JP2017035411A - Mammography apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mammography apparatus capable of thinning thickness of the apparatus.SOLUTION: The mammography apparatus is capable of performing first imaging which images a mamma of a subject on a first side in a state of compressing the mamma with a compression plate and second imaging which images the mamma of the subject on a second side opposite to the first side in a state of holding the mamma with a holding base. The mammography apparatus includes: a first radiation generation part including an electronic beam generation part generating radiation in the first imaging; and a second radiation generation part including an electronic beam part generating radiation in the second imaging. The electronic beam generation part of the second radiation generation part is arranged in a state of being inclined with respect to the electronic beam generation part of the first radiation generation part.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a mammography apparatus that performs mammography using radiation.

  In Patent Document 1, as a mammography apparatus, a radiation generating unit and a radiation detection unit are rotated by a rotating unit, and a function of photographing a breast by CBCT (Cone-Beam CT) and a mammogram photographing by fixing a breast with two plates are disclosed. The structure which has the function to perform is disclosed. In the configuration of Patent Document 1, a subject stands on the front of the apparatus, and mammogram imaging or CBCT imaging is performed with the breast fixed between two plates.

Special table 2013-538668 gazette

  However, in the configuration of Patent Document 1, when performing CT imaging, since the subject's breast is fixed between the two plates, imaging is performed with the subject's breast properly held. Is difficult. Patent Document 1 discloses a configuration of an apparatus that performs mammogram imaging from the first side of the apparatus and CBCT imaging from the second side opposite to the first side while appropriately holding the breast of the subject. Is not disclosed. As described above, in the device configuration in which each image is taken from both sides of the device, the thickness in the front-rear direction of the device may increase, so that it may be difficult to access the breast, and the operation efficiency of the operator may be reduced. .

  An object of the present invention is to provide a mammography apparatus capable of reducing the thickness of the apparatus in view of the above problems.

In order to achieve the object of the present invention, a mammography apparatus according to an aspect of the present invention includes a first imaging for imaging in a state where a breast of a subject is compressed with a compression plate on a first side; A mammography apparatus capable of performing a second imaging in which the breast of the subject is captured by a holding table on a second side opposite to the first side,
In the first imaging, a first radiation generation unit having an electron beam generation unit for generating radiation,
In the second imaging, a second radiation generation unit having an electron beam generation unit for generating radiation,
The electron beam generating unit of the second radiation generating unit is disposed in an inclined state with respect to the electron beam generating unit of the first radiation generating unit.

  According to the present invention, the mammography apparatus can be thinned.

The figure which shows the structure of the mammography apparatus which concerns on 1st Embodiment. The figure which shows the structure of the electron beam and cathode of the mammography apparatus which concerns on 1st Embodiment. The figure which shows the structure of the mammography apparatus which concerns on 2nd Embodiment. The figure which shows the structure of the attachment or detachment mechanism of the compression board of the mammography apparatus which concerns on 2nd Embodiment. The figure which shows the modification of the mammography apparatus which concerns on 2nd Embodiment. The figure which shows the structure of the mammography apparatus of 3rd Embodiment. The figure which shows the modification of the mammography apparatus which concerns on 3rd Embodiment.

  Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the drawings. However, the components described in this embodiment are merely examples, and the technical scope of the present invention is determined by the scope of the claims, and is not limited by the following individual embodiments. Absent.

(First embodiment)
In the first embodiment, a mammography apparatus 100 capable of performing mammogram imaging and CBCT (Cone-Beam CT) imaging will be described. The mammography apparatus includes a first imaging for imaging a subject's breast on a first side with a compression plate, and a breast on the subject on a second side opposite to the first side. It is possible to perform the second imaging in which the image is captured while being held by the holding table. Here, the mammography apparatus includes a first radiation generation unit having an electron beam generation unit that generates radiation in the first imaging, and a second radiation unit having an electron beam generation unit that generates radiation in the second imaging. A radiation generating unit. The electron beam generation unit of the first radiation generation unit has a cathode that generates an electron beam to be irradiated to the target of the anode unit in the first imaging, and the electron beam generation unit of the second radiation generation unit In the second imaging, a cathode for generating an electron beam for irradiating the target of the anode part is provided.

  FIG. 1 is a diagram illustrating a configuration of a mammography apparatus according to the first embodiment. In FIG. 1, the first side is the rear side of the mammography apparatus, and the second side is the front side of the mammography apparatus. In the following description, the first imaging is mammogram imaging, and the second imaging is CT imaging (CBCT imaging). FIG. 1A shows a perspective view from the front of the mammography apparatus during radiography. FIG. 1B shows a side view of the mammography apparatus of FIG. FIG.1 (c) has shown the perspective view from the back of the mammography apparatus of Fig.1 (a).

  The mammography apparatus mainly includes a fixing unit 5 fixed to the ground or floor, a gantry support unit 4 standing on the fixing unit 5 in a direction perpendicular to the ground or floor, and a gantry support unit 4. And a rotating frame 3 which is rotatably installed. The mammography apparatus is installed on the rotating frame 3 and generates a radiation for use in mammogram imaging, and a first radiation for detecting radiation generated by the first radiation generation unit 1. And a detector 2. Further, the mammography apparatus is installed on the rotating frame 3 and generates a radiation used for CBCT imaging, and a second radiation for detecting radiation generated by the second radiation generator 6. And a detector 7. The rotating frame 3 rotatably holds the first radiation generating unit 1 and the first radiation detecting unit 2 that detects the radiation generated by the first radiation generating unit 1 in an opposed state, and The second radiation generation unit 6 and the second radiation detection unit 7 that detects the radiation generated by the second radiation generation unit 6 are rotatably held in a state of facing each other.

  In FIG. 1B, the left side of the apparatus corresponds to the front of the mammography apparatus, and the right side of the apparatus corresponds to the rear of the mammography apparatus. In FIG. 1B, the width in the front-rear direction indicates the thickness of the mammography apparatus. In CBCT imaging, the subject accesses the mammography apparatus from the front side, and in mammogram imaging, the subject accesses the mammography apparatus from the rear side. Also, SID (Source to Image Distance) is different between CBCT imaging and mammogram imaging, and it is assumed that SID is 400 to 500 mm in CBCT imaging and about 650 mm in mammogram imaging. As a result, in the CT apparatus composed of a plurality of radiation generating units in the prior art, the SID is constant, and the mammography unique apparatus configuration is clearly different from the CT apparatus.

  The first radiation generation unit 1 and the second radiation generation unit 6 generate radiation, and include a radiation tube that irradiates radiation, a diaphragm for limiting the radiation irradiation region, and the like.

  The first radiation detection unit 2 detects the radiation emitted from the first radiation generation unit 1, and the second radiation detection unit 7 detects the radiation emitted from the second radiation generation unit 6.

  The rotating frame 3 supports the first radiation generation unit 1 and the first radiation detection unit 2, the second radiation generation unit 6 and the second radiation detection unit 7 in a rotatable state. The rotating frame 3 supports the radiation irradiation direction of the first radiation generation unit 1 and the radiation detection surface of the first radiation detection unit 2 so as to face each other. The rotating frame 3 supports the radiation irradiation direction of the second radiation generation unit 6 and the radiation detection surface of the second radiation detection unit 7 so as to face each other.

  The rotating frame 3 is centered on the rotating shaft 11 while supporting the first radiation generating unit 1 and the first radiation detecting unit 2, the second radiation generating unit 6 and the second radiation detecting unit 7. It is configured to be rotatable. The rotating frame 3 has a donut-shaped hollow shape, and the outer shape thereof is particularly cylindrical. The cylindrical axis of the outer shape of the rotating frame 3 coincides with the rotating shaft 11. By rotating the rotating frame 3, a CT image is captured by 360 ° rotation during CBCT imaging, and CC (head-to-tail direction) imaging and MLO (inside / outside oblique direction) imaging are switched during mammogram imaging.

  The gantry support 4 supports the rotating frame 3. The gantry support part 4 has a rotating part that rotates the rotating frame 3 around the rotating shaft 11 shown in FIG. Specifically, as a configuration of the rotating part, a motor is arranged in the vicinity of the fixed part 5 inside the gantry support part 4, and a timing pulley is arranged on the rotating shaft of the motor. Grooves having the same pitch as the timing pulley of the rotating shaft of the motor are provided in the outer shape (outer peripheral portion) of the rotating frame 3. A rotation transmission member (for example, a timing belt) is wound between the outer shape (outer peripheral portion) of the rotating frame 3 and the timing pulley. The rotation of the rotating shaft of the motor is transmitted to the outer shape (outer peripheral portion) of the rotating frame 3 via the timing pulley and the rotation transmitting member (timing belt), and the rotating frame 3 is rotated by the rotating shaft 11 according to the rotation of the rotating shaft of the motor. Rotate around. Thus, by driving the motor, the rotating frame 3 can be rotated about the rotating shaft 11.

  Further, a rotation support member (for example, a bearing) may be disposed between the rotation frame 3 and the gantry support portion 4 so that the rotation of the rotation frame 3 is smooth. Further, instead of the timing belt, a chain may be used as the rotation transmission member. In that case, the timing pulley may be replaced with a sprocket.

  The fixing portion 5 supports the gantry support portion 4. The gantry support part 4 may have an elevating part that can extend and contract in the vertical direction with respect to the ground or the floor surface with respect to the fixed part 5. Thereby, the gantry support part 4 can change the height of an apparatus by expansion-contraction of an raising / lowering part, and can image | photograph according to the height of a subject.

  The compression plate 8 is supported by the rotating frame 3. In mammogram photography, the subject's breast is sandwiched between the compression plate 8 and the first radiation detection unit 2, and the breast is fixed to acquire an image. The compression plate 8 has a moving unit that can change the distance to the first radiation detection unit 2 on the rotating frame 3.

  A front cover 9 is detachably provided on the second side, and the front cover 9 is provided with a holding base 10 for holding the breast of the subject entered through the opening. As shown in FIG. 1A, the front cover 9 is fixedly supported by the gantry support portion 4. The outer shape of the front cover 9 has a shape including the outermost outer shape of the exposed portion of the rotating frame 3. An opening is formed in the center portion of the front cover 9.

  The holding table 10 supports the subject's breast at the time of imaging and fixes the position of the breast. The holding table 10 is fixedly supported by the front cover 9. The subject puts the breast into the opening of the front cover 9 and places the breast on the holding table 10 at the time of CBCT imaging. Then, CBCT imaging is performed by acquiring an image while rotating the rotating frame 3. Thereby, the front cover 9 can prevent the subject from entering the rotation operation area of the rotating frame 3 at the time of CBCT imaging.

(Arrangement of the first radiation generating unit 1 and the second radiation generating unit 6)
In FIG. 1, the schematic configuration in which the first radiation generation unit 1 and the second radiation generation unit 6 are arranged in the thickness direction of the apparatus has been described. That is, in FIG. 1, the first radiation generation unit 1 and the second radiation generation unit 6 are arranged on the rotating frame 3 with no deviation in the arrangement angle around the rotation axis 11 of the rotating frame 3. The general configuration of the state has been described.

  Therefore, each configuration and arrangement of the first radiation generation unit 1 and the second radiation generation unit 6 will be described in detail with reference to FIG. FIG. 2 is a diagram showing the configuration of the electron beam and the cathode of the mammography apparatus according to the present embodiment. FIG. 2A is a cross-sectional view of the first radiation generating unit 1 and the second radiation generating unit 6 as viewed from the side of the mammography apparatus. FIG. 2B is a diagram showing a configuration example in which two rotating anode type radiation generating units are arranged as a reference example. As shown in FIG. 2A, in the mammography apparatus of the present embodiment, the electron beam generator 106 of the second radiation generator 6 is compared with the electron beam generator 101 of the first radiation generator 1. It is arranged in an inclined state. Specifically, in the mammography apparatus of the present embodiment, the electron beam generator 106 of the second radiation generator 6 is inclined downward with respect to the electron beam generator 101 of the first radiation generator 1. It is arranged with. That is, the electron beam generating unit 106 is arranged in a state inclined downward with respect to the electron beam generating unit 101.

  In the configuration as shown in FIG. 2A, the electron beam 14 generated by the electron beam generator 101 of the first radiation generator 1 and the electron beam generator 106 of the second radiation generator 6 are generated. The first radiation generation unit and the second radiation generation unit are configured so that the electron beam 14 is not placed on the same straight line. That is, the electron beam generating unit 106 of the second radiation generating unit 6 and the electron beam generating unit 101 of the first radiation generating unit 1 are arranged so that the generated electron beams do not lie on the same straight line.

  In other words, the electron beam 14 generated by the electron beam generator 106 of the second radiation generator 6 is generated by the electron beam generator 101 of the first radiation generator 1. The first radiation generation unit 1 and the second radiation generation unit 6 are configured so as not to be parallel to the electron beam 14. That is, the electron beam generating unit 106 of the second radiation generating unit 6 and the electron beam generating unit 101 of the first radiation generating unit 1 are arranged so that the generated electron beams are not parallel.

  2A, the axis of the cathode 12 in the electron beam generator 101 of the first radiation generator 1 and the axis of the cathode 12 in the electron beam generator 106 of the second radiation generator 6 Are arranged on the same straight line, the first radiation generation unit 1 and the second radiation generation unit 6 are configured. That is, the electron beam generating unit 106 of the second radiation generating unit 6 and the electron beam generating unit 101 of the first radiation generating unit 1 are arranged so that the axes of the respective cathodes 12 are not placed on the same straight line. .

  In other words, the axis of the cathode 12 in the electron beam generating unit 101 of the first radiation generating unit 1 and the axis of the cathode 12 in the electron beam generating unit 106 of the second radiation generating unit 6 The first radiation generating unit 1 and the second radiation generating unit 6 are configured so that the two are not parallel. That is, the electron beam generating unit 106 of the second radiation generating unit 6 and the electron beam generating unit 101 of the first radiation generating unit 1 are arranged so that the axes of the respective cathodes 12 are not parallel.

  In mammogram photography, since a single still image is taken for each radiation exposure, a large output is required during radiation exposure. Since the rotary anode type radiation generator can output a large output, the mammography apparatus of the present embodiment includes a rotary anode type radiation generator as a configuration of the first radiation generator 1 for mammogram imaging. It is possible to use. If the output required for mammogram imaging is sufficient, other types of radiation generating units can be used, and the present invention is not limited to the rotary anode type radiation generating unit.

  The first radiation generation unit 1 in FIGS. 2A and 2B has a structure of a rotary anode type radiation generation unit. That is, the anode part of the first radiation generating part 1 is a rotary anode type. The cathode 12 has a cylindrical shape, and has a cathode portion inside the cylindrical shape. The electron beam 14 is irradiated from the cathode portion of the cathode 12 toward the target 21 of the rotating anode portion 13 along the axis of the cathode 12. In the first radiation generating unit 1, the rotating anode unit 13 is rotatably held, and the rotating anode unit 13 is centered on the central axis of the rotating anode unit 13 at least while the electron beam 14 is irradiated. Rotating. Radiation 16 is generated by the electron beam 14 that has collided with the target 21 of the rotating anode portion 13. The cathode 12 of the first radiation generating unit 1 is disposed at a position closer to the subject than the anode part of the first radiation generating unit 1.

  Further, the mammography apparatus of the present embodiment can use a fixed anode type radiation generator as the configuration of the second radiation generator 6 for CBCT imaging. The structure of the fixed anode type radiation generation unit can reduce the distance from the front of the apparatus on the side where the subject stands at the time of imaging to the radiation irradiation region, compared to the structure of the rotary anode type radiation generation unit, A portion close to the chest wall of the subject's breast can be photographed.

  In addition, as long as the distance from the front surface of the apparatus to the radiation irradiation region can be made smaller than the structure of the rotary anode type radiation generation unit, other types may be used and the invention is not limited to the fixed anode type.

  The second radiation generation unit 6 in FIG. 2A has a structure of a fixed anode type radiation generation unit. That is, the anode part of the second radiation generating part 6 is a fixed anode type. The cathode 12 is horizontally disposed in the rotary anode type radiation generating unit, whereas the cathode 12 is disposed in an inclined state in the fixed anode type radiation generating unit. Specifically, the cathode 12 is arranged in a state where it is inclined downward from the horizontal direction by an inclination angle α (for example, about 15 °). The electron beam 14 is irradiated from the cathode portion of the cathode 12 toward the target 22 of the fixed anode portion 15 along the axis of the cathode 12. The fixed anode part 15 is fixedly arranged in the second radiation generating part 6. Radiation 16 is generated by the electron beam 14 colliding with the target 22 of the fixed anode portion 15. The anode part of the second radiation generating unit 6 is arranged at a position closer to the subject than the cathode 12 of the second radiation generating part 6. The fixed anode type radiation generation unit can be configured to have a thinner apparatus in the left-right direction in FIG. 2A than the rotary anode type radiation generation unit, as the cathode 12 is inclined.

  In the rotating anode type radiation generator in the apparatus configuration of the reference example as shown in FIG. 2B, the axis of the cathode 12 and the electron beam 14 are located on the same straight line. On the other hand, as shown in FIG. 2A, in the apparatus configuration of the present embodiment, a fixed anode type radiation generation unit (second radiation generation unit 6) and a rotary anode type radiation generation unit (first The radiation generating part 1) is arranged side by side. In the apparatus configuration having such an arrangement, the axis of the cathode 12 and the electron beam 14 are not located on the same straight line, and are not parallel. Compared to the device configuration in which two rotating anode type radiation generating units are arranged on the same straight line as shown in FIG. 2B, the device configuration shown in FIG. The thickness of the part 4 in the front-rear direction can be reduced.

  Further, the target 21 of the rotary anode part 13 of the first radiation generating part 1 of the present embodiment is arranged at a position in the direction from the rear to the front of the apparatus. The target 22 of the fixed anode part 15 of the second radiation detection part 7 is arranged on the front side of the apparatus. In this way, by arranging the target, it is possible to realize a mammography apparatus that can perform CBCT imaging from the front surface and mammogram imaging from the rear surface while making the thickness of the apparatus in the front-rear direction thin. .

  The first radiation generation unit 1 and the second radiation generation unit 6 generate radiation having a spread from the direction vertically below the target toward the direction inside the apparatus 25 based on the electron beam irradiated to the target. It is possible to make it. Specifically, in the first radiation generation unit 1 and the second radiation generation unit 6, the irradiated radiation is an electron beam angle, an angle of an anode portion on which the electron beam strikes, or an aperture of the radiation generation unit. Thus, irradiation control is performed. For example, as shown in FIG. 2A, the radiation 16 irradiated by the first radiation generating unit 1 is irradiated vertically downward on the rear surface side of the apparatus (outside the rotating frame 3). The radiation 16 irradiated by the first radiation generating unit 1 is irradiated so as to spread toward the inside of the apparatus inside the apparatus (inside the rotating frame 3), and the irradiation range of the apparatus is Spreads in the inside.

  Further, the radiation 16 irradiated by the second radiation generating unit 6 is irradiated vertically downward on the front side of the apparatus (outside the rotating frame 3). In addition, the radiation 16 irradiated by the second radiation generator 6 is irradiated so as to spread toward the inside of the apparatus inside the apparatus (inside the rotating frame 3), and the irradiation range of the apparatus is Spreads in the inside. Accordingly, when the breast of the subject is photographed from the front or rear surface of the mammography apparatus, the blind area can be eliminated as much as possible with respect to the breast whose thickness increases toward the front or back of the mammography apparatus. .

  According to the configuration of the present embodiment, in mammogram imaging, a subject's breast can be held with a compression plate, and in CT imaging, imaging can be performed while being held on a holding table. Shooting can be performed in a held state. According to the configuration of the present embodiment, the thickness of the device can be reduced in the configuration of the device. Further, the accessibility of the subject to the breast is improved, and the operation efficiency of the operator can be improved.

(Second Embodiment)
In the second embodiment, a configuration of a mammography apparatus in which the thickness of the mammography apparatus is further reduced will be described. FIG. 3 is a diagram illustrating a configuration of the mammography apparatus according to the second embodiment. FIG. 3A shows a perspective view from the rear of the mammography apparatus. FIG. 3B shows a rear view (rear front view) of the mammography apparatus during mammogram photography. FIG. 3C shows a rear view (rear front view) of the mammography apparatus in a state where the rotating frame 3 shown in FIG. 3B is rotated at an arbitrary angle.

  In FIG. 3, the same components as those of the mammography apparatus shown in FIG. 1 (first radiation generating unit 1 to rotating shaft 11) are denoted by the same reference numerals, and description thereof is omitted to avoid duplication. To do. The mammography apparatus includes a first imaging for imaging a subject's breast on a first side with a compression plate, and a breast on the subject on a second side opposite to the first side. It is possible to perform the second imaging in which the image is captured while being held by the holding table. Here, the mammography apparatus includes a first radiation generation unit 1 that generates radiation in the first imaging, a second radiation generation unit 6 that generates radiation in the second imaging, and a first radiation generation unit. A rotating unit (rotating frame 3) that rotatably holds the first and second radiation generating units 6. In the mammography apparatus of the present embodiment, the first radiation generation unit 1 and the second radiation generation unit 6 rotate with their arrangement angles shifted from each other about the rotation axis of the rotation unit (rotation frame 3). Is disposed on the portion (rotating frame 3).

  The CT sensor support unit 17 is a member that supports the second radiation detection unit 7. The CT sensor support portion 17 is disposed on the inner peripheral surface of the rotating frame 3. When switching from mammogram imaging to CBCT imaging, the second radiation generation unit 6 is moved to an arbitrary initial position as a CT imaging start position by rotating the rotating frame 3 by an appropriate angle from FIG. Let

  In the configuration of the mammography apparatus of the second embodiment, the first radiation generating unit 1 and the second radiation generating unit 6 are shifted by a predetermined arrangement angle around the rotation axis of the rotating frame 3. 3 is arranged. Specifically, the interval (arrangement angle) between the first radiation generation unit 1 and the second radiation generation unit 6 with respect to the rotating frame 3 is shifted by an interval (arrangement angle) β ° about the rotation axis 11. It is arranged. In 1st Embodiment, the 1st radiation generation part 1 and the 2nd radiation generation part 6 demonstrated the structure (series arrangement structure) arrange | positioned in series along the thickness direction of a mammography apparatus. In 2nd Embodiment, since the space | interval (arrangement angle) of the 1st radiation generation part 1 and the 2nd radiation generation part 6 is shifted and arrange | positioned, it is 1st in the circumferential direction of the internal peripheral surface of the rotation frame 3. It is possible to arrange the one radiation generation unit 1 and the second radiation generation unit 6 side by side. That is, the first radiation generation unit 1 and the second radiation generation unit 6 are arranged in parallel along the circumferential direction of the inner peripheral surface of the rotating frame 3 that intersects the thickness direction of the mammography apparatus. This is the configuration (parallel arrangement configuration). For this reason, in the configuration of the second embodiment, the thickness of the mammography apparatus can be further reduced compared to the thickness in the configuration of the mammography apparatus described in the first embodiment. Become.

  In FIG. 3B, the first radiation generating unit 1 can be configured as a rotary anode type radiation generating unit as described in the first embodiment, but is limited to this example. Instead, the first radiation generating unit 1 can be configured as a fixed anode type radiation generating unit. The second radiation generation unit 6 can be configured as a fixed anode type radiation generation unit, but is not limited to this example, and the second radiation generation unit 6 is a rotary anode type radiation generation unit. It is also possible to configure the generator 6. The configurations of the rotary anode type radiation generating unit and the fixed anode type radiation generating unit are as described in the first embodiment. In the first radiation generation unit 1 and the second radiation generation unit 6 arranged with a gap (arrangement angle) β ° about the rotation axis 11, the straight line passing through the cathode axis and the electron beam trajectory intersects each other. There is nothing.

  In order to prevent interference between the compression plate 8 and the second radiation detection unit 7 by reducing the thickness of the device, the compression plate 8 and the second radiation detection unit 7 can be configured to be detachable. For example, for the second radiation detection unit 7, the second radiation detection unit 7 and the CT sensor support unit 17 are provided with a lock mechanism by engagement between the groove and the protrusion, thereby providing a second radiation detection unit 7. Can be configured to be detachable from the CT sensor support portion 17.

  FIG. 4 is a diagram showing a configuration of an attachment / detachment mechanism for the compression plate 8 of the mammography apparatus according to the second embodiment. FIG. 4A shows a state where the compression plate 8 is removed from the state of FIG. FIG. 4B shows a cross-sectional view of the side surface of the device near the compression plate 8. In FIG. 4B, the compression plate 8 is supported by the compression plate support portion 18. The first radiation detection unit 2 has an attachment / detachment mechanism that attaches / detaches the compression plate support 18 that supports the compression plate 8. The compression plate 8 is configured to be slidable in the vertical direction in FIG. 4B with respect to the compression plate support 18. The compression plate 8 can be detached from the first radiation detection unit 2 together with the compression plate support unit 18. By removing the compression plate 8 and the compression plate support 18, interference with the second radiation detection unit 7 can be prevented. As shown in FIG. 4B, the compression plate support portion 18 has an L-shape, and a tapered portion 401 is provided below the lower L-shaped tip portion. In the first radiation detection unit 2, a tapered portion 402 is provided in a concave portion that fits with the tapered portion 401 of the L-shaped tip portion of the compression plate support portion 18. At the time of attachment, the taper part 401 of the compression plate support part 18 is guided by the taper part 402 of the first radiation detection part 2 and positioned at the fitting position. And the compression board support part 18 and the 1st radiation detection part 2 are fastened by the fastening part 19 which is a screw and a pin.

  At the time of removal, by removing the fastening portion 19, the compression plate support portion 18 is lowered by its own weight, and the fitting between the concave portion of the first radiation detection unit 2 and the L-shaped tip portion of the compression plate support portion 18 is released. The compression plate support 18 can be smoothly removed from the first radiation detection unit 2. The compression plate 8 can receive a pressure of 150 N to 200 N, for example. With the above configuration, there is no backlash with respect to the pressure applied to the compression plate 8, high rigidity after fastening can be realized, and the attachment / detachment mechanism of the compression plate 8 with good operability that can also be smoothly attached and detached is realized. can do. The mammography apparatus can be thinned without interference by the second radiation detector 7 and the attachment / detachment mechanism of the compression plate 8.

  FIG. 5 is a diagram showing a modification of the interval (arrangement angle) between the first radiation generation unit 1 and the second radiation generation unit 6, and in FIG. 5, the arrangement angle is 90 ° (β = 90 °). The case of is illustrated. FIG. 5A shows a perspective view from the rear of the mammography apparatus. FIG. 5B shows a rear view (rear front view) of the mammography apparatus during mammogram photography. FIG. 5C shows a rear view (rear front view) of the mammography apparatus during CBCT imaging.

  By setting β = 90 °, the irradiation axis of the first radiation generation unit 1 and the irradiation axis of the second radiation generation unit 6 are arranged at intervals of 90 degrees around the rotation axis 11 of the rotating frame 3. . By adopting such an arrangement interval, the first radiation generator 1, the second radiation generator 6, the first radiation detector 2, and the second radiation detector are arranged on the rotating frame 3 at equal intervals. The part 7 is arranged. Thus, by arranging the arrangement intervals at equal intervals, it is possible to distribute the load applied to the gantry support portion 4 from the rotating frame 3. Further, deterioration of the rotating mechanism of the rotating frame 3 can be suppressed, and the life of the rotating mechanism of the rotating frame 3 in the mammography apparatus can be extended.

(Third embodiment)
In the third embodiment, based on the configuration of the mammography apparatus described in the second embodiment, a configuration of a mammography apparatus having excellent accessibility to the breast at the time of imaging will be described.

  FIG. 6 is a diagram illustrating a configuration of a mammography apparatus according to the third embodiment. FIG. 6A shows a rear view (rear front view) of the mammography apparatus. FIG. 6B shows a perspective view from the rear of the mammography apparatus during mammogram photography. FIG. 6C shows a perspective view from the rear of the mammography apparatus in a state where the rotary frame 3 shown in FIG. In FIG. 6, the same configuration as the configuration of the mammography apparatus shown in FIG. 1 (first radiation generation unit 1 to rotating shaft 11) is denoted by the same reference numeral, and description thereof is omitted to avoid duplication. To do.

  When switching from mammogram imaging to CBCT imaging, the second radiation generation unit 6 is moved to an arbitrary initial position as a CT imaging start position by rotating the rotating frame 3 by an appropriate angle from FIG. 6B. Let Further, with emphasis on accessibility to the holding table 10 at the time of CBCT imaging, it is used in the state of FIG. 6B, or the rotating frame 3 is rotated by 180 ° and used in the state of FIG. 6C. You may do it. In the configuration of the mammography apparatus of the third embodiment, the first radiation generating unit 1 and the second radiation generating unit 6 are arranged on the opposite side of the rotating frame 3. That is, in the configuration of the mammography apparatus of the third embodiment, the interval (arrangement angle) between the first radiation generation unit 1 and the second radiation generation unit 6 with respect to the rotation frame 3 is centered on the rotation axis 11. The interval (arrangement angle) is shifted by 180 °.

  In FIG. 6, the first radiation generating unit 1 can be configured as a rotary anode type radiation generating unit as described in the first embodiment, but is not limited to this example. It is also possible to configure the first radiation generating unit 1 as a fixed anode type radiation generating unit. The second radiation generation unit 6 can be configured as a fixed anode type radiation generation unit, but is not limited to this example, and the second radiation generation unit 6 is a rotary anode type radiation generation unit. It is also possible to configure the generator 6. The configurations of the rotary anode type radiation generating unit and the fixed anode type radiation generating unit are as described in the first embodiment.

  According to the configuration shown in FIG. 6, the straight line connecting the target 21 of the anode part of the first radiation generator 1 and the target 22 of the anode part of the second radiation generator 6 is connected to the rotation axis 11 of the rotary frame 3. The first radiation generating unit 1 and the second radiation generating unit 6 are arranged on the rotating frame 3 so as to cross each other. The first radiation generating unit 1 and the first radiation generating unit 1 so that a straight line connecting the target 21 of the first radiation generating unit 1 and the target 22 of the second radiation generating unit 6 intersects at the intersection 20 passing on the rotation axis 11 of the rotating frame 3. A second radiation generating unit 6 is disposed on the rotating frame 3. The distance from the target 21 of the anode part of the first radiation generating unit 1 to the rotating shaft 11 of the rotary frame 3 is different from the distance from the target 22 of the anode part of the second radiation generating unit 6 to the rotating shaft 11. As described above, the first radiation generating unit 1 and the second radiation generating unit 6 are arranged on the rotating frame 3.

  With the above configuration, as shown in FIG. 6, it is possible to secure a space in the left and right regions of the holding base 10 while maintaining the thinness of the device as compared with the configuration of the mammography device of the second embodiment. It is possible to facilitate access to the breast of the subject by the operator during CBCT imaging.

  FIG. 7 is a diagram illustrating a modification of the mammography apparatus according to the third embodiment. FIG. 7A shows a rear view (rear front view) of the mammography apparatus. FIG. 7B shows a perspective view from the rear of the mammography apparatus.

  In the configuration shown in FIG. 7, the distance between the first radiation generation unit 1 and the first radiation detection unit 2 in the first imaging is the same as the second radiation generation unit 6 and the second radiation detection in the second imaging. The first radiation generating unit 1 and the second radiation generating unit 6 are arranged on the rotating frame 3 so as to be different from the distance to the unit 7. Further, the distance from the rotating shaft 11 of the rotating frame 3 to the target 22 of the second radiation generating unit 6 is shorter than the distance from the rotating shaft 11 of the rotating frame 3 to the target 21 of the first radiation generating unit 1. In addition, the first radiation generating unit 1 and the second radiation generating unit 6 are arranged on the rotating frame 3. In the configuration of FIG. 7, since the SID for CBCT imaging is shorter than the SID for mammogram imaging, the distance from the rotation axis 11 to the target 22 is set shorter than the distance from the rotation axis 11 to the target 21. Further, when the apparatus configuration shown in FIG. 7 is compared with the apparatus configuration shown in FIG. 6, in the mammography apparatus of FIG. 7, since the second radiation detection unit 7 is supported by the compression plate support unit 18, the CT The sensor support portion 17 need not be configured.

  With the above configuration, the first radiation generating unit 1 and the second radiation generating unit 6 are attached to the rotating frame 3 so that the distance from the rotating shaft 11 to the target 21 and the distance from the rotating shaft 11 to the target 22 are different. Deploy. With such an arrangement, a space can be secured in the left and right areas of the holding table 10 while maintaining a thin apparatus, and the operator can easily access the breast of the subject during CBCT imaging. It becomes possible to.

  In addition, it is not necessary to configure the CT sensor support portion 17, and it becomes possible to reduce the cost and the load on the rotating frame 3. That is, it is possible to reduce the thickness of the apparatus, improve the accessibility of the operator's subject's breast during CBCT imaging, and reduce the cost and weight.

(Other embodiments)
The present invention supplies a program that realizes one or more functions of the above-described embodiments to a system or apparatus via a network or a storage medium, and one or more processors in a computer of the system or apparatus read and execute the program This process can be realized. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

1: first radiation generation unit, 2: first radiation detection unit, 3: rotating frame,
4: gantry support part, 5: fixing part, 6: second radiation generating part,
7: second radiation detection unit, 8: compression plate, 9: front cover,
10: holding table, 11: rotating shaft, 18: compression plate support

Claims (22)

First imaging for imaging in a state where the breast of the subject is compressed with a compression plate on the first side, and a breast on the subject on a second side opposite to the first side A mammography apparatus capable of performing a second imaging for imaging in a held state,
In the first imaging, a first radiation generation unit having an electron beam generation unit for generating radiation,
In the second imaging, a second radiation generation unit having an electron beam generation unit for generating radiation,
The mammography apparatus, wherein the electron beam generation unit of the second radiation generation unit is arranged in an inclined state with respect to the electron beam generation unit of the first radiation generation unit. The electron beam generating unit of the first radiation generating unit has a cathode that generates an electron beam to be irradiated to the target of the anode unit in the first imaging,
2. The mammography apparatus according to claim 1, wherein the electron beam generation unit of the second radiation generation unit includes a cathode that generates an electron beam to be irradiated to a target of the anode unit in the second imaging. .   The electron beam generated by the electron beam generator of the first radiation generator and the electron beam generated by the electron beam generator of the second radiation generator are not placed on the same straight line. The mammography apparatus according to claim 1, wherein the first radiation generation unit and the second radiation generation unit are configured.   The first radiation generation is performed so that the electron beam generated by the electron beam generation unit of the second radiation generation unit is not parallel to the electron beam generated by the electron beam generation unit of the first radiation generation unit. The mammography apparatus according to any one of claims 1 to 3, wherein the first radiation generation unit and the second radiation generation unit are configured.   The first radiation so that the axis of the cathode in the electron beam generator of the first radiation generator and the axis of the cathode in the electron beam generator of the second radiation generator do not lie on the same straight line. The mammography apparatus according to claim 1, wherein the generation unit and the second radiation generation unit are configured.   The first radiation generation unit and the first radiation generation unit are arranged so that the cathode axis of the electron beam generation unit of the first radiation generation unit and the axis of the cathode of the electron beam generation unit of the second radiation generation unit are not parallel to each other. The mammography apparatus according to claim 1, wherein two radiation generation units are configured.   The first radiation generation unit and the first radiation detection unit that detects radiation generated by the first radiation generation unit are rotatably held in a state of facing each other, and the second radiation generation is performed. The rotary frame which hold | maintains rotatably in the state which faced the part and the 2nd radiation detection part which detects the radiation which generate | occur | produced in said 2nd radiation generation part faced to Claim 2 characterized by the above-mentioned. The described mammography apparatus.   The first radiation generation unit and the second radiation generation unit are arranged on the rotating frame with no displacement of the arrangement angle around the rotation axis of the rotation frame. The mammography apparatus according to 7.   The first radiation generation unit and the second radiation generation unit are arranged on the rotary frame with a predetermined arrangement angle shifted from a rotation axis of the rotation frame. The mammography apparatus according to 7.   The mammography apparatus according to claim 9, wherein the arrangement angle is 90 °.   A straight line connecting the target of the anode part of the first radiation generating part and the target of the anode part of the second radiation generating part intersects the rotation axis of the rotating frame so that the first radiation generating part The mammography apparatus according to claim 7, wherein the second radiation generating unit is disposed on the rotating frame.   The distance from the target of the anode part of the first radiation generation unit to the rotation axis of the rotating frame is different from the distance from the target of the anode part of the second radiation generation unit to the rotation axis, The mammography apparatus according to claim 7 or 11, wherein the first radiation generation unit and the second radiation generation unit are arranged on the rotating frame.   The mammography according to claim 2, wherein the anode part of the second radiation generating unit is disposed at a position closer to the subject than the cathode of the second radiation generating part. apparatus.   The mammography according to claim 2, wherein the cathode of the first radiation generating unit is disposed at a position closer to the subject than the anode unit of the first radiation generating unit. apparatus.   The first radiation generation unit and the second radiation generation unit generate radiation having a spread from a direction vertically below the target toward a direction inside the apparatus, based on an electron beam applied to the target. The mammography apparatus according to claim 2.   The distance between the first radiation generation unit and the first radiation detection unit in the first imaging is the distance between the second radiation generation unit and the second radiation detection unit in the second imaging. The mammography apparatus according to claim 7, wherein the first radiation generation unit and the second radiation generation unit are arranged on the rotating frame, as different from FIG.   The distance from the rotation axis of the rotation frame to the target of the second radiation generation unit is shorter than the distance from the rotation axis of the rotation frame to the target of the first radiation generation unit. The mammography apparatus according to claim 7, wherein one radiation generation unit and the second radiation generation unit are arranged on the rotating frame.   The mammography apparatus according to claim 7, wherein the first radiation detection unit includes an attachment / detachment mechanism that attaches / detaches the compression plate support unit that supports the compression plate.   The mammography apparatus according to claim 2, wherein the anode part of the first radiation generating unit is a rotary anode type, and the anode part of the second radiation generating unit is a fixed anode type. First imaging for imaging in a state where the breast of the subject is compressed with a compression plate on the first side, and a breast on the subject on a second side opposite to the first side A mammography apparatus capable of performing a second imaging for imaging in a held state,
A first radiation generator for generating radiation in the first imaging;
A second radiation generator for generating radiation in the second imaging;
A rotating unit that rotatably holds the first radiation generating unit and the second radiation generating unit,
Mammography, wherein the first radiation generation unit and the second radiation generation unit are arranged in the rotation unit in a state in which an arrangement angle is shifted with respect to a rotation axis of the rotation unit. apparatus.   21. The mammography apparatus according to claim 1, wherein the first imaging is mammogram imaging, and the second imaging is CT imaging.   A front cover is detachably provided on the second side, and the holding base for holding the breast of the subject that has entered from the opening is provided on the front cover. The mammography apparatus according to claim 1, wherein:

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