JP2016106963A - Ct apparatus for mammography - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a CT apparatus for mammography capable of imaging breasts while a subject can easily keep a posture.SOLUTION: The CT apparatus for mammography comprises a gantry 10 with a radiation source 104 and a radiation detection part 105 arranged facing each other and images the breasts of a subject P. The gantry 10 comprises: an inclined part 13 inclined conically; and a plane part 14 formed along the end of the inclined part 13. The plane part 14 has an opening 15 for inserting the breasts of the subject P.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a mammography CT apparatus for imaging a subject's breast using radiation.

  There is a mammography CT apparatus that images a breast by arranging a radiation source and a radiation detection unit facing each other in a gantry and irradiating radiation while rotating the radiation source and the radiation detection unit around the breast. .

  The gantry of the mammography CT apparatus has an opening that exposes the breast of the subject between the radiation source and the radiation detection unit. The radiation source and the radiation detection unit rotate around the breast exposed from the opening, and imaging of the breast is performed. (For example, Patent Document 1)

JP 2008-93135 A

  In the conventional mammography CT apparatus, the subject has to keep his / her posture on a flat gantry. Therefore, the subject's head or waist may be pressed by a flat gantry, and it may be difficult for the subject to maintain his posture.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a mammography CT apparatus that can easily maintain a posture of a subject and can perform breast imaging. .

  In order to achieve the above object, a CT apparatus for mammography having a gantry in which a radiation source and a radiation detection unit are arranged to face each other and photographing a breast of a subject, the gantry having a conical shape. An inclined portion that is inclined, and a flat portion formed along an end of the inclined portion, and the flat portion is provided with an opening for inserting the breast of the subject. Yes. The gantry has a truncated conical shape, and an opening for inserting the subject's breast is installed in the truncated head.

  According to the mammography CT apparatus of the present invention, the subject can easily maintain his / her posture and can perform breast imaging.

1 is an external view of a mammography CT apparatus according to Embodiment 1 of the present invention. FIG. 1 is a configuration diagram of a mammography CT apparatus according to Embodiment 1 of the present invention. FIG. The block diagram of the radiation source of CT apparatus for mammography of this invention. The figure which shows the imaging | photography state of the subject in CT apparatus for mammography of this invention. The figure which shows the imaging | photography state of the subject in CT apparatus for mammography of this invention. The external view of the mammography CT apparatus which concerns on Embodiment 2 of this invention. The external view of the mammography CT apparatus which concerns on Embodiment 3 of this invention. The external view of the mammography CT apparatus which concerns on Embodiment 3 of this invention. The external view of the mammography CT apparatus which concerns on Embodiment 4 of this invention.

  Hereinafter, an embodiment of the mammography CT apparatus of the present invention will be described with reference to the drawings as appropriate.

<Embodiment 1>
FIG. 1 is an external view of a mammography CT apparatus according to Embodiment 1 of the present invention. FIG. 1A is an external view of a mammography CT apparatus, showing a gantry 10 having a radiation source and a radiation detection unit therein, and a bed unit 20 that supports a subject P. FIG. 1B shows a state in which the subject P is in a prone posture on the gantry 10 and the bed portion 20.

  The gantry 10 includes therein a radiation source that generates radiation and a radiation detection unit that detects radiation generated from the radiation source. As shown in FIGS. 1A and 1B, the gantry 10 is annular. The gantry 10 has a substantially conical shape (a truncated conical shape), and the gantry 10 is hollow. An opening 15 is provided in a flat portion 14 corresponding to the upper end of the gantry 10. That is, the upper end of the substantially conical (truncated conical) gantry 10 in which the opening 15 is installed is a flat surface.

  Specifically, the gantry 10 includes a truncated cone portion 11 and a cylindrical portion 12. Each of the truncated cone portion 11 and the cylindrical portion 12 is hollow. The lower surface of the truncated cone portion 11 is joined to the upper surface of the cylindrical portion 12. The hollow space inside the gantry 10 is joined by the joining surface of the truncated cone portion 11 and the joining surface of the cylindrical portion 12.

  The truncated conical part 11 in the gantry 10 includes an inclined part 13 having a conical inclined surface and a flat part 14 having a flat surface. In other words, the gantry 10 includes an inclined portion 13 that is inclined in a conical shape, and a flat surface portion 14 that is formed along an end portion of the inclined portion 13, and the flat surface portion 14 includes the subject P. An opening 15 for inserting a breast is provided. The gantry 10 is formed in a convex shape by the inclined portion 13 and the flat portion 14. The subject P is placed on the inclined portion 13 and the flat portion 14 of the gantry 10. The end of the inclined portion 13 is concentric. An end portion of the inclined portion 13 in FIG. 1 is an upper end portion of the gantry 10. The flat surface portion 14 is installed along the concentric circle shape of the inclined portion 13. That is, the flat surface portion 14 is installed concentrically along the inclined portion 13. The size of the flat part 14 is set assuming a standard body shape. Specifically, it is desirable that the diameter width of the flat portion 14 is larger than the shoulder width of the subject P. The diameter width of the flat portion 14 is larger than the diameter width of the opening portion 15 and smaller than the diameter width of the concentric circle formed by the inclined portion 13. The diameter width of the plane portion 14 is, for example, 80 cm to 120 cm. An opening 15 for inserting the breast of the subject P is provided near the center of the flat part 14. The subject P can expose the breast of the subject P between the radiation source in the gantry 10 and the radiation detection unit by inserting the breast into the opening 15.

  Further, the mammography CT apparatus has a bed portion 20 on which the subject P is placed. The bed portion 20 is installed so as to contact the side surface of the gantry 10. In accordance with the cylindrical shape of the gantry 10 (cylindrical portion 12), one side surface of the bed portion 20 is curved. The height of the cylindrical portion 12 and the height of the bed portion 20 are the same. As shown in FIG. 1, the top plate of the bed portion 20 is joined to the inclined portion 13 of the gantry 10. As shown in FIG. 1 (b), the subject P is in a prone posture on the gantry 10 and the bed portion 20, and exposes the breast of the subject P from the opening 15, so that a mammography CT apparatus is provided. Can be taken.

  Here, the imaging posture of the subject P will be described. The subject P first climbs up to the bed part 20 and takes a prone posture from the gantry 10 to the bed part 20 while inserting one of the left and right breasts into the opening 15. At this time, at least one of the head and waist of the subject P is hung on the gantry 10 having a conical inclined surface. The position of the opening 15 into which the breast of the subject P is inserted is the highest, from there to the front of the subject P for the head, and to the back of the subject P for the waist of the subject P, respectively. The gantry 10 is inclined so as to be lowered.

  Specifically, the leg part of the subject P is supported by the bed part 20, and the waist part of the subject P is supported by the inclined part 13. Further, the upper body of the subject P is supported by the flat surface portion 14. The arm portion of the subject P is supported by the inclined portion 13, and the head portion of the subject P is supported by the inclined portion 13. In other words, since the waist, arms, and head of the subject P are supported by the inclined surface (inclined portion 13) of the gantry 10, the subject P can maintain the prone posture without difficulty.

  Thus, the subject P can maintain a prone posture without the head or waist being pressed against the gantry 10 and being pressed. This is because, due to the structure of the human body, the movable angle when turning forward is larger than the moving angle when bending backward.

  In addition, when the subject P is in a prone posture, the arm portion can be placed around the so-called convex gantry 10 (inclined portion 13) so as to hold the gantry 10. You can also take an easy posture.

  FIG. 2 is a diagram showing an internal structure of the gantry 10 of the mammography CT apparatus. The mammography CT apparatus includes a radiation source 104 that generates radiation, a radiation detection unit 105 that detects radiation generated from the radiation source 104, an arm 106 that connects the radiation source 104 and the radiation detection unit 105, and a rotation axis. A rotation drive unit 107 that rotates the arm 106 around C, a control unit 108 that controls each component of the mammography CT apparatus, and a power supply unit 111 that supplies power to each component of the mammography CT apparatus And have.

  The subject P is in a prone posture from the gantry 10 to the bed part 20. The breast S of the subject P is inserted into the opening 15 of the gantry 10. At this time, the breast S of the subject P is disposed between the radiation source 104 and the radiation detection unit 105.

  The gantry 10 is formed in an annular shape with a vertical rotation axis C passing through the center of the opening 15 as the center. FIG. 2 shows a cross section passing through the rotation axis C of the gantry 10. Inside the gantry 10 having an annular structure, a radiation source 104 and a radiation detection unit 105 are disposed to face each other with the rotation axis C interposed therebetween. The radiation detection unit 105 can detect the radiation emitted by the radiation source 104. The radiation source 104 and the radiation detection unit 105 are connected to the arm 106, respectively. The arm 106 is driven to rotate about the rotation axis C by the rotation driving unit 107. Therefore, the radiation source 104 and the radiation detection unit 105 can be rotated while maintaining the opposing arrangement.

  The control unit 108 controls the rotation of the arm 106 in the rotation driving unit 107, the radiation irradiation of the radiation source 104, the radiation detection of the radiation detection unit 105, the image data output, and the like. The control unit 108 has a CPU and a memory therein, and each component is controlled by the CPU executing a control program stored in the memory. Specifically, the control unit 108 controls the number of rotations per second of the arm 106 in the rotation driving unit 107. The rotation drive unit 107 can rotate the arm 106 at the number of rotations. The control unit 108 also controls imaging conditions including tube voltage and tube current in the radiation source 104. The radiation source 104 can emit radiation under the imaging conditions. The control unit 108 also controls the timing at which the radiation detection unit 105 detects radiation and acquires image data based on the radiation. The radiation detection unit 105 may have a detection function for automatically detecting radiation irradiation from the radiation source 104. The detection function for automatic detection is a function in which the radiation detection unit 105 detects radiation and accumulates radiation signals when radiation is emitted from the radiation source 104. When the radiation detection unit 105 detects radiation irradiation, the control unit 108 causes the radiation detection unit 105 to start a main reading operation to acquire image data.

  The power supply unit 111 supplies power to each component. For example, the power supply unit 111 supplies power to the radiation source 104. The radiation source 104 can irradiate radiation based on the tube voltage and tube current in the power supplied from the power supply unit 111.

  FIG. 3 shows the configuration of the radiation source 104 of the mammography CT apparatus. The radiation source 104 includes a tube container 201, an electron emission source 202, an anode 203, a target 2031, and a radiation transmission window 204.

  The radiation source 104 is sealed by a tube vessel 201 and includes therein an electron emission source 202 that generates electrons, an anode 203, and a target 2031. In addition, the tube container 201 includes a radiation transmission window 204 that transmits the radiation generated by the target 2031 to the outside of the tube container 201. The tube container 201 is a metal cylindrical container, and the inside is kept in a vacuum. The electron emission source 202 includes a cathode 2021, a focusing electrode 2022, and a grid electrode 2023. The cathode 2021 generates heat by generating power and generates electrons. Electrons generated at the cathode 2021 are emitted to the anode 203 side due to a potential difference between the cathode 2021 and the anode 203. At this time, the light passes through the electron lens formed by the focus aperture 2024 of the grid electrode 2023 and the focusing electrode 2022, and is converged into a circular electron beam. The target 2031 is a member that generates radiation by the collision of electrons. The target 2031 is deposited on the surface of the anode 203 on which the electron beam collides, and is kept at the ground potential. The anode 203 has a hollow structure so that it can be cooled by water cooling. The surface of the anode 203 on which the target 2031 is deposited is tilted by a predetermined angle with respect to the trajectory of the electron beam (broken line 205), and the electron beam is incident on the target 2031 at the tilt angle. A broken line 205 is an electron beam irradiation direction. When the electron beam collides with the target 2031, radiation is emitted from the target 2031. A radiation transmission window 204 is formed in the reflection angle direction of the electron beam. The radiation transmitting window 204 is a plate-like member formed of a material that transmits radiation, such as beryllium, and is brazed so as to cover the circular hole of the tube container 201. The radiation emitted from the target 2031 is transmitted through the radiation transmission window 204 to be shaped into a cone-shaped beam (a region surrounded by a broken line 206) and irradiated toward the outside of the tube container 201. The That is, the radiation angle / shape of the radiation beam is determined by the incident angle of the electron beam with respect to the target, the shape / position of the radiation transmission window, and the like.

  With the above configuration, the radiation source 104 according to the present embodiment has a cylindrical shape as a whole, and a cone (cone) is directed obliquely upward with respect to the longitudinal direction (the direction of the electron beam) of the tube container 201 from its end. ) It is structured to irradiate the shape with radiation.

  Although the reflective radiation source 104 has been described above, the radiation source 104 may be a transmissive type. Specifically, the radiation source 104 includes a transmissive target, an electron emission source disposed so as to be separated from and opposed to the transmissive target, and a tube container whose internal space is decompressed. The electrons emitted from the electron emission source are irradiated to the transmission target side. Radiation can be generated when the electron emission source irradiates the transmission target with an electron beam. Even the transmissive radiation source 104 can irradiate radiation in a cone shape.

  The radiation source 104 may have a structure in which a radiation tube for generating radiation and a high voltage generation unit for operating the radiation tube are integrated, a so-called mono tank structure.

  FIGS. 4 and 5 are views showing a state in which the mammography CT apparatus photographs the breast of the subject P (a state in which radiation is irradiated).

  The radiation source 104 is disposed along the inclined surface (inclined portion 13) of the gantry 10. Even when the radiation source 104 is rotated about the rotation axis C, the radiation source 104 does not collide with the inclined surface of the gantry 10. Specifically, the radiation source 104 is disposed along the inclined surface of the gantry 10 so as to be parallel to the inclined surface (inclined portion 13) of the gantry 10 configured in a substantially conical shape (a truncated conical shape). ing. In other words, the inclined surface (inclined portion 13) of the gantry 10 is parallel to the longitudinal direction of the radiation source 104. It can also be said that the inclined surface (inclined portion 13) of the gantry 10 is parallel to the irradiation direction of the electron beam generated from the electron emission source of the radiation source 104.

  On the other hand, the inclined surface (inclined portion 13) of the gantry 10 is not parallel to the radiation direction of the radiation source 104. The side surface of the radiation source 104 on the flat portion 14 side is a flat surface. The side surface (plane) on the plane portion 14 side of the radiation source 104 is parallel to the plane portion 14 of the gantry 10.

  Further, the end of the radiation irradiated from the radiation source 104 on the plane portion 14 side is parallel to the plane portion 14 of the gantry 10. That is, the radiation irradiated from the radiation source 104 is irradiated along the plane portion 14 of the gantry 10.

  A symbol X indicates an irradiation area of radiation emitted from the radiation source 104 in a cone shape. The radiation radiated from the radiation source 104 is irradiated such that the upper boundary surface (on the flat surface portion 14 side) of the irradiation region X is substantially the same as the opening surface of the opening 15. That is, the angle θ formed by the boundary surface of the irradiation region X and the longitudinal axis of the radiation source 104 is substantially equal to the angle φ formed by the inclined portion 13 of the gantry 10 and the opening surface of the opening 15. That is, the gantry 10 having a substantially conical shape (a truncated conical shape) is configured such that an inclined side surface thereof forms an angle θ with respect to the opening surface of the opening provided at a position corresponding to the apex thereof. The The angle θ is an angle formed by the longitudinal axis of the radiation source 104 and the irradiation boundary surface on the side close to the axis of the radiation irradiation region X. In other words, the angle θ is an angle formed between the longitudinal axis of the radiation source 104 and the plane portion 14 of the gantry 10. The angle θ is an angle formed between the axis of the irradiation direction of the electron beam generated from the electron emission source of the radiation source 104 and the plane portion 14 of the gantry 10.

  The radiation detection unit 105 is disposed to face the radiation source 104 with the rotation axis C interposed therebetween. The radiation source 104 and the radiation detection unit 105 are connected by an arm 106. The arm 106 is driven to rotate about the rotation axis C by the rotation drive unit 107.

  The radiation detection part 105 detects the radiation which permeate | transmitted the subject with a photoelectric conversion element, and outputs it as an electrical signal. For example, the radiation detection unit 105 includes a conversion panel that detects radiation that has passed through the subject, an absorption plate that absorbs radiation backscattered rays, a power storage unit, and an I for outputting information converted from radiation to electrical signals. / F (interface). An electrical signal can be output to an external device through the I / F (interface). In addition, you may provide the grid which removes the scattering of the radiation by a subject in the radiation detection side of the radiation detection part 105. FIG.

  On the opposite side of the rotation axis C in the radiation detection unit 105 (the opposite side of the radiation detection surface), a radiation shielding unit 301 is installed. Therefore, unnecessary exposure to people other than the subject P can be reduced.

  As shown in FIG. 5, when the radiation source 120 has a monotank structure, the radiation source 120 has a shape adapted to the inclined surface of the gantry 10. Specifically, the shape of the radiation source 120 is determined in accordance with the shape inside the gantry 10 composed of the inclined portion 13 and the flat portion 14. The radiation source 120 is bent in a “<” shape.

  The radiation source 120 is formed along the inner wall of the inclined portion 13 and the inner wall of the flat portion 14. Specifically, in the radiation source 120, the side surface of the radiation source 120 on the plane portion 14 side is parallel to the plane portion 14 of the gantry 10 and has a planar shape. A part of the tube container in the radiation source 120 is parallel to the inclined portion 13 of the gantry 10. A part of the tube container in the radiation source 120 is parallel to the axial direction of the rotation axis C in the radiation source 104 and the radiation detection unit 105.

  The target of the radiation source 120 is installed at a position close to the flat portion 14 of the gantry 10. The inclined surface of the gantry 10 is parallel to the irradiation direction of the electron beam generated from the electron emission source of the radiation source 120. An end of the radiation irradiated from the radiation source 120 on the plane part 14 side is parallel to the plane part 14 of the gantry 10. That is, the radiation irradiated from the radiation source 120 is irradiated along the plane part 14 of the gantry 10.

  The fact that the boundary surface on the opening side of the irradiation region X of radiation emitted from the radiation source 104 is substantially the same as the opening surface of the opening 15 has the following advantages. The CT apparatus for mammography according to the present invention captures a tomographic image of a breast by irradiating radiation while rotating the radiation source 104 (120) and the radiation detection unit 105 around the breast. A portion not in the radiation irradiation area X cannot be imaged. On the other hand, since a breast cancer is frequently occurring on the outside of the upper part of the breast, it is desirable that imaging is possible including this. The fact that the boundary surface of the radiation irradiation region X is substantially the same as the opening surface has an advantage that imaging including a breast cancer occurrence site can be performed.

  As described above, according to the mammography CT apparatus of the present embodiment, the mammography CT apparatus has the gantry 10 in which the radiation source 104 and the radiation detection unit 105 are arranged to face each other, and images the breast of the subject P. The gantry 10 has an inclined portion 13 that is inclined in a conical shape, and a flat surface portion 14 that is formed along the end of the inclined portion 13, and the flat surface portion 14 includes a subject P. An opening 15 is provided for inserting the breast. The gantry 10 has a truncated conical shape, and an opening 15 for inserting the breast of the subject P is installed at the truncated head.

  Therefore, the subject P can easily maintain a prone posture on the gantry and can take an image of the breast. When the subject P is in a prone posture, the head or waist is not compressed, and the pain of the subject P is reduced. Therefore, it is possible to provide a mammography CT apparatus capable of performing mammography suitable for breast cancer examination.

<Embodiment 2>
FIG. 6 is an external view of a mammography CT apparatus according to Embodiment 2 of the present invention. The difference from the first embodiment is that a side opening 401 is provided on the periphery of the gantry 10.

  FIG. 6 shows a state in which the subject P is in a prone posture on the gantry 10 of the mammography CT apparatus of the present invention in order to collect a biopsy sample of the subject P, or the subject P The state which opened the side surface opening part 401 of the gantry 10 in order to treat is shown.

  In radiographic CT imaging, since the breast of the subject P can be radiographed in a so-called three-dimensional manner, the position of the tissue suspected of having a lesion on the three-dimensional coordinates can be obtained. Therefore, if a sample for biopsy can be collected while the breast of the subject P is maintained after imaging, the examination accuracy can be improved while shortening the examination time. In addition, if treatment such as puncture can be performed while the breast of the subject P is maintained after imaging, the treatment accuracy can be improved while shortening the treatment time. For this purpose, in the mammography CT apparatus of the present invention, a side opening 401 is provided at the periphery of the gantry 10.

  In FIG. 6, the side opening 401 provided at the periphery of the gantry 10 can be opened and closed. The side opening 401 can be closed using a lid (not shown) that covers the side opening 401 as shown in FIG. The lid that covers the side opening 401 is the same size as the side opening 401 and has the same shape as the gantry 10. The side opening 401 may be provided on either the left or right side of the gantry 10 or may be provided on both the left and right sides of the gantry 10. That is, the side surface opening 401 may be provided at one place of the gantry 10 or may be provided at a plurality of places of the gantry 10.

  The side opening 401 can be used not only for taking a biopsy sample after imaging, but also for correcting the breast position of the subject P by a technique such as an inspection engineer before imaging. When taking the sample for biopsy or correcting the position of the breast, if the radiation source 104 or the radiation detection unit 105 is in a position where the opening of the side opening 401 is blocked, these operations are hindered. Therefore, when the rotational drive unit 107 is not rotationally driven, the control unit 108 may perform control so that the radiation source 104 and the radiation detection unit 105 are stopped at a position outside the side opening 501. That is, the control unit 108 performs control so that the radiation source 104 and the radiation detection unit 105 do not stop at the side opening 501.

  The side opening 401 is provided with an open / close sensor, and when the opening of the side opening 401 is detected, control is performed so that the radiation source 104 and the radiation detection unit 105 move to a position outside the side opening 401. Also good.

  Here, when the open / close sensor is a contact sensor, it is detected whether or not the lid that covers the side opening 401 is in contact with the side opening 401. When the contact sensor detects that the lid covering the side opening 401 is in contact with the side opening 401, the control unit 108 recognizes that the side opening 401 is closed. When the contact sensor detects that the lid covering the side opening 401 is not in contact with the side opening 401, the control unit 108 recognizes that the side opening 401 is open.

  When the open / close sensor is an illuminance sensor, it detects whether the inside of the gantry 10 is dark. When it is detected that the inside of the gantry 10 is dark, the lid portion covers the side opening 401. At this time, the control unit 108 recognizes that the side opening 401 is closed. When it is detected that the inside of the gantry 10 is bright, the lid portion does not cover the side opening 401. At this time, the control unit 108 recognizes that the side opening 401 is opened.

  Further, in order to improve safety, when the opening / closing sensor detects that the side opening 401 is opened, the control unit 108 prohibits radiation irradiation by the radiation source 104. When the opening / closing sensor detects that the side opening 401 is opened, the control unit 108 stops the rotation driving of the radiation source 104 and the radiation detection unit 105 by the rotation driving unit 107.

  When it is detected by the open / close sensor that the side opening 401 is closed, the control unit 108 allows the radiation source 104 to irradiate the radiation by the rotation driving unit 107. When it is detected by the open / close sensor that the side opening 401 is closed, the control unit 108 permits the rotation drive unit 107 to rotationally drive the radiation source 104 and the radiation detection unit 105.

  The mammography CT apparatus can also include an elevating mechanism (not shown) that elevates and lowers the gantry 10. By raising and lowering the gantry 10 by the lifting mechanism, it may be possible to adjust the height so that a laboratory technician or doctor can easily put the hand into the side opening 401. At this time, the bed unit 102 can also be moved up and down, and the control unit 108 controls the lift amount of the bed unit 102 to be substantially the same as the lift amount of the gantry 10. Even when a technician or a biopsy sample is taken by an inspection engineer, the subject P's head or waist is not pressed against the device, and the subject P is placed in a comfortable posture. Is possible.

  As described above, since the side opening that can be opened and closed is provided on the side surface of the gantry, it is possible to collect a sample for biopsy or perform a procedure by an inspection engineer or the like.

<Embodiment 3>
7 and 8 are external views of a mammography CT apparatus according to Embodiment 3 of the present invention. The difference from the first and second embodiments is that gripping portions 30 and 40 that are gripped by the subject P are installed on the periphery of the gantry 10 in the mammography CT apparatus.

  As shown in FIGS. 7 and 8, gripping portions 30 and 40 are installed on the periphery (outer periphery) of the cylindrical portion 12 of the gantry 10. Note that the gripping portions 30 and 40 are not installed on the inclined portion 13 of the gantry 10.

  7A is an external view of a mammography CT apparatus in which the grip portion 30 is installed, and FIG. 7B is a cross-sectional view of the mammography CT apparatus taken along a broken line Y.

  In order for the subject P to grip the grip portion 30 with both hands, the two grip portions 30 are symmetrically installed on the gantry 10 with the opening 15 interposed therebetween. That is, the two gripping parts 30 are installed in the gantry 10 so as to be symmetrical with respect to the body axis of the subject P placed on the gantry 10 and the bed part 20.

  The grip 30 is curved along the shape of the gantry 10. Specifically, the grip portion 30 is curved along the outer edge (outer periphery) shape of the gantry 10. The grip portion 30 is installed in the gantry 10 in a state where the distance between the grip portion 30 and the gantry 10 is kept constant. The grip portion 30 is not installed on the bed portion 20 side of the gantry 10 so that the grip portion 30 does not contact the waist of the subject P. The two grip portions 30 may be connected on the side surface of the gantry 10 opposite to the bed portion 20 side.

  When the subject P is in the prone posture, the subject P places the arm portion on the inclined portion 13 of the gantry 10 so as to hold the gantry 10. Then, the subject P grips the grip portion 30. Therefore, the subject P can hold the prone posture more stably by grasping the grip portion 30.

  FIG. 8A is an external view of the mammography CT apparatus in which the grip portion 40 is installed, and FIG. 8B is a cross-sectional view of the mammography CT apparatus taken along the broken line Z.

  A recess (groove) is provided on the periphery (outer periphery) of the gantry 10. The concave portion (groove portion) has a function of the grip portion 40 for the subject to grip. Specifically, a recess (groove) is formed as a grip 40 in the circumferential direction of the side surface of the gantry 10.

  Since the subject P grips the grip portion 40 with both hands, the two grip portions 40 are symmetrically installed on the gantry 10 with the opening 15 interposed therebetween. The two gripping portions 40 are installed on the gantry 10 so as to be symmetrical with respect to the body axis of the subject P placed on the gantry 10 and the bed portion 20. Note that the two gripping portions 40 may be connected.

  When the subject P is in the prone posture, the subject P places the arm portion on the inclined portion 13 of the gantry 10 so as to hold the gantry 10. Then, the subject P grips the grip portion 40. Therefore, the subject P can grip the grip portion 40. Therefore, the subject P can hold the prone posture more stably by grasping the grip portion 40.

<Embodiment 4>
FIG. 9 is an external view of a mammography CT apparatus according to Embodiment 4 of the present invention. The difference from the first to third embodiments is that the mammography CT apparatus includes a rotation mechanism for rotating the gantry 10.

  In FIG. 9, it is assumed that the mammography CT apparatus is disposed in the xy plane. The mammography CT apparatus includes a rotating mechanism (gantry rotating unit 56) for rotating the gantry 10. Specifically, the mammography CT apparatus includes a base 50 installed on the floor along the xy direction and a support base 52 connected to the base 50 along the z direction. The support base 52 is provided with a movable base 54 that can move in the vertical direction (z direction). The movable table 54 is provided with a gantry rotating portion 56 for turning the gantry 10.

  First, the movable stand 54 positions the gantry 10 in the vertical direction (z direction). The gantry rotating unit 56 can turn the gantry 10 about a rotation axis parallel to the x axis in accordance with the imaging posture of the subject P.

  When imaging is performed with the mammography CT apparatus, the breast of the subject P is aligned with the position of the center of the front of the gantry 10 of the gantry 10 and the front of the gantry 10 is opposed to the chest of the subject P. Adjust the angle of the part. By using the movable table 54 and the gantry rotating unit 56, it is possible to perform tomographic imaging of the breast in an arbitrary imaging posture from the standing position to the oblique position and the prone position. Thereby, it becomes possible to perform imaging while reducing the burden on the subject P.

Claims (13)

A mammography CT apparatus that has a gantry in which a radiation source and a radiation detection unit are arranged to face each other, and photographs a breast of a subject,
The gantry has an inclined part inclined in a conical shape and a flat part formed along an end part of the inclined part, and the breast of the subject is inserted into the flat part. A CT apparatus for mammography, characterized in that an opening is provided.   The mammography CT apparatus according to claim 1, wherein the gantry is formed in a convex shape by the inclined portion and the planar portion.   2. The mammography CT apparatus according to claim 1, wherein an end of the inclined portion is concentric, and the planar portion is disposed concentrically along the inclined portion.   The mammography CT apparatus according to claim 1, wherein an opening for inserting the subject's breast is installed in the vicinity of the center of the planar portion.   The mammography CT apparatus according to claim 1, wherein the radiation source is disposed along an inclined portion of the gantry.   2. The mammography CT apparatus according to claim 1, wherein the inclined portion of the gantry is parallel to the longitudinal direction of the radiation source.   The CT apparatus for mammography according to claim 1, wherein the inclined portion of the gantry is parallel to the irradiation direction of the electron beam generated from the electron emission source of the radiation source.   The mammography CT apparatus according to claim 1, wherein the radiation source has a transmission target.   The mammography CT apparatus according to claim 1, wherein a side opening that can be opened and closed is provided at a peripheral edge of the gantry.   The mammography CT apparatus according to claim 1, wherein a gripping part to be gripped by a subject is installed at a peripheral edge of the gantry.   The CT apparatus for mammography according to claim 1, further comprising a rotating mechanism for rotating the gantry.   The mammography CT apparatus according to claim 1, further comprising a bed portion on which the subject is placed, wherein the bed portion is installed in contact with a side surface of the gantry. A mammography CT apparatus that has a gantry in which a radiation source and a radiation detection unit are arranged to face each other, and photographs a breast of a subject,
The CT apparatus for mammography, wherein the gantry has a truncated conical shape, and an opening for inserting the subject's breast is installed in the truncated head.

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