JP2000139445A - Testing of microorganism or the like and apparatus therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide both a method for testing microorganisms, or the like, by which the microorganisms are specified, images thereof are accurately grasped and picked up, respective devices for testing specimens are collectively built in one casting unit to automatically carry out judgment of the specimens and accumulation of test results therein and sterilizing and bactericidal treatments of the specimens can simply be conducted, and an apparatus therefor. SOLUTION: This method comprises a culture apparatus, an image take-in device, an arithmetic processing unit and a predisposing treatment device installed so as to separate an image of a specimen obtained from a specimen collected from a substance or an object having microorganisms into the three primary colors, calculate the color information about the respective primary colors, then compare the resultant color information with a first data of the preaccumulated information about the microorganisms, or the like, by the above technique or further an overall data obtained by, as necessary, attaching a second data such as genetic information about the microorganisms, extract characteristics unique to the microorganisms, determine the species thereof, subsequently calculate the predicted breeding state thereof after the passage of a prescribed time and thereby predetect the state of the microorganisms after the passage of a prescribed time required for the breeding of the microorganisms in the specimen thereof.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for testing microorganisms and the like and an apparatus therefor.

[0002]

2. Description of the Related Art The original Shirasu Institute of Science and Technology Co., Ltd., which was merged with the present applicant, has previously filed Japanese Patent Application No. Hei 10-36827.
No., Title of Invention: As an "inspection method and apparatus for an inspection object such as a microorganism", an image of an inspection object cultured in a short time (for example, about 5 to 6 hours) is separated into three primary colors and the like.
For each color, calculate the color information of the histogram, color, and hue, determine the growth coefficient for predicting the growth of the microbial community, and the characteristic coefficient for determining the unique characteristics of each microbe, and then calculate in advance in the same way as the same method By searching the data prepared for accumulation and comparing them, the bacterial species is identified (identified),
Furthermore, by using these growth factors, etc., the reproduction is predicted after the lapse of a general culture time (24, 48 hours, etc.) necessary for the bacterium. An application has been filed so that the later state can be easily known.

[0003]

SUMMARY OF THE INVENTION The present invention is a method and an apparatus developed from the aforementioned Japanese Patent Application No. 10-36827, titled "Method and Apparatus for Inspection of Microorganisms and the Like". , It is the identification of microorganisms,
Accurately grasping and capturing the image, and integrating each device for inspecting the inspection object in one housing, automatically determining the inspection object and accumulating the inspection results there, It is an object of the present invention to provide a method and an apparatus in which sterilization and sterilization of a test object can be easily performed.

[0004]

Means for Solving the Problems In order to be able to know in advance the state of reproduction of the above-mentioned microorganisms (viable bacteria) after a certain period of time, foods such as foods including drinking water and processed materials thereof were collected. The image of the test object is separated into three primary colors in the arithmetic processing unit, color information of a histogram, hue, and color of each primary color is calculated, and the information is added to the first data of the information stored in advance by the method described above. By extracting characteristics unique to microorganisms and determining their types by comparing them with comprehensive data with attached second data such as genetic information, and then calculating the predicted reproductive state after a certain period of time. Thus, a test method for microorganisms and the like for detecting in advance the state after a certain period of time necessary for the propagation of microorganisms in the test object, and a dyeing process and a luminescence process are performed on the test object in advance as necessary, An imaging device that accurately captures images of living organisms, and related devices for inspecting specimens are collectively stored in a single enclosure, where specimens are automatically judged and test results are accumulated. In addition, an inspection device for microorganisms and the like that can perform sterilization and sterilization of the inspection object is also provided.

[0005]

BEST MODE FOR CARRYING OUT THE INVENTION A method for testing microorganisms according to the present invention will be described. An image of the test body obtained from a sample collected from a substance or an object having microorganisms, or if necessary, before and after culturing, light-emission, an image of the test body subjected to a treatment such as staining is separated into three primary colors, etc. The color information of the histogram, the hue, and the hue is calculated, and the first data by the method previously accumulated, and the first data,
Create data with attached secondary data such as genetic information of microorganisms, use this as comprehensive data, compare this comprehensive data with information on new specimens, extract characteristics unique to microorganisms, Is determined, and then the predicted state of propagation after a certain period of time is calculated. .

[0006] Second information such as genetic information of the microorganism [gene amplification (PCR) method: random PCR (RAPD) method, pulse field gel electrophoresis (PFGE) method], etc.
Examples of such data include (1) a normal culture method, (2) an enzyme-antibody (EIA) method, and (3) an immunomagnetic bead method. The characteristics of microorganisms obtained by these methods are quantified. Each or some of the data obtained is used. As described above, according to the present invention, comprehensive data in which second data such as genetic information of the aforementioned microorganisms are attached to the previously stored first data of the microorganisms and the like and compared with a new test object is used. That is, comparing the first data with a test object to be newly inspected this time, when the new test object is the same as a certain microorganism having the first data, the data is extracted and attached to the data at the same time. Gene information and the like are also extracted. Therefore, the identification of the bacteria will be performed reliably based on the genetic information, etc.
The accuracy of identification of the type of microorganism can be further improved.

FIG. 1 shows, as an embodiment of the present invention, an inspection apparatus (J), a culture apparatus [an incubator with an automatic insertion mechanism] (A), an image capturing apparatus (B), and an arithmetic processing. Equipment (C) [computer, etc.], pre-disposal equipment (D)
FIG. 2 is a configuration diagram showing a related arrangement of a power supply unit, a control unit (E), and the like. FIG. 2 is an external view of the inspection device (J) in which these devices are integrated into a housing (H). . It has an insertion slot (h) on the front left side for inserting test specimen containers (1) each containing a specimen (x) [agar, etc.], which is the collected medium, one by one. Monitor screen on the right front of
(2) is provided, where the inspection result, the state of the surrounding environment, and the like can be observed. On the right side of the housing (H), two specimen containers (1) containing the specimen (x) are placed.
Magazine for stacking 0 sheets at a time and storing 4 rows (3)
There is a handle (3 ') for taking out (see below).
When a magnetic field or an electric field is applied to the test object (x), the formation of colonies is promoted. Therefore, when a device incorporating the unit is used, the culture time can be further reduced.

FIG. 3 (a) is a plan view showing the inside of the housing (H) of FIG. 2, and the test bodies (H) are inserted into the culture device (A) one by one from the insertion slot (h). The specimen container (1) containing x) is provided with an identification code such as a bar code, and a set of 20 pieces stacked vertically on the rotating circular mounting table (4) Four sets are arranged in the inner circumference of (4), and a total of 80 sheets are stored.
In this, culturing is performed for a certain time (for example, 6 hours). When the culture is completed, the test object containers (1) are taken out one by one from below by a test object container take-out mechanism (5) [FIG. 1; transport device 1], and after opening the lid, the image taking device (B) [CCD camera, etc.] where the object (x) is photographed. Then, the data of the photographing result is taken into the arithmetic processing unit (C). After the specimen container (1) has been taken, the lid is closed and the specimen container feed arm (6)
[FIG. 1; transport device 2], using the shuttle mechanism (7) as a guide, is sent to a magazine (3) arranged at the rear, where 20 sheets are stacked and stored in four rows,
Sterilization is performed by the pre-disposal equipment (D) [germicidal lamp etc.] to be installed. Thereafter, the magazine (3) is taken out of the housing (H).

[0009] The pre-disposal device (D) may not be provided in the housing (H), and may be taken out of the housing (H) and sterilized. FIG. 3B is a diagram showing the internal front of FIG. 3A except for the arithmetic processing unit (C), and FIG. 3C is an internal side view of the same. In some cases, a device for sterilizing the photographed specimen (x) and the specimen container (1), for example, a sterilizer using a microwave or the like may be incorporated. In this example, the specimen (x), which was the collected medium, was placed in the specimen container (1).
It describes the mechanism of handling when placed in
Depending on the type and mode of the test object (x), the mechanism for handling it
Each of them is appropriately designed, and is not limited to the mechanism of the above embodiment. Further, when the number of specific bacteria increases beyond a certain level in the test object (x), it may be detected and an alarm lamp, a buzzer or the like may be activated. In addition, in a room or the like where this housing (H) is arranged, an additional device for measuring the temperature, humidity, dust, etc. of the space is arranged separately, and information obtained therefrom is sent to the arithmetic processing unit (C). It can also capture and manage the environment.

FIG. 4 shows an inspection object container (1) containing an inspection object (x).
5 is a flow chart from insertion of a cell to culture, image capture, sterilization, and removal.

Next, in the present invention, the test object (x)
The illumination mechanism used in the shooting will be described.
It is indispensable to surely grasp the specimen (x) when taking a picture, but currently an image of the specimen is obtained by illumination from the top surface. This is good when the inspection object is thin, but it is sometimes difficult to obtain the details of the image because the light is easily transmitted. Therefore, in the present invention, the illumination mechanism that can change the illuminance as required on the upper and lower surfaces illuminates the inspection object (x) so as to sandwich it. Further, this lighting device has a feedback function of automatically adjusting the illuminance according to the test object (x). Inspection body by them
The reflected light and the transmitted light are brought to (x), and the details of the inspection object (x) can be captured.

Further, these circumstances are shown in FIGS. 5 (a) and 5 (b).
FIG. 5A shows one image of an inspection object.
(Q), showing a state in which the contour α of the colony [village] (cl ₁ ) and the colony (cl ₂ ) have a crack (scratch or bubble) β. Here, we will describe the case of lighting only from one side.
The contour α of the colony (cl ₁ ) can be judged (searchable) to some extent, but it may be necessary to adjust the illuminance to obtain a more accurate contour α. Next, with respect to the crack β of the colony (cl ₂ ), it is more difficult to obtain the crack β, the flaw, and the bubble at the illumination intensity for searching the contour α. Further, in order to determine the contour α, it is necessary to increase the illuminance, and if the illuminance is increased, it may be difficult to confirm cracks, flaws, bubbles, etc. due to reflection on the surface of the culture medium. According to the present invention, as shown in FIG. 5B, a more detailed outline α ′ can be obtained by transmitting illumination from the lower surface around the outline α ′. For the crack β ′, the details of the crack β ′ can be obtained by changing the illuminance of each lighting device according to the test object (x).

FIG. 6 shows two light sources (I) and (II) arranged with respect to the inspection object (x) and two light receiving portions (I ') and (I').
I ′) and a relationship of controlling the same by the control device (Cr). In this manner, two types of light sources are mounted, and among the two types, the light source (I) is used as the reference light source, and the light source (II) is used. ) Can emit full color light. The light source (I) is installed so as to surround the test object (x), the light source (I) emits reference light, and the light reflected from the test object (x) is detected by the light receiving unit (I ′). A signal is transmitted to the control device (Cr). The control device (Cr) compares the light receiving signal and the light emitting signal, and sends an optimum signal to the light source (I). The same operation is performed for the light source (II). Thus, the characteristics of the test object (x) are more accurately recognized using the two types of light sources. The number of such light sources may be appropriately increased. It is also effective to use the illuminance variable.

Further, the CCD camera (B) is slightly moved. FIG. 7 is a diagram showing the movement of the image before and after the movement. That is, a CCD camera (B) is installed in a mechanism that moves in the X and Y directions, and an image before movement (Q ′ ₁ ) and an image after movement (Q ′ ₂ ) are captured as shown in FIG. The result is a method of improving the resolution by performing an interpolation operation. The image N obtained by this processing method is the pre-movement image N
₀ + the moved image N ₁ is divided into two. This can be done without moving the CCD camera (B).
It can also be performed by using a mechanism for appropriately moving (x). FIG. 8 is a flowchart from the start to the end of image capture, and shows the process of the interpolation process between the image (Q ′ ₁ ) and the image (Q ′ ₂ ). Here, for example, the container itself of the test object container (1) is formed by mixing a material of a luminescent substance that emits light when irradiated with light such as near-ultraviolet light, and by reading an image while emitting fluorescence, the accuracy of the determination is improved. Can be improved.

[0015]

The present invention relates to the above-mentioned Japanese Patent Application No. Hei 10-3682.
No. 7, Title of Invention: Short time (about 5 to 6 hours) in "Testing Method and Apparatus for Test Objects such as Microorganisms"
Separates the image of the test specimen cultured in the above into three primary colors, calculates the histogram, color, and hue for each color, and determines the growth coefficient for predicting the growth of bacterial colonies and the characteristic coefficient for judging the unique characteristics of each microorganism Then, by searching for data that has been calculated and stored in advance in the same manner as in the same method, and comprehensive data to which gene information and the like proposed in the present invention are attached, and by comparing them, the bacterial species is identified (identified). ), And furthermore, by using those growth factors, etc., by predicting the reproduction after the lapse of the general culture time (24, 48 hours, etc.) necessary for the bacterium, a constant The method and apparatus according to the present invention enable the state after the passage of time to be easily known.

This makes it possible to make a more accurate determination of microorganisms, and to accurately capture images of those microorganisms. In addition, related devices for inspecting a test object are provided in one enclosure. Each of the inspection organizations and businesses is a device that integrates and integrates them into the system, and automatically determines the test object and accumulates the test results, and can easily perform sterilization and sterilization of the test object. By arranging and equipping in a place, etc., it is necessary to automatically determine what the target test object is, even without knowledge of the test object, accumulate the results, and thereby prepare for future inspections By subjecting the test body to a predetermined sterilization and sterilization treatment, it can be safely disposed of. In this way, anyone can accurately perform such an inspection, without relying on a specialized inspector.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing an apparatus for testing microorganisms and the like according to the present invention.

FIG. 2 is an external view of an embodiment of an inspection device for microorganisms and the like in the present invention.

FIG. 3 is a diagram showing a main part of an inner surface of the inspection device for microorganisms and the like in FIG. 2;

FIG. 4 is a flowchart illustrating a process from insertion to removal of a test object according to the embodiment of the present invention.

FIG. 5 is a diagram illustrating contour extraction of an image of a colony of a test object and lighting conditions of cracks.

FIG. 6 is a configuration diagram of a light source / light receiving unit and a control device for an inspection object according to the present invention.

FIG. 7 is an explanatory diagram of a photographing device for an inspection object according to the present invention.

FIG. 8 is a flowchart from the start to the end of image capturing of an inspection object according to the present invention.

[Explanation of symbols]

(J) Inspection device (A) Culture device (B) Image capture device (CCD camera) (C) Arithmetic processing device (D) Pre-disposal device (E) Power supply and control device (H) Housing (x) Inspection Body (1) Specimen container (h) Slot (2) Monitor screen (3) Magazine (3 ') Handle (4) Mounting table (5) Specimen container removal mechanism (6) Specimen container feed arm (7 ) Shuttle mechanism (Q), (Q ' ₁ ), (Q' ₂ ), (Q ") Image (Cl ₁ ), (cl ₂ ) Colony (I), (II) Light source (I '), (II' ) Receiver (Cr) controller

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G06T 7/00 G06F 15/62 395 5L096 15/70 460D 9A001 F-term (Reference) 2G020 AA04 AA05 AA08 DA02 DA03 2G059 AA05 BB12 EE01 EE02 HH02 HH03 KK04 MM05 4B029 AA03 AA07 AA08 BB01 CC02 CC07 FA03 FA15 GA01 GA06 GB10 4B063 QA18 QQ05 QR66 QS39 QX01 QX10 5B057 AA07 BA19 DA03 DA12 DA15 H06H KK60

Claims (11)

[Claims] 1. An image of a test object obtained from a sample collected from a substance or an object having microorganisms, or an image of the test object which has been subjected to a treatment such as emission or staining before or after culturing as required, into three primary colors or the like. Separate, calculate the color information of the histogram, hue, and color of each primary color, and attach the second data such as genetic information of microorganisms to the information and the first data of information such as microorganisms according to the method previously stored. By extracting the characteristics unique to microorganisms by comparing them with the comprehensive data obtained, determining the type of the microorganisms, and then calculating the expected state of reproduction after a certain period of time, it is necessary to reproduce the microorganisms in the specimen. An inspection method for microorganisms that detects the state after a certain period of time in advance. 2. An image of a test object obtained from a sample collected from a substance or an object having microorganisms, or an image of the test object which has been subjected to luminescence, staining, or the like before or after culturing if necessary, into three primary colors or the like. Separation, calculation of the color information of the histogram, hue, and color of each primary color, and the information and the first data of the information according to the method previously stored such as microorganisms, or the first data if necessary, the genetic information of microorganisms By comparing with the comprehensive data attached with the second data such as the above, the characteristic unique to the microorganism is extracted and its type is determined, and then the breeding prediction state after a certain period of time is calculated, Inspection devices such as culturing devices, image capturing devices, arithmetic processing devices, and pre-disposal devices that detect in advance the state after a certain period of time necessary for the propagation of microorganisms in the test object, such as microorganisms An inspection device for microorganisms and the like, comprising: 3. The inspection apparatus for microorganisms and the like according to claim 2, further comprising an illuminating device including a light source for irradiating the object to be photographed and another one or more corresponding light sources. . 4. The apparatus for testing microorganisms or the like according to claim 2, further comprising a camera mechanism and / or a moving mechanism of the test object for photographing the test object. 5. The method according to claim 2, wherein the culture device, the image capturing device, the arithmetic processing device, and the preliminary disposal device are integrated in the housing. Inspection equipment for microorganisms. 6. An insertion slot for inserting test specimen containers containing test specimens one by one is provided in the housing, and a plurality of the test specimen containers are vertically arranged on a circular mounting table rotating in the housing. After being cultured for a certain period of time, the test object containers are taken out one by one from below by the test object container take-out mechanism, and after opening the cover, sent to the image capturing device. 4. The inspection object container taken in the arithmetic processing unit and photographed is closed, then closed, sent to a magazine by an inspection object container feed arm, and accumulated in a certain number to be accumulated. An inspection device for a microorganism or the like according to claim 4. 7. The apparatus for testing microorganisms according to claim 2, wherein a monitor screen is provided on the housing. 8. The microorganism according to any one of claims 2, 3, 4, 5, 6, and 7, further comprising a device for sterilizing the photographed test object. Such as inspection equipment. 9. A test object, when the number of specific bacteria increases beyond a certain level, detects the increase and counts an alarm lamp,
The inspection apparatus for microorganisms according to any one of claims 2, 3, 4, 5, 6, 7, and 8 wherein a buzzer or the like is operated. . 10. A separate device for measuring the temperature, humidity, dust status, etc. of the space is separately disposed in a room or the like in which a housing is disposed, and information obtained therefrom is taken into the arithmetic processing unit to manage the environment. The inspection apparatus for microorganisms according to any one of claims 2, 3, 4, 5, 6, 7, 8, and 9. 11. A test object container formed by mixing a substance which emits light when irradiated with light such as near ultraviolet rays.