DE4416406A1 - Output device and output method - Google Patents

Description

The present invention relates to an output device for an automatic analyzer and the like Chen is provided to a reaction vessel a river liquid sample automatically to or from this give; the invention also relates to an output method.

Use one for different types of chemical analysis The automatic analyzer usually has an ID dispenser or dispenser. Such an output device has the task of giving a reaction sample a liquid sample such as a blood component (blood, blood serum, etc.) or urine and a biochemical or immunological to supply liquid reagent that is in agreement selected with a respective object of analysis. Such an output device has a nozzle. The nozzle moves between the reaction vessel and a pro ben container and between the reaction container and a Reagent container and sucks and discharges the liquid sample, the reagent, etc. (hereinafter referred to as "sample" is drawn). To move the sample from the nozzle to the reaction area to dispense containers, a syringe is usually used.

With the distribution or off described above can give the sample due to a pressure difference between between the inside and outside of the nozzle of the issue. This distraction or Zer Dusting of the sample is particularly noticeable if in the nozzle between samples or between a sample and the the expelling or pushing out of the syringe Water bubbles are present. When the sample is scattered the dispersed part of the reaction does not take part part, which is why the sample / reagent ratio of one before  certain value deviates. As a result, the Analy ad result adversely affected or falsified. To one Avoiding such distraction has already been eliminated Proposed device of the type in which the nozzle inserted into the reaction container to dispense the sample is, or in which a mouth area or a tip of the Nozzle with the bottom of the reak while dispensing the sample tion container is brought into contact.

With the output device of the type in which the nozzle inserted into the reaction container to dispense the sample the scattering of the sample to the outside of the re action container can be prevented. However, it is difficult rig, just by inserting the nozzle into the reaction to completely prevent the influence of dispersion. Namely, when a sample scattered in the reaction container stick to the inner wall of the reaction vessel remains, the one available for the reaction Insufficient amount of sample and sample / reagent ver ratio tends to be instable. It is also possible lich that a change in the data and / or an abnormal value occurs. If the on the inner wall of the reacti Sample portion adhering to the chamber along the inner wall gets into the reaction liquid changes over it the sample / reagent ratio during the reaction, which is why an abnormal response or incorrect data occurs can kick.

With the output device of the type in which a coin area of the nozzle while dispensing the sample with the Is brought into contact with the bottom of the reaction container, on the other hand, it is possible to adhere the sample to the to prevent the inner wall of the reaction vessel. Since the If the nozzle is immersed in the sample, the sample remains stick to the tip or mouth of the nozzle. If the nozzle is pulled out of the reaction vessel, a part the sample is therefore taken from the nozzle. The amount of this  the sample taken is not constant. As a result of this the sample / reagent ratio is unstable, which is why an abnormal Male reaction or incorrect data can occur. If the nozzle is not washed clean, it will be at the top the sample sticking with the sample in the reaction container issued sample mixed. Between these samples occurs consequently contamination or contamination on what also leads to incorrect data. If the output rate or nozzle output speed in accordance with the viscosity of liquid samples or that affect each Analysis section or analysis object related issue amount is changed, the outer wall of the nozzle can be changed from the bottom or from the liquid level of the reaction vessel splashing liquid.

The above procedure cannot be used if a second sample (such as blood serum) is drawn is carried out after the reaction vessel a first sample (such as a reagent).

Because the amount of sample to be used is the endeavor has to decrease more and more, the respective analy result of a slight shortfall in the sample, mixing during the reaction, mutual Contamination of samples, etc. to a large extent be negative influences why these factors affect the reliability of the Influence analysis results. If incorrect data on recheck is necessary and it need to perform many additional verification steps become. In particular with a medical analysis device are an improvement in the precision of the data as well as egg ne Shortening the analysis time is essential. As a result it required the negative influence of the output device to reduce the analysis as much as possible.

The invention is therefore based on the object To create an output device that is capable of one from egg  Liquid sample dispensed through a nozzle without waste to use, and where no negative impact on egg ne analysis occurs.

This object is achieved according to the invention 1 specified features solved.

The invention accordingly proposes a dispenser for dispensing predetermined amounts of a liquid sample held by a nozzle into containers, which comprises the following features:
an unloading or dispensing device for dispensing the predetermined amounts of the liquid sample into the container via the nozzle, the dispensing device being an adjusting device for such a movement of the nozzle in at least one vertical direction that the nozzle enters the container, and a Has means for regulating an output amount of the sample;
an arithmetic arithmetic device, which, based on the amount of the liquid sample given, provides a sum (L) in advance of a first value corresponding to the liquid level present at the point in time at which the dispensing of the liquid sample into the container has ended, and from calculates a second value used to prevent the dispensed liquid sample from adhering to the nozzle; and
a height control unit for controlling the height of a mouth portion of the nozzle moved by the adjusting device on the basis of an arithmetic calculation result of the arithmetic computing device while the liquid sample is output from the nozzle.

According to a further aspect of the invention, a dispensing method for dispensing a liquid sample held by a nozzle into containers is proposed, which comprises the following steps:
Performing an arithmetic calculation of a first value that corresponds to the liquid level that is present at the time of completion of dispensing the liquid sample into the containers;
Inserting the nozzle into the containers and positioning a mouth portion of the nozzle at a height expressed by a sum (L) of the first value and a second value used to prevent the dispensed liquid sample from adhering to the nozzle; and
Dispensing a predetermined amount of the liquid sample from the positioned nozzle.

Further advantages and special effects of the invention are the subject of the subclaims.

The invention is described below based on the description of embodiments with reference to the drawing tion explained in more detail. Show it:

Fig. 1 shows schematically the structure of a first embodiment example of the output device according to the invention;

Fig. 2 shows the dimensions of a reaction container of the first embodiment of the output device;

Fig. 3 is a block diagram of the first embodiment with reference to the structure of a control apparatus of Ausga begeräts the same peripheral elements;

Figure 4 shows the height of a nozzle of the first embodiment of the dispenser when the nozzle dispenses a liquid. and

Fig. 5A to 5C, the respective height of the nozzle when ei ne first and second liquid is dispensed.

In Fig. 1, the structure or the structure of a first embodiment of the dispensing or dispensing device according to the invention is shown schematically, which is designated with the reference character Chen 11 . In this output device 11 is a Probenausgabedüse is attached to a Düsenverstellvorrichtung or nozzle displacement means 13 12 which functions as Düsenver reduction mechanism. The nozzle 12 is attached to a ho rizontal arm 14 and extends downward from a distal end portion of the arm 14 .

A proximal end portion of the arm 14 is coupled to a rotating shaft 15 . The rotating shaft 15 is rotated by a rotating motor or drive motor 16 . In accordance with the rotational movement of the shaft 15 , the nozzle 12 rotates in the horizontal direction. The Düsenverstellvorrich device 13 has a vertical motor 17 . The United tical movement motor 17 moves the rotary shaft 15 of the nozzle adjusting device 13 in the vertical direction such that the nozzle 12 moves vertically.

The nozzle 12 is connected to a syringe or pump 20 via a flexible tube or hose 19 . In accordance with the operation of the syringe 20 , the nozzle 12 draws in and discharges a sample. The syringe 20 has a cylinder 20 a and a piston ben 20 c, which is coupled to a piston rod 20 b and slidably arranged in the cylinder 20 a. A projecting end portion of the piston rod 20 b is coupled to a linear drive source 20 d such as a linear motor. The linear drive source 20 d has a device for such a control of the on / off operating time control that the stroke distance of the piston rod 20 b ge is changed, and also has a speed change device for changing the drive speed of the piston rod 20 b, if necessary . The linear movement source or linear drive source 20 d is controlled by a control device described later.

A plurality of reaction containers 21 are attached to a turntable 22 . In accordance with the rotation of the turntable 22 , each of the reaction containers 21 is successively moved to a sample discharge position X of the nozzle 12 . Each reaction container 21 is a rectangular parallelepiped or a rectangular cuboid which, as shown in FIG. 2, has the same width and depth fen dimensions a and b over its entire height. The turntable 22 preferably has holding holes which allow the reaction containers 21 to be exchanged. If necessary, the turntable can hold or guide 22 reaction vessels of various shapes in order to carry out multi-stage analyzes. The turntable 22 is driven by a motor (not shown) to promote a desired reaction container 12 to the dispensing position. If necessary, in accordance with commands from the control device, 26 different rotation and stop processes can be carried out for each analysis stage or object.

A plurality of sample containers 23 are placed on a holder 24 . Each sample container 23 contains a predetermined sample (such as blood serum) as a liquid sample. Each sample container 23 is successively brought into a sample suction position Y of the nozzle 12 .

The output device 11 has the control device 26 as a control device. The control device 26 is connected to a keyboard 27 and a monitor 28 . The control device 26 leads the nozzle adjustment device 13 and the linear drive source 20 d of the syringe 20 to control signals. The keyboard 27 is used to input data, commands, and the like, and the monitor 28 is used to display data, analysis results, and the like. As shown in Fig. 3, the controller 26 has a control unit 29, a storage unit 30, and a computing unit 31 arithme diagram. The data values entered via the keyboard 27 are, for example, analysis values, output quantities of liquid samples of various types, sample numbers, respective shapes of reaction containers, etc.

The nozzle adjustment device 13 is driven in accordance with a command from the control device 26, and the nozzle 12 is moved to a predetermined sample container 23 . Furthermore, the linear drive source 20 d of the syringe 20 is driven and the piston 20 c is moved downwards in the position shown in the figure. The nozzle 12 sucks a sample 25 and holds it there. The nozzle 12 is then moved to the turntable 22 and stopped above a predetermined reaction container 21 . The control unit 26 lowers the nozzle 12 to the reaction container 21 downwardly toward and performs the nozzle 12 into the container 21 a. The control device 26 stops the nozzle 12 at a predetermined height and causes the nozzle 12 to dispense the sample 25 into the reaction container 21 . The stroke or the piston path of the syringe 20 is determined in such a way that, in accordance with an analysis entered via the keyboard 27 step or object, a desired output quantity of the sample (and if necessary also an output speed) is obtained.

As described below, the stop position of the nozzle 12 is adjusted taking into account the dimensions of the reaction container 21 and the discharge amount of the sample 25 . In the storage unit 30 of the control device 26 , data about the dimensions of the reaction container 21 are stored in advance and the control device 26 is supplied with the keyboard 27 via the data on the output quantities of the samples 25 . If this is necessary, data about the dimensions of the reaction container can be entered using the keyboard 27 . If two or more containers of different dimensions have to be used for the purpose of multiple measurements, it is desirable to store data in advance in the storage unit 30 on the respective type of analysis processes, on the shape and dimensions of the reaction containers and on the output quantities that the shapes and dimensions of the reaction containers and the output quantities can be specified only by entering the desired analysis processes on the keyboard 27 .

If the sample 25 is outputted into a still empty reaction container 21 , a height L 1 shown in FIG. 4 of a tip or mouth end 12 a of the nozzle 12 , which is set by the arithmetic computing unit 31 of the control device 26 , according to express the following equation:

L₁ = l₁ + α = V₁ / S + α [mm] (1)

In the above equation, the height is l₁ denotes a liquid or keitspegels -spiegels 32 when the sample 25 surface with a predetermined amount V₁ [.mu.l] in a Bodenflä S [mm] having reaction vessel is issued 21st The height l 1 is obtained before the sample is dispensed. The floor area S is expressed by the following equation

S = a × b [mm²] (2)

In the above equation, a denotes the width and b the depth of the reaction container 21 .

The value α contained in the formula ( 1 ) is freely selected and indicates a distance between the nozzle 12 and the liquid level 32 . A suitable value for α is, for example, a few millimeters. Since the distance α is vorgese hen, the nozzle 12 is as shown in Fig. 4 at a predetermined distance above the liquid mirror 32 , slightly above the liquid level 32nd It is advantageous if the value of the distance α is changed in the range between 1 mm and 5 mm as a function of the delivery rate or output speed of the liquid sample. The arithmetic arithmetic unit 31 calculates the value of the distance α such that the value α increases in accordance with the output rate determined by the diameter of the nozzle, the discharge amount and the discharge time. Based on the calculated value α, the control unit 29 controls the nozzle adjustment device 13 and selectively changes a lower stop position of the nozzle 12 . Splashing of the sample from the bottom or from the liquid mirror in the reaction container 21 is therefore prevented, thereby further preventing the outer wall of the nozzle 12 from becoming contaminated by a sprayed liquid sample during the dispensing process.

When the sample 25 is dispensed, the sample 25 is generally sprayed on the lower side of the nozzle 12 . The atomized sample 25 therefore adheres to the inner wall of the reaction container 21 on the lower side of the mouth section 12 a of the nozzle 12 . Since the value of the distance α decreases, the liquid level 32 of the sample 25 approaches the mouth section 12 a of the nozzle 12 . The atomized sample adhering to the inner wall of the reaction container 21 is therefore absorbed in or taken up by the sample 25 .

In this embodiment of the output device of the present invention, therefore, the entire amount of the sample 25 can be used without any waste, and it is possible to stabilize the sample / reagent ratio at a predetermined value. The influence of the sprayed or atomized sample 25 on the analysis can thus be reduced to a minimum.

Since the nozzle 12 is held on above the liquid level 32 , the sample 25 does not adhere to the nozzle 12 . Consequently, the nozzle 12 does not take a sample 25 .

Although not shown, waste-free use of the reagent can be achieved if the height of the nozzle 12 is similarly adjusted while dispensing the reagent. It should be pointed out that the invention applies both to a dispenser of the type in which a nozzle is used exclusively for a reagent and to a dispenser of the type in which a single nozzle is used both for the sample and for the reagent is used is applicable.

The case in which a first and second liquid sample is dispensed into a single reaction container 21 is described below. For example, a reagent is dispensed after a sample has been dispensed. In this case, in addition to the structure shown in Fig. 1, the following structure is provided. That is, in addition to the sample containers 23 , a plurality of reagent containers containing liquid reagents assigned to respective analysis items are arranged on suitable positioning means such as a second rotary table (not shown), and a reagent is put into a predetermined reaction container 21 on the rotary table 22 is output by means of a second output device (not shown), which has the same structure as the output device shown in FIG. 1. A nozzle adjustment device and a syringe of the second output device are connected to the control device 12 . If necessary, the second turntable can hold a plurality of reagent containers that contain first and second reagents that are associated with specific analysis purposes (such as a water quality test or an enzyme immunoassay) that require multiple dispensing. In this case, the process of dispensing the first and second reagents is performed by sharing a nozzle and a syringe, and the controller 12 controls the plunger stroke of the syringe so that the stroke amount changes in accordance with each reagent.

As can be seen from the illustration in Fig. 5A, the nozzle 12 is inserted into the reaction container 21 and stopped at the height denoted by L₁. In this state, a first sample 33 is output. The height L₁ is determined according to equation (1) above. At this time, since atomization or spattering of the first sample 33 occurs substantially on the lower side of the nozzle 12 , the atomized sample adheres to the inner wall of the reaction container 21 on the lower side of the mouth portion 12 a of the nozzle 12 . When the dispensing is complete, the level 35 of the first sample 33 is close to the mouth portion 12 a of the nozzle 12 , which is why the atomized sample adhering to the inner wall of the reaction container 21 is finally absorbed in the first sample 33 .

After the first sample 33 has been dispensed, the nozzle 12 is pulled out of the reaction container 21 and then sucks in a second sample 34 . The nozzle 12 is returned with the second sample 34 to the same reaction container 21 , whereupon the second sample 34 is given as shown in Fig. 5B at the height indicated by L₂. The value of L₂ can be expressed by the following equation:

L₂ = l₁ + l₂ + α = (V₁ + V₂) / S + α [mm] (3)

When the second sample 34 is dispensed, atomization of the second sample 34 occurs substantially on the lower side of the nozzle 12 . The atomized sample therefore adheres to the inner wall of the reaction container 21 on the lower side of the mouth section 12 a of the nozzle 12 . The smaller the value of α, the closer a level 36 of the second sample 34 lies after the end of the dispensing at the mouth section 12 a of the nozzle 12 . The atomized sample adhering to the inner wall of the reaction chamber 21 is therefore finally absorbed in the second sample 34 .

In the second exemplary embodiment of the output device according to the invention, the respectively provided amounts of the first and second reagent 33 and 34 can therefore be used without any waste, which is why the sample / reagent ratio can be stabilized at a predetermined value. In addition, it is possible to minimize the influence of the atomized portions of the first and second samples 33 and 34 on the analysis.

Since the nozzle 12 is stopped above the liquid level 35 and 36, the first sample 33 and the second sample 34 will not adhere to the nozzle 12 to thereby prevent the nozzle 12, the first and second reagent removes 33 and 34 respectively.

In addition, it is possible to stop the nozzle 12 as shown in FIG. 5C at the height denoted by L₂ and to output both the first sample 33 and the second sample 34 . In that case, the sample will share that has been stäubt zer during the output of the first sample 33 and adhering to the inner wall of the Reaktionsbe hälters 21, absorbed in accordance with the output of the second sample 34 from the second sample 34th The first sample 33 is thus used without waste.

When three or more samples are dispensed into the same reaction container 21 , a final height L _{n is set} according to the following equation to keep the sample / reagent ratio stable:

L _n = (V₁ + V₂ +... + V _n ) / S + α [mm] (4)

Although a single nozzle 12 is provided in the above-described embodiment for sucking up and dispensing the first and second samples, it is also possible to use different nozzles. The first and second samples can be a sample and a reagent. The shape of the reaction vessel is not limited to a rectangular cuboid, but rather may also have the shape of a cylindrical tube, a hemispherical wall, a tapered wall, etc. In the above embodiment, a respective liquid level or level is calculated on the basis of the bottom surface of the reaction container 21 . If the horizontal cross-section of the container in the vertical direction is not constant, it is possible to find out the relationship between an output amount and a liquid level by preliminary experiments and to store a relationship reflecting this table in the storage unit 30 , so that it is possible is to use reaction vessels with a given shape. It goes without saying that a liquid sample can be dispensed into a container or a measuring container as well as into the reaction container. In the above exemplary embodiment, the value L _{n is} calculated on the basis of the output quantity, but it can also be set in steps, for example to 3 mm if the output quantity is between 1 and 10 μl, to 5 mm if the Dispensing amount is between 10 and 20 µl, etc. The device provided for controlling the dispensing pressure is not limited to the syringe described; Rather, another pressure source such as a peristaltic pump can be used for this purpose.

There may be a case in which two or more kinds of liquids, such as a liquid sample, a liquid reagent and a diluting liquid, are discharged in batches into many containers with a desired combination of output amounts corresponding to the respective analysis purposes. In this case, numbers or codes 41 corresponding to the various containers are attached to the reaction containers 21 or the side surface of the turntable 22 and the respective positions on the turntable 22 are stored in the storage unit 30 . The codes 41 are read out by means of a suitable reading device 42 and the last liquid level in each reaction container is stored in the storage unit 30 . Therefore, even if an analysis consisting of a combination of random analysis steps is carried out, it is possible to influence the output taxation advantageously without detecting the respective liquid level. On the other hand, when considering using a liquid level detection device such as electrodes, ultrasonic waves, or a capacity-changing device to evaporation of liquid samples, a residue of liquid is used the washing of the container or a back in the reagent container after the suction to monitor, the control device 26 can be successively output signals supplied, which indicate the detected liquid level, so that no such code reading system is neces sary.

In addition, there may be a case where the value of α is made constant and the discharge rate has to be changed in accordance with a discharge amount or the type of liquid sample. In this case, the control unit 29 delays the stroke movement of the syringe 20 such that the dispensing rate between the time at which the liquid level rises to such a dangerous level that a liquid portion atomized by the liquid surface can reach the nozzle and that time , at which the dispensing is ended, is set to an dispensing rate at which the atomized liquid fraction no longer reaches the nozzle 12 , just before the distance with the value α is reached. The adherence of the liquid sample is therefore prevented.

In the above, an output device has been prepared for output certain quantities of a liquid held by a nozzle speed sample in containers, which an output unit for dispensing the predetermined amounts of the liquid sample into the container via the nozzle and a control unit to control an operation of the output unit points; the output unit comprises an adjustment device for such a movement of the nozzle at least in one vertical direction that the nozzle enters the container and a regulating device for regulating an output quantity the sample. The control unit includes an arithmetic Arithmetic unit, which in advance based on the amount of dispensed liquid sample a sum of a first Value of the river present at that time liquid level at which the output of the liquid test is completed in the container, and from a second value is calculated, which is used that Anhaf th of the given liquid sample at the nozzle prevent. A height control unit is also provided hen, the height of a mouth section of the Adjusting device moving nozzle based on a arithmetic calculation result of arithmetic calculation device controls while the liquid sample from the Nozzle is ejected.

Claims (14)

1. Dispenser for dispensing predetermined quantities of a liquid sample held by a nozzle ( 12 ) into container ( 21 ), comprising:
a dispenser for dispensing the predetermined amounts of the liquid sample into the containers ( 21 ) through the nozzle ( 12 ); and
a control device ( 26 ) for controlling an operating sequence of the output device,
the output device comprising:
an adjusting device ( 13 ) for moving the nozzle ( 12 ) at least in a vertical direction such that the nozzle ( 12 ) enters the container ( 21 ), and
means for regulating an output amount of the sample, and
the control device ( 26 ) having:
an arithmetic calculator ( 31 ) which, based on the amount of liquid sample dispensed, gives a sum (L) of a first value which is a liquid level at the time when the liquid sample is dispensed into the container ( 21 ) and is calculated from a second value used to prevent the liquid sample given from adhering to the nozzle, and
a height control unit ( 29 ) for controlling the height of a mouth section ( 12 a) of the nozzle ( 12 ) moved by the adjusting device ( 13 ) on the basis of an arithmetic calculation result of the arithmetic computing device ( 31 ) while the liquid sample is passed through the nozzle ( 12 ) is output. 2. Apparatus according to claim 1, characterized in that the arithmetic computing device ( 31 ) of the control device ( 26 ) determines the first value on the basis of an object of analysis and / or a shape of each of the containers ( 21 ) entered via an input device ( 27 ) . 3. Apparatus according to claim 1 or 2, characterized in that the arithmetic computing device ( 31 ) of the Steuerein direction ( 26 ) has a device for performing an arithmetic calculation based on a floor area (S) of each of the containers ( 21 ). 4. Device according to one of claims 1 to 3, characterized in that each of the containers ( 21 ) has a constant cross-sectional area. 5. Device according to one of claims 1 to 4, characterized in that the control device ( 26 ) has a memory device ( 30 ) for storing data relating to the first value. 6. Apparatus according to claim 5, characterized in that the arithmetic computing device ( 31 ) of the control device ( 26 ) has a device for performing an arithmetic calculation based on data on the amount of the liquid sample already contained in each of the containers ( 21 ), this data being stored in the memory device ( 30 ). 7. Device according to one of claims 1 to 6, characterized in that the output quantity control device of the output device comprises a syringe ( 20 ) which is capable of changing a drive stroke amount of a piston ( 20 ). 8. Device according to one of claims 1 to 7, characterized in that the nozzle ( 12 ) is held via a rotatable on a vertical rotary shaft holding device and that the container ( 21 ) are held on a turntable ( 22 ). 9. Device according to one of claims 1 to 8, characterized in that the height control unit ( 29 ) a Einrich device for changing the height of the nozzle ( 12 ) in accordance with the container ( 21 ) in which the nozzle ( 12 ) is inserted is. 10. Output device which enables a nozzle ( 12 ) to draw in a liquid sample and to dispense the liquid sample into container ( 21 ) with:
a drive device ( 13 ) for the vertical and horizontal drive of the nozzle ( 12 );
a suction / dispensing device which moves the nozzle ( 12 ) horizontally and the nozzle ( 12 ) allows the suction of a predetermined amount of the liquid sample and which che moves the nozzle ( 12 ) vertically and the nozzle ( 12 ) the output from predetermined amount of the liquid sample enables light; and
a control device ( 26 ) which calculates in advance a liquid level in the containers ( 21 ) on the basis of an amount of the liquid sample given from the nozzle ( 12 ), controls the drive device ( 13 ) on the basis of the calculated liquid level and the amount of a Mouth section ( 12 a) of the nozzle ( 12 ) in each of the containers ( 21 ). 11. Dispensing method for dispensing a liquid sample held by a nozzle ( 12 ) into container ( 21 ), comprising the following steps:
Performing an arithmetic calculation of a first value corresponding to a liquid level ( 32 ) at the time when the dispensing of the liquid sample into each of the containers ( 21 ) is completed;
Introducing the nozzle ( 12 ) into the container ( 21 ) and posi tioning a mouth portion ( 12 a) of the nozzle ( 12 ) at a height, which is a sum (L) of the first value and a second value, which Preventing sticking from given liquid sample to the nozzle ( 12 ) is expressed; and
Dispensing a predetermined amount of the liquid sample from the positioned nozzle ( 12 ). 12. The method according to claim 11, characterized in that in the step of performing the arithmetic calculation, the first value is calculated on the basis of the amount of a further liquid sample already contained in each of the containers ( 12 ). 13. The method according to claim 11 or 12, characterized indicates that the second value be between 1 mm and 5 mm wearing. 14. The method according to any one of claims 11 to 13, characterized characterized in that in the step of performing the arithmetic calculation an output amount of liquid test in accordance with one received in advance specified subject of analysis.