A range of pH of a mobile phase that is usable for an analysis with use of each column is registered by a pH range registrar in association with identification information of each column. A pH of each mobile phase is registered by a pH registrar. A column to be used for an analysis is selected by a column selector. A chromatograph is controlled by an analysis controller such that a mobile phase having a registered pH that is out of a range of pH that is registered in association with a selected column is not supplied to the selected column. The chromatograph is controlled by the analysis controller such that an analysis is performed while a mobile phase having a registered pH that is in a range of pH that is registered in association with a selected column is supplied to the selected column.

An apparatus including a reagent cartridge and a reaction chamber, the reagent cartridge having a reagent capsule removably positioned therein for dispensing of a reagent onto the reaction chamber. A system including a linearly translatable mounting assembly having a plurality of mounting stations dimensioned to receive at least one fluid dispensing cartridge, a linearly translatable bulk reagent dispensing assembly having a plurality of bulk reagent dispensing nozzles coupled thereto and a receiving assembly positioned beneath the mounting assembly and the bulk reagent dispensing assembly, the receiving assembly including a plurality of reaction stations. A method including determining an inventory of an automated sample processing system, downloading a processing protocol from a central controller to the automated sample processing system, operating the automated sample processing system based on the processing protocol and independently of the central controller and dispensing a reagent from the automated sample processing system.

Method and associated system for reading machine-readable labels on a plurality of sample receptacles held by a sample rack. In the method, a machine-readable label associated each of the plurality of sample receptacles is read with a first label reader when the rack is at a first location. The sample rack is then moved from the first location to a second location, where a rack identifier on the sample rack is sensed with a sensor separate from the first label reader. Finally, the rack identifier is associated with the machine-readable labels of the plurality of sample receptacles.

A diagnostic and treatment assembly, configured to diagnose and treat cellular disease. The diagnostic and treatment assembly has a radio wave generator communicatively coupled to a carrier modulator and a radio wave amplifier. An impedance matching system is electrically coupled to the radio wave amplifier. A reflected wave sensor is electrically coupled to the impedance matching system. A radiator applicator is electrically coupled to the reflected wave sensor. A vector impedance analyzer is electrically coupled to the radio wave amplifier. An information collector data network is electrically coupled to the vector impedance analyzer. A data logger is communicatively coupled to the carrier modulator, the vector impedance analyzer, and the reflected wave sensor. The diagnostic and treatment assembly operates in a low-power mode to diagnose a cellular disease and in a high-power mode to treat the cellular disease.

The present invention provides devices and systems for use at the point of care. The methods devices of the invention are directed toward automatic detection of analytes in a bodily fluid. The components of the device are modular to allow for flexibility and robustness of use with the disclosed methods for a variety of medical applications.

A system for measuring a property of a sample is provided. The system comprises a diagnostic measuring device having a memory and a diagnostic test strip for collecting the sample. The strip has embedded thereon a pattern representative of at least first data and second data, the first data being data representing at least one of parameters related to measuring the property, codes usable for calibration of the diagnostic measuring device, or parameters indicating proper connection between the measuring device and the test strip and the second data usable for detecting and rejecting potential errors affecting the proper measurement of the property.

A sample measuring method of optically measuring a sample housed in a container in a sample measurement device, the method including: loading the container such that the container is shielded from light; starting to read information regarding a measurement to be performed on the sample in response to the loading the container; and measuring the sample based on the read information.

The invention relates to a method for controlling a laboratory system comprising at least partially networked laboratory devices for processing samples by means of laboratory processes performed by the laboratory devices, the method comprising:-a process detection step (S1), in which samples to be processed and/or laboratory processes to be performed with the samples are detected via a detection unit (05);-a status determination step (S3), in which a response of networked laboratory devices regarding the current and/or future status and/or the termination of sample processing is obtained by the laboratory devices;-a task update step (S4), in which a task list, at least for the processing of certain samples by means of a certain laboratory device or a plurality of certain laboratory devices in a certain order, is created or updated by a task generation unit at least from the detected samples and/or laboratory processes and/or on the basis of the status of the laboratory devices, in particular by considering predefined prioritisation rules and/or weighting factors;-a management step (S5), in which management instructions are generated and output by a management system on the basis of the current task list, by means of which management instructions detected samples are brought at least indirectly to at least one laboratory device; and-a transport means control step (S6), in which transport means control instructions are generated by a transport means control system on the basis of control instructions and are transmitted to at least one transport means configured as a UAV (unmanned aerial vehicle (04)) at least for the transport of detected samples.

Computer systems (130, 120, 230) support a production process with a first sub-process to process a chemical substance at a production site and with a second sub-process to analyze a physical sample of the chemical substance at a laboratory site. A process control system (120) provides first type data (A) to identify physical samples, and a manufacturing system (130) provides second type data (B) that are required to control a production process. Connector modules (105, 205) transmit the data (A, B) in a message (150) to a laboratory system (230) to obtain laboratory data, as an analysis result. The connector module (205) that is associated with the laboratory system (230) distributes the data according to the types. A control signal module (139) derives a control signal (136/138) for controlling the production process. This control signal closes a control loop for adjusting the first sub-process until the laboratory data shows compliance.

The present invention relates to methods, devices and systems for associating assay information with an assay consumable used in a biological assay. Provided are assay systems and associated consumables, wherein the assay system includes a reader adapted to read/erase/write information from/to an assay consumable identifier associated with the assay consumable. Various types of assay information are described, as well as methods of using such information in the conduct of an assay by an assay system.