JPH06308132A - Automatic analyzing apparatus - Google Patents

Abstract

PURPOSE:To provide an automatic analyzing apparatus which is compact and can prevent the decrease of the temperature of a sample. CONSTITUTION:An automatic analyzing apparatus 1 is provided with a reagent table 8 holding reagent containers 23 and reagent dispensing devices 11-14 for dispensing reagents corresponding to the measuing items for samples kept at constant temperatures into predetermined reaction containers 17. In the apparatus 1, a reagent retreating device 9 retreats the reagent from the reagent container 23 to a reagent retreating container and a thermostatic chamber keeps the reagent retreating container 9 at constant temperatures. The reagent dispensing devices 11-14 dispense the reagent from the reagent retreating container to the reaction container 17.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic analyzer for performing biochemical analysis and immunological analysis, for example.

[0002]

2. Description of the Related Art A conventional automatic analyzer is equipped with a reagent supply device for mixing a reagent with a sample. This reagent supply device generally employs a line dispensing system and a pipetting system. Both methods have advantages, and the former is mainly used in large-scale high-speed analyzers and the latter is used in random-access multi-item single-multi analyzers.

In the reagent supply device, a plurality of reagent containers are held, and the reagent containers contain the reagents. Usually, the reagent container is housed in a refrigerator in order to prevent deterioration of the reagent, and the reagent in the reagent container is dispensed to the reaction container on the reaction line during analysis. The reaction container is immersed in a constant temperature bath, and the sample in the reaction container is kept at a constant temperature.
Then, the reagent is mixed with the sample and heated to, for example, 37 ° C., and the reaction of the reaction liquid (mixed liquid of the sample and the reagent) proceeds under this temperature condition.

However, since the amount of the reagent dispensed to the reaction container is larger than that of the sample, the temperature of the reaction liquid is extremely lowered if the reagent which has been refrigerated is directly dispensed to the reaction container. Therefore, conventionally, it was difficult to raise the temperature of the reaction solution to a predetermined value (here, 37 ° C.) in a short time.

Also, recently, in order to increase the accuracy of analysis, the number of kinds and types of reagents used in one analysis has been increased, and the number of reagent supply steps has been increased. It is in. Therefore, lowering the temperature of the reaction solution has become a more important problem.

Along with this, the number of reagent tables also increases with the number of supply steps. In a normal mechanical configuration, one reagent table is provided for each step, so that the installation space of the reaction table is limited by increasing the number of reagent tables. Therefore, it becomes difficult to arrange the reaction table without complicating the handling of the user.

[0007]

As described above, in the conventional automatic analyzer, the reagent is directly dispensed from the reagent container to the reaction container. In the case of an automatic analyzer equipped with a pipetting-type reagent supply device, in particular, since a plurality of reagents are dispensed for one type of sample, the number of reagents in which the reagent table is dispensed Only needed. Therefore,
Automatic analyzer becomes larger and more expensive.

Further, when a plurality of reagent tables are provided, a cooling mechanism is required for each reagent table, so that the analyzer becomes large and expensive due to the cooling mechanism. Further, since there are a plurality of places for setting the reagent containers, handling of the analyzer is complicated.

Further, conventionally, the cooled reagent is directly mixed with the sample, so that the temperature of the sample may be lowered and the reaction may become unstable. As a result, the reliability of the analysis data decreases. In particular, if the number of reagent supply steps is large, the temperature of the sample is more likely to decrease. Furthermore, since the reagent supply step varies depending on the analysis item, a configuration for controlling each reagent table is required in order to operate each reagent table without waste.

An object of the present invention is to provide an automatic analyzer which is compact and which can prevent a temperature drop of a sample.

[0011]

Means and Actions for Solving the Problems To achieve the above object, the present invention provides a reagent table holding a reagent container and a reagent in a reaction container which is thermostated according to a measurement item. In an automatic analyzer equipped with a reagent dispensing device for dispensing, a reagent retracting device for retracting the reagent from the reagent container to the reagent retracting container is provided, and the reagent dispensing device dispenses the reagent from the reagent retracting container to the reaction container. Especially.

In this way, the present invention makes it possible to reduce the size of the automatic analyzer and prevent the temperature of the sample from decreasing.

As a reaction system to which the automatic analyzer of the present invention can be applied, immunological methods such as EIA (enzyme immunoassay), RIA (radioimmunoassay), FIA (fluorescent immunoassay), CLIA (chemiluminescent immunoassay), etc. Either measurement or biochemical measurement may be used. As the reaction step, either a competitive method or a sandwich method may be adopted.

After binding a reactive antigen or antibody to the carrier particles and / or the surface of the reaction container and reacting this with a test sample, the particles and / or the container are washed (B / F separation). Then, a predetermined labeling substance is reacted with the bound antibody (or antigen) to optically measure whether the labeling substance is finally bound to the carrier particles or the reaction container.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIGS.

FIG. 1 shows an automatic analyzer 1 according to an embodiment of the present invention.
Is schematically shown in a plan view. This automatic analyzer 1 adopts the pipetting method, and the main body 2
Is equipped with a reaction table 3 as a transfer means and a sample rack transfer device 4. The reaction table 3 is arranged substantially in the center of the main body 2, and the sample rack transfer device 4 is arranged along the periphery of the main body 2. Further, the sample rack transfer device 4 includes a supply unit 5, a storage unit 6, and a transport unit 7, and the supply unit 5 and the storage unit 6 are arranged on a side portion of the main body 2. Further, the transport unit 7 connects the supply unit 5 and the storage unit 6.

Reaction table 3 and sample rack storage 4
And the reagent table 8 is arranged between them. In addition, around the reaction table 3, a reagent retracting device (reagent retracting means)
9, sample dispensing device 10, first to fourth reagent dispensing device 1
1, 12, 13, and 14, a photometric device 15, and a reaction container cleaning unit 16 are arranged. The reagent retracting device 9 is interposed between the reaction table 3 and the reagent table 8, and the sample dispensing device 10 is interposed between the reaction table 3 and the transport section 7.

Of these, the reaction table 3 is disk-shaped and rotates stepwise in the direction indicated by arrow A. A large number of reaction vessels 17 are held in the reaction table 3, and these reaction vessels 17 are arranged on the outer peripheral portion of the reaction table 3 at substantially equal intervals.

Each of the reaction vessels 17 is made of a light-transmissive material, has a rectangular parallelepiped shape as shown in FIG. 2, and has an open top. Further, the lower part of the reaction container 17 is immersed in a constant temperature tank (constant temperature means) 18, and the temperature of the reaction container 17 is kept at a predetermined value (for example, 37 ° C.) by the constant temperature tank 18.

The rotation pitch of the reaction table 3 is set to one rotation (360 °) for one reaction container. When the reaction table 3 rotates once by a pitch, the positions of the reaction containers 17 ... It shifts by one.

The reaction table 3, the reaction container 17 ...
Further, it is possible to employ a general one as the constant temperature bath 18. Moreover, only some reaction vessels are shown in FIGS.

In the sample rack transfer device 4, a large number of sample racks 19 are arranged in the supply section 5,
Each of the sample racks 19 holds the sample containers 20, ... 4 (a) and (b)
As shown in FIG.
, Are arranged in a line along the longitudinal direction of the sample rack 19. And sample rack 1
9 is sequentially delivered to the side of the transport unit 7 as indicated by arrow B.

The sample rack 19 delivered to the transport section 7
a is intermittently transported by the transport unit 7 along the transport path indicated by arrow C ₁ . And this sample rack 1
9a is stopped and positioned at a predetermined position near the reaction table 3. Further, at the position where the sample rack 19a is stopped, the sample dispensing apparatus 10 dispenses the sample as described later. Then, after the dispensing of the sample is completed, the sample rack 19 a is transported along the transport path indicated by the arrow C ₂ and stored in the storage unit 6.

Here, in FIG. 1, only some of the sample racks are shown.

The sample dispensing device 10 has a sample suction position P.
_The sample is aspirated from the sample container 20a located at ₁ and the aspirated sample is dispensed to the reaction container 17a located at the sample discharge position P ₂ . That is, the sample dispensing apparatus 10 includes an up / down mechanism, a horizontal reciprocating mechanism, and a suction / discharge probe, which are not shown. The suction / exhaust probe is piped to the microsyringe mechanism. Further, the sample dispensing apparatus 10 reciprocates the suction / exhaust probe between the sample suction position P ₁ and the sample discharge position P _2, and moves it up and down at each position P ₁ , P ₂ .

Here, various general mechanisms can be adopted as the up-and-down mechanism, the reciprocating mechanism, and the intake / exhaust probe.
Illustration and description of these are omitted.

The sample dispensing apparatus 10 is provided with a cleaning tank 22, and the suction / exhaust probe is also moved up and down with respect to this cleaning tank 22. Then, the sample dispensing apparatus 10 cleans the inner and outer walls of the tip of the suction / discharge probe in this cleaning tank 22.

Then, the sample dispensing apparatus 10 dispenses a predetermined sample into the reaction container when the predetermined reaction container stops at the sample discharge position P ₂ . Also, the reaction container 17a
To the next reaction container 17b after the dispensing of the sample is completed.
Since the reaction table 3 is rotated by 360 ° or more before the reaction table 3 is sent to the sample discharge position P ₂ , the sample dispensing apparatus 10 keeps many reaction containers 17 until the reaction table 3 is stopped.
Overdoes.

The transport pitch of the sample racks 19 is set so that the sample dispensing apparatus 10 can aspirate the sample from each sample container 20.

In the reagent table 8, a large number of reagent containers 23 ... Are refrigerated. Reagent containers 22 ... Retain reagents for biochemical analysis according to measurement items and are regularly arranged on the reagent table 8. Then, the reagent containers 23 are transferred by the reagent transfer table 8 in a constant path as shown by an arrow D.

[0031] Reagents retracted device 9, intake as well as the specimen dispensing apparatus 10 pro - preparative comprises a blanking (not shown), a predetermined amount of reagent from the reagent container 23a sent to the reagent aspirating position P ₃ min To do. Then, the reagent retracting device 9 is connected to
Bed The reaction tape - is moved to the side of the cable 3, it is dispensed into the reaction vessel 17c sent to prep reagent to the reagent discharge position P _4.
The reagent withdrawal device 9 that has completed the dispensing is assumed to clean the suction / discharge probe in the washing tank 31 each time dispensing to one reaction container or each time the type of reagent to be dispensed changes.

At this time, the reaction container 17c in which the reagent is dispensed
Is a reaction container in which a sample is not dispensed. That is,
The reaction container 17c is also used as a reagent evacuation container.
Furthermore, the reagent dispensed by the reagent saving device 9 is only temporarily saved in the reaction container 17c and is not yet mixed with the sample. Then, this reagent is subjected to the heat of the thermostat 17 in the reaction container 17c to be thermostatted.

At this point, the reaction container 17c located at the reagent discharge position P ₄ is the reaction container adjacent to the reaction container into which the sample has been dispensed. That is, here, the sample has already been dispensed in the reaction container 17d adjacent (one before) to the reaction container 17c in which the reagent has been dispensed. Further, when the reaction table 3 is rotated once again, the reaction container 17e next to (one after) the reaction container 17c.
Is sent to the reagent discharge position P ₄ .

A diluent container may be placed in the reagent table 8 if necessary. Further, hereinafter, the reaction container used to temporarily save the reagent (or the diluent) is referred to as a reagent saving container.

The first to fourth reagent dispensing devices 11 to 14
Each have an intake / exhaust probe 24 as shown in FIG. The intake / exhaust probe 24 is attached to a horizontal reciprocating mechanism 25 so that the horizontal reciprocating mechanism 25 moves vertically.
It is connected to the rotating mechanism 26. Further, the suction / exhaust probe 24 is connected to a microsyringe mechanism (not shown). The horizontal reciprocating mechanism 25 and the vertical / rotary mechanism 26 constitute a reciprocating mechanism 24a.

Each of these reagent dispensing devices 11 to 14 moves the suction / exhaust probe 24 to dispense the reagent dispensed in the reagent evacuation container into the reaction container in which the sample is dispensed.
That is, the reagent dispensing apparatuses 11 to 14 perform a reagent dispensing operation between the reagent evacuation container and the reaction container to create a reaction liquid (mixed liquid of the sample and the reagent). Further, the first to fourth reagent dispensing apparatuses 11 to 14 are provided with washing tanks 27, and the suction and discharge probe 24 to which the reagent adheres is washed in the washing tank 27.

Here, the number of reaction vessels used as reagent evacuation vessels may be set according to the number of reagents used for the items to be analyzed. However, the number of reaction vessels for reagent evacuation vessels depends on the number of reagent dispensing apparatuses 11-14. In the present embodiment, considering that the reagent retracting device 9 directly dispenses a reagent (for example, a specific diluent) from the reagent container 23 to the reaction container into which the sample has been dispensed, the maximum It is possible to analyze items using 5 types of reagents.

The photometric device 15 comprises a light emitting element 28 and a light receiving element 29, both elements 28 and 29 being the reaction vessel 1.
7 are arranged so as to sandwich the passage route. Then, the light emitting element 28 emits light of a single wavelength and irradiates the reaction container 17 ... Light of various wavelengths is obtained as the reaction of the reaction solution proceeds in the reaction container 17. Then, these lights are incident on the light receiving element 29 and photoelectrically converted, and the sample is analyzed.

In addition, the reaction container 17 after the analysis (and the reagent reserving container after the dispensing) ...
Washed in 6 and reused. In some cases,
Contamination is minimized by adding an exchange mechanism that selectively removes only the reaction container into which the sample has been dispensed from the reaction table 8 after the analysis is completed and replaces it with a new reaction container. However, other reaction vessels may be reused to the maximum extent.

The photometric device 15 and the reaction container cleaning unit 1
As for 6, various general ones can be adopted.

Reference numeral 30 in FIG. 1 denotes a control device. As shown in FIG. 6, the control device 30 includes a reagent table.
Table 8, first reagent transfer device 9, sample rack transfer device 4, sample dispensing device 10, reaction table 3, photometric device 1
5, the reaction container cleaning unit 16, and the second reagent transfer device 1
1 to 14 are controlled respectively. Further, the control unit 30 operates them within a predetermined sequence time (20 sec in this case).

A command as to which item to analyze for which sample and which kind of reagent to be mixed with the sample in accordance with the item is inputted in advance to the control device 30. Then, the control device 30 controls each unit according to this instruction. The control device 30 may be incorporated in the main body 2.

Depending on the analysis item, the number of operating reagent dispensing apparatuses 11 to 14 is selectively switched so that the reagent dispensing apparatuses 11 to 14 can selectively operate with respect to any reaction container 17. It also controls the operation timing. Figure 3
In the above, on the same circumference on the reaction table 3, the reaction containers for the first, second and third reagents corresponding to the supply steps required for one analysis are respectively the reagent evacuation containers 41,
It is used as 42 and 43.

In the automatic analyzer 1 as described above,
The reagent in the reagent container 23 is temporarily stored in the reagent storage container and then mixed with the sample, and the reagent is kept at a constant temperature together with the sample during the storage. Therefore, it is possible to prevent the temperature of the sample mixed with the reagent from decreasing. Then, it is possible to prevent the reliability of the analysis data from being lowered due to the temperature decrease of the sample, and it becomes possible to perform highly accurate analysis.

Furthermore, the necessary reagents are selected from a plurality of reagent containers of the reagent table 8 and collected, and the collected reagents are temporarily saved in the reagent saving container, so that the number of reagent tables 8 is one. One is enough. Then, reagents and diluents can be collected in one reagent table 8. Further, since the number of the reagent table 8 is one, the reagent can be refrigerated by one cooling mechanism, and the installation place of the reagent containers 23 ... Is limited to one place. Therefore, the analyzer 1 does not become large and expensive, and the handling of the analyzer 1 does not become complicated.

Further, the number of reagents according to the analysis item can be arbitrarily changed by the control device 30, and for example, as shown in FIG. 3, which one of the reaction containers 17 to be used is for the sample,
Since which of the reagents is used can be changed at random, the reaction vessels 17 can be used efficiently, so that the analysis of other items can be economically executed without waste.

In the case of processing an analysis item in which a decrease in sample temperature is not a serious problem in the method of analysis, the reagent saving device 9 selectively dispenses the reagent into the reaction container. A control for switching the dispensing operation may be executed.

Further, the present invention is not limited to the above-mentioned constitution, but various modifications are possible.

For example, the reagent transfer devices 11 and 13 between the reaction vessels of the present embodiment are replaced with B / F separation devices, and the reagent transfer devices 12 and 14 between the second and fourth reaction vessels are replaced.
Is used for dispensing the first reagent and the second reagent, it is possible to carry out the EIA method utilizing the antigen-antibody reaction of blood,
The automatic analyzer 1 can be used as an automatic blood analyzer.

Further, the reagent dispensing apparatuses 11 to 14 are supported on the shafts of the rotation centers of the reaction tables 3 so that they can be rotated together with a small predetermined rotation range, respectively.
Dispensing operability may be improved by matching the movement path of the tube with the line in which the reaction vessels 17 are arranged.

At this time, as shown in the time chart of FIG. 7, for example, a part of the reagent dispensing apparatuses 11 to 14 is connected to an appropriate washing water tank and a waste liquid tank (not shown) by an intake / exhaust probe. Configured, for the reaction container containing the reaction solution,
If the B / F separation operation is performed at the same time as the dispensing operation between the reaction vessels, one sequence can be completed in 20 seconds. Also in this case, all the reaction steps can be completed while the respective reaction vessels 17 ...

Next, a second embodiment of the present invention will be described with reference to FIG.

In the first embodiment, a part of the reaction vessels 17 ... Is also used as a reagent evacuation vessel, whereas in the present embodiment, the reaction vessels 17 ... and the reagent evacuation vessels 41 ..., 42 ..., 43.
Are distinguished from each other by arranging them on the reaction table 3 along the mutually different arrangement lines 45a to 45d. Here, the number of array lines 45a to 45d can be determined corresponding to the analysis item having the largest number of reagents used in one analysis. If necessary, the reaction table
A new array line (not shown) may be added to the outer periphery of the bull 3 or, conversely, a removable structure may be added. The first reagent evacuation container 41 ..., the second reagent evacuation container 42, and the third reagent evacuation container 43 ... Are sequentially arranged outside the reaction container 17, and as the reaction table 3 rotates, The reagent container 41 ..., 42 ..., 43 ... is the reaction container 1
Move with 7 ...

Although not shown, the first to third reagents are selected and dispensed into the respective reagent evacuation containers 41 ..., 42 ..., 43 ... In response to a command from the reagent evacuation device / control device 30. Each reagent dispensing device dispenses the first to third reagents into the corresponding reagent evacuation containers 41 ....

According to the automatic analyzer of the present embodiment, the reaction container 17 ... Is not used as the reagent evacuation container 41 ..., 42 ..., 43 ..., Therefore, the reaction container 17 ... Arranged consecutively. Therefore, when the reaction table 3 is rotated, the sample dispensing device does not need to overwhelm the reagent evacuation container and wait for the reaction container, thereby increasing the speed of the sample dispensing process. And high-speed automatic analysis becomes possible.

The present invention is not limited to the above-mentioned embodiments, and various modifications and improvements can be made according to the technical idea of the invention.

For example, in the above-described embodiment, only the reagent for bioscience analysis is contained in the reagent container 23, but it is replaced with the reagent for immunological analysis, or both reagents are contained in the reagent container 23 in some cases. It may be housed for flexible analysis. At this time, depending on the composition of the reagent, a plurality of reagent retraction mechanisms 9 having different transfer mechanisms may be designed to be selectively operated. Needless to say, the rotation pitch of the reaction table 3 can be variously changed depending on the case.

[0058]

As described above, the present invention provides a reagent table holding a reagent container, and a reagent dispensing device for dispensing a reagent according to a measurement item to a specimen that has been thermostatted in a reaction container. In the automatic analyzer provided with, a reagent saving device for saving the reagent from the reagent container to the reagent saving container is provided, and the reagent dispensing device dispenses the reagent from the reagent saving container to the reaction container.

Therefore, according to the present invention, since it is not necessary to newly increase the reagent table for constant temperature, the analytical model can be efficiently operated, the automatic analyzer can be downsized, and the temperature of the sample can be prevented from lowering. Has the effect of enabling.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of an automatic analyzer according to a first embodiment of the present invention.

FIG. 2 is a perspective view showing a reaction container.

FIG. 3 is an explanatory view showing a rotating action of a reaction table.

4A is a plan view of the sample rack, and FIG. 4B is a side sectional view of the sample rack.

FIG. 5 is a configuration diagram of a dispensing apparatus between reaction containers.

FIG. 6 is a time chart showing one sequence of the automatic analyzer according to the first embodiment of the present invention.

FIG. 7 is a time chart showing one sequence when performing B / F separation.

FIG. 8 is an explanatory diagram showing a main part of a second embodiment of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Automatic analyzer, 8 ... Reagent table, 9 ... Reagent shelter device, 11-14 ... Reagent dispensing device, 17 ... Reaction container / reagent shelter container, 18 ... Constant temperature bath, 23 ... Reagent container, 24 ... Suction / discharge Probe, 25 ... Horizontal reciprocating mechanism, 26 ... Vertical / rotating mechanism, 41 ... First reagent dispensing device, 42 ... Second reagent dispensing device, 43 ... Third reagent dispensing device.

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[Procedure amendment]

[Submission date] February 9, 1994

[Procedure Amendment 1]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 3

[Correction method] Change

[Correction content]

[Figure 3]

Claims (3)

[Claims] 1. An automatic analyzer comprising: a reagent table holding a reagent container; and a reagent dispensing means for dispensing a reagent according to a measurement item into a constant temperature sample into a predetermined reaction container. A reagent withdrawal means for withdrawing the reagent from the reagent container to the reagent withdrawal container, and a constant temperature means for isolating the reagent withdrawal container from the reagent container, and the reagent dispensing means divides the reagent from the reagent withdrawal container into the reaction container. An automatic analyzer characterized by pouring. 2. The automatic analyzer according to claim 1, wherein the reagent evacuation container and the reaction container are arranged on the same conveying means. 3. The reagent withdrawal container and the reaction container,
2. The reagent dispensing device, which is arranged along a direction parallel or at a right angle to the transport path, wherein the reagent dispensing device has a mechanism for reciprocating in a direction substantially parallel to the path or at a right angle. Automatic analyzer.