JPH11283019A - Image analyzer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image analyzer capable of forming a corresponding band image area or spot image area inside plural lane image areas as an interested area and performing quantitative analysis by a simple operation in the case that images reproduced based on image data are provided with the plural lane image areas respectively having the plural band image areas or spot image areas. SOLUTION: In this image analyzer provided with an image data storage means 42 for storing the image data for forming and analyzing the plural interested areas in the images displayed on a CRT 50 based on the image data stored in the image data storage means 42 and provided with the plural lane image areas respectively including the plural band image areas or spot image areas, an interested area data copying means 304 for copying interested area data generated in the image data corresponding to one reference lane image area of the plural lane image areas to the image data corresponding to the other lane image area is provided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image analyzing apparatus, and more particularly, to an image reproduced based on image data including a plurality of lanes each having a plurality of bands or spots. The present invention relates to an image analysis apparatus capable of defining a corresponding band or spot in a plurality of lanes as a region of interest and performing quantitative analysis with a simple operation.

[0002]

2. Description of the Related Art When irradiated with radiation, the energy of the radiation is absorbed, stored, recorded, and then excited using electromagnetic waves in a specific wavelength range. After using a stimulable phosphor having a characteristic of emitting a large amount of stimulable light as a radiation detection material and administering a radiolabeled substance to the organism, the organism or a tissue of the organism is administered. A part of the sample is overlapped with the stimulable phosphor sheet on which the stimulable phosphor layer is formed for a certain period of time, so that the radiation energy is reduced to the stimulable phosphor contained in the stimulable phosphor layer. The body is accumulated and recorded, and thereafter, the stimulable phosphor layer is scanned by electromagnetic waves to excite the stimulable phosphor, and the photostimulable light emitted from the stimulable phosphor is photoelectrically emitted. Detecting and generating a digital image signal, Is subjected to image processing, on a recording material such as a display unit or on a photographic film such as a CRT, constructed autoradiographic system to generate an image is known (e.g., KOKOKU 1-6078
No. 4, Japanese Patent Publication No. 1-60782, Japanese Patent Publication No. 4-3
No. 952).

Further, when light is irradiated, the energy is absorbed, stored, recorded, and then excited by using electromagnetic waves in a specific wavelength range. A stimulable phosphor having a characteristic of emitting light in a quantity of light is used as a light detecting material, and fixed polymers such as proteins and nucleic acid sequences are brought into contact with a chemiluminescent substance to generate chemiluminescence. A polymer selectively labeled with a labeling substance, and selectively labeled with the labeling substance;
The chemiluminescent substance is brought into contact, and the chemiluminescence in the visible light wavelength region generated by the contact between the chemiluminescent substance and the labeling substance is accumulated and recorded in the stimulable phosphor layer provided on the stimulable phosphor sheet. Thereafter, the stimulable phosphor layer is scanned by an electromagnetic wave to excite the stimulable phosphor, and the stimulable phosphor emitted from the stimulable phosphor is photoelectrically detected, and a digital image signal is generated. A chemiluminescence detection system that generates image information, performs image processing, reproduces a radiographic image on display means such as a CRT or a recording material such as a photographic film, and obtains information on macromolecules such as genetic information. It is known (eg, US Pat. No. 5,028,793, GB 2,246,197A, and the like).

A system using these stimulable phosphor sheets as a material for detecting an image, unlike the case of using a photographic film, not only does not require a chemical process of development but also obtains image data. By performing image processing on the image, the image is reproduced as desired, or
It has the advantage that quantitative analysis by computer becomes possible. On the other hand, a fluorescence detection (fluorescence) system using a fluorescent substance as a labeling substance instead of a radioactive labeling substance in an autoradiography system is known. According to this system, by reading the fluorescence image, the gene sequence, the expression level of the gene, the metabolism, absorption, and excretion pathways and states of the administered substance in the experimental mouse, the state of the protein, the separation and identification of the protein, or the molecular weight and characteristics Evaluation can be performed.For example, after adding a fluorescent dye to a solution containing a plurality of DNA fragments to be electrophoresed, the plurality of DNA fragments are electrophoresed on a gel support, or the fluorescent dye is After a plurality of DNA fragments are electrophoresed on the gel support, or the plurality of DNA fragments are electrophoresed on the gel support, the gel support is immersed in a solution containing a fluorescent dye. For example, an image is generated by labeling the electrophoresed DNA fragment, exciting a fluorescent dye with excitation light, and detecting the generated fluorescence, thereby forming an image on the gel support. And detect the DNA distribution, or a plurality of DNA fragments, on a gel support by means of electrophoresis, denaturing the DNA (Denatura
) and then, by Southern blotting,
A denatured DNA fragment is hybridized with a probe prepared by transferring at least a part of the denatured DNA fragment on a transfer support such as nitrocellulose and labeling DNA or RNA complementary to the target DNA with a fluorescent dye. Let
DN complementary to probe DNA or probe RNA
By selectively labeling only the A fragment, exciting the fluorescent dye with excitation light, and detecting the generated fluorescence, an image is generated, and the distribution of the target DNA on the transfer support can be detected. can do. Furthermore, DNA complementary to DNA containing the gene of interest labeled with a labeling substance
A probe is prepared, hybridized with the DNA on the transcription support, and the enzyme is bound to a complementary DNA labeled with a labeling substance, and then contacted with a fluorescent substrate to cause the fluorescent substrate to emit fluorescence. Generates an image by detecting the generated fluorescent substance by exciting the generated fluorescent substance with excitation light and detecting the generated fluorescence by the excitation light, and detecting the distribution of the target DNA on the transfer support. Can also. This fluorescence detection system, without using radioactive materials,
There is an advantage that a gene sequence or the like can be easily detected.

[0005] In an image analyzer for reproducing and observing and analyzing the image data converted into an electric signal as a visible image on a display means such as a CRT, a CRT is used.
The region to be analyzed of the image displayed on the display means, such as, is defined as a region of interest using a graphic, and the region can be analyzed. For example, a thin layer chromatography (TLC) image of a protein or an electrophoretic image of a gene has a plurality of lanes each including a plurality of bands or spots, and a plurality of bands or spots in each lane is set as a region of interest. Define
It is often done to determine the concentration.

[0006]

In a thin layer chromatography (TLC) image of a protein or an electrophoretic image of a gene, the concentration of a corresponding band or spot between a plurality of lanes is further determined and compared. In addition, it is often necessary to define a corresponding band or spot between a plurality of lanes as a region of interest. In a conventional image analyzer, in such a case, a user needs to
Using a mouse, a band or a spot is defined as a region of interest for each lane, or a mouse is used to draw a partition line across each lane on a display means such as a CRT to form a plurality of lanes. Although the corresponding band or spot between was defined as the region of interest, in the former, it is difficult to define the corresponding band or spot between multiple lanes as the region of interest, as desired, In the latter case, there is a problem that the operation is complicated.

Therefore, according to the present invention, when an image reproduced based on image data includes a plurality of lane image regions each having a plurality of band image regions or spot image regions, the present invention provides a simple operation. It is an object of the present invention to provide an image analysis apparatus that can define a corresponding band image area or spot image area in a plurality of lane image areas as a region of interest and perform quantitative analysis.

[0008]

SUMMARY OF THE INVENTION The object of the present invention is as follows.
Image data storage means for storing image data, based on the image data stored in the image data storage means, displayed on the display means, each including a plurality of band image areas or a plurality of spot image areas In an image analysis apparatus for defining and analyzing a plurality of regions of interest in an image having a lane image region, region of interest data generated in image data corresponding to one reference lane image region of the plurality of lane image regions Is achieved by an image analysis apparatus having a region-of-interest data copying means for copying image data into image data corresponding to another lane image region. According to the present invention, the region of interest data is generated only for the image data corresponding to one reference lane image region, and the region of interest data is copied only to the image data corresponding to the other lane image region. In the image data corresponding to the image area,
Since the region of interest data is generated, it is possible to define a corresponding band image region or spot image region in a plurality of lane image regions as a region of interest and perform quantitative analysis with a simple operation.

In a preferred embodiment of the present invention, the image processing apparatus further comprises graphic data storage means for storing graphic data, and uses the graphic data stored in the graphic data storage means to store an image corresponding to the reference lane image area. A region of interest is generated in the data, and the region of interest data copying means is configured to copy the graphic data. In another preferred embodiment of the present invention, further, profile data generating means for generating profile data of image data corresponding to each lane image area, and a profile data generating means for generating a profile data corresponding to each lane image area generated by the profile data generating means. Region of interest generating means for generating a region of interest in profile data of image data corresponding to one reference lane image region among the profile data of image data to be copied, wherein the region of interest data copying means Is configured to copy the generated region of interest to the profile data of the image data corresponding to.

In a further preferred aspect of the present invention, the image data is generated using a stimulable phosphor sheet on which a stimulable phosphor layer containing a stimulable phosphor is formed. In a further preferred embodiment of the present invention,
The image data is image data selected from the group consisting of radiation image data of a subject, autoradiography image data, radiation diffraction image data, electron microscope image data, chemiluminescence image data, and fluorescence image data generated by a fluorescence detection system. It consists of. In the present invention, the stimulable phosphor that can be used to generate radiation image data, autoradiography image data, radiation diffraction image data or electron microscope image data of a subject includes radiation or electron beam energy. Any material that can be stored and can be excited by electromagnetic waves and can emit the energy of the stored radiation or electron beam in the form of light, but is not particularly limited, can be excited by light in the visible light wavelength range. Those that are possible are preferred. Specifically, for example, Japanese Patent Application Laid-Open No. Sho 55-1214
No. 5 discloses an alkaline earth metal fluorohalide-based phosphor (Ba _1-x, M ²⁺ _x ) FX: yA (where M
²⁺ is at least one kind of alkaline earth metal element selected from the group consisting of Mg, Ca, Sr, Zn and Cd, X is at least one kind of halogen selected from the group consisting of Cl, Br and I, A is Eu, Tb , Ce, Tm, Dy,
At least one trivalent metal element selected from the group consisting of Pr, He, Nd, Yb and Er, x is 0 ≦ x ≦ 0.
6, y is 0 ≦ y ≦ 0.2. ), JP-A-2-276
No. 997, the alkaline earth metal fluorohalide-based phosphor SrFX: Z (where X is Cl, Br
And at least one halogen selected from the group consisting of and I, Z is Eu or Ce. ), JP-A-59-5
6479 discloses a europium-activated composite halide-based phosphor BaFX.xNaX ': aEu ²⁺ (wherein X and X' are at least one member selected from the group consisting of Cl, Br and I) Halogen,
x is 0 <x ≦ 2, and a is 0 <a ≦ 0.2. ), A cerium-activated trivalent metal oxyhalide-based phosphor disclosed in JP-A-58-69281, MOX: xCe
(Where M is Pr, Nd, Pm, Sm, Eu, Tb,
At least one trivalent metal element selected from the group consisting of Dy, Ho, Er, Tm, Yb and Bi, X is one or both of Br and I, and x is 0 <x <0.
It is one. ), LnOX: xCe which is a cerium-activated rare earth oxyhalide-based phosphor disclosed in JP-A-60-101179 and JP-A-60-90288
(Where Ln is at least one rare earth element selected from the group consisting of Y, La, Gd and Lu, X is Cl,
At least one kind of halogen selected from the group consisting of Br and I, x, is 0 <x ≦ 0.1. ) And europium-activated disclosed in JP-59-75200 JP complex halide 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 kind of alkaline earth metal element selected from the group consisting of Ba, Sr and Ca, and M ^I is L
i, at least one alkali metal element selected from the group consisting of Na, K, Rb and Cs; M ′ ^II is at least one divalent metal element selected from the group consisting of Be and Mg; M ^III is Al, Ga, At least one trivalent metal element selected from the group consisting of In and Tl, A is at least one metal oxide, X is at least one halogen selected from the group consisting of Cl, Br and I;
X ′, X ^″ and X ^{′ ″} are at least one halogen selected from the group consisting of F, Cl, Br and I;
a is 0 ≦ a ≦ 2, b is 0 ≦ b ≦ 10 ⁻² , and c is 0 ≦
c ≦ 10 ⁻² and a + b + c ≧ 10 ⁻² , x
Is 0 <x ≦ 0.5, and 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, excited by electromagnetic waves, and capable of emitting the accumulated light energy in the visible light wavelength range in the form of light may be used, and is not particularly limited. However, those which can be excited by light in the visible light wavelength range are preferred. Specifically, for example, metal halophosphate-based phosphors, rare earth element activated phosphors, aluminate-based phosphors, silicate-based phosphors, and fluoride-based phosphors disclosed in JP-A-4-232864 Body is,
It can be used preferably.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments according to the present invention will be described below in detail with reference to the accompanying drawings. FIG. 1 is a schematic perspective view showing an example of an image reading device that generates image data for an autoradiography image analysis device according to an embodiment of the present invention. In FIG. 1, a stimulable phosphor layer (not shown) containing a stimulable phosphor is formed on a stimulable phosphor sheet 1, and the stimulable phosphor layer is provided with a radioactive label substance. Location information is stored in the form of radiation energy. In this embodiment, a thin layer chromatography (TLC) image of the protein is:
The position information of the radioactive labeling substance is accumulated and recorded in the stimulable phosphor layer of the stimulable phosphor sheet 1.

Here, the positional information means various kinds of information centered on the position of the radiolabeled substance or the aggregate thereof in the sample, for example, the location and shape of the aggregate of the radiolabeled substance present in the sample, It means various types of information obtained as one or any combination of information including the concentration, distribution, and the like of the radiolabeled substance at that position. The stimulable phosphor sheet 1 on which the position information of the radioactive labeling substance in the sample is recorded is scanned and excited by the laser light 2 to generate photostimulated light. The laser light 2 is generated by a laser light source 3 and passes through a filter 4 so that a portion of a wavelength region corresponding to the wavelength region of stimulating light generated from the stimulable phosphor sheet 1 by excitation by the laser light 2 is cut. Is done. Next, the beam diameter of the laser beam 2 is accurately adjusted by the beam expander 5 and is incident on an optical deflector 6 such as a galvanomirror. The laser beam 2 deflected by the optical deflector 6 is transmitted to the fθ lens 7
Are reflected by the plane reflecting mirror 8 and incident on the stimulable phosphor sheet 1 one-dimensionally. The fθ lens 7 is
When scanning the stimulable phosphor sheet 1 with the laser beam 2, it is ensured that the scanning is always performed at a uniform beam speed.

In synchronization with the scanning by the laser beam 2, the stimulable phosphor sheet 1 is moved in the direction of arrow A in FIG. ing. When the stimulable phosphor sheet 1 is irradiated with the laser beam 2, the stimulable phosphor sheet 1 emits a photostimulable light having a quantity of light proportional to the radiation energy stored and recorded, and the emitted photostimulable light enters the light guide 9. The light guide 9 has a light-receiving end formed in a straight line, and is disposed in proximity to a scanning line on the stimulable phosphor sheet 1 so as to face a scanning line. It is connected to the light receiving surface of a photoelectric conversion type photodetector 10 such as a multiplier. The light-guiding sheet 9 is made by processing non-fluorescent glass, and the light incident from the light-receiving end repeats total reflection on the inner surface thereof, passes through the exit end, and passes through the light-emitting end. Its shape is determined so that it is transmitted to the light receiving surface.

Therefore, according to the irradiation of the laser beam 2,
The stimulated emission emitted from the stimulable phosphor sheet 1 enters the light guide 9 and is received by the photodetector 10 via the emission end while repeating total internal reflection. The light receiving surface of the photodetector 10 transmits only the light in the wavelength region of the photostimulable light emitted from the stimulable phosphor sheet 1,
The photodetector 10 is configured to photoelectrically detect only the stimulated emission emitted from the stimulable phosphor sheet 1. The photostimulated photoluminescence detected by the photodetector 10 is converted into an electric signal, and is amplified to an electric signal of a predetermined level by an amplifier 11 having a predetermined amplification factor. Is input to The electrical signal is A /
In the D converter 12, the digital signal is converted into a digital signal with a scale factor suitable for the signal fluctuation width, and is input to the line buffer 13. The line buffer 13 temporarily stores the image data for one scanning line. When the image data for one scanning line is stored as described above, the data is transferred to the line buffer 13. The transmission buffer 14 is configured to output the image data to the autoradiography image analysis device when the predetermined amount of image data is stored. ing.

FIG. 2 is a block diagram of an autoradiographic image analyzing apparatus and an image reading apparatus according to an embodiment of the present invention. In FIG. 2, the autoradiographic image analyzer 30 stores the position information of the radiolabeled substance contained in the sample, which is stored and recorded on the stimulable phosphor sheet 1, read by the image reader 20 and converted into a digital signal. A data processing unit 60 for performing data processing so as to reproduce a visible image having an appropriate density, color tone, contrast and the like and excellent observation analysis characteristics, and a data processing unit 60 from the image reading device 20. And a CRT 50 for reproducing image data containing positional information of a radioactively-labeled substance contained in a sample as an image.

The transmission buffer 14 of the image reading device 20
The temporarily stored image data is input to the reception buffer 62 of the data processing means 60 of the autoradiography image analysis device 30 and temporarily stored therein, and a predetermined amount of image data is stored in the reception buffer 62. Is stored, the stored image data is output to the image data temporary storage unit 41 of the image data storage unit 40 and stored. In this manner, the data is sent from the transmission buffer 14 of the image reading device 20 to the reception buffer 62 of the data processing unit 60,
The temporarily stored image data is further stored in the image data temporary storage unit 41 of the image data storage unit 40 from the reception buffer 62. Thus, when the image data obtained by scanning the entire surface of the stimulable phosphor sheet 1 with the laser beam 2 is stored in the image data temporary storage section 41 of the image data storage section 40, the data of the data processing section 60 The processing unit 64 reads out the image data from the image data temporary storage unit 41 and
After performing necessary data processing, only such image data is stored in the image data storage unit 42 of the image data storage unit 40, and thereafter, the image data is stored in the image data temporary storage unit 41. Delete image data.

The image data stored in the image data storage unit 42 of the image data storage unit 40 is read out by the data processing unit 64 and displayed on the screen of the CRT 50 so that the user can observe and analyze the image. It is supposed to be. FIG. 3 is a block diagram of the data processing means 60. In FIG. 3, the data processing means 60 includes:
The image reading apparatus 20 includes a reception buffer 62 for receiving image data from the transmission buffer 14, a data processing unit 64 for executing data processing, and a temporary memory 66 for temporarily storing image data. Here, the temporary memory 66
Is configured to two-dimensionally expand image data and temporarily store the image data. The data processing means 60 further includes an image data selecting unit 68 for selecting a part of the image data from the image data temporarily stored in the temporary memory 66, and an image data selected by the image data selecting unit 68. Image data enlargement / reduction unit 70 for enlarging or reducing image data, and enlarged / reduced image data storage for temporarily storing image data enlarged or reduced by the image data enlargement / reduction unit 70 in two dimensions. Part 72, CR
A graphic data storage unit 74 for storing various graphic data to be displayed on the screen of T50, and predetermined graphic data are selected from graphic data stored in the graphic data storage unit 74, and enlarged / reduced image data is selected. In order to be superimposed on the image data which is two-dimensionally expanded in the storage unit 72 and temporarily stored, the graphic data setting unit 76 for setting the position and size, and temporarily stored in the enlarged / reduced image data storage unit 72. A data synthesizing unit 78 for synthesizing the stored image data and the graphic data selected and determined in position and size by the graphic data setting unit 76, and an image data and a graphic data synthesized by the data synthesizing unit 78. A synthesized data storage unit 82 that expands two-dimensionally and temporarily stores the data;
A data area selecting section 80 for selecting a predetermined data area from the image data and the graphic data temporarily stored in the synthetic data storage section 82, and a data area of the image data and the graphic data selected by the data area selecting section 80. The data area is expanded two-dimensionally and temporarily stored in a window memory 84. The window memory 84 is two-dimensionally expanded and temporarily stored based on the temporarily stored image data and graphic data. An image display unit 86 for generating an image and a quantitative analysis unit 88 for performing a quantitative analysis on the defined region of interest are provided on the screen of the CRT 50.

An image data selection signal from the selected image data determination means 90 is input to the image data selection section 68.
The image data enlargement / reduction unit 70 is configured to receive an enlargement / reduction signal from the image data magnification determination unit 92. Further, the graphic data setting unit 76 is configured to receive a graphic data display signal from the graphic data display unit 94 and a graphic copy signal from the graphic data copying unit 96. A data synthesis signal is input from data synthesis instructing means 98 for selecting data, determining how to synthesize image data and graphic data, and displaying the data on the screen of CRT 50. . Further, the data area selection unit 8
To 0, a data area designation signal from the data area designation means 100 is input, and to the image display section 86, an image display instruction signal from the image display instruction means 102 is input.
The quantitative analysis unit 88 is configured to receive a quantitative analysis execution signal from the quantitative analysis execution unit 110.

In this embodiment, selected image data determining means 90, image data magnification determining means 92, graphic data displaying means 94, graphic data copying means 96, data combining instructing means 98, data area specifying means 100, image displaying instruction The means 102 and the quantitative analysis executing means 110 are configured to be operable by a mouse 112, respectively.
In FIG. 3, for simplification, the mouse 112 is illustrated as being connected only to the graphic data display unit 94. The autoradiography image analysis device 30 configured as described above performs the following based on the image data stored in the image data storage unit 40 in the following manner.
An image is displayed on the screen of the RT 50 and analyzed. First,
The image data stored in the image data storage unit 42 is two-dimensionally expanded and stored in the temporary memory 66. Next, the selected image data determining means 90 is operated to two-dimensionally expand the image data in the temporary memory 66, select a part of the stored image data, and expand the two-dimensionally in the image data selection unit 68. And is memorized. After that, the image data that has been two-dimensionally expanded and stored in the image data selection unit 68 is two-dimensionally expanded in the enlarged / reduced image data storage unit 72 without being enlarged or reduced. Remembered,
Further, the graphic data is two-dimensionally expanded and stored in the synthesized data storage unit 82 without being synthesized. The image data that is two-dimensionally expanded and stored in the composite data storage unit 82 is two-dimensionally expanded and stored in the window memory 84, and the CRT 50 is operated by operating the image display instruction unit 102. Is displayed as an image on the screen.

The user observes the image displayed on the screen of the CRT 50, and operates the image data magnification determining means 92 as necessary, and the image data enlargement / reduction unit 70 causes the image data selection unit 68 The image data that is two-dimensionally expanded and stored is enlarged or reduced, and the image data is two-dimensionally expanded and stored in the enlarged / reduced image data storage unit 72. Next, the image data that has been two-dimensionally expanded in the enlarged / reduced image data storage unit 72 and stored is read out by the data synthesizing unit 78, and is two-dimensionally expanded in the synthesized data storage unit 82. It is memorized. Thereafter, when the user operates the data area specifying means 100 to specify a partial area of the image data that is two-dimensionally expanded in the combined data storage unit 82 and stored, the specified image data is The image display instruction means 10 is sent to the window memory 84 and is developed and stored two-dimensionally.
2 is operated, the image display unit 86 causes the CRT 50
Is displayed as an image on the screen.

FIG. 4 shows a thin-layer chromatography (TLC) image of a protein labeled with a radiolabel,
The state displayed on the screen of T50 is shown. As shown in FIG. 4, a thin-layer chromatography (TLC) image of a protein labeled with a radiolabel has a plurality of lanes each including a plurality of bands. In order to quantitatively analyze such images, using a figure, each band in each lane is defined as a region of interest, and the concentration in the region of interest is determined and compared.
In particular, in a thin layer chromatography (TLC) image of a protein labeled with a radioactive label, the corresponding band between a plurality of lanes is determined in order to quantify and compare the concentration of the corresponding band between the plurality of lanes. Is often required to be defined as a region of interest. However,
In such a conventional image analysis apparatus, in such a case, the user may use the mouse 112 to select a plurality of lanes for each lane so that a corresponding band between the lanes is defined as a corresponding region of interest. Band of interest
Define or use the mouse 112 to
Draw a dividing line across each lane on the 50 screen,
Although the corresponding band between the plurality of lanes has been defined as the region of interest, in the former, it is difficult to define the corresponding band between the plurality of lanes as the region of interest, as desired. However, the latter has a problem that the operation is complicated. Therefore, in this embodiment, the user selects one lane as a reference lane, defines a plurality of bands included in the lane as a region of interest using a ladder-like figure, and uses the band to define the region of interest. By copying the ladder-like figure to another lane, the band corresponding to the plurality of lanes can be defined as a region of interest.

That is, when defining a region of interest, the user selects one lane as a reference lane among a plurality of lanes displayed on the screen of the CRT 50, and uses the mouse 112 to instruct data synthesis instruction means. The user operates 98 to instruct synthesis of image data and graphic data. Next, the user operates the mouse 112 while observing the image displayed on the screen of the CRT 50 so that the reference lane is defined and a plurality of band image areas in the reference lane are defined by the partition lines. By operating the graphic data display means 94, a graphic display signal including position information corresponding to the operation of the mouse 112 is generated by the graphic data setting unit 7.
6 is input. Upon receiving the graphic display signal, the graphic data setting unit 76 reads the graphic data corresponding to the position information from the graphic data storage unit 74, and stores the coordinate values in the image data of the graphic data corresponding to the ladder-like graphic, Output to the data synthesizing unit 78. The data synthesizing unit 78 synthesizes the graphic data corresponding to the ladder figure input from the graphic data setting unit 76 and the image data which is two-dimensionally expanded and stored in the enlarged / reduced image data storage unit 72. , And two-dimensionally develop and store them in the combined data storage unit 82. The image data and the graphic data corresponding to the ladder-like graphic two-dimensionally expanded and stored in the composite data storage unit 82 are sent to the CR through the window memory 84.
It is displayed on the screen of T50. As a result, based on the image data, a plurality of bands in the reference lane in the image displayed on the CRT 50 is defined as a region of interest by a ladder-like figure. FIG. 5 shows a state in which an image in which a plurality of bands in the reference lane are defined as regions of interest by the user is displayed on the screen of the CRT 50. The coordinate values of the graphic data corresponding to the ladder-like graphic two-dimensionally expanded and stored in the synthetic data storage unit 82 are input to the quantitative analysis unit 88.

Next, the user operates input means (not shown) such as a keyboard or the mouse 112 to
Specify the position of another lane where the ladder figure should be copied. As a result, a graphic data copy signal including information on the position where the ladder graphic designated by the user is to be copied is input to the graphic data setting unit 76. The graphic data setting unit 76
Based on the input figure data copy signal and the coordinate values of the figure data corresponding to the stored ladder figure, figure data to be copied is generated and the coordinate values are stored. Next, when the user operates the input means such as a keyboard or the mouse 112 and operates the data synthesizing instruction means 98, the graphic data generated by the graphic data setting unit 76, together with the coordinate values thereof, is transmitted to the data synthesizing unit 78. And is combined with the image data that is two-dimensionally developed and stored in the enlarged / reduced image data storage unit 72, and is two-dimensionally developed and stored in the combined data storage unit 82. The image data and the graphic data to be copied that are two-dimensionally expanded and stored in the combined data storage unit 82 are displayed as images and graphics on the screen of the CRT 50 via the window memory 84. as a result,
Based on the image data, a plurality of bands in lanes other than the reference lane in the image displayed on the CRT 50 are represented by the same ladder-like figure used for defining the reference lane.
It is defined as a region of interest. FIG. 6 shows a state in which an image in which the corresponding band between the plurality of lanes is defined as the region of interest is displayed on the screen of the CRT 50. The coordinate values of the graphic data corresponding to the ladder-like graphic two-dimensionally expanded and stored in the synthetic data storage unit 82 are
It is input to the quantitative analysis unit 88.

FIG. 7 is a block diagram of the quantitative analysis unit 88. As shown in FIG. 7, the quantitative analysis unit 88
The coordinate storage unit 200 stores the coordinate values of the graphic data input from the combined data storage unit 82, and the figure stored in the coordinate storage unit 200 according to the quantitative analysis execution signal input from the quantitative analysis execution unit 110. Based on the coordinate values of the data, an image data reading unit 202 that reads image data corresponding to the region of interest from image data that is two-dimensionally expanded and stored in the temporary memory 66, and input from the image data reading unit 202. An operation processing unit 204 that executes an operation based on the image data and outputs the operation result to the window memory 84 is provided. When performing a quantitative analysis on a corresponding band image region between a plurality of lanes defined as a region of interest, the user operates the quantitative analysis execution unit 110 to transmit a quantitative analysis execution signal to that effect to the quantitative analysis unit. 88 to the image data reading unit 202 and the arithmetic processing unit 204. Upon receiving the quantitative analysis execution signal, the image data reading unit 202 accesses the coordinate storage unit 200, reads the coordinate values of the graphic data corresponding to the graphic defining the region of interest to be quantified, and reads the read coordinate values. The image data corresponding to the region of interest to be quantified is read out from the image data that is two-dimensionally expanded in the temporary memory 66 based on the stored image data and output to the arithmetic processing unit 204. The arithmetic processing unit 204 performs an arithmetic operation on the image data corresponding to the corresponding band image area between the plurality of lanes according to the quantitative analysis execution signal input from the quantitative analysis execution unit 110, and stores the arithmetic result in the window memory 84. Is output to the window memory 84.
Are displayed on the screen of the CRT 50.

According to this embodiment, one of a plurality of lanes in an image is selected as a reference lane, and a plurality of band image regions in the reference lane are defined as regions of interest using a ladder-like figure. Then, by simply copying the ladder-like figure, the corresponding band image region in another lane can be defined as the region of interest, and with a simple operation, the corresponding band image region between a plurality of lanes is set as the region of interest. And perform quantitative analysis. FIG.
FIG. 9 is a block diagram of a data processing unit 60 of an image analysis device according to another embodiment of the present invention, and FIG. 9 is a block diagram of a quantitative analysis unit 88. In the present embodiment, the autoradiography image analysis device,
Based on the density profile of each lane image region, only a band image region having a high density is defined as a region of interest, and a quantitative analysis can be performed on a corresponding band image region between a plurality of lanes. As shown in the figure, the data processing means 60 generates profile data of the density level of the image data area corresponding to the region of interest in the stored image data by two-dimensionally developing the data in the window memory 84, and Profile data generation unit 3 that outputs to memory 84 and stores the profile data
00, a region-of-interest generation unit 302 that generates region-of-interest data corresponding to a region of interest that defines a band image region in the reference lane image region specified by the user, and copies the region-of-interest data to image data regions corresponding to other lane image regions. It has.
The profile data generation unit 300 receives the profile data generation signal, the profile data storage signal, and the profile display signal from the profile data generation instruction unit 310, and the region of interest data generation unit 302 receives the interest from the region of interest determination unit 312. The region determination signal and the region of interest data copy signal from the region of interest data copy instructing means 314 are input.
The profile data generation instruction signal is also configured to be input to the image data reading unit 202 of the quantitative analysis unit 88.

In the autoradiography image analyzing apparatus according to the present embodiment, first, a plurality of lane image regions are defined by the user as regions of interest. That is, the user operates the graphic data synthesis instructing means 98 using the mouse 112 to instruct synthesis of image data and graphic data. Next, while observing the image displayed on the screen of the CRT 50, the user operates the graphic data display means 94 by operating the mouse 112 so that a plurality of lanes are defined.
A graphic display signal including position information corresponding to the operation 2 is input to the graphic data setting unit 76. Upon receiving the graphic display signal, the graphic data setting unit 76 reads the graphic data corresponding to the position information from the graphic data storage unit 74, and stores the coordinate values in the image data of the graphic data corresponding to the graphic defining each lane. At the same time, the data is output to the data synthesizing unit 78. The data synthesizing unit 78 includes a graphic data setting unit 76
Figure data corresponding to the ladder figure input from
The image data that is two-dimensionally expanded and stored in the enlarged / reduced image data storage unit 72 is combined, and the two-dimensionally expanded and stored in the combined data storage unit 82. The image data and the graphic data which are two-dimensionally expanded and stored in the composite data storage unit 82 are transmitted to a CR through a window memory 84.
It is displayed on the screen of T50. As a result, based on the image data, a plurality of lanes in the image displayed on the CRT 50 are defined as a region of interest by a graphic. FIG. 10 shows a state in which an image in which a plurality of lanes are defined as regions of interest by the user is displayed on the screen of the CRT 50. The coordinate values of the graphic data two-dimensionally expanded and stored in the composite data storage unit 82 are input to the quantitative analysis unit 88.

Next, when the user operates the profile data generation instructing means 310 by specifying the lane for which the density profile is to be generated, the profile data generation signal is transmitted to the profile data generation section 300 and the image data read section 202 of the quantitative analysis section 88. Is input to Upon receiving the profile data generation signal, the image data reading unit 202 accesses the coordinate storage unit 200 to read and read the coordinate values of the graphic data corresponding to the graphic defining the lane for which the density profile is to be generated. Based on the coordinate values, lane image data for which a density profile is to be generated is read out from the stored image data that is two-dimensionally developed in the temporary memory 66 and output to the profile data generation unit 300. The profile data generation unit 300 generates profile data based on the input image data and outputs the profile data to the window memory 84.
When the image display instruction unit 102 is operated, the image display unit 8
6, the density profile curve of the designated lane is displayed on the screen of the CRT 50. Users can use CRT
Observing the density profile displayed on the screen 50 and operating the profile data generation instructing means 312 to save the profile, the profile data generation unit 300 is operated.
Input a profile data storage signal to store profile data.

In this way, the profile data of all the lane image regions in the image displayed on the screen of the CRT 50 is generated and stored in the profile data generating unit 300, and then the band image region with high density is defined as the region of interest. Then, when performing the quantitative analysis, the user selects a reference lane from a plurality of lanes in the image, and operates the profile generation instructing means 310 to display the concentration profile of the reference lane on the screen of the CRT 50. A profile display signal indicating the power of the profile should be output to the profile data generator 300.
To enter. Upon receiving the profile display signal, profile data generating section 300 outputs, to window memory 84, among the stored profile data, reference profile data corresponding to the lane image area designated as the reference lane. When the image display instructing means 102 is operated, the density profile curve of the reference lane image area is displayed on the screen of the CRT 50 by operating the image display instruction means 102 on the reference profile data output to the window memory 84.

The user determines the boundary of the band image area while observing the density profile curve of the reference lane image area displayed on the screen of the CRT 50, and
12 by operating the region-of-interest determination means 312, and outputs the region-of-interest determination signal to the region-of-interest data generator 30.
Enter 2 Upon receiving the region of interest determination signal, the region of interest data generation unit 302 generates region of interest data corresponding to the boundary of the band image region, and stores the coordinate values.
FIG. 11 shows a state in which a region of interest is generated on the density profile curve of the reference lane image region. After determining the region of interest defining the band image region in the reference lane in this manner, the user sets the region of interest defining the band image region in each of the other lane image regions. By operating 314,
The region-of-interest data copying unit 304 inputs a region-of-interest data copy signal indicating that region-of-interest data corresponding to the region of interest defining the reference lane image region should be copied to profile data of another lane image region. Upon receiving the region-of-interest data copy signal, the region-of-interest data copy unit 304 accesses the region-of-interest data generation unit 302 to read out the coordinate values of the region-of-interest data of the reference lane, and is stored in the profile data generation unit 300. The region of interest data is copied onto the profile data of another lane image region.
As a result, a region of interest similar to that of FIG. 11 is generated in the profile data of another lane image region.

Thereafter, when performing a quantitative analysis on the corresponding band image area between a plurality of lanes, the user operates the quantitative analysis executing means 110 to send a quantitative analysis execution signal to that effect to the quantitative analysis section 88. The image data is output to the image data reading unit 202 and the arithmetic processing unit 204. Upon receiving the quantitative analysis execution signal, the image data reading unit 202
Accesses the profile data generation unit 300, reads out the profile data and the region of interest data of each lane image region, and outputs them to the arithmetic processing unit 204. The arithmetic processing unit 204 performs quantitative processing on the profile data and the region of interest data of each lane image area input from the image data reading unit 202 according to the quantitative analysis execution signal input from the quantitative analysis execution unit 110, and calculates The result is output to the window memory 84, and the calculation result is displayed on the screen of the CRT 50 via the window memory 84.

According to the present embodiment, one of the lanes in the image is selected as a reference lane, and a region of interest defining a band image region is determined based on profile data of the reference lane image region. By simply copying on the profile data of the other lane image area, the corresponding band image area in the other lane can be defined as a region of interest and quantitative analysis can be performed. It is possible to define a corresponding band image region as a region of interest and perform a quantitative analysis. The present invention is not limited to the above embodiments, and various changes can be made within the scope of the invention described in the claims, which are also included in the scope of the present invention. Needless to say.

For example, in the above-described embodiment, a case has been described in which a quantitative analysis is performed on a thin-layer chromatography (TLC) image of a protein labeled with a radioactive labeling substance. Without being limited to image analysis, for example, using Southern blot hybridization, autoradiographic images of genes electrophoresed, polyacrylamide gel electrophoresis, protein separation, identification, Alternatively, using the stimulable phosphor sheet 1 such as an autoradiographic image for evaluating molecular weight and characteristics, etc., the stimulable phosphor sheet 1 may be used for quantitative analysis of other generated autoradiographic images. Chemiluminescent images generated using , Separation of the image and proteins fluorescent substance recorded in a gel support or a transfer support, identification,
Alternatively, the present invention can be widely applied to quantitative analysis such as an image of a fluorescent substance for evaluating molecular weight and characteristics.

In the above-described embodiment, the image data obtained by converting the positional information of the radioactively labeled substance in the sample into an electric signal using the stimulable phosphor sheet 1 is converted to the CRT 5.
Although a visible image is displayed on the screen of No. 0, a visible image is once formed using a photographic film instead of the stimulable phosphor sheet 1, and the visible image is read photoelectrically to A similar process can be performed on the image data converted into a signal. Further, in the present invention, means does not necessarily mean physical means, but also includes a case where the function of each means is realized by software. Further, the function of one unit may be realized by two or more physical units, or the function of two or more units may be realized by one physical unit.

[0035]

According to the present invention, when an image reproduced based on image data includes a plurality of lane image regions each having a plurality of band image regions or spot image regions, a simple operation can be performed. Thus, it is possible to provide an image analysis apparatus that can define a corresponding band image area or spot image area in a plurality of lane image areas as a region of interest and perform quantitative analysis.

[Brief description of the drawings]

FIG. 1 is a schematic perspective view showing an example of an image reading device that generates image data for an autoradiography image analysis device according to an embodiment of the present invention.

FIG. 2 is a block diagram of an autoradiography 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 unit.

FIG. 4 is a halftone image showing a screen of a CRT 50 on which a thin-layer chromatography (TLC) image of a protein labeled with a radioactive label is displayed.

FIG. 5 is a halftone image showing a CRT screen on which an image in which a plurality of bands in a reference lane are defined as regions of interest is displayed.

FIG. 6 is a halftone image showing a CRT screen on which an image in which corresponding bands between a plurality of lanes are defined as regions of interest is displayed.

FIG. 7 is a block diagram of a quantitative analysis unit.

FIG. 8 is a block diagram of a data processing unit of an image analysis device according to another embodiment of the present invention. 6 is a halftone image showing a CRT screen.

FIG. 9 is a block diagram of a quantitative analysis unit of an image analysis device according to another embodiment of the present invention.

FIG. 10 is a halftone image showing a CRT screen on which an image in which a plurality of lanes are defined as regions of interest is displayed.

FIG. 11 is a graph showing a density profile curve of a reference lane image area where a region of interest is generated.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 stimulable phosphor sheet 2 laser light 3 laser light source 4 filter 5 beam expander 6 optical deflector 7 fθ lens 8 plane reflecting mirror 9 light guide 10 photodetector 11 amplifier 12 A / D converter 13 line buffer 14 transmission Buffer 20 Image reading device 30 Autoradiography 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 unit 70 Image data enlargement / reduction unit 72 Enlarged / reduced image data storage unit 74 Graphic data storage unit 76 Graphic data setting unit 78 Data synthesis unit 80 Data area selection unit 82 Synthetic data storage unit 84 Window memory 86 Image display unit 88 Quantitative analysis unit 90 Selected image data Data determining means 92 image data magnification determining means 94 graphic data displaying means 96 graphic data copying means 98 data combining instructing means 100 data area designating means 102 image display instructing means 110 quantitative analysis executing means 112 mouse 200 coordinate storage section 202 image data reading section 204 arithmetic processing unit 300 profile data generating unit 302 region of interest data generating unit 304 region of interest data copying unit 310 profile data generation instructing unit 312 region of interest data determining unit 314 region of interest data copying instructing unit

Claims (5)

[Claims] 1. An image data storage means for storing image data, wherein a plurality of band image areas or spot image areas are displayed on a display means based on the image data stored in the image data storage means. In an image analysis apparatus for defining and analyzing a plurality of regions of interest in an image having a plurality of lane image regions including a plurality of lane image regions, the image data is generated into image data corresponding to one reference lane image region of the plurality of lane image regions. An image analyzing apparatus comprising: a region-of-interest data copying unit that copies the obtained region-of-interest data into image data corresponding to another lane image region. 2. A graphic data storage means for storing graphic data, wherein interest area data is generated in image data corresponding to the reference lane image area using graphic data stored in the graphic data storage means. 2. The image analysis apparatus according to claim 1, wherein said region of interest data copying means is configured to copy said graphic data. 3. Profile data generating means for generating profile data of image data corresponding to each lane image area, and profile data of image data corresponding to each lane image area generated by the profile data generating means. A region of interest generating means for generating a region of interest in the profile data of the image data corresponding to one reference lane image region, wherein the region of interest data copying means is configured to copy the image data corresponding to the reference lane image region. The image analysis apparatus according to claim 1, wherein the apparatus is configured to copy the region of interest generated in the profile data. 4. The image data according to claim 1, wherein the image data is generated by using a stimulable phosphor sheet on which a stimulable phosphor layer containing a stimulable phosphor is formed. 4. The image analysis device according to any one of 3. 5. The group of the image data comprising radiation image data of a subject, autoradiography image data, radiation diffraction image data, electron microscope image data, chemiluminescence image data, and fluorescence image data generated by a fluorescence detection system. The image analysis device according to claim 1, wherein the image analysis device is configured by image data selected from the following.