Abstract: A computing device includes a thermal map generator (142) that generates a thermal map for image data voxels or pixels representing a volume or region of interest of a subject based on thermometry image data, which includes voxels or pixels indicating a change in a temperature in the volume or region of interest, and a predetermined change in value to temperature lookup table (144) and a display (145) that visually presents the thermal map in connection with image data of the volume of interest. A method includes generating a thermal map for image data voxels or pixels representing a volume or region of interest of a subject based on thermometry image data, which includes voxels or pixels indicating a change in a temperature in the volume or region of interest, and a predetermined change in voxel or pixel value to temperature lookup table.

Abstract: The present invention relates to a system (10) for guiding an instrument (12, 100, 100A, 100B, 112) in a body (14). The system (10) records an image where the instrument (12, 100, 100A,100B, 112) is identifiable and the instrument (12, 100, 100A, 100B, 112) records signals indicative of the type of tissue at the instrument (12, 100, 100A, 100B, 112). The system (10) determines the tissue type based on a signal from the instrument (12, 100, 100A, 100B, 112). The system (10) displays an image being a combined image of the body (14) and instrument (12, 100, 100A, 100B, 112) and an indication of tissue type at a position where the tissue type was determined. The present invention further relates to a method of displaying an image comprising tissue-type and instrument position in a body. The present invention further relates to an instrument and a software implemented method for being executed on a digital processor.

Abstract: The invention relates to an imaging apparatus (1). First and second image providing units (2, 9) provide a first image showing a region of an object, which includes a resection part to be resected, and a second image showing the region of the object, after the resection procedure has been performed, or showing a resected part, which has been resected. A smallest margin determination unit (13) determines a smallest margin region being a region where a margin between the resection part and the resected part is smallest based on the first and second images. The smallest margin region is the region which most likely contains a part of the object, which should have been resected, like a cancerous part. An optionally following investigation of the resected part or of the remaining object can be more focused by considering this region, thereby allowing for faster corresponding assessing procedures.

Abstract: The positions of the images and a display mode of at least two images of an object are selected based on a comparison of a provided distance value between the edges of the two displayed images and a distance threshold value. By continuously varying the distance value, the corresponding images and the display mode are adapted to an actual distance value.

Abstract: The present invention relates to a system (10) for navigating and positioning an instrument (12, 40, 112) in a body (14). The instrument (12, 40, 112) is detectable by the system (10) and the system (10) displays a view to an operator. The instrument (12, 40, 112) is adapted to identify tissue parameters. The system (10) is adapted to display an image being a combined image of the interior of a body (14) and an indication of the tissue parameter at the appropriate earlier locations. The present invention further relates to a method (44) including determining tissue parameters and displaying the parameters in an image of a body (14). The present invention further relates to a software implemented method (44) for being executed on a digital processor. The present invention further relates to an instrument (12, 40, 112).

Abstract: The invention relates to an energy application planning apparatus for planning an application of energy to an object (3) like a tumor. An energy application element representation represents an energy application element (5) like an ablation needle including an energy application part for applying energy and a sensing part (7). An arrangement of the energy application element (5) with respect to the object (3) is determined depending on the positions of the energy application part and the sensing part (7) with respect to the energy application element (5) as defined by the energy application element representation and depending on the object representation. The application of energy can therefore not only be planned such that the application of energy is performed as desired, but also such that the object and/or a surrounding of the object are sensible as desired. In this way, the planning procedure can be improved.

Abstract: The present invention relates to a method and device for preventing metal artifacts computer tomography scans made during biopsy taking, when a metal needle is present in the field of view of a scan. The direction of the metal needle and the direction of the electro-magnetic field are determined in advance. For the determination of the electro-magnetic field a position of a source of the electro-magnetic field a position of a detector are considered. The user may be warned, when the determined direction of the electro-magnetic field and of the direction of the metallic needle correspond to each other.

Abstract: The present invention relates to a method and a device for determining a display mode for displaying at least two images of an object. The positions of the images and the display mode of the images are selected based on a comparison of a provided distance value between the edges of the two displayed images and a distance threshold value. By e.g. continuously varying the distance value, the corresponding images and display mode are adapted to the actual distance value.

Abstract: A computing device includes a thermal map generator (142)that generates a thermal map for image data voxels or pixels representing a volume or region of interest of a subject based on thermometry image data, which includes voxels or pixels indicating a change in a temperature in the volume or region of interest, and a predetermined change in value to temperature lookup table (144) and a display (146) that visually presents the thermal map in connection with image data of the volume of interest. A method includes generating a thermal map for image data voxels or pixels representing a volume or region of interest of a subject based on thermometry image data, which includes voxels or pixels indicating a change in a temperature in the volume or region of interest, and a predetermined change in voxel or pixel value to temperature lookup table.

Abstract: The present invention relates to a system (10) for navigating and positioning an instrument (12, 40, 112) in a body (14). The instrument (12, 40, 112) is detectable by the system (10) and the system (10) displays a view to an operator. The instrument (12, 40, 112) is adapted to identify tissue parameters. The system (10) is adapted to display an image being a combined image of the interior of a body (14) and an indication of the tissue parameter at the appropriate earlier locations. The present invention further relates to a method (44) including determining tissue parameters and displaying the parameters in an image of a body (14). The present invention further relates to a software implemented method (44) for being executed on a digital processor. The present invention further relates to an instrument (12, 40, 112).

Abstract: The present invention relates to a system (10) for guiding an instrument (12, 100, 100A, 100B, 112) in a body (14). The system (10) records an image where the instrument (12, 100, 100A,100B, 112) is identifiable and the instrument (12, 100, 100A, 100B, 112) records signals indicative of the type of tissue at the instrument (12, 100, 100A, 100B, 112). The system (10) determines the tissue type based on a signal from the instrument (12, 100, 100A, 100B, 112). The system (10) displays an image being a combined image of the body (14) and instrument (12, 100, 100A, 100B, 112) and an indication of tissue type at a position where the tissue type was determined. The present invention further relates to a method of displaying an image comprising tissue-type and instrument position in a body. The present invention further relates to an instrument and a software implemented method for being executed on a digital processor.

Abstract: The invention relates to an imaging apparatus (1). First and second image providing units (2, 9) provide a first image showing a region of an object, which includes a resection part to be resected, and a second image showing the region of the object, after the resection procedure has been performed, or showing a resected part, which has been resected. A smallest margin determination unit (13) determines a smallest margin region being a region where a margin between the resection part and the resected part is smallest based on the first and second images. The smallest margin region is the region which most likely contains a part of the object, which should have been resected, like a cancerous part. An optionally following investigation of the resected part or of the remaining object can be more focused by considering this region, thereby allowing for faster corresponding assessing procedures.

Abstract: An X-ray apparatus 10 executes a first scan of an object during a forward movement F and a second scan during a backward movement B. Due to the wiper-like movement of the X-ray imaging device 18 supported by an arm 12 of the X-ray apparatus 10, the time between two scans may be very short.

Abstract: The invention relates to an energy application planning apparatus for planning an application of energy to an object (3) like a tumor. An energy application element representation represents an energy application element (5) like an ablation needle including an energy application part for applying energy and a sensing part (7). An arrangement of the energy application element (5) with respect to the object (3) is determined depending on the positions of the energy application part and the sensing part (7) with respect to the energy application element (5) as defined by the energy application element representation and depending on the object representation. The application of energy can therefore not only be planned such that the application of energy is performed as desired, but also such that the object and/or a surrounding of the object are sensible as desired. In this way, the planning procedure can be improved.

Abstract: A computed tomography acquisition method, an imaging system, a computer readable medium provides laterally displacing a radiation detector (204) from a position with centered detector geometry with a centered transverse field of view to a first offset position (212); emitting first radiation by the radiation source (202), detecting the first radiation by the radiation detector (204) and acquiring projection data indicative of the first radiation; rotating the support around the rotational axis (214) by 180°; emitting second radiation by the radiation source (202), detecting the second radiation by the radiation detector (204) and acquiring projection data indicative of the second radiation; displacing the radiation detector (204) from the first offset position to a second offset position (226), with opposite direction and double length of the first displacement (a); emitting third radiation by the radiation source (202), detecting the third radiation by the radiation detector (204) and acquiring projection da

Abstract: The present invention refers to 3D rotational X-ray imaging systems for use in computed tomography (CT) and, more particularly, to a fast, accurate and mathematically robust calibration method for determining the effective center of rotation (I) in not perfectly isocentric 3D rotational C-arm systems and eliminating substantially circular ring artifacts (RA) which arise when using such a CT scanner system for acquiring a set of 2D projection images of an object of interest to be three-dimensionally reconstructed.

Abstract: An X-ray apparatus 10 executes a first scan of an object during a forward movement F and a second scan during a backward movement B. Due to the wiper-like movement of the X-ray imaging device 18 supported by an arm 12 of the X-ray apparatus 10, the time between two scans may be very short.

Abstract: A method for providing information about a spatial gain distribution of a scintillator for a primary radiation is provided which does not require the irradiation of the scintillator with the primary radiation. The method comprises the step of irradiating the scintillator with a secondary radiation for generating an image of a spatial secondary gain distribution of the scintillator for said second radiation. The spatial secondary gain distribution image corresponds to an image of the spatial primary gain distribution for the primary radiation. In an embodiment of the invention, i.e. in an X-ray imaging device where the primary radiation is X-ray radiation, the invention provides for an accurate calibration of the X-ray detector without irradiating the X-ray detector with X-ray radiation. Rather, irradiation with UV radiation as the secondary radiation provides the desired spatial secondary gain distribution image which can be used for calibration.

Abstract: Current C-arm examination devices are not capable of performing 360 degrees rotations. The reason for this is that the cabling which connects the external cabinets to the detector, collimator and x-ray tube does not allow for such a rotation. According to an exemplary embodiment of the present invention, an examination apparatus is provided which has a connection device connecting the external cabinets to the C-arm which is adapted for enabling a rotation of the C-arm of more than 360 degrees. Such a connection device may comprise a storing device for winding up the cable.

Abstract: A computed tomography acquisition method, an imaging system, a computer readable medium provides laterally displacing a radiation detector (204) from a position with centered detector geometry with a centered transverse field of view to a first offset position (212); emitting first radiation by the radiation source (202), detecting the first radiation by the radiation detector (204) and acquiring projection data indicative of the first radiation; rotating the support around the rotational axis (214) by 180°; emitting second radiation by the radiation source (202), detecting the second radiation by the radiation detector (204) and acquiring projection data indicative of the second radiation; displacing the radiation detector (204) from the first offset position to a second offset position (226), with opposite direction and double length of the first displacement (a); emitting third radiation by the radiation source (202), detecting the third radiation by the radiation detector (204) and acquiring projection da