JP2783449B2 - Analyzer line control system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention provides a first analyzer having a single analysis line, a plurality of analysis lines, and a sample which is shorter than the analysis cycle of the first analyzer. And a second analyzer for analyzing a plurality of analysis lines by aspirating a plurality of analysis lines and continuously supplying samples.

[Conventional technology]

Generally, in a biochemical automatic analyzer, a test sample is analyzed by reacting a test sample solution with a predetermined reagent in a reactor and performing colorimetric measurement of the reagent.

FIG. 5 is a flow diagram of a conventional automatic biochemical analyzer using a rotary reactor (Japanese Patent Publication No. 53-34079).
Is a sample supply unit, 35 is a sampling head, 40 is a measurement valve, and 49 is a rotary reactor.

The sample supply unit 31 includes a turntable 32, a number of sample tubes 3 provided on the circumference of the turntable 32, and a turntable driving device 34, and a sample liquid to be tested is injected into the sample tube 33, respectively.

The sampling head 35 includes a suction tube 36 and a moving device 37 for moving the suction tube 36. The tip of the suction tube 36 is inserted into a sample tube at a specific position among a large number of sample tubes on the turntable 32. Then, the sample liquid is sucked up. Also sampling head
35 can be inserted into the cleaning tank 38 as shown by the dotted line. In this state, the tip of the suction pipe 36 is cleaned by, for example, spraying water from the nozzle 39.

The sample liquid measurement valve 40 is composed of fixed members 41 and 42 and a rotating member 43 placed in close contact with the rotating members, and the rotating member has at least two holes 44a and 44b having the same volume. ing. The sampling head 35 is attached to the fixing member 41.
Is connected, and a switching valve 45 is connected to the fixed member 42. The switching valve 45 is connected to a pump 46, and the pump 46 is again connected to the cleaning liquid tank 47 through the switching valve 45.

The rotary reactor 49 has a rotating body 50 and a plurality of reaction tubes 51 on the same circumference held by the rotating body 50. The rotating body 50 is driven by a driving device and rotates intermittently. Symbols A, B, C,..., L in the figure indicate specific positions of the reaction tube 51. A valve is provided above and below the rotary reactor 49, and a light source 52 is provided substantially at the center of the rotating body. A detector 53 is disposed opposite the light source 52. The light source 52 and the detector
The position of 53 may be reversed.

The position A (specified first position) of the reaction tube 51 is a position where the sample and the first reagent are introduced into the reaction tube. A pipe 61 passing through a preheating chamber 60 is connected to the fixing member 41 of the measurement valve, a pump 62 is provided in the middle of the pipe, and a lower end is inserted into a container 64 filled with the first reagent 63. ing.
Two pipes 65 and 66 further penetrate the preheating chamber 60, and the second reagent flows into one 65 and the cleaning fluid flows into the other 66.

When the pump 62 is operated, the first reagent 63 is heated and then introduced into the measurement valve 40, and the sample liquid fractionated into the hole 44b of the rotating member 43 having a constant volume is extruded, and is moved to the position A. It is introduced into a certain reaction tube 51. A means for stirring the sample-first reagent mixture is placed at an intermediate position between the positions A and B. In this position, the top of the reaction tube is depressurized and air (or any other desired gas) is introduced into the reaction tube. Since the air moves upward as bubbles in the liquid, the sample liquid and the first reagent introduced at the position A are well stirred, thereby promoting the reaction.

The position of H is the introduction position of the second reagent. When the pump 71 is operated, the second reagent is sucked up, heated to a predetermined temperature in the preheating chamber 60, and then introduced into the reaction tube 51.

The intermediate position between H and I is a stirring means position similar to that located between A and B, in which air is introduced through the resistance tube 74 and the bubbles terminate or react with the first reagent. The sample in the process and the second reagent are stirred.

The position of J indicates the measurement position, and the light from the lamp 52 placed at the center of the rotating body is irradiated on the reaction solution through the reaction tube, and the transmitted light is detected by the detector 53.

The output signal from the detector 53 is sent to a recorder or a display device 76 via an amplifier 75, and the absorbance during the reaction between the sample and the reagent is recorded or displayed on a time axis. The amplifier 75
Is output to an A / D converter 77 and digitized, and the signal is sent to a data analyzer 78 such as an electronic calculator to perform a predetermined calculation.

K and L are washing positions where a washing liquid such as water is introduced from a pipe 66. The pipe 66 is inserted into the cleaning liquid tank 47 via an air mixing section 79 and a pump 80. The air mixing section 79 is inserted into the cleaning liquid tank 44 from the compressor 81 via a valve 82. Compressed air is sent from the compressor 81 to the air mixing section 79 via the valve 82, and air is mixed into the cleaning liquid from the pump 80. As a result, the cleaning liquid containing bubbles is introduced into the reactor 51, and the cleaning effect can be enhanced.

The middle of J and K, the middle of K and L, and the middle of L and A are positions where the liquid in the reaction tube is discharged. Compressed air is introduced from the compressor 81 into the upper part of the reaction tube via the valve 83 and the pipe 84, The liquid in the reaction tube is pushed out by the pressure, and the piping
It is sent through 85 to the sump.

Electrolyte analyzers are used for automated biochemical analyzers that measure the amount of GOT and GPT in serum and plasma by colorimetry by reacting with reagents as described above. It measures Na ⁺ , K ⁺ , and Cl ^- concentrations in plasma. In the electrolyte measuring device, a method of measuring a sample by diluting the sample to a certain magnification with a diluent for the following reasons is generally adopted. That is, in the electrolyte analyzer, since the sample has a high concentration, when the sample is introduced and measured at the same concentration, the degree of contamination and deterioration of the electrode is severe.
Therefore, it is necessary to sufficiently perform the cleaning. In addition, the longer the entire channel system, the larger the amount of sample used. Further, since a semi-solid component such as a protein or lipid is contained and a volume error occurs, a measurement error increases. For this reason, a diluted sample is used.

Both the biochemical automatic analyzer and the electrolyte measuring device analyze and measure components such as blood and urine, and there are some biochemical automatic analyzers in which the electrolyte measuring device is incorporated in a single device as an attachment.

[Problems to be solved by the invention]

However, when an electrolyte analyzer and a biochemical automatic analyzer are combined into a single device to form a series of sample suction systems, the electrolyte analyzer has only a single analysis line, whereas the biochemical automatic analyzer has only a single analysis line. Since the analyzer has a plurality of analysis lines, it is necessary to synchronize, and various problems occur.

FIG. 6 is a diagram for explaining an analysis cycle of each analyzer.

In the case of a certain electrolyte measuring device, since there is only a single analysis line, a sample is sucked, diluted, measured and washed as shown in FIG. ,
This is the analysis cycle.

In general, in an electrolyte measuring device, it is customary to increase the measurement accuracy by measuring the electrode potential a plurality of times. In this case, the difference between the first measurement and the second measurement based on the two measurements is the set value. If it is within the range, the measurement is terminated.

On the other hand, for example, in the case of a biochemical automatic analyzer having 96 analysis lines, as shown in FIG. 6 (b), when each analysis line is sampled for 6 seconds, it has an analysis time of 576 seconds. The analysis cycle is 6 seconds.

When the above-mentioned electrolyte measuring machine and the automatic biochemical analyzer are integrated into a single device and an analysis is to be performed by a series of sample supply systems, the analysis cycles of the two must be synchronized. Therefore, conventionally, in the case of the example shown in FIG. 6, the analysis time of the electrolyte measuring device is fixed at 54 seconds and synchronized. For this reason, in the electrolyte measuring device, it was not possible to increase the number of measurements and increase the analysis accuracy until the difference between the previous measurement and the measurement of the previous measurement was within the set value without increasing the analysis accuracy. . If the difference between the first and second measurements is greater than or equal to the set value, the analysis time must be increased so that three or four measurements can be repeated until the difference from the previous measurement is within the set value. There is a problem that it is necessary to increase the length, and the waste time increases.

Further, when the sample is blood and urine, the latter has a higher concentration, so that there is a problem that it is difficult to perform the same processing. Therefore, an electrolyte measuring device is prepared according to each sample. Therefore, there is a problem that the equipment cost is also increased.

The present invention has been made to solve the above problems, and facilitates synchronization between an electrolyte measuring instrument and a biochemical automatic analyzer, and aims to improve analysis accuracy even when configured with a single device. It is an object of the present invention to provide a line control system of an analyzer capable of performing the above. Another object of the present invention is to be applicable to different samples as well, such as blood and urine.

[Means for Solving the Problems] For this purpose, the present invention provides a first analyzer having a single analysis line and a plurality of analysis lines, and aspirates a sample in a cycle shorter than the analysis cycle of the first analyzer. A second analyzer for analyzing a plurality of analysis lines, and a line control system of the analyzer for continuously supplying a sample, wherein a sample aspirating time and an analysis cycle of the first analyzer are set to a second analyzer. It is characterized in that the number of sampling cycles of the analyzer is an integral multiple of that of the analyzer, and the analysis cycle of the first analyzer can be extended by an integral number of the number of cycles of the sample of the second analyzer.

[Action]

In the line control method of the analyzer according to the present invention, the sample suction time and the analysis cycle of the first analyzer are set to an integral multiple of the sample suction cycle of the second analyzer, and the analysis cycle of the first analyzer is set to the second. Since the sample can be extended by an integral multiple of the sample aspirating cycle of the first analyzer, synchronization can be achieved even if the first analyzer is extended. Therefore, the number of times of measurement in the first analyzer can be increased, and the number of washing steps can be increased, so that the measurement accuracy is improved, samples of different properties are analyzed, and a washing step is set according to the sample. be able to.

〔Example〕

 Hereinafter, embodiments will be described with reference to the drawings.

First, before describing the line control method of the analyzer of the present invention, an electrolyte measuring instrument applied to the present invention will be described.

FIG. 3 is a diagram showing a configuration example of an electrolyte measuring device applied to the line control system of the analyzer of the present invention, and FIG. 4 is a diagram showing an outline of a measurement flow.

In FIG. 3, a sampling cup 1 is a container for storing samples such as collected blood and urine. The sampling pipette 2 moves the sampling nozzle between the sampling cup 1 and the washing jar 3 to suck the sample,
The diluting liquid is discharged to the cleaning pot 3 and the discharged diluting liquid is sucked. The sampling pump 10 weighs and transfers the sample, and the dilution pump 11 performs dilution of the sample, cleaning of the dilution cell 5, and the like. A drain air valve 6 is a solenoid valve for supplying pressurized air for draining and washing the dilution cell 5, and a mixing air valve 7.
Is a solenoid valve for supplying pressurized air for stirring of the dilution cell 5, and the resistance tube 8 adjusts the pressure of the pressurized air for stirring.

The ion-selective electrode 21 is an electrode for selectively measuring the activity of Na, K, and Cl ions, and the comparative electrode 22 is a reference electrode for extracting the potential of each ion electrode. Flow cell 23
Is a cell for guiding a standard solution or sample to each electrode surface. The standard solution pump 27 is a pump for transferring the standard solution from the internal standard solution tank 31 to the pot 29, and the waste solution pump 26 is
A pump for transferring a standard solution or a sample into the flow cell 23 and draining it to the waste liquid tank 32, a comparative external cylinder liquid pump 25 includes:
This is a pump for transferring the comparative external cylinder liquid from the comparative external cylinder liquid tank 33 to the flow cell 23. Pot 29 contains flow cell 23
And a function of shutting off the flow path from the standard solution supply system during measurement.

The dilution cell 5 has upper and lower openings, and mixes the sample and the diluent with pressurized air. The upper opening is opened to the atmosphere, and the sample, the diluent, and the washing liquid (diluent) are opened from the lower opening. The upper opening is closed, the sample and diluent are agitated with pressurized air from the lower opening, the upper opening is opened to the atmosphere, and the waste liquid pump 26 is operated from the lower opening to dilute. Transfer the sample.

The pump change valve 9 is a rotary type valve including an upper stator S and a lower rotor R in the figure. By moving (rotating) the rotor R in the horizontal direction in the figure, the line Y1 has a switching position to be selectively connected to A, B, and C on the stator S side, and the sampling pump 10, the dilution pump 11. Switching between suction and discharge is performed. Similarly, the dilution valve 4 is a rotary valve including an upper stator S and a lower rotor R in the figure. Then, the lower opening of the dilution cell 5 connected to the stator S side is moved by rotating (rotating) the rotor R in the left-right direction in the figure, so that A,
It has a switching position that is selectively connected to B and C, and switches the stirring, transfer, and drainage of the diluent. The four-way change valve 13 is a connection between the dilution system and the measurement system,
Switching is performed, and at the time of measurement, the flow path is cut off from the dilution system.

 Next, the measurement flow will be described.

Since the weighing of the sample starts from a state in which the diluting system is filled with the diluent, an operation for setting the initial state will be described. When the pump change valve 9 is in the position shown in the drawing, the diluent tank 30 communicates with the sampling pump 10 and the dilution pump 11, and the other line B1 of the dilution pump 11 is closed. Solution pump 11
The diluting liquid is sucked from the diluting liquid tank 30 by the suction operation of.
Therefore, after suction of the diluent, the rotor R of the pump change valve 9 is shifted to the left in the figure to connect the line Y1 on the rotor R side to the line Y3 of the stator S. In this state, the line Y1 connected to the other side of the sampling pump 10 is closed on the stator S side of the pump change valve 9. Therefore, the diluting liquid is discharged from the line Y3 to the sampling pipette 2 through the dilution valve 4 by the discharging operation of the sampling pump 10. Thereafter, the pump change valve 9 is returned to the original position, the suction operation is performed again, and the same discharge operation is performed, whereby the dilution system is exhausted and filled with the diluent, and the sampling pipette 2 is further exhausted.
Is discharged from. Therefore, sampling pipette 2
Is set on the washing jar 3 side, the washing jar 3 is also filled with the diluent.

From the above state, the process proceeds to the weighing of the sample and the replacement and measurement of the internal standard solution as follows. The dilution valve 4, the pump change valve 9, and the four-way change valve 13 start in the illustrated state.

First, the sampling pump 10 performs a predetermined stroke suction operation with the sampling pipette 2 in the space position, and then performs the same suction operation in the order of the sampling cup 1, the space, and the washing jar 3. As a result, the line from the sampling pipette 2 to the dilution valve 4 contains the diluent-air-sample-air-diluent with the volume corresponding to the suction stroke of the sampling pump 10. The reason why the both sides of the sample thus weighed are insulated from the diluent with air is to prevent the sample from being diffused into the diluent by direct contact between the sample and the diluent.

On the other hand, while the standard solution pump 27 is activated to transfer the standard solution to the pot 29, the standard solution and the comparative external solution are transferred to the flow cell 23 by the waste liquid pump 26 and the comparative external solution pump 25.

Next, the dilution valve 4 moves the rotor to the right in the figure, connects the line on the stator side to which the sampling pipette 2 is connected and the line Y2 on the rotor side, and the pump change valve 9 connects the rotor to the rotor. Move to the right in the figure to connect the rotor line Y1 and the stator line Y2. Then, the sample is set in the line Y2 between the dilution valve 4 and the pump change valve 9 by the suction operation of the sampling pump 10. Thereafter, the dilution valve 4 is moved to the position shown in the figure, and the pump change valve 9 moves the rotor to the left in the figure to connect the line B1 on the rotor side to the line Y2 on the stator side. The sample and the diluting liquid are introduced into the diluting cell 5 by the discharging operation 11. In this case, the amount of the diluting liquid to be introduced into the dilution cell 5 is determined by the discharge stroke of the dilution pump 11. For example, when diluting by 20 times, if the sampling pump 10 weighs 10 ml, the 190 ml The discharge stroke of the dilution pump 11 is determined so that the diluent is introduced into the dilution cell 5.

When the sample and the diluent are introduced into the dilution cell 5, the dilution valve 4 moves the rotor to the left in the figure, opens the mixing air valve 7, and agitates the inside of the dilution cell 5 with pressurized air. In this case, since the upper line of the dilution cell 5 is closed on the rotor side of the dilution valve 4, pressurized air is supplied and stirred until the pressure in the dilution cell 5 is balanced.

When the stirring is completed, the dilution valve 4 moves the rotor further to the left in the figure, connects the bottom line of the dilution cell 5 to the four-way change valve 13 side, and the four-way change valve 13 The diluted sample is transferred to the flow cell 23 by operating the waste liquid pump 26 and introduced to the ion-selective electrode 21. In this case, the upper opening of the dilution cell 5 is connected to the drain air valve 6
And is opened to the atmosphere by a drain air valve 6.

Needless to say, the measurement of the internal standard solution is performed before the diluted sample is introduced into the electrode after the internal standard solution is replaced and the stable time has elapsed.

Then, after the stabilization time elapses after the diluted sample is introduced into the electrode, the four-way change valve 13 is returned to the state shown in the figure, the flow system is shut off, the sample is measured, and then washing using the internal standard solution is performed. Run.

On the other hand, after the diluted sample has been transferred to the flow cell 23, the dilution cell 5 is washed in the washing mode. in this case,
For example, using a diluent as the washing water, the dilution valve 4 is switched and introduced through the lower opening in the same manner as the sample. Thereafter, pressurized air is introduced from the drain air valve 6 through the upper opening, and then through the lower opening. Drain from the four-way change valve 13 to the drain.

Next, an embodiment of the present invention in which the above-mentioned electrolyte measuring instrument is incorporated in a conventional automatic biochemical analyzer will be described.

FIG. 1 is a diagram for explaining one embodiment of a line control system of an analyzer according to the present invention, and FIG. 2 is a diagram for explaining the entire line control.

In FIG. 1, the sample transport means 200 has a reading mechanism and a transport line driving mechanism, and controls the sample transport line 700 while reading the ID and inspection information of each label attached to the sampling cup. Control unit 1
00 is the sample transport unit 200 based on the ID and inspection information of each sampling cup read by the sample transport unit 200.
And the analysis control of the electrolyte measuring device 300 and the biochemical analyzer 500. Electrolyte analyzer 300, biochemical analyzer 500
Has sample suction mechanisms 400 and 600, performs sample suction from the sampling cup 800 on the transported sample transport line 700 based on an instruction from the control unit 100, and performs a predetermined analysis.

Next, overall line control by the control unit will be described with reference to FIG.

First, when the sample is transported to a predetermined position, the presence or absence of electrolyte measurement and the presence or absence of biochemical analysis are checked. At this time, in the control unit 100, the information of the label read by the sample transport unit 200, the sample at the suction position of the sample suction mechanism 400 of the electrolyte measuring device 300 from the sample transport history by the sample transport unit 200, the biochemical analyzer 500 Sample suction mechanism 600
The sample at the suction position can be recognized. Therefore, if both of the IDs and the analysis items are “Yes”, the start of the analysis is instructed to the electrolyte measuring device 300 and the biochemical analyzer 500 together with the analysis items. Based on this instruction, the electrolyte measuring device 300 and the biochemical analyzer 500 execute a predetermined sample suction from the sampling cup 800, respectively.
Perform analysis. Then, after the completion of the electrolyte measurement and the completion of the biochemical analysis, the process moves to the next sample transport.

Here, the completion of the electrolyte measurement is when the suction of the sample into the single analysis line is completed, and is an integral multiple of the analysis cycle of the biochemical analyzer 500. The completion of the biochemical analysis is when the suction of the sample to the analysis line corresponding to each analysis item is completed. Therefore, assuming that the sample suction time of the electrolyte measuring device 300 is 12 seconds, this 12
After a lapse of seconds, the analysis cycle of the biochemical analyzer takes 6 seconds.
In the case of 10 analysis items, it will be after 60 seconds have elapsed. Then, since the completion of the biochemical analysis is judged after judging the completion of the electrolyte measurement, for example, when the analysis item of the biochemical analyzer is 1, 12 seconds, and when 3, the analysis item is 18 seconds, the next sample is transported. Move on.

In the case of electrolyte measurement only or biochemical analysis only, the start of electrolyte measurement and biochemical analysis is instructed, respectively, and after completion, transfer to the next sample is carried out.

However, the start of the electrolyte measurement is after the analysis of the previous sample is completed. This is because, as described above, since the electrolyte measuring device does not perform a single analysis line, if the analysis time, that is, the analysis cycle is, for example, 54 seconds, it is not possible to aspirate the sample until this cycle is completed. is there. Therefore, when the electrolyte measurement is continuous, it takes 54 seconds to move to the next sample transport even when the number of analysis items in the biochemical analysis is small.

According to the present invention, in the electrolyte measuring device, the sample suction time is set to an integral multiple of the analysis cycle of the biochemical analyzer as described above, and the analysis cycle (analysis time) is extended by an integer ash of the analysis cycle of the biochemical analyzer. To make it possible,
As a result, synchronization can be achieved even when the analysis time for electrolyte measurement is extended.

The extension of the analysis time in the electrolyte measuring device is performed, for example, in the following cases.

The first is a case where the number of measurements is increased to increase the measurement accuracy. In the electrolyte measurement by the ion selective electrode method,
It is customary to measure the electrode potential a plurality of times to improve data quality. In order to obtain a minimum analysis time of, for example, 54 seconds, the measurement is performed twice, and the measurement is terminated when the difference between the first and second values is within the set value. However, when the difference is equal to or larger than the set value, the third and fourth measurements are repeated until the difference between two consecutive values falls within the set value. When the maximum number of times has been exceeded, the process ends as a measurement error.

The second case is that the measurement of the internal standard solution is repeated until the difference between the measured value and the previous measured value falls within the set value.

Third is the case of measuring an external standard solution. In this case, unlike the first and second cases, there is a possibility of a sampling error, so that it is necessary to repeat the basic analysis cycle again, and the sample is transferred in a cycle of 54 seconds instead of 12 seconds. . The condition for this repetition is determined by comparing with the immediately preceding measured value and determining whether or not the value is within the set value.
Therefore, the measurement is repeatedly performed at a cycle of 54 seconds until the measured value falls within the set value. However, when the first and second repetition conditions are the same, the same repetition measurement is performed. The measurement of the external standard solution is usually performed every day prior to the measurement of the sample.

Further, since the concentration of urine is higher than that of blood, there is a problem in performing a mixed analysis of urine and blood in consideration of calibration of electrode sensitivity and washing of lines. In the present invention, since the analysis time can be extended, the number of washing cycles is made larger than that of washing with blood, and when the sample is urine, for example, by doubling the washing cycle as compared with the case of blood,
Mixed analysis can be performed. With an electrolyte measuring machine that sets the blood analysis cycle to the above 54 seconds cycle, the analysis time is extended to 12 seconds and the analysis time is set to 66 seconds, so that urine can be handled as a sample using the normal blood measurement. Becomes

〔The invention's effect〕

As is clear from the above description, according to the present invention, since the analysis cycle of the electrolyte measuring machine is extended by an integral multiple of the analysis cycle of the biochemical automatic analyzer, the analysis cycle is continuously connected to the electrolyte measuring machine and the biochemical automatic analyzer. In this case, synchronization when supplying a sample can be easily achieved, and the number of measurements can be easily increased in order to increase analysis accuracy. Further, even if the number of washings of the electrolyte measuring device is increased, the analysis cycle corresponding to the time can be extended, so that blood and urine can be processed in the same system by increasing the number of washings.

[Brief description of the drawings]

FIG. 1 is a diagram for explaining one embodiment of a line control system of an analyzer according to the present invention, FIG. 2 is a diagram for explaining overall line control, and FIG. 3 is a diagram of an analyzer of the present invention. The figure which shows the example of a structure of the electrolyte measuring device applied to a line control system, 4th
The figure shows the outline of the measurement flow, FIG. 5 is the flow path diagram of a conventional biochemical automatic analyzer using a rotary reactor, and FIG. 6 is a view for explaining the analysis cycle of each analyzer. is there. 100: control unit, 200: sample transfer means, 300: electrolyte measuring device, 400 and 600: sample suction mechanism, 500:
Biochemical analyzer.

Claims (4)

(57) [Claims] 1. A second analyzer comprising a first analyzer having a single analysis line and a plurality of analysis lines, wherein a sample is sucked in a cycle shorter than the analysis cycle of the first analyzer to analyze the plurality of analysis lines. And a line control system of an analyzer for continuously supplying a sample, wherein the sample suction time and the analysis cycle of the first analyzer are set to an integral multiple of the sample suction cycle of the second analyzer. And an analysis cycle of the first analyzer can be extended by an integral multiple of a sample suction cycle of the second analyzer. 2. An electrolyte measuring machine is used as a first analyzer, and a biochemical automatic analyzer is used as a second analyzer. 2. The line control method for an analyzer according to claim 1, wherein the measurement is terminated when the value is within the range. 3. The line according to claim 2, wherein in the measurement of the external standard solution of the electrolyte measuring device, the sample is transferred in the analysis cycle and the analysis cycle can be repeatedly extended by a measurement error. control method. 4. The line control system for an analyzer according to claim 2, wherein the number of sample washing steps is increased or decreased according to the sample in the electrolyte measuring device.