Abstract systems and methods of biopsy control include reconstructing a 3D volume from a plurality of tomosynthesis projection images and producing a plurality of synthetic stereo images from the plurality of tomosynthesis projection images. At least the synthetic stereo images are presented on a graphical display to a clinician to facilitate at least one input of a biopsy location for biopsy control.

A stitch imaging system, which uses a plurality of radiographic imaging units, includes an information acquisition unit configured to acquire information indicating a layout relationship among the plurality of radiographic imaging units, and a correction unit configured to correct a radiographic image or radiographic images acquired from at least one of the plurality of radiographic imaging units specified based on the information indicating the layout relationship, based on correction data specified based on the information indicating the layout relationship.

An X-ray fluoroscopic imaging apparatus which can accurately perform enhancement processing of a device and can also reduce a burden on an operator is provided. An exclusion region E is set so as to surround an obstacle on an X-ray image generated by an image generation unit. A marker extraction unit extracts a marker from a region except for an exclusion region in the X-ray image. An integration unit superimposes a predetermined number of X-ray images on the basis of the position of the marker to generate an integrated image. In this case, detecting obstacle as a marker can be avoided, so the integrated image becomes an image with a stent suitably highlighted. Even in cases where it is difficult to set the region-of-interest so that an obstacle falls out of the range, such as a case in which an obstacle overlaps or is in proximity to a stent, it is easy to set the exclusion region so that the marker is out of range and the obstacle falls within the range. Therefore, the enhancement processing of the stent can be suitably executed according to more various situations.

An image processing apparatus includes a display configured to display a medical image; an input unit configured to receive n (n being an integer equal to or greater than three) number of input points with respect to the displayed medical image; and a controller configured to set a window in the medical image based on an area in a shape of a polygon, the area being defined by the input points, and to perform image processing of reducing at least one of brightness and definition of the medical image in a remaining area except for an area of the window.

Among other things, one or more techniques and/or systems for calibration of a radiation system to compute a gain correction(s) are provided. A calibration procedure is performed during which a portion of the detector array is shadowed by an object, causing the detector array to be non-uniformly exposed to radiation. A portion of a projection generated from the calibration procedure and indicative of radiation that did not traverse the object is separated from a portion of the projection indicative of radiation that did traverse the object, and a gain correction(s) is computed from the portion of the projection indicative of radiation that did not traverse the object (e.g., and is thus indicative of radiation that merely traversed air).

According to the image processing device of the present invention, the binarization image having increasing assuredness can be generated by extracting the metal piece from the original image with the graph cut processing. The image processing device of the present invention is the system that executes an image trimming from near the center of the intermediate region after the metal piece is divided relative to the image of the roughly extracted binarization image near the center of the intermediate region in that it is difficult to decide whether it belongs to the metal piece or not. Following such steps, the intermediate region can be assuredly trimmed while executing the image trimming in the region as small as possible.

Apparatus having an x-ray source and a DR detector configured to travel cooperatively around a radiographic imaging axis. An imaging volume defines a spatial region to be imaged by the x-ray source and the DR detector. Radiopaque fiducials are selectively positioned in the imaging volume.

There is provided a method for predicting risk of osteoporotic fracture, comprising: receiving imaging data of a computed tomography (CT) scan of a body of a patient containing at least a bone portion, the CT scan being performed with settings selected for imaging of non-osteoporosis related pathology; processing the imaging data to identify the bone portion; automatically extracting features based on the imaging data denoting the identified bone portion; computing an osteoporotic fracture predictive factor indicative of the risk of developing at least one osteoporotic fracture in the patient, or the risk of the patient having at least one severe osteoporotic fracture, based on the extracted features, the predictive factor calculated by applying a trained osteoporotic fracture classifier to the extracted features, the osteoporotic fracture classifier trained from data from a plurality of CT scans performed with settings selected for imaging non-osteoporosis related pathology; and providing the predictive factor.

A system and method are provided for obtaining an improved visualization of bone objects comprised in a projection X-ray image. The projection X-ray image comprises bone objects which at least in part overlap. According to the system and method, a number of the bone objects are delineated by a contour, thereby obtaining a number of delineated bone objects. For each of the number of delineated bone object, a bone suppression technique is applied to the image to obtain respective bone image data individually showing the respective delineated bone object while suppressing shadows of obstructing objects. The bone image data generated for each of the number of delineated bone objects is used to generate an output image in which the bone objects do not overlap. An advantage of the system and method is that a non-overlapping, shadow-suppressed, presentation of the bone objects may be created from an X-ray image which was obtained by projectional radiography.

A method for processing a radiographic image of a patient, executed at least in part on a host processor, initiates exposure in response to an instruction entered from an operator console and obtains radiographic image data from a digital detector that is subjected to the exposure. The obtained radiographic image data is analyzed according to a set of predefined criteria for diagnostic suitability of the image. One or more results of the diagnostic suitability analysis at the operator console is indicated and a listing of one or more corrective actions at the operator console according to the indicated results is provided.