RU2757204C1 - Device for automatic analysis - Google Patents

Abstract

FIELD: automatic analysis devices.

SUBSTANCE: invention relates to a device for automatic analysis. The device contains a sample and reagent holder (101) capable of holding the sample and reagent on one disk, a reactor (103) for mixing and reacting the sample and the reagent, dispensers (102a) and (102b) for distributing the sample or reagent, a unit (111) inputting data of the sample placed in the sample and reagent holder and requesting an analysis element for each sample, a planning device (112) for determining the analysis sequence, a device control unit (114), a block (115) for calculating the completion time of the analysis of all samples based on the analysis sequence determined by the scheduling device, and an output block (116) for reporting the calculated estimated completion time of all analyzes, wherein the completion time of all analysis items requested for a group of samples is calculated and reported before analysis starts, and estimated time to complete analysis is updated during analysis.

EFFECT: provides an automatic analysis device capable of calculating the completion time of all analysis items requested for a group of samples before starting analysis, even in the case of a device that is unable to add a sample during analysis.

13 cl, 4 dwg

Description

The technical field to which the invention relates

The present invention relates to an automatic analysis apparatus.

State of the art

From Patent Document 1, an automatic analysis apparatus is known, which is capable of notifying the estimated time of completion of the analysis of the actual sample under investigation. Patent Document 2 also discloses an automatic analysis device and an integrated automatic analysis device capable of providing an accurate estimated analysis completion time by recalculating the required analysis time, analysis start time and analysis completion time with a predetermined distribution in time.

List of links

Patent documents

Patent Document 1: Japanese Unexamined Patent Application No. 2010-145210.

Patent Document 2: Japanese Unexamined Patent Application No. 2010-217114.

Summary of the invention

Technical challenge

In an automatic analysis device that is capable of supplying an additional sample, the user can supply a new sample without receiving information about the progress of the analysis of an already studied group of samples when a new sample is fed into the device. However, since in an automatic analysis device that is not capable of supplying an additional sample, the user cannot start the analysis of a new sample until all the analysis elements specified for the analyzed group of samples are completed, the user needs to predict the time of completion of the analysis of the group of samples.

On the other hand, in an automatic analysis apparatus of a complex type, which is capable of performing analytical studies using different detection principles, such as biochemical analysis and immunoassay of a sample, for example, in parallel, analysis elements using different detection principles are requested and executed at the same time. Since the analysis items requested for one sample start to run irregularly depending on the optimization of the analysis time and the priority of the analysis items, the completion time of all the analysis items requested for one sample is difficult to predict based on the timing of when the sample analysis starts. first.

In addition, although the completion time of the analysis is influenced by the cleaning operation to avoid sample and reagent insufficiency and transfer between the sample and the reagent, as well as interruption of a new analysis, for example, when an abnormality occurs, they are difficult to predict before the analysis begins. Accordingly, when such an effect is recorded during analysis, the analysis completion time should be adjusted.

Thus, the object of the present invention is to provide an automatic analysis device capable of calculating the completion time of all analysis items requested for a group of samples before starting analysis even in the case of a device that is not capable of adding a sample during analysis.

The solution of the problem

In order to solve the above problem, the present invention provides a device for automatic analysis comprising a holder for holding an analyzed sample and a reagent required for analysis, a reactor for mixing and introducing a sample and a reagent into a reaction, a dispenser for dispensing a sample or reagent from the holder into the reactor, a unit input for receiving input data of the analysis element, which are the data of the sample and the sample analysis element, the device control unit based on the analysis sequence determined from the analysis element data, the unit for calculating the estimated time of completion of the analysis of all samples placed in the holder based on the analysis sequence.

Advantages of the invention

In accordance with the present invention, an automatic analysis device can be provided that is capable of calculating the completion time of all analysis items requested for a group of samples before starting analysis even in the case of a device that is unable to add a sample during analysis.

Brief Description of Drawings

FIG. 1 is a diagram illustrating one example of the configuration of an automatic analysis device.

FIG. 2 is a diagram of the steps involved in calculating the estimated time to complete the analysis.

FIG. 3A is a diagram illustrating the configuration of the analysis completion time data of the automatic analysis apparatus.

FIG. 3B is a diagram illustrating the result obtained by updating the analysis completion time data in FIG. 3A based on the plan for the cleaning operation.

FIG. 4 is a diagram illustrating an example of a monitor screen for notifying a user when all analyzes have been completed by the output device shown in FIG. 1.

Description of embodiments

Embodiments of the present invention will now be discussed in detail with reference to the drawings.

First embodiment

According to a first embodiment, a device for automatic analysis is proposed, comprising a holder for holding an analyzed sample and a reagent required for analysis, a reactor for mixing and introducing a sample and a reagent into a reaction, a dispenser for dispensing a sample or a reagent from the holder into the reactor, an input unit for receiving input analysis item data, which are sample data and sample analysis item, a device control unit based on the analysis sequence determined from the analysis item data, and a unit for calculating the estimated completion time of all analyzes to complete the analysis of all samples placed in the holder based on the analysis sequence. According to the first embodiment, there is also provided a device for automatic analysis, comprising a holder for holding a plurality of analyzed samples and reagents required for analysis, a first dispenser for dispensing into a first sample vessel and a reagent for a first group of analysis elements, a second dispenser for dispensing into a second sample vessel, and a reagent for the second group of analysis elements, a reactor for mixing and reacting a sample and a reagent stored in the first vessel and in the second vessel, a control unit for the first and second dispensers and a unit for calculating the estimated completion time of an analysis element constituting each group of analysis elements.

FIG. 1 is a schematic plan view of an automatic analysis apparatus 10 and a block diagram of a control mechanism 11 therefor. The device 10 for automatic analysis contains a sample and reagent holder (hereinafter referred to as the holder) 101 for storing sample vessels 1011 and reagent vessels 1012 on the circumference of the same disk, a dispenser 102 (first dispenser 102a, second dispenser 102b) for aspiration and release sample and reagent from / to holder 101, reaction vessels 1031 into which dispenser 102 dispenses the sample or reagent, reactor (incubator) 103 holding reaction vessels 1031 around the circumference, into which the reaction solution obtained by mixing the sample and reagent is dispensed, and measuring device 104 (first measuring device 104a, second measuring device 104b) for collecting data about each element of analysis from the reaction vessel 1031. For simplicity's sake, only a portion of the sample vessels 1011, reagent vessels 1012, and reaction vessels 1031 are shown. located on a circle.

The first dispenser 102a, the second dispenser 102b, the first meter 104a, and the second meter 104b are dispensers and meters for dispensing sample and reagent, for example, for biochemical analysis and immunoassay. The reagent used for each assay can be stored in the holder 101. The reactor 103 can also be shared for biochemical assays and immunoassays.

The user places the sample container 1011 or the reagent container 1012 in the holder 101. The holder 101 can be rotated about a central axis and moves the freely selected sample container 1011 or the reagent container 1012, set in a position accessible to the dispenser 102. Since after the start of the analysis in With the automatic analysis apparatus 10 according to this configuration, the holder 101 is rotated every time a sample needs to be dispensed, the user cannot put a new sample vessel into the holder 101 until the analysis is finished.

An input unit 111 provided in the control mechanism 11 collects sample identification data, reagent identification data, and analysis item data required to perform analysis. The scheduling device 112 provided in the control engine 11 generates analysis sequence data based on the data collected by the input unit 111. The analysis sequence data is data obtained by sequencing each of the analysis elements of the respective samples automatically analyzed by the automatic analysis apparatus 10. The control unit 114 controls the dispenser 102 or the like. so that the analysis is performed according to the sequence that is determined by the generated analysis sequence data, with the dispenser 102 and the like. installed on the device 10 for automatic analysis.

When biochemical analysis and immunoassay are performed in parallel in the automatic analysis apparatus 10, analysis sequence data is generated for each analysis. Accordingly, for example, the moment when the first dispenser 102a begins to aspirate a sample or reagent to perform biochemical analysis of the sample, and the moment when the second dispenser 102b begins to aspirate a sample or reagent to perform an immunoassay on the same sample, optionally follow one after the other, and are appropriately determined by the scheduling device 112.

The calculating unit 115 of the control mechanism 11 calculates the estimated completion time of all analyzes based on the analysis sequence data generated by the planning device 112 and stored in the memory 113. The estimated completion time of all analyzes means the estimated time when the results of all analysis elements of each sample installed in the holder are output. 101, and the user can install a new sample in the holder 101. Since the estimated completion time of all analyzes is calculated in this embodiment based on the analysis sequence data generated by the planning device 112, it can be calculated before the user activates the automatic analysis device 10. to start analysis. The output unit 116 notifies the user of the calculated estimated completion time of all analyzes.

Next, the process will be explained until the user of the automatic analysis device obtains the estimated completion time of all analyzes in the respective steps 21u-27 illustrated in FIG. 2 diagrams of device actions for automatic analysis. These explanations refer to a situation where calibration, quality control, etc. have already been performed on the automatic analysis device and general analysis of the samples begins. In addition, the control mechanism 11 may be provided by executing a program by a central processing unit (CPU) in the automatic analysis device 10 or by a personal computer (PC) connected to the automatic analysis device 10 and having a control device port or hard disk drive. In other words, the executors of the respective steps 21u-27 are illustrated in FIG. 1 automatic analysis device and external PC, excluding user intervention. A step indicated with the appended "u" means that it is performed with the participation of the user.

First, in step 21, the user places the sample for analysis and the desired reagent in the sample and reagent holder 101. The time required to complete all analysis elements of the placed sample becomes the estimated completion time of all analyzes calculated by the automatic analysis device 10. In step 22u of collecting the sample identification data, the identification data of the placed sample is input to the input unit 111. Sample identification data includes data that is uniquely numbered for each sample, for example, in the form of a bar code on the side of the sample vessel 1011. This data can be collected, for example, by mounting a barcode reader on the holder 101 and reading the barcode from the installed sample vessel 1011. Even if the sample vessel 1011 does not have sample identification data such as a bar code, by recognizing, for example, with a sensor, that the sample vessel 1011 is physically positioned in the holder 101, the insertion position itself can be used as the sample identification data.

In the step 23u of collecting the reagent identification data, the identification data of the placed reagents are entered into the input unit 111. Reagent identification data includes data that is uniquely numbered for each reagent, for example, in the form of a radio frequency identifier (RFID) on the side of the reagent vessel 1012. These reagent identification data can be collected, for example, by mounting an RFID reader on the holder 101 and reading a barcode from the installed reagent vessel 1012. Even if the reagent vessel 1012 does not have reagent identification data, such as RFID, by recognizing, for example, with a sensor, the fact that the reagent vessel 1012 is physically positioned in the holder 101, the user can determine the identification data of the reagents placed in the prescribed position. for example, using the keyboard or monitor screen of the device for automatic analysis. The order in which the sample ID collection step 22u and the reagent ID collection step 23u are performed is irrelevant, and these steps may be performed simultaneously.

In step 24u of collecting the analysis request data, the user enters the analysis item data for the sample placed in the holder 101 into the input unit 111. The analysis request data contains a plurality of analysis items requested for the sample and is linked to the sample identification data and the reagent identification data. In addition, the identification data of the samples can be used as a key, for example, to query the clinical laboratory data management system (LIS), and the data of the analysis items can be input to the input unit 111. In the case of, for example, collecting the sample-identification data in the sample-identification collecting step 22u, a trigger is provided.

After the input of the analysis item data is completed, the step 25 of generating the analysis sequence data in the planning device 112 is performed. This step can be initiated as needed after input, or it can be initiated immediately after the user activates the monitor screen of the device for automatic analysis, for example, to start analysis. Since, when the sample vessel is mounted on a rack and fed into an automatic analysis device, the sequence of feeding the samples depends on the sequence of feeding the racks, which is unknown before they were fed, the sequence of analysis is difficult to determine. In addition, in an automatic analysis apparatus in which a sample is mounted on a disk-shaped holder 101, the analysis sequence is also difficult to define in a system with the possibility of adding a new sample during analysis. Since the automatic analysis apparatus according to the present embodiment is not applicable in the described situation when a new sample is added during analysis, the analysis sequence can be determined at this point in time.

The assay sequence in step 25 of creating assay sequence data can be created for each sample or for each assay element, for example, as a sequence without transfer influence in terms of reagent characteristics, or as a sequence without cross contamination in terms of assay sensitivity characteristics. For example, in the case of a complex type automatic analysis apparatus that is capable of performing multiple types of analysis in parallel, such as biochemical analysis and immunoassay, analysis sequence data is generated for each type of analysis. The generated analysis sequence data is stored in a storage device 113, such as memory and a hard disk, provided in the automatic analysis apparatus 10 or, for example, connected to a PC.

After the analysis sequence data is generated in step 25, an estimated time to complete all analyzes is calculated in step 26. Calculation may be initiated immediately after step 25 and immediately after the user activates the monitor screen provided in the output unit 116 of the control mechanism 11 to begin analysis. To calculate the estimated completion time for all analyzes, in addition to the analysis sequence data, the required analysis time is required. Assay Time Required refers to the time from the start of the assay required to dispense a sample or reagent for each individual assay element of a single sample, before the assay result is displayed. As the required analysis time, for example, the reaction time of the sample and the reagent specified for each analysis element can be used. The method for calculating the estimated completion time for all analyzes is described below.

In step 27, notifying the estimated completion time of all analyzes, the output unit 116 notifies the user of the estimated completion time of all analyzes calculated in step 26. An alert may be triggered immediately after step 26 and, for example, immediately after the user activates the monitor screen. to start the analysis. The notification method is displayed, for example, on the monitor screen.

The following describes one example of a method for calculating in step 26 the estimated time to complete all analyzes. The estimated completion time for all analyzes can also be calculated and used in other ways. As shown in the following expression, the estimated completion time for all analyzes (hereinafter abbreviated - TE) is determined by summing the processing time before analysis (hereinafter abbreviated - Dpre), the maximum value (hereinafter abbreviated - Dproc), the analysis completion time (hereinafter abbreviated - De) and processing time after analysis (hereinafter abbreviated - Dpost) with the start time of analysis (hereinafter abbreviated - TS).

TE = TS + Dpre + Dproc + Dpost

Pre-analysis processing is a general designation of the operations performed by the automatic analysis device before analysis is performed, and includes, for example, resetting the mechanism provided in the automatic analysis device, checking the detection sensitivity of the measuring device, and the like. In addition, the step 22u of collecting the sample ID or the step 23u of collecting the reagent ID can also be re-executed without user intervention, and the step 24u of collecting the analysis request data from the upstream system and re-creating the analysis sequence data. Since the time taken to complete the operation is fixed for all operations, Dpre becomes a fixed time known before the start of the analysis. If no pre-analysis processing is performed, Dpre is assumed to be 0.

De means the time until the output of the result for each analysis element after the start of the analysis in the sequence specified by the data of the analysis sequence, which after the completion of the processing before the analysis is taken as the origin (0). De can be calculated by summing the analysis start time (hereinafter abbreviated - Ds) and the required analysis time (hereinafter abbreviated - Dr) for each element (De = Ds + Dr). As shown in the following expression, Ds is obtained by multiplying the interval time (hereinafter abbreviated as Di) after the automatic analysis device starts executing the analysis element in the sequence specified by the analysis sequence data by the analysis sequence (hereinafter abbreviated as idx).

Ds = Di × (idx-l)

Since in this case, the start time of the analysis element for the first time after the completion of pre-analysis processing is taken to be 0, Di is multiplied by (idx-1).

Table 31 in FIG. 3A illustrates an example of the above-described calculation of De. Table 31 is stored, for example, in memory 113. The analysis sequence, sample and analysis item data in Table 31 in FIG. 3A includes the described analysis sequence data. If De is calculated when Di is received, for example, in 20 seconds, the analysis element of sample A of the second analysis sequence becomes Dproc, and finally the automatic analysis device outputs the analysis result.

Table 31 provides a case where the Ds value is not constant for the analysis of each of the types that can be performed by the automatic analysis apparatus. As one of the reasons that the Ds value becomes unstable, one can specify the number of mechanisms for dispensing the sample. Since there are multiple mechanisms for dispensing the sample, each mechanism dispenses at a feasible time, there are many Ds values. Since the dispensing of the sample in the automatic analysis apparatus 10 is performed by the first dispenser 102a and the second dispenser 102b, there are two Ds values.

Since in this case there is Ds for biochemical analysis and Ds for immunoassay, after creating a table for each of them, the De value of each of them is calculated, and the larger of the De values for biochemical analysis and De values for immunoassay is taken as Dproc. If there are three or more De, the maximum of the values is taken as Dproc. The reason for creating a plurality of tables is the case where De cannot be obtained by a simple calculation, since a group of analysis items with different Ds values described above is processed, and the case where the Ds value is added or subtracted for each type of analysis in order to recalculate De after starting the analysis described below. , which allows you to reduce the cost of computation compared to the case when they are combined in one table.

Post-analysis processing is a general term for operations performed after the automatic analysis device completes all requested analyzes until the user can use the holder 101, examples of which are, for example, the reset operation of the mechanism provided in the automatic analysis device. , cleaning operation of the dispenser, etc. Since the execution time of the operation is taken to be constant for each operation, the Dpost value becomes a constant time known before the start of the analysis. If no post-analysis processing is performed, Dpost is assumed to be 0.

Since, as described above with respect to Dpre, Dproc and Dpost in the calculation of TE (TE = TS + Dpre + Dproc + Dpost), the analysis sequence data is defined, it can be calculated before the analysis by the automatic analysis device starts. For example, with respect to TS, real time can be used immediately after the user activates the monitor screen to start the analysis, or real time of calculating TE. Whichever time is used as TS, TE can be calculated for the user prior to the start of the analysis by the automatic analysis device. In the example described below, illustrated in FIG. 4, TS is taken as 08:30 2020/1/1, and TE is taken as 08:45 2020/1/1.

Next, referring to FIG. 4, a method for displaying the estimated completion time of all analyzes by the output unit 116 is discussed. The user is notified of the calculated estimated completion time of all analyzes by displaying it, for example, on the screen 4 of the monitor provided in the device 10 for automatic analysis. In this case, one example of a method of notifying about the estimated time of completion of all analyzes is considered, while in addition to the method described above, voice notification, notification by transmission to other terminals via a communication network, etc. is also possible.

The monitor screen 4 comprises a real-time display device 41, a display device 42 for the estimated completion time of all analyzes, and the like. The real time display device 41 displays the real time in a format such as year, month, day, hour and minute. The display device 42 of the estimated completion time of all analyzes displays the estimated completion time of all analyzes in the format of, for example, year, month, day, hour and minute, calculated by the calculator 115. When the estimated completion time of all analyzes is not calculated by the calculator 115 or after the analysis is completed, for example, the estimated completion time of all analyzes is not displayed in order to avoid misunderstanding by the user. Although the real-time display 41 and the display 42 of the estimated completion time of all analyzes in FIG. 4 displays only time data, for example, text data and coloring can also be used to distinguish them by the user. The time can also be displayed, for example, "5 minutes after 08:45".

The analysis completion time (hereinafter abbreviated as Titem) of the analysis item requested for each sample can be calculated in the calculator 115 according to the formula (TS + Dpre + De) based on the data obtained in the process of calculating the estimated completion time of all analyzes. The maximum value among Titem for each sample also becomes the analysis completion time (hereinafter abbreviated as Tsmp) of the sample. Regarding, for example, Tsmp and Titem, the Tsmp value may be displayed on the monitor screen 4 by the display device 43 of the name of the sample whose analysis request is received by the automatic analysis device, or Titem may be displayed on the monitor screen 4 by the display device 45 of the estimated completion time of the analysis element execution, which is matched to the display unit 44 of the name of the analysis item requested for each sample.

In accordance with the present embodiment, the user may know the time when a new sample for analysis can be placed in the automatic analysis device and the analysis may begin based on the time data displayed on each of the devices including the display device 42 of the estimated completion time of all analyzes. , a sample name display device 43 or a display device 45 of the estimated completion time of the analysis item.

Second embodiment

In a second embodiment, a method is provided for updating the estimated completion time of all analyzes after the start of the analysis. The user is notified of the estimated completion time of all analyzes prior to the start of the analysis by the next message transmitted from the control unit 114 to the calculation unit 115. The next message is transmitted at the start of the analysis and further with a shorter interval than Di. When the analysis starts in accordance with the analysis sequence data during the transmission of the next message, the control unit 114 notifies the calculator 115 of the updated data, including, for example, the name of the sample, the name of the analysis element and the analysis sequence. The calculator 115, which received the next message, updates the estimated analysis completion time based on the updated data, as shown in Table 31 in FIG. 3A stored in memory 113.

When the next message is received, the calculator 115 performs an update with respect to the data object of the estimated analysis completion time when the value of Ds is 0 or less. The update is performed by subtracting Di from Ds and recalculating De. At the moment when the value of De is already equal to 0, the subtraction and recalculation are not performed. When De is recalculated to a negative value, -Dr is set to Ds, and De is taken to 0. After the updated data is added to the next message, the ETA data specified by the sample and the analysis element from the received updated data are extracted from it. With regard to the obtained data of the estimated completion time of the analysis, Di is subtracted from Ds, and De is recalculated. Then, with respect to data later than the estimated analysis completion time data to which the analysis sequence belongs, Di is subtracted from Ds, and De is similarly recalculated. At the moment when the value of De is already equal to 0, the subtraction and recalculation are not performed. When De is recalculated to a negative value, -Dr is set to Ds, and De is set to 0. The above processing is performed only on the estimated analysis completion time data including the sample and analysis item specified in the updated data, while the estimated time data the immunoassay item completions are not updated when there is a plurality of estimated time to complete the assay, namely, for example, when updated data of the biochemical assay item is received.

After completion of the recalculation of De, the calculator 115 calculates Dproc in a manner similar to the calculation method before recalculation, and calculates the estimated completion time of all analyzes. At this moment, real time is used as TS. By performing the processing described above, triggered by the next message after the start of the analysis, the estimated completion time of all analyzes can be updated. The user can be notified of the actual estimated completion time of all analyzes after being updated by the output unit 116, which can regularly refer to the estimated completion time of all analyzes for display.

Unless a problem occurs when updating the estimated completion time of all analyzes in the manner described above while running the analysis, a result similar to the estimated completion time of all analyzes calculated prior to the start of the analysis can usually be obtained. On the other hand, during the execution of the analysis, for example, there is an interruption of a new element of analysis due to insufficient sample and reagent, cleaning operation to avoid carryover and lack of necessary consumables.

For example, when an insufficient sample is detected, the automatic analysis device interrupts the analysis element where it happened, and the analysis element that was requested for the sample, but has not yet been started. The control unit 114 notifies the calculation unit 115 of the insufficient sample. The calculator 115 extracts an analysis item where the sample has become insufficient and the Ds value exceeds 0 from the sample data table and the estimated analysis completion time generated before the analysis was started. With regard to the data of the estimated completion time of the analyzed item of analysis, the -Dr value is set to Ds, and the De value is recalculated (De becomes 0). For example, if a sample is found to be insufficient during the biochemical analysis when the biochemical analysis and the immunoassay are performed in parallel, the estimated time to complete the analysis of the insufficient sample is also derived from the estimated time to complete the immunoassay. After the estimated completion time of the considered analysis is determined and the Ds value exceeds 0, the -Dr value is set to Ds, and the De value is recalculated. Similar processing is also performed when insufficient sample is detected during immunoassay.

After finishing the processing of the analysis element data where the sample is found to be insufficient, resetting of the Ds value is performed taking into account the data of the estimated analysis completion time, where Ds is 0. When the Ds value before setting is 0 or more, resetting is performed by Ds = Di × (idx-l ) from the analysis sequence idx at the moment when the analyzed element of analysis has a reference sequence 1. Finally, the Dproc value is calculated in a manner similar to the calculation method before recalculation, and the estimated completion time of all analyzes is calculated and reported.

If the reagent is insufficient, for example, the automatic analysis device interrupts the execution of the analysis elements where deficiency is detected, including the analysis element that has started to run. The control unit 114 notifies the calculation unit 115 of the reagent insufficiency. The calculating unit 115 extracts from the data table of the estimated time of completion of the analysis an analysis element in which the reagent is used. With respect to the estimated completion time data of the same item, where the Ds value exceeds 0, the -Dr value is set to Ds, and the De value is recalculated (De becomes 0). After resetting the Ds value, by analogy with the case of detecting sample failure, the Dproc value is calculated, and the estimated completion time of all analyzes is calculated and reported.

When the assay result can be influenced by the distribution of different reagents or samples using the same dispenser, or when the device is loaded before transferring the aspirated or immediately discharged reagent or sample to the aspirated and then discharged reagent or sample and affects the analysis result, block 114 control allows the automatic analysis device to schedule and execute a cleaning operation between the aspiration and discharge operations that are affected and the aspiration and discharge operations that are affected. A cleaning operation is the operation of cleaning the distal end and the inner surface of a portion of the probe to aspirate and release the sample or reagent into the dispenser, for example, with water or detergent. Analysis cannot be resumed during a cleanup operation.

When the above influence of carryover is inferred from the analysis sequence and there is no time to perform cleaning between operations, the automatic analysis device changes the execution of the analysis that is affected and schedules the cleaning operation. In this case, the start time of the affected analysis is delayed from the time Ds when the analysis sequence data is first generated. For example, if only Di is used for a cleanup operation, when performing a one-off cleanup operation thereafter, the analysis Ds is deferred by Di. For example, when a cleanup operation is scheduled between analysis sequences 3 and 4 according to the estimated analysis completion time from Table 31 in FIG. 3A, the updated data is not added to the normal data, and the control unit 114 transmits the normal data to the calculator 115, or the clearing operation execution data may be added. In this case, the calculator 115 introduces a clear operation between the analysis sequences 3 and 4 according to the estimated analysis completion time to update the analysis sequence as shown in Table 32 in FIG. 3B and then updates the completion time of all analyzes.

In other words, the control unit 114 changes the sequence of the analysis of the first group of analysis elements and the second group of analysis elements so that the sample and reagent distributed in the first dispenser and in the second dispenser do not affect the analysis result, and the calculator 115 calculates the completion time of all analyzes based on the analysis delay time taking into account the change in the analysis sequence by the control unit 114. In particular, the control unit 114 instructs the control mechanism 11 to perform a cleaning operation in order to avoid transfer of the sample and reagent dispensed to the first dispenser and the second dispenser, the calculator 115 updates the completion time of all analyzes taking into account the input of the cleaning operation, and the output unit 116 outputs the updated time completion of all analyzes. Preferably, the calculator 115 calculates the completion time of all analyzes until the analysis of all samples placed in the holder 101 is completed, based on the larger of the values received during the execution of the first group of analysis elements and during the execution of the second group of analysis elements. ...

The automatic analysis device is also configured to interrupt a new analysis element and continue analysis until the completion of the executed element when it detects that the required consumables are insufficient, namely when, for example, the reaction vessel used invariably in all analyzes becomes insufficient during analysis. The control unit 114 notifies the calculation unit 115 of the fact of the interruption. The calculator 115, which received the notification, sets the value -Dr to Ds and takes Ds as 0, taking into account the data of the estimated time of completion of the analysis, where the value of Ds exceeds 0. After that, the value of Dproc is calculated, and the estimated time of completion of all analyzes is updated in a manner similar to before recalculating.

The next is a high-priority test. A high priority test is an analysis element when the result is influenced by the very high sensitivity of the analysis element, and the component associated with the dispenser, when aspirating a sample for another analysis element, contaminates the sample for the next analysis. When this item of analysis is requested for a sample, the high-priority test is performed first, and the other test items do not start until the result is received. The reason for this is that if an abnormal high priority test is obtained, the test is performed again and the sample must be protected from contamination until it is completed. The update of the analysis completion time with respect to the item pending before the completion of the high-priority test is calculated at this point based on the updated data from the control unit 114, similarly to the calculation of the transfer time.

The present invention is not limited to the above-described embodiments, and various modifications are included. The above described embodiments have been explained in detail in order to provide a better understanding of the present invention and need not be limited to one embodiment including all contemplated configurations.

In addition, although each of the above-described configurations, functions, control units, and the like explained mainly by the example of creating a program in which part or all of them are implemented, of course, they can be implemented in hardware by implementing them partially and completely, for example, in an integrated circuit, etc. In other words, instead of a program, the functions of the control unit can be fully or partially provided, for example, by an integrated circuit such as an ASIC (application specific integrated circuit) and FPGA (field programmable gate array), etc.

List of positions

10: device for automatic analysis

11: control mechanism

101: sample and reagent holder

102a: first dispenser

102b: second dispenser

103: reactor

104a: first measuring device

104b: second measuring device

111: input block

112: scheduling device

113: storage device

114: control unit

115: computation block

116: output block

31, 32: table

4: monitor screen

41: real time display device

42: display device for the estimated completion time of all analyzes.

Claims (30)

1. A device for automatic analysis, containing: holder for holding the analyzed sample and the reagent required for the analysis, a reactor for mixing and reacting the sample and the reagent, dispenser for dispensing a sample or reagent from the holder into the reactor, an input unit for receiving input data of an analysis item, which is the sample data and the sample analysis item, a device control unit based on the analysis sequence determined from the analysis item data, and a unit for calculating the estimated time of completion of the analysis of all samples placed in the holder based on the analysis sequence. 2. The automatic assay apparatus of claim 1, wherein the holder holds the sample and reagent on a single disk. 3. A device for automatic analysis according to claim 1, comprising a device for outputting the estimated completion time of all analyzes, calculated by the calculation unit. 4. A device for automatic analysis according to claim 3, in which the calculator updates the estimated completion time of all analyzes taking into account the start of the sample analysis with respect to the analysis item, and the output device displays the estimated completion time of all analyzes, updated by the calculator. 5. A device for automatic analysis, containing: holder for holding a variety of analyzed samples and reagents required for analysis, the first dispenser for dispensing into the first vessel the sample and the reagent for the first group of analysis elements, a second dispenser for dispensing a sample and a reagent for the second group of analysis elements into the second vessel, a reactor for mixing and reacting the sample and reagent stored in the first vessel and in the second vessel, the control unit for the first dispenser and the second dispenser, and a unit for calculating the estimated completion time of an analysis element that makes up each group of analysis elements. 6. The device for automatic analysis according to claim 5, in which the first group of analysis elements is a group of analysis elements of the first type, the second group of analysis elements is a group of analysis elements of the second type, which differs from the analysis of the first type, and the calculator calculates the time of completion of all analyzes until the analysis of all samples placed in the holder is completed based on the greater of the values including the time required to complete the first group of analysis elements, the time required to complete the second group of analysis elements. 7. The automatic analysis apparatus according to claim 6, wherein the calculating unit calculates the completion time of all analyzes based on the delay in starting analysis by the control unit. 8. The automatic assay apparatus of claim 5, wherein the holder holds the sample and reagent on a single disc. 9. The automatic analysis apparatus of claim 7, wherein the control unit directs a cleaning operation to be performed to avoid transfer of samples and reagents dispensed to the first dispenser and the second dispenser. 10. The device for automatic analysis according to claim 9, wherein the calculating unit updates the completion time of all analyzes taking into account the cleaning operation. 11. The device for automatic analysis according to claim 10, comprising a device for outputting the time of completion of all analyzes, updated by the calculator. 12. The automatic analysis apparatus of claim 10, wherein the completion time of all analyzes is updated upon detection of insufficient sample or reagent during analysis of the sample. 13. The device for automatic analysis according to claim 5, in which the first group of analysis elements includes an analysis element related to biochemistry, and the second group of analysis elements includes an analysis element related to immunity.

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