JPH0365502B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a reagent supply device for an automatic biochemical analyzer, and more particularly to a reagent supply device for an automatic biochemical analyzer that can easily and significantly increase the number of biochemical analysis items.

Conventionally, in this type of automatic biochemical analyzer, the number of analysis items has been roughly determined based on the size of the device, mechanical control, etc.
(published in Publication No. 168553), it is not possible to analyze more than 16 items, and other devices can only analyze almost the same number of items. Limited to programmed items. Therefore, in the case of conventional biochemical automatic analyzers, when measuring items below the pre-programmed analysis items, the switching work must be performed manually, and the switching work requires changing the program. This method is extremely complicated, such as requiring replacement of reagents and reagents, and has the problem that it is virtually impossible to change the measurement items.

This invention was devised in view of the current situation, and its purpose is to provide an automated biochemical analysis method that is easy to handle and can increase the number of analysis items in automated biochemical analysis without increasing the size of the device. The present invention aims to provide a reagent supply device for an apparatus.

In order to achieve such an object, the present invention aspirates a sample at a predetermined position and dispenses it into a reaction tube, then dispenses a reagent into the reaction tube at a predetermined position, and performs colorimetric analysis using light from a light source. A reagent supply device in an automatic biochemical analyzer configured to perform measurements, which is arranged concentrically on the inner circumferential side of a turret-shaped feeding device that holds a plurality of reaction tubes into which a sample is dispensed. and a first reagent holding device on which a plurality of reagent containers according to a plurality of measurement items are mounted, which is detachable from the feeding device and can be driven independently, and a reagent is dispensed by the reagent holding device. A plurality of tubes are arranged concentrically on the inner circumferential side of a turret-shaped measurement feeder that conveys the reaction tube, and are detachable from the measurement feeder and can be driven independently. and a second reagent holding device on which a reagent container is placed.

Hereinafter, the present invention will be described in detail based on embodiments shown in the accompanying drawings.

As shown in FIG. 1, the automatic biochemical analyzer (10 containers containing the sample for comparison, 1 container containing the comparative sample, and 11 containers are arranged.) A plurality of sample cassettes F holding
and container 1 held in this sample cassette F.
A pipette device G that aspirates a predetermined amount of the sample in a predetermined position and dispenses it into a reaction tube 11, a turret-shaped feeding device H that holds a plurality of the reaction tubes 11, and this feeding device H. The feeding device H is placed on the inner circumferential side of
A first reagent container holding device A, which is a reagent supplying device that is arranged concentrically with and detachable from the feeding device H, and a first reagent corresponding to the measurement item from the first reagent container holding device A. a reaction tube exchange device L for transferring the reaction tube 11 into which a predetermined amount of the reaction tube has been dispensed from the feeding device H to the measurement turret K; and a second reagent container holding device A' which is another reagent supply device that is detachable from the measurement turret K, and an optical system for colorimetrically measuring the sample in the reaction tube 11 held by the measurement turret K. Device M
, a signal processing device N that displays and stores data measured by the optical device M, and a cleaning device O that cleans the reaction tube 11 after the measurement work has been completed. In FIG. 1, reference numeral P indicates a drive device for synchronously and intermittent rotation control of the feeding device H and the measuring turret K, and Q indicates a stirring device.

The dispensing device T includes a reaction tube 1 that is transferred to a dispensing position.
Step 1: Dispense the reagent from reagent container B corresponding to the measurement item.

Referring to FIG. 2, reagent container holding devices A, A',
The driving of the turret-like feeding device H and the measuring turret K will be explained. The reagent container holding devices A, A' have a turret plate a with a concave cross section on which the reagent containers B are placed radially, and a shaft 12 is pivotally attached to the center of the turret plate a, on which the reagent containers B are placed radially. , are intermittently driven by a drive device 81.

The turret-like feeding device H and the measuring turret K, which are disposed around the outer periphery of the turret plate a and suspend the reaction tube 11, are intermittently driven by a drive device 41 via a gear 40.

As shown in FIG. 3, this reagent container B includes a reagent storage section 1 formed into a box shape from a reagent-resistant material, a pump 2 fixed to the outside of the rear wall 1a of this reagent storage section 1, and the above-mentioned It consists of a reagent pipette 3 that is removably inserted into an opening 1c bored in the top plate 1b of the reagent storage section 1, and an extendable tube 4 that connects the reagent pipette 3 and the pump 2. There is.

The pump 2 has a piston rod 5 extending downwardly and movably, and a pawl 6 fixed to the piston rod 5.
As shown in Fig. 4, a drive device D capable of forward and reverse rotation.
The first cam 7 and the second cam 8 are arranged to engage with each other, respectively.

That is, after the pawl 6 engages with the protrusion 7a of the first cam 7, the pawl 6 descends as the first cam 7 descends, and the piston rod 5 moves downward accordingly. Then, a predetermined amount of reagent C is aspirated from the reagent pipette 3. Further, in the pump 2, the claw 6 is the protrusion 8a of the second cam 8.
After engaging with the second cam 8, the pawl 6 rises, and the piston rod 5 moves upward accordingly, causing a discharge operation, and the reagent C is discharged from the reagent pipette 3. has been done.
Note that the first cam 7 and the second cam 8 of the drive device D
Although not shown, the rotation control mechanism and the elevation control mechanism are controlled by a combination of a known cam mechanism and a gear mechanism.

Further, the reagent pipette 3 is attached to the support arm 1d so that it can be inserted into and removed from the reagent storage section 1 through the opening 1c of the reagent storage section 1 via the gripping arm 9 of the gripping device T disposed adjacent to the reagent container B. Retained.

That is, the reagent pipette 3 is removably held on the pipette support arm 1d which is placed upright near the opening 1c on the top plate 1b of the reagent storage section 1. As shown in FIG. 3, at the upper end of the
e is formed, and the opening of this support portion 1e is opened toward the direction of the gripping device T shown in FIG. Further, a stopper 3a is provided protruding from the outer periphery of the upper end of the reagent pipette 3, and this stopper 3a
is engaged with the support part 1e of the support arm 1d, so that the reagent pipette 3 is normally closed to the opening 1.
It is kept inserted in c. The stopper 3a may be configured to be vertically adjustable so that the immersion depth of the reagent C in the reagent pipette 3 can be varied.

Therefore, the reagent pipette 3 is gripped by the gripping arm 9 at the reagent C dispensing position with a predetermined amount of reagent C aspirated, and is lifted out of the reagent storage section 1 as shown by the imaginary line in FIG. It is taken out and inserted into the reaction tube 11. Next, the reagent pipette 3
The reagent C is introduced into the reaction tube 11 via the pump 2.
After discharging, it is inserted again into the reagent storage part 1 of the same reagent container B while being held by the gripping arm 9,
After this, the gripping arm 9 releases its hold on the reagent pipette 3. In this case, since the reagent pipette 3 is connected by the extendable tube 4, it is smoothly guided to the predetermined position.

Reagent container B configured in this way has six turret plates each containing 24 reagents C in the order of the most frequently used reagents.
They are arranged in a ₁ , a ₂ , a ₃ , a ₄ , a ₅ , and a ₆ . Turret plates a ₁ , a ₃ , a ₅ are arranged on the first reagent holding device A side, and turret plates a ₂ , a ₄ , a ₆ are arranged on the second reagent holding device A′ side. It is something that
A signal reading device 20 is disposed at the bottom of each turret plate _a1 to _a6 , and this signal reading device 20 engages with the reading section 21 of the feeding device H or the measuring turret K to preliminarily The programmed reagent classification signals on the turret plates _a1 to _a6 are sent to a signal processing device N to specify the type of analysis item.

Incidentally, when replacing the turret plates _a1 to _a6 , the turret plates _a1 to _a6 may be inserted into the shaft 12 and pivotally attached, for example, by tightening a stopper.

Therefore, in the biochemical automatic analyzer X according to this embodiment, the number of analysis items is _a1 - _a2 , _a3 - _a4 , _a5
−a Divide into 3 groups of ₆ , and 24 for each group.
Since each item can be measured, a total of 72 items can be analyzed, and the work of replacing turret plates _a1 to _a6 can be done simply by attaching and detaching turret plate a, making the work extremely easy. play.

In the above embodiment, the case where six turret plates a are used is explained as an example, but if there are many measurement items, six or more may be used. Of course, the number of reagent containers B placed on the turret plate a is not limited to 24, and may be more than 24 or less. Although the reagents are arranged in order of frequency, the reagents are not limited to this, and may be arranged, for example, by specific type or by specific measurement item group.

Since the present invention includes the above configuration, it is possible to easily and significantly increase the number of analysis items without increasing the size of the device, and it is possible to analyze all the items required in an automatic biochemical analyzer.

[Brief explanation of drawings]

The drawings show a reagent supply device in an automatic biochemical analyzer according to an embodiment of the present invention, in which FIG. 1 is a principle diagram schematically showing the configuration of the automatic biochemical analyzer, and FIG. , FIG. 3 is a perspective view of a reagent container, FIG. 4 is a cross-sectional view schematically showing the operating state of the device,
FIG. 5 is an explanatory diagram showing a state in which reagent containers attached to the first reagent holding device and the second reagent holding device are combined in descending order of the frequency of use of the reagents. A, A'...Reagent container holding device, B...Reagent container, C...Reagent, X...Biochemical automatic analyzer, M
...Optical device, 11...Reaction tube.

Claims (1)

[Claims] 1 Aspirate the sample at a predetermined position and dispense it into a reaction tube,
Next, dispense the reagent into the reaction tube at a predetermined position,
A reagent supply device for an automatic biochemical analyzer configured to perform colorimetric measurements using light source light,
A plurality of measurements arranged concentrically on the inner circumferential side of a turret-shaped feeding device that holds a plurality of reaction tubes into which a sample is dispensed, and which are removable from the feeding device and can be driven independently. A first reagent holding device on which a plurality of reagent containers according to the items are mounted, and a turret-shaped measurement feeding device that transports reaction tubes into which reagents are dispensed from the reagent holding device are arranged concentrically on the inner circumferential side. and a second reagent holding device on which are mounted a plurality of reagent containers according to a plurality of measurement items, which are arranged and detachable from the measurement feeding device, and can be driven independently. Reagent supply device for chemical automatic analyzer.