JP6026171B2 - Medical image photographing apparatus and medical image photographing method - Google Patents

Description

  Embodiments described herein relate generally to a medical image capturing apparatus and a medical image capturing method having a first X-ray detector and a second X-ray detector.

  In a conventional medical imaging apparatus (for example, an X-ray imaging apparatus called an angio apparatus), an X-ray generation unit that generates X-rays with respect to a subject P and X-rays that pass through the subject are two-dimensionally detected. And an X-ray detector for generating X-ray projection data. The X-ray generation unit and the X-ray detection unit are supported by an arm (generally called a C arm), and the C arm is moved in the body axis direction of the subject on the bed or around the body axis of the subject. By rotating, the subject can be imaged from various directions.

  Further, in an examination using an X-ray imaging apparatus, there is a demand for clearly observing an intended region with a higher resolution although the region of interest is narrow. In order to satisfy this demand, in addition to a normal X-ray detector (first detector), a second X-ray detector (second detector) having a small field of view but having a high resolution is combined. There is also an X-ray imaging apparatus that can switch to any one of the second detectors and perform imaging.

  For example, in the X-ray imaging apparatus described in Patent Document 1, a wide-field first X-ray detector that detects X-rays transmitted through a subject, and a field of view that is smaller than that of the first X-ray detector and has a high resolution. A second X-ray detector is provided, and an image detected by the second X-ray detector is displayed overlapping the image detected by the first X-ray detector. In the example of Patent Document 1, the position of the second X-ray detector is movable in the X direction and the Y direction.

  However, since the field size of the second detector is narrow, it is difficult to set the region of interest of the operator within the field size of the second detector. Further, it takes time to align the second detector, and the examination time becomes longer and the exposure of the subject and the operator increases, and further improvement is required. Further, since the first X-ray detector and the second X-ray detector have different visual field regions and sensitivities, the X-ray irradiation conditions are not the same, so there is a problem that it takes time to set the imaging conditions. .

JP 2008-229270 A

  The problem to be solved by the present invention is to provide a medical image photographing apparatus and a medical image photographing method capable of easily performing alignment with a diagnostic region when an image is collected using a second detector. It is in.

The medical imaging apparatus according to the embodiment includes an X-ray generation unit that includes an X-ray tube that generates X-rays and that emits X-rays to the subject, and a first X that detects X-rays that have passed through the subject. A first detector that detects X-rays transmitted through the subject at a fixed position within a field of view of the first X-ray detector and having a higher resolution in a smaller field of view than the first X-ray detector; And the second X-ray detector based on real-time first image data collected using the first X-ray detector. Based on the first image data, an image processing unit that generates a frame image indicating a visual field region by a line detector, enlarges the image data of the region indicated by the frame image in the first image data, and Using a first display unit that displays the frame image superimposed on a first image, and the second X-ray detector Serial images collected when imaging a subject, comprising a second display section for artificially displayed using an image obtained by the expansion process.

1 is a block diagram showing a configuration of a medical image photographing apparatus according to an embodiment. 1 is a perspective view showing an overall structure of a medical image photographing apparatus according to an embodiment. The block diagram which shows the principal part of the medical image imaging device in one Embodiment. Explanatory drawing which shows the operation | movement of the image shooting in one Embodiment. Explanatory drawing which shows the image | photographing operation | movement in 2nd Embodiment. Explanatory drawing which shows the setting operation | movement of the irradiation condition of the X-ray in 3rd Embodiment.

  Hereinafter, a medical image photographing apparatus according to an embodiment will be described in detail with reference to the drawings. In addition, in each figure, the same code | symbol is attached | subjected about the same location.

(First embodiment)
FIG. 1 is a block diagram illustrating a configuration of a medical image photographing apparatus according to an embodiment. The medical imaging apparatus of FIG. 1 is an X-ray imaging apparatus 100 called an angio apparatus, for example, and includes an X-ray generation unit 10 that generates X-rays with respect to the subject P, and an X-ray that has passed through the subject P. Are two-dimensionally detected, and an X-ray detection unit 20 that generates X-ray projection data based on the detection result is provided.

  The X-ray generation unit 10 includes an X-ray irradiation unit having an X-ray tube 11 and an X-ray diaphragm 12, a high voltage control unit 13, and a high voltage generator 14. The X-ray tube 11 is a vacuum tube that generates X-rays, and accelerates electrons emitted from a cathode (filament) by a high voltage to collide with a tungsten anode to generate X-rays. The high voltage control unit 13 controls the high voltage generator 14 in accordance with an instruction signal from the system control unit 33 (described later), the tube current of the X-ray tube 11, the tube voltage, the X-ray pulse width, the irradiation period, the imaging period, Control of X-ray irradiation conditions including irradiation time and the like is performed.

  The X-ray detection unit 20 includes a first X-ray detector 211, a charge / voltage converter 22 that converts charges read from the first X-ray detector 211 into a voltage, and a charge / voltage converter 22. The A / D converter 23 that converts the output of the digital signal into a digital signal is output, and X-ray projection data is output from the A / D converter 23.

  The X-ray detection unit 20 includes a second X-ray detector 212. The second X-ray detector 212 has a smaller field of view than the first X-ray detector 211 but has a higher resolution. The second X-ray detector 212 is smaller in size than the first X-ray detector 211. The second X-ray detector 212 also converts a charge read from the second X-ray detector 212 into a voltage, and outputs the charge / voltage converter as a digital signal. An A / D converter for conversion is provided and X-ray projection data is output from the A / D converter, but for convenience, the charge / voltage converter and the A / D converter are not shown. Note that, as the first X-ray detector 211 and the second X-ray detector 212, an FPD (Flat Panel Detector) is generally used.

  The X-ray generator 10 and the X-ray detector 20 are supported by an arm (C arm) 24. The C-arm 24 can move in the body axis direction of the subject P placed on the couch top 25 and can rotate around the body axis of the subject P. The X-ray generation unit 10 and the X-ray detection unit 20 constitute an imaging unit 26. By rotating the C-arm 24, the imaging unit 26 rotates around the subject P and is observed from a plurality of different angular directions. The specimen P can be photographed.

  The X-ray image capturing apparatus 100 includes an image data storage unit 31, an image calculation unit 32, a system control unit 33, an operation unit 34, and a display unit 35. The image calculation unit 32 processes the X-ray projection data collected by the first X-ray detector 211 or the second X-ray detector 212 to generate image data. Further, image processing such as edge enhancement and S / N improvement is performed on the generated image data as necessary. The generated image data is stored in the image data storage unit 31. The image data stored in the image data storage unit 31 is read out as necessary, supplied to the display unit 35, and displayed.

  The system control unit 33 includes a CPU, a storage circuit (not shown), and an ABC circuit 331. Based on input information, setting information, and selection information supplied from the operation unit 34, X-ray imaging is performed via the bus line 39. Each unit of the apparatus 100 is controlled centrally.

  The operation unit 34 is used by a user such as an operator or doctor to input various commands, and has an interactive interface including an input device such as a mouse, a keyboard, a trackball, and a joystick, a display panel, and various switches. . Further, the operation unit 34 sets the moving direction and moving speed of the top board 25, sets the rotation / movement direction and rotation / moving speed of the imaging system, sets the X-ray irradiation conditions including tube voltage and tube current, and the like. Do.

  The display unit 35 includes a display data generation unit 36, a conversion unit 37, and a monitor 38 in order to display image data. The display data generating unit 36 generates display data by synthesizing incidental information with image data or converting the image data into a predetermined display format. The conversion unit 37 performs D / A (digital / analog) conversion and television format conversion on the display data to generate an image signal, and displays the image signal on a monitor 38 such as a liquid crystal display.

  In addition, the X-ray image capturing apparatus 100 includes a moving mechanism unit 40. The movement mechanism unit 40 includes a diaphragm movement control unit 41 and a mechanism control unit 42. The diaphragm movement control unit 41 performs movement control of the diaphragm blades and the like in the X-ray diaphragm 12, and the mechanism control unit 42 moves the movement mechanism 43 of the top plate 25, the imaging system movement mechanism 44, and the detector movement mechanism 45. Take control. The movement mechanism unit 40 operates in response to the operation of the operation unit 34, and performs movement control of each unit under the control of the system control unit 33.

  FIG. 2 is a perspective view showing the overall configuration of the X-ray imaging apparatus 100 (angio apparatus). In FIG. 2, the X-ray generation unit 10 and the X-ray detection unit 20 are supported by a C arm 24 so as to face each other. The X-ray detection unit 20 includes a first detector 211 and a second detector 212. A couch is arranged with respect to the C arm 24, and a subject (not shown) is placed on the couchtop 25 of the couch. Controlled by 1).

  The C arm 24 is supported by, for example, a rail provided on the ceiling, and is movable in the body axis direction from the head (Cranial) to the leg (Caudal) of the subject. The imaging unit 26 (the X-ray generation unit 10 and the X-ray detection unit 20) can rotate around the body axis around the body axis by the rotation of the C-arm 24. Further, the photographing unit 26 can be slid and rotated along the C arm 24.

  The X-ray projection data is processed by the image calculation unit 32 and the image data is displayed on the display unit 35. The display unit 35 is attached to, for example, a ceiling, and has three display units 351, 352, and 353 here. In addition, an operation unit 341 is attached to the bed, and in response to the operation of the operation unit 341, the system control unit 33 controls the height and position of the top board 25, controls the movement / rotation of the C arm 24, Adjustment of the X-ray irradiation range, control of irradiation timing, and the like are performed.

  FIG. 3 is a configuration diagram illustrating a main part of the medical image photographing apparatus according to the first embodiment. In FIG. 3, the X-ray tube 11, the first X-ray detector 211, the second X-ray detector 212, the high voltage generator 14, the C arm 24, the top plate 25 on which the subject P is placed, and the operation unit 341, display units 351 to 353, and an image processing unit 30 are shown. The image processing unit 30 includes an image data storage unit 31, an image calculation unit 32, and a system control unit 33.

  The second X-ray detector 212 is attached to the C arm 24, for example. The C arm 24 is provided with an attachment member 46, and the second X-ray detector 212 is supported by the attachment member 46 so as to be rotatable about a hinge 47. Therefore, the second X-ray detector 212 is normally located at a position outside the field of view of the first X-ray detector 211 (indicated by a dotted line) by rotating around the hinge 47 as a fulcrum, and if necessary It moves to a position (indicated by a solid line) that faces the X-ray tube 11.

  Note that the mounting position and rotation mechanism of the second X-ray detector 212 are not limited to the illustrated example, and are normally located outside the field of view of the first X-ray detector 211 and are selectively X-ray tubes. Any structure can be used as long as it can move to a position facing 11. Further, the position may be finely adjusted after moving to a position facing the X-ray tube 11.

  An image collected using the first X-ray detector 211 is displayed on the display unit 351, and a part of the image collected using the first X-ray detector 211 is enlarged on the display unit 352. An image collected using the second X-ray detector 212 is displayed on the display unit 353.

  Next, with reference to FIG. 4, an image capturing operation by the medical image capturing apparatus 100 according to the first embodiment will be described. FIG. 4A shows a state in which the real-time image 51 collected using the first X-ray detector 211 is displayed on the display unit 351. FIG. 4B shows a state in which the enlarged image 52 obtained by enlarging a part of the real-time image collected using the first X-ray detector 211 is displayed on the display unit 352. FIG. 4C shows a state in which the image 53 collected using the second X-ray detector 212 is displayed on the display unit 353.

  A frame image 54 showing the field of view of the second X-ray detector 212 when the second X-ray detector 212 is set is displayed on the real-time image 51 in the real-time image 51 of the display unit 351. Since the second X-ray detector 212 is set at a fixed position of the first X-ray detector 211, a frame image 54 indicating the visual field area of the second X-ray detector 212 is previously displayed in the image processing unit 30. It is generated by the (system control unit 33) and displayed on the real time image 51 in a superimposed manner.

  When the operator operates the operation unit 341 to move the top plate 25 and perform panning imaging, the real-time image 51 also varies with the movement of the top plate 25, but the visual field region of the second X-ray detector 212 is changed. The display position of the frame image 54 to be represented is fixed.

  The display unit 352 displays an enlarged image 52 obtained by digitally zooming the image in the region indicated by the frame image 54 in the real-time image 51. The enlargement ratio is set so that the enlarged image 52 has the same size as the image 53 collected by the second X-ray detector 212. Note that the image can be enlarged by capturing the real-time image 51 once in the image data storage unit 31 and enlarging the image data in the area indicated by the frame image 54 in the acquired image data in accordance with the display size of the display unit 352. .

  By observing the enlarged image 52 in this way, an image (an image of a region of interest to be examined) acquired when the subject is imaged using the second X-ray detector is displayed on the display unit 352 in a pseudo manner. Can be displayed. That is, the enlarged image 52 of the display unit 352 represents an image collected by the second detector 212 in a pseudo manner. Usually, since the size of the second X-ray detector 212 is considerably smaller than that of the first X-ray detector 211, the region of interest can be obtained only by looking at the image in the frame image 54 displayed on the display unit 351. Is difficult to determine, but it is easy to set the site of interest by displaying the enlarged image.

  Therefore, by comparing the image 52 and the image 51 on the display unit 352, the region to be imaged by the second X-ray detector 212 can be confirmed in advance. If the position is not the desired position, the top plate 25 is moved, and the images 52 and 51 are checked simultaneously, so that the position of the second X-ray detector 212 is adjusted and the second X-ray detector 212 is adjusted. The image 53 collected using the line detector 212 can be displayed on the display unit 353. The acquired image 53 obtained by the second X-ray detector 212 has a high resolution and is displayed on the display unit 353 so that the acquired image 53 is displayed in almost the same size as the enlarged image 52 of the display unit 352.

  As described above, in the first embodiment, when an X-ray image is collected using the second X-ray detector 212 having a smaller field of view than the first X-ray detector 211 but having a high resolution, A frame image 54 indicating the visual field area of the second X-ray detector 212 is superimposed on the acquired image 51 of the first X-ray detector and displayed. Further, by enlarging and displaying the image within this frame and displaying it on the display unit 352, the image collected by the second detector image 212 can be simulated and displayed in advance, and the second X-ray detector 212 can be displayed. Therefore, it is possible to easily perform alignment with the diagnostic region when collecting images.

  Since the second X-ray detector 212 is set at a fixed position with respect to the first X-ray detector 211, the total number of pixels in the image in the field of view of the second X-ray detector 212 and the first X-ray detector 212 are set. From the pixel pitch ratio of the first X-ray detector 211 and the second X-ray detector 212, the region of the frame image 54 drawn on the display unit 351 can be calculated. In addition, from the ratio of the pixel pitches of the first X-ray detector 211 and the second X-ray detector 212, it is calculated how many times the image data in the area of the frame image 54 drawn on the display unit 351 is enlarged. The enlarged image 52 with the calculated enlargement ratio can be displayed on the display unit 352.

(Second Embodiment)
Next, an image capturing operation performed by the medical image capturing apparatus 100 according to the second embodiment will be described. In the first embodiment, a partial image area of the real-time image 51 is enlarged and enlarged in real time, and the enlarged image 52 is displayed. However, in the second embodiment, the first X-ray detector 211 is used in advance. A pseudo image is generated and displayed based on the collected image.

  That is, as shown in FIG. 5A, the image 51 collected immediately before by the first X-ray detector 211 is reproduced on the display unit 351, and the second detector 212 of the second detector 212 is reproduced as in the first embodiment. A frame image 54 indicating the display area is displayed.

  Next, when the surgeon operates the operation unit 341 to move (pan) the top plate 25, the movement distance amount is calculated. The movement distance amount is calculated based on the movement amount when the top plate moving mechanism 43 is moved by the mechanism control unit 42. The calculated moving distance amount is sent to the image processing unit 30. In the image processing unit 30, the moving distance is converted into a numerical value of the number of pixels of the first X-ray detector 211.

  Then, as shown in FIG. 5A, the frame image 54 displayed on the display unit 351 is moved in units of pixels in accordance with the amount of movement of the top board 25. In FIG. 5A, an image 51 shows a reproduced image before moving the top board 25, and the center of the frame image 54 is at the intersection of the lines X0 and Y0. On the other hand, when panning is performed by moving the top plate 25, the center of the frame image 54 moves to the intersection of the axes X1 and Y1 according to the amount of movement, and the image processing unit 30 displays the area indicated by the moved frame image 54 ′. The image inside is digitally zoomed to display the enlarged image 52 on the display unit 352.

  Furthermore, after observing the image 51 and the enlarged image 52 and determining the position of the subject's attention site (the position of the top board 25), the second X-ray detector 212 is set. The display unit 353 displays the image 53 collected by the second X-ray detector 212. The acquired image 53 obtained by the second X-ray detector 212 has a high resolution and is displayed on the display unit 353 so that the acquired image 53 is displayed in almost the same size as the enlarged image 52 of the display unit 352. That is, the enlarged image 52 of the display unit 352 represents an image collected by the second detector 212 in a pseudo manner.

  When X-rays are always radiated when determining the region of interest, the exposure dose to the subject P increases. However, in the second embodiment, it is not always necessary to irradiate the X-rays. The amount can be reduced.

(Third embodiment)
Next, a third embodiment will be described with reference to FIG. The third embodiment relates to the setting of the X-ray irradiation conditions during image acquisition by the second X-ray detector 212.

  As shown in FIG. 6A, in the image acquisition by the first X-ray detector 211, the region of interest (ROI) 55 of the subject P is wide, and the region of interest (ROI) of the second X-ray detector 212 is narrow. That is, the range indicated by the frame image 54 is the region of interest (ROI) of the second X-ray detector 212. For this reason, the X-ray irradiation conditions for imaging using the first X-ray detector 211 cannot be applied to the irradiation conditions for imaging using the second X-ray detector 212 as they are.

  Therefore, in the third embodiment, first, the brightness level of the collected image of the first detector 211 is automatically adjusted by the ABC circuit 331 provided in the system control unit 33. The ABC (Auto Brightness Control) circuit 331 automatically adjusts the brightness level of the central area (ROI 55) of the fluoroscopic image data. When the brightness level is lower than the optimum level, the X-ray irradiation amount is increased. When the luminance level is higher than the optimum level, the tube voltage and tube current supplied to the X-ray tube 11 are set so as to reduce the X-ray irradiation amount, and the optimum level is maintained even if the diagnosis site of the subject P changes. To control.

  Then, the image processing unit 30 calculates a distribution ratio between the level distribution of the collected image of the region of interest 55 controlled by the ABC circuit 331 and the level distribution of the collected image of the region indicated by the frame image 54. That is, after measuring the pixel value distribution in the ROI 55 based on the acquired image of the first X-ray detector 211, the pixel value distribution of the image acquisition area (area of the frame image 54) of the second X-ray detector 212 is measured. To do.

  FIG. 6B shows the pixel value distribution by the collected image of the first detector 211, and FIG. 6C shows the pixel value distribution of the region indicated by the frame image 54. Next, a distribution ratio is calculated based on each pixel value distribution. For example, the ratio of the pixel values of the high frequency portions (S1 and S2) in the pixel value distributions of FIG. 6B and FIG. 6C is obtained, and the X-ray irradiation condition of the first X-ray detector 211 is obtained. The X-ray irradiation condition to the second X-ray detector 212 is calculated by multiplying the calculated distribution ratio.

  The image processing unit 30 stores information on the sensitivity ratio between the first X-ray detector 211 and the second X-ray detector 212. The sensitivity ratio is a ratio of output image signal levels when X-ray detectors 211 and 212 are respectively irradiated with X-rays. Therefore, the X-ray irradiation condition for the second X-ray detector 212 is set by multiplying the previously obtained X-ray irradiation condition for the second X-ray detector 212 by the sensitivity ratio.

  The image processing unit 30 constitutes a calculation unit that calculates a distribution ratio between the level distribution of the collected image of the region of interest of the subject obtained by the ABC circuit 331 and the level distribution of the collected image of the region indicated by the frame image. To do. Also, a setting unit for setting the X-ray irradiation condition for imaging using the second X-ray detector by multiplying the X-ray irradiation condition for imaging using the first X-ray detector by the distribution ratio. Configure.

  In this way, the X-ray irradiation conditions for the second X-ray detector 212 can be calculated in advance, and this can be used as an initial value. After the initial values are set, the tube current and tube voltage of the X-ray tube 11 need only be finely adjusted as necessary, and image acquisition using the second X-ray detector 212 can be easily performed. .

  As described above, according to the embodiment of the present invention, when the X-ray image is collected using the second X-ray detector having a higher resolution and a smaller field of view than the first X-ray detector, The field-of-view frame of the X-ray detector is displayed on the acquired image of the first X-ray detector, and the image in the frame is enlarged and displayed, whereby the image is acquired using the second X-ray detector. It is possible to easily perform alignment with the diagnostic area. In addition, it is possible to quickly set the X-ray condition when imaging using the second X-ray detector. Further, the exposure dose can be reduced and the inspection time can be shortened.

  As mentioned above, although several embodiment of this invention was described, these embodiment is shown as an example and is not intending limiting the range of invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the invention described in the claims and equivalents thereof as well as included in the scope and gist of the invention.

100 ... X-ray imaging apparatus (angio apparatus)
DESCRIPTION OF SYMBOLS 10 ... X-ray generation part 11 ... X-ray tube 20 ... X-ray detection part 211,212 ... 1st, 2nd X-ray detector 24 ... C arm 25 ... Top plate 26 ... Imaging | photography part 30 ... Image processing part 31 ... Image data storage unit 32 ... image calculation unit 33 ... system control unit 34 ... operation unit 353 (351, 352, 353) ... display unit 39 ... bus line 40 ... movement mechanism unit 45 ... detector movement mechanism

Claims (9)

An X-ray generation unit that includes an X-ray tube that generates X-rays and exposes the subject to X-rays, a first X-ray detector that detects X-rays transmitted through the subject, and the first X-rays A second X-ray detector for detecting X-rays transmitted through the subject at a fixed position within the field of view of the first X-ray detector and having a high resolution with a smaller field of view than the line detector An imaging unit for imaging the subject;
Based on the first real-time image data collected using the first X-ray detector, a frame image indicating a visual field region by the second X-ray detector is generated, and the first image data An image processing unit for enlarging the image data of the region indicated by the frame image,
A first display unit that displays the frame image superimposed on a first image based on the first image data;
A second display unit that displays, in a pseudo manner, an image collected when the subject is imaged using the second X-ray detector, using the enlarged image;
A medical image photographing apparatus comprising:   The second X-ray detector has a position outside the field of view of the first X-ray detector and a fixed position within the field of view of the first X-ray detector and facing the X-ray tube. The medical image photographing apparatus according to claim 1, wherein the medical image photographing apparatus is selectively movable. A third display unit that displays a second image based on real-time second image data collected when the subject is imaged using the second X-ray detector;
The medical image photographing apparatus according to claim 1, wherein the first and third display units are arranged so that the first image on which the frame image is superimposed and the second image can be compared. A storage unit for storing first image data collected using the first X-ray detector;
When panning is performed using the first detector by relatively moving the top plate on which the subject is placed and the imaging unit, the image processing unit moves the storage unit in accordance with the movement by the panning. Moving the frame image area on the first image data stored in the first image data, expanding the image data of the area indicated by the moved frame image in the first image, and The medical image photographing device according to claim 1 displayed on the screen. An ABC circuit for automatically adjusting the brightness level of the acquired image by controlling the X-ray irradiation conditions when imaging using the first X-ray detector;
A calculation unit that calculates a distribution ratio between the level distribution of the collected image of the region of interest of the subject obtained by the ABC circuit and the level distribution of the collected image of the region indicated by the frame image;
Setting for setting the X-ray irradiation condition when imaging using the second X-ray detector by multiplying the X-ray irradiation condition when imaging using the first X-ray detector by the distribution ratio And a medical image photographing apparatus according to claim 1.   The setting unit further multiplies the distribution ratio calculated by the calculation unit by a sensitivity ratio between a detection sensitivity of the first X-ray detector and a detection sensitivity of the second X-ray detector, and The medical image photographing apparatus according to claim 5, wherein X-ray irradiation conditions for photographing using the X-ray detector of 2 are set. An X-ray generator that exposes the subject to X-rays, a first X-ray detector that detects X-rays transmitted through the subject, and a smaller field of view and higher resolution than the first X-ray detector And a second X-ray detector for detecting X-rays transmitted through the subject at a fixed position within the field of view of the first X-ray detector, and an imaging unit for imaging the subject Prepared,
Generating a frame indicating a visual field region by the second X-ray detector based on real-time first image data collected using the first X-ray detector;
The image data of the area within the frame in the first image data is enlarged,
While viewing the pseudo image that would be obtained when the second X-ray detector is arranged by pseudo display on the display unit using the enlarged image, the second X-ray is obtained in advance. A medical image capturing method for determining the position of a detector. Storing the first image data collected using the first X-ray detector in a storage unit;
When the pan on which the subject is placed and the imaging unit are moved relative to each other and panned using the first detector, the first stored in the storage unit in accordance with the movement due to the panning. The frame image area on the image data is moved, and the image of the area indicated by the moved frame image in the first image data is enlarged and displayed on the display unit, and the second X 8. The medical image photographing method according to claim 7, wherein the position of the second X-ray detector is determined in advance while observing a pseudo image that will be obtained when the line detector is arranged. The X-ray irradiation conditions when taking an image using the first X-ray detector are controlled by the ABC circuit to automatically adjust the brightness level of the collected image,
Calculating a distribution ratio between the level distribution of the collected image of the region of interest of the subject obtained by the ABC circuit and the level distribution of the collected image of the region indicated by the frame image;
Claims: X-ray irradiation conditions for imaging using the second X-ray detector are set by multiplying the X-ray irradiation conditions for imaging using the first X-ray detector by the distribution ratio. Item 8. A medical image photographing method according to Item 7.