Abstract: A medical image processing system that can accept commissions to perform 3D formation using a 3D forming apparatus includes a storage unit, a selection accepting unit, a part identifying unit, and a screen generating unit. The storage unit stores a medical image, and body part information representing a human body part in the medical image. The selection accepting unit accepts selection with regard to the medical image stored in the storage unit. The part identifying unit identifies the body part included in the medical image, using the body part information corresponding to the medical image regarding which the selection accepting unit has accepted selection. The screen generating unit generates a screen that can accept a commission to form a formed object of the body part identified by the part identifying unit.

Abstract: [Object] The invention is intended to provide a medical image processing apparatus in which improvement of accuracy of boundary detection of a heart is achieved. [Solving Means] A medical image processing apparatus acquires volume data of a heat, detects a three-dimensional left ventricle coordinate system composed of three axes including at least a left ventricle long axis of the heart from the volume data; uses a boundary model expressed in the left ventricle coordinate system and detects a left ventricle boundary from the volume data, and displays a cross-sectional image orthogonal to at least one axis of the three axes of the left ventricle coordinate system together with the detected left ventricle boundary on the cross-sectional image.

Abstract: An object of the present invention is to alleviate an image diagnosing work in a work station or the like. In a viewer 7 for displaying, on a display unit 11, image data based on a radio signal transmitted from a capsule endoscope to be inserted into a subject, an image processing circuit 35 processes image data received from a receiving apparatus 5 via an interface 34, so as to produce an image processing result of the image data, and further, a control unit 38 displays the image and the image processing result on the display unit 11 in real time, so as to enable a body-cavity image to be observed with reference to the image processing result.

Abstract: Disclosed are an apparatus and method for sharing and managing information in a PACS. A system for storing and managing medical image includes a pre-processing unit for generating a second medical image set by using at least part of a first medical image set and a medical image storage unit for storing the first medical image set and the generated second medical image set and store first information, stored in relation to any one of the first medical image set and the second medical image set, in relation to the other of the first medical image set and the second medical image set. Although thin-slice data is deleted, annotation or marking for 3-D data can be maintained and managed.

Abstract: An information processing apparatus includes a report acquisition unit adapted to acquire report information including a region of interest in a medical image and comment information associated with the region of interest, a related region acquisition unit adapted to acquire a region related to the region of interest in the medical image, a determination unit adapted to determine a display position of a display region of the comment information so as not to make the display region of the comment information overlap the related region, and a display control unit adapted to display the medical image including the comment information so that the comment information is displayed at the determined display position of the display region on a display unit.

Abstract: An image processing apparatus according to an embodiment includes a scanning protocol creation unit, an image acquisition unit, a post-processing unit, and a storage unit. The scanning protocol creation unit creates a scanning protocol for a particular part of body of an object. The image acquisition unit acquires source image data by scanning the particular part using an imaging device according to scanning parameters in the scanning protocol. The post-processing unit performs post-processing on the source image data according to post-processing parameters in the scanning protocol to obtain processed image data. The storage unit stores the scanning protocol, or store the source image data and the processed image data or index identifiers thereof in association with parameters related to the scanning protocol as single job data of the object. The scanning protocol includes the scanning and the post-processing parameters, and information related to the imaging device and the post-processing unit.

Abstract: For the purpose of providing an image processing method for determining the variance of noise in an image, a residual sum of squares of pixel values is determined for each of a plurality of local regions defined over the entire image (502-508); a histogram thereof is obtained (510); and the variance of noise is determined based on the value of the residual sum of squares that gives a peak of the histogram (512, 514).

Abstract: A method to generate a final image with a medical imaging system, wherein the final image highlights suspect regions in a tissue matrix and wherein the final image is generated from a first image and from previously acquired images of the tissue matrix is provided. The method comprises: creating a 3D map of suspicion from the previously acquired medical images; generating a 2D map of suspicion by projecting all or part of the 3D map of suspicion onto a plane from a point reproducing the conditions of acquisition of the first image; and generating a final 2D image of the tissue matrix from the first image and/or from the 2D map of suspicion, wherein the final 2D image highlights suspect regions in the tissue matrix.

Abstract: A method for managing and/or processing medical image data is disclosed, in particular for controlling a medical workflow. Furthermore, a computer system and a computer program product having a computer program product code for implementing the method are disclosed. One embodiment is directed to a method for managing and/or processing medical image data including inputting medical image data generated by one or several modalities, the image data including the description data according to a predefined structure; assigning the image data to a template as a function of the classification thereof, with the template specifying the respective processing of image data in one or several processing steps and being used for the classification preferably of lists of classification criteria; and extracting the classification criteria at least partially from the description data.

Abstract: In a medical imaging system the flexibility and power of measurement tools is improved by making the measurements objects themselves, whereby flexible interaction is provided. The measurement objects (52) are aware of their position relative to other graphical objects (50, 51), in the image. A user of a medical imaging system is thus enabled to easily perform desired measurements and to display the results thereof in a reliable and flexible manner. A method, an apparatus and a computer-readable medium are provided for processing cursored user interaction with a spatially displayed medical image for producing graphics related measurement data on the medical image. The medical image comprises at least one graphics object and dynamic measurement objects are attached to said graphics object, wherein the measurement object may be moved, removed or transferred to other graphic objects on the medical image at any time.

Abstract: Methods, systems and related computer program products are provided for processing a medical image of a breast to detect anatomical abnormalities therein, including anatomical abnormalities that may be associated with breast cancer. The medical image of the breast, which includes a background region bordering a breast tissue region along a skinline thereof, is processed to detect an inward-facing retraction along the skinline, which can be potentially indicative of an anatomical abnormality in the breast tissue. In one preferred embodiment, a display monitor displays first information representative of the medical image of the breast and second information identifying a location of the detected inward-facing retraction on the medical image of the breast. In another preferred embodiment, one or more metrics characterizing the detected inward-facing retraction are used as features in the classification of potential CAD detections in the breast tissue region.

Abstract: Methods, systems and related computer program products are provided for processing a medical image of a breast to detect anatomical abnormalities therein, including anatomical abnormalities that may be associated with breast cancer. The medical image of the breast, which includes a background region bordering a breast tissue region along a skinline thereof, is processed to detect an inward-facing retraction along the skinline, which can be potentially indicative of an anatomical abnormality in the breast tissue. In one preferred embodiment, a display monitor displays first information representative of the medical image of the breast and second information identifying a location of the detected inward-facing retraction on the medical image of the breast. In another preferred embodiment, one or more metrics characterizing the detected inward-facing retraction are used as features in the classification of potential CAD detections in the breast tissue region.

Abstract: A method for MRI signal analysis of an area of a biological tissue comprising: a) providing a biological tissue, wherein physiological activity is taking place in an area thereof; b) acquiring sequential magnetic resonance images, at least during a portion of time in which said physiological activity is taking place, of said area and of at least a portion of the tissue in a vicinity of the area; c) constructing, responsive to at least one pixel-related parameter value of said images, a pixel parameter space; and d) separating the pixel parameter space into at least two subspaces.

Abstract: A method is disclosed for generating sinograms by sampling a plurality of transducers acoustically coupled with the surface of a volume of tissue over a period of time after a light pulse at one wavelength, and after another light pulse at a different wavelength, and for processing those sinograms, reconstructing at least two optoacoustic images from the two sinograms, processing the two optoacoustic images to generate two envelope images and generating a parametric map from information in the two envelope images. In an embodiment, motion and tracking are determined to align the envelope images. In an embodiment, at least a second parametric map is produced from information in the same two envelope images. In an embodiment an ultrasound image is also acquired, and the parametric map is coregistered with and overlayed upon the ultrasound image, and then displayed.

Abstract: A method, system, and method of doing business in a standards-based medical imaging environment is described in relation to the communication of computer-aided detection (CAD) results among devices, with one embodiment relating to the DICOM standard. CAD results are fixably integrated into the pixels of a secondary image derived from a source image, and the secondary image is transferred using a DICOM Secondary Capture Image Information Object Instance (SCI-IOI). The DICOM SCI-IOI is transferred to a viewing workstation, whereby a clinician can open, manipulate, and view the secondary image in a side-by-side comparison with the source image or derivative images thereof. Advantageously, CAD results are communicated to the clinician in a DICOM-conforming manner independent of whether the viewing workstation supports standard DICOM accommodations, such as CAD Structured Report Information Object Instances (CAD SR-IOIs), for the type of CAD results that need to be presented.

Abstract: A method, system, and method of doing business in a standards-based medical imaging environment is described in relation to the communication of computer-aided detection (CAD) results among devices, with one embodiment relating to the DICOM standard. CAD results are fixably integrated into the pixels of a secondary image derived from a source image, and the secondary image is transferred using a DICOM Secondary Capture Image Information Object Instance (SCI-IOI). The DICOM SCI-IOI is transferred to a viewing workstation, whereby a clinician can open, manipulate, and view the secondary image in a side-by-side comparison with the source image or derivative images thereof. Advantageously, CAD results are communicated to the clinician in a DICOM-conforming manner independent of whether the viewing workstation supports standard DICOM accommodations, such as CAD Structured Report Information Object Instances (CAD SR-IOIs), for the type of CAD results that need to be presented.

Abstract: A method, system, and method of doing business in a standards-based medical imaging environment is described in relation to the communication of computer-aided detection (CAD) results among devices, with one embodiment relating to the DICOM standard. CAD results are fixably integrated into the pixels of a secondary image derived from a source image, and the secondary image is transferred using a DICOM Secondary Capture Image Information Object Instance (SCI-IOI). The DICOM SCI-IOI is transferred to a viewing workstation, whereby a clinician can open, manipulate, and view the secondary image in a side-by-side comparison with the source image or derivative images thereof. Advantageously, CAD results are communicated to the clinician in a DICOM-conforming manner independent of whether the viewing workstation supports standard DICOM accommodations, such as CAD Structured Report Information Object Instances (CAD SR-IOIs), for the type of CAD results that need to be presented.

Abstract: A three-dimensional-based modeling method and system designed for dentistry and related medical (and appropriate non-medical) applications. Data capture means produces a point cloud representing the three-dimensional surface of an object (e.g., dental arch). Three-dimensional recognition objects are provided, particularly within those areas in the image field that have low image definition, and particularly in such of these areas that appear in overlapping portions of at least two images, to provide the three-dimensional image processing software with position, angulation, and orientation information sufficient to enable highly accurate combining (or “stitching”) of adjoining and overlapping images. Alignment, and creation of aligned related objects or models thereof, such as maxillar and mandibular arches, is facilitated.

Abstract: A three-dimensional-based modeling method and system designed for dentistry and related medical (and appropriate non-medical) applications. Data capture means produces a point cloud representing the three-dimensional surface of an object (e.g., dental arch). Three-dimensional recognition objects are provided, particularly within those areas in the image field that have low image definition, and particularly in such of these areas that appear in overlapping portions of at least two images, to provide the three-dimensional image processing software with position, angulation, and orientation information sufficient to enable highly accurate combining (or “stitching”) of adjoining and overlapping images. Alignment, and creation of aligned related objects or models thereof, such as maxillar and mandibular arches, is facilitated.