A medical image diagnosis apparatus for use in a therapeutic procedure to a subject includes processing circuitry. The processing circuitry is configured to determine a status of a current therapeutic procedure; determine at least one proposed preset of settings of the medical image diagnosis apparatus according to the status of the current therapeutic procedure; and perform a control in accordance with the at least one proposed preset.

An X-ray imaging method is for generating contrast-enhanced image data relating to an examination region of an object to be examined. In an embodiment of the method, first contrast-agent influenced measured X-ray projection data with a first X-ray energy spectrum and at least one set of second contrast-agent influenced measured X-ray projection data with a second X-ray energy spectrum are acquired from the examination region. Subsequently, image data assigned to a third X-ray energy spectrum with a third mean energy, based on the first and at least second measured X-ray projection data is reconstructed based on the first and at least second measured X-ray projection data that has been acquired. A mean energy of the first X-ray energy spectrum and a mean energy of the second X-ray energy spectrum are selected as a function of a dimension parameter value of the object that is to be examined.

This disclosure generally relates to systems, methods, and devices for performing high-resolution computer tomography (CT) scans providing highly detailed images of particular regions using whole body clinical CT scanners while maintaining high imaging speeds and low dose levels. In particular, the disclosed systems use flat panel detectors in conjunction with common CT detectors to quickly produce high-resolution CT images.

Methods and systems are disclosed for radiating a moving object. The method may comprise acquiring a plurality of indicators of the phase of a physiological cycle of a patient and a plurality of images of the patient that include a target. Each image may be taken at a different phase of the physiological cycle and may be registered to the phase at which the image was taken. The method may also include identifying the target in each of the plurality of images, calculating a dose of radiation required to treat the target, calculating the number, orientation, and dwell time of one or more radiation beams required to deliver the calculated required dose of radiation to the target, and calculating a position of each of the one or more radiation beams required to achieve the calculated orientation. Each position may be a function of the phase of the physiological cycle to which each of the plurality of images is registered.

A medical apparatus of embodiments includes processing circuitry. The processing circuitry is configured to input third projection data to a first trained model to generate fourth projection data, the first trained model being generated through learning using first projection data collected by a first X-ray detector included in a first scanner and relatively greatly affected by scattered rays as learning data of an input side and using second projection data relatively less affected by scattered rays as learning data of an output side, the first trained model being configured to generate, on the basis of the third projection data collected by a second X-ray detector included in a second scanner, the fourth projection data in which the influence of scattered rays in the third projection data has been reduced. The first projection data is collected by the first X-ray detector in a case where a collimator provided in a first X-ray source included in the first scanner has a first opening width. The second projection data is collected by the first X-ray detector in a case where the collimator has an opening width smaller than the first opening width.

The present invention provides a radiotherapy apparatus (100) to generate both photon and electron beam mounted with dual KV beam ray source used for stereotactic imaging and CBCT (Cone Beam Computed Tomography) image with a greater FOV (Field Of View). The apparatus (IOO) comprises of a ring gantry (101), which includes at least two KV sources (102a and 102b), at least two movable detector (103 and 104) and a LINAC X-ray tube (106). The two movable detectors (103, 104) include a first movable detector (104) and a second movable detector (103). The second movable detector (103) has mechanism capture a half fan mode of X-ray beam of imaging radiation with a greater FOV having 250×450 mm. The half fan mode of X ray is captured by moving the second movable detector (103) or first movable detector (104) further towards the ISO centre (105) of the ring gantry (101).

Imaging methods and imaging systems are provided. Methods and systems of the subject invention can include linearly translating a source and a detector. The source and the detector can be moved in opposite or approximately opposite directions. Acquired data can be used to reconstruct a tomographic image by using, for example, a compressive sensing technique.

This imaging controller of the imaging controller includes: an imager position determination section that determines whether or not a first imager is located in an overlapping region where a rotation range of the first imager and a rotation range of a second imager overlap each other when a rotation mechanism rotates the first and second imagers by an angle greater than the predetermined angle; and an imaging timing control section that causes one or both of the first and second imagers to perform imaging when arrival of an imaging timing is detected and that causes only the second imager to perform imaging in at least one imaging timing whose arrival is detected in a state where the imager position determination section determines that the first imager is located in the overlapping region.

A system and method include acquisition of Q (Q≧2) energy images of M (M≧2) different materials, each one of the Q energy images associated with a respective range of photon energies, determination of R (R≧2) combinations of N (N≧2) energy images from the Q energy images, determination of an overlap associated with each of the R combinations of N energy images, the overlap associated with a combination of first N energy images indicating an extent of overlap between distribution functions associated with each of the M different materials and determined based on the first N energy images, and identification of one of the R combinations of N energy images associated with a smallest overlap of the determined overlaps.

Imaging systems and methods for rapidly generating reconstruction image data of an object while allowing access to the object during imaging. In some embodiments, the system may comprise at least one radiation source that moves along a path, which path may be defined by an enclosed gantry, and emits radiation toward at least one radiation detector. The radiation source(s) and the radiation detector may be positioned such that at least a portion of an object, such as a portion of a patient's anatomy, can be positioned in between the plurality of radiation sources and the radiation detector to facilitate generation of the reconstruction image data.