JP3933499B2 - Sample analyzer and sample analysis system, and containers and racks used in them. - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a sample analyzer such as a blood analyzer and a urine analyzer, and more particularly to a sample analyzer that simplifies operations for shutdown processing.
[0002]
[Prior art]
In recent years, sample analyzers have become more sophisticated, and the throughput of specimens has improved. For example, in the blood analyzer, an apparatus capable of measuring 150 samples per hour (for example, XE-2100 (manufactured by Sysmex Corporation)) is realized.
[0003]
The blood analyzer described above is for measuring blood cell information such as the number of blood cells using a detector such as a flow cytometer after sucking blood into the apparatus. At the time of measurement, dirt (for example, a blood component previously measured) must not remain in the detector or the flow path. This is because, for example, the detection sensitivity fluctuates due to dirt remaining on the detector, or the detector is clogged, thereby adversely affecting the measurement result. On the other hand, as the number of specimens processed by the apparatus increases, the possibility of residual dirt has increased.
[0004]
Therefore, in the blood analyzer described above, the detector and the flow path are washed away with the diluent every time one sample is measured, and the dirt remains by performing a so-called shutdown operation every predetermined period (for example, once a day). Is preventing.
In the shutdown operation, the cleaning liquid (for example, sodium hypochlorite solution) is passed through the detector and the flow path, or the cleaning liquid is retained in the detector and each chamber for a predetermined time to remove the dirt.
[0005]
[Problems to be solved by the invention]
In the above-described shutdown operation, a user of the sample analyzer (hereinafter simply referred to as an operator) selects “shutdown operation” from an input / output unit such as a panel keyboard provided in the sample analyzer, Start by aspirating the cleaning liquid from the suction part.
However, this operation is complicated and requires learning of an operation method. In particular, in a facility that handles a large amount of samples such as a blood test center, a blood analysis system in which several to tens of blood analyzers are connected is used. Performing the above operation on all of these blood analyzers is a very complicated operation for the operator.
The present invention has been made in view of such circumstances, and provides a sample analyzer capable of shutting down the apparatus without an operator performing a special operation on the sample analyzer.
[0006]
The shutdown operation may include an operation of retaining the cleaning liquid in the detector or the like, and it takes a long time (several minutes to several tens of minutes) until the shutdown operation is completed. In the conventional sample analyzer, the operator has to wait until the shutdown operation is completed, and then give an instruction to turn off the apparatus or to measure the next sample.
[0007]
The present invention has been made in consideration of such circumstances, and it is possible to simplify the operation of the operator by automating the operation from the shutdown operation to the power-off or the measurement of the next sample. An analyzer is provided.
[0008]
[Means for Solving the Problems]
The present invention relates to a suction unit for sucking liquid, a measurement mechanism unit for measuring a sample, a liquid information reading unit for reading information on the type of liquid to be sucked, and information on the type of liquid read by the liquid information reading unit. If the sample is a sample, operate the measurement mechanism to measure the sample, and if the type of liquid is a cleaning liquid, operate the measurement mechanism to perform a shutdown operation using the cleaning liquid. A sample analyzer including a control unit is provided.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
For example, a pipette is used as the suction portion in the present invention, and a general one for a sample analyzer can be used for this. As the pipette used here, a pipette with a pointed tip generally called a piercer or a needle in preparation for a liquid container with a cap can be suitably used.
[0010]
The measurement mechanism section includes a sampling valve for quantifying a sample, a liquid heater for heating a reagent, a chamber for retaining a liquid therein, a syringe pump and a diaphragm pump for transferring a certain amount of liquid, a motor for operating them, It is composed of an air pressure source, a detector such as a flow cytometer, a tube connecting each part, a valve for opening and closing a flow path, etc., and a general one for a sample analyzer can also be used for this.
[0011]
A bar code reader or an IC chip reader can be used for the liquid information reading unit. In this case, as information stored in the barcode or IC chip, for example, a number indicating the cleaning liquid is determined in advance. The information stored in the barcode or IC chip is preferably the specimen number when the liquid to be sucked is a sample. The bar code and the IC chip may be attached to the liquid container, or may be attached to a rack on which the liquid container is mounted.
For the liquid information reading unit, a liquid container containing a liquid to be sucked or a sensor for detecting the shape of the rack (for example, a micro switch or an optical sensor) can be used. In this case, for example, the shape of the liquid container or the rack is determined depending on whether the liquid to be stored is a sample or a cleaning liquid.
The liquid information reading unit may use an optical sensor that irradiates light to the liquid container and detects whether or not the light is transmitted. If the liquid is a sample (for example, blood), light is not transmitted. If the liquid is a cleaning liquid, light is transmitted. This makes it possible to determine whether the liquid in the liquid container is a sample or a cleaning liquid.
[0012]
Examples of the liquid information read by the liquid information reading unit include information on whether the liquid is a sample or a cleaning liquid, and information on whether the liquid is whole blood or plasma. The types of information are not limited to these, and are not limited to two types.
[0013]
The control unit controls the operation of the measurement mechanism unit based on the liquid information read by the liquid information reading unit. For example, if the liquid is a sample, a measurement operation is performed, and if the liquid is a cleaning liquid, the measurement mechanism unit is caused to perform a shutdown operation. If the liquid is whole blood, the measurement mechanism unit performs a measurement operation for whole blood, and if the liquid is plasma, the measurement operation for plasma is performed. This eliminates the need for the operator to change the operation of the sample analyzer according to the type of liquid, and simplifies the operation.
[0014]
As the control unit, a microcomputer or personal computer including a CPU, a ROM, and a RAM can be used.
[0015]
The operation of the measurement mechanism unit may include a measurement operation for measuring the sample and a shutdown operation for retaining the cleaning liquid in the measurement mechanism unit for a predetermined time.
The cleaning liquid may be retained in a portion having a high possibility of adhesion of dirt, for example, in a reaction chamber for reacting a detector, a sample, and a reagent, a drain chamber for storing a drain liquid (waste liquid), or the like.
Examples of the detector include a flow cytometer, a blood cell detector that detects the number of red blood cells and platelets by an electric resistance method, and a hemoglobin detector that detects the amount of hemoglobin by a colorimetric method.
The operation of the measurement mechanism unit may include a measurement operation for measuring the sample and a shutdown operation for causing the cleaning liquid to flow into the detector of the measurement mechanism unit.
The shutdown operation is an operation for cleaning the inside of the sample analyzer, and has a higher cleaning effect than the cleaning operation performed for each measurement operation of the sample.
As the cleaning liquid, a sodium hypochlorite solution is preferable because of its high cleaning effect, but a diluting liquid or water can also be used.
[0016]
The control unit may turn off the power source of the sample analyzer after the measurement mechanism unit performs a shutdown operation.
The control unit may place the sample analyzer in a liquid suction standby state after the measurement mechanism performs a shutdown operation.
The liquid suction standby state is a so-called standby state in which the next liquid can be sucked as it is.
[0017]
The sample analyzer of the present invention includes a selection unit for selecting whether to turn off the power source of the sample analyzer after executing the shutdown operation or to place the sample analyzer in a liquid suction standby state after executing the shutdown operation. The unit may be configured to control the operation of the sample analyzer according to the selected information.
Thus, the operator can select whether to turn off the power supply of the sample analyzer after the shutdown operation or to start the measurement of the next sample as it is.
[0018]
A plurality of sample analyzers of this invention may be connected. This provides a sample analysis system with improved sample throughput. As a sample analysis system, for example, the HST series (manufactured by Sysmex Corporation) is known.
[0019]
The present invention provides a container containing a liquid to be sucked into a sample analyzer, to which information indicating that the liquid is a cleaning liquid is added.
The present invention also provides a rack for mounting a container containing a liquid to be sucked into a sample analyzer, to which information indicating that the liquid is a cleaning liquid is added.
Examples of information indicating that the liquid is a cleaning liquid include a barcode, an IC chip, and the shape of a container or a rack (the size of the container or the rack or a protrusion attached to the container or the rack).
[0020]
【Example】
Hereinafter, the present invention will be described in detail based on embodiments shown in the drawings. This does not limit the invention.
FIG. 1 is a plan view showing the configuration of a blood analysis stem in which a sampler for transferring a rack in which a liquid container is mounted is connected to the blood analyzer of one embodiment according to the present invention. A blood analyzer 218 is installed in the center of the blood analysis system 1, and a rack shipping unit 208 that stocks a plurality of racks 226 carrying the liquid containers 200 on the right side and carries them out one by one collects the rack 226 on the left side. Each rack collection unit 216 for stocking is provided. A transfer unit 210 is provided between the rack dispatch unit 208 and the rack collection unit 216 for transferring the racks 226 one by one (transverse feed). The rack shipping unit 208, the rack collection unit 216, and the transfer unit 210 are collectively referred to as a sampler 2.
[0021]
The blood analyzer 218 includes a barcode reader 217 for reading the barcode of the liquid container 200, a stirring unit 211 for stirring the liquid stored in the liquid container 200, and aspirating the stirred liquid from the liquid container 200. , A measuring mechanism 214 for measuring the sucked liquid by quantification, dilution, hemolysis, etc., a control unit 201, an input unit 202, an output unit 203, and a power supply unit 215. Although details will be described later, the control unit 201 includes a CPU, a ROM, a RAM, and a hard disk drive (HDD). The input unit 202 and the output unit 203 are composed of a panel keyboard LCD. The power supply unit 215 supplies power to each unit (also supplies power to the sampler 2). The control unit 201, the input unit 202, the output unit 203, and the power supply unit 215 are configured by a personal computer, and are connected to the measurement mechanism unit 214 via an interface such as TCP / IP (Transmission control protocol // internet protocol). May be.
In this embodiment, only one blood analyzer 218 is connected to the sampler 2, but a plurality of blood analyzers 218 may be connected.
In this embodiment, the barcode reader 217 is directly connected to the control unit 201, but may be connected via a control unit (not shown) of the sampler 2.
[0022]
As shown in FIG. 2, each rack 226 has a test tube stand shape so that ten liquid containers 200 can be mounted. The liquid container 200 is a cylindrical test tube container with a bottom, and the upper end opening is closed with a cap 7, and blood is used as a sample inside or a sodium hypochlorite solution (for example, Cell Clean (manufactured by Sysmex Corporation) as a cleaning solution. )).
[0023]
Although not shown, a bar code is affixed to the liquid container 200. The barcode is read by the barcode reader 217 through the slit 9 (FIG. 2). In the barcode, the sample number of the sample when the sample is stored in the liquid container 200, and information indicating that the cleaning solution is stored when the cleaning solution is stored in the liquid container 200 (for example, , 99-99999 may be preliminarily determined to indicate the cleaning liquid).
[0024]
Hereinafter, with reference to FIG. 3, the internal configuration of blood analyzer 218, particularly control unit 201 will be described in detail.
FIG. 3 is a block diagram showing the internal configuration of the blood analyzer 218.
As described above, blood analyzer 218 includes bar code reader 217, LCD panel keyboard as input unit 202 and output unit 203, measurement mechanism unit 214, stirring unit 211, suction unit 212, power supply unit 215, and control unit 201. It is configured.
The control unit 201 includes an analysis unit 60, a liquid type determination unit 61, an operation control unit 62, a power off unit 63, a suction standby unit 64, a power off / standby selection unit 65, a power off / standby database (hereinafter referred to as a database). 70, a measurement operation DB 71, a shutdown operation DB 72, and an analysis result DB 73. These are composed of a CPU, a ROM, a RAM, and a hard disk drive (HDD), and each unit is connected by a BUS.
A well-known thing can be used as the measurement mechanism part 214, the stirring part 211, and the suction part 212, for example, what is used for XE-2100 (made by Sysmex Corporation) can be used.
[0025]
FIG. 4 is a fluid circuit diagram showing a part of the suction unit 212 and the measurement mechanism unit 214 and the control unit 201. As shown in the figure, the measurement mechanism unit 214 includes a sampling valve 29 for quantifying a sample, liquid heaters 100a and 100b for heating a reagent, and chambers 22, 30, 41, 46, and 49 for retaining a liquid therein. 54, Syringes 31 and 38 for transferring a certain amount of liquid, diaphragm pumps 23 and 36, motors for operating them, negative pressures 25 and 37, positive pressures 28 and 53, a flow cell 39 for measuring a sample, and various parts are connected. Tube, a valve for opening and closing the flow path, and the like.
Hereinafter, the operation of the blood analysis system 1 will be described with reference to the flowcharts shown in FIGS. 1 to 4 and FIG. 5.
[0026]
After the operator of the blood analysis system 1 executes the shutdown operation (the shutdown operation will be described later), the blood analysis system 1 is automatically turned off as it is or the power of the next sample is not turned off. Select whether to enter the liquid suction standby state so that measurement is possible. Specifically, the power-off / standby selection unit 65 causes the LCD panel keyboards 202 and 203 to display a screen prompting selection of “power-off” or “liquid suction standby”. The information selected by the operator is stored in the power off / standby DB 70 (S0). This operation need not be performed every time the sample is measured, and may be performed only when the system is introduced, for example.
[0027]
When a plurality of racks 226 loaded with the liquid containers 200 are arranged in a vertical line in the rack shipping section 208 (S1), all the racks 226 move forward while being aligned in the direction indicated by arrow C (S2), and then the top rack 226 is sent to the left transfer unit 210 and is laterally fed in the direction indicated by the arrow D (S3).
[0028]
The rack 226 transferred by the transfer unit 210 stops at a position where the leading liquid container 200 faces the barcode reader 217. When the barcode reader 217 reads the barcode of the first liquid container 200 (S4), the information is sent to the liquid type determination unit 61 of the control unit 201, and the liquid container 200 is again fed laterally to the stirring unit 211. Stop at a position opposite to.
[0029]
When the first liquid container 200 is stirred by the stirring unit 211 (S5), the rack 226 moves by a predetermined distance (arrangement pitch of the liquid containers 200), and the liquid is sucked from the liquid container 200 after stirring by the suction unit 212. Aspirated (S6). The rack 226 that has completely sucked the liquid in the mounted liquid container 200 is transferred to the rack recovery unit 216 and delivered in the direction indicated by the arrow E.
[0030]
Based on the information sent from the barcode reader 217, the liquid type determination unit 61 determines whether the liquid in the liquid container 200 is a sample (blood) or a cleaning liquid (S7).
When the liquid in the liquid container 200 is blood, the operation control unit 62 reads the measurement operation program from the measurement operation DB 71 and causes the measurement mechanism unit 214 to perform a measurement operation (S8). The measurement operation will be described later with reference to FIG.
[0031]
The measurement result obtained by the measurement mechanism unit 214 is analyzed by the analysis unit 60 and displayed on the LCD panel keyboards 202 and 203. The analysis result is stored in the analysis result DB 73 (S9). Then, the blood analysis system 1 returns to the liquid suction standby state waiting for the next liquid suction (S10).
When the rack 226 is placed on the rack shipping unit 208 or the transfer unit 210 (S10-1) The rack sending unit 208 or the transfer unit 210 automatically continues the forward or lateral feed of the rack (S2 or S3), and continues the operation of the blood analysis system 1 described above (S2 to S10 or S13 or S14).
[0032]
As a result of the determination in step S7, when the liquid in the liquid container 200 is a cleaning liquid, the operation control unit 62 reads the shutdown operation program from the shutdown operation DB 72 and causes the measurement mechanism unit 214 to perform a shutdown operation (S11). . The shutdown operation will be described later with reference to FIG. During the shutdown operation, the operation of the sampler 2 is stopped.
[0033]
When the operator has selected to automatically turn off the power of the blood analysis system 1 after executing the shutdown operation, that is, when “Power Off” is stored in the power off / standby DB 70 (S12), After the shutdown operation ends, the power-off unit 63 instructs the power supply unit 215 to stop supplying power. Thereby, the power supply of the blood analysis system 1 is turned off (S13).
[0034]
When the operator has automatically selected the blood analysis system 1 to be in the liquid suction standby state after executing the shutdown operation, that is, when “liquid suction standby” is stored in the power-off / standby DB 70 (S12) After completion of the shutdown operation, blood analysis system 1 returns to the liquid suction standby state in accordance with an instruction from suction standby unit 64 (S14).
When the rack 226 is placed on the rack shipping unit 208 or the transfer unit 210 (S14-1) The rack sending unit 208 or the transfer unit 210 automatically restarts the forward or lateral feed of the rack (S2 or S3), and restarts the operation of the blood analysis system 1 described above (S2 to S10 or S14).
As a result, the measurement of the sample can be resumed without any special operation by the operator.
[0035]
Hereinafter, the measurement operation will be described with reference to FIG. Unless otherwise stated, the valve is in a closed state.
In the figure, first, the valve 21 is opened to allow the reagent chamber 22 and the diaphragm pump 23 to communicate with each other. Next, when the valve 24 is opened, 1 mL of the reagent (diluent) is sucked into the diaphragm pump 23 by the negative pressure 25. When the valves 21 and 24 are closed and the valves 26 and 27 are opened, 1 mL of reagent is supplied from the diaphragm pump 23 to the liquid heater 100a through the nipple 15a and heated by the positive pressure 28.
By repeating the above operation a plurality of times, the reagent that has risen to a predetermined temperature is sent out from the nipple 17a and fills the flow path up to the front of the reaction chamber 30 through the reagent flow path 29a of the sampling valve 29.
[0036]
Next, the syringe 31 is operated to suck the sample (blood) from the liquid container 200 into the quantitative flow path 29 b of the sampling valve 29. The sampling valve 29 is rotated to quantify the 4 μL sample, and the quantitative flow path 29b is switched to the reagent flow path 29a. As a result, the sample is sandwiched by the reagent. Therefore, when the diaphragm pump 23 is operated as described above to deliver 1 mL reagent from the liquid warmer 100a, 4 μL of the sample flows into the reaction chamber 30 together with 1 mL of reagent, and is stirred in the reaction chamber 30 so that the diluted sample is obtained. Created.
[0037]
Next, when the valves 33, 34, and 35 are opened and the negative pressure 37 is applied to the diaphragm pump 36, the flow path between the reaction chamber 30 and the valve 34 is filled with the diluted sample. When the valves 33 and 34 are closed and the syringe 38 is operated, the diluted sample is discharged from the nozzle 40 in the flow cell 39.
[0038]
On the other hand, when the valve 57 is opened, the sheath liquid is supplied from the chamber 41 to the flow cell 39 by the positive pressure 42 and wraps the diluted sample discharged from the nozzle 40 to form a so-called sheath flow. The sheath flow is irradiated with light from the light emitting element 43, and light such as scattered light or fluorescence from particles contained in the diluted sample is detected by the light receiving element 44.
[0039]
The analysis unit 60 of the control unit 201 analyzes the characteristics of the particles in the diluted sample based on the detected light intensity. Then, the diluted sample forming the sheath flow and the sheath liquid are discharged to the drainage chamber 46.
[0040]
Subsequently, a cleaning operation is performed. This cleaning operation is performed for each measurement operation and is not a shutdown operation.
First, the valves 47 and 48 are opened. A positive pressure 50 is applied to the diluent chamber 49 to cause the diluent to flow to the valve 47, the nipple 16a, the liquid warmer 100a, the nipple 18a, the sampling valve 29, and the reaction chamber 30, and before the reaction chamber 30 overflows. Valves 47 and 48 are closed.
[0041]
The valves 33, 34, and 35 are opened, a negative pressure 37 is applied to the diaphragm pump 36, and the diluent is sucked from the reaction chamber 30 to the diaphragm pump 36 through the valves 33 and 34. When the valves 34 and 35 are closed, the valves 51 and 52 are opened, and the positive pressure 53 is applied to the diaphragm pump 36, the diluted solution of the diaphragm pump 36 is discharged to the drainage chamber 54 through the valve 51. Next, when the valve 55 is opened, the remaining dilution liquid in the reaction chamber 30 is also discharged into the drainage chamber 54.
[0042]
Next, when the valves 48 and 56 are opened and a positive pressure 50 is applied to the diluent chamber 49, the diluent passes from the diluent chamber 49 through the valve 56, the liquid warmer 100 b, the syringe 38, the nozzle 40 and the flow cell 39. It is discharged to the drain chamber 46. As a result, blood remaining in the flow path is discharged, and the liquid can be sucked from the next liquid container 200.
[0043]
Hereinafter, the shutdown operation will be described with reference to FIG. In this embodiment, the shutdown operation refers to an operation in which the cleaning liquid is allowed to flow into the flow cell 39 to be retained, but is not limited thereto, and the cleaning liquid may be retained in each chamber as necessary. Unless otherwise stated, the valve is in a closed state.
The sampling valve 29 is switched, and the liquid container 200 (the cleaning liquid is stored in the liquid container 200) and the valve 59 are communicated with each other via the cleaning liquid channel 29c of the sampling valve 29.
[0044]
When the valves 34, 35, 59 are opened and the negative pressure 37 is applied to the diaphragm pump 36, the flow path between the valve 34 and the valve 59 is filled with the cleaning liquid.
When the valves 34, 35, 59 are closed and the syringe 38 is operated, the cleaning liquid filled in the flow path between the valve 34 and the valve 59 is discharged from the nozzle 40 in the flow cell 39. The cleaning liquid discharged from the nozzle 40 stays in the nozzle 40 and the flow cell 39.
Leave in this state for a predetermined time (about 5 to 10 minutes). The predetermined time may be a fixed time or may be set by an operator.
[0045]
When the valves 48 and 56 are opened and a positive pressure 50 is applied to the diluent chamber 49, the diluent passes through the valve 56, the liquid warmer 100 b, the syringe 38, the nozzle 40 and the flow cell 39 from the diluent chamber 49. The cleaning liquid staying in the flow cell 39 is discharged to the drain chamber 46.
At the same time, when the valve 57 is opened, the sheath liquid is supplied from the chamber 41 to the flow cell 39 by the positive pressure 42 and discharged together with the cleaning liquid staying in the flow cell 39 to the drain chamber 46.
Next, the drainage liquid staying in the drainage chambers 46 and 54 is discharged to the outside of the apparatus.
This completes the shutdown operation.
[0046]
When “power off” is selected as the operation after the shutdown operation by the operator, the power off unit 63 instructs the power source unit 215 to stop power supply.
When “liquid suction standby” is selected as the operation after the shutdown operation by the operator, the suction standby unit 64 causes the agitation unit 211, the suction unit 212, the measurement mechanism unit 214, and the like to wait for the next liquid to be sucked. Instruct to receive.
[0047]
In the sample analyzer of the present invention, the control unit 201 may be provided with a power-on unit that automatically turns on the sample analyzer at a time preset by the operator. Accordingly, the sample analyzer can be set in a liquid suction standby state when the operator is at work, and the operator can start measuring the sample immediately after the work.
[0048]
If the operator mistakenly puts the cleaning liquid into the sampler 2 in the time zone when the sample is to be measured and the shutdown operation is started, the sample measurement is interrupted.
Therefore, the sample analyzer of the present invention may be configured such that an operator can set in advance a time period in which the shutdown operation can be started. Specifically, the control unit 201 may include a shutdown startable time setting unit for setting a startable time zone for the shutdown operation and a shutdown startable time DB for storing the startable time zone.
[0049]
Even if the sample analyzer of the present invention is configured so that an error occurs to the sample analyzer manufacturer or operator's mobile phone when an operation error occurs during the shutdown operation Good. As a result, the sample analyzer can be quickly restored.
[0050]
【The invention's effect】
According to the sample analyzer of the present invention, the operator can shut down the apparatus without performing any special operation on the sample analyzer.
Further, according to the sample analyzer of the present invention, it is possible to simplify the operation of the operator by automating the operation from the shutdown operation to the power-off or the next sample measurement.
[Brief description of the drawings]
FIG. 1 is a plan view showing a configuration of a blood analysis stem in which a sampler is connected to a blood analyzer of one embodiment according to the present invention.
FIG. 2 is a perspective view of a rack 226 on which a liquid container 200 is mounted.
3 is a block diagram showing an internal configuration of blood analyzer 218. FIG.
4 is a fluid circuit diagram showing a suction unit 212, a part of a measurement mechanism unit 214, and a control unit 201. FIG.
FIG. 5 is a flowchart for explaining the operation of the blood analysis system 1;
[Explanation of symbols]
1 Blood analysis system
2 Sampler
200 Liquid container
201 Control unit
202 Input section
203 Output unit
208 rack shipping department
210 Transfer section
211 Stirrer
212 Suction unit
214 Measuring mechanism
215 Power supply
216 Rack recovery unit
217 Bar code reader
218 Blood analyzer
226 racks

Claims (10)

When the suction unit for sucking the liquid, the measurement mechanism unit for measuring the sample, the liquid information reading unit for reading information on the type of liquid to be sucked, and the liquid type information read by the liquid information reading unit are samples, And a control unit that operates the measurement mechanism so as to perform a shutdown operation using the cleaning liquid when the type of the liquid is a cleaning liquid . Shutdown operation, the sample analyzer according to claim 1 including the behavior of the wash solution in the measurement mechanism section Ru a predetermined time dwell. Shutdown operation, the sample analyzer according to claim 1 including the behavior of Ru allowed to flow into wash solution to the measurement mechanism unit of the detector. Control unit, the measurement mechanism section is a sample analyzer according to claim 1 to claim 3, wherein to turn off the sample analyzer After executing the shutdown operation. Control unit, the sample analyzer according to claim 1 to claim 3, wherein to the liquid suction standby state of the sample analyzer after measurement mechanism unit executes a shutdown operation. A selection unit for the sample analysis device after the execution of the shutdown operation to turn off the power to choose whether to liquid suction standby state of the sample analysis device after execution of the shutdown operation, the information control unit selected 6. The sample analyzer according to claim 1 , wherein the operation of the sample analyzer is controlled according to the above . Liquid information reading unit, a sample analyzer according to claim 1 to claim 6, wherein a bar code reader. A sample analysis system in which a plurality of sample analyzers according to claim 1 are connected. A container with claims 1 to liquids which are aspirated into the sample analyzer according to claim 7, wherein, container information indicating that the liquid is the cleaning liquid is added. A rack for mounting a container containing a liquid to be sucked into the sample analyzer according to any one of claims 1 to 7 , to which information indicating that the liquid is a cleaning liquid is added.

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