A medical imaging system includes a gantry, a display device, and a control circuit. The gantry includes detector arms circumferentially spaced apart along a perimeter of a bore and radially movable towards and away from a subject. The control circuit generates a subject shape outline of the subject within the bore based on obtained contour image data of the subject. The control circuit determines designated scan positions of the detector arms based on the subject shape outline. The control circuit displays the subject shape outline on the display device within a gantry visualization that is a graphical representation of the gantry showing the bore. The control circuit displays a set of graphical detector arms on the display screen within the gantry visualization. The graphical detector arms are displayed at the designated scan positions relative to the gantry of the gantry visualization to show a subject-gantry geometric relationship.

In an X-ray imaging apparatus, an X-ray irradiation unit, an X-ray detection unit, a control unit configured to control irradiation of an X-ray, an X-ray image processing unit configured to operate independently of the control unit, and a storage battery for the X-ray image processing unit and the control unit are provided. The X-ray image processing unit is configured to acquire information on a remaining amount of the storage battery from the control unit and perform processing of reducing power consumption of the X-ray image processing unit when the remaining amount of the storage battery is equal to or less than a predetermined threshold value.

A radiation dose received by a patient from a radiation therapy system can be verified by acquiring a cine stream of image frames from an electronic portal imaging device (EPID) that is arranged to detect radiation exiting the patient during irradiation. The cine stream of EPID image frames can be processed in real-time to form exit images providing absolute dose measurements at the EPID (dose-to-water values), which is representative of the characteristics of the radiation received by the patient. Compliance with predetermined characteristics for the field can be determined during treatment by periodically comparing the absolute dose measurements with the predetermined characteristics, which can include a predicted total dose in the field after full treatment and/or a complete irradiation area outline (CIAO). The system operator can be alerted or the irradiation automatically stopped when non-compliance is detected.

The present invention relates to determining baseline shift of an electrical signal generated by a photon detector (102) of an X-ray examination device (101). For this purpose, the photon detector comprises a processing unit (103) that is configured to determine a first crossing frequency of a first pulse height threshold by the electrical signal generated by the photon detector. The first pulse height threshold is located at a first edge of a noise peak in the pulse height spectrum of the electrical signal.

A radiation imaging system including an image acquisition unit configured to acquire a radiographic image based on radiation, an image processing setting unit configured to set multiple types of image processing for a specific imaging procedure, an image processing unit configured to perform the multiple of types of image processing set by the image processing setting unit on a radiographic image acquired in the specific imaging procedure to generate multiple radiographic images, and an association setting unit configured to set whether the multiple radiographic images generated by the image processing unit are to be associated with one another.

The present invention is directed to a system and method for performing tissue, preferably bone tissue manipulation. The system and method may include implanting markers on opposite sides of a bone, fractured bone or tissue to facilitate bone or tissue manipulation, preferably in-situ closed fracture reduction. The markers are preferably configured to be detected by one or more devices, such as, for example, a detection device so that the detection device can determine the relative relationship of the markers. The markers may also be capable of transmitting and receiving signals. An image may be captured of the bone or tissue and the attached markers. From the captured image, the orientation of each marker relative to the bone fragment may be determined. Next, the captured image may be manipulated in a virtual or simulated environment until a desired restored orientation has been achieved. The orientation of the markers in the desired restored orientation may then be determined. The desired relationship between markers may then be programmed into, for example, the detection device. Next, actual physical reduction and/or manipulation of the bone may begin. During the manipulation procedure, the orientation of the markers may be continuously monitored and when the markers substantially align with the virtual or simulated orientation of the markers in the desired restored orientation, an indicator signal is transmitted.

An X-ray detector includes a detection unit to convert X-rays into a signal value and an evaluation unit. The detection unit and the evaluation unit are configured in a common component, the extent of the component along a first direction being not greater than the extent of the detection unit. The evaluation unit includes at least one correction unit to correct the signal values, a computation unit to control the correction, and a memory unit to store at least one correction parameter. The evaluation unit is designed such that the signal values are corrected as a function of the at least one correction parameter. A method and detector group are also disclosed.

Methods, systems, and devices for medical imaging are described. Examples may include an augmented reality (AR) server receiving a set of medical imaging data acquired by at least a first imaging modality. The set of medical imaging data may include a visual representation of a biological structure of a body. Next, the medical imaging data can be used to render an isolated anatomical model of a least a portion of the biological structure. The isolated anatomical model can be received by an AR viewing device such as AR glasses. The AR viewing device may display on a display of the AR viewing device, a first view perspective of the isolated anatomical model in a first orientation. The first orientation may be based on a position of the first AR viewing device relative to the body. Examples include displaying a virtual position of the medical instrument in the AR viewing device.

This invention relates to a device for identifying the location of internal anatomical features by externally marking on skin during a CAT scan comprising a flexible sheet having a plurality of intersecting lines mounted with at least one 3D structure wherein the sheet is provided in the form of a mesh comprising an x-ray opaque material.

A method for geometric calibration of a mobile radiography apparatus, executed at least in part by a computer, acquires a series of tomosynthesis projection images of a patient positioned between an x-ray source of the mobile radiography apparatus and a detector that is positionally uncoupled from the x-ray source. A vector field is generated having a first set of vectors indicative of feature movement between a first acquired projection image and a second acquired projection image. The generated vector field is associated with an epipolar geometry according to an optimization of an energy relationship between an epipolar model and the generated vector field values. The mobile radiography apparatus is calibrated according to the associated model epipolar geometry. At least a portion of the tomosynthesis image is reconstructed and displayed.