Apparatuses (devices, systems) and methods for shielding (protecting) surroundings around periphery of regions of interest located inside objects (e.g., patients) from radiation emitted by X-ray systems towards the objects. Apparatus includes: at least one radiation shield assembly including a support base connectable to an X-ray system radiation source or detector, and a plurality of radiation shield segments sequentially positioned relative to the support base, thereby forming a contiguous radiopaque screen configured for spanning around the region of interest periphery with a radiopaque screen edge opposing the object. Radiation shield segments are individually, actively controllable to extend or contract to selected lengths with respective free ends in directions away from or towards the support base(s), for locally changing contour of the radiopaque screen edge. Applicable for shielding (protecting) medical personnel, and patients, from exposure to X-ray radiation during medical interventions or/and diagnostics.

The present disclosure provides systems and methods for automated scan preparation and real-time monitoring/adjustment in medical imaging. The automated scan preparation may include positioning a target subject to be scanned by a medical imaging device, determining a rotation scheme of the medical imaging device, targeting a scan region of the target subject with an imaging isocenter of the medical imaging device, determining target position(s) of component(s) of the medical imaging device, performing a virtual scan, generating a reference subject model representing an internal structure of the target subject, or the like. The real-time monitoring/adjustment operations may include achieving automatic brightness stabilization, monitoring a posture of the target subject, adjusting the position of component(s) of the medical imaging device, estimating a dose distribution, monitoring a treatment of the target subject, performing a motion correction, or the like.

An apparatus for Digital Imaging in the Head Region of a Patient includes an X-ray source and an X-ray sensor, supported on i a rotary arm supported on a structure by a motor driven translation and rotation means. The rotary arm is provided with adjustment means for varying the distance between the source and the sensor. The apparatus comprises a single sensor for both panoramic imaging and computed tomography, and has a control unit, that controls the source, the sensor, the adjustment means, and the translation and rotation means and operates the apparatus in a basic operation mode for bigger patients and in an alternative operation mode for smaller patients, in which the distance between the source and the sensor is reduced as compared to the distance used for the basic operation mode.

A mobile radiographic imaging system includes a mobile radiographic imaging apparatus and a radiographic imaging cassette. The radiographic imaging apparatus includes a displacement mechanism that electrically displaces a radiation emission unit and a displacement mechanism controller that controls the operation of the displacement mechanism. The radiographic imaging cassette includes a remote operation unit that is provided in a housing to remotely operate the displacement mechanism and an operation instruction transmission unit that transmits an operation instruction for operating the displacement mechanism to the displacement mechanism controller in a case where the remote operation unit is operated.

A radiographing apparatus includes a radiation detection panel including an effective image-acquisition area configured to detect radiation and a casing configured to house the radiation detection panel. The casing includes an incidence surface on which the radiation is incident, a back surface opposite the incidence surface, and a side surface between the incidence surface and the back surface. On the side surface of the casing, a level-difference portion indicating a position based on the effective image-acquisition area and a protrusion protruding more outward than the level-difference portion are provided.

The present invention relates to providing guiding information for operating an X-ray imaging system. In order to provide an improved positioning distance control facilitating the work flow, an X-ray imaging system (10) is provided, comprising a moveable X-ray source (12) and/or a moveable X-ray detector (14). The system further comprises a plurality of object-surface detecting sensors (16), a positioning detection arrangement (18), a processing unit (20), and a display unit (22). The sensors are arranged such to detect object data of objects located between the X-ray source and the X-ray detector. The positioning detection arrangement is provided to detect the current position of the X-ray source and/or the X-ray detector and the position of the sensors. The processing unit is configured to compute a situation-map (26) of the current spatial situation between the X-ray source and the X-ray detector based on the object data provided by the sensors and the current position, the situation-map distinguishing at least between empty spaces and spaces occupied by rigid objects. The situation-map comprises a representation (25) of the X-ray source and the X-ray detector in relation to the spatial situation. Further, the display unit is configured to display the situation-map to a user operating the X-ray imaging system.

A medical examination, treatment, or examination and treatment device is provided. The medical examination, treatment, or examination and treatment device includes a cover panel. The cover panel includes a sensor for detecting a collision. The sensor includes a first plate mounted on the examination, treatment, or examination and treatment device, and a second plate mounted on the inside of the cover panel and spaced apart from the first plate. Spring elements are disposed between the first plate and the second plate.

A radiological imaging system including a bed extending along a main direction, and a load-bearing structure supporting the bed in a raised position. The system includes a collapsible gantry having a circular trajectory of expansion lying on a positioning plane, and the collapsible gantry includes a source to emit radiation and a detector to receive the radiation. The gantry also includes a casing housing the source and the detector. The casing includes a fixed arched module and a mobile arched module. There is a rotation mechanism suitable to rotate the collapsible gantry in relation to the bed and the load-bearing structure to vary the inclination of the positioning plane in relation to the main direction. There is also a kinematic expansion mechanism connected to the casing to translate the mobile arched module with respect to the fixed arched module.

An X-ray detector includes an anti-scatter grid, an electrode and a converter element for converting X-rays into electrical charges in a stacking arrangement. In an embodiment, the stacking arrangement is externally enclosed by a protective element. The protective element extends in the stacking direction such that an enclosed area is at least arranged between the anti-scatter grid and the converter element and along the entire height of the converter element in the stacking direction. An adhesive element is arranged between the anti-scatter grid and the electrode.

A collision sensor device for a medical apparatus includes a sensor structure having a first sensor and a second sensor that are separated by a spacer layer, at least one crumple layer that adjoins one of the first sensor and the second sensor and is configured to provide a run-on path, and an outer surface layer provided on a side facing away from the medical apparatus in an installed state of the collision sensor device.