the bottom opening and extending from the sleeve wall towards the sleeve axis, wherein each support foot has a bottom surface and a top surface configured to abut the container bottom surface of a respective container forming a gap between the support foot bottom surface and the container bottom surface along the sleeve axis. The one or more support feet comprise a thermally conductive polymer.

Provided herein is a method for isolating high molecular weight (HMW) DNA using beads that are at least 200 μm in diameter that utilizes a device for retaining the beads and where the purified DNA eluant exits the device without shearing the HMW DNA. In some embodiments, the method comprises precipitating the DNA onto the beads, washing the beads in the device, and then eluting the DNA from the beads therein while substantially avoiding shear. Compositions and kits for practicing the method are also provided.

Provided herein is a method for isolating high molecular weight (HMW) DNA using beads that are at least 200 μm in diameter that utilizes a device for retaining the beads and where the purified DNA eluant exits the device without shearing the HMW DNA. In some embodiments, the method comprises precipitating the DNA onto the beads, washing the beads in the device, and then eluting the DNA from the beads therein while substantially avoiding shear. Compositions and kits for practicing the method are also provided.

A transport or packaging container accommodating a plurality of supporting structures for closures, for transporting or packaging closures for closing cartridges for use in pharmaceutical, medical or cosmetic applications, in which the transport or packaging container is box-shaped and includes a bottom, which is closed or sealed by a seal, upstanding lower side-walls extending essentially perpendicularly from the bottom, a circumferential supporting step extending horizontally from the upstanding lower side-walls, upper side-walls extending upward from said circumferential supporting step, and a circumferential flange formed at upper ends of the upper side-walls; and the plurality of supporting structures for closures is accommodated inside the transport or packaging container.

A transport or packaging container accommodating a plurality of supporting structures for closures, for transporting or packaging closures for closing cartridges for use in pharmaceutical, medical or cosmetic applications, in which the transport or packaging container is box-shaped and includes a bottom, which is closed or sealed by a seal, upstanding lower side-walls extending essentially perpendicularly from the bottom, a circumferential supporting step extending horizontally from the upstanding lower side-walls, upper side-walls extending upward from said circumferential supporting step, and a circumferential flange formed at upper ends of the upper side-walls; and the plurality of supporting structures for closures is accommodated inside the transport or packaging container.

A system for transporting a sample in a clinical analysis system includes a sample container holding the sample, a ferromagnetic base connected to a bottom portion of the sample container, and a puck. The puck is used for transporting the sample container in the clinical analysis system. The puck comprises an embedded magnet for securing the sample container to the puck using the ferromagnetic base.

A system for transporting a sample in a clinical analysis system includes a sample container holding the sample, a ferromagnetic base connected to a bottom portion of the sample container, and a puck. The puck is used for transporting the sample container in the clinical analysis system. The puck comprises an embedded magnet for securing the sample container to the puck using the ferromagnetic base.

Disclosed are a reagent holder, a testing apparatus assembly, an aqueous humor collection device and an aqueous humor collection method. The reagent holder (9) comprises a holder body and a functional station arranged on the holder body, wherein the functional station comprises a fluid holding tube insertion hole (91) and an elastic component. The elastic component can elastically act on a fluid holding tube (106) in the case where the fluid holding tube (106) is inserted into the liquid holding tube insertion hole (91) so as to enable the fluid holding tube (106) to elastically move in the direction of the central axis of the hole of the fluid holding tube insertion hole (91). By means of using the reagent holder to elastically fix the fluid holding tube (106), the rigid collision between a fluid drawing device and a bottom wall of the fluid holding tube (106) can be converted into an elastic collision, so as to prevent a testing apparatus from triggering a firing pin protection function during the fluid drawing process, such that the depth to which the fluid drawing device can extend into the tube cavity of the fluid holding tube (106) is greatly increased, and the sample extraction amount is thus effectively increased.

A preanalytic system is disclosed. The preanalytic system comprises a cap gripper configured to grip a cap of a laboratory sample container, wherein the cap is connected to a rod of a swab located within the laboratory sample container, wherein the cap gripper is further configured to release the cap from the laboratory sample container, and a cutting device configured to cut the rod of the swab when the cap is in a position released from the laboratory sample container.