An X-ray imaging apparatus includes an imaging device configured to capture a camera image of a target; a controller configured to stitch a plurality of X-ray images of respective divided regions of the target to generate one X-ray image of the target; and a display configured to display a settings window that provides a GUI for receiving a setting of an X-ray irradiation condition for the respective divided regions and the camera image in which positions of the respective divided regions are displayed.

The present invention provides a mobile imaging system for imaging of patients in medical interventions comprising a ring gantry with a plurality of independently rotating rings whereas a first rotating ring positions an X-ray source with collimator and a second rotating ring positions an image detector such that the region of interest (patient) can be positioned off-centered with respect to the ring center. The system supports planar X-ray imaging and Computed Tomography (CT) and Cone beam CT (CBCT) acquisitions of three dimensional (3D) volumes with variable X-ray field of views (FOVs) adapted to regions of interest (ROIs), which are not required to be of cylindrical shape. The mobile system can be equipped with stereoscopic cameras integrated in the gantry an on moving rings to support optical tracking and navigation of instruments within the same co-ordinate system of X-ray information. The gantry can be equipped with additional sensors and robotic manipulators on further rings operating in said co-ordinate system on mobile platform. The gantry provides a generic mechanical and electrical interface to a supporting structure, which can be attached to a variety of mobility platforms to support robotic positioning of the system in various orientations of scanner in treatment rooms to accommodate a wide range of patient setups, including the possibility for inclined and vertical scans of patients in upright position.

This X-ray imaging apparatus is provided with an image controller for generating a composite image by superimposing a plurality of X-ray images. The image controller includes a detection processing unit configured to detect both a marker for indicating a position of a predetermined target object to be indwelled in a body of a subject and a device to be placed in the body of the subject separately from the predetermined target object, in the generated X-ray image. The image controller includes a composition processing unit configured to generate the composite image by superimposing the plurality of X-ray images based on the detected marker and the detected device.

There is disclosed an image processing apparatus including a hardware processor which generates a highly resolved still image from a plurality of frame images obtained by continuously imaging a moving subject. The hardware processor analyzes each of the plurality of frame images to calculate a feature amount, and determines, on a basis of the calculated feature amount, a reference frame image which becomes a reference when generating the highly resolved still image from the plurality of frame images.

The present invention relates to guiding an interventional device. In order to provide improved guidance when navigating by the aid of roadmapping, an apparatus (10) for guidance of an interventional device is provided. The apparatus comprises an input unit (12); a data storage unit (14), a data processing unit (16) and an output unit (18). The data storage unit is configured to provide a vasculature map of a region of interest with a vasculature presentation of a subject's vasculature structure. The input unit is configured to receive and transfer to the data processing unit at least one current image of the region of interest, wherein an interventional device is at least partly visible in the at least one current image when inserted within the vasculature structure in the region of interest. The data processing unit is configured to combine the vasculature map and the at least one current image, and to detect a location of at least one part of the interventional device in the vasculature map, and to detect if the at least one part of the interventional device lays outside the vasculature presentation shown in the vasculature map and to determine a branching-off location for the interventional device on the vasculature map, and also to adapt the vasculature map in the branching-off location providing an indication of the branching-off location. The output unit is configured to provide an adapted vasculature map.

A medical image diagnosis apparatus according to an embodiment includes an ultraviolet light source, processing circuitry, and an imaging equipment. The ultraviolet light source emits an ultraviolet ray. The processing circuitry controls irradiation of the ultraviolet ray to an irradiation object irradiated with the ultraviolet ray in an examination room by moving a position of the ultraviolet light source relatively with respect to the irradiation object. The imaging equipment acquires a medical image of a subject.

The present disclosure relates to a system and method for digital radiography. The system may include an X-ray generation module, an X-ray acquisition module, a control module, a support module and a power supply module. The system may include one or more moving components. The X-ray acquisition module may have different configurations, such as a vertical configuration, a horizontal configuration and a free-style configuration. The control module may be configured for controlling the motion of the moving components, the selection of an X-ray acquisition module of a specific configuration, and parameters of the X-ray exposure and image acquisition. The support module may include a system of guiding rails. The power supply module may include a supercapacitor.

One or more example embodiments relates to a method for controlling a motion of a component of a medical installation, comprising capturing a first position parameter via a first position sensor, the first position sensor being on the component; capturing a second position parameter via a second position sensor, the second position sensor being on the component; determining, by a control unit, a position spacing for the position sensors based on the first position parameter and the second position parameter; and generating a control signal for a drive unit of the component based on the determined position spacing.

The present invention relates to positioning a medical imaging system in relation to an object. In order to provide improved positioning possibilities which facilitate the workflow during an intervention, a medical imaging apparatus (10) is provided with an image acquisition arrangement (12), which is positionable in relation to an object (16) to acquire image data (18) of the object from different directions. An output unit (14) is arranged to provide the image data. According to the invention, first movement direction indicators (22) are provided to indicate possible movement directions of the image acquisition arrangement in relation to the object. Further, a display apparatus (24), comprising a display area (26) to display image data (30) of an object provided by an image acquisition arrangement and a movement direction indication (28), may be provided, wherein the movement direction indication is configured to provide second movement direction indicators (32) in relation to the displayed image data of the object to indicate possible movement directions of the image acquisition arrangement in relation to the object. The first movement direction indicators and the second movement direction indicators are equivalent.

Embodiments generally relate to routing a bundle of loose cables with a cable chain during a medical procedure. The cable chain comprises split tubing and a plurality of links extending discretely along a length of the split tubing. Each link comprises a housing including an outer surface and an inner surface. The outer surface comprises a magnet and the inner surface forms a recess in the link. The split tubing is disposed within the recesses of the links.