JP6584813B2 - Exposure dose calculation device, exposure dose management system, and control method and program thereof - Google Patents

Description

The present invention relates to an exposure dose calculation apparatus, an exposure dose management system, a control method thereof, and a program thereof.

The medical image diagnosis that has been taken using the X-ray CT apparatus or the like, radiation exposure dose value received at the time of CT imaging (CTDIvol: Volume Computed Tomography Dose Index ) that is used as an index for managing the radiation exposure of the subject It is common. In such an X-ray CT apparatus, a detector is attached to a cylindrical reference phantom made of an acrylic resin (hereinafter also referred to as a CTDI phantom) at the time of shipment, and an X-ray dose is detected. Settings are being made. Therefore, it is possible to output a CTDIvol as supplementary information of the medical image data as a value corresponding to the photographing conditions such as X-ray tube current during CT imaging, can be used CTDIvol as an evaluation index of the radiation exposure dose of the subject.

CTDI phantoms used for initial setting of the apparatus include those for a body diameter of 32 cm and those for a head of 16 cm in consideration of the size of the examination site of the subject. The reference value acquired based on the phantom is stored, and CTDIvol calculated based on the reference value corresponding to the examination site is output as supplementary information of the medical image data. CTDIvol this is output as additional information of the medical image data as is, can be used as an evaluation index of the radiation exposure dose of the subject, rather than those strictly considering the type of the subject, the type of the object How to calculate the radiation exposure dose in response has been demanded.

As a method capable of calculating the radiation exposure dose in consideration of type, Patent Document 1, the scanned image (e.g., AP scan images scanned in a state in which the subject lying on the bed: AP SCA
N PROJECTION IMAGE) is disclosed, and a method for correcting the CTDIvol to a value corresponding to the body type is disclosed.

JP 2004-73397 A

However, since the AP scan image used when obtaining the body shape in Patent Document 1 is not an image photographed by rotating the gantry, it is photographed as shown in FIGS. 14 (a-1) to (a-3). The distance between the subject 1400 and the X-ray tube 1402 and the X-ray detector 1403 changes according to the position of the bed 1301 when the bed is moved. The AP scan image captured in FIG. 14 (a-1) is FIG. 14 (b-1), the AP scan image captured in FIG. 14 (a-2) is FIG. 14 (b-2), The AP scan image photographed in FIG. 14A-3 is FIG. 14B-3. As described above, even if the subject is the same, the images are not always the same as shown in FIGS. 14B-1 to 14B-3. In other words, body width obtained from the AP scan image is different depending on the distance from the X-ray tube 1402, and the method disclosed in Patent Document 1, can be reliably calculated radiation exposure dose in accordance with body type of the subject I can not say.

As a method of removing distortion caused by such an AP scan image, there is a method of acquiring body type information of a subject from a tomographic image taken while rotating a gantry with an X-ray CT apparatus. However, since the recent CT imaging a plurality of tomographic images are photographed, in order to calculate the radiation exposure dose from such a plurality of tomographic images, images on the identified either one tomographic image Therefore, it can be said that it is quite complicated.

The present invention has been made in view of the above problems, and an object thereof is to provide an exposure dose calculation apparatus that can easily acquire an exposure dose according to the body shape of a subject.

In order to achieve the above object, an exposure dose calculation apparatus of the present invention uses a latham image generated from a plurality of medical images acquired by imaging a subject with an X-ray apparatus, Specifying means for specifying at least one body type information of the body thickness; acquisition means for acquiring a correction coefficient corresponding to the body type information specified by the specifying means; and the correction coefficient and medical image acquired by the acquiring means Calculating means for calculating an exposure dose by imaging with the X-ray apparatus of the subject using a value indicating the X-ray intensity at the time of imaging, and the specifying means uses the latham image to The length of the subject at the center position in the body axis direction of the specimen is specified.

According to the present invention, it is possible to provide a radiation dose calculating device which can be easily obtained exposure line amount according to type of the object.

It is a diagram illustrating an example of a system configuration of the radiation exposure dose control system. 2 is a diagram illustrating an example of a hardware configuration of a medical image display apparatus (information processing apparatus) 102 and server apparatuses 103 and 104. FIG. It is a flowchart illustrating a flow for calculating the radiation exposure dose in accordance with the physique of the subject. It is an example of the initial screen of a medical image display apparatus. It is an example of a radiation exposure dose management screen. It is an example of a radiation exposure dose management screen. It is a figure explaining the process which produces | generates a Latham image (AP direction). It is a figure explaining the process which produces | generates a Latham image (Lateral direction). Used in correcting radiation exposure dose in accordance with body type of the subject, a correction table showing the correction factor for body width, body thickness of the subject. It is a flowchart illustrating the flow of displaying the radiation exposure dose graph. A list screen to display the radiation exposure dose of the patient. It is an example of a radiation exposure dose graph. It is an example of a radiation exposure dose graph. It is a figure for demonstrating the problem in a prior art.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

Figure 1 is a diagram showing a system configuration of the radiation exposure dose control system in the embodiment.

Radiation exposure dose control system of the present invention, modalities 101 such as X-ray CT apparatus, a medical image display apparatus 102 (radiation exposure dose calculating device), hospital image management server 103 (server) of, but LAN (Local Area Network) Are connected to each other via a hospital network such as WAN (Wide Area Network). Further network in hospitals, with outpatient image management server 104 (radiation exposure dose control apparatus) can be connected each other to enable data communication over the network, it is also possible to store the hospital such as an image hospital.

  Note that each terminal configuration in FIG. 1 is an example, and it goes without saying that there are various configuration examples depending on applications and purposes.

  Hereinafter, although an X-ray CT apparatus will be described as an example in the present embodiment as a modality, the present invention is not limited to this, and any modality that requires dose management is applicable.

  The X-ray CT apparatus 101 can transmit and store a captured medical image to a medical image display apparatus 102 set in advance, an in-hospital image management server 103, or an external image management server 104. Medical image data (DICOM image data) imaged by the X-ray CT apparatus 101 and transmitted to the server includes the patient name, patient ID, patient sex, the value of the X-ray tube current at the time of imaging by the X-ray CT apparatus, It consists of incidental information such as CTDIvol (dose information) indicating the X-ray intensity at the time of medical image capturing and image data.

The medical image display apparatus 102 is a workstation that can perform various image processing based on medical image data (a plurality of tomographic image data) captured by the X-ray CT apparatus 101. In the present embodiment, the medical image display apparatus 102 generates a laysum image obtained by viewing a plurality of tomographic images taken by the X-ray CT apparatus 101 from a predetermined direction, and the body shape index of the subject on the laysum image. Body width and / or body thickness values are acquired, correction values are acquired from the correction value table using values corresponding to the body type of the subject, and CTDIvol provided in the incidental information of DICOM image data the radiation exposure dose to be calculated that reflects the type of the object by correcting.

  The image management server 103 is a server device for storing and managing images captured mainly by in-hospital modalities. The image management server 103 is a medical image transmitted from the modality or after being processed by the medical image display device 102. Medical images can also be saved. By accessing the image management server 103 from an in-hospital information processing apparatus (not shown), it is possible to browse medical images in the image management server 103 from a desired location.

  The image management server 103 is a server device that is provided outside the hospital and can store and manage medical images taken from hospital modalities, medical images processed by the medical image display device 102, and the like. . The image management server 103 can receive storage requests from a plurality of hospitals and can manage radiation doses at a plurality of hospitals.

  FIG. 2 is a diagram illustrating an example of a hardware configuration of the medical image display apparatus 102, the image management server 103, and the image management server 104.

  The CPU 201 comprehensively controls each device and controller connected to the system bus 204.

  Further, the ROM 202 or the external memory 211 (storage means) has a BIOS (Basic Input / Output System) or an operating system program (hereinafter referred to as OS), a medical image display device 102, an image management server 103, an image, and the like as a control program of the CPU 201. Various programs described below necessary for realizing the function executed by the management server 104 are stored. The RAM 203 functions as a main memory, work area, and the like for the CPU 201.

  The CPU 201 implements various operations by loading a program necessary for execution of processing into the RAM 203 and executing the program.

  The input controller 205 controls input from an input device 209 such as a keyboard or a pointing device such as a mouse (not shown).

  The video controller 206 controls display on a display device such as the display 210. The type of the display device is assumed to be a CRT or a liquid crystal display, but is not limited thereto.

  The memory controller 207 is a card type memory connected via an adapter to a hard disk, a flexible disk, or a PCMCIA card slot for storing a boot program, browser software, various applications, font data, user files, editing files, various data, etc. The access to the external memory 211 is controlled.

  A communication I / F controller (communication I / FC) 208 is connected to and communicates with an external device via a network, and executes communication control processing in the network. For example, Internet communication using TCP / IP is possible.

  Note that the CPU 201 enables display on the display 210 by executing outline font rasterization processing on a display information area in the RAM 203, for example.

Further, the CPU 201 enables a user instruction with a mouse cursor (not shown) on the display 210.

Various programs and the like used for each terminal of the present invention to execute various processes to be described later are recorded in the external memory 211, and are executed by the CPU 201 by being loaded into the RAM 203 as necessary.
Furthermore, definition files and various information tables used by the program according to the present invention are stored in the external memory 211.

Next will be described the flow for calculating the radiation exposure dose that reflects the type of the object with reference to FIGS. 3 to 9.

FIG. 3 is a flowchart showing processing performed by the medical image display apparatus 102 according to the embodiment of the present invention. The process shown in the flowchart of FIG. 3 is realized by the CPU 201 reading and executing the stored control program. FIG. 4 is an example of an initial screen of the image processing program of the medical image display apparatus 102. FIG. 5 is an example of an initial screen of the dose management screen 500 displayed on the medical image display apparatus 102. Figure 6 is an example of how the radiation exposure dose that reflects the type of the subject at a dose management screen 500 displayed by the medical image display apparatus 102 is calculated. FIG. 7 is a diagram for explaining a laysum image in the front-rear direction of the subject. FIG. 8 is a diagram for explaining a left-right laysum image of the subject. FIG. 9 shows a correction coefficient 903 used when correcting the CTDIvol to correspond to the body shape of the subject stored in advance in the storage means of the medical image display apparatus 102, and the body shape information (body width + body thickness) of the subject. 901, body thickness 911, body width 921), and effective diameter 912. FIGS. 9A to 9C show the correction coefficient used when correcting the CTDIvol calculated based on the initial value acquired with the 16 cm phantom according to the body shape, the body shape information and the effective diameter of the subject. It is a table which shows. FIGS. 9D to 9F show the correction coefficient used when correcting the CTDIvol calculated based on the initial value acquired with the 32 cm phantom according to the body shape, the body shape information and the effective diameter of the subject. It is a table which shows.

  In S301 of FIG. 3, the CPU 201 of the medical image display apparatus 102 determines whether the dose management tool has been activated. If it is determined that the dose management tool has been activated, the process proceeds to S302.

  Specifically, it can be determined whether or not the dose management button 446 is pressed on the initial screen of the medical image processing program installed in the medical image display apparatus 102 shown in FIG.

  The initial screen of the medical image display apparatus 102 in FIG. 4 is displayed in the medical image display apparatus 102 or image management by pressing the search button 405 in a state where the patient name 401, patient ID 402, examination date 406, calendar 407, etc. are selected. Medical images stored in the servers 103 and 104 can be searched.

  As the retrieved information, information acquired from supplementary information of medical image data such as patient name 411, patient ID 412, gender 413, latest date 414, modality 415, age 416, state 417, and comment 418 is displayed as a list screen 410. Is done.

  When the user selects a desired patient on the list screen 410, examination information such as the patient attribute 421, examination date 422, modality 423, examination description 424, patient name 425, examination ID 426, etc. is displayed on the examination information list screen 420. Is done. When the user selects desired inspection information on the inspection information list screen 420, the series number of the inspection information is displayed on the series information list screen 430. Series information such as 431, pixel size 432, FOV 433, inspection date and time 434, modality 435, slice thickness 436, number of images 437, and the like are displayed. When any series information is selected, thumbnails or the like of images of the series can be displayed in the display area 440.

  Further, the user selects, for example, a plurality of tomographic images captured by the X-ray CT apparatus 101 in a state where desired series information is selected on the series information list screen 430 (or a state where one image in the series is selected). In addition, a 3D drawing button 441 for performing three-dimensional display, a viewer button 442 for viewing a tomographic image, a printer transfer button 443, a report registration button 444 for registering a report, and saving a selected image in the image management servers 103 and 104 An instruction for performing each desired process such as an external storage button 445 for performing a dose calculation, a dose management button 446 for performing a dose calculation process, and the like can be given. It is also possible to select a desired medical image after pressing a button for starting each desired process.

In S302, the CPU 201 of the medical image display apparatus 102 reads the medical image data (DICOM image data) selected by the user. If a series is selected before the dose management button 446 is pressed, the medical image data of the selected series is read. On the other hand if it is not selected, pressing the DICOM image read button 511 of the radiation exposure dose management screen of FIG. 5, by selecting the medical image data to calculate the radiation exposure dose, also load the medical image data it can.

  In S303, the CPU 201 of the medical image display apparatus 102 acquires dose information (CTDIvol) and the like from the medical image data acquired in S302. Specifically, when the DICOM image data is read, the subject parameter 512 for performing dose calculation, the CTDIvol for the CT dose index 514, and the parameters for dose calculation shown in the dose management screen 500 of FIG. 5 from the incidental information of the DICOM data. 515 etc. are read. (Fig. 6)

  In S304, the CPU 201 of the medical image display apparatus 102 displays a dose management screen 500 shown in FIG. 5, and accepts a designation of a calculation processing method and other inputs from the user via this screen.

  In step S <b> 305, the CPU 201 of the medical image display apparatus 102 determines which is the body shape calculation processing method designated by the user.

  Specifically, the calculation processing method is designated by the user selecting a calculation method for the body type of the subject on the dose management screen of FIG. The body type information of the subject can be acquired from a laysum image generated based on a plurality of medical images (tomographic images) acquired as DICOM image data. Does the user use the body width acquired from the AP image (front-rear direction image) of the subject as the body shape (AP diameter), or uses the body thickness acquired from the lateral image (left-right direction image) (Lateral diameter)? ), Whether to use both body width and body thickness (Lateral + AP diameter) can be selected in the selection field 523.

Further, the user may select the phantom size and the like of the configuration and radiation exposure dose calculation parameters 518 of a user selected item 513 in dose control screen. If the phantom size and the like can be acquired from the accompanying information of the DICOM data, the contents of the DICOM data are reflected.

  In addition, when dose information (CTDIvol) cannot be acquired from incidental information of DICOM data, a user can input appropriately on a dose management screen.

  If it is determined in S305 that the body width obtained from the AP image is used as the body shape information of the subject (AP diameter is selected), the process proceeds to S306, and the CPU 201 of the medical image display apparatus 102 extracts a laysum image from a plurality of medical images. Generated and displayed in the display area 516.

  For example, in the X-ray CT apparatus 101, imaging is performed with the subject lying on the bed 701 as shown in FIG. 7A, and a plurality of tomographic images as shown in FIG. The laysum image is an image generated based on a value obtained by integrating the CT values of the plurality of tomographic images (or volume images) along a predetermined direction. FIG. 7C shows an example of an AP image generated along the direction (AP direction) from the front surface to the rear surface of the subject. The generated ray-sum image is displayed in the display area 516 of the dose management screen 500.

  In step S307, the CPU 201 of the medical image display apparatus 102 acquires body width information of the subject specified by the laysum image generated in step S306. As an acquisition method, the width of the subject at the center position in the body axis direction of the subject in the region examined by the X-ray CT apparatus can be automatically obtained from the laysum image. In addition, it is possible to accept designation of two points from the user for the laysum image displayed in the display area 516 of FIG. 6 (611), and obtain the distance between the two points as body width information.

In S308, the CPU 201 of the medical image display apparatus 102 acquires the phantom size. The phantom size can be referred to when there is data in the accompanying information of the DICOM data. On the other hand when there is no data of the phantom size in the supplementary information of the DICOM data, which the user has set via the radiation exposure dose calculation parameters 518 of dose management screen 500 is obtained.

  In step S308, the CPU 201 of the medical image display apparatus 102 specifies a table to be used based on the body width information acquired in step S307 and the phantom size acquired in step S308, and further acquires a correction coefficient from the table. To do.

In S318, radiation exposure to CPU201 of the medical image display apparatus 102, using the correction coefficient obtained acquired dose information in S303 the (CTDIvol) in step S308 is corrected (integration), it is corrected in accordance with the body type of the subject Calculate the dose.

In S319, CPU 201 of the medical image display apparatus 102, stored in the storage means radiation exposure dose, etc. calculated in Latham image and S318 generated in S306. Such conservative treatment can also be performed automatically after the radiation exposure dose is calculated may be the accompanying is stored the user presses a data storage button 522 dose management screen 500.

  Further, the storage means to be stored may be storage means in the medical image display apparatus 102 or may be stored in the database 1040 on the image management server 104 outside the hospital.

  Next, in steps S304 to S309, S318, and S319, AP diameter is selected in the selection field 523 in FIG. 6 (601), and the distance between the two points is represented by the AP-direction laysum image displayed in the display area 516. This will be specifically described based on an example in which 32 cm is used as the width information and the phantom.

  When “20.6 cm” is acquired as the distance (body width information) between two points of the laysum image displayed in the display area 516, the information is displayed in the column 602 of the dose management screen 500. The In the display area 517, a medical image of the surface from which body width information has been acquired is displayed.

  9F, which is a correction table corresponding to the AP image of the 32 cm phantom, is specified from the storage unit of the medical image display apparatus 102, and the correction coefficient “20.6 cm” corresponding to “20.6 cm” is determined based on the correction table. 1.48 ”and effective coefficient“ 25 ”are acquired. Even when the correction table is not provided, a necessary correction coefficient can be obtained as appropriate based on correction coefficients corresponding to two adjacent body widths. The acquired correction coefficient “1.48” is displayed in the conversion coefficient column 519, and the effective coefficient “25” is displayed in the effective coefficient column.

When the CTDIvol acquired from the incidental information of the DICOM data is “8.9216” as shown in the CT dose index column 603 of FIG. 6, the correction coefficient “1.48” and the CTDIvol “8.9216” are used. integrating the "13.204" is calculated as the radiation exposure dose in accordance with body width.

Note that the two points that can be selected in the display area 516 in FIG. 6 are selected at the center position in the body axis direction of the layham image in this embodiment, but are acquired at any position in the Z axis direction of the layham image. May be. In that case, it is possible to radiation exposure dose in accordance with body type the acquired body width when the (integrated) on the basis is calculated.

By data storage button 522 in this state it is depressed, the with the subject information obtained from the DICOM image, the correction coefficient "1.48" and radiation exposure dose "13.204" is stored .

Further, as shown in this example, receiving a desired site-user on Latham image, by'll calculate the integrated radiation exposure dose in accordance with the corresponding object, radiation exposure for photographing position containing the desired organ The dose can be calculated easily.

  Returning to FIG. 3, the description will be continued. When it is determined in S305 of FIG. 3 that the body thickness obtained from the lateral image is used as the body shape information of the subject (when the lateral diameter is selected), the process proceeds to S310. In step S <b> 310, the CPU 201 of the medical image display apparatus 102 generates a laysum image from a plurality of medical images and displays it in the display area 516. In this case, as shown in FIG. 8 (a), a lateral image (FIG. 8 (b)) obtained by accumulating CT values along the direction (lateral direction) from the left surface to the right surface of the subject is dose management. It is displayed in the display area 516 of the screen 500.

  In S <b> 311, the CPU 201 of the medical image display apparatus 102 acquires the body thickness information of the subject specified by the laysum image generated in S <b> 310. As an acquisition method, the image may be acquired automatically from the laysum image, or the user accepts designation of two points for the laysum image displayed in the display area 516 of FIG. 6 (611), and between the two points Can be acquired as body thickness information.

In step S312, the CPU 201 of the medical image display apparatus 102 acquires the phantom size. Phantom size, to when there is data in the supplementary information of the DICOM data can also refer to the data, when there is no data in the supplementary information of the DICOM data, user radiation exposure dose calculation dose management screen 500 What is set via the parameter 518 is acquired.

  In step S313, the CPU 201 of the medical image display apparatus 102 identifies a table to be used based on the body thickness information acquired in step S311 and the phantom size acquired in step S312, and further acquires a correction coefficient from the table. To do.

In S318, radiation exposure to CPU201 of the medical image display apparatus 102, using the correction coefficient obtained acquired dose information in S303 the (CTDIvol) at S313 is corrected (integration), it is corrected in accordance with the body type of the subject Calculate the dose.

In S319, CPU 201 of the medical image display apparatus 102, stored in the storage means radiation exposure dose, etc. calculated in Latham image and S318 generated in S310. Such conservative treatment can also be performed automatically after the radiation exposure dose is calculated may be the accompanying is stored the user presses a data storage button 522 dose management screen 500.

It is possible to calculate the radiation exposure dose as in the case of obtaining the type information of the object using the Latham image of the AP direction when obtaining the type information of the object using the lateral direction of the Latham image as described above .

  If it is determined in S305 that the body width and body thickness obtained from the AP image and the lateral image are used as the body shape information of the subject (when Lateral + AP diameter is selected), the process proceeds to S314.

  In S <b> 314, as in S <b> 306 and S <b> 310, the CPU 201 of the medical image display apparatus 102 generates two laysum images in the AP direction and the lateral direction from a plurality of medical images and displays them in the display area 516.

  In S315, as in S307 and S311, the CPU 201 of the medical image display apparatus 102 acquires the body width and body thickness information of the subject specified by the laysum image generated in S314.

  In S316, as in S308 and S312, the CPU 201 of the medical image display apparatus 102 acquires the phantom size.

  In S317, as in S309 and S313, the CPU 201 of the medical image display apparatus 102 specifies a table to be used based on the body width and body thickness information acquired in S315 and the phantom size acquired in S316, Further, a correction coefficient is acquired from the table.

In S318, radiation exposure to CPU201 of the medical image display apparatus 102, using the correction coefficient obtained acquired dose information in S303 the (CTDIvol) at S317 is corrected (integration), it is corrected in accordance with the body type of the subject Calculate the dose.

In S319, CPU 201 of the medical image display apparatus 102, stored in the storage means radiation exposure dose, etc. calculated in Latham image and S318 generated in S314. Such conservative treatment can also be performed automatically after the radiation exposure dose is calculated may be the accompanying is stored the user presses a data storage button 522 dose management screen 500. The storage destination is not limited to the medical image display apparatus 102, but can be stored in the in-hospital image management server 103 or the out-of-hospital image management server 104.

  As described above with reference to FIGS. 3 to 9, in the present embodiment, the subject information of at least one of the body width and the body thickness of the subject specified by using a laysum image generated from a plurality of medical images. Is used to correct CTDIvol, which is the X-ray intensity at the time of medical image capturing.

The body shape of the subject is obtained from a scan image (for example, AP scan image: AP SCAN PROJECTION IMAGE) that has been scanned while the subject is lying on the bed as disclosed in JP 2004-73397 A, and CTDIvol is calculated. A method for correcting the value according to the body shape has been known. However, since this conventional AP scan image is not an image photographed by rotating the gantry, it depends on the position of the bed 1301 when photographed as shown in FIGS. 14 (a-1) to (a-3). Thus, the distance between the subject 1400, the X-ray tube 1402 and the X-ray detector 1403 changes. The AP scan image captured in FIG. 14 (a-1) is FIG. 14 (b-1), the AP scan image captured in FIG. 14 (a-2) is FIG. 14 (b-2), The AP scan image photographed in FIG. 14A-3 is FIG. 14B-3. As described above, even if the subject is the same, the images are not always the same as shown in FIGS. 14B-1 to 14B-3. In other words, body width obtained from the AP scan image is different depending on the distance from the X-ray tube 1402, in the method disclosed in Patent Document 1 could not be reliably calculated radiation exposure dose in accordance with body type of the subject .

On the other hand, in the present embodiment, by acquiring a body shape using a lathe image, the actual body shape of the subject is used compared to the case where the body shape of the subject is used from a scan image taken without rotating the gantry as in the past. it is possible to calculate the value reflecting the, it said to be obtained a highly reliable radiation exposure dose are made.

Further, as in the present embodiment, by acquiring the body width and body thickness of the subject from the laysum image, it is possible to reduce the trouble of selecting the position for acquiring the subject information from a plurality of medical images. it can be said that the radiation exposure dose in accordance with body type of the subject are in obtained.
Incidentally, Latham image generation from a plurality of medical images (tomographic images) in the present embodiment has been described as a series of flows of radiation exposure dose calculating, in advance Latham image without a series of flows

If you save a representative value of CTDIvol the X-ray intensity during medical imaging, it acquires the type and representative of CTDIvol at a desired timing, it is also possible to calculate the radiation exposure dose in accordance with body type. Specifically, after generating any one of the laysum images, the data save button 522 is pressed without specifying 611 two points. Thus, stored as DICOM image data of the central portion of the representative value (e.g., the imaging area of CTDIvol the X-ray strength at Latham images and medical imaging without calculating the radiation exposure dose in accordance with body type of the subject CTDIvol) is stored. By thus keep the Latham image, the user radiation exposure were corrected for the Latham image at a desired timing to acquire the type information of the subject, the CTDIvol are representative of the time of medical images photographed body type A dose can be obtained. Thus, according to a plurality of order can be calculated as appropriate radiation exposure dose need not keep a medical image, while reducing the capacity of the image management server at a desired timing of the object type in order to calculate the radiation exposure dose it is possible to calculate the radiation exposure dose.

Next, with reference to FIGS. 10 to 13, a description about how to manage the radiation exposure dose in accordance with body type of the subject. Radiation exposure dose is calculated as shown in S319 of FIG. 3 may be managed by the medical image display apparatus 102 and the image management server 103 and out-of-hospital image management server 104 of the hospital. Such radiation exposure dose is managed by the management means can see the list, for example, from the information processing apparatus or the like of the medical image display apparatus 102 and not shown. And it is possible to generate a list or radiation exposure dose control graph with reference to the information managed by the management means the radiation exposure dose to the list information on the basis.

Here, on the basis of the radiation exposure dose corresponding to a plurality of subjects that are managed by the image management server 104 outside the hospital, radiation exposure dose control graph generated according the medical image display apparatus 102 to generate an instruction of the graph A description will be given using an example in which is displayed.

Figure 10 is a flowchart illustrating a series of flow for displaying the radiation exposure dose graph. The processing shown in the flowchart of FIG. 10 is realized by reading and executing a control program stored in the CPU 201 of the medical image display apparatus 102 and the CPU 201 of the image management server 104. Figure 11 is a list of a plurality of radiation exposure dose of the subject (patient) managed by the image management server 104, generated by the image management server 104 in response to a request of the medical image display apparatus 102, the medical image display 4 is a list screen displayed on the device 102. The user can perform the display instruction of the radiation exposure dose graph through this screen. An example of a radiation exposure dose control graph displayed this way is shown in FIG. 12 and FIG. 13.

  In S <b> 1001 of FIG. 10, the CPU 201 of the medical image display apparatus 102 requests the image management server 104 to display a list image.

In S1002, CPU 201 of the image management server 104, in response to the display request of the medical image display apparatus 102, based on a plurality of X-ray CT examination information managed image management server 104 within, Latham image and radiation exposure dose A list screen that can grasp management information such as is generated. At the same time, a display screen 1101 including a list screen and a condition column 1130 for setting a graph display condition is transmitted to the medical image display apparatus 102 in S1003.

  In step S <b> 1004, the CPU 201 of the medical image display apparatus 102 displays the display screen 1101 transmitted from the image management server 104 on the display.

An example of such a display screen 1101 is shown in FIG. As can be seen from the display screen 1101 shown in FIG. 11, in the image management server 104, the selection box 1102 and the management number 1103, the examination date 1104 acquired from the DICOM data, the patient ID 1105, the patient name 1106, the gender 1107, the age 1108, and the weight 1109 The imaging region 1110 is managed. Furthermore, the number of images 1111 that indicates the number of Latham images stored, the X-ray intensity during medical imaging CTDIvol1112 (when CTDIvol or data storage button 522 used for calculating the radiation exposure dose is pressed A representative value of CTDIvol specified), DLP 1113, and phantom size 1114 are managed. Furthermore, managing the effective diameter 1116-transform coefficients 1117 such obtained from radiation exposure dose 1115, the correction table calculated by correcting the CTDIvol according to type of the object.

The list screen, the examination information data after the calculation of the radiation exposure dose 1115 is registered, Latham images generated but examination information and can identify the radiation exposure dose 1115 is registered data in a state that is not calculated Are listed. In the example of FIG. 1 and No. 2 and No. 3 and no. 5, an inspection information data after radiation exposure dose 1115 in accordance with the body type of the subject is calculated is registered. And No. 4 and no. 6, Latham images are generated as the inspection information data in a state of radiation exposure dose 1115 is not calculated is registered. Depending on whether this example contains the value of such radiation exposure dose 1115 can determine whether it is a state. By displaying as can be determined in this way the list screen, easily check whether radiation exposure dose in accordance with body type of the subject is calculated in the examination information managed by the radiation exposure dose control means can do.

New registration button 1118 on the display screen 1101, without using the dose control screen 500, a button for registering the Latham images and information such as the radiation exposure dose 1115 of a new patient. A delete button 1119 on the display screen 1101 is a button that can delete examination information for which the selection box 1102 is selected. Download button 1120 on the display screen 1101 is a button for downloading Latham images and information such as the radiation exposure dose 1115 that is managed as management items of the examination information selection box 1102 is selected. The overwrite save button on the display screen 1101 is a button for saving the overwrite on the examination information selected in the selection box 1102.

Here Latham image has been generated is not calculated radiation exposure dose 1115 No. 4 or No. If you want to register the radiation exposure dose in accordance with body type of the subject it will be described with respect to 6 tests. No. 4 or No. When the download button 1120 is pressed while 6 is selected, the CPU 201 of the medical image display apparatus 102 activates the dose management tool. Then, the corresponding laysum image stored in the management server 104 and the representative value of CTDIvol are acquired. And like the flow of radiation exposure dose calculation described with reference to FIGS. 3 to 9, identifying at least one of the object information of the body width and the body thickness from Latham image, corrects the CTDIvol using the subject information specified to calculate radiation exposure dose to.

Sonouede, by pressing the data storage button 522 dose management screen 500, it is possible to overwrite save the calculated radiation exposure dose with respect to the downloaded test information.

  In addition, it is possible to directly save the overwriting without performing the calculation process in the medical image display apparatus 102 as described above.

This need not save the plurality of tomographic images as that Latham image is stored, it is possible to calculate the radiation exposure dose at a desired timing may be further preserved.

  Returning to FIG. 10, the description of the graph generation processing will be continued. In step S1005, the CPU 201 of the medical image display apparatus 102 determines whether the graph display button 1131 has been pressed by the user. If it is determined that the graph display button 1131 has been pressed by the user, the CPU 201 of the medical image display apparatus 102 sends a graph display request to the image management server 104 together with the conditions in the condition column 1130 of the graph display conditions in S1006. I do. Specifically, when the graph display button 1131 is pressed, a graph display request corresponding to the item checked in the condition column 1130 is made to the image management server 104.

In step S <b> 1007, the CPU 201 of the medical image display apparatus 102 generates a graph according to conditions specified by the user. Specifically, by preparing a template of the graph to be applied to each pre-condition setting, select a template according to the conditions set by the condition field 1130, on the data managed as radiation exposure dose Template A graph is generated by reflecting.

  In step S <b> 1008, the CPU 201 of the image management server 104 transmits the graph generated in step S <b> 1007 to the medical image display apparatus 102.

  In step S1009, the CPU 201 of the medical image display apparatus 102 displays the graph transmitted from the image management server 104, and the process ends.

Next, an example of the graph generated in this way will be specifically described. In condition field 1130 of FIG. 11, imaging region: chest, abdomen, Gender: Female, Male, item: CTDIvol, shown in FIG. 12 where the graph display button 1131 in the state in which radiation exposure dose was selected is pressed. In this case, it is divided into the chest and abdomen, and is divided into female and male, and is selected template is divided into CTDIvol and radiation exposure dose graph examination information managed is plotted is displayed .

  Further, in the condition column 1130 shown in FIG. 11, when the imaging region: chest is checked, the gender: female is checked, the item: CTDIvol is checked, and the percentile display is checked, FIG. A template as shown is selected, and a graph on which inspection information is plotted is displayed.

Further, in condition column 1130 shown in FIG. 11, imaging region: breast is checked, Sex: Male is checked, items: when the radiation exposure dose is checked, percentiles display is checked, FIG 13 (b ) Is selected, and a graph on which inspection information is plotted is displayed.

  In the condition column of FIG. 11, the graph cannot be displayed when any one of the items is not selected. Therefore, when any one is not selected, the graph display button 1131 is grayed out. For example, the selection may be disabled.

Based on the examination information managed as described above, the ability to see a graph corresponding to a desired condition, the user can grasp the index for the appropriate radiation exposure dose.

  The present invention can be implemented as a system, apparatus, method, program, storage medium, or the like, and can be applied to a system including a plurality of devices. You may apply to the apparatus which consists of one apparatus.

  Note that the present invention includes a software program that implements the functions of the above-described embodiments directly or remotely from a system or apparatus. The present invention also includes a case where the information processing apparatus of the system or apparatus is achieved by reading and executing the supplied program code.

  Therefore, the program code itself installed in the information processing apparatus in order to realize the functional processing of the present invention with the information processing apparatus also realizes the present invention. In other words, the present invention includes a computer program itself for realizing the functional processing of the present invention.

  In that case, as long as it has the function of a program, it may be in the form of object code, a program executed by an interpreter, script data supplied to the OS, and the like.

  Examples of the recording medium for supplying the program include a flexible disk, hard disk, optical disk, magneto-optical disk, MO, CD-ROM, CD-R, and CD-RW. In addition, there are magnetic tape, nonvolatile memory card, ROM, DVD (DVD-ROM, DVD-R), and the like.

  As another program supply method, a browser on a client computer is used to connect to an Internet home page. The computer program itself of the present invention or a compressed file including an automatic installation function can be downloaded from the homepage by downloading it to a recording medium such as a hard disk.

  It can also be realized by dividing the program code constituting the program of the present invention into a plurality of files and downloading each file from a different homepage. That is, the present invention also includes a WWW server that allows a plurality of users to download a program file for realizing the functional processing of the present invention with an information processing apparatus.

  In addition, the program of the present invention is encrypted, stored in a storage medium such as a CD-ROM, distributed to users, and key information for decryption is downloaded from a homepage via the Internet to users who have cleared predetermined conditions. Let The downloaded key information can be used to execute the encrypted program and install it in the information processing apparatus.

  Further, the functions of the above-described embodiment are realized by the information processing apparatus executing the read program. In addition, based on the instructions of the program, the OS or the like operating on the information processing apparatus performs part or all of the actual processing, and the functions of the above-described embodiments can be realized by the processing.

  Further, the program read from the recording medium is written in a memory provided in a function expansion board inserted into the information processing apparatus or a function expansion unit connected to the information processing apparatus. Thereafter, the CPU of the function expansion board or function expansion unit performs part or all of the actual processing based on the instructions of the program, and the functions of the above-described embodiments are realized by the processing.

  The above-described embodiments are merely examples of implementation in carrying out the present invention, and the technical scope of the present invention should not be construed as being limited thereto. That is, the present invention can be implemented in various forms without departing from the technical idea or the main features thereof.

101 Modality 102 Medical Image Display Device 103 Image Management Server 104 Image Management Server

Claims (10)

A specifying means for specifying body type information of at least one of a body width and a body thickness of a subject by using a Latham image generated from a plurality of medical images acquired by imaging the subject with an X-ray device;
Obtaining means for obtaining a correction coefficient corresponding to the body type information identified by the identifying means;
Calculating means for calculating an exposure dose by imaging with the X-ray apparatus in the subject using the correction coefficient acquired by the acquiring means and a value indicating the X-ray intensity at the time of imaging a medical image; Prepared,
The identification unit is configured to identify a length of a subject at a central position in a body axis direction of the subject by using the latham image. It said acquisition means, according to the correction coefficient corresponding to the type information, in claim 1, characterized in that to get from the first storage means for storing information indicating a correspondence relationship between the type information and the correction factor Exposure dose calculation device. Dose calculating apparatus according to claim 1 or 2, further comprising a second storage means for storing with integrated information exposure dose calculated by the calculation means. The exposure dose calculation apparatus according to any one of claims 1 to 3 , wherein the laysum image is at least one of a front-rear direction rasom image of the subject and a left-right direction laysum image of the subject. The specification unit receives a specification of two positions from a user in a state where the laysum image is displayed, and specifies a distance corresponding to the body shape of the subject from the two points. The exposure dose calculation apparatus according to any one of 1 to 4 . Value indicating the X-ray intensity at the time of shooting the medical images, radiation dose calculating device according to any one of claims 1 to 5, characterized in that it is CTDIvol. Based on the dose calculated by the calculation means, claims and further comprising a graph generating means for generating a radiation dose management graph corresponding to a predetermined condition including at least one of specific imaging region and sex Item 7. The exposure dose calculation apparatus according to any one of Items 1 to 6 . A specifying step of specifying body type information of at least one of a body width and a body thickness of a subject using a laysum image generated from a plurality of medical images acquired by imaging the subject with an X-ray device;
An obtaining step for obtaining a correction coefficient corresponding to the body type information identified in the identifying step;
Using the correction coefficient acquired in the acquisition step and a value indicating the X-ray intensity when a medical image is acquired, a calculation step of calculating an exposure dose by imaging with the X-ray apparatus in the subject;
With
The method for controlling an exposure dose calculating apparatus characterized in that the specifying step specifies the length of the subject at a central position in the body axis direction of the subject using the latham image. A program that can be executed by the exposure dose calculation device,
The exposure dose calculation device,
A specifying means for specifying body type information of at least one of a body width and a body thickness of a subject by using a Latham image generated from a plurality of medical images acquired by imaging the subject with an X-ray device;
Obtaining means for obtaining a correction coefficient corresponding to the body type information identified by the identifying means;
Calculating means for calculating an exposure dose by imaging with the X-ray apparatus in the subject using the correction coefficient acquired by the acquiring means and a value indicating the X-ray intensity at the time of imaging a medical image; Make it work
The program is characterized in that the specifying means specifies the length of the subject at the center position in the body axis direction of the subject using the latham image. A specifying means for specifying body type information of at least one of a body width and a body thickness of a subject by using a Latham image generated from a plurality of medical images acquired by imaging the subject with an X-ray device;
Obtaining means for obtaining a correction coefficient corresponding to the body type information identified by the identifying means;
A calculating means for calculating an exposure dose by imaging with the X-ray apparatus in the subject using the correction coefficient acquired by the acquiring means and a value indicating the X-ray intensity when imaging a medical image;
With
The identification means identifies the length of the subject at the center position in the body axis direction of the subject using the latham image.

Images