Disclosed herein is a method of acquiring a medical image of an X-ray apparatus, including: acquiring an original radiation image of a target object and capturing condition information of the object; acquiring a scatter radiation image related to the original radiation image by inputting the original radiation image and the capturing condition information to a learning network model configured to estimate scatter radiation; and acquiring a scatter radiation-processed medical image from the original radiation image on the basis of the original radiation image and the scatter radiation image, wherein the learning network model configured to estimate scatter radiation is a learning network model taught using a plurality of scatter radiation images and a plurality of pieces of capturing condition information related to each of the plurality of scatter radiation images.

A shroud for an extended reality (XR) headset may include an opacity filter including a first region having a first light transmissivity, and a second region having a second light transmissivity different from the first light transmissivity. The shroud may also include a connection mechanism for removably connecting the opacity filter to the XR headset to position at least a portion of the opacity filter in a user's field of view when viewing a real-world scene while the XR headset is worn by the user.

The present disclosure relates to a medical system. The medical system may determine a working phase of the medical system. The working phase of the medical system may include a positioning phase, a scanning phase, and/or a scanning completion phase. The medical system may determine a position of a target portion of an object in the medical system based on one or more images associated with the object captured by an imaging sensor. The medical system may further control an operation of a positioning lamp of the medical system based on the working phase of the medical system and the position of the target portion of the object in the medical system.

Disclosed herein are radiotherapy systems and methods that can display a workflow-oriented graphical user interface(s). In an embodiment, a system comprises a radiotherapy machine comprising: a gantry having a screen in communication with a server, the screen configured to display a graphical user interface; and at least one camera, wherein the server is configured to present, in real time, images received from the at least one camera for display on a graphical user interface displayed on the screen.

A mobile orthodontic treatment system includes comprising a mobile trailer and a panoramic machine provided within the trailer. The panoramic machine is configured to obtain a 2-D image of a patient's mouth and includes a base secured to the floor of the housing and a stanchion secured to the trailer by a bracket. The mobile orthodontic treatment system further includes a digital scanner and a monitor provided within the housing. The digital scanner is configured to obtain a 3-D image of the patient's mouth and display the image on the monitor. The digital scanner and the monitor are mounted on a wall of the housing by a wall mount articulating bracket. The mobile orthodontic treatment system further includes a lift assembly provided on one of a side and an end of the housing to enable disabled people to enter and exit the housing.

A cabinet X-ray image system for obtaining X-ray images and colorized or grey scale density X-ray images of a specimen includes a sampling chamber for containing the specimen, a display, an X-ray system including, an X-ray source, a photon counting X-ray detector, and a specimen platform, and a controller configured to selectively energize the X-ray source, control the photon counting X-ray detector to collect a projection X-ray image of the specimen when the X-ray source is energized, determine the density of different areas of the specimen from data collected from the photon counting X-ray detector of the projection X-ray image, create a density X-ray image of the specimen wherein different areas of the specimen are indicated as a density or range of densities based on the determined density of different areas of the specimen, and selectively display the density X-ray image of the specimen on the display.

An X-ray device includes a camera to image an object and output the image of the object, a display member using a touch screen to display the image of the object output from the camera, and an X-ray irradiation region of the object, an X-ray irradiation region controller to control a region of the object to which an X-ray is irradiated, and a control member to enable the irradiation region controller to control the region of the object to which an X-ray is irradiated according to the X-ray irradiation region, when the X-ray irradiation region is determined, based on the image of the object displayed in the display member.

The invention relates to an arrangement in connection with a mammography apparatus, in the invention, a screen or a user interface with a screen is attached to the mammography apparatus, which attachment is realized such that the screen or the user interface with a screen is aligned or can be aligned at least partly towards a lower tray structure of the mammography apparatus. Such screen or a user interface with a screen can be arranged in a functional connection with an information system and patient images recorded earlier in the information system can be displayed on the screen or the user interface with a screen.

A transparent radiation shield, attachable to a patient support platform, and movable to shield a physician from imaging radiation, includes a transparent computer display that is controllable to provide a data overlay on the shield pertaining to patient data and/or x-ray images.

A method is for controlling operation of a medical technology device using a wireless, hand-held, mobile operator device including a touchscreen. The wireless, hand-held, mobile operator device including a touchscreen is also disclosed. The method includes using the mobile operator device for implementing a medical technology workflow including acquiring patient data of the at least one patient from an acquisition user interface; selecting, via a selection user interface, a medical technology protocol containing operating parameters to be carried out for the at least one patient; setting remote-controllably adjustable components of the medical technology device, according to the at least one patient positioned in the medical technology device and according to the medical technology protocol, using a settings user interface; and activating, with the at least one patient positioned and components set, the medical technology procedure in an activation user interface.