Disclosed is a specimen transfer device connected to a rack transportation path of a specimen testing system, and the specimen transfer device includes: an ascending/descending mechanism configured to move a rack between a first ascending/descending position at which the rack in a first tier is disposed, and a second ascending/descending position at which the rack in a second tier is disposed; a container transfer mechanism configured to transfer a specimen container, to a second rack disposed in the second tier, from a first rack moved by the ascending/descending mechanism from the first ascending/descending position to the second ascending/descending position; a rack waiting region disposed in the first tier and configured to cause the rack to stay in a waiting state between the first ascending/descending position and a carrying-out position to the rack transportation path; and a first transportation mechanism configured to transport the first rack moved by the ascending/descending mechanism from the second ascending/descending position to the first ascending/descending position, through the rack waiting region, to the carrying-out position.

Disclosed is a specimen testing system that includes: a specimen rearrangement unit configured to transfer a specimen container held in a first rack to a second rack; a specimen processing unit configured to process a specimen in the specimen container held in the second rack; a specimen storage unit configured to transfer the specimen container having been processed by the specimen processing unit from the second rack to a specimen container storage instrument for storage; a transportation unit configured to transport the second rack among the specimen rearrangement unit, the specimen processing unit, and the specimen storage unit; and a transportation control unit programmed to control the transportation unit. The transportation control unit is programmed to control bidirectional transportation of the second rack between the specimen rearrangement unit and the specimen storage unit.

Disclosed is a fluid disposing system including a centrifugal separator that centrifugally separates a liquid that is supplied, a reagent supply module provided on one side of the centrifugal separator and that supplies a reagent to the centrifugal separator, a pipetting module provided at an upper portion of the centrifugal separator and that feeds a fluid to the centrifugal separator, a feeding module coupled to one side of the pipetting module, and that moves the pipetting module in an X axis direction and a Y axis direction corresponding to a horizontal direction, and a Z axis direction that is perpendicular to the horizontal direction, and a separation module including a magnetic bead for magnetically separating a material that has been primarily separated by the centrifugal separator.

A pipette tip extension attachable to a pipette tip is disclosed. The pipette tip extension has a proximal end, a distal end, and an exterior wall extending between the proximal end and the distal end. The exterior wall has an outer side and an inner side and forms at the proximal end a reception aperture for inserting a pipette tip. The pipette tip extension also has a bottom at the distal end, an inner cavity enclosed by the inner side of the exterior wall and the bottom, and one or more distance elements arranged at the inner side of the exterior wall and protruding into the inner cavity.

Automated liquid handling system for processing a plurality of samples in at least one microscope sample carrier, wherein the microscope sample carrier comprises a plurality of sample deposition wells, wherein each sample deposition well is defined on its lateral sides by one or more lateral walls and on its bottom side by a sample deposition surface, the automated liquid handling system comprising: a centrifuge adapted to centrifuge the microscope sample carrier; an automated transportation device adapted to transfer the plurality of samples and/or a plurality of liquids into and/or out of each of the plurality of sample deposition wells of the microscope sample carrier, and adapted for transporting the microscope sample carrier across the automated liquid handling system, wherein the automated transportation device is configured to couple with a coupling section of the microscope sample carrier; one or more storage containers for receiving and/or storing the plurality of samples and/or the plurality of liquids.

There is provided an automated analysis device capable of transferring instruments to be used for an analysis process to a predetermined processing position efficiently and rapidly. In an automated analysis device of the invention, a transfer unit forming a transfer mechanism to transfer instruments to be used for analyte processing into an analyte processing space includes a holding portion to hold the instruments. The holding portion includes a first fitting attachment portion to be attachable to a first instrument in a fitted state, and a second fitting attachment portion to be attachable to a second instrument in a fitted state.

A sample consumable that carries a microvolume of sample to a sample loader. The consumable is precisely aligned utilizing a double-alignment feature to the loader. The loader is based on a crank-slider geometry and allows for simple, one-handed operation for the user. Overall, the consumable and sample loader increase reproducibility of in-line sample loading and offers ease-of-use.

An automated analyzer is provided with one or more dispensing lines 109, 209 that are each for loading and unloading, at one end thereof, a sample rack 101 having placed therein one or more sample containers accommodating a sample for analysis and for conveying the sample rack back and forth from a dispensing position for dispensing the sample from the sample containers and sample rack removal parts 111, 211 that are provided adjacent to the other ends of the dispensing lines 109, 209 and provide and receive sample racks to and from the dispensing lines 109, 209. According to this configuration, it is possible to convey an urgent sample while suppressing device complexity, preventing cost from increasing, and also maintaining speed.

A pipette tip extension attachable to a pipette tip having a proximal end, a distal end, and an exterior wall extending between the proximal end and the distal end is disclosed. The exterior wall has an outer side and an inner side and forms at the proximal end a reception aperture for inserting a pipette tip, and at the distal end a dispense aperture. The pipette tip extension further has an inner cavity, a distance element connected to the inner side of the exterior wall, and a constriction element.

Systems and methods for automated cell processing of biological samples, such as cells for use in cell therapy and regenerative medicine. Systems for automated processing of batches derived from biological samples comprise: a closed and sterile enclosure; a plurality of reagent containers; at least one reagent dispenser; a quality control module for analyzing at least one characteristic of a batch; a harvesting module; a robotic module; and a control unit (CU) communicatively coupled to the at least one reagent dispenser, the quality control module, the harvesting module and the robotic module for controlling the automatic processing of batches. The automatic processing may be executable without handling by a human operator. The system may be configured to automatically process the plurality of batches without cross-contamination between batches, e.g., under GMP conditions.