JP6937415B2 - Medical diagnostic imaging equipment - Google Patents

Description

An embodiment of the present invention relates to a medical diagnostic imaging apparatus.

The magnetic resonance imaging device has a frame equipped with an imaging mechanism such as a magnet. A substantially hollow bore is formed in the gantry. MR (Magnetic Resonance) imaging is performed with the patient inserted in the bore. Although a gantry with a relatively large bore diameter has been developed, many patients feel stress in MR examinations due to the long MR imaging time, noise during gantry driving, oppressive feeling in the bore, and a feeling of blockage. ..

Japanese Patent Application No. 2015-214741

An object of the embodiment is to provide a medical diagnostic imaging apparatus capable of improving the habitability in the bore of the gantry.

The medical diagnostic imaging apparatus according to the present embodiment includes a gantry, a moving body, a screen, a reflector, and a frame. The gantry has a bore and is equipped with a medical imaging mechanism. The moving body can move in the bore along the central axis of the bore. The screen is provided on the moving body, and an image from the projector is projected from a side opposite to the side where the top plate is inserted into the bore. The reflector reflects the image projected on the screen. The frame is provided on the moving body and supports the reflector. The frame passes through a gap between the outer edge of the screen and the inner wall of the bore at the top of the screen.

FIG. 1 is a diagram showing a configuration of a medical image diagnosis system including a medical image diagnosis device according to the first embodiment. FIG. 2 is a diagram showing a configuration of a magnetic resonance imaging apparatus according to the first embodiment. FIG. 3 is a diagram showing an example of the installation environment of the magnetic resonance imaging system according to the first embodiment. FIG. 4 is a perspective view of the mobile screen device according to the first embodiment. FIG. 5 is a side view of the mobile screen device of FIG. FIG. 6 is a front view of the mobile screen device of FIG. FIG. 7 is a perspective view of the connected mobile screen device and the top plate according to the first embodiment. FIG. 8 is a diagram showing how the first support portion can move along the central axis and the second support portion can move along the outer shape direction according to the first embodiment. FIG. 9 is a diagram showing an example of a vibration damping device provided between the first support portion and the moving body according to the first embodiment. FIG. 10 is a diagram showing an example of a vibration damping device provided between the second support portion and the reflector according to the first embodiment. FIG. 11 is a diagram showing an example of an optical path when the reflector is a prism mirror according to the first embodiment. FIG. 12 is a diagram showing an optical path when the reflector is a normal mirror according to the first embodiment. FIG. 13 is a diagram showing an example of an optical path of a reflector having a Fresnel structure in addition to a prism mirror according to the first embodiment. FIG. 14 is a view showing a side surface of the mobile screen device according to the first application example of the first embodiment. FIG. 15 is a side view showing a side surface of the mobile screen device according to the second application example of the first embodiment. FIG. 16 shows a moving body contracted along the central axis and a second support in a state where the mobile screen device is arranged outside the bore on the projector side according to the second application example of the first embodiment. Indicates a part. FIG. 17 relates to a second application example of the first embodiment, in which a second support portion connects the first support portion and the second support portion in a state where the mobile screen device is arranged outside the bore. It shows how the part is folded toward the screen with the rotation axis as the axis of rotation. FIG. 18 is a perspective view of the mobile screen device according to the second embodiment. FIG. 19 is a side view showing a side surface of the mobile screen device according to the second embodiment. FIG. 20 is a view of the mobile screen device according to the second embodiment as viewed from the projector side. FIG. 21 is a side view showing a side surface of the mobile screen device according to the third embodiment. FIG. 22 is a view of the mobile screen device according to the third embodiment as viewed from the projector side. FIG. 23 is a view showing a front view of the mobile screen device according to the fourth embodiment together with a front view of the mobile screen device according to the first to third embodiments. FIG. 24 is a top view of the mobile screen device according to the fourth embodiment and the mobile screen device according to the first to third embodiments as viewed from the upper surface of the top plate. FIG. 25 is a perspective view of the mobile screen device according to the fourth embodiment.

As a technique for reducing stress in MR inspection, for example, there is a head coil equipped with a mirror for viewing an image on a liquid crystal monitor arranged behind the gantry. On the other hand, in a magnetic resonance imaging (MRI) device, the diameter of the bore may be reduced in order to obtain better imaging performance, and the patient space may be narrowed. At this time, MR imaging in a small-diameter bore has a problem that stress is great for the subject.

Hereinafter, the medical diagnostic imaging apparatus according to the present embodiment will be described with reference to the drawings. In the following description, components having substantially the same function and configuration are designated by the same reference numerals, and duplicate explanations will be given when necessary.

(First Embodiment)
FIG. 1 is a diagram showing a configuration of a medical image diagnosis system 1 including a medical image diagnosis device 10 according to the present embodiment. As shown in FIG. 1, the medical image diagnosis system 1 includes a medical image diagnosis device 10, a projector 100, and a projector control device 200, which are connected to each other so as to be able to communicate with each other by wire or wirelessly. The medical diagnostic imaging apparatus 10 includes a gantry 11, a sleeper 13, a mobile screen apparatus 15, and an imaging control unit 17. For example, the gantry 11, the bed 13, and the mobile screen device 15 are installed in the examination room, and the imaging control unit 17 is installed in the control room adjacent to the examination room. The gantry 11 is equipped with a mechanism for realizing medical imaging. A bore having a hollow shape is formed on the gantry 11. A sleeper 13 is installed in front of the gantry 11. The sleeper 13 movably supports the top plate on which the subject P is placed. The sleeper 13 moves the top plate under the control of the gantry 11 and the console. A mobile screen device 15 is movably provided in the bore of the gantry 11. A projector 100 is installed in front of or behind the gantry 11. An image from the projector 100 is projected on the mobile screen device 15.

The projector control device 200 is a computer device that controls the projector 100. The projector control device 200 supplies data related to the image to be projected to the projector 100. The projector 100 projects an image corresponding to the data from the projector control device 200 onto the screen of the mobile screen device 15. The projector 100 is equipped with at least a display device and a light source. The display device displays an image corresponding to the data from the projector control device 200. The light source irradiates the display device directly or indirectly through the optical system. The light transmitted or reflected from the display device (hereinafter referred to as projected light) is directly or indirectly emitted to the outside of the projector 100 via an optical system. When the projected light is applied to the mobile screen device 15, an image corresponding to the projected light is projected on the mobile screen device 15.

The imaging control unit 17 functions as the center of the medical diagnostic imaging apparatus 10. For example, the imaging control unit 17 controls the gantry 11 for performing medical imaging. Further, the imaging control unit 17 reconstructs a medical image regarding the subject P based on the raw data collected by the gantry 11 in the medical imaging. The imaging control unit 17 may be configured so that the projector 100 can be controlled via the projector control device 200. The configuration of the medical image diagnosis system 1 in this embodiment is not limited to the above.

The medical image diagnosis system 1 according to the present embodiment makes it possible to improve the habitability in the bore at the time of medical imaging by the medical image diagnosis device 10 by using the projector 100 and the mobile screen device 15. The medical image diagnostic device 10 according to the present embodiment may be any device capable of imaging the subject P using the gantry 11 on which the bore is formed. Specifically, the medical diagnostic imaging apparatus 10 according to the present embodiment includes an MRI apparatus, an X-ray computer tomography (CT) apparatus, a PET (Positron Emission Tomography) apparatus, and a SPECT (Single Photon Emission Tomography) apparatus. It can be applied to a single modality such as a device. Alternatively, the medical image diagnostic device 10 according to the present embodiment may be applied to a composite modality such as an MR / PET device, a CT / PET device, an MR / SPECT device, and a CT / SPECT device. However, in order to make the following description concrete, it is assumed that the medical image diagnostic apparatus 10 according to the present embodiment is a magnetic resonance imaging apparatus 10. Further, the medical image diagnosis system 1 including the magnetic resonance imaging device 10, the projector 100, and the projector control device 200 will be referred to as a magnetic resonance imaging system 1.

FIG. 2 is a diagram showing a configuration of a magnetic resonance imaging device 10 according to the present embodiment. As shown in FIG. 2, the magnetic resonance imaging device 10 includes an imaging control unit 17, a pedestal 11, a sleeper 13, and a mobile screen device 15. The image pickup control unit 17 includes a gradient magnetic field power supply 21, a transmission circuit 23, a reception circuit 25, and a console 27. The console 27 includes an image pickup control circuit 31, a reconstruction circuit 32, an image processing circuit 33, a communication circuit 34, a display circuit 35, an input circuit 36, a main memory circuit 37, and a system control circuit 38. The image pickup control circuit 31, the reconstruction circuit 32, the image processing circuit 33, the communication circuit 34, the display circuit 35, the input circuit 36, the main memory circuit 37, and the system control circuit 38 are communicably connected to each other via a bus. .. The gradient magnetic field power supply 21, the transmission circuit 23, and the reception circuit 25 are provided separately from the console 27 and the gantry 11.

The gantry 11 has a static magnetic field magnet 41, a gradient magnetic field coil 43, and an RF coil 45. Further, the static magnetic field magnet 41 and the gradient magnetic field coil 43 are housed in a housing (hereinafter, referred to as a gantry housing) 51 of the gantry 11. A bore 53 having a hollow shape is formed in the gantry housing 51. The RF coil 45 is arranged in the bore 53 of the gantry housing 51. Further, the mobile screen device 15 according to the present embodiment is arranged in the bore 53 of the gantry housing 51.

The static magnetic field magnet 41, the gradient magnetic field coil 43, the RF coil 45, and the like correspond to a medical imaging mechanism. When the medical image diagnosis device 10 has various modalities such as a CT device, a PET device, a SPECT device, a CT / PET device, an MR / PET device, an MR / SPECT device, a CT / SPECT device, etc. It corresponds to a set of various imaging devices installed on the mount in the modality.

The static magnetic field magnet 41 has a hollow substantially cylindrical shape, and generates a static magnetic field inside the substantially cylindrical shape. As the static magnetic field magnet 41, for example, a permanent magnet, a superconducting magnet, a normal conducting magnet, or the like is used. Here, the central axis of the static magnetic field magnet 41 is defined as the Z axis, the axis perpendicular to the Z axis is referred to as the Y axis, and the axis horizontally orthogonal to the Z axis is referred to as the X axis. The X-axis, Y-axis, and Z-axis form a Cartesian three-dimensional coordinate system.

The gradient magnetic field coil 43 is a coil unit that is attached to the inside of the static magnetic field magnet 41 and is formed in a hollow substantially cylindrical shape. The gradient magnetic field coil 43 generates a gradient magnetic field by receiving a current supply from the gradient magnetic field power supply 21.

The gradient magnetic field power supply 21 supplies a current to the gradient magnetic field coil 43 according to the control by the imaging control circuit 31. The gradient magnetic field power supply 21 generates a gradient magnetic field in the gradient magnetic field coil 43 by supplying a current to the gradient magnetic field coil 43.

The RF coil 45 is arranged inside the gradient magnetic field coil 43, and receives the supply of RF pulses from the transmission circuit 23 to generate a high frequency magnetic field. Further, the RF coil 45 receives a magnetic resonance signal (hereinafter referred to as an MR signal) emitted from a target atomic nucleus existing in the subject P under the action of a high-frequency magnetic field. The received MR signal is supplied to the receiving circuit 25 via wire or wireless. Although the RF coil 45 described above is a coil having a transmission / reception function, a transmission RF coil and a reception RF coil may be provided separately.

The transmission circuit 23 transmits a high-frequency magnetic field for exciting a target atomic nucleus such as a proton existing in the subject P to the subject P via the RF coil 45. Specifically, the transmission circuit 23 supplies the RF coil 45 with a high-frequency signal (RF signal) for exciting the target atomic nucleus under the control of the imaging control circuit 31. The high-frequency magnetic field generated from the RF coil 45 vibrates at a resonance frequency peculiar to the target nucleus and excites the target nucleus. An MR signal is generated from the excited target nucleus and detected by the RF coil 45. The detected MR signal is supplied to the receiving circuit 25.

The receiving circuit 25 receives the MR signal generated from the excited target nucleus via the RF coil 45. The receiving circuit 25 processes the received MR signal to generate a digital MR signal. The digital MR signal is supplied to the reconstruction circuit 32 via wire or wireless.

A sleeper 13 is installed adjacent to the gantry 11. The sleeper 13 has a top plate 131 and a base 133. The subject P is placed on the top plate 131. The base 133 slidably supports the top plate 131 along each of the X-axis, Y-axis, and Z-axis. The sleeper drive device 135 is housed in the base 133. The sleeper drive device 135 moves the top plate 131 under the control of the image pickup control circuit 31. As the sleeper drive device 135, for example, any motor such as a servo motor or a stepping motor may be used.

The image pickup control circuit 31 has a CPU (Central Processing Unit) or MPU (Micro Processing Unit) processor and a memory such as a ROM (Read Only Memory) or a RAM (Random Access Memory) as hardware resources. The image pickup control circuit 31 synchronously controls the gradient magnetic field power supply 21, the transmission circuit 23, and the reception circuit 25 based on the pulse sequence information supplied from the system control circuit 38, and uses a pulse sequence corresponding to the pulse sequence information. The subject P is imaged.

The reconstruction circuit 32 has a processor such as a CPU, a GPU (Graphical processing unit), and an MPU, and a memory such as a ROM or RAM as hardware resources. The reconstruction circuit 32 reconstructs an MR image of the subject P based on the MR signal from the reception circuit 25. For example, the reconstruction circuit 32 performs a Fourier transform or the like on an MR signal arranged in k-space or frequency space to generate an MR image defined in real space. The reconstruction circuit 32 is an integrated circuit for a specific application (Application Special Integrated Circuit: ASIC), a field programmable gate array (Field Programmable Logic Device: FPGA), or another composite programmable logic device (FPGA) that realizes a reconstruction function. It may be realized by a Simple Programmable Logic Device (CPLD) or a simple programmable logic device (Simple Programmable Logic Device: SPLD).

The image processing circuit 33 has a processor such as a CPU, GPU, and MPU and a memory such as a ROM and RAM as hardware resources. The image processing circuit 33 performs various image processing on the MR image reconstructed by the reconstructing circuit 32. The image processing circuit 33 may be realized by an ASIC, FPGA, CPLD, or SPLD that realizes the above image processing function.

The communication circuit 34 performs data communication with the projector control device 200 or the projector 100 via a wire or wireless (not shown). Further, the communication circuit 34 may perform data communication with an external device such as a PACS server connected via a network or the like (not shown). Further, the communication circuit 34 may perform data communication with a device described later attached to the mobile screen device 15.

The display circuit 35 displays various information. For example, the display circuit 35 displays an MR image reconstructed by the reconstruction circuit 32 and an MR image processed by the image processing circuit 33. Further, the display circuit 35 may display an image projected by the projector 100.

Specifically, the input circuit 36 has an input device and an input interface circuit. The input device receives various commands from the user. As an input device, a keyboard, a mouse, various switches, and the like can be used. The input interface circuit supplies the output signal from the input device to the system control circuit 38 via the bus. The input circuit 36 is not limited to the one provided with physical operating parts such as a mouse and a keyboard. For example, an electric signal processing circuit that receives an electric signal corresponding to an input operation from an external input device provided separately from the magnetic resonance imaging device 10 and outputs the received electric signal to various circuits is also input. It is included in the example of the circuit 36.

The main storage circuit 37 is a storage device such as an HDD (hard disk drive), an SSD (solid state drive), or an integrated circuit storage device that stores various information. Further, the main storage circuit 37 may be a drive device or the like that reads and writes various information to and from a portable storage medium such as a CD-ROM drive, a DVD drive, or a flash memory. For example, the main memory circuit 37 stores an MR image, a control program of the magnetic resonance imaging device 10, and the like.

The system control circuit 38 has a CPU or MPU processor and a memory such as a ROM or RAM as hardware resources. The system control circuit 38 functions as the center of the magnetic resonance imaging device 10. Specifically, the system control circuit 38 reads out the control program stored in the main storage circuit 37, expands it on the memory, and controls each part of the magnetic resonance imaging apparatus 10 according to the expanded control program.

Hereinafter, the magnetic resonance imaging apparatus 10 of the present embodiment will be described in detail.

First, the installation environment of the magnetic resonance imaging system 1 according to the present embodiment will be described with reference to FIG. FIG. 3 is a diagram showing an example of the installation environment of the magnetic resonance imaging system according to the present embodiment. As shown in FIG. 3, an examination room 300 in which MR imaging is performed and a control room 400 adjacent to the examination room 300 are provided. A pedestal 11 and a sleeper 13 are installed in the examination room 300. A sleeper 13 is provided in front of the gantry 11. A mobile screen device 15 is provided in the bore of the gantry 11. The inspection room 300 is a shield room capable of shielding the leakage magnetic field from the gantry 11 and the electromagnetic field from the outside. The examination room 300 is provided with a door D1 for entering and exiting the room. Further, a door D2 for traffic between the inspection room 300 and the control room 400 is provided between the inspection room 300 and the control room 400. A console 27, a projector 100, and a projector control device 200 are installed in the control room 400. The projector 100 is installed behind the gantry 11 with a wall 500 between the inspection room 300 and the control room 400. A window 510 through which the projected light LP can be transmitted is provided in a portion of the wall 500 where the projected light LP propagating from the projector 100 toward the mobile screen device 15. The projected light LP can be propagated from the projector 100 installed in the control room 400 to the mobile screen device 15 in the examination room 300 through the window 510. It is preferable that the control room 400 is also provided with a door D3 for entering and exiting the room.

The above layout is an example and is not limited to this. For example, although the projector 100, the projector control device 200, and the console 27 are installed in the control room 400, the console 27 and the projector control device 200 may be installed in a different room from the projector 100. Further, if the projector 100 can be formed of a material that is not affected by the magnetic field, the projector 100 may be provided in the inspection room 300. Further, in addition to the inspection room 300 and the control room 400, a machine room or the like for installing the gradient magnetic field power supply 21 and the receiving circuit 25 may be provided.

A hollow bore 53 is formed in the gantry housing 51. A rail 55 parallel to the central axis Z of the bore 53 is formed in the lower portion of the bore 53 of the gantry housing 51. The rail 55 is a structure that guides a slide along the central axis Z of the top plate 131 and the mobile screen device 15. The rail 55 is provided on the inner wall 57 of the gantry housing 51 in contact with the bore 53. The rail 55 is made of a non-magnetic material that does not act on the magnetic field used for magnetic resonance imaging. Here, the direction from the bed side to the projector side with respect to the Z axis is defined as the + Z axis direction, and the direction from the projector side to the bed side is defined as the −Z axis direction.

Next, the structure of the mobile screen device 15 will be described with reference to FIGS. 4 to 7. FIG. 4 is a perspective view of the mobile screen device 15 according to the present embodiment. FIG. 5 is a side view of the mobile screen device 15. FIG. 6 is a front view of the mobile screen device 15. FIG. 7 is a perspective view of the adjacent mobile screen device 15 and the top plate 131.

As shown in FIGS. 4 to 7, the mobile screen device 15 includes a moving body 61, a screen 63, a frame 65, and a reflector 67. The moving body 61 is a structure (moving carriage) that moves along a rail 55 provided on the inner wall 57 of the gantry housing 51. Wheels (not shown) that roll on the rail 55 are attached to the lower portion of the moving body 61 in order to improve the runnability of the rail 55. If the moving body 61 can travel on the rail 55, it is not always necessary to provide wheels, and the surface in contact with the rail 55 may be formed of a material having a low coefficient of friction. Further, instead of the rail 55 and the wheel, a guide such as a linear motion bearing may be provided. With these configurations, the moving body 61 can move in the bore along the central axis Z of the bore 53. The moving body 61 supports the screen 63 and the frame 65. The moving body 61 is formed of a non-magnetic material such as a resin that does not act on a magnetic field.

As shown in FIG. 7, for example, the moving body 61 and the top plate 131 may be adjacent to each other. At this time, the moving body 61 can move in the bore together with the top plate 131 along the central axis Z of the bore 53. A subject fixture 137 is attached to the front portion (+ Z axis direction side) of the top plate 131. The subject fixing tool 137 fixes the head of the subject P placed on the top plate 131. The subject fixture 137 has a curved shape so as to cover the back of the head without obstructing the view of the subject P placed on the top plate 131 on its back. That is, the frontal side of the subject fixture 137 is open.

As shown in FIGS. 4 to 7, the screen 63 is provided on the moving body 61. The image from the projector 100 is projected onto the screen 63 from the side opposite to the side where the top plate 131 is inserted into the bore 53. That is, the projector 100 is arranged on the side opposite to the sleeper 13 with the screen 63 interposed therebetween. Here, the surface of the screen 63 on the projector 100 side is referred to as the back surface, and the surface on the sleeper 13 side is referred to as the front surface. The screen 63 is preferably made of a translucent material in order to project an image on the surface. As such a translucent material, translucent plastic, frosted glass, or the like may be used. Since the screen 63 is made of a translucent material, the projected light emitted from the projector 100 is applied to the back surface of the screen, and an image corresponding to the projected light is projected on the front surface. As a result, the subject P and the like can see the image projected on the surface from the sleeper 13 side through the reflector 67. The screen 63 may have a planar shape or a curved surface shape. When it has a curved surface shape, it is preferable that the concave surface faces the sleeper 13 side, that is, the concave surface is arranged so as to form a surface. When the concave surface faces the bed 13 side, it is possible to cover the rear periphery of the head of the subject P placed on the top plate 131 with the screen 63. As a result, the field of view of the subject P can be filled with the image projected on the screen 63 and immersed in the image.

As shown in FIG. 6, the frame 65 has an outer diameter RS smaller than the diameter RB of the inner wall 57 in contact with the bore 53 of the gantry housing 51. By designing the outer diameter RS to be smaller than the inner diameter RB in this way, the mobile screen device 15 can be inserted into the bore 53. In the bore 53, wind is flowing from a ventilation fan (not shown) provided on the gantry 11. By providing the gap G1 between the edge of the screen 63 and the inner wall 57, it is possible to prevent the wind sent from the ventilation fan from being blocked by the screen 63.

As shown in FIGS. 4, 5 and 7, at the two connection points 66 between the frame 65 and the moving body 61, the subject P placed on the top plate 131 can visually recognize the image via the reflector 67. In this state, it is located on the projector side with respect to the screen 63. The connection portion 66 between the frame 65 and the moving body 61 is provided at a position on the moving body 61 that does not block the image projected from the projector 100 to the screen 63. The frame 65 has a first support portion 651 and a second support portion 653.

The frame 65 is provided on the moving body 61 so as to be movable along the central axis Z. In addition to the above, the frame 65 may be provided on the moving body 61 so that the second support portion 653 can be moved in the outer shape direction along the outer shape of the first support portion 651. FIG. 8 is a diagram showing how the first support portion 651 can move along the central axis Z and how the second support portion 653 can move along the outer shape direction. The first support portion 651 and the second support portion 653 will be described in detail later. At least one of the first support portion 651 and the second support portion 653 may be made of a transparent material. More preferably, the frame 65 is made of a transparent material. As a result, the feeling of pressure on the subject P by the frame 65 can be reduced.

The surface of the first support portion 651 facing the moving body 61, that is, the inner surface (hereinafter referred to as the inner surface) of the first support portion 651, is the surface of the projected light LP emitted from the projector 100. A diffusion structure may be provided to diffuse the projected light that has arrived. The diffusion structure is, for example, a coating coating for forming a fine uneven surface, a surface treatment (blast treatment) such as sandblasting, and various diffusers (diffusers).

A vibration damping device that suppresses the vibration of the reflector 67 due to the vibration of the moving body 61 may be provided between the first support portion 651 of the frame 65 and the moving body 61. FIG. 9 is a diagram showing an example of a vibration damping device 68 provided between the first support portion 651 and the moving body 61. The vibration damping device 68 is, for example, various dampers made of a non-magnetic material, a shock absorber, and the like. As a result, as shown in FIG. 9, even if the moving body 61 inserted in the bore vibrates, the vibration of the reflector 67 is suppressed by the vibration damping device 68, and the subject P can be immersed in the image. ..

As shown in FIGS. 4, 5 and 7, the first support portion 651 is connected to the moving body 61 at the connection point 66 and is arranged on the projector side with respect to the screen 63. At this time, the position of the first support portion 651 is a position outside the field of view of the subject P placed on the top plate 131. The first support portion 651 has, for example, a shape curved along the inner wall 57 of the bore 53. The shape of the first support portion 651 is not limited to the above arc as long as it does not block the image projected from the projector 100 onto the screen 63.

As shown in FIG. 8, the first support portion 651 may be supported by the moving body 61 so as to be movable toward the projector along the central axis Z of the bore 53. At this time, for example, a linear motion bearing is provided at the end of the first support portion 651, that is, the connection portion 66. Further, the moving body 61 is provided with a guide rail (not shown) for guiding the linear motion bearing provided at the end of the first support portion 651 along the central axis Z between the screen 63 and the projector 100. NS. As a result, the position of the reflector 67 can be adjusted along the central axis Z.

As shown in FIGS. 4 to 7, the second support portion 653 supports the reflector 67 from the first support portion 651 beyond the screen 63. For example, the second support portion 653 supports the reflector 67 across the screen 63 by passing a gap between the outer edge of the screen 63 above the midpoint between the upper end and the lower end of the screen 63 and the inner wall 57 of the bore 53. do. In other words, the second support portion 653 extends from the first support portion 651 through the gap between the outer edge of the screen 63 above the midpoint between the upper and lower ends of the screen 63 and the inner wall 57 of the bore 53, and is reflected. Supports the plate 67. Specifically, the second support portion 653 is above the midpoint between the upper end and the lower end of the screen 63 in the gap between the inner wall 57 of the bore 53 and the screen 63, and is the center line of the screen 63 parallel to the Y axis. It passes through two positions symmetrical with respect to the bore 53 and is composed of two arms parallel to the central axis Z of the bore 53. The second support portion 653 rotatably supports the reflector 67 with the X-axis as the rotation axis by these two arms. At this time, the cross-sectional shape of each of the two arms has, for example, a shape curved along the inner wall 57 of the bore 53. As a result, the angle of the reflector 67 can be adjusted with the X axis as the rotation axis.

The second support portion 653 may be supported by the first support portion 651 so as to be movable toward the projector along the central axis Z of the bore 53. At this time, for example, a linear motion bearing is provided at the connecting portion 70 between the second support portion 653 and the first support portion 651. Further, the second support portion 653 is provided with a guide rail for guiding the linear motion bearing along the central axis Z of the bore 53. At this time, the linear motion bearing and the guide rail for guiding the linear motion bearing are made of a non-magnetic material.

The structure of the second support portion 653 is not limited to the structure shown in FIGS. 4 to 7. For example, the second support portion 653 extends from the upper end of the first support portion 651 along the central axis Z of the bore 53 beyond the screen 63 to a position directly above the subject fixture 137 of the top plate 131. It may be one arm. At this time, the arm as the second support portion 653 extends from, for example, the position of the uppermost end of the first support portion 651 beyond the screen 63 to a position directly above the top plate 131. The connecting portion 70 between the first support portion 651 and the second support portion 653 is not limited to the position of the uppermost end of the first support portion 651.

Further, as shown in FIG. 8, the second support portion 653 may be supported by the first support portion 651 so as to be movable from the upper end of the first support portion 651 to at least one connection portion 66. At this time, a non-magnetic guide rail for guiding the linear motion bearing is provided on the side surface of the first support portion 651 facing the inner wall 57 of the bore 53 from the upper end of the first support portion 651 to at least one connection portion 66. Be done. As a result, the position of the reflector 67 can be adjusted along the Y axis perpendicular to the top plate 131. When the second support portion 653 has two arms and each of the two arms is moved to the nearest connection point 66, the arm supporting the reflector 67 has a structure that can be expanded and contracted in the X-axis direction. The reflector 67 moves along the central axis Z, moves along the direction perpendicular to the top plate 131 (for example, the Y-axis direction), and moves in a direction orthogonal to the central axis (for example, X). It may be supported by the frame 65 so that at least one of rotations about the axis) can be realized.

A vibration damping device that suppresses the vibration of the reflector 67 due to the vibration of the moving body 61 may be provided between the second support portion 653 and the reflector 67. FIG. 10 is a diagram showing an example of a vibration damping device 72 provided between the second support portion 653 and the reflector plate 67. As shown in FIG. 10, even if the moving body 61 inserted in the bore vibrates, the vibration of the reflector 67 is suppressed by the vibration damping device 72, and the subject P can be immersed in the image.

The reflector 67 is separated from the surface of the moving body 61 so as not to hit the head of the subject P placed on the top plate 131 in a state where the moving body 61 and the top plate 131 are connected. It is supported by the second support portion 653 of the frame 65. As shown in FIGS. 4 to 7, the reflector 67 is provided at a substantially end portion of the second support portion 653. The reflector 67 reflects the image projected on the surface of the screen 63. The reflector 67 is made of a non-magnetic material, and may be made of any material as long as the object can be optically reflected. For example, as the reflector 67, a mirror in which aluminum is vapor-deposited on acrylic, a half mirror in which a dielectric film is attached, or the like may be used. The subject P whose head is arranged on the subject fixture 137 can see the image projected on the surface through the reflector 67.

The reflector 67 is rotatably provided on the second support portion 653 in order to manually adjust the angle of the reflector 67. Specifically, as shown in FIG. 5, it is rotatably provided around the rotation axis RR1 by a rotation mechanism (not shown) provided on the second support portion 653. The rotation axis RR1 is provided, for example, parallel to the X axis so that the orientation of the reflector 67 with respect to the surface of the screen 63 can be adjusted. More specifically, the second support portion 653 is provided so as to be switchable between at least a first angle for the first projection format and a second angle for the second projection format, which will be described later. Is good. The first projection format is a format in which the subject P views the image of the screen 63 from outside the gantry 11 without passing through the reflector 67. Therefore, the first angle of the reflector 67 in the first projection format may be set to an angle that does not block the view of the subject P or the like outside the gantry 11, for example, substantially horizontal. At this time, the second support portion 653 is moved toward the projector side along the central axis Z, or is moved along the first support portion 651 to the connection point 66.

The second projection format is a format in which an image is viewed through the reflector 67 in the bore 53. When switching from the first projection format to the second projection format, the second support portion 653 moves so that, for example, the reflector 67 is located directly above the subject fixture 137, as shown in FIGS. 4 to 7. Will be done. The second angle of the reflector 67 in the second projection format may be set to an arbitrary angle between horizontal and vertical according to the physique and the like of the subject P who is an observer.

The reflector 67 may be configured by a prism mirror. FIG. 11 is a diagram showing an example of an optical path 672 when the reflector 67 is a prism mirror 671. FIG. 12 is a diagram showing an optical path 674 when the reflector 67 is a normal mirror 673. As shown in FIGS. 11 and 12, when the prism mirror 671 is used as the reflector 67, the angle of the reflector 67 can be made acute with respect to the central axis Z as compared with the normal mirror 673. As a result, the reflector 67 can be brought closer to the subject P than the normal mirror 673, and the posture of the reflector 67 can be lowered.

The reflector 67 may have a Fresnel structure. When the prism mirror 671 is used as the reflector 67, the thickness of the reflector 67 increases. At this time, a Fresnel structure may be added to the reflector 67 in addition to the prism mirror 671. FIG. 13 is a diagram showing an example of an optical path 676 of a reflector 675 having a Fresnel structure added to a prism mirror 671. In FIGS. 11 to 13, components other than the reflector in the mobile screen device 15 and the like are omitted. As shown in FIG. 13, the thickness of the reflector 675 can be reduced like a normal mirror 673, and the angle of the reflector 675 can be made acute with respect to the central axis Z. As a result, even in the gantry 11 having the small-diameter bore, the reflector 67 can be inserted into the bore 53 in a state where the image projected on the screen 63 can be visually recognized by the subject P.

According to the configuration described above, the following effects can be obtained.
According to the medical image diagnostic apparatus 10 according to the present embodiment, the connection portion 66 between the frame 65 supporting the reflector 67 and the moving body 61 is positioned on the projector side with respect to the screen 63 in the second projection format. Can be done. In addition, according to the present embodiment, the frame 65 that supports the reflector 67 is placed at a position that does not block the image projected from the projector 100 onto the screen 63 and does not obstruct the space in which the subject P is placed. Can be provided. As a result, the side surface of the head of the subject P placed on the top plate 131 and inserted into the bore 53 is open, so that the subject P can obtain a more open feeling.

That is, according to the medical image diagnostic apparatus 10 according to the present embodiment, even in the gantry 11 having a small-diameter bore, in the second projection format, the image quality of MR imaging is not adversely affected, and the coil shape and imaging are performed. The reflector 67 can be inserted into the bore 53 without depending on the site. In addition, according to the diagnostic imaging apparatus 10 for medical use, even if the gantry 11 has a small-diameter bore, the subject P is provided with a feeling of openness in the patient examination space without sacrificing the patient examination space in the bore. However, the awareness of the frame 65 by the subject P can be reduced.

Further, according to the medical diagnostic imaging apparatus 10, the movement of the reflector 67 along the central axis Z by the first support portion 651 and the movement of the reflector 67 along the outer diameter of the screen 63 by the second support portion 653 causes Y. The position of the reflector 67 along the axis and the Z axis can be easily adjusted. As a result, it is not necessary to place the subject P on the top plate in accordance with the position of the reflector 67, and the position and angle of the reflector 67 can be freely adjusted with respect to the position of the subject P placed on the top plate 131. The degree is improved and the inspection efficiency is improved.

Further, according to the medical diagnostic imaging apparatus 10, a diffusion structure or the like can be provided on the inner surface of the first support portion 651. As a result, the projected light that reaches the screen 63 through the inner surface of the first support portion 651 can be reduced, or the projected light can be prevented from reaching the screen 63 through the inner surface of the first support portion 651. can. From these facts, according to the medical diagnostic imaging apparatus 10, a clearer image can be provided to the subject P, and the habitability in the bore 53 of the gantry 11 can be improved.

From these facts, according to the medical image diagnostic apparatus 10 according to the present embodiment, the subject P is aware of the oppressive feeling and the wearing feeling on the mobile screen apparatus 15 in the second projection format during the execution of MR imaging. Since this can be reduced, a relaxing image projected on the screen 63 can be provided to the subject P in a wide and realistic state, and the immersive feeling of the subject P in the image can be improved. can. That is, the medical image diagnostic apparatus 10 can provide the subject P with an examination environment in which the subject P can be sufficiently relaxed.

From the above, the medical imaging apparatus 10 can reduce anxiety about the subject P arranged in the bore and make the subject P feel that the examination time is shorter than the actual length. , The subject P can be allowed to stand still during the execution of imaging. Therefore, the medical image diagnostic apparatus 10 can stably collect images and improve the quality of images related to the subject P.

(First application example)
The difference between this application example and the embodiment is that, for example, the light generated by a plurality of irradiators (in-bore illumination) provided on the second support portion 653 of the frame 65 (hereinafter referred to as bore illumination light) is referred to as light. It is to be projected on the inner wall 57 substantially directly above the top plate 131. That is, the second support portion 653 in this application example is equipped with an irradiator related to in-bore lighting.

FIG. 14 is a diagram showing a side surface of the mobile screen device 15 according to this application example. As shown in FIG. 14, the second support portion 653 has at least one irradiator 74 that generates light to irradiate the inner wall 57 of the bore 53 facing the top plate 131. The number of irradiators 74 is not limited to 6 as shown in FIG. The irradiator 74 is, for example, LEDs arranged in a row along a central axis Z over a predetermined length. The irradiator 74 may adjust the amount of the bore illumination light BL according to the position of the mobile screen device 15 in the bore in order to keep the degree of illumination in the bore constant.

Further, even if the irradiator 74 generates light corresponding to the hue, brightness, light shape pattern, etc. for making the examination space for the subject P arranged in the bore 53 comfortable (for example, relaxing). good. The power supply line connected to the irradiator 74 via the mobile body 61 and the first support portion 651 and the irradiator 74 are covered with a magnetically shielded member. Instead of the irradiator 74, various non-magnetic or magnetic-proof optical instruments (various lenses, amplifiers, etc.) may be provided in the second support portion 653. At this time, an optical fiber that transmits visible light from the outside of the bore 53 is connected to the optical device via the moving body 61 and the first support portion 651.

When the second support portion 653 is made of a transparent material, the surface of the second support portion 653 facing the moving body 61 or the top plate 131, that is, the lower surface of the second support portion 653 is covered with the above-mentioned irradiator. Alternatively, a structure may be provided in which the projected light that has reached the second support portion 653 is reflected and diffused on the inner wall 57 of the bore 53. This structure is, for example, a coating coating, a blasting treatment, or a diffuser (diffuser) that forms a fine uneven surface.

According to the medical image diagnostic apparatus 10 according to the present application example, the following effects can be obtained in addition to the effects according to the present embodiment.
According to the medical image diagnostic apparatus 10, the medical image diagnostic apparatus 10 has at least one irradiator 74 which is provided on the second support portion 653 of the frame 65 and generates light to irradiate the inner wall 57 of the bore 53 facing the top plate 131. Thereby, for example, the periphery of the subject P can be brightened at the request of the subject P or the like. In addition, according to the medical diagnostic imaging apparatus 10, when the top plate 131 on which the subject P is placed moves between the end of the bore 53 on the bed 13 side and the imaging position, it is passed through the irradiator 74. The hue of the light emitted to the inner wall 57 can be changed.

From the above, according to the medical image diagnostic apparatus 10 according to the present application example, it is possible to irradiate the intra-bore illumination at the optimum position for the subject P, and the subject P inserted into the bore 53 is a video and a subject P. You can get the feeling of being surrounded by the irradiation light. In addition, when the top plate 131 moves to the imaging position, it is possible to produce a more relaxing environment around the subject P who is viewing the image by changing the light.

(Second application example)
The difference between this application example and the embodiment is that the second support portion 653 and the moving body 61 have a structure in which the second support portion 653 and the moving body 61 can expand and contract along the central axis Z according to the position of the top plate 131 in the bore, and the first support portion The second support portion 653 has a foldable structure with the connecting portion between the 651 and the second support portion 653 as a rotation axis. FIG. 15 is a side view showing a side surface of the mobile screen device 15 according to this application example.

As shown in FIG. 15, the moving body 61 and the second support portion 653 have a nesting structure and a mechanism for expanding and contracting the moving body 61 and the second support portion 653 according to the amount of insertion of the top plate 131 into the bore. Hereinafter referred to as an expansion / contraction mechanism). The nesting structure is configured by providing, for example, a non-magnetic linear motion bearing and a guide rail for each of the plurality of nests. The expansion / contraction mechanism is, for example, various non-magnetic transmission mechanisms in which each of the plurality of nested portions in the nested structure and the end portion of the top plate 131 on the opposite side of the projector 100 are connected. The various transmission mechanisms include, for example, non-magnetic worm gears, rack and pinions, belt drives, chain drives, shaft drives, and the like. The various transmission mechanisms expand and contract the moving body 61 and the second support portion 653 according to the insertion amount of the top plate 131, that is, increase or decrease the overlapping amount of nesting.

The moving body 61 and the second support portion 653 can be expanded and contracted along the central axis Z according to the position of the top plate 131 in the bore, that is, following the stroke of the top plate 131 by the nesting structure and the expansion / contraction mechanism. It becomes. The stretchable structure of the moving body 61 and the second support portion 653 is not limited to the nested structure, as long as it is stretchable along the central axis Z and has the strength to support the reflector 67. It may have any structure.

FIG. 15 shows the moving body 61 and the second support portion 653 before contraction along the central axis Z in a state where the mobile screen device 15 is arranged outside the bore 53 on the projector side. FIG. 16 shows a moving body 61 and a second support portion 653 contracted along the central axis Z in a state where the mobile screen device 15 is arranged outside the bore 53 on the projector side. As shown in FIG. 16, the length of the mobile screen device 15 protruding from the bore 53 on the projector side by contracting the moving body 61 and the second support portion 653 along the central axis Z is shown in FIG. It is shorter than the length of the mobile screen device 15.

The first support portion 651 rotatably supports the contracted second support portion 653 at the connecting portion between the first support portion 651 and the second support portion 653 with the X axis as the rotation axis. In FIG. 17, in a state where the mobile screen device 15 is arranged outside the bore 53, the screen 63 has the second support portion 653 with the connecting portion 70 between the first support portion 651 and the second support portion 653 as a rotation axis. It shows how it is folded toward. As shown in FIG. 17, when the mobile screen device 15 is not used, the mobile screen device 15 is folded after the moving body 61 and the second support portion 653 are contracted to the outside of the bore 53 on the projector side. Be placed.

According to the medical image diagnostic apparatus 10 according to the present application example, the following effects can be obtained in addition to the effects according to the present embodiment.
According to the medical diagnostic imaging apparatus 10, the moving body 61 and the second support portion 653 have a structure in which the moving body 61 and the second support portion 653 can expand and contract along the central axis Z according to the position of the top plate 131 in the bore, and the first support portion The second support portion 653 has a foldable structure with the connecting portion 70 between the 651 and the second support portion 653 as a rotation axis. As a result, according to this application example, when the mobile screen device 15 is located outside the bore 53 on the projector side when the mobile screen device 15 is not in use, the length of protrusion from the bore 53 is shortened. Can be done.

From the above, the distance between the wall 500 on the projector side and the gantry housing 51 in the examination room 300 can be shortened, the examination room 300 can be reduced, or the space in the examination room 300 can be effectively utilized. Can be done. In addition, according to this application example, the limitation of the moving range of the top plate 131 inserted in the bore is relaxed, so that the examination room 300 can be used efficiently. Further, even when the mobile screen device 15 is not used, the mobile screen device 15 can be spatially and efficiently stored outside the bore 53 on the projector side.

(Second Embodiment)
The difference from the first embodiment is that the lower end of the screen 63 is located below the mounting surface of the subject P on the top plate 131 inserted in the bore. FIG. 18 is a perspective view of the mobile screen device 15 according to the present embodiment. As shown in FIG. 18, the lower end of the screen 63 is located below the mounting surface of the subject P on the top plate 131. At this time, a gap is provided between a part of the screen located below the mounting surface of the subject P on the top plate 131 (hereinafter, referred to as a lower screen) and the top plate 131. The projected light LP projected from the projector 100 onto the screen 63 also reaches the lower screen. Due to this gap, the subject P placed on the top plate 131 can visually recognize the image on the lower screen via the reflector 67. Although one arm is described as the second support portion 653 in FIG. 18, the second support portion 653 may be two arms as shown in FIGS. 4 to 7 and 19.

FIG. 19 is a side view showing a side surface of the mobile screen device 15 of the present embodiment. As shown in FIG. 19, the image projected from the projector 100 onto the screen 63 also reaches the lower screen. FIG. 20 is a view of the mobile screen device 15 according to the present embodiment as viewed from the projector side. The mobile screen device 15 in FIGS. 19 and 20 has two arms as a second support 653. As shown in FIG. 20, the screen 63 in the present embodiment has a cutout portion corresponding to the cross-sectional shape of the second support portion 653 in order to pass the second support portion 653 from the projector side to the top plate side. You may be doing it.

According to the medical image diagnostic apparatus 10 according to the present embodiment, the following effects can be obtained in addition to the effects according to the first embodiment.
According to the medical diagnostic imaging apparatus 10, the lower end of the screen 63 can be arranged below the mounting surface of the subject P on the top plate 131 inserted in the bore. As a result, the area of the screen 63 in the present embodiment becomes wider than the cross-sectional area of the bore 53 above the top plate 131. As a result, the image projected on the screen 63 can be provided over a wider field of view of the subject P, and the immersive feeling of the subject P in the image can be improved. That is, the medical image diagnostic apparatus 10 can provide the subject P with a test environment in which the subject P can be sufficiently relaxed.

From the above, the medical imaging apparatus 10 can further reduce anxiety about the subject P arranged in the bore and make the subject P feel that the examination time is shorter than the actual length. Therefore, the subject P can be allowed to stand still during the execution of imaging. Therefore, the medical image diagnostic apparatus 10 can collect images more stably, and can further improve the quality of the image relating to the subject P.

(Third Embodiment)
The difference between the first embodiment and the second embodiment is that the frame 65 has a substantially tubular shape in which an arc along the inner wall 57 of the bore 53 is extended along the central axis Z from the projector side beyond the screen 63. To have.

FIG. 21 is a side view showing a side surface of the mobile screen device 15 according to the present embodiment. FIG. 22 is a view of the mobile screen device 15 according to the present embodiment as viewed from the projector side. As shown in FIGS. 21 and 22, the frame 65 has a diameter larger than the outer diameter of the screen 63 and smaller than the inner diameter of the bore 53. The frame 65 has a thickness sufficient to support the reflector 67. The thickness of the frame 65 has, for example, a thin wall shape thinner than the gap between the inner wall 57 of the bore 53 and the screen 63. The frame 65 in this embodiment may be made of a transparent material.

As shown in FIGS. 21 and 22, the lower end of the screen 63 in this embodiment is located below the mounting surface of the top plate 131. The lower end of the screen 63 in the present embodiment may be at a level corresponding to the mounting surface of the top plate 131 as in the screen 63 as shown in the first embodiment.

As shown in FIG. 21, at the end of the frame 65 on the top plate side, the portion farthest from the projector 100 is the position facing the upper portion of the inner wall 57 of the bore 53, and the portion closest to the projector 100 is the sky. It is a position adjacent to the mounting surface of the plate 131. That is, the end of the frame 65 on the top plate side is cylindrical from the position close to the upper end of the bore 53 to the mounting surface on the projector side from the position where the head of the subject P is placed on the top plate 131. It has a truncated shape at the ends. The shape of the end portion of the frame 65 on the top plate side is not limited to the above description.

According to the medical image diagnostic apparatus 10 according to the present embodiment, the following effects can be obtained.
According to the medical image diagnostic apparatus 10, the screen 63 is formed from the projector side along the central axis Z by forming an arc along the inner wall 57 of the bore 53 with a thickness thinner than the gap between the screen 63 and the inner wall 57 of the bore 53. It has a substantially tubular frame 65 that extends beyond. Thereby, according to the medical diagnostic imaging apparatus 10 according to the present embodiment, it is possible to provide the frame 65 that supports the reflector 67 without sacrificing the patient examination space. Further, according to the mobile screen device 15 according to the present embodiment, since the frame 65 has a substantially cylindrical shape, it does not hinder the field of view of the subject P and has the same effect as described in the first embodiment. Can be obtained.

(Fourth Embodiment)
The difference from the first to third embodiments lies in the structure of the first support portion 651. The connection portion 66 according to the present embodiment is located on the projector 100 side with respect to the screen 63. The gap between the upper end of the screen 63 and the inner wall 57 of the bore 53 is larger than the gap between each of the left and right ends of the screen 63 and the inner wall 57. FIG. 23 is a view showing a front view of the mobile screen device 15 in the present embodiment together with a front view of the mobile screen device 15 in the first to third embodiments. As shown in FIG. 23, the gap GA2 between the upper end of the screen 63 and the inner wall 57 of the bore 53 in the present embodiment is larger than the gap GA1 between each of the left and right ends of the screen 63 and the inner wall 57. FIG. 24 is a top view of the mobile screen device 15 according to the present embodiment and the mobile screen device 15 according to the first to third embodiments as viewed from the upper surface of the top plate 131. As shown in FIGS. 23 and 24, according to the present embodiment, the viewing angle VA2 of the subject P via the reflector 67 is set to the subject P via the reflector 67 in the first to third embodiments. The viewing angle of VA1 can be made wider than that of VA1. Further, according to the present embodiment, as shown in FIGS. 23 and 24, the reach range L2 of the projected light passing through the gap between the screen 63 and the inner wall 57 to the inner wall 57 is defined as the first to third embodiments. It can be made wider than the reachable range L1 of the projected light in. Thereby, in this embodiment, the projected light can reach a wider area of the inner wall 57 as compared with the first to third embodiments.

FIG. 25 is a perspective view of the mobile screen device 15 according to the present embodiment. As shown in FIG. 25, the lower end of the first support portion 651 is provided on the moving body 61 via a linear motion bearing and a guide rail 62 (not shown). The connection point 66 between the frame 65 and the moving body 61 corresponds to the contact surface between the linear motion bearing and the guide rail 62. Further, the second support portion 653 directly above the rectangular reflector 67 having a long side in the Y-axis direction is arranged at a position separated from the reflector 67 by a predetermined interval. As shown in FIG. 25, a part 655 of the second support portion 653 directly above the reflector 67 functions as a handle for moving the frame 65 along the central axis Z.

The outer edge of the screen 63 preferably has a shape in which the gap between the upper end of the screen 63 and the inner wall 57 is larger than the gap between each of the left and right ends of the screen 63 and the inner wall 57. For example, when the cross-sectional shape of the bore 53 is circular as shown in FIG. 6, the shape of the outer edge of the screen 63 is the length along the X axis at the outer edge of the screen 63 as the major axis and the length along the Y axis. Is an ellipse whose minor axis is. That is, the shape of the outer edge of the screen 63 in the present embodiment is shown in FIGS. 4, 6, and 7 by extending the left and right ends of the outer edge of the screen 63 shown in FIGS. 4, 6, and 7 along the X axis. The upper end of the outer edge of the screen 63 is shortened along the Y axis. The shape of the outer edge of the screen 63 is not limited to an ellipse flattened in the vertical direction, and if the relationship of the size of the gap can be maintained, a polygon, a conic section, or the upper part of the screen 63 shown in FIG. 4 is cut off. Structure may be used.

In the first support portion 651, in the upper portion located above the connection position (connection portion) between the first support portion 651 and the second support portion 653, the projected light LP emitted from the projector 100 is the outer edge of the screen 63. It is provided at a position where it can pass through the area between the bore 53 and the inner wall 57. In other words, the upper portion of the first support portion 651 is formed so as not to block the projected light LP passing between the outer edge of the screen 63 and the inner wall 57 of the bore 53. At this time, a part of the projected light LP is projected onto the inner wall 57 of the bore 53 by passing between the screen 63 and the upper portion and then passing through the gap between the screen 63 and the inner wall 57. As shown in FIG. 25, when the second support portion 653 has a U-shape, the space through which the projected light projected on the inner wall 57 of the bore 53 passes beyond the upper part of the screen 63 is the first support portion 651. It becomes a space surrounded by the upper part of the above and the second support portion 653. That is, as shown in FIG. 25, the frame 65 has an opening surrounded by an upper portion of the first support portion 651 and a second support portion 653. In other words, when the second support portion 653 has a U-shape, this opening is a screen in a state where the subject P placed on the top plate 131 can visually recognize the image through the reflector 67. It is arranged across 63.

An example of the upper portion of the first support portion 651 that does not block the projected light LP will be described. As shown in FIG. 25, the first support portion 651 has a central axis in a lower portion in which the width TH2 along the central axis Z in the upper portion of the first support portion 651 is located below the connection position in the first support portion 651. It is formed so as to be narrower than the width TH1 along Z. At this time, the gap GA2 between the upper portion and the screen 63 is wider than the gap GA1 between the lower portion of the first support portion 651 and the screen 63. The upper portion of the first support portion 651 may be omitted as long as it has the strength to support the second support portion 653 and the reflector 67. At this time, an opening region is provided from the handle 655 of the second support portion 653 toward the projector 100 so that the projected light reaches the inner wall 57 of the bore 53.

According to the configuration described above, the following effects can be obtained.
According to the medical image diagnostic apparatus 10 according to the present embodiment, the connection portion 66 between the frame 65 and the moving body 61 is located on the projector 100 side with respect to the screen 63, and the upper end of the screen 63 and the inner wall 57 of the bore 53. The gap between them can be made larger than the gap between each of the left and right ends of the screen 63 and the inner wall 57. In addition, by making the shape of the reflector 67 rectangular, it is possible to provide the subject P with an image projected on the screen 63 over a wider viewing range by utilizing the width of the screen 63. Further, according to the medical image diagnostic apparatus 10, the projected light LP emitted from the projector 100 can pass through the upper portion of the first support portion 651 over the region between the outer edge of the screen 63 and the inner wall 57. Can be provided at a position. In addition, according to the medical imaging apparatus 10, the gap between the upper portion of the first support portion 651 and the screen 63 is wider than the gap between the lower portion of the first support portion 651 and the screen 63. be able to. Further, according to the medical imaging apparatus 10, the width of the upper portion of the first support portion 651 along the central axis Z is narrower than the width of the lower portion of the first support portion 651 along the central axis Z. Can be done. That is, according to the present embodiment, the projected light can reach a wider area of the inner wall 57 as compared with the first embodiment. As a result, according to the present embodiment, the shape of the screen 63 can be formed into a shape suitable for the desired range in order to allow the projected light on the inner wall 57 to reach a desired range. That is, according to the present embodiment, the reachable range of the projected light on the inner wall 57 can be designed (set) by the shape of the screen 63.

From these facts, according to the medical image diagnostic apparatus 10 according to the present embodiment, the projected light LP can be projected over a wide range by the inner wall 57 on the back side of the rectangular reflector 67 utilizing the width of the screen 63. According to the medical image diagnostic apparatus 10, the periphery of the reflector 67 can be filled with an image in the field of view of the subject P placed on the top plate 131 and inserted into the bore 53. As a result, it is possible to provide the subject P with a higher field of view and a more realistic image space, and the image reflected by the reflector 67 and the image projected on the inner wall 57 of the bore 53 can be used. It is possible to improve the immersive feeling and the sense of unity of the subject P with respect to the image. That is, the medical image diagnostic apparatus 10 can provide the subject P with a test environment in which the subject P can be sufficiently relaxed.

From the above, the medical imaging apparatus 10 can further reduce anxiety about the subject P arranged in the bore and make the subject P feel that the examination time is shorter than the actual length. Therefore, the subject P can be allowed to stand still during the execution of imaging. Therefore, the medical image diagnostic apparatus 10 can collect images more stably, and can further improve the quality of the image relating to the subject P.

According to the medical diagnostic imaging apparatus such as the above-described embodiment and at least one application example, it is possible to improve the habitability in the bore of the gantry 11.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and the equivalent scope thereof.

1 ... Medical diagnostic imaging system (magnetic resonance imaging system), 10 ... Medical diagnostic imaging device (magnetic resonance imaging device), 11 ... Stand, 13 ... Sleeper, 15 ... Mobile screen device, 17 ... Imaging control unit, 21 ... Tilt Magnetic power supply, 23 ... Transmission circuit, 25 ... Reception circuit, 27 ... Console, 31 ... Image control circuit, 32 ... Reconstruction circuit, 33 ... Image processing circuit, 34 ... Communication circuit, 35 ... Display circuit, 36 ... Input circuit, 37 ... main memory circuit, 38 ... system control circuit, 41 ... static magnetic field magnet, 43 ... gradient magnetic field coil, 45 ... RF coil, 51 ... gantry housing, 53 ... bore, 55 ... rail, 57 ... inner wall, 61 ... moving Body, 63 ... screen, 65 ... frame, 66 ... connection point, 67 ... reflector, 68 ... vibration suppressor, 70 ... connection part, 72 ... vibration suppressor, 74 ... irradiator, 100 ... projector, 131 ... top plate , 133 ... base, 135 ... sleeper drive device, 137 ... subject fixture, 200 ... projector control device, 300 ... examination room, 400 ... control room, 500 ... wall, 510 ... window, 651 ... first support part, 653 ... 2nd support, 655 ... Handle, D1 ... Door, D2 ... Door, D3 ... Door, GA1 ... Gap between the lower part of the 1st support and the screen, GA2 ... Upper part of the 1st support Gap between screens, L1 ... Range of reach of the projected light passing through the gap between the screen and the inner wall in the first to third embodiments, L2 ... Gap between the screen and the inner wall in the fourth embodiment. The reach of the projected light that has passed through the inner wall, TH1 ... the width along the central axis Z in the lower portion of the first support portion, TH2 ... the width along the central axis Z in the upper portion of the first support portion, G1 ... Gap, RR1 ... rotation axis, VA1 ... viewing angle of the subject via the reflector in the first to third embodiments, VA2 ... viewing angle of the subject via the reflector in the fourth embodiment.

Claims (18)

A pedestal with a bore formed and equipped with a medical imaging mechanism,
A moving body that can move in the bore along the central axis of the bore.
A screen provided on the moving body and the image from the projector is projected from the side opposite to the side where the top plate is inserted into the bore.
A reflector that reflects the image projected on the screen,
A frame provided on the moving body and supporting the reflector is provided.
The frame passes through a gap between the outer edge of the screen and the inner wall of the bore at the top of the screen.
Medical diagnostic imaging equipment. The frame is
A first support portion connected to the moving body and arranged on the projector side with respect to the screen.
It has a second support portion that extends from the first support portion through the gap and supports the reflector.
The medical diagnostic imaging apparatus according to claim 1. The connection point between the frame and the moving body is located on the projector side with respect to the screen in a state where the subject placed on the top plate can see the image through the reflector. The medical diagnostic imaging apparatus according to claim 1 or 2. The medical diagnostic imaging apparatus according to claim 1, wherein the gap between the upper end of the screen and the inner wall of the bore is larger than the gap between each of the left and right edges of the screen and the inner wall. The medical diagnostic imaging apparatus according to claim 2, wherein the first support portion has a curved shape along the inner wall. In the first support portion, the upper portion located above the connection position between the first support portion and the second support portion is a region where the projected light emitted from the projector is located between the outer edge and the inner wall. The medical diagnostic imaging apparatus according to claim 2, which is provided at a position where it can pass through. The medical diagnostic imaging apparatus according to claim 6, wherein the gap between the upper portion and the screen is wider than the gap between the lower portion located below the connection position in the first support portion and the screen. .. The medical diagnostic imaging apparatus according to claim 7, wherein the width of the upper portion along the central axis is narrower than the width of the lower portion along the central axis. At least one of the second support portion and the moving body is
It can be expanded and contracted along the central axis according to the position of the top plate in the bore.
The medical diagnostic imaging apparatus according to claim 2. At least one of the second support portion and the moving body contracts along the central axis in a state where the moving body is arranged outside the bore on the projector side.
The second support portion can be folded with the connection position between the first support portion and the second support portion as a rotation axis in a state of being arranged outside.
The medical diagnostic imaging apparatus according to claim 9. The second aspect of the invention, wherein the surface of the first support portion facing the moving body is provided with a diffusion structure for diffusing the projected light that has reached the surface of the projected light emitted from the projector. Medical diagnostic imaging equipment. The medical diagnostic imaging apparatus according to claim 1, wherein the lower end of the screen is located below the surface on which the subject is placed on the top plate inserted into the bore. The medical image diagnostic apparatus according to claim 1, wherein the reflector is composed of a prism mirror. The medical diagnostic imaging apparatus according to claim 1, wherein the reflector has a Fresnel structure. The medical image diagnostic apparatus according to claim 1, further comprising a vibration damping device provided on the moving body and suppressing the vibration of the reflector due to the vibration of the moving body. The reflector is
At least one of movement along the central axis, movement along the direction perpendicular to the top plate, and rotation with the direction orthogonal to the central axis and the direction perpendicular to the central axis as the rotation axis can be realized. The medical diagnostic imaging apparatus according to claim 1, which is supported by the frame. The medical image diagnostic apparatus according to claim 1, further comprising at least one irradiator provided on the frame and generating light to irradiate the inner wall of the bore facing the top plate. The medical diagnostic imaging apparatus according to claim 1, wherein the frame is made of a transparent material.

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