JPH09145594A - Method for determining and displaying particle aggregation pattern of reacted specimen in clinical inspection and print system thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance the accuracy while correcting a data by picking up the particle aggregation pattern of reacted specimen on a microplate and obtaining an image data and then analyzing and comparing the image data. SOLUTION: The particle aggregation pattern of a specimen in each well on a microplate 2 is picked up by means of a CCD camera 4 and the video signal of image being delivered to an image processing unit 6 is subjected to A/D conversion thus obtaining the image data of individual specimen. In this regard, only the effective part of particle aggregation pattern in a hole is taken out to produce an image data. Feature values (concentration, volumetric parameter) particle aggregation pattern in the well of specimen of are then operated using the image data in effective part. Parameters of the feature values are compared with decision criteria thus determining the attributes of aggregation image of specimen.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to reading of a particle aggregation pattern and determination of results in a reacted sample reacted in a well of a microplate in clinical tests such as blood group and virus tests using the agglutination method. The present invention relates to an automatic inspection method and an improvement of an inspection system used for the inspection method.

[0002]

2. Description of the Related Art A means for automatically discriminating the pattern of agglutination image of particles of a reacted sample reacted in each well of a microplate is to obtain some parameters as information of the agglutination pattern of the sample. Conventionally, there has been known means for digitizing and storing in a memory, comparing these digitizing parameters with a judgment reference value, and determining whether the attribute of the particle aggregation pattern corresponds to aggregation / non-aggregation or other. There is.

On the other hand, there is a means of using a hard copy of the particle aggregation pattern of the sample. This means is a means for taking a picture of a microplate exhibiting a predetermined aggregation pattern in each well and performing discrimination from this picture.

[0004]

When performing visual judgment of a particle agglomeration pattern by human eyes, a certain pattern is digitized so as to approximate human recognition, and when automatically judged by these numbers, Almost the same result as the human visual judgment can be obtained. The digitization method for this pattern is solved as an issue.

In addition, a photograph of the microplate in which each reacted sample is present in each well arranged in parallel is taken, or the judgment result of only digitized data is stored,
A means for making a hard copy of the particle agglomeration pattern of each sample and discriminating the particle agglomeration pattern based on this makes correspondence between individual sample IDs and test results in the photographs taken when performing a large number of sample inspection processes. There is a problem that it takes a lot of time and labor to perform the operation, moreover, it is easy to make a work mistake, and the management and the search are inconvenient.

Further, there is a demand that the characteristic values of the particle agglomeration pattern of individual specimens, data such as inspection results and the images thereof be saved as a file and can be searched at any time.

The present invention has been made in order to solve the above-mentioned problems occurring in the conventional means, and it is possible to accurately inspect and discriminate the particle aggregation pattern of the reacted sample in each well of the microplate. In addition, the image data of each sample can be saved as a file together with the numerical data such as the characteristic value of the particle aggregation pattern of each sample and the test result for each well, and the plate ID for each plate can be saved. Further, the feature value of the particle aggregation pattern of the sample, the inspection result, and the image data thereof can be searched by the sample ID of each sample. Moreover, from the stored image data of the particle agglomeration pattern of each sample, the pattern can be reproduced and displayed on the monitor in a display method such as light and shade, concentration distribution cross section, three-dimensional, etc. According to the analysis comparison,
The purpose is to provide a new means to check the improvement of accuracy and correct the data.

[0008]

In the present invention, as means for achieving the above-mentioned object, a particle aggregation pattern of a reacted sample in a well on a microplate is photographed by a CCD camera, The video signal is A /
The image data is obtained by D conversion and taken in a buffer, and the image is displayed on the screen of the display device. The average density of aggregated particles in a certain concentration layer and aggregated aggregated particles are displayed according to the transmittance of each pixel of the particle aggregation pattern. The present invention proposes a method for inspecting a particle aggregation pattern of a reacted sample in a clinical test, which comprises determining the amount and determining the attribute of the sample aggregation image using these data as parameters.

More specifically, in the means of the present invention, the imaging of the particle aggregation pattern of the reacted sample in each well aligned on the microplate with a CCD camera is reliable and reproducible. In order to obtain good data, the microplate is divided into a plurality of sections, and the sections are divided into sections. For example, in the case of a plate in which the number of wells to be aligned is 120, it is divided into 4 and 5 × 6 = 30.
The particle aggregation pattern of the specimen in each well is photographed.

Further, in order to read the image of the particle agglomeration pattern of the sample in each well taken and to process the image, the video signal is A / D converted and sent as digitized data to the image processing unit, and the sample in each well is read. Do each one individually.

At this time, in order to avoid the influence of the edge shadow of the well, a round area slightly smaller than the well size is determined, and image data in this area (referred to as an effective portion) is used.
The characteristic value of the particle aggregation pattern is obtained.

The steps of reading an image of the particle agglomeration pattern of the sample photographed in each well and processing the image are as follows:
By performing A / D conversion on the video signal of the image captured by the CD camera and sent to the image processing unit, the image data of each sample can be obtained. At this time, the data is taken as image data by extracting only the effective portion in the hole of the particle aggregation pattern. Using the image data of this effective portion, the characteristic value (parameter such as concentration and volume) of the particle aggregation pattern in the well of the sample is calculated, and the characteristic value parameter is compared with the determination reference value to make the determination result. Further, the total result is determined based on the determination result in each well for each sample unit.

Further, the obtained image data is stored in a data storage device, but in order to save the capacity of the device, only the effective portion in the hole of the above-mentioned particle aggregation pattern is taken out and the image of each specimen is stored. Save as data.

Further, in order to maintain the accuracy of calculation of the judgment feature value, the particle aggregation pattern center position determination process is performed for each well so that the physical center of gravity of the particle aggregation pattern is always aligned with the center of the effective portion.

Further, in order to perform the image reading process accurately, it is carried out for each well, but at this time, the read image data is temporarily stored in the buffer and the image is displayed on the display screen. A window moving operation is performed for each well so that the center is adjusted to the physical barycentric coordinates of the image of the particle aggregation pattern of the sample in the well.

This window movement operation utilizes recursive processing, and if the physical center of gravity of the sample particle agglomeration pattern is at an arbitrary point within the initial window, the window center is taken as an image image of the sample particle agglomeration pattern. It will automatically adjust to the physical center of gravity of.

The image of the particle agglomeration pattern of the sample taken by the CCD camera is processed by transmitting each pixel of the effective portion centered on the physical center of gravity of the image of the particle agglomeration pattern on the image of the particle agglomeration pattern. Depending on the rate
The concentration value of aggregated particles on a certain concentration layer is statistically converted. Thus, the average density of aggregated particles and the aggregated amount of aggregated particles in a certain concentration layer are obtained, and the attribute of the sample aggregated image is determined using these data as parameters. As a result, almost the same result as the visual judgment can be obtained.

The image data is recorded by storing the transmittance data of each pixel in the effective pattern area in an external memory in units of wells. Re-determination is performed based on the stored image data. Furthermore, based on the stored image data, a grayscale image of the particle aggregation pattern is reduced on the display screen, and the density distribution in the visual direction and the vertical direction is calculated by the density correlation calculation on a plurality of rings with respect to the center of the pattern. It is possible to display a clear three-dimensional view of the average cross section and the details of the particle aggregation pattern.

The display of the above-mentioned determination result and particle aggregation pattern is managed by the plate ID and the sample ID so that they can be simultaneously displayed on one screen.

The above judgment results and particle agglomeration patterns are managed by the plate ID and the sample ID, and when the data is input to the printer when necessary, the printer simultaneously prints on one sheet of hard copy. Will be done.

[0021]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described with reference to the following drawings. FIG. 1 is an overall system configuration diagram of the inspection apparatus of the embodiment, FIG. 2 is an example of a screen display displayed on the screen of the display apparatus, and FIG. 3 is an example of a particle aggregation pattern printed on a sheet by a printer. Is a reflection mirror, 2 is a microplate, 3 is a light source, 4 is CC
D camera, 5 is a drive / control mechanism for driving and controlling the operation of a moving mechanism for moving the microplate 2, and controlling the operation of the CCD camera, 6 is an image processing unit, 7 is a display device, 8 is a personal computer, 9 indicates a printer.

The microplate 2 is an ordinary one in which a large number of wells for accommodating a small amount of sample are arranged in an array, and is an abutment body movably supported in the front and rear and left and right on a body (not shown). A micromounter is mounted on the micromachine so that the abutment is displaced by the drive / control mechanism 5 incorporated in the machine body so as to be displaced in the desired amount in the front-rear direction and the left-right direction to obtain the pixels required for the determination. Read the plate separately.

The drive / control mechanism 5 controls the drive of the above-mentioned microplate 2 and CCD camera 4 in response to a command from a computer incorporated in the personal computer 8.

The image processing unit 6 is provided with an A / D converter for A / D converting the video signal of the image from the CCD camera 4 into digitized data (image data), and a buffer for temporarily storing this data. To do.

The display device 7 displays data in characters and
Although it is a normal one that is displayed on a cathode ray tube as a figure,
The particle aggregation pattern of the sample photographed by the CCD camera 4 is monitored in the window on the screen.

The personal computer 8 has a computer incorporated therein, whereby the control of the drive / control mechanism 5 and the arithmetic processing of the image data inputted from the image processing unit 6 and the screen of the display device 7 are performed. Controls such as effective area determination processing and center position determination processing of the image of the particle agglomeration pattern monitored in the window are performed.

The printer 9 responds to the supplied sheet by
It is an ordinary one that prints a predetermined character / figure by an input signal, and image data of a particle agglomeration pattern photographed by a CCD camera is printed by a signal sent from the personal computer 8.

The microplate 2 on which the particle agglomeration pattern of the reacted sample supplied to the above-mentioned inspection device is placed on each well is conveyed to a predetermined position above the light source 3 by the drive / control mechanism 5.

The image of the particle agglomeration pattern in each well of the microplate 2 is CC imaged by the mirror 1.
The video signal is sent to the D camera 4 and converted by the image processing unit 6 into image data.

This image data is subjected to the effective area determination and the center position determination processing of the particle aggregation pattern under the control of the personal computer 8 and then each particle aggregation pattern relating to the aggregation degree of the particle aggregation pattern in the well. The feature value of is calculated for each well.

The result of the particle aggregation pattern is obtained by comparing the parameter of the characteristic value of the particle aggregation pattern calculated for each well with a preset reference value. The results of all the well patterns of one sample are compared with the integration determination condition to obtain the integration result.

The characteristic value of the particle aggregation pattern, the determination result for each well, the total result for each sample unit, and the image data for each well are made into a file and stored in a hard disk of a personal computer.

The saved file is loaded, the characteristic value data of the sample contained in the file, the determination result, or the image of the particle aggregation pattern is displayed on the monitor 7 and printed by the printer 9.

[0034]

According to the present invention, the following effects can be obtained. Aggregation of the particle aggregation pattern of the sample for each well,
Since an image of the particle aggregation pattern can be saved together with the automatic determination result such as non-aggregation, when an abnormal result or data is generated, the particle aggregation pattern can be displayed immediately on the monitor for comparison.

The digitized data (characteristic value) of the precious particle agglomeration pattern and the image data photographed by the CCD camera can be stored for a long time (unless the corresponding file is deleted), and multi-system image display and printing can be performed. By storing the image data obtained by CCD photography in addition to the numerical data, it is possible to leave a record as basic information for reconfirmation and determination of numerical data in the past.

[Brief description of the drawings]

FIG. 1 is an example of an overall system configuration diagram of an inspection apparatus for a particle aggregation pattern of a sample according to the present invention.

FIG. 2 is a plan view and a three-dimensional view of a particle aggregation pattern displayed on the screen of a display device.

FIG. 3 is a plan view and a cross-sectional view of a particle aggregation pattern printed on a sheet by a printer.

[Explanation of symbols]

1 ... Reflective mirror, 2 ... Microplate, 3 ... Light source, 4
... CCD camera, 5 ... Drive / control mechanism, 6 ... Image processing unit, 7 ... Display device, 8 ... Personal computer, 9 ... Printer.

Claims (2)

[Claims] 1. An average concentration of aggregated particles and a volume of aggregated particles in a concentration layer having each particle aggregation pattern of a reacted sample in a well on a microplate are obtained, and these digitized characteristic values are used as judgment reference values. A method for determining a particle agglutination pattern of a reacted sample in a clinical test, which is characterized by determining the attribute of a sample agglutination image. 2. An agglutination pattern (concentration image) of each of the reacted particles in a well on a microplate is displayed, and an analysis image such as a judgment result and a concentration distribution sectional view of the pattern, a three-dimensional diagram, etc. is displayed. Display and print on the same screen so that it is easy to compare and confirm the numerical value of the judgment result and the image.Display and print of the particle aggregation pattern of the reacted sample in the clinical test. method.