JP2016158658A - X-ray diagnostic apparatus and medical image diagnostic apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an X-ray diagnostic apparatus and a medical image diagnostic apparatus capable of supporting a user in easily grasping a display area for displaying an operation result image.SOLUTION: An X-ray diagnostic apparatus includes an operation receiving part, an image acquisition part, a display area selection part, and a grasping support part. The operation receiving part receives an instruction operation of a user through an input part. The image acquisition part acquires an image according to the operation. The display area selection part selects a selection display area which is a display area for displaying the image according to the operation acquired by the image acquisition part of a plurality of display areas that a display part possesses. The grasping support part executes support processing for the user to grasp the position of the selection display area of the plurality of display areas, and displays the image according to the operation in the selection display area.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to an X-ray diagnostic apparatus and a medical image diagnostic apparatus.

  Medical image diagnostic apparatuses such as an X-ray diagnostic apparatus, an X-ray CT (Computed Tomography) apparatus, an MRI (Magnetic Resonance Imaging) apparatus, an ultrasonic diagnostic apparatus, and a nuclear medicine diagnostic apparatus include an imaging apparatus that captures a medical image of a subject. Have. An examination room in which an imaging device is installed may be provided with a display unit having a plurality of display areas so that a plurality of images can be displayed simultaneously. This type of display unit may have a plurality of display monitors, and one monitor is divided into a plurality of display areas, or one monitor is set as one display area, and a different image is displayed for each display area. It is configured to be displayable.

  When a display unit having a plurality of display areas is used, the degree of freedom in image arrangement of which image is displayed in which display area is increased. As a technique using the high degree of freedom of image arrangement, for example, there is a technique for switching the image arrangement based on the presence or absence of imaging by an imaging apparatus.

JP 2009-189556 A

  On the other hand, various functions that are executed in response to user input operations are implemented in the medical image diagnostic apparatus. Some of these types of functions involve displaying an image (hereinafter referred to as an operation result image) as a result of executing the function. For example, in the function of creating one image from a plurality of images obtained by one-time imaging according to a user's input operation and storing the image in the storage unit, the created image is stored in the storage unit as a function execution result. Some images are stored, and the created image (operation result image) is automatically displayed. In this case, when the display unit has a plurality of display areas, it is difficult for the user to grasp which position (which display area) the operation result image is displayed on the display unit.

  Further, in the conventional technique, the display area in which the operation result image is displayed is determined according to a complicated image arrangement rule. For this reason, it is more difficult for the user to grasp the position where the operation result image is displayed. In addition, when the user manually designates a display area in which the operation result image is displayed, the user's effort is increased and convenience is lowered.

  An X-ray diagnostic apparatus line according to an embodiment of the present invention includes an operation reception unit, an image acquisition unit, a display area selection unit, and a grasp support unit in order to solve the above-described problem. The operation accepting unit accepts a user instruction operation via the input unit. The image acquisition unit acquires an image corresponding to the operation. The display area selection unit selects a selection display area, which is a display area for displaying an image corresponding to the operation acquired by the image acquisition unit, from among a plurality of display areas included in the display unit. The grasp support unit executes a support process for the user to grasp the positions of the selected display areas in the plurality of display areas and displays an image corresponding to the operation in the selected display area.

1 is a block diagram showing an example of an X-ray diagnostic apparatus according to an embodiment of the present invention. The external view which shows an example in case an X-ray diagnostic apparatus has a biplane type imaging part. (A)-(e) is explanatory drawing which shows the 1st-5th layout example of a some display area. The schematic block diagram which shows the structural example of the function implementation part by CPU of a main control part. An example of a procedure for assisting the user to easily grasp the position of the selection display area where the operation result image is displayed in the plurality of display areas by the CPU of the main control unit shown in FIG. 1 is shown. flowchart. Explanatory drawing which shows an example in case the assistance process by a grasp assistance part is a process which blinks at least one part area | region of a selection display area. Explanatory drawing which shows an example in case the assistance process by a grasp assistance part is a process which displays an animation using several progress images, when displaying an operation result image in a selection display area. Explanatory drawing which shows an example in case the assistance process by a grasp assistance part is a process which displays the animation which connects a reception display area and a selection display area visually. Explanatory drawing which shows the other example in case the assistance process by a grasp assistance part is a process which displays the animation which connects a reception display area and a selection display area visually. Explanatory drawing which shows the other example in case the assistance process by a grasp assistance part is a process which displays an animation using a some progress image, when displaying an operation result image in a selection display area. (A) is explanatory drawing which shows an example in case the assistance process by a grasp assistance part is a process which displays the layout figure of a some display area, (b) is an enlarged view of the A section of Fig.11 (a). Explanatory drawing which shows an example in case the assistance process by a grasp assistance part is a process which displays the image which shows the position of the selection display area in a some display area on the display image of a wearable display device. Explanatory drawing which shows another example in case the assistance process by a grasp assistance part is a process which displays the image which shows the position of the selection display area in a some display area on the display image of a wearable display device. Explanatory drawing which shows an example in case the assistance process by a grasp assistance part is a process which outputs the assistance sound output which shows the position of a selection display area | region from a speaker.

  Embodiments of an X-ray diagnostic apparatus and a medical image diagnostic apparatus according to the present invention will be described with reference to the accompanying drawings.

  The medical image diagnostic apparatus according to an embodiment of the present invention only needs to be configured to be able to use a display unit having a plurality of display areas. Examples of the medical image diagnostic apparatus include an X-ray diagnostic apparatus, an X-ray CT apparatus, and an MRI. Various modalities such as an apparatus, an ultrasonic diagnostic apparatus, and a nuclear medicine diagnostic apparatus can be used. In the following description, an example in which an X-ray diagnostic apparatus is used as a medical image diagnostic apparatus will be described.

  FIG. 1 is a block diagram showing an example of an X-ray diagnostic apparatus 10 according to an embodiment of the present invention.

  As shown in FIG. 1, the X-ray diagnostic apparatus 10 includes an imaging unit 11 and an image processing device 12. The imaging unit 11 of the X-ray diagnostic apparatus 10 is usually installed in an examination room and configured to generate image data related to the subject O. The image processing apparatus 12 is installed in a control room adjacent to the examination room, and is configured to generate and display an image based on the image data. Note that the image processing apparatus 12 may be installed in an examination room in which the imaging unit 11 is installed.

  The imaging unit 11 includes an X-ray detection unit 13, an X-ray source 14, a C arm 15, an injector 16, a bed 17, a top plate 18, an examination room display unit 19, an examination room input unit 21, a wearable display device 22, a speaker 23, and It has a controller 24.

  The X-ray detection unit 13 is provided at one end of the C-arm 15 so as to be opposed to the X-ray source 14 with the subject O supported by a top plate 18 (for example, a catheter table) of the bed 17 interposed therebetween. It is done. The X-ray detection unit 13 is configured by a flat panel detector (FPD), detects X-rays irradiated on the X-ray detection unit 13, and generates X-ray projection data based on the detected X-rays. Output. This projection data is given to the image processing apparatus 12 via the controller 24. Note that the X-ray detection unit 13 may include an image intensifier, a TV camera, and the like.

  The X-ray source 14 is provided at the other end of the C arm 15 and has an X-ray tube and an X-ray diaphragm. The X-ray diaphragm is an X-ray irradiation field diaphragm composed of, for example, a plurality of lead feathers. The X-ray diaphragm is controlled by the controller 24 to adjust the irradiation range of X-rays irradiated from the X-ray tube.

  The C arm 15 holds the X-ray detection unit 13 and the X-ray source 14 together. When the C arm 15 is driven by being controlled by the controller 24, the X-ray detection unit 13 and the X-ray source 14 move around the subject O as a unit.

  FIG. 2 is an external view showing an example when the X-ray diagnostic apparatus 10 includes a biplane imaging unit 11. As shown in FIG. 2, the imaging unit 11 of the X-ray diagnostic apparatus 10 is a biplane type having two X-ray irradiation systems configured by an X-ray detection unit 13, an X-ray source 14, and a C arm 15. Also good. When the biplane imaging unit 11 is provided, the X-ray diagnostic apparatus 10 performs X-rays from two directions, that is, an F (Frontal) side having a floor-mounted C arm and an L (Lateral) side having a ceiling traveling Ω arm. Biplane images (F-side image and L-side image) can be obtained by individually irradiating the beam. When the biplane imaging unit 11 is provided, since many images are always displayed, it is more difficult for the user to grasp where the operation result image is displayed.

  The injector 16 is a device that is controlled by the controller 24 and injects a contrast medium via a catheter (catheter tube, not shown) inserted into a predetermined site (affected part) of the subject O. The timing of injection and stop of the contrast agent and the concentration and injection rate of the contrast agent are automatically controlled by the controller 24. The injector 16 may be prepared as an external isolated device different from the X-ray diagnostic apparatus 10. In this case, the X-ray diagnostic apparatus 10 does not include the injector 16. In addition, the injector 16 does not need to be controlled by the controller 24 regardless of whether it is prepared externally. For example, the injector 16 receives an instruction from the user via an input unit provided in the injector 16 and responds to this instruction. The contrast agent may be injected at a different concentration, speed and timing.

  The bed 17 is installed on the floor and supports the top board 18. The couch 17 is controlled by the controller 24 to move or rotate (roll) the top plate 18 in the horizontal and vertical directions.

  The examination room display unit 19 is composed of one or a plurality of display devices and has a plurality of display areas 20. A plurality of display areas 20 may be assigned to one display device, or one display area 20 may be assigned to one display device. When one display area 20 is assigned to one display device, the examination room display unit 19 includes a plurality of display devices. As a display device constituting the examination room display unit 19, a general display output device such as a liquid crystal display or an OLED (Organic Light Emitting Diode) display can be used.

  Although FIG. 1 shows an example in which the examination room display unit 19 is suspended from a rail fixed to the ceiling, the examination room display unit 19 is placed on a table placed on the floor. It may be installed. Further, when the examination room display unit 19 includes a plurality of display devices, all the display devices do not have to be provided in one place, and may be provided in a distributed manner in the examination room.

  FIGS. 3A to 3E are explanatory diagrams illustrating first to fifth layout examples of the plurality of display areas 20. The hatching in FIG. 3 shows the bezel portion of the display device.

  As shown in FIG. 3, the layout of the plurality of display areas 20 constituting the examination room display unit 19 can be freely set. For example, the plurality of display areas 20 may be assigned to one display device (see FIG. 3A). One display area 20 may be assigned to one display device (see FIG. 3B).

  When a plurality of display areas 20 are assigned to one display device, various modes can be adopted for the size and arrangement of the display areas 20 in the display device (see FIG. 3C). At this time, the layout of the display area 20 in the display device can be changed automatically by the image processing device 12 via the controller 24 at an arbitrary timing or according to an instruction from the user.

  Further, the examination room display unit 19 may be configured by a plurality of display devices while assigning a plurality of display areas 20 to one display device (see FIG. 3D). Moreover, the examination room display unit 19 may be configured by one display device to which a plurality of display areas 20 are assigned and a plurality of display devices to which one display area 20 is assigned (FIG. 3E). reference).

  The examination room input unit 21 includes, for example, a general input device such as a keyboard, a trackball, a touch panel, and a numeric keypad, a hand switch for instructing the X-ray exposure timing, and the like. An operation input signal corresponding to the operation is output to the image processing device 12. For example, the user performs an instruction operation for creating one medical image from a plurality of medical images obtained by one imaging of the subject O and storing the medical image in the storage unit 33 via the examination room input unit 21. be able to.

  The wearable display device 22 is configured by a general wearable display device that can be mounted by a user such as a head-mounted display and can display an image superimposed on the user's field of view, and is controlled by the image processing device 12 to display various images. To do. The image displayed by being superimposed on the user's field of view by the wearable display device 22 may be a stereoscopically viewable three-dimensional image using a hologram or the like.

  The speaker 23 is controlled by the image processing apparatus 12 via the controller 24 and outputs a sound such as a beep sound or a sound to the user. In the following description, “speech” means a sound obtained by reading out text data with a sound recognized as a human voice by a listener. In addition to “sound”, “sound” includes “music”, “sound effect (beep sound, etc.)” and the like.

  The speaker 23 may be a device that is provided near each of the display areas 20 and that can output sound having directivity. In this case, the user's attention can be directed toward the display area 20 corresponding to the speaker 23 by outputting sound having directivity from the speaker 23. Further, when the wearable display device 22 includes a receiver, this receiver may be used as the speaker 23.

  The controller 24 includes a storage medium such as a CPU, RAM, and ROM. The controller 24 is controlled by the image processing device 12 in accordance with a program stored in the storage medium, and controls the X-ray irradiation system to perform fluoroscopic imaging, DA (Digital Angiography) imaging of an X-ray diagnostic image of the subject O, DSA (Digital Subtraction Angiography) imaging or the like is executed to generate image data, which is given to the image processing device 12.

  The controller 24 is controlled by the image processing device 12 to display an operation result image (an image displayed as a result of a function executed in response to a user operation) on the display area 20 of the examination room display unit 19. Then, a process for assisting the user to easily grasp the position of the area where the operation result image is displayed in the plurality of display areas 20 is executed. This support process may be a process for assisting the user to grasp the position of the region where the operation result image is displayed in the plurality of display regions 20.

  1 shows an example in which the controller 24 and the image processing apparatus 12 are connected by wire, but the controller 24 and the image processing apparatus 12 may be connected via the network 100 so as to be able to transmit and receive data. .

  The RAM of the controller 24 provides a work area for temporarily storing programs executed by the CPU and data. The storage medium such as the ROM of the controller 24 stores an activation program for the imaging unit 11, a control program for the imaging unit 11, and various data necessary for executing these programs. Note that the storage medium such as the ROM of the controller 24 includes a recording medium that can be read by the CPU, such as a magnetic or optical recording medium or a semiconductor memory, and programs and data in these storage media. A part or all of these may be downloaded via an electronic network.

  On the other hand, the image processing apparatus 12 includes a control room display unit 31, a control room input unit 32, a storage unit 33, a network connection unit 34, and a main control unit 35, as shown in FIG.

  The control room display unit 31 is configured by a general display output device such as a liquid crystal display or an OLED (Organic Light Emitting Diode) display, for example, and displays various images such as medical images under the control of the main control unit 35.

  The control room input unit 32 includes at least a pointing device, and is configured by a general input device such as a mouse, a trackball, a keyboard, a touch panel, and a numeric keypad. For example, an operation input signal corresponding to a user operation is sent to the main control unit 35. Output. For example, a user who operates the image processing apparatus 12 in the control room performs an instruction operation for creating one medical image from a plurality of medical images obtained by one imaging of the subject O and storing the medical image in the storage unit 33. This can be done via the control room input unit 32.

  A voice input microphone may be used as the control room input unit 32 and the examination room input unit 21. In this case, the microphone converts the voice input by the user into a digital voice signal, and the main control unit 35 performs an operation corresponding to the voice input by the user by performing voice recognition processing on the digital voice signal.

  The storage unit 33 stores medical image data (including volume data (medical three-dimensional image data)) and reconstructed image data output from the imaging unit 11. A plurality of logical drives (virtual storage areas (drives)) in the storage unit 33 may be set. The logical drive may include a storage area in which storage areas of a plurality of storage devices (physical disks) are bundled. For example, when a plurality of storage devices are used as one disk array, this disk array becomes one logical drive. At this time, RAID (Redundant Arrays of Inexpensive Disks) may be constructed for the array. Further, when one disk array is further divided arbitrarily, there are a plurality of logical drives. Different RAID (Redundant Arrays of Inexpensive Disks) levels may be constructed in the same array.

  The network connection unit 34 implements various information communication protocols according to the form of the network 100. The network connection unit 34 connects the X-ray diagnostic apparatus 10 and other electrical devices according to these various protocols. Here, the network 100 means an entire information communication network using telecommunications technology. In addition to a wireless / wired LAN such as a hospital basic LAN (Local Area Network) and an Internet network, a telephone communication line network, an optical fiber communication network. Cable communication networks and satellite communication networks.

  The X-ray diagnostic apparatus 10 may receive medical image data from the modality 101 or the image server 102 connected via the network 100. Volume data received via the network 100 is also stored in the storage unit 33. The medical images received from these modalities 101 and the image server 102 are displayed on one or a plurality of display areas 20 of the examination room display unit 19 and the control room display unit 31.

  The image server 102 is a server for long-term storage of images provided in, for example, a PACS (Picture Archiving and Communication System), and is an X-ray CT apparatus, an MRI apparatus, and an X-ray apparatus connected via the network 100. Reconstructed images, volume data, and the like generated by the modality 101 such as a line diagnostic apparatus, nuclear medicine diagnostic apparatus, and ultrasonic diagnostic apparatus are stored.

  The main control unit 35 is composed of a storage medium such as a CPU, RAM, and ROM, and controls the operation of the X-ray diagnostic apparatus 10 according to a program stored in the storage medium.

  The CPU of the main control unit 35 loads a display position grasp support program stored in a storage medium such as a ROM and data necessary for executing the program into the RAM, and a plurality of display areas 20 according to the program. A process for assisting the user to easily grasp the position of the area where the operation result image is displayed is executed. This support process may be a process for assisting the user in grasping the position of the area where the operation result image is displayed in the plurality of display areas 20, for example, an examination room display unit via the controller 24. 19, image display control of the wearable display device 22 via the network 100, and sound output control using the speaker 23 via the controller 24, or a combination thereof.

  The RAM of the main control unit 35 provides a work area for temporarily storing programs and data executed by the CPU. The storage medium such as the ROM of the main control unit 35 stores a startup program for the X-ray diagnostic apparatus 10, a display position grasp support program, and various data necessary for executing these programs. A storage medium such as a ROM has a configuration including a recording medium readable by a CPU, such as a magnetic or optical recording medium or a semiconductor memory, and a part of programs and data in the storage medium. Or you may comprise so that all may be downloaded via an electronic network.

  FIG. 4 is a schematic block diagram illustrating a configuration example of the function realization unit by the CPU of the main control unit 35. Note that these function implementation units may be realized by cooperation of a plurality of processors, or may be realized by hardware logic such as a circuit without using a CPU.

  As shown in FIG. 4, the CPU of the main control unit 35 performs at least an operation reception unit 41, a reception function execution unit 42, an image acquisition unit 43, a display area selection unit 44, and a grasp support unit 45 by a display position grasp support program. Function. Each unit 41-45 uses a required work area in the RAM as a temporary storage location for data.

  The operation receiving unit 41 receives a user instruction operation via the examination room input unit 21 and the control room input unit 32.

  The reception function execution unit 42 executes a function according to the operation received by the operation reception unit 41, and gives an image (operation result image) according to the function execution result to the image acquisition unit 43.

  The function executed by the reception function execution unit 42 according to the present embodiment may be a function that is executed in accordance with the user's instruction operation and has an image displayed on the execution result of the function.

  As a function executed by the reception function execution unit 42 according to the present embodiment, for example, a map save function is cited. The map saving function creates one MAP image (a user-desired one-frame medical image) from a Run image (a group of medical images consisting of a plurality of frames collected by one imaging), and stores the MAP image in a storage unit This is a function to be stored in 33. In many cases, the map saving function is accompanied by a function of storing the MAP image in the storage unit 33 and displaying the MAP image in any of the plurality of display areas 20. The MAP image display function attached to the map saving function can be set not to be executed by the user.

  When the map save function is accompanied by the MAP image display function, when the user receives information from the operation accepting unit 41 that the map save function is used and the map image is created from the Run image, the accept function executing unit 42 stores the created MAP image in the storage unit 33 and gives the image acquisition unit 43 information on the MAP image (operation result image) created to be displayed in any of the display areas 20.

  Moreover, as a function performed by the reception function execution part 42 which concerns on this embodiment, the image transfer function from a control room to an examination room is mentioned, for example. This type of image transfer function is useful when a user in the control room and a user in the examination room work together. For example, when performing endovascular treatment, a user who inserts a device into a blood vessel with respect to the subject O in the examination room can receive work support from the user in the control room by providing an image using the image transfer function. . When the operation reception unit 41 receives an instruction to display a predetermined image (operation result image) on the examination room display unit 19 from the control room user via the control room input unit 32, the reception function execution unit 42 displays Information on the predetermined image is given to the image acquisition unit 43 to be displayed in any of the areas 20. The predetermined image may be a medical image stored in the storage unit 33 or an image indicating data related to the medical image.

  In addition, other functions executed by the reception function execution unit 42 according to the present embodiment include, for example, an auto map function. The auto-map function is a function for extracting a medical image captured under the same X-ray irradiation condition as the X-ray irradiation condition including the current X-ray irradiation angle and displaying the medical image on the examination room display unit 19. . According to the auto map function, the user can easily confirm an image captured in the past at the current angle of the C-arm 15. When receiving information from the operation accepting unit 41 indicating that an instruction operation for requesting use of the auto map function has been accepted from the user, the accepting function executing unit 42 includes the current X-ray irradiation angle from the imaging unit 11 via the controller 24. Information on X-ray irradiation conditions is acquired. Then, the reception function execution unit 42 extracts a medical image (operation result image) imaged under the same X-ray irradiation condition as the current X-ray irradiation condition from the storage unit 33 and displays the medical image in one of the display areas 20. Information about the extracted medical image is given to the image acquisition unit 43 as much as possible.

  The image acquisition unit 43 receives information on the operation result image from the reception function execution unit 42 and acquires the operation result image from the reception function execution unit 42 or from the storage unit 33.

  The display area selection unit 44 selects an area for displaying an operation result image (hereinafter, referred to as a selection display area 50) from the plurality of display areas 20 included in the examination room display unit 19. At this time, it is preferable to avoid the display area 20 displaying a fluoroscopic image, for example, during fluoroscopic imaging. Therefore, a priority is given to the importance level of the currently displayed image, and the display area 20 in which the low priority image is displayed or the display area 20 in which nothing is displayed is selected and displayed in the selection display area 50. It may be selected as (region to display the operation result image). Further, when a rule is set for the image arrangement of the plurality of display areas 20 by the method described in Patent Document 1, the selection display area 50 may be determined according to this rule.

  The grasping support unit 45 executes processing for assisting the user to easily grasp the positions of the selection display areas 50 in the plurality of display areas 20 and displays the operation result image in the selection display area 50.

  This support process may be a process for assisting the user in grasping the position of the selection display area 50 where the operation result images are displayed in the plurality of display areas 20, and at least image display and sound output. On the other hand, the position of the selection display area 50 may be notified to the user. Therefore, the support processing includes, for example, image display control using the laboratory display unit 19 via the controller 24, image display control of the wearable display device 22 via the network 100, and sound using the speaker 23 via the controller 24. It is executed by any one of output control or a combination thereof.

  Next, an example of the operation of the X-ray diagnostic apparatus 10 and the medical image diagnostic apparatus according to the present embodiment will be described.

  5 assists the user in easily grasping the position of the selection display area 50 where the operation result images are displayed in the plurality of display areas 20 by the CPU of the main control unit 35 shown in FIG. It is a flowchart which shows an example of the procedure in the case. In FIG. 5, reference numerals with numbers added to S indicate steps in the flowchart.

  First, in step S <b> 1, the operation reception unit 41 receives a user instruction operation via the examination room input unit 21 or the control room input unit 32.

  Next, in step S <b> 2, the reception function execution unit 42 executes a function according to the operation received by the operation reception unit 41, and gives an image (operation result image) according to the function execution result to the image acquisition unit 43. . Note that when the function execution result is not accompanied by an image display, the series of procedures ends.

  Next, in step S <b> 3, the image acquisition unit 43 receives the operation result image information from the reception function execution unit 42, and acquires the operation result image from the reception function execution unit 42 or from the storage unit 33.

  Next, in step S <b> 4, the display area selection unit 44 selects the selection display area 50 for displaying the operation result image from the plurality of display areas 20 included in the examination room display unit 19.

  Next, in step S <b> 5, the grasping support unit 45 executes processing for assisting the user to easily grasp the position of the selection display area 50 in the plurality of display areas 20, and selectively displays the operation result image. It is displayed in the area 50.

  With the above procedure, it is possible to assist the user in easily grasping the position of the selection display area 50 where the operation result image is displayed in the plurality of display areas 20.

  Next, the support process by the grasp support unit 45 will be described in detail.

  The support process by the grasp support unit 45 may be a process for assisting the user to grasp the position of the selection display area 50 where the operation result image is displayed in the plurality of display areas 20. The position of the selection display area 50 may be notified to the user by at least one of the sound outputs. The grasp support unit 45 according to the present embodiment controls the display of the support image display 60 using the laboratory display unit 19 via the controller 24, for example, and the support image on the display image of the wearable display device 22 via the network 100. Support processing is executed by either display control of the display 60, output control of the support sound output 70 using the speaker 23 via the controller 24, or a combination thereof. This will be specifically described below.

  FIG. 6 is an explanatory diagram illustrating an example in which the support process by the grasp support unit 45 is a process of blinking at least a part of the selection display area 50. FIG. 6 shows an example in which the outer frame of the selection display area 50 is blinked and displayed as the support image display 60.

  As shown in FIG. 6, the user's line of sight can be attracted to the selection display area 50 by blinking at least a part of the selection display area 50 where the operation result image 51 is displayed. For this reason, the user can easily grasp the position of the selected display area 50 in the plurality of display areas 20.

  FIG. 7 is an explanatory diagram illustrating an example in which the support process by the grasp support unit 45 is a process of displaying an animation using a plurality of progress images when the operation result image 51 is displayed in the selection display area 50. FIG. 7 shows an example in which the process of enlarging the operation result image 51 as the support image display 60 is displayed as an animation using a plurality of progress images.

  When displaying the operation result image 51 in the selection display area 50, the process of enlarging the operation result image 51 can be animated using a plurality of progress images to attract the user's line of sight to the selection display area 50. . Moreover, you may combine this animation display and the blink display shown in FIG.

  Among the functions executed by the reception function execution unit 42, when the map save function is used, the user first receives an instruction operation related to the creation of the MAP image in the area where the Run image 52 is displayed. An operation for creating a MAP image from the Run image 52 is performed by paying attention to a region for the purpose (hereinafter referred to as a reception display region 53). At this time, if the selection display area 50 where the MAP image is displayed is away from the reception display area 53, it is difficult for the user to grasp where the MAP image is displayed. In this case, it is preferable to present information associating the reception display area 53 with the selection display area 50 as the support image display 60.

  FIG. 8 is an explanatory diagram illustrating an example in which the support process by the grasp support unit 45 is a process of displaying an animation that visually connects the reception display area 53 and the selection display area 50. FIG. 8 shows an example in which a movement animation simulating the operation result image 51 moving from the reception display area 53 to the selection display area 50 is displayed as the support image display 60.

  By displaying the moving animation of the operation result image 51, the user can easily grasp the position of the selection display area 50 where the MAP image is displayed.

  FIG. 9 is an explanatory diagram illustrating another example in which the support process by the grasp support unit 45 is a process of displaying an animation that visually connects the reception display area 53 and the selection display area 50. FIG. 9 shows an example in which the operation result image 51 is moved from the reception display area 53 to the selection display area 50 as the support image display 60 by a so-called slide-in / slide-out movement animation. Also, the slide-in / slide-out movement animation may be displayed in the display area 20 existing between the reception display area 53 and the selection display area 50).

  As shown in FIG. 9, the user can easily grasp the position of the selection display area 50 also by the animation display of slide-in and slide-out. The moving animation display shown in FIGS. 8 and 9 can be combined with either or both of the blinking display shown in FIG. 6 and the enlarged animation shown in FIG. In addition, the operation result image 51 itself may not be used for the movement animation shown in FIGS. 8 and 9, and a symbolic image (such as a rectangular frame, an arrow image, or a point trajectory) may be used.

  FIG. 10 is an explanatory diagram showing another example of the case where the support process by the grasp support unit 45 is a process of displaying an animation using a plurality of progress images when displaying the operation result image 51 in the selection display area 50. is there. In FIG. 10, when an image 54 that has been displayed in advance in the selection display area 50 as the support image display 60 is flipped and switched to the operation result image 51 using a plurality of progress images (animated animation display). An example of was shown.

  The user's line of sight can be attracted to the selection display area 50 also by the flip animation display. Further, the turning animation display may be combined with any or all of the blinking display shown in FIG. 6, the enlarged animation shown in FIG. 7, and the moving animation shown in FIGS. Specifically, the moving animation may be displayed first, the turning animation may be performed when the operation result image 51 reaches the selection display area 50 in the moving animation, and the enlarged animation may be repeated when the turning animation ends. At this time, the peripheral area of the selection display area 50 may be kept blinking.

  FIG. 11A is an explanatory diagram illustrating an example of the case where the support process by the grasp support unit 45 is a process of displaying a layout diagram of a plurality of display areas 20, and FIG. It is an enlarged view of the A section. FIG. 11 shows an example in which a layout diagram highlighting the positions of the selection display areas 50 in the plurality of display areas 20 is displayed in a partial area of the reception display area 53 as the support image display 60.

  In the example shown in FIG. 11, when an instruction operation related to creation of the operation result image 51 is received in the reception display area 53, the positions of the selection display areas 50 in the plurality of display areas 20 are highlighted in a partial area of the reception display area 53. Display the displayed layout diagram. As this partial area, for example, a partial area in an area where a menu image is displayed can be used.

  In addition, even when there is no reception display area 53 such as when the auto map function is executed or when the image transfer function from the control room is executed, a layout diagram highlighting the positions of the selection display areas 50 in the plurality of display areas 20 is displayed. Good. In this case, the layout diagram may be displayed on the display area 20 (for example, an area for displaying a menu image, an image showing status information, or the like) with a high frequency and time for the user to send a line of sight.

  By displaying the layout diagram in which the positions of the selection display areas 50 in the plurality of display areas 20 are highlighted, the user can easily grasp the positions of the selection display areas 50. The layout diagram display may be combined with any or all of the blinking display shown in FIG. 6, the enlarged animation shown in FIG. 7, the moving animation shown in FIGS. 8 and 9, and the turning animation shown in FIG. Good.

  FIG. 12 is an explanatory diagram illustrating an example in which the support process by the grasp support unit 45 is a process of displaying an image indicating the position of the selected display area 50 in the plurality of display areas 20 on the display image of the wearable display device 22. It is. FIG. 12 shows an example in which blinking display is performed at a position corresponding to the position of the selection display area 50 on the display image of the wearable display device 22 as the support image display 60.

  Note that the alignment of the selection display area 50 on the display image of the wearable display device 22 can be performed using an image acquired by a camera (not shown) provided in the wearable display device 22. Specifically, for example, a real space and a virtual space are aligned by detecting a marker (not shown) provided in advance in the laboratory display unit 19 using a camera (not shown) provided in the wearable display device 22. Can do. Alternatively, the image of the examination room display unit 19 may be stored in advance, and the real space and the virtual space may be aligned by detecting the position of the examination room display unit 19 from the camera image by pattern matching.

  By performing blinking display at a position corresponding to the position of the selection display area 50 on the display image of the wearable display device 22 worn by the user, the user can easily grasp the position of the selection display area 50.

  FIG. 13 shows another example in which the support process by the grasp support unit 45 is a process for displaying an image indicating the position of the selected display area 50 in the plurality of display areas 20 on the display image of the wearable display device 22. It is explanatory drawing. FIG. 13 shows an example in which an arrow image indicating the positional relationship between the reception display area 53 and the selection display area 50 is displayed on the display image of the wearable display device 22 as the support image display 60.

  Further, an arrow for emphasizing the position of the selection display area 50 may be displayed even when there is no reception display area 53 such as when the auto map function is executed or when the image transfer function from the control room is executed.

  By displaying an arrow image indicating the position of the selection display area 50 on the display image of the wearable display device 22 worn by the user, the user can easily grasp the position of the selection display area 50.

  Also, the examples shown in FIGS. 12 and 13 can be combined with the support image display 60 shown in FIGS. Further, the support image display 60 shown in FIGS. 6 to 11 may be performed on the display image of the wearable display device 22.

  FIG. 14 is an explanatory diagram illustrating an example of the case where the support process by the grasp support unit 45 is a process of outputting the support sound output 70 indicating the position of the selection display area 50 from the speaker 23. In FIG. 14, when the speaker 23 is a device that is provided near each of the display areas 20 and can output sound having directivity, the speaker 23 outputs sound having directivity to thereby output the speaker 23. An example in which the user's attention is directed to the direction of the display area 20 corresponding to is shown.

  The assistance sound output 70 may be a beep sound, for example. By associating the beep sound generation type (sound generation time, scale, frequency, etc.) with the position of the display area 20 in advance, the user can perceive the position of the selection display area 50 according to the beep sound generation type. . The support sound output 70 may be a sound for guiding the position of the selection display area 50.

  By outputting the assist sound output 70 indicating the position of the selection display area 50 from the speaker 23, the user can easily grasp the position of the selection display area 50. Further, the support sound output 70 may be combined with the support image display 60 (see, for example, FIG. 6-13).

  In the medical image diagnostic apparatus such as the X-ray diagnostic apparatus 10 according to the present embodiment, the user grasps the position of the selection display area 50 in the plurality of display areas 20 by at least one of the support image display 60 and the support sound output 70. Can help you. For this reason, when the user gives an instruction to execute the function, the user can easily grasp the position of the selection display area 50 where the operation result image 51 is displayed without stress. Therefore, according to the medical image diagnostic apparatus such as the X-ray diagnostic apparatus 10, the examination time of the subject O can be shortened, the burden on the user can be reduced, and the user's procedure efficiency can be improved.

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

  For example, the support process may be any process that can assist the user in grasping the position of the selection display region 50, and the modes of the support image display 60 and the support sound output 70 are the same as those shown in FIGS. It is not limited to examples.

  In the above example, an example of supporting the grasp of the position of the selection display area 50 where the operation result image 51 displayed in response to the most recent instruction operation is shown has been described. In each of the selected display areas 50, the speed of blinking and the brightness, the speed of animation, the density of colors, the color, and the like may be varied to support position grasping simultaneously. The support process may be stopped after a predetermined time has elapsed or when a confirmation operation by the user is received.

DESCRIPTION OF SYMBOLS 10 X-ray diagnostic apparatus 19 Display part 20 Display area 21 Examination room input part 22 Wearable display device 23 Speaker 32 Control room input part 33 Storage part 41 Operation reception part 42 Reception function execution part 43 Image acquisition part 44 Display area selection part 45 Grasp Support unit 50 Selection display area 53 Reception display area 60 Support image display 70 Support sound output

Claims (14)

An operation accepting unit for accepting a user instruction operation via the input unit;
An image acquisition unit that acquires an image according to the operation;
A display region selection unit that selects a selection display region that is a display region for displaying an image according to the operation acquired by the image acquisition unit from among a plurality of display regions of the display unit;
A grasp support unit that executes a support process for the user to grasp the position of the selection display area in the plurality of display areas and displays an image corresponding to the operation in the selection display area;
An X-ray diagnostic apparatus comprising: A reception function execution unit that executes a function according to the operation received by the operation reception unit and gives an image according to a function execution result to the image acquisition unit as an image according to the operation;
The X-ray diagnostic apparatus according to claim 1, further comprising: The reception function execution unit
As a function according to the operation, one medical image is created from a plurality of medical images obtained by one imaging of the subject and stored in the storage unit, and the created medical image is stored in the image acquisition unit. Give to the
The X-ray diagnostic apparatus according to claim 2. The grasp support unit
As the support process, an acceptance display area that is a display area for accepting an instruction operation related to creation of one medical image from the plurality of medical images, and the selection display area that displays the created medical image; To display an animation that visually connects
The X-ray diagnostic apparatus according to claim 3. The reception function execution unit
As a function according to the operation, the medical image stored in the storage unit is extracted and given to the image acquisition unit.
The X-ray diagnostic apparatus according to any one of claims 2 to 4. The reception function execution unit
As a function corresponding to the operation, a current X-ray irradiation condition including a current X-ray irradiation angle is acquired, and a medical image captured under the same X-ray irradiation condition as the current X-ray irradiation condition is stored in the storage unit To extract and give to the image acquisition unit,
The X-ray diagnostic apparatus according to claim 5. The grasp support unit
Flashing at least a part of the selection display area as the support process;
The X-ray diagnostic apparatus according to any one of claims 1 to 6. The grasp support unit
As the support process, when displaying an image according to the operation in the selection display area, an animation is displayed using a plurality of progress images.
The X-ray diagnostic apparatus according to any one of claims 1 to 7. The grasp support unit
As the support process, an image indicating the position of the selection display area in the plurality of display areas is displayed on a display image of a wearable display terminal worn by a user.
The X-ray diagnostic apparatus according to any one of claims 1 to 8. The grasp support unit
As the support process, a layout diagram showing the position of the selected display area in the plurality of display areas is displayed in a partial area of the display unit.
The X-ray diagnostic apparatus according to any one of claims 1 to 9. The grasp support unit
As the support process, a sound indicating the position of the selected display area in the plurality of display areas is output from a speaker.
The X-ray diagnostic apparatus according to any one of claims 1 to 10. The speaker,
Further comprising
The speaker is
The display unit is configured to output sound having directivity,
The grasp support unit
As the support process, the user perceives the position of the selected display area in the plurality of display areas by outputting a sound having the directivity from the speaker.
The X-ray diagnostic apparatus according to claim 11. A display unit having the plurality of display areas;
The X-ray diagnostic apparatus according to any one of claims 1 to 12, further comprising: An operation accepting unit for accepting a user instruction operation via the input unit;
An image acquisition unit that acquires an image according to the operation;
A display region selection unit that selects a selection display region that is a display region for displaying an image according to the operation acquired by the image acquisition unit from among a plurality of display regions of the display unit;
A grasp support unit that executes a support process for the user to grasp the position of the selection display area in the plurality of display areas and displays an image corresponding to the operation in the selection display area;
A medical image diagnostic apparatus comprising:

Images