KR101628578B1 - Blood cell analysis apparatus - Google Patents

Abstract

The present invention relates to a blood cell analyzing apparatus. The blood cell analyzing apparatus includes: a dilution module mixing a blood cell sample and a diluent for analyzing the sample together; a plurality of optical analysis modules into which a fixed amount of each sample which is the same as the one extracted from the dilution module is dividedly introduced and which carries out a partition-analysis on the sample with each of the optical analysis modules; and a dividedly-introducing unit dividedly introducing the sample into the plurality of optical analysis modules.

Description

Blood cell analysis apparatus -

TECHNICAL FIELD The present invention relates to a hematology analyzer, and more particularly, to a hematology analyzer having an improved structure for improving the efficiency of blood analysis efficiency and quality control.

One of the methods for examining blood is the CBC (Complete Blood Cell Count) test widely used.

That is, the CBC test is one of the most basic blood tests with various clinical indications ranging from diagnosis to diagnosis, treatment and follow-up of the disease. Through this test, information on three types of cells (blood cells) present in the blood, that is, red blood cells, white blood cells, and platelets, can be obtained by using various parameters.

An automatic hematology analyzer is widely used to automatically measure the number of blood cells in a certain volume after appropriately diluting the blood to obtain the numerical information of the blood cell. Numerical data of hemocyte can be obtained by the technique of measuring the number of cells through a microscope using a hemocytometer, but an automated hematology analyzer is more widely used because it can measure various indices other than numerical information .

However, in the above-described conventional blood cell testing apparatus, the number of specimens to be processed per equipment is relatively small, so that a large number of hospitals (usually five or more) have been used.

It is well known that the efficiency of the blood test can be increased by using a plurality of equipments. However, in addition to having a disadvantage of purchasing a plurality of expensive equipments, control is inefficient, resulting in waste of manpower and time.

Quality management refers to all means of managing analytical values within a certain level of confidence through statistical processing in order to ensure accuracy and precision of analytical results.

Since this level of accuracy requires the same reliability of the analysis results of each equipment, it is necessary to use separate reagents or check up each equipment using patient samples.

Therefore, since the labor and time of the manager for the quality control are proportional to the number of the equipments, and the expenses such as consuming reagents are generated, it has been pointed out that the inefficiency of the quality management when using several hematology analyzers has been pointed out.

SUMMARY OF THE INVENTION The present invention has been made to overcome the above problems, and it is an object of the present invention to provide a hematology analyzer capable of simultaneously increasing blood analysis efficiency and quality control efficiency.

Another object of the present invention is to provide a hematology analyzer capable of increasing space utilization efficiency.

According to an aspect of the present invention, there is provided a hematology analyzer comprising: a dilution module in which a blood sample and a sample analysis diluent are mixed with each other; A plurality of optical analysis modules for splitting the same sample extracted from the dilution module into a predetermined amount and dividing the sample into individual optical analysis devices; And dividing inflow means for dividing the sample into a plurality of optical analysis modules and introducing the sample into the plurality of optical analysis modules.

Wherein the dilution module comprises: dilution tanks provided in a number corresponding to the optical analysis modules; A plurality of blood-side connection tubes for fluidly connecting the dilution tank and the blood extraction needle so that the blood sample can be dividedly introduced into each of the dilution tanks; And a plurality of vacuum modules for causing the blood sample to flow into the blood-side connection tube through the respective blood extraction needles.

The split inflow means may be configured to connect the dilution tank and each of the optical analysis modules in fluid-flowable and one-to-one correspondence so that sample samples stored in the respective dilution tanks can be divided and introduced into the respective optical analysis modules And a plurality of analysis side connection tubes.

Wherein the dilution module comprises: a dilution tank of the single unit; A single unit blood-side connection tube for fluidly connecting the dilution tank and the blood extraction needle of the single unit so that the blood sample can be introduced into the dilution tank in a divided manner; And a single unit vacuum module for allowing the blood sample to flow into the blood-side connection tube through the blood extraction needle.

Wherein the split inflow unit is configured to fluidly connect the dilution tank and each optical analysis module of the single unit so that a sample sample contained in the dilution tank of the single unit can be divided and introduced into each of the optical analysis modules And a plurality of analysis-side connection pipes to be connected to the network.

Wherein the dividing and introducing means includes one connecting pipe connected to the dilution tank of the single unit and a connecting pipe connected to the dilution tank of the single unit so that the sample sample accommodated in the dilution tank of the single unit can be dividedly introduced into each of the optical analysis modules, And a plurality of branch pipes branched from the optical analysis module and connected to the optical analysis modules.

The dilution module comprises: a plurality of dilution tanks; A plurality of blood-side connection tubes fluidly connecting the dilution tank and the single unit blood extraction needle so that the blood sample can be dividedly introduced into the dilution tank; A single unit vacuum module for allowing the blood sample to flow into the blood-side connector through the blood extraction needle; And selective connection means for selectively connecting the blood extraction needle of the single unit to the plurality of blood-side connection tubes.

The selective connection means preferably includes a solenoid valve selectively communicating any one of the vacuum module of the single unit and the blood-side connection tubes.

Wherein the optical analysis modules comprise analysis tanks arranged radially along the circumferential direction and in which the sample sample flows, each of the optical analysis devices comprising light sources arranged at an arrangement central axis of the analysis tanks .

In the hematology analyzing apparatus according to the present invention having the above-described structure, after the sample to be analyzed is divided into the dilution modules and introduced into the optical analysis module after each sample sample is divided by the division inflow means By analyzing the blood separately, it is possible to divide the analysis of the blood, thereby shortening the analysis time, thereby improving the efficiency of blood analysis. Moreover, it is possible to inspect the use of a plurality of equipments with one equipment, The efficiency of the system can be increased.

According to the present invention, hematology analysis can be efficiently performed even with a single apparatus without using a plurality of equipments, so that it is possible to easily secure an installation space and to increase the efficiency of space utilization. do.

1 is a block diagram of a hematology analyzer according to an embodiment of the present invention.
2 is a diagram for explaining the configuration and operation principle of an embodiment of the present invention.
3 is a diagram for explaining an example of a layout structure of an embodiment of the present invention.
4 is a view for explaining the configuration and operation principle of a blood cell analyzer according to another embodiment of the present invention.
FIG. 5 is a diagram for explaining the configuration and operation principle of a blood cell analyzer according to another embodiment of the present invention. FIG.
FIG. 6 is a view for explaining the configuration and operation principle of a hematology analyzer according to another embodiment of the present invention. FIG.

Hereinafter, a hematology analyzer according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram of a hematology analyzer according to an embodiment of the present invention. FIG. 2 is a view for explaining the configuration and operation principle of an embodiment of the present invention. Fig.

As shown in these drawings, the hematology analyzing apparatus according to the present invention is used for a CBC (Complete Blood Cell Count) test, which is one of blood testing methods. The hematology analyzing apparatus includes a dilution module 1 and an optical analysis module 2, And a division inflow means.

In order to analyze the blood, a specific diluent is used together with the target of analysis such as red blood cells, white blood cells, platelets, etc. for reasons of analysis smoothness or analysis efficiency. Here, since the specific diluent corresponds to a widely known substance, a further explanation will be omitted.

The dilution module 1 includes a dilution tank 11 as shown in FIG. 2, in which a blood sample to be analyzed and a dilution solution for sample analysis are mixed with each other.

The dilution module 1 may be implemented in various ways. In the present embodiment, a plurality of dilution tanks 11 provided in the number corresponding to the optical analysis modules 2 are connected to the blood-side connection tube 12, And a vacuum module (14).

In the dilution tank 11, the same blood sample is divided and introduced through the plurality of blood extraction needles 13 and the blood-side connection tube 12 by the function of each of the vacuum modules 14, The sample sample S formed by mixing with the dilution liquid of the dilution tank 11 flows into the plurality of optical analysis modules 2 in a divided manner.

A concrete configuration in which a blood sample to be analyzed functions from the dilution module 1 to the optical analysis module 2 will be described below.

1) Dilution module

2, the dilution module 1 employed in the present embodiment includes dilution tanks 11 provided in the number corresponding to the optical analysis modules 2. [ The same blood sample is dividedly introduced into each of the dilution tanks 11. To realize such division inflow, the present embodiment includes a plurality of blood-side connection tubes 12 and a plurality of vacuum modules 14 .

Each of the blood-side connection pipes 12 connects the dilution tank 11 and the blood extraction needle 13 so that the blood sample can be dividedly introduced into the respective dilution tanks 11 do.

Each of the vacuum modules 14 allows a blood sample to flow into each of the blood-side connection tubes 12 through the blood-extracting needle 13, for example, by a selective opening and closing operation of the channel by a solenoid valve.

2) Optical analysis module

Referring to FIG. 2, a plurality of optical analysis modules 2 employed in the present embodiment are provided with a sample sample S (S) divided into a predetermined amount as a blood sample to be analyzed is divided and introduced into a plurality of dilution modules 1 Respectively.

Wherein each optical analysis module 2 comprises an analysis tank 20 for analysis of the sample sample S and wherein the analysis tank 20 is adapted to determine whether the sample sample S is a sheath fluid (Hereinafter referred to as a "torrent") to form a rapids 23 for allowing the cells to be optically analyzed one by one.

That is, when the sample S flows into the analysis tank 20 during the flow of the torrent 23, the sample S is sucked up with the rapids 23 and elongated and elongated And blood cells of the sample sample S are aligned along the direction of elongation, respectively, so that the blood cells can be easily targeted by the optical analyzer 24, which will be described later.

Therefore, in the present embodiment, the torrent 23 and the sample S are partitioned by the main body 21 for the sake of understanding, but the torrent 23 is in contact with the sample S It is generally assumed that the sample S is formed around the periphery of the sample S.

The sample S is irradiated by an optical analyzer such as a laser 24 after passing through the main body 21.

The optical analysis device employed in the optical analysis module 2 may be variously implemented, but in this embodiment, the laser 24 is employed. As the laser 24 is irradiated, the sample S can be analyzed and counted for blood, particularly white blood cells.

On the other hand, an optical analyzer 25 is provided on the opposite side of the laser 24, with the analyzing tank as a center. In this embodiment, the trajectory of reaching the optical analyzer 25 by refraction or the like after the laser 24 is irradiated on the sample S is shown as a straight line for convenience, but it is generally bent by about 15 degrees.

As best shown in FIG. 3, the plurality of optical analysis modules 2 are preferably arranged radially along the circumferential direction in order to increase the efficiency of space utilization. According to this arrangement, the light sources of the respective optical analysis apparatuses are arranged on the arrangement central axis of the analysis tanks 20, thereby enabling optimization of the space utilization.

3) Split inflow means

As described later, the divided inflow means for dividing and introducing the sample into the optical analysis module 2 can be implemented by various methods. In the present embodiment, the dilution tank 11 and the angle And a plurality of analytical connection tubes 3 for connecting the analysis tank 20 fluid-flowable and one-to-one correspondingly.

Each of the analysis side connection tubes 3 is a method of implementing a hydraulic device such as a known fluid circuit so that a sample sample S accommodated in each of the dilution tanks 11 is supplied to each of the optical analysis modules 2, And serves as an intermediary for the inflow.

The hematology analyzing apparatus according to the present invention having the above-described configuration divides a specific blood sample into a single instrument, analyzes the result, collects the analysis values, and completes the analysis of a specific blood sample. By having a mechanism to analyze by the equipment, it is possible to further improve the analysis efficiency.

The hematology analyzer according to an embodiment of the present invention has been described above.

As described above, the hematology analyzing apparatus according to the present invention including the dilution module 1, the plurality of optical analysis modules 2, and the division inflow means divides the sample to be analyzed into the dilution module 1 After the introduction, each sample sample (S) is separately analyzed after being introduced into the optical analysis module (2) while being divided by the division inflow means, so that the analysis of the blood can be performed in a divided manner It is possible to increase the efficiency of blood analysis, and it is also possible to inspect the use of a plurality of equipments with one equipment, thereby deriving the merit that the efficiency of the quality control can be improved.

According to the present invention, hematology analysis can be efficiently performed even with a single apparatus without using a plurality of equipments, so that it is possible to easily secure an installation space and to increase the efficiency of space utilization. do.

In the drawings, reference numeral 4 (see FIG. 1) is a known resistance measuring means for measuring the size and number of blood cells in a manner using electrical resistance, that is, electric resistance principle. It is commonly used with devices.

Various embodiments of the invention described below are directed to various implementations in which the inventive concepts of the present invention may be employed.

Referring to FIG. 4, a blood cell analyzer according to another embodiment of the present invention will be described in detail.

4 is a view for explaining the configuration and operation principle of a hematology analyzer according to another embodiment of the present invention.

The embodiment shown in this figure differs from the above-described embodiment in the configuration relating to the dilution module 100 and the division inflow means, and has a difference in function due to this.

This embodiment adopts a configuration in which the configuration for blood supply and dilution is made as a single unit and the diluted sample sample is divided into the optical analysis module to be introduced thereinto, thereby having a simple configuration as compared with the configuration of the above-described embodiment.

That is, the dilution module 100 employed in this embodiment comprises a single unit dilution tank, a single unit blood side connection tube 120 and a single unit vacuum module 140, , And is composed of a plurality of analysis-side connector tubes as in the above-described embodiment.

According to this embodiment, a blood sample is extracted from one blood extracting needle 130 connected to a blood sample, mixed with the diluting solution through one dilution module 100, and then the mixed sample sample is mixed with each optical The blood analysis efficiency and the accuracy control efficiency can be improved by having the blood flow into the analysis module and the advantage of having a relatively simple configuration.

Of course, as shown in Fig. 5, one connecting pipe 301 and a plurality of branch pipes 302 (see Fig. 5), together with a dilution tank of a single unit and a dilution module composed of a single unit blood- It is also possible to implement a segmented inflow means composed of a plurality of segments.

According to this embodiment, one connecting pipe 301 is connected to the dilution tank of the single unit, and a plurality of branch pipes 302 are branched from the connecting pipe 301 and connected to each optical analysis module, The sample can be divided and analyzed.

This embodiment is troublesome in that the quantitative split valve 303 for allowing the sample sample to flow in the same way through each of the branches 302 is troublesome. However, The number of checklist items to be checked is reduced, thereby making it possible to further improve the efficiency of quality control.

FIG. 6 is a view for explaining the configuration and operation principle of a blood cell analyzer according to another embodiment of the present invention.

The embodiment shown in this figure has a structure in which a dilution module includes a plurality of dilution tanks 401 and a plurality of blood side connection tubes 402 while a single unit is adopted in the case of the vacuum module 403 .

That is, the present embodiment includes a plurality of dilution tanks 401 and a plurality of blood-side connection tubes 402, thereby enabling quick and accurate analysis of sample samples while simplifying the configuration of the blood sample supply side And enables rapid blood sample supply.

In order to exercise this function, the present embodiment includes a single unit vacuum module 403 for allowing a blood sample to flow into the blood-side connection tubes 402 through the blood extracting needle 405, And a selective connection means (406) for selectively connecting the blood extraction needles (405) of the single unit to the plurality of blood side connection tubes (402).

The selective contact means can be implemented, for example, in the same manner as the solenoid valve 406, and enables vacuum operation by the vacuum module 403 to any one of the plurality of blood-side connection tubes 402 .

This selective connecting means can further increase the efficiency of supplying the blood sample to the dilution module side, thereby further increasing the blood analysis efficiency according to the present embodiment.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Do.

1: dilution module 11: dilution tank
12: Blood side connector 13: Needle for blood extraction
14: Vacuum module 2: Optical analysis module
20: analysis tank 21:
22: a rapier forming part 23: a rapier
24: laser 25: optical analyzer
3: Analysis side connector 4: Resistance measurement means
S: sample sample

Claims (9)

delete A dilution module in which a blood sample and a diluent for sample analysis are mixed with each other; A plurality of optical analysis modules for splitting the same sample extracted from the dilution module into a predetermined amount and dividing the sample into individual optical analysis devices; And division inflow means for dividing and introducing the sample into the plurality of optical analysis modules,
Wherein the dilution module comprises: dilution tanks provided in a number corresponding to the optical analysis modules; A plurality of blood-side connection tubes for fluidly connecting the dilution tank and the blood extraction needle so that the blood sample can be dividedly introduced into each of the dilution tanks; And a plurality of vacuum modules for allowing the blood sample to flow into the blood-side connection tube through the respective blood extraction needles,
The optical analysis modules comprising analytical tanks arranged radially along the circumferential direction and into which the sample sample is introduced,
Wherein each of the optical analyzers comprises light sources disposed on the central axis of the array of the analysis tanks and optical analyzers positioned on opposite sides of the respective analysis tanks. 3. The method of claim 2,
The split inflow means,
A plurality of analytical connection tubes for connecting the dilution tank and each of the optical analysis modules to each other in a fluid-flowable manner and in a one-to-one correspondence relationship so that a sample sample contained in each of the dilution tanks can be dividedly introduced into each of the optical analysis modules, And a blood cell analyzer for analyzing the blood cell. delete delete delete delete delete delete

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