A device for receiving, stacking, and removing microplates is presented and described. The device comprises a tower for stacking the microplates, wherein a microplate comprises a container and, optionally, a lid. There is a retaining device at the lower end of the tower, which has a first retaining tool and a second retaining tool, and preferably partially encompasses a microplate. The first retaining tool is designed to hold a microplate in a form-fitting manner. The second retaining tool is designed to fix a container in the microplate in place in a frictional manner. The first retaining tool is above the second retaining tool in the stacking direction. A system that comprises the device described above, a dispenser device, and a transport device, is also disclosed. The dispenser device is used to fill microplates, and the transport device is used to add and remove microplates to and from the device.

A processor assembly including a core module operable to expose a sample on a slide; a staining module operable to apply a stain to the exposed sample; and a robotic transfer mechanism to transfer the slide from the core module to the staining module. Also, an apparatus including a rectangular body having an open rear end and an opposite front end; a flange having a first side and a second side, wherein the first side of the flange is coupled to the front end of the body; and a pair of legs extending from second side of the flange, wherein the pair of legs are operable to engage opposite side edges of a slide. A method comprising: exposing a sample on a slide in a core module of a processor assembly; robotically transferring the slide from the core module of the processor assembly to a staining module of the processor assembly; applying a reagent to the exposed sample in the staining module by a thermal inkjet printing process; and after applying the reagent, robotically transferring the slide back to the core module.

A device for container storing is presented. The device comprises storage with at least one storing level including a pipetting storing level for fluid pipetting. Each storing level has storing positions having a container holder to detachably hold at least one container. A handler is movable with respect to the storage for transferring containers with respect to the storing positions. A storing position of the pipetting storing level includes a flat spring to bias a container against the container holder. The flat spring has a through hole to provide a pipette access to a lid of the container. A system for pipetting is also presented, comprising the device and a pipettor movable with respect to the pipetting storing level with at least one pipette for pipetting contained in a container stored in the pipetting storing level. The pipette has a pipette tip to penetrate a lid of the container.

Described is a lateral flow high throughput assay device analyzer for preparing and analyzing a plurality of lateral flow assay samples. The analyzer comprises a cartridge stage for supporting an assay cartridge, an elevation adjustment mechanism, and a translation adjustment mechanism for aligning the cartridge stage and assay cartridge relative to a vertical support structure, fluid metering device, and detection device for high throughput lateral flow assay analysis.

The invention relates to a feeding system (10) having a feeding apparatus (30) for conveying laboratory vessels for samples, microorganisms, cell cultures or the like, and a carrier (12) having one or plural holders (16) for storing laboratory vessels, which feeding apparatus (30) has a loading area (36) and an unloading area (46) remote from the loading area (36) in which plural laboratory vessels can be stored in a vertically stacked configuration, with each receiving unit (34) being coupled to an endless conveyor unit (38) which transports the receiving unit (34) from the loading area (36) to the unloading area (46), and in which the carrier (12) can be used to introduce laboratory vessels into one or plural receiving units (34) in the loading area (36), for which purpose the carrier (12) is at least partially slid over the at least one receiving unit (34) which is to be loaded or unloaded, and for this purpose has projections (28, 32) and/or recesses that are associated with the carrier (12) and are provided in the loading area (36) of the feeding apparatus (30), which will result in positive locking of the feeding apparatus (30) and the carrier (12) when the carrier (12) has been inserted in the loading area (36). According to the invention, the carrier (12) has at least two holders (16) and the positive locking of the carrier (12) and the receiving unit (34) in the loading area (36) of the feeding apparatus (30) will allow only a single predefined orientation of the carrier (12) in the loading area (36).

The invention relates to a system for automatic closure of sample vessels (PG), in particular of sample vessels (PG) with medical laboratory samples, with iii. a plurality of identically shaped, stackable closure caps (10) which have a convex outer face and a concave inner face and which are stacked in at least one closure cap stack in such a way that an upper closure cap (10) in the closure cap stack bears with its convex outer face on the concave inner face of a lower closure cap (10) lying immediately below in the closure cap stack, iv. a closure gripper (20) for gripping an uppermost closure cap (10) from the at least one closure cap stack, for transferring the gripped closure cap (10) to the sample vessel (PG) to be closed, and for introducing the gripped closure cap (10) into an opening of the sample vessel in order to tightly close the opening, wherein the closure gripper (20) has a centering piece which can be inserted into a closure cap (10) in such a way that it bears on the concave inner face of the closure cap (10). With such a system, automated closure of sample vessels is possible in a space-saving and efficient way. Furthermore, a method for automatic closure of sample vessels is also disclosed.

The invention relates to a conveying device (IO) for positioning and providing laboratory vessels (12; 12a, 12b, 12c) for nutrient media, samples, microorganisms, cell cultures, or the like for analysis, sample preparation, and/or sample manipulation at an associated apparatus (64), comprising at least one first conveying unit (32) for conveying the laboratory vessels (12) between an initial region (30) and a provision region (60), where the laboratory vessel (12) is held for the analysis or preparation. According to the invention, a plurality of conveying units is present, which perform only a translational motion of the laboratory vessel (12) along an axis, wherein the first conveying unit (32) vertically conveys the laboratory vessel (12) from the initial region (30) to a predetermined height region (50) and vice versa, and a second conveying unit (56) is provided, which horizontally conveys the laboratory vessel (12) from the height region (50) to the provision region and vice versa.

A processor assembly including: an exposure station operable to expose a sample on a slide; a print station operable to apply a reagent to the exposed sample through a thermal inkjet process; and a robotic transfer mechanism to transfer the slide from the exposure station to the print station. Also, a reagent cartridge including: a body defining a container having a volume therein; a nonmetallic bag in the container operable to contain a reagent; and a printhead at a base of the body, the printhead coupled to an outlet of the bag. Further, a method including exposing a sample on a slide in a processor assembly; robotically transferring the slide to a printing station of the processor assembly; and applying a reagent to the exposed sample at the printing station by a thermal inkjet printing process.

A preprocessing apparatus uses preprocessing kits prepared for samples, respectively, sets the preprocessing kits in plural processing ports provided so as to correspond to preprocessing items, and executes a predetermined preprocessing item. A controller which controls operations of a carrying mechanism holding and carrying the preprocessing kits, and processing parts executing the preprocessing items in the respective processing ports, includes a processing-state control part, a random access part, and a preprocessing part. The random access part is configured to check availability of a preprocessing port corresponding to a preprocessing item to be executed on a sample contained in a preprocessing kit, and set the preprocessing kit in a processing port if the processing port is available as a processing port corresponding to the preprocessing item. The preprocessing part executes a corresponding preprocessing item on a sample in a preprocessing kit when the preprocessing kit is set in the processing port.

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.