JPS63292066A - Sample diluting method - Google Patents

Abstract

PURPOSE:To improve analyzing accuracy, by discharging a specified amount of a sample so that the attaching amount on a container wall is suppressed to the minimum value, discharging a specified amount of diluting liquid at a high speed from a place higher than the sample discharging position, and diluting and regulating the sample to a specified concentration. CONSTITUTION:A path from a pure water well 7 to a nozzle 22 is filled with pure water by a switching driving of a diluter driving part 42 and a three-way solenoid valve 6. Then a specified amount of a sample is sucked through the nozzle 22 from a sample container on a sample line 31 on a turntable 3. Then, a sampler arm 21 is turned, and the nozzle 22 is set over a specified diluting container on a diluting line 32 on the table 3. Thereafter, a rack pinion 26 is driven. The tip of the nozzle 22 is stopped at a position in the vicinity of the bottom of the diluting container. The sucked sample is quietly discharged. When the discharge of the sample is finished, the pinion 26 is driven, and the nozzle is lifted. a specified amount of pure water is discharged at a high speed from a position higher than the position at the time of the sample discharge under this state. Since the sample is diluted into a specified concentration by the force of the discharging of pure water, the accuracy of analysis is improved.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application This invention relates to a method for diluting a specimen. More specifically, the present invention relates to a specimen dilution method used in an automatic analyzer suitable for clinical biochemical tests of biological fluid specimens such as serum, plasma, and urine.

(b) Conventional technology Some automatic analyzers used in the field of clinical biochemistry -
The sample prepared in advance on the sample line on the turntable is sucked in a certain amount from the nozzle of the sampler in which the flow path to the nozzle is filled with dilution water in advance, and is introduced into the nozzle tip and held there. , the nozzle in this state is set at a predetermined position in the dilution container of the dilution line on the turntable, and at that position, the diluent extrudes the specimen and discharges a predetermined amount of the diluent at a constant discharge speed. A method of diluting a specimen to a predetermined concentration in a dilution container is used.

(c) Problems to be Solved by the Invention However, in the above sample dilution method, the sample discharged first and the diluent discharged later cannot be sufficiently mixed, resulting in a concentration gradient, resulting in dilution. When re-sampling the sample that has been sampled, errors may occur, leading to a decrease in analysis accuracy. A situation where the sample and diluent are not sufficiently mixed is that the sample that is discharged first settles at the bottom of the reaction vessel, and the diluent that is subsequently discharged is not sufficiently stirred and the sample at the bottom in the discharge liquid is mixed. Concentration becomes relatively high.

Additionally, in general, in the above-mentioned automatic analyzers, etc., the discharge speed is fast and the nozzle position set in the reaction vessel is eccentric, so the discharged liquid rises up the opposite wall of the vessel, but the liquid does not reach the bottom of the vessel. As the amount accumulates, the elevated position shown above will decrease. Therefore, the liquid discharged first rises highest along the vessel wall. Since this first discharged liquid is the specimen stock solution, this stock solution adheres to the vessel wall and remains, resulting in a relatively low concentration.

The present invention has been made in view of the above situation, and aims to provide a method for diluting a specimen that can sufficiently mix the specimen and diluent and guarantee a predetermined dilution concentration by changing the discharge conditions of the specimen and diluent. It is.

(d) Means for Solving the Problems Thus, according to the present invention, a certain amount of the sample sucked into the nozzle of the sampler is pushed out from the tip of the nozzle using a predetermined amount of diluent supplied from the rear of the nozzle. A method of diluting the specimen by discharging the sample together with the diluent into a container, in which the nozzle tip opening is positioned near the bottom of the container (first discharge position) at the time of discharge, and the total discharge amount is reduced at that position. After discharging a portion of the liquid at a low discharge speed, the nozzle is pulled up to a second discharge position above the first discharge position,
A method for diluting a specimen is provided, which is characterized in that the remaining portion is discharged at a high discharge speed at that position.

In the method of the present invention, when discharging the specimen and diluent into the reaction container, the discharging position of the sampler nozzle is set at two stages, 1st and 2nd, and the discharging speed at each set position is set at 2 stages. It is characterized by being discharged in stages.

Regarding the two-stage set positions, the first discharge position is selected such that the nozzle tip of the sampler is near the bottom of the reaction vessel and does not come into contact with the predetermined amount of liquid discharged and retained. The setting position of the rear stage is selected to be higher than the front stage and a position where the liquid to be discharged does not travel along the vessel wall.

The low discharge speed at the first discharge position is defined as the speed at which the highest point at which the discharged liquid rises from the bottom of the container to the vessel wall is kept below the vessel wall immersion position due to the total amount of liquid discharged into the reaction vessel. This means that a speed close to that of natural fall is preferable. Further, the high discharge speed at the second discharge position is higher than the speed at the first discharge position and has a sufficient stirring effect, but is preferably such a speed that the liquid does not bounce out of the container.

The discharge volume at the first discharge position is a part of the total discharge volume of the sample and diluent, and as mentioned above, the volume that does not come into contact with the nozzle at that position is selected. Corresponding amounts are preferred.

The mechanism for setting the nozzle position in two stages as described above is a mechanism in which the sampler is configured to be vertically movable using a rack and pinion, etc., and a mechanism is provided in which the original sampler drive section and this vertical drive section are provided, and each of these drive circuits is controlled by a microcomputer. can be mentioned.

An example of a mechanism for variable discharge speed in two stages is a cylinder pump for sample suction/discharge connected to the nozzle of the sampler, and a cylinder pump connected to the cylinder pump for diluent supply. Examples include a mechanism that is composed of a cylinder pump, in which each cylinder pump drive section is connected to a respective drive circuit, and the drive is controlled by microcontrollers through these circuits.

(E) Effect According to the present invention, in a sampler that holds a certain amount of sample at the tip of the nozzle and a diluent is introduced behind it, when discharging, the tip of the nozzle is first placed near the bottom of the reaction vessel (the first In this state, a part of the total amount including the sample is gently discharged and remains at the bottom of the reaction vessel. Next, the nozzle is raised and its tip is set higher than the first discharge position, and the remaining liquid is discharged from that position at a higher speed than at the time of discharge, stirring and supplying the remaining liquid.

The present invention will be described in detail below with reference to Examples, but the present invention is not limited thereby.

(F) Embodiment FIG. 1 is an explanatory diagram of a partial configuration of an example of an automatic biochemical analyzer constituting a specimen dilution section for carrying out the method of the present invention.

In the figure, the sample diluting section (1) is mainly composed of a sampler (2), a turntable (3), a guilter (4), and a control section (5) that controls the driving of these.

The sampler (2) has a horizontal sampling arm (2
1), a sample suction/discharge nozzle (22) attached downward to one end of the arm, and the arm (21).
A rotation shaft (23) is attached to the other end in parallel with the nozzle (22) and supports the arm horizontally and rotatably; a pipetter (24) for aspirating and discharging a predetermined amount of the sample; It consists of a transfer pipe (a) that connects the pipetter (24) and the nozzle (22). The above rotation axis (23
) is provided with a rotating pulley (25), and a rack and pinion (26) is configured below the pulley (25). The pulley (25) and rack pinion (26) are equipped with respective driving motors (27) and (28),
The sampling arm (21) is driven by these motors.
horizontal rotation and vertical movement of the nozzle (22). A cylinder pump with a capacity of 30 μQ is used for the pipettor (24), and is connected to a pipetter drive unit (29). The pipettor drive section (29) uses a stepping motor, and by varying the number of rotations by varying pulses and adjusting the pipetter drive, the discharge speed can be adjusted.

The turntable (3) has a sample line (31) on its outer periphery and a dilution line (32) on its inner periphery, and includes a rotation drive unit (33) that intermittently rotates the table in a fixed direction. .

The Guilutor (4) is composed of a cylinder pump (41) with a capacity of 1000 μQ and a Guilutor drive section (42) that drives the pump. The guilter (4) is connected to a three-way solenoid valve (6). This three-way solenoid valve (
6) is connected to the pipettor (24) and the other to the pure water storage tank (7) through pipes (b) and (c), respectively, and the pipe (b) is connected to the pipettor (
24) and communicates with the transfer pipe (a) through a communication path (not shown) set in the pipe (24). Therefore, by driving the guilter and switching the three-way solenoid valve, a predetermined amount of pure water can be discharged from the pure water storage tank through the nozzle. A stepping motor is used in the guilter drive section (42), and is set to be able to drive at a higher speed than the pipettor drive section (29).

The control unit (5) is composed of a CPU, and includes the sampler rotation shaft drive motor (27), a rack and pinion drive motor (28), a turntable rotation drive unit (33), a pipetter drive unit (29), It is electrically connected to a circuit section (8) having drive circuits for driving each of the guilter drive section (42) and the three-way solenoid valve (6). Therefore, the control signal output from the control section (5) is transmitted to each drive circuit, and each drive section can be driven and controlled in accordance with a preset order.

Next, the specimen dilution method of the present invention will be explained using the operation of the above-mentioned apparatus.

First, the flow path from the pure water storage tank to the nozzle is filled with pure water by switching drive of the Guilutor drive unit and the three-way solenoid valve. In this state, the nozzle is set on a predetermined sample container on the sample line of the turntable by rotation of the sampler arm, and then the rack and pinion is driven to insert the nozzle into the sample container, and the tip of the nozzle is placed at the bottom of the container. It will be stopped at a nearby location. Next, the pipetter is driven by the pipetter drive unit to a predetermined position! (toμQ) of specimen is aspirated from the nozzle. At this time, the pure water filled in the channel is sucked into the pipettor, and the sample is sucked into the tip of the channel including the nozzle. In addition, in parallel with the above-mentioned pipettor drive, three-way solenoid valve switching and guilutor drive are performed.
A predetermined amount of ff1 (190 μ
Q) Pure water is aspirated. Thereafter, the rack and pinion is driven to lift the nozzle from the sample container, and then the sampler arm is rotated to set the nozzle on a predetermined dilution container in the dilution line of the turntable. Thereafter, the rack and pinion is driven in a predetermined manner to insert the nozzle downward into the dilution container, and the nozzle is stopped when the tip of the nozzle is located near the inner bottom of the dilution container.

Next, in this state, the pipetter drive section is gently driven by a predetermined pulse, and the entire amount of the aspirated sample is gently discharged from the nozzle tip. The sample discharged at this time is stored in the dilution container without moving up the wall of the dilution container. When the ejection of the sample is completed, the rack and pinion is driven to lift the nozzle and stop it when the tip of the nozzle is located at the upper part of the dilution container. Next, in this state, the guilutor driving section is driven with a higher pulse than when driving the pipettor described above, and a predetermined amount of pure water is discharged from the nozzle tip at a higher position and at a higher speed than when discharging the sample. The specimen already stored in the dilution container is agitated by the force of this discharge of pure water. Time showing the relationship between the nozzle tip position (a), the plunger position of the cylinder pump for pipettor (b), and the plunger position of the guideluter cylinder pump (c) and time regarding the timing of discharge of the above specimen and pure water. An example of the chart is shown in FIG.

Thereafter, the above operations are repeated to sequentially dilute a predetermined sample to a desired concentration and prepare it in the dilution line of the turntable.

(g) Effects of the Invention According to the method of the invention, after a certain amount of the sample is ejected so as to minimize the amount adhering to the vessel wall, a predetermined amount of diluent is dispensed at a point higher than the sample ejection position. Since the sample solution is discharged at high speed, there is less accumulation of the sample stock solution due to adhesion to the vessel wall, and it is sufficiently stirred and diluted to a predetermined concentration, making it possible to improve analysis accuracy.

[Brief explanation of the drawing]

FIG. 1 is a partial configuration explanatory diagram of an example of an automatic biochemical analyzer that constitutes a specimen dilution section for carrying out the method of the present invention, and FIG. 2 is a time chart diagram showing an example of the timing for discharging specimens and diluent. be. (2)...Sampler, (3)...Turntable, (4)...Guilyuta, (5
)...Control unit, (6)...Three-way solenoid valve, (7)...Pure water storage tank, (8)...
...Circuit section, (21)...Sampling arm, (22)...
...Nozzle, (23) ...Rotation axis, (2
4)・・・Pipetta, (25)・・・・・・
・Pulley, (26)... Rack and pinion, (2
7)...Rotation drive motor, (28)...
...Rack and pinion drive motor, (29)...
・Pipetta drive unit, (31)...sample line,
(32)...Dilution line, (41)...
...Cylinder pump, (42)...Guiluta drive unit. Figure 2

Claims (1)

[Claims] 1. Pushing a certain amount of the sample sucked into the nozzle of the sampler from the tip of the nozzle with a predetermined amount of diluent supplied from the rear of the nozzle and discharging it into a container together with the diluent. A method for diluting the sample by diluting the sample, the tip opening of the nozzle being placed near the bottom of the container (
After discharging a part of the total discharge amount at a low discharge speed at that position, the nozzle is pulled up to a second discharge position above the first discharge position, and the remaining amount is discharged at that position. A specimen dilution method characterized by dispensing at a high dispensing speed.