The invention is a cap for a pathogen sample tube, the tube having an open end and the cap being configured to secure the open end of the tube to prevent spillage of any sample stored in the tube. The cap includes a first pierceable protective film section configured to enable an automated pipette or other sample withdrawal system to pierce the protective film section and to aspirate at least some of the sample. The cap also includes a second pierceable protective film section lying underneath the first pierceable protective film section; the film sections are separated by an air gap, that is approximately 2 mm in depth. The film sections are made from a thin aluminium foil that is approximately 25 microns thick, with a thin lacquer coating on its upper side and a co-extrusion coating, such as a polymer coating, on the lower side.

A blister pack may include a containing body with an opening; and a lid sealed over the opening and provided with a weakening pattern, wherein a width of the lid at the weakening pattern is thinner that a width of the lid elsewhere, and wherein the lid is configured to burst at the weakening pattern when the blister pack is subjected to pressure, so as to allow liquid content inside the containing body to be discharged out of the blister pack through the burst weakening pattern. A blister pack holder is also disclosed.

In a method for metering minimum liquid quantities, a vessel closed in a pressure-tight manner is acted on by compressed air to transport liquid from the vessel through a transfer tubing to a metering valve.

A sample measurement system includes: a measurement unit that measures a sample stored in a sample container; a transport unit that transports a rack capable of holding sample containers via the measurement unit; a first transport-in/transport-out unit and a second transport-in/transport-out unit in each of which racks can be set alongside in a first direction, and that send the set racks to be transported to the measurement unit and receive the racks transported from the measurement unit; and a controller that controls the first transport-in/transport-out unit and the second transport-in/transport-out unit so that the racks are sequentially sent from the first transport-in/transport-out unit and the second transport-in/transport-out unit. The first transport-in/transport-out unit and the second transport-in/transport-out unit are disposed alongside in a second direction crossing the first direction, and each send the racks from one side in the first direction, and receive the racks from the other side.

A sample measurement system includes: a measurement unit that measures a sample stored in a sample container; a transport unit that transports a rack capable of holding sample containers via the measurement unit; a first transport-in/transport-out unit and a second transport-in/transport-out unit in each of which racks can be set alongside in a first direction, and that send the set racks to be transported to the measurement unit and receive the racks transported from the measurement unit; and a controller that controls the first transport-in/transport-out unit and the second transport-in/transport-out unit so that the racks are sequentially sent from the first transport-in/transport-out unit and the second transport-in/transport-out unit. The first transport-in/transport-out unit and the second transport-in/transport-out unit are disposed alongside in a second direction crossing the first direction, and each send the racks from one side in the first direction, and receive the racks from the other side.

A laboratory system for a laboratory automation system is presented. The laboratory system comprises a sample container carrier. The sample container carrier is configured to carry a laboratory sample container and comprises a removal detector. The removal detector is configured to interact with the laboratory sample container to detect a removal of the carried laboratory sample container from the sample container carrier. Furthermore, the laboratory system is configured to determine based on the detected removal that a before valid logic assignment of the sample container carrier to the carried laboratory sample container is invalid.

A secure specimen sample bottle includes a base container for receiving a specimen. The base container has a plurality of locking protrusions formed along an inner surface of the base receptacle. A bottle includes a lock ring that has an upright spire structure that has a closed top end and the opposing open bottom end including a plurality of flexible fins that are configured to interlockingly mate with the locking protrusions so as to prevent removal of the lock ring relative to the base container upon engagement of the flexible fins to the locking protrusions. A removable cap is coupled to the lock ring.

Disclosed are high-throughput vessel supply systems and methods of supplying sample vessels, such as samples stored in test tubes. A system for supplying a plurality of individual vessels that each contains a sample is disclosed.

Disclosed are high-throughput vessel supply systems and methods of supplying sample vessels, such as samples stored in test tubes. A system for supplying a plurality of individual vessels that each contains a sample is disclosed.

The present invention is, in combination, a bone marrow isolation tube and a centrifuge tube. The combination includes a centrifuge tube which defines a tube cavity and includes an upper cylindrical section connected to a lower tapered section which terminates at a bottom reservoir. The isolation tube is adapted to be received within the centrifuge tube cavity. The isolation tube includes a body with a tubular shaped outer surface wherein the interior of the isolation tube defines a lumen which includes an upper cylindrical lumen section and a lower conical lumen section terminating at an orifice. The isolation tube includes at least one wing extending radially outward from the outer surface of the isolation tube. The wing is configured to make contact with the interior surface of the centrifuge tube and wedge the isolation tube into the tapered section of the centrifuge tube during centrifuging. The present invention is also, in combination, a bone marrow isolation tube and a centrifuge tube. The centrifuge tube defines a tube cavity and includes at least two support members defining an insertion space and attached to the interior surface in an upper cylindrical section, the upper cylindrical section connected to a lower tapered section which terminates at a bottom reservoir. The isolation tube is adapted to be received within the insertion space with a flange that is configured to make contact with the support members of the centrifuge tube thereby wedging the isolation tube into the insertion space of the centrifuge tube during centrifuging.