Disclosed is a station, for testing an analyte in a sample, enabling accurate and quick reaction and analysis of the sample and a reagent in one apparatus. To this end, the present disclosure provides a station, which is for testing a sample by means of inserting a cuvette, having a standby chamber on which a collecting member is placed, a sample chamber, a reagent chamber and a detection unit. The station comprises: a housing which has an input/output part into which a cuvette is inserted; a driving unit which is provided inside the housing, horizontally moves the cuvette, vertically moves a collecting member, reacts a sample in a sample chamber and a reagent in a reagent chamber, and injects a reaction result thereof into a detection unit; and an optical reader which is provided on the horizontal movement path of the cuvette and is for analyzing the reaction result.

The present invention concerns a SBS-standard test tube rack which is suitable for use in automated capping and de-capping of flat bottomed test tubes, in particular of flat bottomed glass vials, both for individual test tube capping and de-capping as well as simultaneous capping and de-capping of all test tubes in the aforementioned SBS-standard test tube rack.

The present invention relates to a system for conducting the identification and quantification of micro-organisms, e.g., bacteria in biological samples. More particularly, the invention relates to a system comprising a disposable cartridge and an optical cup or cuvette having a tapered surface; wherein the walls are angled to allow for better coating and better striations of the light, an optics system including an optical reader and a thermal controller; an optical analyzer; a cooling system; and an improved spectrometer. The system may utilize the disposable cartridge in the sample processor and the optical cup or cuvette in the optical analyzer.

The invention relates to a sample processing system and method for processing biological samples, comprising a sample processing device having: a receiving plate, which is arranged substantially horizontally in a plane; a first and second working arm, which can move relative to the receiving plate and extend substantially parallel to each other in a second direction (Y) over the receiving plate; at least one pipetting device mounted on the first working arm, which is movable in the second direction (Y) and in a third direction (Z) orthogonal in relation to the first and second direction (X, Y); at least one gripping device, mounted on the second working arm, with grippers that can be rotated around a gripper axis of rotation (GA) parallel to the third direction (Z); and a control device for controlling the pipetting device and the gripping device.

A method and a device for transferring tubes between a laboratory automation system and a sample archiving system are presented. When transferring a tube from the laboratory automation system to the sample archiving system, a tube carrier carrying a tube is conveyed to a first take-over module via a first conveyor. At the first take-over module, the tube is removed from the tube carrier and the empty tube carrier is conveyed away from the first take-over module via a second conveyor. When transferring a tube from the sample archiving system to the laboratory automation system, an empty tube carrier is conveyed to a second take-over module via a third conveyor. At the second take-over module, at least one tube is inserted into the tube carrier and the tube carrier carrying the at least one tube is conveyed away from the second take-over module via a fourth conveyor.

An automation system for use with in-vitro diagnostics that includes a track configured to provide one or more paths and a plurality of sleeves. Each sleeve is configured to hold one of a plurality of fluid containers. The system also includes a plurality of carriers configured to travel along the track. Each carrier is separable from each sleeve and configured to hold one of the plurality of sleeves. The system further includes a tray having a plurality of rows. Each row is configured to hold at least one of: (i) one or more of the plurality of sleeves; and (ii) one or more of the plurality of carriers. The tray is configured to at least one of: (i) unload the plurality of sleeves or the plurality of carriers from the tray; and (ii) load the plurality of sleeves or the plurality of carriers to the tray.

An automated sample specimen storage system including a tube holding microplate including a plate frame, a predetermined array of tube holding receptacles formed in the plate frame, the receptacles having a SBS standard pitch corresponding to the predetermined array, and being configured for holding therein sample store and transport tubes, each disposed so as to contain sample specimen in a sample storage of the storage system and to effect, with the sample tube, delivery from the sample storage to a workstation, the predetermined array of receptacles defining a volume capacity of the tube holding microplate, and each of the receptacles being shaped to conformally engage walls of the sample tubes and hold a respective one of the sample store and transport tubes, wherein the receptacles are arranged so that the tube holding microplate volume capacity defined by the predetermined array is an under optimum volume capacity.

The invention relates to a sample processing system and method for processing biological samples, comprising a sample processing device having: a receiving plate, which is arranged substantially horizontally in a plane; a first and second working arm, which can move relative to the receiving plate and extend substantially parallel to each other in a second direction (Y) over the receiving plate; at least one pipetting device mounted on the first working arm, which is movable in a second direction (Y) and in a third direction (Z) orthogonal in relation to the first and second direction (X, Y); at least one gripping device, mounted on the second working arm, with grippers that can be rotated around a gripper axis of rotation (GA) parallel to the third direction (Z); and a control device for controlling the pipetting device and the gripping device.

The invention provides an improved method for sensitive and specific detection of target molecules, cells, or viruses. The inventive method uses large area imaging to detect individual labeled targets complexed with a target-specific selection moiety. The invention eliminates wash steps through the use of target-specific selection through one or more liquid layers that can contain optical dye and density agents. By eliminating washes the invention simplifies instrumentation engineering and minimizes user steps and costs. The invention uses sensitive image analysis to enumerate individual targets in a large area, is scalable, and can be deployed in systems ranging in complexity from manual to highly automated.

The present invention relates to a system for conducting the identification and quantification of micro-organisms, e.g., bacteria in biological samples. More particularly, the invention relates to a system comprising a disposable cartridge and an optical cup or cuvette having a tapered surface; wherein the walls are angled to allow for better coating and better striations of the light, an optics system including an optical reader and a thermal controller; an optical analyzer; a cooling system; and an improved spectrometer. The system may utilize the disposable cartridge in the sample processor and the optical cup or cuvette in the optical analyzer.