A centrifugal processing unit for directing the movement of substances within a sample processing cartridge has a rotor with an accommodation for receiving the sample processing cartridge, the accommodation only allowing a free pivoting motion of the cartridge about a respective pivot axis, wherein each pivot axis is orthogonal to the rotor axis and to a respective force vector of a centrifugal force, a rotor drive to create the centrifugal force, a blocking element, allowing the free pivoting motion of the cartridge in a release position and preventing the free pivoting motion in a blocking position, wherein the blocking element is arranged on the rotor spaced apart above the accommodation is disclosed.

An analytical laboratory system and method for processing samples is disclosed. The system includes a manager unit, as well as an aliquotter unit and a centrifuge unit.

A gripper unit for handling a vessel for receiving biological material is proposed, inter alia. The vessel has a lid which can assume an open position and a closed position. The gripper unit comprises a gripper for gripping and releasing the vessel, and a lid holder, for holding a lid in a defined position in relation to the vessel. The defined position is an open position of the lid.

A centrifugal separation apparatus includes a plurality of centrifugal separators each comprising a rotator which supports a plurality of sample containers containing a sample therein, a base in which the centrifugal separators are arranged in columns and stages and a route is defined therein, the centrifugal separators being movable inside the base, and a movement mechanism that sequentially move the centrifugal separators along the route in the base.

A tube from a plurality of tubes from a tube rack configured to removably hold the plurality of tubes are removed from a tube rack. A weight of the tube which has been removed from the tube rack is determined. A balancing parameter of the tube is determined by a computing device. An estimated balancing parameter of each of a plurality of remaining tubes from the plurality of tubes in the tube rack is determined. A corresponding rotor position from a plurality of rotor positions within the rotor for the tube is determined by the computing device based at least on the balancing parameter of the tube, the balancing parameters of previously placed tubes from the plurality of tubes placed within the rotor and the estimated balancing parameter of each of the plurality of remaining tubes. The transport unit places the tube in the corresponding rotor position within the rotor.

An automatic processing device for liquid samples includes a sample region, a control module, an image identification device and a centrifuge. The sample region is configured to accommodate a plurality of centrifuge tubes. The control module includes a mechanical module. The mechanical module is configured to unscrew or tighten upper caps of the centrifuge tubes, and is configured to draw liquid from the centrifuge tubes or discharge liquid to the centrifuge tubes. The image identification device is coupled to the control module. The centrifuge is coupled to the control module. The centrifuge is configured to accommodate the centrifuge tubes and perform centrifugal treatment.

A separation container for extracting a portion of a sample for use or testing and method for preparing samples for downstream use or testing are provided. The separation container may include a body defining an internal chamber. The body may define an opening, and the body may be configured to receive the sample within the internal chamber. The separation container may further include a seal disposed across the opening, such that the seal may be configured to seal the opening of the body, and a plunger movably disposed at least partially inside the internal chamber. The plunger may be configured to be actuated to open the seal and express the portion of the sample.

A method provides for procuring platelet rich plasma (PRP) from a sample of whole blood in a vial. The method includes the steps of: separating the whole blood into layers through centrifugation with an upper layer containing platelet poor plasma (PPP) and a PRP layer below the upper layer containing PRP; adjusting an end point of a first range of motion of an extractor relative to a position of the PRP layer; moving the extractor through the first range of motion through the vial, PPP passing out from the upper layer through the extractor; and after the extractor reaches the end point of the first range of motion, extracting the PRP through the extractor and collecting the PRP.

A determination mechanism which obtains information about the weight of the specimen housed in the specimen container is arranged on a conveyor line for connecting between a loading module and an automatic centrifugal unit, the specimens are held without being installed at an adaptor until the number of the specimens which can be subjected to a centrifugal processing at once by the automatic centrifugal unit arrives, and the specimens are installed after the arrival in an order from a heavier specimen at the adaptors to be paired, which are installed at the symmetric positions to each other across the rotation central axis. Also, the specimen is installed at the gravity-center position of the adaptor first, and the subsequent specimens are installed from the inner side at the point-symmetric positions to each other across the gravity-center position.

A method provides for procuring platelet rich plasma (PRP) from a sample of whole blood in a vial. The method includes the steps of: separating the whole blood into layers through centrifugation with an upper layer containing platelet poor plasma (PPP) and a PRP layer below the upper layer containing PRP; adjusting an end point of a first range of motion of an extractor relative to a position of the PRP layer; moving the extractor through the first range of motion through the vial, PPP passing out from the upper layer through the extractor; and after the extractor reaches the end point of the first range of motion, extracting the PRP through the extractor and collecting the PRP.