An automatic analysis apparatus of the present invention includes: a measurement section that measures a sample; a remaining quantity detecting section that detects that a remaining quantity of a consumable article used in the measurement section has become less than or equal to a predetermined quantity that is set in advance; a setting section that is capable of setting in which mode, of a first mode and a second mode applied for operation control of the measurement section, to operate the measurement section for each consumable article when the remaining quantity detecting section detects that the remaining quantity of the consumable article has become less than or equal to the predetermined quantity; and a control section that controls operation of the measurement section based on the setting of the setting section.

One variation of a method includes, during a calibration period: triggering collection of an initial bioaerosol sample by an air sampler located in an environment; and triggering dispensation of a tracer test load by a dispenser located in the environment; accessing a detected barcode level of a barcode detected in the initial bioaerosol sample; accessing a true barcode level of the barcode contained in the tracer test load; and deriving a calibration factor for the environment based on a difference between the detected barcode level and the true barcode level. The method further includes, during a live period succeeding the calibration period: triggering collection of a first bioaerosol sample by the air sampler; accessing a detected pathogen level of a pathogen detected in the first bioaerosol sample; and interpreting a predicted pathogen level of the pathogen in the environment based on the detected pathogen level and the calibration factor.

One variation of a method includes, during a calibration period: triggering collection of an initial bioaerosol sample by an air sampler located in an environment; and triggering dispensation of a tracer test load by a dispenser located in the environment; accessing a detected barcode level of a barcode detected in the initial bioaerosol sample; accessing a true barcode level of the barcode contained in the tracer test load; and deriving a calibration factor for the environment based on a difference between the detected barcode level and the true barcode level. The method further includes, during a live period succeeding the calibration period: triggering collection of a first bioaerosol sample by the air sampler; accessing a detected pathogen level of a pathogen detected in the first bioaerosol sample; and interpreting a predicted pathogen level of the pathogen in the environment based on the detected pathogen level and the calibration factor.

One variation of a method includes, during a calibration period: triggering collection of an initial bioaerosol sample by an air sampler located in an environment; and triggering dispensation of a tracer test load by a dispenser located in the environment; accessing a detected barcode level of a barcode detected in the initial bioaerosol sample; accessing a true barcode level of the barcode contained in the tracer test load; and deriving a calibration factor for the environment based on a difference between the detected barcode level and the true barcode level. The method further includes, during a live period succeeding the calibration period: triggering collection of a first bioaerosol sample by the air sampler; accessing a detected pathogen level of a pathogen detected in the first bioaerosol sample; and interpreting a predicted pathogen level of the pathogen in the environment based on the detected pathogen level and the calibration factor.

An analysis device management system manages one or a plurality of analysis devices and includes a first generator that one-to-one corresponds to each analysis device and manages state information of a corresponding analysis device, a storage that stores the module, a receiver that receives an analysis execution request for using the one or plurality of analysis devices, and a state manager that updates the state information of one or a plurality of modules corresponding to the one or plurality of analysis devices designated by the received analysis execution request.

A quality control method of a specimen analysis system is disclosed, including: receiving a setting of a quality control measurement condition from a user; determining at least one quality control specimen to be used for quality control measurement from among a plurality of the quality control specimens stored in a storage, according to the quality control measurement condition and information on the quality control specimens that are stored in the storage section; taking out the determined quality control specimen from the storage; transporting the determined quality control specimen to a measurement unit; and measuring the transported quality control specimen by the measurement unit.

A method for controlling a specimen analysis system including at least one measurement unit according to one or more embodiments is disclosed. The method may include automatically starting at least one measurement unit according to a schedule registered by a user; automatically supplying a quality control specimen to the measurement unit that is automatically started; and measuring the quality control specimen by the measurement unit.

A quality control method of a specimen analysis system according to one or more embodiments is disclosed. The quality control method may include cooling and storing a quality control material comprising a cell of known concentration; heating the cooled and stored quality control material; transporting the heated quality control material to an analyzer; and measuring the quality control material by the analyzer.

A method and apparatus for automatic engagement with an analyzer, a computer device and a storage medium The method comprises: acquiring test information of a sample under test and state information of an analyzer, the state information indicating whether the analyzer is in an idle state or an operating state (102); if the analyzer is in an idle state, conveying the sample under test to the analyzer (104); and performing a test on the sample under test according to the test information (106). The method can acquire state information of an analyzer to enable a sample under test to be conveyed to the analyzer timely for performing a test thereon without requiring maintenance personnel to adjust the analyzer according to the state information of the analyzer, thereby reducing manual costs and increasing operation efficiency of the analyzer.

A coverslipping machine (1) is embodied to be connected to an electrical power grid in order to be supplied with electrical energy as an electrical load; and removes specimen slides (4), having samples present thereon, from a specimen slide magazine (5) and respectively carries out a coverslipping process in which a mounting medium (7) and then a coverslip (8) are applied onto each specimen slide (4); and deposits the coverslipped specimen slides (4) in the specimen slide magazine (5) or in a further specimen slide magazine (55). The coverslipping machine (1) has an electrical energy reservoir (12) and an electronic control apparatus (13). The electronic control apparatus (13) detects disruptions in the supply of electrical energy from the power grid and, in the event of a disruption, switches over to a withdrawal of electrical energy from the electrical energy reservoir (12), and carries out a safety routine that includes at least the safety steps of completing the coverslipping of specimen slides (4) already equipped with the mounting medium (7), and then depositing them in the specimen slide magazine (5) or in the further specimen slide magazine (55).