JP2003189179A - Abnormal shade detector and image output device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an abnormal shade detector that easily detects an object of an abnormal shade in a state that an abnormal shade and a normal tissue can easily be distinguished. <P>SOLUTION: The abnormal shade detector is provided with: a multiple frequency processing means that applies conversion processing to an unsharpened image signal with picture frequency bands and adding a differential image signal obtained by a difference between the unsharpened image and the image signal after the conversion processing above to a medical use image signal obtained from a subject to produce a processed image signal; and an abnormal shade detection means that uses the processed image signal obtained by the multiple frequency processing means to detect an abnormal shade. The multiple frequency processing means is characterized in that the multiple frequency processing means conducts processing to emphasize the unsharpened image signal having a frequency component of a frequency band including a lesion. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an abnormal shadow detection device for detecting a candidate for an abnormal shadow by processing a medical image signal obtained from a subject, and an image output device for outputting the processed image.

[0002]

2. Description of the Related Art Computer-aided diagnosis for detecting abnormal shadow candidates such as lung cancer and breast cancer for the purpose of reducing the burden on an interpreting doctor and overlooking abnormal shadows.
s: CAD) has been developed. In the case of breast cancer, it has been widely reported that two major findings, a mass shadow and microcalcification, are detected.

The following is a paper on the detection of the two major findings of breast cancer. (1) Tumor shadow: Regarding the tumor shadow, a method of detecting by comparing the left and right breasts (Me
d. Phys. , Vol. 21. No. 3, pp. 44
5-452),-Detection method using iris filter
-II), Vol. J75-D-11, no. 3, p
p. 663-670, 1992), a method of detecting using a Quait filter (Theoretical theory (D-II), Vol. J76-D-11, no. 3,
pp. 279-287, 1993), 2 based on the histogram of the pixel values of the divided breast region
Quantification and detection (JAMIT Frontie
r Proceedings, pp. 84-85, 1995), a minimum directional difference filter that takes the minimum output of a large number of directional Laplacian filters (Communication theory (D-II), V
ol. J76-D-11, no. 2, pp. 241-2
49, 1993), and the like.

(2) Microcalcification clusters: Regarding microcalcification clusters, a region suspected of calcification is localized from the breast region, and false from the standard deviation value of the optical density difference of the shadow image or the boundary density difference. How to delete positive candidates (IEEE TransBiom
ed Eng BME-26 (4): 213-219,
1979),-Detection method using an image that has been subjected to a Laplacian filter process (Physics (D-II), Vol. J71-D
-11, no. 10, pp. 1994-2001, 19
88), ・ Detection method using morphologically analyzed images in order to suppress the influence of background patterns such as mammary glands (Biology (D-
II), Vol. J71-D-11, no. 7, pp.
1170-1176, 1992), and the like.

[0005]

In the above cases, when detecting an abnormal shadow using a conventional image, it is difficult to distinguish the abnormal shadow to be detected from normal tissue, and it is difficult to detect the abnormal shadow. , I sometimes mistakenly judge normal tissue as an abnormal shadow.

The present invention has been made in view of the above problems, and an abnormal shadow detecting apparatus capable of easily detecting an abnormal shadow to be detected and a normal tissue, and an abnormal shadow detecting apparatus, , An image output device is provided.

[0007]

The present invention for solving the above problems is as follows. (1) The invention according to claim 1 performs a conversion process on a non-sharp image signal of a plurality of frequency bands with respect to a medical image signal obtained from a subject, and outputs the non-sharp image and the image signal after the conversion process. Multiple frequency processing means for generating a processed image signal by adding difference image signals obtained by the difference, and abnormal shadow detection means for detecting an abnormal shadow using the processed image signal obtained by the multiple frequency processing means. And the multi-frequency processing means, as the conversion processing, performs processing for emphasizing a non-sharp image signal possessing a frequency component of a frequency band including a lesion, is there.

According to the present invention, the medical image signal from the subject is subjected to conversion processing on the unsharp image signals in a plurality of frequency bands, and the difference obtained by the difference between the unsharp image and the image signal after the conversion processing. A processed image signal is generated by adding the image signals, and when the abnormal shadow is detected using the processed image signal, the conversion process is performed by a non-owner having a frequency component in a frequency band including a lesion. A process for emphasizing a sharp image signal is performed.

By thus enhancing the unsharp image signal possessing the frequency component of the frequency band including the lesion, it becomes easy to distinguish the abnormal shadow that is the detection target from the normal tissue, and the abnormal It becomes easy to detect the shadow candidates.

(2) In a second aspect of the present invention, a medical image signal obtained from a subject is converted into a non-sharp image signal of a plurality of frequency bands, and the non-sharp image and the post-conversion processing are performed. Multiple frequency processing means for generating a processed image signal by adding the difference image signals obtained by the difference of the image signals, and an abnormality for detecting an abnormal shadow using the processed image signal obtained by the multiple frequency processing means. A shadow detecting unit, wherein the multiple frequency processing unit performs, as the conversion process, a process of suppressing an unsharp image signal having a frequency component other than a frequency band including a lesion. It is a shadow detection device.

According to the present invention, the medical image signal from the subject is converted into the unsharp image signals in a plurality of frequency bands, and the difference obtained by the difference between the unsharp image and the image signal after the conversion processing is obtained. A processed image signal is generated by adding the image signals, and when the abnormal shadow is detected using the processed image signal, the conversion process includes frequency components other than the frequency band including the lesion. A process for suppressing an unsharp image signal is performed.

As described above, by performing the processing for suppressing the non-sharp image signal possessing the frequency component other than the frequency band including the lesion, it becomes easy to distinguish the abnormal shadow to be detected from the normal tissue, It becomes easy to detect candidates for abnormal shadows.

(3) In the invention according to claim 3, the medical image signal obtained from the subject is subjected to conversion processing into a non-sharp image signal of a plurality of frequency bands, and the non-sharp image and the post-conversion processing are performed. Multiple frequency processing means for generating a processed image signal by adding the difference image signals obtained by the difference of the image signals, and an abnormality for detecting an abnormal shadow using the processed image signal obtained by the multiple frequency processing means. Shadow detection means, and the multi-frequency processing means performs, as the conversion processing, processing for emphasizing a non-sharp image signal having a frequency component of a frequency band including a lesion and other than a frequency band including a lesion. The abnormal shadow detecting apparatus is characterized by performing processing for suppressing an unsharp image signal having the frequency component of.

According to the present invention, the medical image signal from the subject is converted into the unsharp image signals in a plurality of frequency bands, and the difference obtained by the difference between the unsharp image and the image signal after the conversion processing. A processed image signal is generated by adding the image signals, and when the abnormal shadow is detected using the processed image signal, the conversion process is performed by a non-owner having a frequency component in a frequency band including a lesion. A process of emphasizing a sharp image signal and a process of suppressing a non-sharp image signal having a frequency component other than a frequency band including a lesion are performed.

As described above, the processing for emphasizing the non-sharp image signal having the frequency component of the frequency band including the lesion is performed, and the non-sharp image signal having the frequency component other than the frequency band including the lesion is suppressed. By applying processing,
This makes it easier to distinguish between the abnormal shadow that is the detection target and normal tissue, and it becomes easier to detect candidates for abnormal shadows.

(4) The invention according to claim 4 is characterized in that the multiple frequency processing means carries out, as the conversion processing, processing for suppressing low-frequency frequency components included in a plurality of frequency bands to be processed. The abnormal shadow detection device according to any one of claims 1 to 3.

According to the present invention, in the above (1) to (3), as the conversion processing of the multiple frequency processing means, processing for suppressing low frequency frequency components included in a plurality of frequency bands to be processed is performed. .

It should be noted that, in a region where the influence of the background trend is strong, the feature changes depending on the position where the lesion exists, so suppression of the background trend is an extremely important issue. In such a case, by suppressing the low-frequency component that includes the background trend, it becomes easier to distinguish the abnormal shadow that is the target of detection from normal tissue, and it becomes easier to detect abnormal shadow candidates. .

(5) The invention according to claim 5 is characterized in that the multi-frequency processing means suppresses low-frequency components and high-frequency components and emphasizes intermediate frequency components as the conversion processing. The abnormal shadow detection device according to any one of claims 1 to 3.

In the present invention, in the above (1) to (3), the low frequency component refers to a frequency component that includes a background trend, and the high frequency component refers to a high frequency component that includes noise. Pointing. Since the abnormal shadow exists in the frequency band between them, by suppressing the frequency components other than the abnormal shadow and emphasizing the frequency components in which the abnormal shadow may exist, the performance of the abnormal shadow detection process is improved. .

(6) In the invention according to claim 6, when the medical image signal is a mammogram or a plain X-ray image of the chest and the abnormal shadow for detection is a tumor shadow, the multiple frequency processing means performs the conversion. As processing, 0.016 lp
6. The abnormal shadow detecting apparatus according to claim 1, wherein a process of suppressing a low frequency component lower than / mm and a high frequency component lower than 0.1 lp / mm is performed.

According to the present invention, in the above (1) to (5), when the medical image signal is a mammogram or a plain chest X-ray image and a tumor is detected, it is lower than 0.016 lp / mm by the multi-frequency processing means. Frequency component, 0.1 lp /
A process of suppressing high-frequency components from mm is performed, and by this process, a component of a tumor corresponding to a diameter of 5 mm to 30 mm stands out in the image and detection becomes easy.

(7) The invention according to claim 7 is characterized in that the frequency band to be suppressed or emphasized in the multiple frequency processing means is determined based on at least one of the object part and the type of abnormal shadow. An abnormal shadow detection device according to any one of claims 1 to 5.

In the present invention, in the above (1) to (5), the frequency band to be suppressed or emphasized in the multiple frequency processing is determined based on at least one of the object region and the type of abnormal shadow, and therefore, it is used for detection purposes. It becomes possible to create an image in accordance with it, and it becomes possible to perform multi-frequency processing suitable for the object part used for the determination or the type of abnormal shadow, and it becomes easy to detect a candidate of abnormal shadow.

(8) In the invention described in claim 8, the medical image signal obtained from the subject is subjected to conversion processing into a non-sharp image signal in a plurality of frequency bands, and the non-sharp image and the post-conversion processing are performed. Multiple frequency processing means for generating a processed image signal by adding the difference image signals obtained by the difference of the image signals, and an abnormality for detecting an abnormal shadow using the processed image signal obtained by the multiple frequency processing means. An abnormal shadow detecting device, comprising: a shadow detecting means, wherein the multiple frequency processing means performs, as the conversion processing, processing depending on at least one of a density or a pixel value of the medical image signal. is there.

According to the present invention, the medical image signal from the subject is subjected to conversion processing on the unsharp image signals in a plurality of frequency bands, and the difference obtained by the difference between the unsharp image and the image signal after the conversion processing. When the processed image signal is generated by adding the image signals and the abnormal shadow is detected using the processed image signal, the multi-frequency processing means uses at least one of the density or the pixel value of the medical image signal. The conversion processing that depends on is performed.

By carrying out the conversion processing depending on at least one of the density or the pixel value of the medical image signal in this manner, only the density or the pixel value in which an abnormal shadow is likely to appear is emphasized, or the contrast is relatively high. It is possible to detect lesions in any density range with the same criteria by suppressing the density or pixel value that is easy to see, and emphasizing the density or pixel value that is hard to have contrast. It becomes easy to distinguish between normal tissue and normal tissue, and it becomes easy to detect candidates for abnormal shadows.

(9) In the invention according to claim 9, when the medical image signal is a mammogram, the multiple frequency processing means performs, as the conversion processing, a low density of an unsharp image signal having a low frequency component, Alternatively, the abnormal shadow detecting apparatus according to claim 8, wherein processing for suppressing the emphasis degree of the low pixel value is performed.

According to the present invention, in the above (8), as the conversion processing of the multiple frequency processing means, the emphasis degree of the low density or the low pixel value of the signal of the low frequency frequency component included in the plurality of frequency bands to be processed is set. A process of suppressing is applied.

In the mammogram, the background trend of the high density portion (high pixel value) close to the skin line is strong. In such a case, by suppressing the emphasis degree of the low-frequency part of low density (low pixel value), overcorrection is prevented, and it becomes easier to distinguish the abnormal shadow that is the detection target from normal tissue. , It becomes easy to detect abnormal shadow candidates.

(10) When the medical image signal is a mammogram, the invention according to claim 10 has a classifying unit for classifying the medical image signal according to the regressive state of the mammary gland, and the multiple frequency processing unit comprises: The frequency band to be suppressed or emphasized, the density to be suppressed or emphasized, or the pixel value to be suppressed or emphasized is determined according to the result of the classification by the classification means, or
The abnormal shadow detection device according to claim 8.

In the present invention, the above (1) to (3),
In (8), when the medical image signal is a mammogram,
The frequency band to be suppressed or emphasized, the density to be suppressed or emphasized, or the pixel value to be suppressed or emphasized is determined according to the result classified by the classifying means, and it is suitable according to the result classified by this processing. Multiple frequency processing becomes possible, and detection of abnormal shadow candidates becomes easy.

For example, for an image in which a thick mammary gland is widely spread, there is a strong possibility that an abnormal shadow exists in the thick mammary gland, so that it is difficult to provide contrast, and the degree of emphasis is increased or the mammary gland is almost fat. In an image in which tissue is replaced, the contrast is likely to occur, so by suppressing the degree of enhancement, the detection rate can be improved.

(11) The invention according to claim 11 is a display device for displaying at least one of a medical image signal obtained from a subject or the processed image signal obtained by processing by the multiple frequency processing means. A state of superimposing an abnormal shadow candidate detected by the abnormal shadow detection means on the display of the medical image signal or the processed image signal, or the display of the medical image signal or the processed image signal. The abnormal shadow detection device according to any one of claims 1 to 10, wherein the abnormal shadow detection device is displayed in a state in which it is not overlapped with, or in at least one of the states.

According to the present invention, the detected abnormal shadow candidate is superposed on the display of the medical image signal or the processed image signal, or is not superposed on the display of the medical image signal or the processed image signal. Alternatively, since the images are displayed in both states, it is easy to detect an abnormal shadow candidate from the displayed image.

(12) According to the twelfth aspect of the invention, the medical image signal obtained from the subject is subjected to conversion processing into a non-sharp image signal in a plurality of frequency bands, and the non-sharp image and the post-conversion processing are performed. Output the image based on the processed image signal converted by the multiple frequency processing means for generating the processed image signal by adding the difference image signals obtained by the difference of the image signals Image output means, and the multi-frequency processing means,
As the conversion process, a process of emphasizing a non-sharp image signal having a frequency component of a frequency band including a lesion, or a process of suppressing a non-sharp image signal having a frequency component other than a frequency band including a lesion And the image output means outputs an image based on the processed image signal converted by the multiple frequency processing means.

According to the present invention, the medical image signal from the subject is subjected to conversion processing on the unsharp image signals in a plurality of frequency bands, and the difference obtained by the difference between the unsharp image and the image signal after the conversion processing. When generating a processed image signal by adding image signals and outputting the image, the conversion process includes a process of emphasizing a non-sharp image signal possessing a frequency component of a frequency band including a lesion, and a lesion. At least one of a process of suppressing an unsharp image signal having a frequency component other than the frequency band is performed.

As described above, the processing for enhancing the non-sharp image signal having the frequency component of the frequency band including the lesion is performed, and / or the non-sharp image signal having the frequency component other than the frequency band including the lesion is displayed. An image in which a lesion is emphasized can be presented by performing a suppressing process and displaying an image of the result of such a process on a CRT display or outputting to a film, and improvement in diagnostic performance can be expected.

(13) According to the thirteenth aspect of the present invention, the process of suppressing the non-sharp image signal having a frequency component other than the frequency band including the lesion corresponds to a low frequency component corresponding to a background trend and noise. The image output device according to claim 12, wherein the image output device is a process of simultaneously suppressing high-frequency components.

In the above (12), as the processing for suppressing the non-sharp image signal having the frequency component other than the frequency band including the lesion, the low frequency component corresponding to the background trend and the high frequency component corresponding to the noise are used. It is preferable that the treatments simultaneously suppress

[0041]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described in detail below with reference to the drawings. FIG. 2 is a block diagram showing an embodiment of the present invention.

In FIG. 2, reference numeral 101 denotes an image data input means for inputting a radiation image as a medical image signal, and 10
Reference numeral 2 is an image data storage means for storing the output of the image data input means 101, 103 is a classification means for classifying medical image signals, and 104 is a processing characteristic determination means for determining processing characteristics for medical image signals according to the classification result. is there.

Reference numeral 105 performs conversion processing on the non-sharp image signals in a plurality of frequency bands according to the determined processing characteristics, and obtains a difference image signal obtained by the difference between the non-sharp image and the image signal after the conversion processing. It is a multi-frequency processing means for generating a processed image signal by adding. Reference numeral 106 is an abnormal shadow detecting means for performing processing for detecting an abnormal shadow candidate from the processed image signal from the multiple frequency processing means 105. Reference numeral 107 indicates a candidate for an abnormal shadow, using the medical image signal stored in the image data storage means 102, the processed image signal processed by the multiple frequency processing means 105, and the abnormal shadow detected by the abnormal shadow detection means 106. The image output control means controls the output of the image to be displayed in at least one of the state in which the processed image signal is displayed and the state in which the processed image signal is not displayed. Reference numeral 108 denotes an image display means for displaying the image generated by the image output control means 107, and 109 denotes the image output control means 1.
Image printing means for printing out the image generated in 07.

As the image display means 108, for example, CR
A T display, a liquid crystal display, or the like is used, and as the image printing unit 109, for example, a printer that outputs to film or a printer that outputs to paper is used.

The operation of the abnormal pattern detection apparatus 100 configured as described above will be described below. In addition,
Here, the flowchart of FIG. 1 is referred to. <(1) Input> X-ray film is used to capture a radiation image. A laser digitizer is used to input these X-ray photographs into the abnormal pattern detection apparatus 100 shown in FIG. In this method, a film is scanned with a laser beam, the amount of transmitted light is measured, and the value is analog-digital converted to input a medical image signal as digital image data to the image data input means 101 (FIG. 1S1).

For inputting an image, it is possible to use a device using an optical sensor such as a CCD. Further, instead of reading the film, it is also possible to connect a photographing device as described in JP-A-55-12429, which can directly output a digital image using a stimulable phosphor. is there. In this case, the film becomes unnecessary and the cost can be reduced.

It is also possible to input an X-ray image obtained from a flat panel detector (FPD) which picks up an X-ray image by a plurality of two-dimensionally arranged detection elements and outputs it as an electric signal. For example, JP-A-6-34209
As described in Japanese Patent Publication No. 8, a photoconductive layer that generates electric charges according to the intensity of irradiated X-rays, and a method that accumulates the generated electric charges in a plurality of two-dimensionally arranged capacitors are known. Used.

Further, as described in JP-A-9-90048, X-rays are absorbed in a phosphor layer such as an intensifying screen to generate fluorescence, and the intensity of the fluorescence is set for each pixel. A method of detecting with a photodetector such as a photodiode is also used. Other means for detecting fluorescence include CCD and C-MOS.
There is also a method using a sensor. Further, a configuration in which an X-ray scintillator that emits visible light by irradiation of X-rays and a lens array and an area sensor corresponding to each lens are combined is also used.

When a digital X-ray image is obtained with the various configurations described above, the effective pixel size of the image is, for example, 200 μm for a mammogram (X-ray image of the breast), depending on the region to be imaged and the diagnostic purpose. It is preferably not more than 100 μm, more preferably not more than 100 μm. In order to maximize the performance of the image diagnosis support apparatus of the present invention, it is preferable to store and display image data input with an effective pixel size of about 50 μm, for example.

The pixel size of the image data used for the analysis for detecting the abnormal shadow candidate in the abnormal shadow detection means 106 described later does not need to be equal to the pixel size of the input image. For example, the effective pixel size of the input image is 50μ
The image data used for detecting the abnormal shadow candidate may be data obtained by thinning the input image and converting it into an effective pixel size of 100 μm. The number of gradations of the image is 1
0 bit or more is preferable, and 12 bit or more is particularly preferable. Moreover, it is not necessary to limit to a simple X-ray image, but CT or MR
It is also possible to adopt a configuration in which image data obtained from a photographing device such as I is input.

The medical image signal input to the image data input means is stored in the image data storage means 102 after the input image data is compressed if necessary. Here, as the data compression, reversible compression or irreversible compression using various methods such as known JPEG, DPCM, wavelet compression, etc. is used. Lossless compression is preferable because there is no deterioration of diagnostic information associated with data compression.

In a small-scale diagnosis, since the data amount is not so large, the medical image signal can be stored in the magnetic disk or the like as the image data storage means 102 without being compressed. In this case, data can be stored and read at an extremely high speed as compared with a magneto-optical disk. When reading images, a fast cycle time is required, so
The necessary data is also stored in the semiconductor memory.

<(2) Classification> The pixel size of the medical image signal used in the analysis for the shadow candidate detection used in the classification processing by the classification means 103 does not need to be equal to the pixel size of the input image. The effective pixel size of the input image is set to 50 μm, and the medical image signal used for shadow candidate detection is processed by thinning the input image to obtain an effective pixel size of 100 μm.
You may use what was converted into m. The number of gradations of the image is preferably 10 bits or more, and particularly preferably 12 bits or more. Also, CT need not be limited to simple X-ray images.
It is also possible to adopt a configuration for inputting a medical image signal obtained from an imaging device such as an MRI or MRI.

The images stored in the image data storage means 102 are sequentially read out and classified by the classification means 103 while being subjected to image processing (FIG. 1S2). Classification means 10
Reference numeral 3 reads the medical image signal stored in the image data storage means 102, performs gradation processing, frequency processing, dynamic range compression processing, multi-frequency processing, etc., and then classifies the mammary gland and the like. The gradation processing is described in, for example, Japanese Patent Publication No. 6-44796 and Japanese Patent Publication No. 5-69347. The frequency enhancement processing is described in JP-B-62-62373 and JP-B-62-62376. The dynamic range compression processing is described in Japanese Patent Registration No. 266318. Furthermore, multi-frequency processing is disclosed in Japanese Patent Laid-Open No. 10-7539.
No. 5 publication. In this case, the classification unit 103 performs a process of changing the image processing according to the state of the mammary gland.

As a method of classifying the mammary gland, for example, the mammary gland is classified based on the density of the pectoral muscle, the variation of the mammary gland area is histogrammed, and the proportion of the mammary gland in the breast is determined. In this way, the ratio of the mammary glands to the breast is obtained and classified into a plurality of stages.

As an example of classification based on the actual density of the mammary gland,
As an example, it can be classified as follows. It is fatty, the mammary glands retract, and the breast is almost completely replaced with fat. If the lesion is within the imaging range, detection is easy (Fig. 3 (a)). Shows the mammary gland scattered, and the mammary gland parenchyma is scattered in the breast replaced with fat. The detection of the lesion is relatively easy (FIG. 3 (b)). Shows a non-uniform concentration, in which fat is mixed in the mammary gland parenchyma, resulting in a non-uniform concentration. There is a risk that the lesion will be hidden by the normal mammary gland (Fig. 3 (c)). Is most common in young women and has mammary glands almost all over the breast. The mammary gland regresses with aging, and the mammary gland becomes almost absent as shown in (a) (Fig. 3).
(D)).

Then, using the classification result of the classifying means 103, the processing characteristic determining means 104 determines the frequency characteristic at the time of processing in the multiple frequency processing means 105 described later for each classification (FIG. 1S3). As a result, it is possible to perform processing so as to obtain an appropriate image according to the classification such as the degree of mammary gland regression, and it is possible to support image diagnosis.

<(3) Multi-frequency processing> In FIG.
Reference numeral 105a denotes an unsharp image signal creating unit that creates an unsharp image signal from the original image signal; 105b, a conversion processing unit that adds a converting process to the unsharp image signal created by the unsharp image signal creating unit 105a; A difference processing unit for obtaining the difference between the signal and the image signal after the conversion process and the difference between the unsharp image signal and the image signal after the conversion process, and 105d adds the difference image signal obtained by the difference processing unit 105c. It is an addition processing unit.

The non-sharp image signal generation unit 105a, the conversion processing unit 105b, the difference processing unit 105c, and the addition processing unit 105d can be realized by hardware or software.

That is, in the multi-frequency processing means 105, based on the characteristics determined by the processing characteristic determining means 104, the conversion processing portion 105b performs a plurality of conversion processing operations on the unsharpened image created by the unsharpened image creating portion 105a. Conversion processing is performed on the non-sharp image signal in the frequency band. Then, the difference processing unit 105c generates a difference between the non-sharp image and the image signal after the conversion process, and the addition processing unit 105d adds the difference image signal obtained by the difference, thereby executing the multiple frequency processing. Then, a processed image signal is generated.

The operation of the apparatus thus configured will be described below. Non-sharp image signal creation unit 105
a creates an unsharp image signal for the original image signal using, for example, a pyramid algorithm. The unsharp image signal generation unit 105a obtains unsharp image signals in a plurality of frequency bands having different frequency characteristics. Conversion processing unit 105
In step b, image signal conversion processing is performed on the obtained non-sharp image signal. As this image signal conversion processing, any known image signal conversion processing technology can be used.

The difference processing section 105c obtains the difference between the converted image signal and the original image signal and the non-sharp image signal and the converted image signal thus obtained. Here, the obtained difference image signal is the difference between the unsharp image signal or the original image signal in the adjacent frequency bands and the unsharp image signal after conversion. Next, the addition processing unit 105d adds the difference signals obtained by the difference processing unit 105c to obtain a high frequency component signal.
By adding the high-frequency component signal thus obtained to the original image signal, a processed image signal is obtained.

The multi-frequency processing executed by the multi-frequency processing means 105 includes the following (a) to (j) in the present embodiment. (A) A process of emphasizing a non-sharp image signal having a frequency component of a frequency band including a lesion is performed. By this process,
This makes it easy to distinguish the abnormal shadow that is the detection target from normal tissue, and it becomes easy to detect candidates for abnormal shadows.

(B) A process for suppressing an unsharp image signal having a frequency component other than a frequency band including a lesion is performed.
By this processing, it becomes easy to distinguish the abnormal shadow that is the detection target from the normal tissue, and the candidate of the abnormal shadow is easily detected.

(C) A process of emphasizing a non-sharp image signal having a frequency component in a frequency band including a lesion and a process of suppressing an unsharp image signal having a frequency component other than the frequency band including a lesion. Give. By this processing, it becomes easier to distinguish the abnormal shadow that is the detection target from the normal tissue, and it becomes easy to detect the candidate of the abnormal shadow.

(D) In the above (a) to (c), processing for suppressing low frequency frequency components included in a plurality of frequency bands to be processed is performed. By this processing, in the region where the influence of the background trend is strong, the characteristics change depending on the position where the lesion exists, so suppression of the background trend is an extremely important issue. In such a case, by suppressing the low-frequency component that includes the background trend, it becomes easier to distinguish the abnormal shadow that is the target of detection from normal tissue, and it becomes easier to detect abnormal shadow candidates. .

(E) In the above (a) to (c), as the conversion processing, low frequency components and high frequency components are suppressed,
The intermediate frequency component is emphasized. Here, the low frequency component refers to a frequency component that includes a background trend, and the high frequency component refers to a high frequency component that includes noise and the like. Then, according to this processing, since the abnormal shadow exists in the frequency band between them, the frequency components other than the abnormal shadow are suppressed, and the frequency components in which the abnormal shadow may exist are emphasized to detect the abnormal shadow. It leads to improvement of processing performance.

(F) In the above (a) to (e), when the medical image signal is a mammogram or a plain chest X-ray image and the abnormal shadow to be detected is a tumor shadow, 0.01
A process of suppressing low frequency components below 6 lp / mm and high frequency components above 0.1 lp / mm is performed. With this process, the diameter is 5
mm ~ 30 mm of the component of the tumor appears in the image,
Easy to detect.

(G) In the above (a) to (e), the frequency band to be suppressed or emphasized is determined based on at least one of the subject region and the type of abnormal shadow, and the process is performed. By this processing, it is possible to create an image according to the detection purpose, it is possible to perform multi-frequency processing suitable for the object part used for the determination or the type of abnormal shadow, and it is easy to detect candidates for abnormal shadow. become. (H) A process depending on at least one of the density of the medical image signal and the pixel value is performed. By this processing, only the density or pixel value at which an abnormal shadow is likely to appear is emphasized, or the density or pixel value at which contrast is relatively easy to be suppressed is suppressed, and the density or pixel value at which contrast is hard to be emphasized are emphasized. By doing so, it is possible to detect lesions in any concentration range with similar criteria, which makes it easy to distinguish the abnormal shadow that is the detection target from normal tissue, and it is easy to detect candidates for abnormal shadows. Become.

(I) In (g) above, when the medical image signal is a mammogram, a process for suppressing the low density or low pixel value enhancement degree of the non-sharp image signal having a low frequency component is performed. By this processing, the background trend of the high density portion (high pixel value) close to the skin line is strong in the mammogram. In such a case, by suppressing the emphasis degree of the low-frequency part of low density (low pixel value), overcorrection is prevented, and it becomes easier to distinguish the abnormal shadow that is the detection target from normal tissue. , It becomes easy to detect abnormal shadow candidates.

(J) In (a) to (c) or (g) above, when the medical image signal is a mammogram, according to the classification result regarding the regressed state of the mammary gland in the classification means 103,
Determine the frequency band to suppress or enhance, the concentration to suppress or enhance, or the pixel value to suppress or enhance,
Apply processing. This processing enables multi-frequency processing suitable for the classified result, and facilitates detection of abnormal shadow candidates. For example, for an image in which a thick mammary gland is widely spread, there is a strong possibility that an abnormal shadow is present in the thick mammary gland, so it is difficult to provide contrast, and the degree of emphasis is increased or the mammary gland is mostly replaced with adipose tissue. In such an image, since the contrast is easily added, the detection rate can be improved by suppressing the emphasis degree.

FIG. 5 is a characteristic diagram showing an example of frequency characteristics of the multiple frequency processing in the multiple frequency processing means 105. Here, the horizontal axis represents the spatial frequency, and the vertical axis represents the response (degree of emphasis or suppression). Here, the unit of the horizontal axis, cycle / mm, is synonymous with lp / mm. There is a frequency band of ~ in order from the highest frequency. For example, the characteristic of is that the frequency band in the vicinity is emphasized by combining ~, or the frequency band in the vicinity is emphasized by combining ~. The thing is the characteristic.

FIG. 6 shows an example of a state in which the multi-frequency processing as described above is performed. Here, FIG. 6A is an example in which the medical image signal is displayed as it is, and FIG. 6B is the above-mentioned FIG.
6A shows a profile of a broken line portion between points A and B in FIG. 6A, FIG. 6C shows an image by the processed image signal converted by the multiple frequency processing, and FIG.
The profile of the broken line part between point C-point D of (c) is shown.

As is clear from FIG. 6, the multi-frequency processing of this embodiment proves that the features of the tumor shadow are emphasized as shown in FIG. 6 (d). There is.

<(4) Abnormal Shadow Detection> With respect to the processed image signal subjected to the multiple frequency processing by the multiple frequency processing means 105, the abnormal shadow detection means 106 detects an abnormal shadow candidate (S5 in FIG. 1). That is, computer diagnosis support (Computer
-Aided Diagnosis (CAD) is executed.

The abnormal shadow detection means 106 analyzes the processed image signal processed by the multi-frequency processing means 105 to detect microcalcification clusters and tumor shadows as shown in FIG. 7, for example. FIG. 7 is a diagram showing an example of a main image on the display screen displayed on the display as a photograph of a halftone image in one embodiment of the present invention.

FIG. 7A shows an example of microcalcification clusters. The clustering of microcalcifications is one of the key findings for finding early-stage breast cancer, as it is likely to be an early cancer. On the mammogram, it is displayed as a small white shadow with a roughly conical structure. Further, the tumor shadow shown in (b) is displayed as a mass having a certain size, and a whitish and round shadow close to a Gaussian distribution on the mammogram.

<(5) Result display> Image output control means 10
Reference numeral 7 denotes an abnormal shadow candidate detected by the abnormal shadow detection means 106 when the image is displayed on the image display means 108 (S6 in FIG. 1) or when printed out by the image print means 109. Display in a state of being overlaid on the display, display of the abnormal shadow candidates detected by the abnormal shadow detecting means 106 in a state of not being overlaid on the display of the processed image signal, and of abnormal shadows detected by the abnormal shadow detecting means 106 A display of the candidate superimposed on the display of the processed image signal,
It is desirable to display the abnormal shadow candidate detected by the abnormal shadow detecting means 106 by either of the display in a state where it does not overlap the display of the processed image signal. In the above items (1) to (3), it is also preferable that either or both of the image based on the processed image signal and the image based on the medical image signal can be selected and displayed in a state of being overlapped with the abnormal shadow candidate.

In the present invention, the detected abnormal shadow candidate is not superposed on the display of the processed image signal (or medical image signal) or on the display of the processed image signal (or medical image signal). Since it is displayed in one or both of the states, the displayed image facilitates detection of abnormal shadow candidates.

As a result display, arrows, squares (□), triangles (Δ), etc. may be drawn on the abnormal shadows on the image (see FIG. 8), and the outline of the abnormal shadows on the image. Lines may be written (see FIG. 9), and the abnormal shadow detection means 10
The shape of the abnormal shadow detected by 6 may be output as it is.

If the candidate for the abnormal shadow is not superimposed on the display of the processed image signal, a shoe of the subject is created outside the display of the processed image signal, and an abnormality occurs at a position roughly aligned with the actual subject. You may make it output the result of a shadow candidate.

Further, for example, when the image reader displayed on the image display means 108 clicks on a mark such as an arrow displayed as an abnormal shadow with the mouse, the abnormal shadow detection means 106 becomes abnormal. The main indicators judged to be displayed. Alternatively, an index may be displayed in a list for each result that CAD is output as an abnormal shadow.

Although the above description is of the embodiment as an abnormal shadow detection apparatus, it can be applied to the embodiment of an image output apparatus for film output or CRT display.

That is, as an example of the embodiment of the image output device, the medical image signal from the subject is subjected to conversion processing into the non-sharp image signal of a plurality of frequency bands, and the non-sharp image and the post-conversion processing are performed. When the processed image signal is generated by adding the difference image signals obtained by the difference of the image signals to output the image, as the conversion process,
(A) a process of emphasizing a non-sharp image signal having a frequency component in a frequency band including a lesion; and (b) a process of suppressing a non-sharp image signal having a frequency component other than a frequency band including a lesion. At least one is applied, and an image based on the processed image signal subjected to such conversion processing is output.

In this way, the processing for emphasizing the non-sharp image signal having the frequency component of the frequency band including the lesion is performed, and / or the non-sharp image signal having the frequency component other than the frequency band including the lesion is displayed. An image in which a lesion is emphasized can be presented by performing a suppressing process and displaying an image of the result of such a process on a CRT display or outputting to a film, and improvement in diagnostic performance can be expected.

As the processing for suppressing the non-sharp image signal having the frequency component other than the frequency band including the lesion, the processing for simultaneously suppressing the low frequency component corresponding to the background trend and the high frequency component corresponding to the noise is performed. Preferably there is.

According to such an image output apparatus, for example, in the case of a mammogram, if the target lesion is a tumor shadow,
There is a high possibility that a tumor shadow exists in the intermediate frequency component between the low frequency component corresponding to the background trend and the high frequency component corresponding to noise or mammary gland, and the low frequency component and the high frequency component are suppressed at the same time. Designing frequency characteristics that emphasize frequency components is effective for emphasizing lesions. By presenting this image in which the lesion is emphasized to the image interpretation, improvement in image interpretation performance can be expected. The image output device in this case is C
This corresponds to an RT display, a liquid crystal display, a film output device, or the like.

The above-described embodiment is an example of the present invention, and the present invention is not limited to this configuration.

[0089]

According to the present invention, it is possible to provide an abnormal shadow detection device and an image output device that can easily detect an abnormal shadow to be detected and a normal tissue in a easily distinguishable state.

[Brief description of drawings]

FIG. 1 is a flowchart showing an example of an embodiment of the present invention.

FIG. 2 is a block diagram showing an embodiment of the present invention.

FIG. 3 is an explanatory diagram showing an embodiment of the present invention.

FIG. 4 is a block diagram showing an embodiment of the present invention.

FIG. 5 is an explanatory diagram showing an embodiment of the present invention.

FIG. 6 is an explanatory view showing a display screen showing a state of one embodiment of the present invention on a display with a photograph of a halftone image.

FIG. 7 is a diagram showing an example of a detected image, and is a diagram showing a photograph of a halftone image as an example of a main image on a display screen displayed on a display in an embodiment of the present invention.

FIG. 8 is a diagram showing an example of a display screen displayed on the display in a photograph of a halftone image in one embodiment of the present invention.

FIG. 9 is a diagram showing an example of a display screen displayed on the display as a photograph of a halftone image in one embodiment of the present invention.

[Explanation of symbols]

101 image data input means 102 image data storage means 103 classification means 104 processing characteristic determining means 105 multiple frequency processing means 106 Abnormal shadow detection means 107 image output control means 108 image display means 109 image printing means

Continued front page    F-term (reference) 4C093 AA01 AA26 CA18 CA21 DA06                       FF04 FF08 FF16 FF17 FF30                       FF34 FF36 FG13 FG14                 5B057 AA08 BA03 CA02 CA08 CA12                       CA16 CB02 CB08 CB12 CB16                       CE03 CE04 CE08 CE15 CG09                       CH09 DA08 DB02 DB05 DB09                       DC32 DC36                 5L096 AA03 AA06 BA03 BA06 DA01                       EA06 FA26 GA08 MA03

Claims (13)

[Claims] 1. A difference obtained by subjecting a medical image signal obtained from a subject to conversion processing of a non-sharp image signal in a plurality of frequency bands, and obtaining a difference between the non-sharp image and the image signal after the conversion processing. A multiple frequency processing means for generating a processed image signal by adding the image signals, and an abnormal shadow detecting means for detecting an abnormal shadow using the processed image signal obtained by the multiple frequency processing means, The abnormal frequency detection device, wherein the multiple frequency processing means performs, as the conversion processing, processing for emphasizing a non-sharp image signal having a frequency component of a frequency band including a lesion. 2. A difference obtained by performing a conversion process on a non-sharp image signal in a plurality of frequency bands with respect to a medical image signal obtained from a subject, and obtaining a difference between the non-sharp image and the image signal after the conversion process. A multiple frequency processing means for generating a processed image signal by adding the image signals, and an abnormal shadow detecting means for detecting an abnormal shadow using the processed image signal obtained by the multiple frequency processing means, The abnormal frequency detection device, wherein the multiple frequency processing means performs a process of suppressing an unsharp image signal having a frequency component other than a frequency band including a lesion, as the conversion process. 3. A difference obtained by subjecting a medical image signal obtained from a subject to conversion processing of non-sharp image signals in a plurality of frequency bands, and obtaining a difference between the non-sharp image and the image signal after the conversion processing. A multi-frequency processing means for generating a processed image signal by adding the image signals, and an abnormal shadow detection means for detecting an abnormal shadow using the processed image signal obtained by the multi-frequency processing means, The multi-frequency processing means performs, as the conversion processing, processing for emphasizing a non-sharp image signal having a frequency component in a frequency band including a lesion, and a non-sharp image having a frequency component other than the frequency band including a lesion. An abnormal shadow detection device, characterized in that processing for suppressing a signal is performed. 4. The multiple frequency processing means, as the conversion processing, performs processing for suppressing low frequency frequency components included in a plurality of frequency bands to be processed, according to any one of claims 1 to 3. An abnormal shadow detection device according to claim 1. 5. The multiple frequency processing means suppresses low frequency components and high frequency components and emphasizes intermediate frequency components as the conversion processing.
The abnormal shadow detection device according to claim 3. 6. When the medical image signal is a mammogram or a plain chest X-ray image and the abnormal shadow for detection is a tumor shadow, the multi-frequency processing means sets the conversion processing to 0.
The abnormal shadow detection apparatus according to any one of claims 1 to 5, wherein processing is performed to suppress low-frequency components lower than 016lp / mm and high-frequency components lower than 0.1lp / mm. 7. The frequency band to be suppressed or emphasized in the multiple frequency processing means is determined based on at least one of a subject part and an abnormal shadow type. An abnormal shadow detection device according to claim 1. 8. A difference obtained by performing a conversion process on a non-sharp image signal in a plurality of frequency bands with respect to a medical image signal obtained from a subject, and obtaining a difference between the non-sharp image and the image signal after the conversion process. A multiple frequency processing means for generating a processed image signal by adding the image signals, and an abnormal shadow detecting means for detecting an abnormal shadow using the processed image signal obtained by the multiple frequency processing means, The abnormal frequency detection device, wherein the multi-frequency processing means performs, as the conversion processing, processing depending on at least one of the density and the pixel value of the medical image signal. 9. When the medical image signal is a mammogram, the multi-frequency processing means performs, as the conversion processing, an enhancement degree of low density or low pixel value of an unsharp image signal having a low frequency component. The abnormal shadow detection apparatus according to claim 8, wherein a suppressing process is performed. 10. When the medical image signal is a mammogram, the medical image signal includes a classifying unit that classifies the medical image signal according to a retraction state of the mammary gland, and the multi-frequency processing unit determines a result classified by the classifying unit. 9. A frequency band to be suppressed or emphasized, a density to be suppressed or emphasized, or a pixel value to be suppressed or emphasized is determined in accordance with the above, according to any one of claims 1 to 3 or claim 8. Abnormal shadow detection device. 11. A display device for displaying at least one of a medical image signal obtained from a subject and the processed image signal obtained by processing by the multiple frequency processing means, the abnormal shadow detection means. The abnormal shadow candidate detected by the state of superimposing on the display of the medical image signal or the processed image signal, or the state of not superimposing on the display of the medical image signal or the processed image signal, at least one of The display is made in a state.
The abnormal shadow detection device according to claim 10. 12. A difference obtained by performing a conversion process on a non-sharp image signal in a plurality of frequency bands with respect to a medical image signal obtained from a subject, and obtaining a difference between the non-sharp image and the image signal after the conversion process. Multiple frequency processing means for generating a processed image signal by adding image signals, and image output means for outputting an image based on the processed image signal converted by the multiple frequency processing means, and The multiple frequency processing means performs, as the conversion processing, processing for emphasizing an unsharp image signal having a frequency component in a frequency band including a lesion, or non-owning a frequency component other than a frequency band including a lesion. At least one of a sharp image signal suppressing process and the image output means is based on the processed image signal converted by the multiple frequency processing means. An image output device, which outputs an image based on the image. 13. The process of suppressing an unsharp image signal having a frequency component other than the frequency band including the lesion is a process of simultaneously suppressing a low frequency component corresponding to a background trend and a high frequency component corresponding to noise. The image output device according to claim 12, wherein the image output device is provided.