JP2009070074A - Image processor and image processing program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform reproduction while securing continuity in diagnosis using the same image. <P>SOLUTION: This image processor has: a storage means for storing a radiation image and a prescribed image processing condition; a display area selection means for selecting a display area of the radiation image; an image processing means performing image processing of the radiation image under the prescribed image processing condition; an image display means for displaying the display area selected by the display area selection means, which is the radiation image executed with the image processing by the image processing means; an image processing condition adjustment means for adjusting the image processing condition under which the image processing is executed by the image processing means; and a control means for making the storage means store the image processing condition in the image processing in each radiation image, making the image processing means execute the image processing under the image processing condition stored in the storage means about the radiation image performed with the image processing before, and performing control to display the radiation image performed with the image processing on the image display means. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an image processing apparatus and an image processing program for processing a radiographic image, and more specifically, based on the image processing adjustment amount such as image density and contrast applied by the user, the same image from the next time is used. The present invention relates to an image processing apparatus and an image processing program that can provide an image processing apparatus and an image processing program that can be reproduced while ensuring continuity in diagnosis.

  In recent years, an apparatus capable of directly capturing a radiographic image as a digital image has been developed. For example, as a device for detecting a radiation dose applied to a subject and obtaining a radiographic image formed in accordance with the detected dose as an electrical signal, a method using a detector using a stimulable phosphor is disclosed in JP Many publications such as 55-12429 and JP 63-189853 are disclosed.

  In such a device, the stimulable phosphor is applied to the sheet-like substrate by fixing or vapor deposition or the like, and the radiation transmitted through the subject is irradiated by the imaging device to irradiate the stimulable phosphor. Absorb.

  Thereafter, in a reading device called a reader, the stimulable phosphor is excited by light or thermal energy, and thereby the radiation energy accumulated by the absorption by the stimulable phosphor is emitted as fluorescence. Is subjected to photoelectric conversion to obtain an image signal.

  On the other hand, a charge corresponding to the intensity of irradiated radiation is generated in the photoconductive layer, the generated charge is accumulated in a plurality of capacitors arranged two-dimensionally, and the accumulated charges are taken out. A radiation image detection apparatus has been proposed.

  Such a radiation image detection apparatus uses what is called a flat panel detector (FPD). As described in JP-A-9-90048, this type of FPD includes a phosphor that emits fluorescence corresponding to the intensity of irradiated radiation, and fluorescence emitted from the phosphor directly or through a reduction optical system. Known is a combination of a photodiode that receives light and performs photoelectric conversion, or a combination of photoelectric conversion elements such as a CCD. In addition, as described in Japanese Patent Laid-Open No. 6-342098, there is also known one that directly converts irradiated radiation into electric charges.

  In these radiological image detection apparatuses, image processing such as gradation conversion processing and edge enhancement processing is generally performed on an acquired image so as to be an image suitable for diagnosis. On the other hand, it is cumbersome to manually perform these image processing after image acquisition.

  Therefore, in these devices, image processing conditions that seem to be optimal are set in advance according to the imaging region such as the head, chest, and abdomen, and the imaging direction, and the conditions are specified at the time of image acquisition, and the image is automatically displayed. It is the structure which performs a process.

  In addition, the distribution state of the image signal in the region of interest is determined for each image, and the gradation processing condition is determined based on the distribution state, thereby being influenced by the good distribution state of the image signal in the region of interest. The following Patent Document 1 describes that the adjustment processing conditions are not inappropriate.

Patent Document 2 below describes image processing appropriate for displaying a partial area in addition to displaying the entire area.
JP-A-8-331358 (first page, FIG. 1) JP 2006-68038 A (1st page, FIG. 1)

  In the above Patent Document 1, when the image processing condition is manually adjusted for the region of interest, the adjusted gradation processing condition is not stored, and only the adjusted image is stored. Yes. Therefore, when there are a plurality of examination sites in one image, it is not possible to obtain a diagnostic image that has been subjected to image processing optimal for diagnosis of each of the examination sites.

  Further, in Patent Document 2 described above, it is possible to obtain a diagnostic image that has been subjected to optimal image processing for diagnosis of each examination site by performing optimal image processing on an arbitrary designated area and displaying the enlarged image. it can.

  However, when a diagnosis is performed on an image of a selected area, even if the image is referred to again later, the same area as the previous diagnosis image cannot always be displayed immediately. In other words, if an image subjected to optimized image processing is displayed in the selected area, the image processing conditions are different from the previous diagnosis of the lesion, thus ensuring continuity of diagnosis. It may not be possible, and it may take time to properly diagnose the lesion.

  Especially in small clinics, etc., there is a limit to the size of the monitor that can display the image, and the entire image may not be displayed, so that the area selected in the previous diagnosis can be easily reached. It is desired.

  In addition, when the entire image is displayed, fine details may not be displayed finely due to the number of pixels of the monitor, and a device that can easily reach the area selected in the previous diagnosis is desired. Yes.

  The present invention has been made in view of the problems as described above. When an image area is selected and image processing parameter adjustment is performed on the selected area, the same image from the next time is used. An object of the present invention is to provide an image processing apparatus and an image processing program that can be reproduced while ensuring continuity in diagnosis.

That is, the above-described problems can be solved by the inventions listed below.
(1) The invention according to claim 1 is an image processing apparatus for processing a radiographic image having a signal corresponding to an irradiation dose of radiation that has passed through a subject, and a display area selection unit that selects a display area of the radiographic image Image processing condition adjusting means for setting an image processing condition for the display area selected by the display area selecting means, and image processing of the radiation image based on the image processing condition set by the image processing condition adjusting means Image processing means, image display means for displaying the radiation image, storage means for storing the radiation image and the image processing condition in association with each other, and the radiation image stored in the storage means in the image display means When displaying, the entire radiographic image including the area selected by the display area selecting means is subjected to image processing conditions stored in association with the radiographic image. An image processing apparatus characterized by comprising a control means for controlling so as to be displayed on the image display means performs image processing by the image processing means Zui.

  (2) In the invention according to claim 2, the control means stores the position information of the display area for each radiation image in the storage means, and displays the radiation image that has been subjected to the previous image processing. The image processing apparatus according to claim 1, wherein control is performed so that the position of the display area is displayed together.

  (3) In the invention according to claim 3, when the control means stores the position information of the display area for each radiographic image in the storage means, and displays the radiographic image that has been subjected to the previous image processing, The image processing apparatus according to claim 1, wherein the image processing device is controlled to display the radiation image in the display area.

  (4) In the invention according to claim 4, the control means causes the storage means to store a final image processing condition at the end of processing in the image processing for each radiation image, and the radiation image that has been subjected to image processing before. The image processing means is caused to execute image processing under the image processing conditions stored in the storage means, and the radiographic image subjected to the image processing is controlled to be displayed on the image display means. An image processing apparatus according to any one of claims 1 to 3.

  (5) The invention according to claim 5 is an image processing program for processing a radiographic image having a signal corresponding to an irradiation dose of radiation that has passed through the subject, and a display area selecting means for selecting a display area of the radiographic image Image processing condition adjusting means for setting image processing conditions for the display area selected by the display area selecting means, and image processing for processing the radiation image based on the image processing conditions set by the image processing condition adjusting means Means for displaying the radiation image, storage means for storing the radiation image and the image processing condition in association with each other, and displaying the radiation image stored in the storage means on the image display means. , Based on the image processing conditions stored in association with the radiographic image for the entire radiographic image including the area selected by the display area selecting means. An image processing program characterized by operating the control means computer as, for controlling to display on said image display means performs image processing by the image processing unit Te.

According to the present invention, the following effects can be obtained.
(1) In the invention described in claim 1, when obtaining an image suitable for diagnosis with respect to a radiographic image having a signal corresponding to the radiation dose transmitted through the subject, image processing of the radiographic image for the selected region If the conditions are stored and the radiation image is read again, the entire image including the selected area is subjected to image processing under the stored image processing conditions when the image was processed previously. To display.

  As a result, by performing image processing on the entire image including the selected area based on the adjustment amount of the image processing condition of the area selected last time, the same image processing conditions as the previous time can be reproduced and selected in the previous diagnosis. Thus, it is possible to accurately diagnose a lesion or the like in an area that has been enlarged and displayed with continuity from the previous diagnosis.

  (2) In the invention described in claim 2, when the radiographic image subjected to the previous image processing is subjected to image processing under the previous image processing conditions and displayed, the position of the display area selected last time is also displayed. As a result, not only the previous image processing can be reproduced, but also the previous selected area can be reproduced. This makes it possible to easily restart the previous diagnosis work.

  (3) In the invention described in claim 3, when the radiographic image subjected to the previous image processing is subjected to image processing under the previous image processing conditions and displayed, the display area selected last time is enlarged and displayed as in the previous time. As a result, not only the previous image processing can be reproduced, but also the previous selected area can be reproduced as it is. This makes it possible to easily restart the previous diagnosis work.

  (4) In the invention according to claim 4, when obtaining an image suitable for diagnosis with respect to a radiographic image having a signal corresponding to the radiation dose transmitted through the subject, the final image at the end of processing in the previous image processing is obtained. When the radiation image is read out again, the entire image including the selected area is imaged under the stored image processing condition when the image processing was previously performed. Process and display.

  As a result, by performing image processing on the entire image based on the adjustment amount of the image processing condition of the area selected at the end of the previous time, the same image processing conditions as the previous time can be reproduced and selected in the previous diagnosis. Thus, it is possible to accurately diagnose a lesion or the like in an area that has been enlarged and displayed with continuity from the end of the previous diagnosis.

  (5) In the invention according to claim 5, when obtaining an image suitable for diagnosis with respect to a radiographic image having a signal corresponding to the radiation dose transmitted through the subject, image processing of the radiographic image for the selected region is performed. If the conditions are stored and the radiation image is read again, the entire image including the selected area is subjected to image processing under the stored image processing conditions when the image was processed previously. To display.

  As a result, by performing image processing on the entire image based on the adjustment amount of the image processing condition of the previously selected area, the same image processing condition as the previous time can be reproduced, and the image is selected and enlarged in the previous diagnosis. It is possible to accurately diagnose a lesion or the like in an area with continuity from the previous diagnosis.

The best mode for carrying out the present invention will be described below in detail with reference to the drawings.
BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of an image processing apparatus and an image processing program of the best mode for carrying out the present invention will be described. Note that the present invention is not limited thereby.

  Note that each means of the embodiment of the present embodiment can be configured by hardware, firmware, or software. For this reason, FIG. 1 is shown as a functional block diagram along the processing procedure of each step, each means, and each routine.

Moreover, FIG. 1 which is this functional block diagram can also be used as a flowchart for understanding the embodiments of the image processing apparatus and the image processing program.
Hereinafter, the configuration and operation (processing) of the present embodiment will be described in detail while being classified into (1) to (7) after the entire description.

<Overall configuration and processing flow>
overall structure:
The radiographic image capturing apparatus 10, the radiographic image input apparatus 20, and the image processing apparatus 100 are connected as shown in FIG.

  Note that the image processing apparatus 100 of this embodiment is an apparatus used in a small-scale facility such as a personal clinic or a small clinic, and image adjustment and interpretation / diagnosis are performed on the image processing apparatus 100 as a viewer. It is made at the same time.

In this embodiment, an operator such as a doctor who operates the viewer is referred to as a user in the following description.
The image processing apparatus 100 includes a control unit 101, an image display unit 105, an image display change unit 110, an image processing condition setting unit 120, a parameter storage unit 130, an image processing condition adjustment unit 140, an adjustment information storage unit 150, a parameter change. The means 160 is configured as shown in FIG.

  Note that each means in the image processing apparatus 100 in FIG. 1 is a constituent element of the image processing apparatus 100, but also constitutes each step of the image processing method and each routine of the image processing program. The image processing apparatus 100 described above can be configured by combining a CPU, a memory, and the like with a processing program, but can also be configured using a programmable gate array.

Process flow:
In the radiographic image input device 20, image data obtained by radiography in the radiographic image capturing device 10 is acquired. Each acquired image data is assigned an image number as identification information, and is transmitted to the control means 101 of the image processing apparatus 100.

  The control unit 101 creates a reduced image for image processing from the image data acquired by the radiation image input device 20. Then, the control unit 101 sends a reduced image for image processing to the image processing condition setting unit 120.

  Further, the control unit 101 acquires information such as an imaging region or an imaging direction by inputting from a user interface such as the operation input unit 107 or analyzing a reduced image using an image analysis program. This is sent to the condition setting means 120.

  The operation input unit 107 corresponds to various user interfaces such as a keyboard, a pointing device, and a touch panel on the image display unit 105, and operation information obtained by being operated by the user is transmitted to the control unit 101.

  The control means 101 constitutes an image processing means, and performs image processing on the image data using the image processing conditions determined by the image processing condition setting means 120 described later. The processed image that has been subjected to image processing is displayed on the image display means 105, or is output via a network, a signal cable, or the like (not shown), output to a film, or displayed on a diagnostic monitor.

  On the other hand, the control unit 101 transmits the image processing condition determined by the image processing condition adjusting unit 140 and the image processing condition set by the image processing condition setting unit 120 to the adjustment information storage unit 150. In addition, the control unit 101 transmits an image display area change request or a black and white reverse display request instructed by the image display change unit 110 to the adjustment information storage unit 150.

  Returning to FIG. 1, the image processing condition adjusted by the image processing condition adjusting unit 140 and transmitted from the control unit 101 is associated with the image number assigned to the image data in the image processing condition storage unit 151. Remembered. In addition, regarding the image display area change request and the black / white inverted display request input by the image display changing unit 110 when the image processing condition is adjusted by the image processing condition adjusting unit 140, the image number assigned to the image data and It is stored in the image display condition storage unit 152 in association with each other.

  Here, FIG. 6 shows the image processing parameters, the radiation image display area, and the radiation image display state stored in the adjustment information storage means 150 calibrated by the image processing condition storage means 151 and the image display condition storage means 152. It explains using.

  FIG. 6 is a schematic diagram showing a data structure of information stored in the adjustment information storage unit 150. In the adjustment information storage unit 150, for each image number 1501 assigned to a radiographic image, a pre-change image processing parameter 1502, a post-change image processing parameter 1503, a selected image size 1504, and a monochrome inversion processing flag 1505 are stored in association with each other. Has been.

  The pre-change image parameter 1502 is an image processing parameter read from the parameter storage unit 130 described later on the basis of imaging information such as an imaging region, imaging direction, and irradiated radiation intensity by the image processing condition setting unit 120. Examples of the pre-change image parameter 1502 include an output density value 1506 with respect to a predetermined input signal value, an output density contrast 1507 with respect to two predetermined input signal values, and an unillustrated enhancement frequency band.

  The post-change image processing parameter 1503 is an image processing parameter that is determined by the image processing condition setting unit 120 after the user adjusts the radiographic image displayed on the image display unit 105 while observing the radiation image with the image processing condition adjustment unit 140. This corresponds to the adjusted parameter.

  The post-change image processing parameter 1503 includes a density correction value 1508, a contrast correction value 1509, an enhancement frequency band (not shown), and the like, which are the same image processing parameters as the pre-change image parameter 1502.

  The selected image size 1504 is selected by the image display changing unit 110, which is stored when a part of the radiation image is enlarged and displayed by the image display changing unit 110 while the user observes the radiation image displayed on the image display unit 105. It is the information regarding the size of the specified area. In the present embodiment, the ratio of the enlarged display area to the original radiation image is stored, but it may be the number of pixels or the actual size.

  The black-and-white reversal processing flag 1505 is information stored when the radiographic image display is reversed by the image display changing unit 110 while the user observes the radiographic image displayed on the image display unit 105.

  The image processing condition setting unit 120 specifies necessary image processing conditions from information such as an imaging region or an imaging direction obtained from the control unit 101, and parameters necessary for setting the image processing conditions from the parameter storage unit 130. Call. In addition to the basic preset parameters saved in advance, the parameter storage means 130 also stores secondary change parameters given from the parameter change means 160 for changing or correcting the preset parameters. ing.

  The parameter storage unit 130 will be described with reference to FIG. FIG. 7 is a schematic diagram showing a data structure of information stored in the parameter storage unit 130. The parameter storage unit 130 stores a preset parameter 1302 and a change parameter 1303 in association with each imaging condition 1301 such as an imaging region, an imaging direction, and irradiated radiation intensity.

The imaging condition 1301 includes an imaging region, an imaging direction, an irradiated radiation intensity, and the like. In this embodiment, an imaging region 1304 and an imaging direction 1305 are included.
The preset parameter 1302 is a basic image processing parameter and cannot be rewritten. Examples of the preset parameter 1302 include a density value 1306 for a predetermined input signal value, an output density contrast 1307 for two predetermined input signal values, an emphasis frequency band (not shown), and the like.

  The change parameter 1303 is an image processing parameter for changing according to the user's preference when an intended radiation image cannot be obtained with the preset parameter 1302, and is an image processing parameter that can be rewritten by the parameter changing unit 160 described later. It is.

  The change parameter 1303 includes a density correction value 1308, a contrast correction value 1309, and an emphasis frequency band (not shown) that are the same image processing parameters as the preset parameter 1302.

  Returning to FIG. 1, the image processing condition setting unit 120 determines the optimum image for each image data based on the parameter and the reduced image for image processing, and also based on the adjustment parameter from the image processing condition adjustment unit 140. Determine processing conditions. Here, the image processing condition determined by the image processing condition setting unit 120 is transmitted to the control unit 101.

  The image processing condition adjustment means 140 is a means for inputting adjustment of image processing conditions for the image displayed on the image display means 105. For example, the image processing condition adjustment means 140 includes an input device such as a mouse and a keyboard (not shown) and a program for enabling these operations. .

  While confirming the processed image with the image display unit 105, the user uses the image processing condition adjustment unit 140 to adjust parameters relating to image processing such as image density, contrast, and edge enhancement. When the user performs parameter adjustment with the image processing condition adjustment unit 140, the default image processing condition is compared with the image processing condition corresponding to the changed image, and the parameter adjustment amount and the changed parameter value are determined. To do. The determined parameter is transmitted to the control means 101.

  The image processing condition storage unit 151 of the adjustment information storage unit 150 stores the parameter adjustment amount and the changed parameter value obtained by the image processing condition adjustment unit 140 for each image processing condition. In addition, when an image display area change request or a black and white reversal display request is generated by the image processing condition adjusting unit 140 or the image display changing unit 110, the image display condition storage unit 152 stores the image processing condition for each image processing condition.

  The parameter change unit 160 recalculates the change parameter 1303 for each photographing condition 1301 shown in FIG. 7 and every time a predetermined number of image processings are performed. The calculated parameters are sent to the image processing parameter storage unit 130, and image processing is performed using the parameters from the next time.

  In this embodiment, when the area selected by the image display changing unit 110 satisfies a predetermined condition, the parameter changing unit 160 is based on the adjusted parameter adjusted by the image processing condition adjusting unit 140. The parameter stored in the parameter storage unit 130 is corrected or changed.

  As described above, the touch panel on the image display unit 105, the image display change unit 110, and the image processing condition adjustment unit 140 also constitute an operation unit that receives an operation from the user.

<Details of each means, each step, each routine>
Hereinafter, the operation of the image processing apparatus 100 will be described with reference to FIG. FIG. 2 is a flowchart showing the flow of processing from acquisition to display of a radiographic image executed by the image processing apparatus 100. 3 to 4 are explanatory diagrams showing examples of display screens, and FIG. 5 is a flowchart showing processing related to display.

(1) Radiation image input (step S201):
The radiation image input device 20 detects radiation that has been captured by the radiation image capturing device 10 and transmitted through the subject, and acquires the detected radiation as an image signal. Specific examples of the configuration of the radiation image input apparatus 20 include those described in Japanese Patent Application Laid-Open Nos. 11-142998 and 2002-156716, using a stimulable phosphor plate.

  For those using a flat panel detector (FPD) as an input device, those described in Japanese Patent Laid-Open No. 6-342098 that directly convert detected X-rays into charges and obtain them as image signals, There is an indirect system described in Japanese Patent Publication No. 9-90048 in which detected X-rays are once converted into light, and then the light is received and converted into electric charges.

  In the present embodiment, the image data acquired in step S201 is handled as having a gradation number of 12 bits, that is, a value from 0 to 4095. In addition, there are some that acquire image data acquired from these apparatuses via a network. The acquired image data is transmitted to the control means 101.

(2) Acquisition part / imaging direction acquisition (step S203):
The control means 101 that has received the image data input in step S201 creates a reduced image for image processing from the received image data (step S202 in FIG. 2). This is to perform subsequent processing at high speed and reduce hardware resources necessary for computation.

The control unit 101 acquires the imaging region and the imaging direction, which are imaging conditions (step S203 in FIG. 2).
By analyzing the reduced image generated in step S202, the imaging region is identified as, for example, “chest front”, “chest side”, “finger”, “lumbar spine”, and the like. For example, an algorithm described in Japanese Patent Laid-Open No. 2003-190129 can be used for automatic recognition of an imaging region. Further, instead of analyzing the reduced image, the image may be acquired by inputting from a not-shown interface by a user or by taking a photographing order inputted at the time of photographing.

The shooting direction is acquired by a user input from an interface (not shown) or by taking a shooting order input at the time of shooting.
(3) Image processing condition setting (steps S204, S205, S206)
The image processing condition setting unit 120 searches the imaging conditions 1301 stored in the parameter storage unit 130 for those that match the imaging conditions including the imaging region and the imaging direction acquired in step S203.

Then, a preset parameter 1302 associated with the matching shooting condition 1301 is read out and set as an image processing condition.
In step S205, it is determined whether or not to automatically adjust the image processing parameter, that is, the preset parameter 1302 read in step S204. Whether or not to perform automatic adjustment is determined based on whether or not the user has previously selected an automatic adjustment mode in which image processing parameters are automatically adjusted on a setting screen (not shown) or the like. If the automatic adjustment mode has not been selected (NO in step S205 in FIG. 2), the process in step 207 is executed. When the automatic adjustment mode is not selected, image processing is always performed using the preset parameter 1302 as an image processing condition. Therefore, a radiographic image can always be diagnosed under the same image processing condition, and there are few individual differences between subjects and imaging conditions. It is official for the diagnosis of radiographic images of the imaging site. When the automatic adjustment mode is selected (YES in step S205 in FIG. 2), the image processing condition setting unit 120 includes the imaging region acquired in step S203 among the imaging conditions 1301 stored in the parameter storage unit 130. Also, a search is made that matches the shooting condition consisting of the shooting direction.

  Then, the change parameter 1303 associated with the matching shooting condition 1301 is read, and the preset parameter 1302 read in step S204 is subjected to a predetermined calculation (for example, addition or subtraction) using the change parameter 1303. The parameter is an image processing condition.

  In step S203, the control unit 101 performs image processing on the original image input in step S201 using the image processing conditions set in step S204 or step S206, that is, the image processing parameters. Then, the image data subjected to the image processing is displayed on the diagnostic monitor such as the image display means 105 from the control means 101 (step S204 in FIG. 2).

(4) Image processing condition adjustment (steps S209 and S210):
The image processing condition adjustment unit 140 that adjusts the image processing conditions includes an image display unit 105 that displays an image subjected to image processing, and an operation input unit that corrects and inputs the density, contrast, display range, and the like of the image. Is done.

  FIG. 3 shows an operation display screen 300 in the image display means 105 when adjusting image processing conditions. Here, the image processing condition adjustment unit 140 is configured as a user interface including an operation display screen 300 and a touch panel in the image display unit 105 as shown in FIG.

  Note that the operation of selecting various adjustment items can be performed by performing a click operation on the portion of the screen using a pointing device such as a mouse or a touch pen. When the image processing condition adjusting unit 140 has a touch panel, the operation can be realized by touching the part on the screen with a finger.

  First, the radiation image 301 is displayed on the image display unit 105 as a part of the display screen 300 by the control unit 101. In parallel with this, various adjustment items that support image processing (for example, display area change icon 302, density / contrast adjustment icon 303, black / white inversion designation icon 304) are displayed on the display screen of image display means 105. Is displayed in the right half of.

  While viewing the radiation image 301 or the adjustment items 302 to 304 displayed on the image display unit 105, the user changes various items 302 to 304 such as density and contrast so that his / her favorite image can be obtained.

  Here, as the adjustment of the image processing conditions, various settings for the area such as the lesion, for example, black and white inversion setting 304 for making the area such as the lesion easy to see, and the density for making the area such as the lesion easy to see. And the contrast adjustment setting 303 are executed.

  In the operation display screen 300 of FIG. 3, it is assumed that a doctor or the like operates the pointing device, selects the density / contrast icon 303, and performs an operation for changing the density or contrast for this adjustment item.

  This operation is transmitted from the image processing condition adjustment unit 140 to the control unit 101, and the control unit 101 displays a radiation image 301 that has been subjected to processing for changing density and contrast in the operation display screen 300 for the lung field region. .

  That is, every time the image processing condition is adjusted by the image processing condition adjusting unit 140, the control unit 101 receives a parameter corresponding to the adjusted image processing condition from the image processing condition setting unit 120, and again applies to the original image. Then, image processing is executed by applying parameters corresponding to the adjusted image processing conditions (step S207 in FIG. 2). Then, the image subjected to the image processing with the adjusted parameters is displayed on the diagnostic monitor such as the image display means 105 from the control means 101 (step S208 in FIG. 2).

(5) Image display condition adjustment (steps S211, S212):
The user can change image display conditions such as display area change and black / white reversal so that his / her favorite image can be obtained while viewing the radiation image 301 or the adjustment items 302 to 304 displayed on the image display unit 105. Can do.

Here, as the adjustment of the image display condition, setting of an image display range such as displaying an enlarged area such as a lesion is performed.
For example, on the operation display screen 300 in FIG. 3, it is assumed that the user operates the pointing device to select a part of the lung field region and performs the display region change 302 and determination 305 operations.

  This operation is transmitted from the image processing condition adjustment unit 140 to the control unit 101, and the control unit 101 performs a process of enlarging and displaying a partial region 306 of the selected lung field radiation image 301 over the entire image display region. Execute and display the enlarged radiation image.

At this time, the size of the area 306 is acquired based on the number of vertical × horizontal pixels, the ratio to the original image 301, or the like (step S212 in FIG. 2).
Furthermore, it is assumed that on this operation display screen, a doctor or the like operates the pointing device and performs an operation of selecting black and white reversal 304 (YES in step S211 in FIG. 2). This operation is transmitted from the image processing condition adjusting unit 140 to the control unit 101, and the control unit 101 executes a process for reversing the image in black and white and displays a black and white reversal image 401 as shown in FIG. 4 on the image display unit 105. To do. At this time, the black and white reverse display state is acquired (step S212 in FIG. 2).

  That is, every time an adjustment or instruction is added to the image display condition in the image processing condition adjusting unit 140 (YES in step S211 in FIG. 2), the control unit 101 acquires the adjusted image display condition (in FIG. 2). Step S212). Then, the image processed according to the adjusted image display condition (step S207 in FIG. 2) is displayed from the control unit 101 on a diagnostic monitor such as the image display unit 105 (step in FIG. 2). S208).

(6) Storage of image processing conditions and image display conditions (step S213):
In the adjustment information storage unit 150 that stores the parameter adjustment amount, the parameter determined in step S204 or S206 in FIG. 2 is used as the pre-change image processing parameter 1502, and the adjusted parameter added by the user in the image processing condition adjustment unit 140 is used. Each image data obtained by the radiation image input device 20 is stored in the image processing condition storage unit 151 as a changed image processing parameter 1503 in association with the image number 1501 (step S213 in FIG. 2).

  Similarly, in the adjustment information storage unit 150, the image display condition storage unit adds the image display condition added by the user in the image processing condition adjustment unit 140 in step S211 of FIG. 2 for each image data obtained by the radiation image input device 20. In 152, the size 1504 and the black and white reversal processing flag 1505 are stored (S213 in FIG. 2). That is, the image processing parameter and the display state are stored in the image display condition storage unit 152 in association with each other.

Here, the image display conditions correspond to display shapes (rectangles, circles, ellipses,...), Display ranges (start point coordinates / end point coordinates, center coordinates and radius,...), And the like.
In this case, when the image displayed by the user's operation is closed, the control unit 101 terminates the above-described various processes as having been diagnosed, and associates the image processing condition and the image display condition with the image data. The adjustment information is stored in the adjustment information storage unit 150. In this case, a common inspection number, ID, or file name may be assigned to the image processing condition, the image display condition, and the image data for association.

  In addition, inspection numbers, IDs, and file names of image processing conditions and image display conditions may be described in a predetermined area such as a header of image data. Alternatively, the image processing conditions and the image display conditions themselves may be described in a predetermined area such as a header of the image data.

  Since the image data has a large capacity, a large-capacity hard disk device (not shown) may be provided inside the image processing apparatus 100, but an image data storage device is connected to the outside of the image processing apparatus 100. It may be left.

(7) Image display (image display with reproduction of image processing):
Hereinafter, with reference to the flowchart of FIG. 5, image display accompanied by reproduction of image processing which is a feature of the present embodiment will be described.

  The user searches for a desired image from the stored images based on the patient name, examination number, ID, and the like previously associated with the image via the operation input means 107 (step S501 in FIG. 5).

  At this time, has the control unit 101 displayed the searched image data once in the image display unit 105 with the user adjusting the image display condition or the image processing condition in the past? It is determined whether or not (step S502 in FIG. 5).

  In this case, a dedicated flag may be used as to whether or not the image data has been displayed once with adjustment, but whether or not already adjusted image display conditions and image processing conditions exist. You may judge by.

  When the image data has not been displayed with adjustment by the user in the past (NO in step S502 in FIG. 5), the control unit 101 reads the image data (step S504 in FIG. 5). Then, image processing is performed by applying normal image processing conditions (step S504 in FIG. 5) and displayed on the image display means 105 (step S505 in FIG. 5).

  Here, the normal image processing conditions are image processing conditions based on various parameters determined in advance according to the part. Alternatively, it is an image processing condition in which a predetermined parameter is corrected by a past learning function. As a result, the image processing conditions are almost appropriate for each part.

  When the user has selected image data that has been displayed at least once in the past with adjustment of image display conditions and image processing conditions (YES in step S502 in FIG. 5). The control means 101 reads the image data (step S504 in FIG. 5), and further reads the image display conditions and image processing conditions corresponding to the image data from the adjustment information storage means 150 (step S507 in FIG. 5). ). In this case, the image display conditions and image processing conditions corresponding to the image data are read from the adjustment information storage unit 150 using the file name, ID, patient number, and the like of the image data. When the image display condition and the image processing condition are stored in the header of the image data, the image display condition and the image processing condition are extracted from the corresponding part such as the header.

  Then, the control means 101 executes image processing by applying the previous image processing conditions to the entire area of the read image data (step S508 in FIG. 5). In this case, even if the previous display of the image data was an enlargement of a part of the area and the image processing was performed on that part, the image processing conditions for that part were applied to the whole area. To execute image processing.

  Here, the control means 101 displays a confirmation message as to whether or not to display the previous display range on the image display means 105 based on the stored image display conditions, and inquires the user (in FIG. 5). Step S509).

  In particular, in a small clinic, the size of a monitor that can display an image is limited, and the entire image may not be displayed. Even if the entire image can be displayed, it is not fine due to the number of pixels. In some cases, the user is inquired about the entire display, the previous selection area, or the arbitrary selection area.

  When an intention display for displaying the previous display range is input from the user (YES in step S509 in FIG. 5), the control unit 101 stores the previous image stored for the image processed under the previous image processing condition. Based on the image display condition, the corresponding area is enlarged and displayed on the image display means 105 (step S510 in FIG. 5).

  Further, when the intention display indicating that the entire image is displayed is input from the user (the entire image is displayed in step S509 in FIG. 5), the control unit 101 displays the entire image image-processed under the previous image processing condition in the image display unit 105. This is displayed (step S511 in FIG. 5).

  Here, FIG. 8 is an operation display screen 800 in the image display means 105 at the time of the previous diagnosis. FIG. 9 is an operation display screen 900 in the image display means 105 when the enlarged display is performed at the time of the previous diagnosis. FIG. 10 shows an operation display screen 1000 in the image display means 105 at the time of the current diagnosis.

  That is, at the time of the previous diagnosis of the image, the user designates and enlarges an area 806 that is considered to be a lesion from the entire radiation image 801 shown in FIG. When the image is displayed after being processed under the processing conditions (FIG. 9), as shown in FIG. 10, the entire image is displayed with the entire image processed under the same conditions as the previous image processing conditions. Will be.

  For example, when the user operates the pointing device, specifies the area 806 specified in FIG. 8, selects the display area change icon 302, and performs an operation to change (enlarge) the display area for this adjustment item. To do.

  This operation is transmitted from the image processing condition adjustment unit 140 to the control unit 101, and the control unit 101 displays the radiation image 301 that has been subjected to the enlargement process in the operation display screen 900 for the designated region 806 (FIG. 9). ).

  Also, assume that the user operates the pointing device on the operation display screen 900 of FIG. 9 to select the density / contrast icon 303 and perform an operation of changing the density and contrast for this adjustment item. In other words, it is assumed that the radiographic image 901 is enlarged as shown in FIG. 9 and image processing with enhanced contrast is executed as a suitable state for the enlarged region of FIG. In this case, in the enlarged area of FIG. 9, the contrast is enhanced and the lesioned part is easily identified.

  Then, when the same image is read out next time, the control unit 101 applies the same image processing condition as the processing for changing the density and contrast for the previous region 806 for the entire image, The radiation image 1001 is displayed in the operation display screen 1000 (see FIG. 10). That is, the entire image is displayed as a radiation image 1001 as shown in FIG. 10 in a state where image processing for density and contrast similar to those in FIG. 9 is executed.

  Therefore, although the image processing of the entire image is not in an appropriate state, the image processing is performed in a state that the user himself considers appropriate for a part of the region (region of interest) focused on at the time of the previous diagnosis. Although it is displayed, it becomes obvious at a glance which part was focused on last time.

  Even if it is not obvious, if you look around the entire image and there is a part that has been subjected to appropriate image processing in a part of the area, it is determined that the part is the region of interest that you focused on last time. You can also In the specific example of FIG. 10, the density and contrast are adjusted at the time of the previous diagnosis, and the contrast is excessively emphasized in the entire lung field image, but the contrast is in an appropriate state near the bronchus. For this reason, it is remembered that the vicinity of the bronchus was interpreted in the previous diagnosis, and the continuity of the diagnosis is ensured.

  Further, when an intention display for displaying an arbitrary area is input from the user (arbitrary area in step S509 in FIG. 5), the control unit 101 receives designation of the display area (step S512 in FIG. 5), For the image that has been image-processed under the previous image processing conditions, the designated arbitrary area is displayed on the image display means 105 (step S513 in FIG. 5).

  Here, at the time of the previous diagnosis of the image, if the area considered to be a lesion is enlarged and then displayed after image processing under image processing conditions suitable for the partial area, An arbitrary area is displayed in a state where the entire image has been subjected to image processing under the previous image processing conditions.

  Therefore, although it is not an appropriate state for image processing for an arbitrary region currently displayed, some regions (regions of interest) focused on at the time of the previous diagnosis are processed in a state that the user seems to be appropriate. Therefore, it is obvious at a glance which part was focused on the previous time while displaying an arbitrary area. Even if it is not obvious at a glance, if there is a part that has been subjected to appropriate image processing in some area when looking around an arbitrary area, it is determined that the part is a region of interest focused on the previous time You can also

  In other words, the image is read and the entire image or arbitrary area is displayed, but the image processing is applied using the previous image processing conditions, so that the continuity with the previous diagnosis is maintained. Display can be performed. As a result, by performing image processing on the entire image based on the adjustment amount of the image processing condition of the previously selected area, the same image processing condition as the previous time can be reproduced, and the image is selected and enlarged in the previous diagnosis. It is possible to accurately diagnose a lesion or the like in an area with continuity from the previous diagnosis.

  In addition, when the entire display is performed with the previous image processing condition applied (step S511 in FIG. 5) or when an arbitrary area is displayed (step S513 in FIG. 5), the previous display is further performed. The display range can be switched to an enlarged display, and the previous display range can be displayed with a frame or the like in the whole display or arbitrary area display. As a result, not only the previous image processing can be reproduced, but also the previous selected area can be reproduced. This makes it possible to easily restart the previous diagnosis work.

  In addition, when the entire image is displayed by executing image processing under the same condition as the state where the previous image processing condition is applied (FIG. 9) (step S511 in FIG. 5) or when an arbitrary area is displayed (FIG. 9). In step S513 in FIG. 5, when the region designated in the previous time (region 806 in FIG. 8) and enlarged (FIG. 9) is subjected to image processing as shown in FIG. 11 and the entire image is displayed, the previous image processing is performed. The position of the region 806 to which the condition is applied may be displayed as a frame 1106 in the radiation image 1101 in FIG. As a result, not only the previous image processing can be reproduced, but also the previous selected area can be reproduced. This makes it possible to easily restart the previous diagnosis work.

  In addition, on the display screen of FIG. 10 or FIG. 11, the user clicks the “enlarged area display” icon (1009 in FIG. 10 or 1109 in FIG. 11) using the pointing device, and receives the control. 101 performs control to enlarge and display the previous display range. This makes it possible to reproduce the same image processing conditions as in the previous time, and to accurately diagnose a lesion or the like in an area selected and enlarged in the previous diagnosis with continuity from the previous diagnosis.

It is explanatory drawing which shows the flow of the whole structure or the whole process of one Embodiment of this invention. It is a flowchart which shows the flow of the process in embodiment of this invention. It is a schematic diagram which shows the mode of the image processing in embodiment of this invention. It is a schematic diagram which shows the mode of the image processing in embodiment of this invention. It is a flowchart which shows the flow of the process in embodiment of this invention. It is a schematic diagram which shows the data structure of the information memorize | stored in the adjustment information storage means in embodiment of this invention. It is a schematic diagram which shows the data structure of the information memorize | stored in the parameter memory | storage means in embodiment of this invention. It is a schematic diagram which shows the mode of the image processing in embodiment of this invention. It is a schematic diagram which shows the mode of the image processing in embodiment of this invention. It is a schematic diagram which shows the mode of the image processing in embodiment of this invention. It is a schematic diagram which shows the mode of the image processing in embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Radiographic imaging means 20 Radiation image input means 100 Image processing apparatus 101 Control means 105 Image display means 107 Operation input means 110 Image display change means 120 Image processing condition setting means 130 Parameter storage means 140 Image processing condition adjustment means 150 Adjustment information storage Means 160 Parameter changing means

Claims (5)

An image processing apparatus for processing a radiographic image having a signal corresponding to an irradiation dose of radiation transmitted through a subject,
Display area selection means for selecting a display area of the radiation image;
Image processing condition adjusting means for setting image processing conditions for the display area selected by the display area selecting means;
Image processing means for image processing the radiation image based on the image processing conditions set by the image processing condition adjusting means;
Image display means for displaying the radiation image;
Storage means for storing the radiation image and the image processing condition in association with each other;
When displaying the radiation image stored in the storage means on the image display means, the entire radiation image including the area selected by the display area selection means is stored in association with the radiation image. Control means for performing image processing by the image processing means on the basis of the image processing conditions and controlling the display on the image display means;
An image processing apparatus comprising: The control means stores the position information of the display area for each radiographic image in the storage means, and displays the position of the display area together when displaying the radiographic image that has been subjected to the previous image processing. To control,
The image processing apparatus according to claim 1. The control means stores position information of the display area for each radiographic image in the storage means, and displays the radiographic image in the display area when displaying the radiographic image that has been subjected to image processing before. To control,
The image processing apparatus according to claim 1. The control means stores the final image processing condition at the end of processing in the image processing for each radiographic image in the storage means, and the image stored in the storage means for the radiographic image previously processed. Causing the image processing means to execute image processing under processing conditions, and performing control to display the radiographic image subjected to the image processing on the image display means;
The image processing apparatus according to claim 1, wherein the image processing apparatus is an image processing apparatus. An image processing program for obtaining an image suitable for diagnosis with respect to a radiographic image having a signal corresponding to an irradiation dose of radiation transmitted through a subject,
Display area selecting means for selecting a display area of the radiation image;
Image processing condition adjusting means for setting image processing conditions for the display area selected by the display area selecting means;
Image processing means for image processing the radiation image based on the image processing conditions set by the image processing condition adjusting means;
Image display means for displaying the radiation image;
Storage means for storing the radiation image and the image processing condition in association with each other;
When displaying the radiation image stored in the storage means on the image display means, the entire radiation image including the area selected by the display area selection means is stored in association with the radiation image. Control means for controlling the image processing means to perform image processing on the basis of the image processing conditions and displaying on the image display means;
An image processing program for operating a computer as a computer program.