Abstract: A method for verifying the position of at least two bone structures relative to each other, comprising the method steps of: recording a three-dimensional dataset which represents the bone structures; segmenting the three-dimensional dataset into segments, wherein each segment represents a bone structure and the segments exhibit a known relative position in the three-dimensional dataset; changing the virtual relative position of the segments, such that the virtual relative position of the segments matches the actual relative position of the bone structures; and verifying whether the virtual relative position of the segments matches a target position of the bone structures.

Abstract: A method for artifact-free rendering of metal parts in 3D three-dimensionally reconstructed images of an examination object in a patient, includes recording a 3D scan without metal parts producing a 3D data record, recording n projection images with metal parts from known locations or directions, 2D/3D registering bone in the n projection images with the 3D data record, 2D/3D registering of the metal parts from the n projection images and 3D models of the metal parts, calculating locations of the metal parts in the 3D data record based on the 2D/3D registration thereof, and superposing all current locations of the metal parts in the 3D data record. There is no need for a new 3D scan to check current screw positions. The 3D representation of screw positions in the bone is performed without artifacts, enabling reliable assessment of screw locations, for example in spinal column surgery.

Abstract: A bone fracture is treated by employing a database with comparison data records. The records each include at least one 3D image data record of at least one bone. Each comparison data record is assigned to an examination object, into which a comparison implant was implanted prior to recording the 3D image data record. A two-dimensional x-ray image of a target bone is generated. A 2D/3D registration of the x-ray image with 3D image data records is effected and a deviation value is calculated for each comparison data record. A reference data record is determined by selecting the comparison data record that includes the 3D image data record with the lowest deviation value. An implantation parameter is determined which describes a parameter of the implant and/or of a fastening element for fastening the implant, using the reference data record and/or displaying data of the reference data record on a display.

Abstract: A system for displaying an image includes at least one x-ray source for emitting radiation, a detector for acquiring the radiation emitted by the radiation source for generating an x-ray image, the detector being disposed opposite the radiation source in relation to an object to be examined, a computer unit for performing computational operations, a display device for displaying x-ray images acquired by the detector and at least one data acquisition unit for acquiring surface information of the object to be examined. The data acquisition unit is disposed on the detector side and the computer unit is configured to correlate the data acquired by the detector-side data acquisition unit with the x-ray image.

Abstract: A method and a system for determining an angle between two parts of a bone that are twisted relative to one another about the axis of a bone shaft. The system is particularly suitable for determining the antetorsion angle of a femur. In order to determine an antetorsion angle of a bone easily intraoperatively, a method with the following steps is proposed: establishing the position of a first orientation feature assigned to a first part of the bone, in particular a femoral neck axis, using an imaging method, establishing the position of a second orientation feature assigned to a second part of the bone, in particular a condyle tangent or a condyle plane, using an imaging method, and determining the angle, in particular the femoral antetorsion angle, from the positions of the two orientation features.

Abstract: A mobile medical apparatus contains a movement device for a moving the entire apparatus. The mobile medical apparatus has a detection device for detecting the movement of the apparatus, a storage device for storing information describing the movement of the apparatus, and a control interface for inputting a control command to the apparatus for repeating a movement in accordance with information describing the movement of the apparatus.

Abstract: A method for determining a distance between a first point and a second point on an object under examination inside the body of a person under examination by way of x-ray imaging by an x-ray device. The method includes the recording of x-ray images at different relative positionings of the x-ray device, which contain the first and the second point respectively. The relative positionings are substantially shifted in relation to one another in parallel to a central beam. Stereo reconstruction is carried out to define a 3D position of the first point and of the second point. The distance between the first point and the second point is determined from the 3D position of the first point and the 3D position of the second point.

Abstract: A method of generating a preview of at least one low-dose x-ray image includes the followings steps: obtaining an initial volumetric representation of a patient from an x-ray device; creating at least one x-ray image projection from the initial volumetric representation; injecting correlated noise into at least one of the x-ray image projections; and processing the noise-injected x-ray image projections to create at least one preview of a patient-specific low-dose x-ray for showing to a user. There are also described a device for generating at least one preview of a low-dose x-ray image, a corresponding imaging system, and a non-transitory computer readable medium.

Abstract: A visualization of an X-ray region during the production of an X-ray recording of an object is produced. In order to reduce radiation exposure for a physician and/or the patient during X-ray recordings, a proposal is made to record a video image of a region, which is captured by a beam from the X-ray source, of the object, to display the video image and to represent at least a portion of the beam in the displayed video image.

Abstract: A navigation aid for introducing an elongate medical penetration element into a patient. An X-ray image, containing a target region for the penetration element in a desired target position in a patient, is superimposed in alignment with video sequence images, containing at least in part the penetration element, to form a combination image sequence. The penetration element is captured in a start position and a desired penetration course of the penetration element at least to the target region of the penetration element in a desired target position, is visually displayed in the combination image sequence. A penetration element, such as a medical implant and/or instrument, in particular a K-wire (Kirschner wire), may carry a number of markers, such as additional bodies, coatings, elevations, and/or depressions, said markers altering a light reflection, are situated on and/or at and/or in the penetration element.

Abstract: The pose of an implant represented in a medical image is determined from the medical image. The x-ray image of the implant is compared to a database of the implant viewed at different poses (e.g., viewed from different directions). The implant pose associated with the best match indicates the pose of the implant in the x-ray image.

Abstract: Disclosed herein is a framework for facilitating fused-image visualization for surgery evaluation. In accordance with one aspect of the framework, at least one pre-operative image and at least one intra-operative image of an anatomical structure are received. A region of interest may be identified in the intra-operative image. The pre-operative image may be straightened, and a symmetric region may be identified in the straightened pre-operative image. The symmetric region is substantially symmetrical to a target region in the straightened pre-operative region. The target region corresponds to the region of interest in the intra-operative image. The symmetric region may be extracted and reflected to generate a reference image. The intra-operative image may be rigidly registered with the reference image to generate registered intra-operative image, which is overlaid on the target region in the straightened pre-operative image to generate a fused image.

Abstract: A supporting device is provided for a radiation source and a radiation detector, as well as an imaging device having a supporting device. The supporting device contains a base unit, a guidance device with a first segment and a second segment, and a first support arm. The first segment is rotatably arranged at a first rotation connection at the first support arm. The first support arm is pivotably arranged at the base unit of the supporting device such that, by a pivot movement of the first support arm, the first segment can be moved from a first position in which the segments make contact with one another, into a second position in which the segments are separated from one another.

Abstract: A method for repositioning a mobile imaging system includes: a) capturing an image recording of at least one optical marker as a reference variable which is disposed close to an examination and/or treatment area of an object, b) capturing the image recording direction as a further reference variable, c) wherein the capturing mobile imaging system is in a predefined position and/or alignment suitable for image recording, d) detecting a changed and/or non-capturable position of the at least one optical marker and/or a changed and/or non-capturable image recording direction, and e) repositioning the mobile imaging system using a comparison of the reference variables from a) and b) with the respectively corresponding reference variables from d). An image capturing unit and an optical marker are also provided.

Abstract: A user is visually assisted when fixing an implant with a locking element in, or on, a bone. The location of a guide instrument for guiding the locking element relative to the implant is set by a target apparatus. The implant can be rotated and/or positioned by moving the target apparatus. The guide instrument carries at least one x-ray marker. An x-ray device records an x-ray image of the target region of the locking element and the x-ray marker. The orientation and position of a projected straight line, which forms a projection of a longitudinal axis of the guide instrument in the image plane, is determined from the position and/or form of the image of the x-ray marker. A superposed illustration is calculated of the x-ray image with a graphical element indicating the orientation and position of the projected straight line and the superposed illustration is output on a display.

Abstract: A method generates a 3D image data set of a volume to be examined, in which at least part of a foreign object is positioned. A set of 2D projection images is recorded, the image regions which present the foreign object are detected in at least two 2D projection images of the set. The image regions which present the foreign object are segmented in the at least two 2D projection images. A marking assigned to the segmented image regions is incorporated in the at least two 2D projection images. The 2D projection images, including the at least two 2D projection images having the incorporated markings, are used for the reconstruction of a 3D image data set containing the marking.

Abstract: The device enables the detection of positions of the navigation marking elements on a reference star by way of at least two projection images taken by an X-ray system at different pivoting angles of a C-arm. The positions of the navigation marking elements on the reference star are also calculated by a navigation system tracking camera. The transformation from the coordinate system of the navigation system into the coordinate system of the X-ray system is calculated from the position of the reference star detected by the X-ray system and the position of the reference star detected by the tracking camera. The navigation marking elements are located outside of the volume which is reconstructed by way of the imaging process in order to prepare tomographic images. The positions of the navigation marking elements are determined from two-dimensional projections. All the navigation marking elements need only be detected by at least two projection images.

Abstract: A bone fracture is treated by employing a database with comparison data records. The records each include at least one 3D image data record of at least one bone. Each comparison data record is assigned to an examination object, into which a comparison implant was implanted prior to recording the 3D image data record. A two-dimensional x-ray image of a target bone is generated. A 2D/3D registration of the x-ray image with 3D image data records is effected and a deviation value is calculated for each comparison data record. A reference data record is determined by selecting the comparison data record that includes the 3D image data record with the lowest deviation value. An implantation parameter is determined which describes a parameter of the implant and/or of a fastening element for fastening the implant, using the reference data record and/or displaying data of the reference data record on a display.

Abstract: A computer-aided control system, a computer-based method and a computer program or a computer program product control an implant positioning of an endoprosthesis. Planning data are generated on the basis of a preoperatively acquired first image data set. The endoprosthesis is provisionally positioned intraoperatively. A second image data set representing the current ACTUAL position of the endoprosthesis is thereupon acquired. Control data are thereupon generated, the control data serve for the fine positioning of the endoprosthesis and being based on a comparison between DESIRED and ACTUAL states.

Abstract: A method for artifact-free rendering of metal parts in 3D three-dimensionally reconstructed images of an examination object in a patient, includes recording a 3D scan without metal parts producing a 3D data record, recording n projection images with metal parts from known locations or directions, 2D/3D registering bone in the n projection images with the 3D data record, 2D/3D registering of the metal parts from the n projection images and 3D models of the metal parts, calculating locations of the metal parts in the 3D data record based on the 2D/3D registration thereof, and superposing all current locations of the metal parts in the 3D data record. There is no need for a new 3D scan to check current screw positions. The 3D representation of screw positions in the bone is performed without artifacts, enabling reliable assessment of screw locations, for example in spinal column surgery.