A system and method for automatic closure of sample vessels such as vessels with medical laboratory samples, having a plurality of identically shaped, stackable closure caps with a convex outer face and concave inner face that are stacked in a closure cap stack such that an upper closure cap in the stack bears with its convex outer face on the concave inner face of a lower closure cap lying immediately below in the stack. The system includes a closure gripper for gripping an uppermost closure cap from the stack, for transferring the gripped closure cap to the sample vessel to be closed, and for introducing the gripped closure cap into an opening of the sample vessel in order to tightly close the opening. The closure gripper has a centering piece insertable into a closure cap such that it bears on the concave inner face of the closure cap.

An automated system for processing a sample contained in a liquid sample container includes an automated tool head configured to rotate about a first axis, and to translate along a second axis different than the first axis, an analytic element positioner having an analytic element holder configured to releasably grip an analytic element, and a specimen transfer device carried by the tool head, wherein the tool head is configured to automatically position a working end of the specimen transfer device to obtain a specimen from a sample container held in the sample container holder, and to transfer the obtained specimen to an analytic element held by the analytic element holder, respectively, through one or both of rotation of the tool head about the first axis and translation of the tool head along the second axis.

Systems and methods for automated biological sample preparation for use in rapid identification and antimicrobial susceptibility testing of microorganisms, such as bacteria and fungi, are provided.

A heating device for heating a thermally fixable sealing cover disposed over the microplate adjacent the wells, a cooling device for actively cooling the microplate and a controller set up to control activity of the heating and cooling devices in a manner to heat the sealing cover so as to thermally fix it to the microplate and to actively cool the microplate so as to keep a temperature of the samples below a predefined temperature when heating the sealing cover. It further relates to a method for automatically sealing a microplate in which the thermally fusible sealing cover is disposed over the microplate, the sealing cover is heated to thermally fix it to the microplate and the microplate is actively cooled in a manner that a temperature of the liquid reaction mixtures is kept below a predefined temperature when heating the sealing cover.

A sample vessel rack (1), which comprises a frame (2) with a plurality of openings (3) in the upper surface of the frame for sample vessels (9), and a locking plate member (5) movable in a plane parallel to the upper surface of the frame (2) of the rack from a releasing position to a locking position and back, wherein the removal of the sample vessels (9) from the rack is prevented when the locking plate member is in the locking position, the openings (3) of the upper surface of the frame (2) comprises slots (12) formed on their side, and in the locking position a part of the locking plate member (5) sets itself in the area of the slots. The invention also relates to such a method and a sample vessel rack system.

Example automated storage modules for analyzer liquids are described herein. An example apparatus includes a refrigerated storage module having a plurality of shelves (to store a plurality of carriers) and a loading bay having an array of slots to receive one or more of the carriers. The loading bay is accessible by a user for manual loading or unloading of the carriers. The example apparatus includes a first carrier transporter coupled to the storage module to transfer the carriers between the shelves and a first transfer location and a second carrier transporter movable along a track connecting the storage module to an automated diagnostic analyzer. The second carrier transporter is to transfer a first carrier between the first transfer location and a slot in the loading bay and a second carrier between the first transfer location and a second transfer location accessible by the automated diagnostic analyzer.

A method of handling laboratory sample containers by a laboratory sample container handling system is presented. The method comprises providing a laboratory sample container comprising an assigned ID information to the laboratory sample container handling system, reading the assigned ID information, checking, if the read ID information is unique or not unique within the laboratory sample container handling system, and if the read ID information (2) is not unique within the laboratory sample container handling system, assigning a new ID information to the laboratory sample container. The new ID information is unique within the laboratory sample container handling system.

A sample container of patient sample material includes a sample container barcode containing patient-identifying information. The sample container barcode on the sample container is read, and a tubular reaction vessel is provided to a printer module configured to print a barcode directly onto a surface of the tubular reaction vessel. The printer module prints a barcode on the surface of the reaction vessel by a thermal printing method, and the barcode printed onto the reaction vessel is associated with the sample container barcode.

A gripping device for handling sample containers is presented. The sample containers are closed by caps of a given cap type or are not closed by caps. The gripping device comprises a number of fingers configured to collectively cause gripping of a sample container, a tactile sensor device arranged at at least one of the fingers and configured to sample a longitudinal profile of the sample container and of the cap, if any, being gripped, and a control device coupled to the tactile sensor device. The control device determines if the sample container is closed by a cap or not closed by a cap based on the sampled longitudinal profile.

A container for receiving vessels for use in an automated analyzer is presented. The container comprises a wall assembly including a first wall and a second wall. The wall assembly forms a receptacle for receiving a vessel having one or more covers or lids. At least one of the first and second walls moves to provide a first open configuration for receiving the vessel and a second closed configuration. The container further comprises an actuator configured to translate the vessel from a first position after being received in the container to a second position and the wall assembly in the second closed configuration is positioned so that at least one engaging element attached to the wall assembly engages with the covers or lids of the vessel to open the covers or lids while the vessel is being translated by the actuator from the first position to the second position.