First analysis information including at least one of a sample analysis condition, a sample preparation condition and a kind of sample is assigned to at least one kind of jig, and the jig is arrangeable to correspond to any of a plurality of sample holders. Holding information representing whether a sample is held by each sample holder and jig information for identifying the kind of jig are acquired by a first information acquirer from an automatic sample injector. The first analysis information in regard to a corresponding sample holder is specified by a first analysis information specifier based on jig information. A batch file for controlling a sequence of analysis or preparation in regard to a sample held by a sample holder corresponding to a jig is created by a batch file creator with use of the holding information and the first analysis information.

Systems and methods include an optimization-based load planning module for laboratory analyzers of bio-fluid samples. The optimization-based load planning module is executable on a computer server and is configured to optimize assay (lab test) assignments across a large number of laboratory analyzers based on one or more of the following user selected and weighted objectives: reduced turn-around-time, load balancing, efficient reagent usage, lower quality assurance costs, and/or improved system robustness. The optimization-based load planning module outputs a load plan comprising computer executable instructions configured to cause a system controller of a laboratory analyzer system to schedule and direct each requested test to be performed at one or more selected laboratory analyzers of the laboratory analyzer system in accordance with the user selected and weighted objectives. Other aspects are also described.

In a scenario where a laboratory is required to perform a plurality of tests on biological samples from a plurality of tubes in a manner that satisfies certain constraints, it is possible that the laboratory could handle the samples and assign them to machines in a manner which ensures that the relevant constraints are met. This could include using matrices and optimization functions to represent tubes, tests, machines and prescriptions, and could also include dynamically determining whether and how to aliquot the samples so as to meet the constraints given the conditions under which the samples would be processed.

The automatic analysis system comprises an analysis device which introduces sample containers which have been placed at a predetermined placement location into an analysis unit to perform analysis on the samples, and a management device which has a function of transmitting identification information for a sample to said analysis device when an analysis request has been made for that sample. The analysis device comprises a sample information management unit which retains sample identification information transmitted from the management device as analysis-requested sample information and retains identification information for samples which have been analyzed by the analysis unit as analysis-completed sample information.

The invention relates to a laboratory instrument for the instrument-controlled handling of a partial problem in a treatment process which contains treatments of at least one laboratory sample. The invention moreover relates to a system containing a plurality of such laboratory instruments, wherein the system serves for the instrument-controlled handling of a problem containing a plurality of these partial problems in the treatment process of at least one laboratory sample. And the invention relates to a method for the instrument-controlled handling of a partial problem in a treatment process which contains treatments of at least one laboratory sample.

Systems and methods are described to determine a prioritization schedule for samples handled by a system with multiple remote sampling systems. A system embodiment includes, but is not limited to, an analysis system at a first location; one or more remote sampling systems at remote from the first location, the one or more remote sampling systems configured to receive a liquid segment and transfer a liquid sample to the analysis system via a transfer line; and a controller communicatively coupled with the analysis system and the one or more remote sampling systems, the controller configured to assign a priority value to a sample for analysis by the analysis system and to manage a queue of samples received from at the one or more remote sampling systems on the basis of the assigned priority value.

In an automatic analyzer in which required maintenance can be executed efficiently, without omission, an operation control unit controls operations of an analysis module (ISE, AU1, AU2) including a sample vessel transport mechanism, a reagent vessel transport mechanism, a reaction vessel transport mechanism, a sample dispensing mechanism, and a reagent dispensing mechanism, and of a display unit, and analyzes a sample accommodated in a reaction vessel. The operation control unit stores a validity period for each maintenance item of the analysis module (ISE, AU1, AU2) and an execution time for each maintenance item in a memory, displays an execution time together with an identification representation of execution priority level based on the expiration dates on the display unit, rearranges the display order of the maintenance items on the basis of the execution priority level, in accordance with an operator's instruction inputted through an operation input portion.

Double bag having a first compartment containing a composition to be distributed and a second compartment for receiving a used fluid, a first bag connector communicating with the first compartment and serving to empty the latter, and a second bag connector communicating with the second compartment and serving to fill the latter.

A method for operating a laboratory automation system, having: a control device and a transport system with carriers and a first empty carrier queue provided with a first fixed number of queue spaces, each assignable an empty carrier; the method comprising: providing additional queue spaces, each assignable an empty carrier, assigning a first number of additional queue spaces from the additional queue spaces to the first empty carrier queue, operating the first empty carrier queue with the first fixed number of queue spaces plus the first number of additional queue spaces, assigning, in response to receiving operation data in the control device, a second number of additional queue spaces from the additional queue spaces to the first empty carrier queue and operating the first empty carrier queue with the first fixed number of queue spaces plus the second number of additional queue spaces. Further, a laboratory automation system is provided.

A method of routing test samples during periods of laboratory disruption in a laboratory system is disclosed. The method comprises determining that a laboratory device is unavailable, masking a target laboratory device so that test samples are not sent to the target laboratory device and test samples cannot be retrieved from the target laboratory device, rerouting test samples from the target laboratory device to a buffer, calculating a new laboratory workflow after the laboratory device becomes available, unmasking the target laboratory device after the new laboratory workflow is calculated, and retrieving the test samples from buffer and sending the test samples to the target laboratory device.