JPH0836639A - Image analyzer - Google Patents

Abstract

PURPOSE:To provide an image analyzer capable of quantitative analysis by forming an image onto a display means such as a CRT screen based on image data and designating a desired image area for the quantitative analysis. CONSTITUTION:The image analyzer is provided with an image density lower limit setting means 102 setting a lower limit of an image density, an image density upper limit setting. means 104 setting an upper limit of the image density, and an image area specifying section 80 specifying the image area with a density of the image displayed on a CRT 50 whose density is a lower limit or over of the image density set by an image density lower limit setting means and whose density is an upper limit or below the image density set by an image density upper limit setting means.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image analysis apparatus, and more particularly to an image analysis apparatus capable of quantitatively analyzing an image as desired.

[0002]

2. Description of the Related Art A substance labeled with a radiolabel is administered to an organism, and the organism or a part of the tissue of the organism is used as a sample, and the sample is used as a radiation film such as a high-sensitivity X-ray film. By overlapping for a certain time,
The radiographic film is exposed or exposed, and the position information of the radiolabeled substance in the sample is obtained based on the exposed part of the radiographic film. Numerator
A chemiluminescent substance is contacted with a chemiluminescent substance, and the chemiluminescent substance is selectively labeled with a labeling substance, and the macromolecule selectively labeled with the labeling substance is contacted with the chemiluminescent substance to label the chemiluminescent substance. By detecting chemiluminescence in the visible light wavelength range caused by contact with a substance, a chemiluminescence detection method for obtaining information on macromolecules such as genetic information, irradiating a metal or non-metal sample with an electron beam,
An electron that detects an image of a biological tissue by performing elemental analysis, composition analysis of the sample, structural analysis of the sample, etc. by detecting a diffraction image or transmission image of the sample, and irradiating the biological tissue with an electron beam. A detection method using a microscope, a radiation diffraction image detection method of irradiating a sample with radiation, detecting the obtained radiation diffraction image, and performing structural analysis of the sample are known.

These methods have hitherto been used as detection materials.
Using a photographic film, a radiographic image on the photographic film,
This was done by recording a chemiluminescence image, an electron microscope image, a radiation diffraction image, etc., and visually detecting the visible image. However, when a photographic film is used as the detection material, an autoradiography detection method is used. And the radiation diffraction image detection method have a problem that the sensitivity of the radiation film is low and it takes a long time to record an image.The chemiluminescence detection method reliably detects weak chemiluminescence. In order to do so, it is necessary to use a high-sensitivity film with a high γ value, but when using a high-sensitivity film with a high γ value, be sure to use the linear portion of the characteristic curve,
It is difficult to expose, there are many exposure mistakes, there is a problem that it is necessary to repeat exposure by changing the exposure conditions. Furthermore, in the detection method with an electron microscope, The film has a small number of linear parts of the characteristic curve, so it is difficult to select the exposure conditions, and there is the problem that repeated exposure is required due to an exposure error. However, there is a problem that the manual processing is indispensable and the operation is complicated.

Therefore, when radiation, visible light, or an electron beam is irradiated instead of the conventional photographic film, the energy is absorbed and accumulated, and then excited by using an electromagnetic wave in a specific wavelength range. Then, the emitted radiation, visible light,
The photostimulable phosphor having the characteristic of emitting photostimulable light in an amount corresponding to the amount of energy such as electron beam was used as a detection material for radiation, visible light, electron beam, etc., and was emitted from the photostimulable phosphor. The stimulated emission is photoelectrically detected, converted into a digital signal, and the obtained image data is subjected to predetermined image processing, and then the image is reproduced on a display means such as a CRT screen or a photographic film. The proposed autoradiography detection method, chemiluminescence detection method, electron microscope detection method, and radiation diffraction image detection method are proposed (for example, Japanese Patent Publication No. 1-60784 and Japanese Patent Publication No. 1-6078).
No. 2, Japanese Patent Publication No. 4952/1992, US Pat. No. 5,
No. 028,793, GB Patent Publication No. GB 2,24
6,197A, JP-A-61-51738, JP-A-61-93538, JP-A-59-15843). According to the detection method using this stimulable phosphor, not only the chemical treatment called development processing is unnecessary, but also in the autoradiography detection method and the radiation diffraction image detection method, the exposure time is significantly increased. The chemiluminescence detection method and the detection method using an electron microscope have the advantages that there are few exposure mistakes and that exposure can be performed easily. Since the image is reproduced later, it is preferable that the image data is subjected to signal processing so that the image can be reproduced as desired or quantitative analysis by a computer can be performed.

[0005]

In such an autoradiography detection method, a chemiluminescence detection method, an electron microscope detection method, and a radiation diffraction image detection method,
Specify a specific image area for quantitative analysis of the image,
Often it is necessary to integrate the densities of pixels within the image area. When such a quantitative analysis is performed using a display means such as a CRT, in the conventional image analysis device,
Since it is possible to specify only the density that is higher than the predetermined density, if there is an image area with a density higher than the density of the image area to be quantitatively analyzed, specify the desired image area,
There was a problem that quantitative analysis could not be performed. Autoradiography images, chemiluminescence images, electron microscope images, radiation diffraction images, etc. are once recorded on a photographic film, the recorded images are photoelectrically read, digitalized, and the desired image signals are obtained. The signal processing described above causes the same problem when a visible image is reproduced on a display means such as a CRT screen or on a photographic film.

[0006]

It is an object of the present invention to provide an image analysis apparatus for forming an image on a display means such as a CRT screen based on image data and quantitatively analyzing the image, by designating a desired image area and performing quantitative analysis. It is an object of the present invention to provide an image analysis device that can be used.

[0007]

The object of the present invention is displayed on an image density lower limit setting means for setting a lower limit of image density, an image density upper limit setting means for setting an upper limit of image density, and a display means. An image area for specifying an image area of a density of the image which is equal to or higher than the lower limit of image density set by the image density lower limit setting means and lower than or equal to the upper limit of image density set by the image density upper limit setting means This is achieved by an image analysis device equipped with specifying means. In a preferred embodiment of the present invention, further, there is provided image area extension designating means for designating an extension of an image area to be quantitatively analyzed among the images displayed on the display means, and the image area specifying means designates the image area extension. Of the images included in the image area in the extension specified by the means, the image density lower than or equal to the lower limit value of the image density set by the image density lower limit setting means and lower than the image density set by the image density upper limit setting means. It is configured to specify an image area having a density equal to or lower than the upper limit value. In a further preferred embodiment of the present invention, further, image data storage means for storing image data obtained by converting positional information of the radiolabeled substance in the sample into an electric signal, and an image stored in the image data storage means. The image data in the image data area stored in the memory means corresponding to the image area specified by the image area specifying means is provided with a memory means for expanding the data two-dimensionally and temporarily storing the data. On the other hand, the image area specifying means is configured to be capable of data processing so that the image area is displayed on the display means at a predetermined density.

[0008] In a further preferred aspect of the present invention, it further comprises graphic data storage means for storing graphic data corresponding to a graphic to be displayed on the display means, and the image area extension designating means is the graphic data storage means. The extension of the image area to be analyzed is designated based on the stored graphic data. In a further preferred aspect of the present invention, the memory means includes temporary memory means for two-dimensionally developing the image data stored in the image data storage means and temporarily storing the image data, and the temporary memory means. A part of the stored image data is selected and enlarged or reduced, or two-dimensionally expanded without being enlarged or reduced and temporarily stored, and a selected image data memory means, Image data stored in the selected image data memory means is synthesized with the graphic data stored in the graphic data storage means, is two-dimensionally developed, and is temporarily stored in the synthesized data memory means, and the synthesized data memory means. A part of the image data and the graphic data stored in the data memory means has a window memory and means for two-dimensionally expanding and temporarily storing, and further, the temporary memory. Image data selecting means for selecting a part of the image data temporarily stored in the memory means, and enlarging or reducing the image data selected by the image data selecting means, in the selected image data memory means, It develops two-dimensionally,
Image data enlarging / reducing means to be temporarily stored, and image data stored in the selected image data memory means are combined with the graphic data stored in the graphic data storage means, and the combined data memory means is combined. A data synthesizing unit that is two-dimensionally developed and temporarily stored, and a partial area of the image data and graphic data stored in the synthesized data memory unit is two-dimensionally developed in the window memory unit. And a data area selecting means for temporarily storing, wherein the image area specifying means sets the lower limit value of the image density set by the image density lower limit value setting means among the images displayed on the display means. An image area having a density equal to or lower than the image density upper limit set by the image density upper limit setting means is stored in the window memory means so as to be specified. Are data processing configured to be able to image data.

[0009] In a further preferred aspect of the present invention, the image data is generated by using a stimulable phosphor sheet. In a further preferred aspect of the present invention, the image data is constituted by image data selected from the group consisting of autoradiography image data, radiation diffraction image data, electron microscope image data, and chemiluminescence image data. In a further preferred embodiment of the present invention, autoradiographic image data,
Radiation diffraction image data or electron microscope image data
Radiation or electron beam emitted from the sample is accumulated in and absorbed by the stimulable phosphor, and then the stimulable phosphor is irradiated with an electromagnetic wave to emit light emitted from the stimulable phosphor. It is obtained by photoelectric conversion. In a further preferred embodiment of the present invention, the chemiluminescence image data is that visible light emitted from a sample is accumulated in and absorbed by a stimulable phosphor, and then the stimulable phosphor is irradiated with an electromagnetic wave. It is obtained by photoelectrically converting the light emitted from the stimulable phosphor.

In the present invention, a stimulable phosphor that can be used for producing an autoradiographic image, a radiation diffraction image or an electron microscope image is capable of storing radiation or electron beam energy, It is not particularly limited as long as it is excited and can release the energy of the accumulated radiation or electron beam in the form of light, but it is preferably one that can be excited by light in the visible light wavelength range. . Specifically, for example, the alkaline earth metal fluorohalide-based phosphors (Ba) disclosed in JP-A-55-12145 are disclosed.
_1-x, M ²⁺ _x ) FX: yA (where M ²⁺ is Mg, Ca,
At least one alkaline earth metal element selected from the group consisting of Sr, Zn and Cd, X is at least one halogen selected from the group consisting of Cl, Br and I,
A is Eu, Tb, Ce, Tm, Dy, Pr, He, N
At least one trivalent metal element selected from the group consisting of d, Yb, and Er, x is 0 ≦ x ≦ 0.6, and y is 0 ≦ y.
≦ 0.2. ), The alkaline earth metal fluorohalide-based phosphor SrFX: Z disclosed in JP-A-2-276997 (where X is at least one halogen selected from the group consisting of Cl, Br and I, Z Is Eu
Or Ce. ), A europium-activated composite halogen-based phosphor BaFX · xNaX ′: aEu ²⁺ disclosed in JP-A-59-56479 (wherein X and X ′ are both composed of Cl, Br and I). Is at least one halogen selected from the group, and x is 0 <x ≦
2, a is 0 <a ≦ 0.2. ), JP-A-58-69
MOX: xCe, which is a cerium-activated trivalent metal oxyhalogen-based phosphor disclosed in Japanese Patent No. 281
Is Pr, Nd, Pm, Sm, Eu, Tb, Dy, Ho,
At least one trivalent metal element selected from the group consisting of Er, Tm, Yb, and Bi, X is one or both of Br and I, and x is 0 <x <0.1. ), JP-A-60-101179 and 60.
LnOX: xCe, which is a cerium-activated rare earth oxyhalogen-based phosphor disclosed in Japanese Patent Publication No. 90288, wherein Ln is at least one rare earth element selected from the group consisting of Y, La, Gd, and Lu, and X is At least one halogen selected from the group consisting of Cl, Br and I, x is 0 <x ≦ 0.1) and JP-A-59-59.
Europium activated complex halide-based items has been disclosed in Japanese -75200 phosphor ^{M II FX · aM I X '} · bM' II X
^'' ₂ · cM ^III X ^'” ₃ · xA: yEu ²⁺ (where M
^II is at least one alkaline earth metal element selected from the group consisting of Ba, Sr and Ca, M ^I is Li, N
at least one alkali metal element selected from the group consisting of a, K, Rb and Cs, M ′ ^II is Be and Mg
At least one divalent metal element selected from the group consisting of, M ^III is at least one trivalent metal element selected from the group consisting of Al, Ga, In and Tl, A is at least one metal oxide, and X is Cl. , Br and I, at least one halogen selected from the group consisting of, X ', X
^{″ And} X ^{′ ″} are at least one halogen selected from the group consisting of F, Cl, Br and I, and a is 0
≦ a ≦ 2, b is 0 ≦ b ≦ 10 ⁻² , c is 0 ≦ c ≦ 10
⁻² and a + b + c ≧ 10 ⁻² , and x is 0 <x
When ≦ 0.5, y is 0 <y ≦ 0.2. ) Can be preferably used.

In the present invention, stimulable phosphors that can be used to generate a chemiluminescent image include:
Any energy capable of accumulating light energy in the visible light wavelength range, being excited by electromagnetic waves, and capable of releasing accumulated energy of light in the visible light wavelength area in the form of light, is not particularly limited. However, those that can be excited by light in the visible light wavelength range are preferable. Specifically, for example, the metal halophosphate-based phosphor, the rare earth element-activated phosphor, the aluminate-based phosphor, the silicate-based phosphor, and the fluoride-based phosphor disclosed in JP-A-4-232864 are disclosed. Body is,
It can be preferably used.

[0012]

According to the present invention, the image analysis apparatus comprises the image density upper limit value setting means and the image density lower limit value setting means, and the image area lower limit value among the images displayed on the display means by the image area specifying means. Since it is possible to specify an image area having a density equal to or higher than the lower limit value of the image density set by the setting means and lower than or equal to the upper limit value of the image density set by the image density upper limit value setting means, it is displayed on the display means. Even if there is an image area having a higher density than the density of the image area to be quantitatively analyzed, the image density upper limit value setting means and the image density lower limit value setting means can set the density range as desired. By setting, it becomes possible to specify the image area to be quantitatively analyzed and execute the quantitative analysis. According to a preferred embodiment of the present invention, further, an image region extension designating unit for designating an extension of an image region to be quantitatively analyzed among the images displayed on the display unit is provided, and the image region specifying unit is provided with the image region extension. Of the images included in the image area within the extension designated by the designating means, the image density which is equal to or higher than the lower limit of the image density set by the image density lower limit setting means and which is set by the image density upper limit setting means. Since it is configured to specify an image area having a density equal to or lower than the upper limit value of, the image displayed on the display means, in addition to the image area to be quantitatively analyzed, the image set by the image density lower limit value setting means. Even if there is an image area whose density is equal to or higher than the lower limit value of the density and equal to or lower than the upper limit value of the image density set by the image density upper limit setting means, the outside area specified by the image area extension specifying means is used. Image only included in the image area of the inner, it is possible to perform a quantitative analysis, efficient, it is possible to perform quantitative analysis.

According to a further preferred embodiment of the present invention, the image data storage means for storing the image data obtained by converting the positional information of the radiolabeled substance in the sample into an electric signal, and the image data storage means. A memory means for two-dimensionally expanding the stored image data and temporarily storing the image data, and corresponding to the image area specified by the image area specifying means, within the image data area stored in the memory means. The image area specifying unit displays the image area to be quantitatively analyzed, because the image area specifying unit is configured to be capable of data processing so that the image area is displayed at a predetermined density on the display unit. By the means, it becomes possible to perform quantitative analysis while recognizing. According to a further preferred embodiment of the present invention, it further comprises graphic data storage means for storing graphic data corresponding to the graphic to be displayed on the display means, and the image area extension designating means is stored in the graphic data storage means. Since the outline of the image area to be analyzed is specified based on the graphic data, the outline of the image area including the image area to be analyzed can be visually specified on the display means. become.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of the present invention will be described in detail below with reference to the accompanying drawings. Figure 1
FIG. 1 is a schematic perspective view showing an image reading device that generates image data to be analyzed by an autoradiography image analysis device according to an embodiment of the present invention. In FIG. 1, positional information of a radioactive labeling substance contained in a sample (not shown) is accumulated in a stimulable phosphor sheet 1 in the form of radiation energy. Here, in the present specification, the positional information is various information centered on the position of the radiolabeled substance or its aggregate in the sample, for example, the position where the aggregate of the radiolabeled substance present in the sample is present. It means various information obtained as one or any combination of information consisting of shape, concentration of radiolabeled substance at that position, distribution and the like. In this embodiment,
Positional information of the radiolabeled substance for studying the metabolism, absorption, and excretion routes and states of the administered substance in the experimental mouse is stored and recorded in the stimulable phosphor sheet 1.

The stimulable phosphor sheet 1 on which the position information of the radiolabeled substance in the sample is accumulated and recorded is scanned with the laser beam 2 to be excited to generate stimulated emission. The laser light 2 is generated by the laser light source 3, and the filter 4
By passing through, the portion of the wavelength region corresponding to the wavelength region of the photostimulable light generated from the stimulable phosphor sheet 1 due to the excitation by the laser light 2 is cut. Then, the beam diameter of the laser beam 2 is accurately adjusted by the beam expander 5, and the laser beam 2 enters the optical deflector 6 such as a galvanometer mirror. Laser light 2 deflected by the optical deflector 6
Is reflected by the plane reflecting mirror 8 via the fθ lens 7 and is one-dimensionally incident on the stimulable phosphor sheet 1.
The fθ lens 7 ensures that when the stimulable phosphor sheet 1 is scanned by the laser light 2, the scanning is always performed at a uniform beam speed. In synchronization with the scanning with the laser light 2, the stimulable phosphor sheet 1 is moved in the direction of the arrow in FIG. 1, and the entire surface thereof is scanned with the laser light 2. When the stimulable phosphor sheet 1 is irradiated with the laser beam 2, the stimulable phosphor sheet 1 emits photostimulable light in an amount proportional to the radiation energy stored and recorded.
Incident on.

The light-guiding sheet 9 has a light-receiving end portion formed in a straight line, and is arranged in proximity to the scanning line on the stimulable phosphor sheet 1, and the light-emitting end portion thereof has a circular shape. It forms an annular shape and is connected to the light receiving surface of a photoelectric conversion type photodetector 10 such as a photomultiplier. This light guide sheet 9 is made by processing a transparent thermoplastic resin sheet such as an acrylic synthetic resin, and the light incident from the light receiving end repeats total reflection on the inner surface of the light emitting sheet while the light exiting end is emitted. The shape is determined so as to be transmitted to the light receiving surface of the photodetector 10 through the portion. Therefore, the photostimulable light emitted from the stimulable phosphor sheet 1 in response to the irradiation of the laser beam 2 is incident on the light guide sheet 9, and inside the light guide sheet 9, while repeating total reflection, through the emission end portion, The light is received by the photodetector 10. A filter is attached to the light-receiving surface of the photodetector 10, which transmits only the light in the wavelength region of the photostimulable light emitted from the stimulable phosphor sheet 1 and cuts the light in the wavelength region of the laser light 2. Therefore, the photodetector 10 is configured to photoelectrically detect only stimulated light emitted from the stimulable phosphor sheet 1. The photostimulable light photoelectrically detected by the photodetector 10 is converted into an electric signal, amplified by an amplifier 11 having a predetermined amplification factor into an electric signal of a predetermined level, and then the A / D converter 12 Entered in. The electric signal is converted into a digital signal by the A / D converter 12 with a scale factor suitable for the signal fluctuation width, and input to the line buffer 13. The line buffer 13 is
The image data for one scanning line is temporarily stored, and when the image data for one scanning line is stored as described above, the data is stored more than the capacity of the line buffer 13. The image data is output to the transmission buffer 14 having a large capacity, and the transmission buffer 14 is configured to output the image data to the autoradiography image analysis device when the image data having a predetermined capacity is stored.

FIG. 2 is a block diagram of an autoradiographic image analysis device and an image reading device according to an embodiment of the present invention. In FIG. 2, the autoradiographic image analysis device 30 includes a stimulable phosphor sheet 1
The image data containing the position information of the radiolabeled substance contained in the sample, which has been stored and recorded in the image reading device 20 and converted into a digital signal, is received,
In order to reproduce a visible image having an appropriate color tone, contrast, etc. and excellent observation and analysis characteristics, the data processing means 60 for performing data processing and the data processing device 60 input from the image reading device 20 to perform data processing. The image data storage means 40 for storing the image data thus obtained and the CRT 50 for reproducing the image data including the positional information of the radiolabeled substance contained in the sample as an image are provided. The image data temporarily stored in the transmission buffer 14 of the image reading device 20 is input to the reception buffer 62 of the data processing means 60 of the autoradiography image analysis device 30 and temporarily stored, and the reception buffer 62. When a predetermined amount of image data is stored therein, the stored image data is output to and stored in the image data temporary storage unit 41 of the image data storage means 40. In this way, the image data sent from the transmission buffer 14 of the image reading device 20 to the reception buffer 62 of the data processing unit 60 and temporarily stored is further stored in the image data storage unit 40 from the reception buffer 62. It is stored in the image data temporary storage unit 41. Thus, when the image data obtained by scanning the entire surface of the stimulable phosphor sheet 1 with the laser light 2 is stored in the image data temporary storage unit 41 of the image data storage unit 40,
The data processing unit 64 of the data processing unit 60 reads out the image data from the image data temporary storage unit 41, stores the image data in the temporary memory 66 of the data processing unit 60, performs the necessary data processing, and then executes such image data. Only the image data is stored in the image data storage unit 42 of the image data storage unit 40.
After that, the data processing unit 64 erases the image data stored in the image data temporary storage unit 41.

The image data stored in the image data storage section 42 of the image data storage means 40 is read by the data processing section 64 and displayed on the screen of the CRT 50 for the operator to observe and analyze the image. It is supposed to be displayed. FIG. 3 is a block diagram of the data processing means 60. In FIG. 3, the data processing unit 60 two-dimensionally develops a reception buffer 62 that receives image data from the transmission buffer 14 of the image reading device 20, a data processing unit 64 that executes data processing, and image data. And a temporary memory 66 for temporarily storing.
The data processing means 60 further includes an image data selection unit 68 for selecting a part of the image data from the image data temporarily stored in the temporary memory 66, and the image data selected by the image data selection unit 68. And an image data enlargement / reduction unit 70 capable of enlarging or reducing
An enlarged / reduced image data storage unit 72 that two-dimensionally expands image data enlarged or reduced by the reduction unit 70 and temporarily stores it, and various graphic data to be displayed on the screen of the CRT 50. Graphic data storage unit 74
And image data temporarily stored in the enlarged / reduced image data storage unit 72 and the graphic data storage unit 74,
A data synthesizing unit 76 for synthesizing the graphic data to be displayed on the screen of the CRT 50, and synthetic data for two-dimensionally developing the image data and the graphic data synthesized by the data synthesizing unit 76 and temporarily storing them. The storage unit 77, the data region selection unit 78 that selects a predetermined data region from the image data and the graphic data temporarily stored in the composite data storage unit 77, and the image selected by the data region selection unit 78. The data area of the data and the graphic data is two-dimensionally developed to temporarily store the window memory 79, and a specific image area of the image displayed on the screen of the CRT 50 is displayed with a predetermined density. As described above, the image area specifying unit 80 that processes the image data stored in the window memory 79, and the window memory 79.
Image data and graphic data stored in the
An image display unit 82 for displaying on the screen of 0 is provided.

As shown in FIG. 3, the image data selecting section 68 receives the image data selection signal from the selected image data determining section 88, and the image data enlarging / reducing section 70 receives the image data magnification determining section. The enlargement / reduction signal from 90 is input. Further, in the graphic data storage unit 74,
A graphic data selection signal from the graphic data selection means 94 and an enlargement / reduction signal from the image data magnification determination means 90 are input, and which graphic data is selected in the data synthesizing section 76 and how the image data and the graphic data are selected. And synthesize
A data combination signal from the data combination instruction means 96 for determining whether to display on the screen of the CRT 50 is input.
Further, the data area selection unit 78 receives the data area designation signal from the data area designation unit 98, and the enlarged / reduced image data storage unit 72 and the window memory 79 receive the color tone setting signal from the color tone setting unit 92. It has been entered. In addition, the image display unit 82 includes an image display instruction unit 1.
The image display instruction signal from 00 is input. Further, the image area specifying unit 82 has a data combining instruction unit 96.
From the above, a data synthesis instruction signal is input, and the image area specifying unit 82 performs data processing on the image data stored in the window memory 79. In order to specify an image area having a predetermined density on the screen of the CRT 50, the image density is specified. The image density lower limit value setting signal from the image density lower limit value setting means 102 for setting the lower limit value and the image density upper limit value setting signal from the image density upper limit value setting means 104 for setting the upper limit value of the image density are
Each is input, and further, graphic data selection means 94
Therefore, when the graphic data selection signal is input, the image density set by the image density lower limit value setting means 102 in the image area surrounded by the graphic corresponding to the graphic data selected by the graphic data selecting means 94. A density conversion signal is output from the density conversion unit 106 that converts an image area having a density equal to or higher than the lower limit value and equal to or lower than the image density upper limit value set by the image density upper limit value setting unit 104 to a desired density. It has been entered.

Here, in the present embodiment, the selected image data determining means 88, the image data magnification determining means 90, the color tone setting means 92, the graphic data selecting means 94, the data synthesizing instructing means 96, the data area designating means 98, the image. The display instruction unit 100, the image density lower limit value setting unit 102, the image density upper limit value setting unit 104, the density conversion unit 106, and the mouse (not shown) are operable. FIG.
Is a CRT50 in the autoradiography image analysis apparatus according to the embodiment of the present invention configured as described above.
3 is a flow chart showing an embodiment in the case of quantitatively analyzing a specific image area having a predetermined density in the image displayed on the screen of FIG.

First, the image data to be displayed on the screen of the CRT 50 is read from the image data storage section 42 of the image data storage means 40 into the temporary memory 66, expanded two-dimensionally and temporarily stored. To be done. Then, using the mouse, the selected image data determining means 88 is operated to input an image data selection signal to the image data selection section 68, which is two-dimensionally expanded in the temporary memory 66 and temporarily stored. The image data enlarging / reducing unit 7 is selected from the image data by selecting the image data including the image area to be observed and analyzed, and operating the image data magnification determining means 90 as necessary.
An enlargement / reduction signal is input to 0 to enlarge or reduce the selected image data, and the enlargement / reduction image data storage unit 7
2 、 Two-dimensionally expanded and temporarily stored,
The color tone setting means 92 is operated to set the color tone of the image displayed on the screen of the CRT 50. Thereafter, the operator operates the data combination instruction means 96 to two-dimensionally store the image data stored in the enlarged / reduced image data storage unit 72 in the combined data storage unit 77 without combining the graphic data. Expand to and store temporarily. Next, the operator operates the data area designating means 98, and the data area selecting section 78.
Then, a data area designation signal is input to select an area of the image data to be displayed on the screen of the CRT 50, and the data is two-dimensionally expanded and temporarily stored in the window memory 79.
In this way, when the image display instruction signal is input from the image display instruction means 100, the image display unit 82 causes the image data that is two-dimensionally expanded and temporarily stored in the window memory 79 to be stored in the CRT 50. An image displayed on the screen and having the color tone set by the color tone setting means 92 is obtained on the screen of the CRT 50.

In this way, when an image having a predetermined color tone is displayed on the screen of the CRT 50, the operator can
The image displayed on the screen of 0 is observed, the image area to be quantitatively analyzed and the upper limit value and the lower limit value of the density thereof are determined, the image density lower limit value setting means 102 is operated, and the image area specifying unit 80 is displayed. , The image density lower limit value setting signal is input, and the image density upper limit value setting means 104 is operated to input the image density upper limit value setting signal to the image area specifying unit 80, and the density of the image area to be quantitatively analyzed. Is greater than or equal to the image density lower limit value set by the image density lower limit value setting means 102 and less than or equal to the image density upper limit value set by the image density upper limit value setting means 104, and then the density conversion means 106 is set. In operation, the density conversion signal is input to the image area specifying unit 80 and is equal to or higher than the image density lower limit value set by the image density lower limit value setting unit 102 and is higher than the image density upper limit value setting unit 10. The density of the image area having an image density upper limit value or less of the concentration set by, converted to the desired concentration. As shown in FIG. 5, on the screen of the CRT 50,
The state where the image region to be quantitatively analyzed is selected is shown. As shown in FIG. 5, in the present embodiment, the image density lower limit value set by the image density lower limit value setting means 102 is greater than or equal to the image density upper limit value set by the image density upper limit value setting means 104. There are two or more image areas with densities in the range on the screen of the CRT 50. Therefore, when quantitatively analyzing the image area, the operator can determine the radiation dose contained in a specific organ of the experimental mouse by selecting the quantitative data corresponding to the image area to be quantitatively analyzed.

According to this embodiment, even if there is an image area having a density higher than that of the image area to be quantitatively analyzed on the screen of the CRT 50, the image area to be quantitatively analyzed is specified and desired. Thus, it becomes possible to perform a quantitative analysis. In the autoradiography analysis apparatus according to the embodiment of the present invention, the operator operates the graphic data selection means 94 to select an area including an image area to be quantitatively analyzed on the screen of the CRT 50. It is a flow chart which shows an example in the case of specifying and performing quantitative analysis by the figure corresponding to the figure data. First, the image data to be displayed on the screen of the CRT 50 is the image data storage means 40.
From the image data storage section 42, the image data is stored in the temporary memory 66, expanded two-dimensionally, and temporarily stored. Next, the mouse is used to operate the selected image data determination means 88 to input an image data selection signal to the image selection unit 68, and the image is two-dimensionally expanded in the temporary memory 66 and temporarily stored. Image data including an image region to be observed and analyzed is selected from the data, and the image data magnification determining unit 90 is operated as necessary to input an enlargement / reduction signal to the image data enlargement / reduction unit 70. , The selected image data is enlarged or reduced, and the enlarged / reduced image data storage unit 72 is two-dimensionally developed and temporarily stored, and further, the color tone setting means 92 is operated to operate the CRT 50.
Set the color tone of the image displayed on the screen. afterwards,
The operator operates the graphic data selection means 94 to select predetermined graphic data, operates the data combination instruction means 96, and causes the data combination section 76 to select the predetermined graphic data and the enlarged / reduced image. The image data stored in the data storage unit 72 is combined and stored in the combined data storage unit 77. Further, the operator operates the data area designating means 98, inputs the data area designating signal to the data area selecting section 78, selects the area of the image data to be displayed on the screen of the CRT 50, and the window memory 79. Then, it is expanded two-dimensionally and temporarily stored. In this way, when the image display instruction signal is input from the image display instruction means 100, the image display unit 82 outputs the image data and the graphic data which are two-dimensionally expanded and temporarily stored in the window memory 79. , An image displayed on the screen of the CRT 50 and having a color tone set by the color tone setting means 92 is a CRT.
Obtained on 50 screens.

In this way, the operator observes the obtained image and graphic on the screen of the CRT 50, and the image area to be quantitatively analyzed is specified by being surrounded by the graphic corresponding to the selected graphic data. It is determined whether or not there is. As a result, when it is determined that the image is surrounded by the graphic corresponding to the selected graphic data and is not specified, the operator again operates the data synthesis instructing means 96 to determine the image area to be quantitatively analyzed. The position of the selected predetermined graphic data is adjusted by the data synthesizing unit 76 until it is specified by being surrounded by the graphic corresponding to the selected graphic data. In this way, as shown in FIG. 7, an image having a predetermined color tone is displayed on the screen of the CRT 50, and the image area to be quantitatively analyzed is surrounded by the graphic 120 corresponding to the selected graphic data and specified. Then, the operator operates the image data magnification determination means 90 to enlarge / contract the image data.
An expansion signal is output to the reduction unit 70 and the graphic data storage unit 74 to expand the image data corresponding to the image area to be quantitatively analyzed and the graphic data corresponding to the graphic 120 by the same magnification, and the combined data storage unit 77. Then, the enlarged image data and graphic data are two-dimensionally developed and stored, and the data area designating unit 98 is operated to be stored in the combined data storage unit 77 by the data area selecting unit 78. A predetermined area of the image data and the graphic data is selected, and it is two-dimensionally developed in the window memory 79,
Two-dimensionally developed and stored so as to be superposed on the stored image data and graphic data. FIG. 8 shows the image data and the graphic data temporarily stored in the window memory 79 on the screen of the CRT 50.
It is the drawing displayed as an image and a figure. As shown in FIG. 8, on the screen of the CRT 50, an image area to be quantitatively analyzed surrounded by a figure 120 is enlarged,
It is displayed.

In this way, the operator observes the image displayed on the screen of the CRT 50, operates the image density lower limit value setting means 102 according to the density of the specified image area,
The image density lower limit value setting signal is input to the image area specifying unit 82, the image density upper limit value setting means 104 is operated, and the image density upper limit value setting signal is input to the image area specifying unit 82, and the graphic 120 is displayed. The density of the image area specified by being surrounded by is equal to or higher than the image density lower limit value set by the image density lower limit value setting means 102 and equal to or lower than the image density upper limit value set by the image density upper limit value setting means 104. The concentration is set within the range, and then the concentration converting means 1
06 by operating the density conversion signal to the image area specifying unit 82.
, And the density of the specified image area surrounded by the graphic 120 is converted into a desired density. FIG. 9 shows a state in which an image region to be quantitatively analyzed is selected on the screen of the CRT 50 in this way. As shown in FIG.
In this embodiment, the image area to be quantitatively analyzed is selected by selecting the graphic data and synthesizing it with the image data.
On the screen of the CRT 50, it is specified by being surrounded by the graphic 120 corresponding to the selected graphic data, and only the image area in the graphic 120 is converted to the desired density.

Therefore, according to this embodiment, the graphic 12
By using 0, only the image area to be quantitatively analyzed can be specified and the quantitative analysis can be easily performed. Similar to the embodiment of FIGS. 6 to 9, an image region to be quantitatively analyzed is specified by using a figure, and the lower limit value of the image density and the upper limit value of the image density are adjusted to make the image region to be quantitatively analyzed. It is also possible to display only the contour portion of the image on the screen of the CRT 50 at a desired density. FIG. 10 is thus obtained, C
It shows an image displayed on the screen of the RT50.
According to the present embodiment, it is possible to perform quantitative analysis of a desired image area while observing the image inside the image area to be quantitatively analyzed. The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the invention described in the claims, and these are also included in the scope of the present invention. Needless to say.

For example, in the above-mentioned embodiment, the positional information of the radiolabeled substance for studying the metabolism, absorption, excretion route, state, etc. of the administered substance in the experimental mouse was obtained.
The stimulable phosphor sheet 1 is stored and recorded, photoelectrically read out, subjected to predetermined data processing, displayed on the screen of the CRT 50, and the displayed image is quantitatively analyzed. Without being limited to radiography, for example, autoradiography images of genes using the hybridization method by Southern blotting method, separation and identification of proteins by polyacrylamide gel electrophoresis, or analysis of molecular weight and characteristics Not only when analyzing autoradiography images such as autoradiography images for evaluation and those generated by thin-layer chromatography (TLC) of proteins, but also for analyzing genes using Southern blot hybridization method. Chemiluminescence image,
Chemiluminescence images such as chemiluminescence images generated by thin-layer chromatography of proteins, chemiluminescence images for separation and identification of proteins, and evaluation of molecular weight and characteristics by polyacrylamide gel electrophoresis were used. Also in the case of analyzing chemiluminescence images, electron beam transmission images and electron diffraction images of metal or non-metal samples generated by using an electron microscope, electron microscope images of biological tissues, and even metal or non-metal It can also be widely applied when analyzing a radiation diffraction image of a sample or the like.

Further, in the above embodiment, the CRT 5
Although the color image is displayed on the screen of 0, a monochrome image may be displayed. Also,
In the above-mentioned embodiment, the image data obtained by converting the positional information of the radioactive labeling substance in the sample into an electric signal using the stimulable phosphor sheet 1 is displayed as an image on the screen of the CRT 60. However, instead of the stimulable phosphor sheet 1, a radiation film is used to once form a visible image, the visible image is photoelectrically read, and the same processing is performed on the image data converted into an electric signal. It is also possible to do so. Further, in the above embodiment, the image is
Although it is formed on the screen of the CRT 50, an image may be formed on a display unit other than the CRT 50. Further, in the present specification, the term “means” does not necessarily mean physical means, but also includes cases where the functions of the respective means are realized by software. Further, the function of one means may be realized by two or more physical means, or the functions of two or more means may be realized by one physical means.

[0029]

According to the present invention, an image analyzing apparatus for forming an image on a display means such as a CRT screen based on image data and quantitatively analyzing the image data, by designating a desired image area and quantitatively analyzing the image area. It is possible to provide an image analysis device capable of doing so.

[Brief description of drawings]

FIG. 1 is a schematic perspective view showing an example of an image reading apparatus that generates image data to be analyzed by an autoradiographic image analysis apparatus according to an embodiment of the present invention.

FIG. 2 is a block diagram of an autoradiographic image analysis device and an image reading device according to an embodiment of the present invention.

FIG. 3 is a block diagram of a data processing means.

FIG. 4 is a flowchart showing an operation in an example of quantitative analysis executed in the autoradiography analysis apparatus according to the example of the present invention.

FIG. 5 is a diagram showing an example of an image region to be quantitatively analyzed generated on a CRT screen by the autoradiography analyzing apparatus according to the embodiment of the present invention.

FIG. 6 is a flowchart showing an operation in another embodiment of the quantitative analysis executed in the autoradiography analysis apparatus according to the embodiment of the present invention.

FIG. 7 is a diagram showing an example of a figure and an image area generated on a CRT screen by the autoradiography analyzer according to the embodiment of the present invention.

FIG. 8 is a drawing showing an example of a figure and an image area enlarged and generated on a CRT screen by the autoradiography analyzing apparatus according to the embodiment of the present invention.

FIG. 9 is a diagram showing another example of an image region to be quantitatively analyzed generated on a CRT screen by the autoradiography analyzing apparatus according to the embodiment of the present invention.

FIG. 10 is a diagram showing another example of an image region to be quantitatively analyzed generated on a CRT screen by the autoradiography analyzing apparatus according to the embodiment of the present invention.

[Explanation of symbols]

 1 Storage Phosphor Sheet 2 Laser Light 3 Laser Light Source 4 Filter 5 Beam Expander 6 Optical Deflector 7 fθ Lens 8 Planar Reflector 9 Light Guide Sheet 10 Photodetector 11 Amplifier 12 A / D Converter 13 Line Buffer 14 transmission buffer 20 image reading device 30 autoradiographic image analysis device 40 image data storage unit 41 image data temporary storage unit 42 image data storage unit 50 CRT 60 data processing unit 62 reception buffer 64 data processing unit 66 temporary memory 68 image data selection Part 70 Image data enlarging / reducing part 72 Enlarging / reducing image data storage part 74 Graphic data storage part 76 Data composition part 77 Composite data storage part 78 Data area selection part 79 Wind memory 80 Image area identification part 82 Image display part 88 Selected image Data determination means 9 Image data magnification determining means 92 tone setting means 94 the graphic data selecting means 96 the data synthesis instructing means 98 the data area specifying means 100 image display instruction unit 102 image density lower limit setting means 104 image density upper limit setting unit 106 density conversion unit 120 figures

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Office reference number FI technical display area // G01N 23/04

Claims (9)

[Claims] 1. An image analysis apparatus for forming an image on a display means based on image data and quantitatively analyzing the image, and setting an image density lower limit value setting means for setting a lower limit value of the image density and an upper limit value of the image density. An image density upper limit setting means and an image displayed on the display means, which is equal to or higher than the lower limit of the image density set by the image density lower limit setting means and set by the image density upper limit setting means. An image analysis apparatus comprising image area specifying means for specifying an image area having a density equal to or lower than the upper limit of the obtained image density. 2. The image display device further comprises image area extension designating means for designating an extension of an image area to be quantitatively analyzed among the images displayed on the display means, and the image area identifying means is the image area extension designating means. Among the images included in the image area in the outer area specified by, the image which is equal to or more than the lower limit value of the image density set by the image density lower limit setting means and which is set by the image density upper limit setting means The image analysis apparatus according to claim 1, wherein the image analysis apparatus is configured to identify an image area having a density equal to or lower than the upper limit value of density. 3. An image data storage unit for storing image data, and a memory unit for two-dimensionally expanding the image data stored in the image data storage unit and temporarily storing the image data. For the image data in the image data area stored in the memory means, which corresponds to the image area specified by the image area specifying means, the image area specifying means causes the image area to be displayed in a predetermined manner on the display means. The image analysis apparatus according to claim 1 or 2, wherein the image analysis apparatus is configured to be capable of data processing so as to be displayed in density. 4. The graphic data storage means for storing graphic data corresponding to the graphic to be displayed on the display means, wherein the image area extension designating means is the graphic data stored in the graphic data storage means. The image analysis apparatus according to claim 2 or 3, wherein the image analysis apparatus is configured to specify an extension of an image region to be analyzed based on the data. 5. The temporary memory means for two-dimensionally expanding the image data stored in the image data storage means to temporarily store the image data, and the image data stored in the temporary memory means. A selected image data memory means for selecting and enlarging or reducing a part of it, or two-dimensionally expanding it without enlarging or reducing it and temporarily storing it, and the selected image data memory means. Image data stored in the graphic data storage means is combined with the graphic data stored in the graphic data storage means, expanded two-dimensionally and temporarily stored in the composite data memory means, and stored in the composite data memory means. The image data and a part of the graphic data are two-dimensionally developed and have a window memory and means for temporarily storing, and further, an image temporarily stored in the temporary memory means. Image data selection means for selecting a part of the image data, and image data selected by the image data selection means are enlarged or reduced, two-dimensionally expanded in the selected image data memory means, and temporarily Image data enlarging / reducing means to be memorized, and the image data stored in the selected image data memory means are combined with the graphic data stored in the graphic data storage means, and the composite data memory means A data synthesizing unit that develops dimensionally and stores temporarily, and a partial area of the image data and the graphic data stored in the synthetic data memory unit,
The window memory means includes a data area selecting means for two-dimensionally developing and temporarily storing, and the image area specifying means, among the images displayed on the display means,
An image area having a density equal to or higher than the lower limit value of the image density set by the image density lower limit value setting means and lower than or equal to the upper limit value of the image density set by the image density upper limit value setting means is specified. The image analysis apparatus according to claim 4, wherein the image data stored in the window memory means can be processed. 6. The autoradiographic image analysis apparatus according to claim 1, wherein the image data is generated by using a stimulable phosphor sheet. 7. The image data is constituted by image data selected from the group consisting of autoradiography image data, radiation diffraction image data, electron microscope image data and chemiluminescence image data. 7. The image analysis device according to any one of items 1 to 6. 8. The autoradiographic image data,
The radiation diffraction image data or the electron microscope image data, the radiation or electron beam emitted from the sample, accumulated in the stimulable phosphor, to absorb, after which, the stimulable phosphor, by irradiating an electromagnetic wave. The image analysis device according to claim 7, wherein the image analysis device is generated by photoelectrically converting light emitted from the stimulable phosphor. 9. The chemiluminescence image data allows visible light emitted from a sample to be accumulated and absorbed in a stimulable phosphor, and then the stimulable phosphor is irradiated with an electromagnetic wave to produce the stimulable phosphor. The image analysis device according to claim 7, wherein the image analysis device is generated by photoelectrically converting light emitted from the luminescent phosphor.