A test tube rack dispatching method, a pipeline analysis system and a test tube rack. Said method is applied to a pipeline analysis system. The pipeline system comprises a sample conveying mechanism, at least two test devices and at least two test platforms corresponding to the at least two test devices, the sampling mechanism being connected to the at least two test platforms. Said method comprises: scanning a readable and writable label of a test tube rack placed in the pipeline system, so as to read test mode information corresponding to the test tube rack; and dispatching, by the sample conveying mechanism, the test tube rack to a test platform corresponding to the test mode information, so as to test samples on the test tube rack by a test device corresponding to the test platform.

An apparatus for treating biological samples disposed on substrates, including: an input buffer for receiving one or more substrate holders each being adapted to support a plurality of the substrates; a treatment zone including a plurality of treatment stations each being adapted to receive one of the substrates; a reagent dispenser configured by a controller to dispense reagents to the substrates at the treatment stations; a substrate transport device configured by the controller to transport individual substrates between the substrate holders in the input buffer and the treatment stations.

The present invention relates to a method of loading a sample storage device (10) for a plurality of sample carriers (38A-38E) equipped with sample containers (34), said method comprising: during removal of sample containers (34) from the sample storage device (10): providing at least one output sample carrier (38A) having sample containers (34) that can be taken up from the output sample carrier (38A); providing a target sample carrier (38B) in which sample containers (34) taken up from the output sample carrier (38A) can be deposited; providing a refilling sample carrier (38C) which is at least partially filled with sample containers (34); removing at least one sample container (34) from the output sample carrier (38A) and depositing the at least one sample container (34) in the target sample carrier (38B), and for each sample container (34) removed from the output sample carrier (38A) and deposited in the target sample carrier (38B), removing another sample container (34) from the refilling sample carrier (38C) and refilling the space of the removed sample container (34) in the output sample carrier (38A) with the other sample container (34) from the refilling sample carrier (38C). Moreover, the invention relates to a loading system (12) designed for performing the method.

Provided is an automatic analysis device and an automatic analysis system capable of executing separate operations by respective analysis units even in a device configuration where a same control part controls two or more analysis units.

The automatic analysis device includes: a biochemistry analysis unit (201); an electrolyte analysis unit (211); one analysis unit control CPU (120) for controlling operations of the biochemistry analysis unit (201) and the electrolyte analysis unit (211); and a storage part (133) for storing time charts (302, 312, 314, and 322) of operations having different purposes for the biochemistry analysis unit (201) and the electrolyte analysis units (211). Two or more of the biochemistry analysis units (201) and the electrolyte analysis units (211) operate independent to each other based on the time charts (302, 312, 314, and 322) stored in the storage part (133).

Apparatus for treating biological samples disposed on substrates, including: an input buffer for receiving one or more substrate holders each being adapted to support a plurality of the substrates; a treatment zone including a plurality of treatment stations each being adapted to receive one of the substrates; a reagent dispenser configured by a controller to dispense reagents to the substrates at the treatment stations; a substrate transport device configured by the controller to transport individual substrates between the substrate holders in the input buffer and the treatment stations.

An automatic analyzer is capable of transporting a sample at an optimum timing and a method of transporting the sample. An automatic analyzer includes an analysis unit which measures a sample, a transport unit which transports the sample to the analysis unit, and a control unit which controls the analysis unit and the transport unit. A sample is transported to the analysis unit by a time of starting an aspirating operation on the sample by allowing the analysis unit to perform a pre-measurement operation for each measuring method which needs to be performed before aspirating the sample even when the sample is still in the transport unit.

A system for analyzing one or more samples includes a sample analysis sub-system configured to perform one or more measurements on the one or more samples. The system further includes a controller configured to: receive design of experiment (DoE) data for performing the one or more measurements on the one or more samples; determine rankings for a set of target parameters; generate a recipe for performing the one or more measurements on the one or more samples based on the DoE data and the rankings of the set of target parameters; determine run parameters based on the recipe; perform the one or more measurements on the one or more samples, via the sample analysis sub-system, according to the recipe; and adjust the run parameters based on output data associated with performing the one or more measurements on the one or more samples.

Systems, methods and computer-readable media are provided for determining a sequential ordering of predefined transfers for transferring an object from source points of a source array to destination points of a destination array in a laboratory automation system. For each transition to a next transfer, first and second component travel costs between current and next transfer positions are determined. A transition travel cost is determined from the first and second component travel costs. The cost of each sequential ordering of the predefined transfers is based upon an aggregate of the transition travel costs for each ordering of the transfers. The resolved sequential ordering may be based upon the sequential ordering that has the lowest cost.

Embodiments disclosed herein relate to methods and systems for performing an automated assay, and particularly to performing an assay on a plurality of samples on an automated instrument.

A method for operating a laboratory system comprising instruments for processing samples and a control unit connected by a communication network is presented. The method comprises receiving and identifying a biological sample and retrieving an order list from a database. The list comprises a plurality of targets defining one or more processing steps to be carried out on the biological sample by one or more of the laboratory instruments. The method also comprises selecting a workflow strategy and retrieving workflow acceptance criterion corresponding to the workflow strategy. The control unit determines a sample workflow for processing the sample based on the workflow strategy and determines whether the sample workflow satisfies the workflow acceptance criterion. If the sample workflow does not satisfy the workflow acceptance criterion, workflow strategy and the workflow acceptance criterion is refined and the sample workflow is determined again until it satisfies the workflow acceptance criterion.