JPH07218396A - Automatic chemical analyzer - Google Patents

Abstract

PURPOSE:To provide an automatic chemical analyzer, which can cope with the chemical analysis of multiple items and mutiple samples and can achieve the improvement of processing efficiency and the reduction of the analysis cost. CONSTITUTION:Reaction cells 31a-31k and 32a-32k, a means 40, which distributes samples into the reaction cells 31a-31k and 32a-32k, means 50 and 60, which distributes reagent, and an analysis means, which analyzes the above described sample by the reaction of the aforementioned sample and the reagent, are provided in an automatic chemical analyzer. In this analyzer, the reagent distributing means 50 and 60 have pipetting mechanisms 53 and 63, which suck the reagents from reagent cells 52 and 62 and discharge the reagent into reaction cells 31a-31k and 32a-32k, and dispensing mechanisms 54 and 64, which discharge the reagent through tubes 55a-55h and 65a-65g guided from other reagent cells.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic chemical analyzer for automatically performing chemical analysis based on a result of a reaction between a specimen sample (hereinafter referred to as "specimen") and a reagent. The present invention relates to an automatic chemical analyzer suitable for analysis of multiple samples.

[0002]

2. Description of the Related Art Conventionally, a sample (sample) is dispensed into a reaction tube, and a reagent is dispensed into the reaction tube by a reagent dispensing mechanism.
An automatic chemical analyzer is used for automatically performing chemical analysis by the reaction with this reagent. Such an automatic chemical analysis device has a processing capacity, that is, a small automatic chemical analysis device having a processing capacity of 1000 tests / 1 hour or less and a large size of 3000 tests / 1 hour depending on the number of items that can be processed in a unit time. It is divided into an automatic chemical analyzer. In general, small automatic chemical analyzers are delivered to small and middle hospitals, and large automatic chemical analyzers are delivered to large hospitals. The reagent dispensing mechanism used in small automatic chemical analyzers is a pipetting mechanism in which the tip of the nozzle sucks the required amount of reagent from each reagent bottle and discharges it into the reaction cell. The device is a dispensing mechanism that supplies the reagent from the reagent storage to the tip of the nozzle through the tube and discharges the reagent to the reaction cell as needed.

A small automatic chemical analyzer is usually constructed as shown in FIG. FIG. 3 is a plan view showing a main part of the automatic chemical analyzer. That is, reference numeral 1 is the reaction disk, the second reaction line, 2 _a to 2 _k is the reaction cell, 3 sample transporter, 3 _a to 3 _l sample cup sample is held, the first rotary reagent 4 Storage, 5 (5 _{a to} 5 _m )
Is a first reagent bottle, 6 is a second rotating reagent storage, 7 (7 _{a to} 7
_n ) is the second reagent bottle, 8 is the sample nozzle, 9 is the first
The reagent nozzle 10 indicates a second reagent nozzle. The reaction disk 1 intermittently rotates in the direction of arrow R _{1 at a} constant cycle. In one cycle, the reaction cells 2 _a to 2 _k are rotatably transferred so as to stop at a position rotated by, for example, one rotation + 1 pitch from an arbitrary stop position. Further, the first rotating reagent storage 4 and the second rotating reagent storage 6 are indicated by arrows R ₂ and R ₃ respectively.
And forward and reverse rotatable rotation direction, to rotate the transfer of the first reagent bottle 5 _a to 5 _m and the second rotation reagent bottle 7 _a to _7-n, respectively. Further, the sample nozzle 8, the first reagent nozzle 9, and the second reagent nozzle 10 are respectively provided with support shafts 8a, 9a,
It is possible to swing in the directions of arrows X ₁ , X ₂ , and X ₃ in the drawing around 10a. Furthermore, the sample carrier 3 is indicated by an arrow Y in the figure.
It is movable in linearly sample cup 3 _a to 3 _l direction.

In such an automatic chemical analyzer, a sample is analyzed as follows. The sample is dispensed to the reaction cell 2 _a when the sampling nozzle 8 moves from the sample cup 3 _a located at the sample dispensing position C to the sample dispensing position A ₁ . Next, after a lapse of a predetermined cycle, the reaction cell 2 _a is rotatably transferred by the reaction disk 1 and reaches the first reagent dispensing position A ₂ . At the same time, the first rotating reagent container 4 rotationally transfers the first reagent bottle 5 _a corresponding to the predetermined analysis item to the predetermined position B ₁ . Reagents required amount from the first reagent bottle 5 _a by the first reagent nozzle 9 is sucked, dispensed into the reaction cell 2 _a. Similarly, the reaction cell 2 _a is rotationally transferred by the rotation of the reaction disk 1 and reaches the second reagent dispensing position A ₃ after a predetermined cycle has elapsed. At the same time, the second reagent bottle 6 _a corresponding to a predetermined analysis item is rotatably transferred to the predetermined position B ₂ by the second rotation reagent storage 6. At this time, the reagent in the second reagent bottle 7 _{a and} the reagent in the first reagent bottle 5 _a may be different reagents. The required amount of reagent is sucked from the second reagent bottle 7 _a by the second reagent nozzle 10 and dispensed into the reaction cell 2 _a . Then, the result of the reaction is measured by a photometric system (not shown), and the result of the chemical analysis is reported to the operator. Similarly for the reaction cell 2 _{b and} thereafter, sample dispensing, first reagent dispensing,
The second reagent is dispensed and the predetermined analysis result is reported to the operator.

The first rotating reagent storage 4 is selected according to the analysis item.
By arranging the first reagent bottle containing the different first reagent and the second reagent bottle containing the different second reagent in the second rotating reagent container 6, the first rotating reagent container 4 and the second rotating reagent container
By rotating the rotating reagent container 6 to separate the reagents, different reagents can be dispensed for each reaction cell.

On the other hand, a large-scale automatic chemical analyzer is usually constructed as shown in FIG. That is, in the figure, 11 is a reaction disk, 12, 13, 14 are reaction lines, and 12 _a
˜12 _k , 13 _a ˜13 _k , 14 _a ˜14 _k are reaction cells, 15 is a sample transporter, 15 _a ˜15 _l is _a sample cup holding a sample, 16 is a first reagent nozzle, and 17 is a first reagent nozzle. The two-reagent nozzle, 18 is a sample nozzle provided with three nozzles. The reaction disk 1
1 rotates intermittently in the direction of arrow S at a constant cycle. In one cycle, the reaction cells 12 _a to 1 _a are stopped so as to stop at a position rotated by, for example, one rotation + 1 pitch from an arbitrary stop position.
2 _k , 13 _{a to} 13 _k , 14 _{a to} 14 _k are rotatably transferred. Further, the first reagent nozzle 16 and the second reagent nozzle 1
7 each of the six nozzle opening 16 _a ~16 _f, 17 _a ~
17 _f are provided for each of the fluid tubes 19 _a
~19 _f, 20 _a ~20 _f one end of is connected. Fluid tube _{19 a ~19 c, 19 d ~19} f, 20 a ~
The other ends of 20 _c and 20 _{d to} 20 _f are respectively connected to a reagent container (not shown) to send a predetermined reagent. In addition, the first reagent nozzle 16 and the second reagent nozzle 17 have arrows T ₁ ,
It is provided slidably in the T ₂ direction, that is, in the radial direction of the reaction disk 11. Further, the sample transport unit 15 is linearly movable in the sample 15 _a to 15 _l in the drawing direction of arrow U. Furthermore, the sample nozzle 18 is configured to be swingable in the direction of arrow V in the figure about the support shaft 18a.

In such an automatic chemical analyzer, the sample is analyzed as follows. When the sample nozzle 18 reaches the sample dispensing position D ₁ from the sample cup 15 _e located at the sample collecting position E, the sample is dispensed to the reaction cells 12 _a , 13 _a , and 14 _a , respectively. Next, the reaction cell 1 is rotated by rotating the reaction disk 11.
2 _a , 13 _a , and 14 _a reach the first reagent dispensing position D ₂ after the lapse of _a predetermined cycle. At the same time, the first reagent nozzle 16
There slides, the nozzle opening 16 _a ~ 16 _c is positioned in the reaction cell 12 _a, on 13 _a, 14 _a respectively. Subsequently, predetermined reagent via the fluid tube 19 _a ~ 19 _c are dispensed into the reaction cell _{12 a, 13 a, 14 a} . Similarly, the reaction cell 12 _a is rotatably transferred by the rotation of the reaction disk 11, and after a lapse of a predetermined time, the second reagent dispensing position D ₃
To reach. At the same time, the second reagent nozzle 17 slides, and the nozzle openings 17 _{a to} 17 _c are respectively moved to the reaction cell 12.
_It is located on _a , 13 _a , and 14 _a . Subsequently, a predetermined reagent is added to the reaction cell 12 via the fluid tubes 20 _{a to} 20 _c.
It is dispensed into _a , 13 _a , and 14 _a . Then, the result of the reaction is measured by a photometric system (not shown), and the result of the chemical analysis is reported to the operator. Reaction cells 12 _b , 13 _b , 14 _b
Thereafter, sample dispensing, first reagent dispensing, and second reagent dispensing are performed in the same manner, and a predetermined analysis result is reported to the operator.

The first reagent nozzle 1 is selected according to the analysis item.
6 and the second reagent nozzle 17 are slid and moved so that the nozzle openings 16 _{d to} 16 _f and 17 _{d to} 17 _f are located on the first reagent dispensing position D ₂ and the second reagent dispensing position D ₃ , respectively. by arranging a plurality of reagent containers within 16 _a ~ 16
_c, and 17 _a to 17 _c is dispensing reagent capable of dispensing different reagents.

As described above, since the pipetting mechanism shown in FIG. 3 is capable of directly sucking from the reagent storage, the required amount of reagent is minimized and it is suitable for use of expensive reagents. Moreover, since many kinds of reagent storages can be arranged, it is easy to make the analysis multi-item. Further, since the dispensing mechanism shown in FIG. 4 has a high degree of freedom in arranging the reagent storage, a large-capacity reagent storage can be used, and a large number of sample specimens can be analyzed without frequent replenishment of reagents. It is possible.

[0010]

However, there are the following problems in the case where a large number of processing items and samples are analyzed using the above-mentioned conventional automatic chemical analyzer. That is, in the automatic chemical analyzer using the pipetting mechanism, there is a limit to the total amount of reagents that can be arranged, and if an attempt is made to increase the capacity of the reagent storage for one item in order to handle multiple samples, the type of reagents that can be arranged, There was a problem that the number of processing items decreased. For this reason, when the number of items is increased, it is necessary to frequently replenish the reagent, and efficient processing cannot be performed.

On the other hand, in the automatic chemical analyzer using the dispensing mechanism, it is necessary to fill the inside of the tube connecting the reagent container and the nozzle with the reagent, and there is a problem that the dead volume of the reagent is large. Therefore, there is a problem that the test cost increases when the reagents are expensive such as special items such as immunological analysis items (viruses, special proteins, drugs, hormones) that reflect the characteristics of recent diseases.

Therefore, the present invention is applicable to chemical analysis of multiple items and multiple samples, can minimize the required amount of expensive reagents, and can perform efficient processing. Is intended to provide.

[0013]

In order to solve the above problems and achieve the object, the present invention provides a plurality of reaction cells, means for dispensing a specimen sample into the reaction cells, and reagents for the reaction cells. In an automatic chemical analyzer equipped with a dispensing means and an analyzing means for analyzing the specimen sample by a reaction between the specimen sample and a reagent, the means for dispensing the reagent sucks the reagent from the first reagent storage. Then, a pipetting mechanism for ejecting the reagent to the reaction cell and a dispensing mechanism for ejecting the reagent introduced from the second reagent storage via the tube to the reaction cell are provided. It is preferable that the first reagent storage is arranged in the same plane as the plurality of reaction cells, and the second reagent storage is arranged in a direction perpendicular to the plurality of reaction cells.

[0014]

As a result of taking the above-mentioned means, the following effects occur. That is, since a pipetting mechanism and a dispensing mechanism are provided as means for dispensing reagents, reagents used for special items that analyze only a small number of samples are dispensed by the pipetting mechanism, and a large number of samples are analyzed. The reagents used in the general items for performing the analysis can be dispensed by a dispensing mechanism. Here, since the pipetting mechanism sucks the reagent directly from the reagent storage and dispenses it into the reaction cell, the required amount of the reagent can be minimized and the number of reagent storages that can be arranged can be increased. On the other hand, since the dispensing mechanism dispenses the reagent from the reagent storage through the tube, the degree of freedom in arranging the reagent storage is increased, and by increasing the capacity of the reagent storage, the number of times of refilling the reagent can be suppressed. Therefore, it is possible to handle chemical analysis of multiple items and multiple samples, and it is possible to minimize the amount of expensive reagents required, so that it is possible to improve processing efficiency and reduce analysis costs.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a plan view showing a main part of an automatic chemical analyzer according to an embodiment of the present invention, and FIG. 2 is a perspective view showing the appearance of the same. 30 in FIG. 1 is a table 7 described later.
0 is a reaction disk arranged on the 0, 40 is a sample dispensing device, 50 is a first reagent dispensing device, and 60 is a second reagent dispensing device.

The reaction disk 30 is provided with double reaction lines 31 and 32 arranged concentrically, and rotates intermittently in a constant cycle in the P ₁ direction in the figure. For one cycle, reaction cells 31 _{a to} 31 described later are stopped so as to stop at a position rotated by, for example, one rotation + 1 pitch from an arbitrary stop position.
_k, 32 _a to 32 rotate to transfer along the _k the reaction line 31, 32. Therefore, the reaction cell, which will be described later, advances by one pitch after the lapse of the cycle. Reaction line 3
Reaction cells 31 _{a to} 31 _k and 32 _{a to} 32 _k formed of translucent containers are respectively held at ₁ and 32 at equal pitches. Further, the center points of the reaction cells 31 _a and 32 _a and the reaction disk 30 are arranged on a straight line, and similarly, 31 _b , 32 _b , 31 _c , 32 _c , ... Are also arranged.

The sample dispensing device 40 is provided with a sample carrier 41 slidably movable in the N direction in the drawing, that is, in a direction parallel to the tangent to the circumference of the reaction disk 30, and is held on the sample carrier 41. Sample cup 4
A sample nozzle 42 for sucking a predetermined amount of sample from 1 _{a to} 41 _l is provided. The sample nozzle 42 includes a first nozzle 43 for the reaction line 31 and a second nozzle 44 for the reaction line 32, and is provided so as to be swingable in the Z ₁ direction in the figure about the support shaft 42 _a . .

The first reagent dispensing unit 50 includes a first rotary reagent storage 51, and the reagent bottle 52 _a to 52 _m, which is held in the first rotation reagent storage 51, a first piperazinyl coating nozzle 53,
A first dispensing nozzle 54 is provided. In addition,
Reagent contained in the reagent bottle 52 _a to 52 _m can be m kinds in one.

The first pipetting nozzle 53 is a support shaft 53.
It is provided so as to be swingable in the Z ₂ direction in the figure around _a .
The first dispensing nozzle 54 is configured to be slidable in the arrow Q ₁ direction in the figure. Also provided eight nozzle orifices 54 _a through 54 _h, respectively one end of the fluid transport tubes 55 _a to 55 _h are connected. The other end of liquid transport tube 55 _a to 55 _h is connected to the reagent storage 71, which is cold is shown in Fig. Reagent storage 7
A plurality of reagent containers (not shown) are arranged in 1
They are respectively connected to the liquid transport tube 55 _a to 55 _h. The same type of reagents may be placed in these reagent containers, or a plurality of types of reagents may be placed depending on the inspection item. The liquid transport tube 55 _a ~
55 _h is installed in a heat insulation or cold insulation pipe so that the reagent in the tube does not deteriorate due to temperature. The first
The pipetting nozzle 53 and the first dispensing nozzle 54 can dispense the reagent into both the reaction lines 31 and 32, respectively.

The second reagent dispensing mechanism 60, a second rotary reagent storage 61, and the reagent bottle 62 _a through 62 _n held in the second rotation reagent reservoir 61, a second piperazinyl coating nozzle 63,
A second dispensing nozzle 64 is provided.

The second pipetting nozzle 63 is a support shaft 63.
It is provided so as to be swingable in the Z ₃ direction in the figure around _a .
The second dispensing nozzle 64 is configured to be slidable in the arrow Q ₁ direction in the figure. Also provided are seven nozzle ports 64 _a to 64 _g, respectively one end of the fluid transport tubes 65 _a to 65 _g are connected. The other end of liquid transport tube 65 _a to 65 _g is connected to the reagent storage 71, which is cold is shown in Fig. The liquid transport tube 55 _a to 55 _g is plumbed to adiabatic or the cold pipe as reagents in the tube does not deteriorate at temperature. It should be noted that the second pipetting nozzle 63 and the second dispensing nozzle 64 can dispense the reagent to both the reaction lines 31 and 32, respectively.

On the other hand, as shown in FIG. 2, the automatic chemical analyzer comprises a table 70 for supporting the reaction disk 30, the first rotating reagent container 51 and the second rotating reagent container 61, and a reagent container provided above the table 70. 71 is provided.

[0023] In addition, the reagent bottle 52 _a ~52 _m, 62 _a
Up to 62 _n contain expensive reagents used for special analysis items, and the reagent storage 71 contains ordinary reagents used for general analysis items.

The automatic chemical analyzer configured as described above operates as follows. At the sample dispensing position F ₁ ,
Sample cup 41 located at sample collection position H
_{From c} , the sample is sucked by the first nozzle 43 and the second nozzle 44 of the sampling nozzle 42 and dispensed into the reaction cells 31 _a and 32 _a of the reaction lines 31 and 32, respectively. The first nozzle 43 and the second nozzle 44 are formed in the same structure, and both of them simultaneously sample and separately dispense into the reaction cells 31 _{a to} 31 _k and 32 _a to 32 _k at the same time. There is. For this reason, the difference between samples caused by alternately dispensing the samples with one sampling nozzle is eliminated.

When the sample dispensing is completed, the reaction disk 30 rotates in the direction of the arrow P in the figure, and one cycle, that is,
Stop after 1 rotation + 1 pitch rotation. At this time, the reaction cells 31 _a and 32 _a stop at the sample dispensing position F ₁ and the next sample is dispensed.

After several cycles, the reaction cells _31a , 32
_a stops at the first reagent dispensing position F ₂ . The first reagent bottle 52 _a corresponding to a predetermined analysis item by the first rotary reagent storage 51 is rotatably transported to a predetermined position G ₁ simultaneously. By the first reagent pipetting nozzle 53, the first reagent bottle 52
_A required amount of reagent is sucked from _a and dispensed into the reaction cell 31 _a . After being dispensed, use the cleaning rule (not shown)
The inside and outside of the reagent pipetting nozzle 53 are washed with pure water, and a standby state is maintained until the next reagent dispensing.

On the other hand, the nozzle opening 54 _a of the reaction cell 32 _a first piperazinyl computing nozzles 54 corresponding to the analysis item is upwardly slid, sent from the reagent storage 71 predetermined reagent,
A predetermined amount is dispensed.

When the dispensing is completed, the reaction disk 30 is again used.
Is rotated, and the chemical reaction by the first reagent in the reaction cells 31 _a and 32 _a is observed by a photometric system (not shown). further,
After several cycles, the reaction cells 31 _a and 32 _a stop at the second reagent dispensing position F ₃ . At the same time, the second reagent bottle 62 _a corresponding to a predetermined analysis item is generated by the second rotating reagent storage 61.
Is rotatably transferred to a predetermined position G ₂ . The second reagent pipetting nozzle 63 sucks _a required amount of reagent from the second reagent bottle 62 _a and dispenses it into the reaction cell 31 _a . After dispensing, the inside and outside of the second reagent pipetting nozzle 63 are washed with pure water by a cleaning rule (not shown), and a standby state is set until the next reagent is dispensed.

On the other hand, the nozzle opening 64 _a of the second piperazinyl coating nozzle 64 in the reaction cell 32 _a upward in response to the analysis item slides, reagents are fed from the reagent storage 71, is dispensed a predetermined amount of min. Therefore, each of the reaction cells 31 _a and 32 _a is dispensed with two kinds of reagents.

Regarding the chemical reaction in the reaction cells 31 _a and 32 _a by the second reagent, the reaction is continuously observed while the reaction disk 30 is rotationally transferred by a photometric system (not shown). The reaction cells 31 _a and 32 _a for which the reaction measurement has been completed are washed and dried at a washing / drying position (not shown), and wait for the next sample analysis.

As described above, according to this embodiment, since the expensive reagent used in the special item for analyzing only a small number of samples is dispensed by the pipetting mechanism, the required amount of the reagent is minimized. The number of reagent storages that can be arranged can be increased. On the other hand, reagents used in general items that analyze a large number of samples are dispensed by a dispensing mechanism, which increases the degree of freedom in arranging the reagent storage and increasing the capacity of the reagent storage. The number of times of reagent replenishment can be suppressed. Therefore, it is possible to handle chemical analysis of multiple items and multiple samples, and it is possible to minimize the amount of expensive reagents required, so that it is possible to improve processing efficiency and reduce analysis costs.

The present invention is not limited to the above embodiment. That is, although the number of reaction lines is two in the above embodiment, the number of reaction lines is not limited to two. The reagent may be dispensed by a pipetting mechanism and a dispensing mechanism in one reaction line. Of course, various modifications can be made without departing from the scope of the present invention.

[0033]

According to the present invention, a reagent used in a special item for analyzing only a small number of samples is dispensed by a pipetting mechanism, and a reagent used in a general item for analyzing many samples is analyzed by a dispensing mechanism. Reagent dispensing can be performed. This minimizes the amount of reagents needed,
The number of reagent storages that can be arranged can be increased. Moreover, the degree of freedom in arranging the reagent storage is increased, and the capacity of the reagent storage can be increased. Therefore, it is possible to handle chemical analysis of multiple items and multiple samples, and it is possible to minimize the required amount of expensive reagents and perform efficient processing.

The reagent storage of the pipetting mechanism is arranged in the same plane as the reaction line, and the reagent storage of the dispensing mechanism is out of the same plane with respect to the reaction line.
That is, by arranging above or below the reaction disk, the device can be downsized.

[Brief description of drawings]

FIG. 1 is a plan view showing a main part of an automatic chemical analyzer according to an embodiment of the present invention.

FIG. 2 is a perspective view showing the device.

FIG. 3 is a plan view showing a main part of a conventional small-sized automatic chemical analyzer.

FIG. 4 is a plan view showing a main part of a conventional large-scale automatic chemical analyzer.

[Explanation of symbols]

30 ... reaction disk 31, 32 the reaction line _{31 a ~31 k, 32 a ~32} k ... reaction cell 40 ... sample dispensing apparatus 41 ... sample transporter 41 _a to 41 _l ... sample cup 42 ... sample nozzle 43 ... first 1 nozzles 44 ... second nozzle 50 ... first reagent dispensing unit 51 ... first rotary reagent storage _{52 a ~52 m, 62 a ~62} n ... reagent bottle 53 ... first piperazinyl computing nozzle 54 ... first dispensing nozzle 54 _{a to} 54 _h , 64 _a to 64 _g ... Nozzle port 55 _{a to} 55 _h , 65 _{a to} 65 _g ... Liquid transport tube 60 ... Second reagent dispensing mechanism 61 ... Second rotating reagent storage 63 ... Second pipette Ting nozzle 64 ... Second dispensing nozzle 70 ... Table 71 ... Reagent storage

Claims (2)

[Claims] 1. A plurality of reaction cells, means for dispensing a specimen sample into the reaction cells, means for dispensing a reagent into the reaction cells, and analysis of the specimen sample by a reaction between the specimen sample and the reagent. In the automatic chemical analyzer provided with the analyzing means, the means for dispensing the reagent includes a pipetting mechanism for sucking the reagent from the first reagent storage and discharging the reagent into the reaction cell, and a second reagent storage. An automatic chemical analysis device, comprising: a dispensing mechanism that discharges a reagent guided through a tube to the reaction cell. 2. The first reagent storage is arranged in the same plane as the plurality of reaction cells, and the second reagent storage is arranged in a direction perpendicular to the plurality of reaction cells. The automatic chemical analyzer according to claim 1.