JPH04191661A - Method and device for taking sample dividing automatic chemical analysis apparatus - Google Patents

Abstract

PURPOSE:To make it possible to suck a prescribed amount of sample from vessels different in size by monitoring the liquid surface of the sample when the sample is sucked and by lowering a sample nozzle in following so that the position of the liquid surface required for aliquot be obtained. CONSTITUTION:According to an instruction of a control device 20, a drive motor 14 is made to operate to lower a sampling nozzle 9 to sample vessels 27 to 29 located at an aliquot-taking position 2a. When an electrode 10 detects the liquid surface of a sample, the motor 14 is stopped, a transfer valve 21 and others are set in a sample suction mode and suction is conducted. When the liquid surface lowers below the electrode 10 before aliquot-taking, the control device 20 is informed of this through a detecting circuit 15 and the nozzle 9 is lowered until the fore end of the electrode 10 detects the liquid surface again. By repeating this suction cycle, a prescribed amount of the sample is taken in partition. According to this constitution, the sample in a prescribed amount can be sucked even when the sample vessels are different in size.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to an automatic chemical analyzer used in the field of medical testing, in particular: 1. This invention relates to a sample separation method for an automatic chemical analyzer having a D recognition function and an improvement of the apparatus.

(Prior Art) In recent years, various medical tests, such as blood and urine tests, have become indispensable factors in medical diagnosis. In this case, there is always a demand from the testing side for an automatic chemical analyzer that can analyze samples efficiently and without errors. In order to meet this demand, an automatic chemical analyzer equipped with an ID recognition function has been developed and is already in use.

(Problem to be solved by the invention) However, conventional devices of this type are designed on the premise that the size of the sample container used is constant, and moreover, the work system when using this device is Because the system is such that the same container used to collect samples from patients is used throughout the analysis process, samples may be collected using containers of different sizes depending on whether the patient is an adult or a child. can also be considered. At that time, it is necessary to transfer the sample to a container (sample cup) specifically designed for automatic chemical analyzers, resulting in a deterioration of testing efficiency. Therefore, there has been a strong desire for an automatic chemical analyzer that can perform analysis work even when sample containers have different sizes.

[Configuration of the invention] (Means for solving the problem) The first configuration of the present invention to achieve this objective is to
In the sample separation method of an automatic chemical analyzer having a recognition function, the automatic chemical analyzer includes a detection means capable of detecting a sample liquid level in a sample container, and a sampling device configured to be able to be raised and lowered with respect to the liquid level. The second feature is that the nozzle descends to follow the liquid level and dispenses a predetermined amount of sample without interrupting the sampling operation when sucking the sample.The second is ID recognition. A sample aliquoting device of an automatic chemical analyzer having a function includes a detection means capable of detecting a sample liquid level in a sample container, a sampling nozzle configured to be able to rise and fall with respect to the liquid level, and when a sample absorption meter is used, The nozzle lift drive means, sample suction drive means, and sampling nozzle, which follow the nozzle descent to the liquid level and dispense a predetermined sample amount without interrupting the sampling operation, detect any descending obstacles such as the bottom of the container. and a control means for operating the drive means.

(Function) The function of the present invention based on this configuration is that when sucking a sample from a sample container, the sample liquid level is monitored by the sample liquid level detection means, and the sampling/liquid level detection means is used to monitor the sample liquid level so that the liquid level position required for sample separation is obtained. The nozzle is lowered to follow the liquid level to aspirate a predetermined sample amount.

(Example) Hereinafter, the present invention will be explained in detail based on an illustrated embodiment.

FIG. 1 is a schematic configuration diagram of a sample transfer/separation device having an ID recognition means, and FIG. 2 is a sample analysis device including an automatic chemical analyzer equipped with an ID recognition function according to the present invention and its host computer. A schematic diagram of the system, FIG. 3 is an explanatory diagram of the operation of the sample transfer/separation device in the configuration of FIG. 1.

In FIG. 2, the automatic chemical analyzer 1 is equipped with an ID recognition function. Sample transfer with a configuration known per se
The sorting device 2 has an ID recognition means 2a shown in FIG.

The analysis and measurement device 3, which has a configuration known per se, measures the degree of reactivity by adding reagents and the like to a sample dispensed into a reaction cell (both not shown) on a reaction line, using a method known per se. do. The arithmetic and control device 4 controls the devices 2 and 3 and processes their data. The host computer 5 (hereinafter simply referred to as CPU) connected online to the automatic chemical analyzer 1 includes a reader 6 that reads analysis items, test numbers, etc. from the test request form, and a reader 6 that reads analysis items, test numbers, etc. from the test request form, and inputs analysis request items and records analysis results. It is comprised of an input/output device 7 for performing searches, etc., and an analysis result report output device 8.

Now, the sample transfer/separation device 2 shown in FIG. 2 will be described in detail with reference to FIG. 1. The sample transfer/separation device 2 shown in FIG. The electrode 10 constitutes a liquid level detection sensor.

The sampling nozzle 9 is fixed to an insulating member 11. Further, the tip of the sampling nozzle 9 is cut into an inverted V shape so that suction can be performed even when reaching the bottom of the sample container. The electrode 10 is connected to the spring 129 by the insulating member 11.
It is electrically insulated from member 13. This is for liquid level detection.

The member 13 is supported by an elevating mechanism (not shown) so as to be able to move up and down in the vertical direction, and is driven by forward and reverse rotation of an elevating drive motor 14. A liquid level detection circuit 15 connected to the electrode 10 detects a change in capacitance due to the electrode 10 coming into contact with the liquid level.

The photosensor 16 is a light shielding material 17 fixed to the nozzle 9.
This constitutes nozzle overload detection. The pressure sensor 18 detects the pressure inside the tube during sample suction. The control device 20 controls the switching valve.

21 and the syringe drive motor 22 are drive-controlled.

The tubes 23, 24, and 25 communicate from the nozzle 9 to the pressure sensor 18, the switching valve 21, and the diluent tank 26.

To explain in detail each of the sample state diagrams 27 to 29, which show examples of the states of samples placed in various sample containers, the state diagram 27 is an example of the state when the sample cup 27a is used, and - The state diagram 28 when using a boat fishing container shows blood clot 28a9 separation agent 28b, serum 28c.
It is separated into

State diagram 29 uses a pediatric microcontainer 29a held by an auxiliary member 29b. As shown in FIG. 4, ID labels 30a to 30c shown in FIG. 4, which can be read by the ID recognition means 2a, are affixed to predetermined locations of the sample containers shown in these state diagrams 27 to 29. . Note that the state diagrams 27 to 29 in FIG. 1 may be expressed as sample containers 27 to 29.

Next, the operation of the automatic chemical analyzer 1 shown in FIG. 2 having this configuration will be explained using the flowchart shown in FIG. 5.

Regarding "rID reading in FIG. 5," analysis is started by setting a sample container containing a sample in any state among the sample containers 27 to 29 containing the various samples in the sample transfer/preparation device 2. When a switch (not shown) is operated, the ID labels 30 of the sample containers 27 to 29 transferred by the sample transfer device/separation device 2 are displayed.
a to 30c are read by the ID recognition means 2a when they pass through the ID recognition means 2a, and identification signals of the ID labels 30a to 30c are transmitted to the CPU 5 via the arithmetic and control unit 4.

Regarding the "worksheet request for the read ID," the CPU 5 that receives the signal searches and collates the ID based on this signal, and transfers it to the automatic chemical analyzer 1 as a worksheet.

Regarding the "setting of analysis conditions from the transferred worksheet," the apparatus 1 obtains analysis work information from this worksheet through the transfer, and performs predetermined analysis preparations.

Regarding "aspirating and aliquoting the required sample amount," when the sample containers 27 to 29 reach the aliquoting position 3a in Fig. 3,
The lifting drive motor 14 is operated in response to an instruction from the control device 20, and the sampling nozzle 9, which had been previously retracted to the upper position, is lowered. At this time, when the electrode 10 detects the sample liquid level and sends the detection signal to the control device 20 via the detection circuit 15, the operation of the lifting drive motor 14 is stopped, and the switching valve 21 and the syringe drive motor 22 are stopped.
is set to the sample suction mode, and the sample is suctioned through the nozzle 9.

At this time, if the liquid level effectively immerses the tip of the electrode 10 until a predetermined amount of sample has been taken out, the control device 20
The preparative separation process ends with a preparative separation completion signal from the controller, and the process proceeds to the sample separation into a reaction tube and the reagent separation process, which are known per se. However, before the predetermined amount of sample is completely separated, In the case of a sample that is below the tip of the electrode 10, the detection circuit detects this condition and notifies the control device 20.

At this point, the control device 20 lowers the nozzle 9 until the tip of the electrode 10 detects the liquid level again. By repeating such a suction cycle, a predetermined amount of sample is collected. Furthermore, if the tip of the nozzle 9 reaches the bottom of the sample container before the predetermined amount of sample is taken (sample state diagram 27), the light shielding member 17 of the nozzle 9 slidably attached to the member 13 Pushed up photosensor 16
A detection signal is notified to the control device 20, and the control device 20
stops the operation of the nozzle drive motor 14.

In this case, sample suction is performed until the pressure change signal from the pressure sensor 18 due to no sample is notified to the control device 20. If a pressure change signal is obtained before the predetermined amount is collected, the automatic chemical analyzer 1 separates the amount according to the priority items in case of sample shortage, and sends a sample shortage message to the analytical measurement device. Also listed in

In addition, in the case of sample 28, when the nozzle reaches the separation agent 28b due to insufficient serum volume, the pressure sensor 18 detects an increase in the internal pressure of the communication tube 23 due to the separation agent, and the controller 20 is notified and a suction operation is performed. stop.

After the above steps, two steps similar to the conventional method are executed, namely, "measurement data check" and "report with rID", thereby completing the steps before "termination".

As described above, with the sample collection method and apparatus of the present invention, a predetermined amount of sample can be aspirated even if the sample containers have different sizes.

Although the shape of the electrode is concentric with the nozzle in the present invention, the nozzle is formed of an electrical conductor and the nozzle 9 and electrode 1
A similar effect can be obtained by arranging a configuration in which 0 is provided individually and a step similar to that described above is provided between them.

Further, although a photo sensor is used to detect nozzle overload, a switch or the like may be used instead to obtain a pseudo electric signal as an input signal to the detection circuit 15.

[Effects of the Invention] As described above, according to the present invention, since the sample liquid level in the sample tube is monitored during sample aspiration during sample separation, analysis work can be easily performed even when sample containers of different sizes are used. It becomes possible to realize a novel sample separation method and device for an automatic chemical analyzer that can perform the following.

[Brief explanation of the drawing]

FIG. 1 is a schematic configuration diagram of a sample separation device according to the present invention,
FIG. 2 is a schematic diagram of a sample analysis system including an automatic chemical analyzer equipped with an ID recognition function according to the present invention and its host computer, and FIG. 3 is a schematic diagram of a sample analysis system in the configuration of FIG. FIG. 4 is a schematic external view of the sample container, and FIG. 5 is a flowchart of the analysis process according to the present invention. -13= 1: Automatic chemical analyzer 2: Sample transfer/separation device 2a: ID recognition means 3: Analysis and measurement device 4:
Arithmetic control unit 5: CPU6: Reading device
7: Input/output device 8: Analysis result output device 9: Sampling nozzle 10: Electrode 11: Insulating member 12: Spring
1-3= Member 14: Lifting drive motor 1
5: Detection circuit 16: Photo sensor 17: Light shielding material 1
8: Pressure sensor 19: Syringe 20: Control device 21: Switching valve 22: Syringe drive motor 23-25: Tube 26: Diluent tank 27-29:
Sample containers 30a to 30c: ID label agent Patent attorney Kensuke Chika Agent Patent attorney Takeshi Konfuji

Claims (5)

[Claims] (1) In a sample separation method for an automatic chemical analyzer having an ID recognition function, the automatic chemical analyzer includes a detection means capable of detecting a sample liquid level in a sample container, and is capable of rising and lowering with respect to the liquid level. An automatic chemical analyzer characterized in that a sampling nozzle configured as above is provided, and when a sample is aspirated, the descent of the sampling nozzle follows the sample liquid level, so that a predetermined amount of sample is collected. Sample preparation method. (2) In a sample separation device of an automatic chemical analyzer having an ID recognition function, a detection means capable of detecting a sample liquid level in a sample container, and a sampling nozzle configured to be movable up and down with respect to the liquid level; a nozzle elevating drive means for causing the descent of the sampling nozzle to follow the sample liquid level during sample suction; a sample suction drive means for dispensing a predetermined amount of sample through the sampling nozzle; and a descending obstacle to the sampling nozzle. 1. A sample separation device for an automatic chemical analyzer, comprising: a nozzle overload detection means capable of detecting nozzle overload; and a control means for operating each of the drive means. (3) The sample separation device for an automatic chemical analyzer according to claim 2, wherein the sample liquid level detection means is configured to have a step of a predetermined length with respect to the suction port of the sampling nozzle. (4) The control means controls the nozzle to stop descending when a nozzle overload signal is obtained by the nozzle overload detection means.
or a sample separation device for an automatic chemical analyzer according to 3. (5) Claims 2 to 4 are characterized in that the suction port of the sampling nozzle is processed so that the sample liquid can be sucked even if it reaches the bottom of the sample container.
A sample separation device for an automatic chemical analyzer according to any one of the above.