Abstract: Various embodiments include systems and methods for utilizing depth from ultrasound volume rendering for 3D printing. Volumetric ultrasound dataset may be generated, based on echo ultrasound signals, and one or more volume rendered ultrasound images, based on the volumetric ultrasound dataset, may be displayed. Based on the one or more volume rendered ultrasound images and/or the volumetric ultrasound dataset, three-dimensional (3D) printing data may be generated. The 3D printing data may be configured to enable producing, via a 3D printer, a physical volume representation of one or more objects and/or structures in the one or more volume rendered ultrasound images. The 3D printing data may be based on 3D modeling of at least a portion of at least one of the one or more volume rendered ultrasound images. The 3D modeling may comprise a surface mesh representation.

Abstract: An ultrasound imaging system and method includes accessing a graphical model of a representative patient, accessing a medical image of an anatomical structure, and registering the medical image with the graphical model to generate a composite image. The imaging system and method includes displaying the composite image and simultaneously displaying an unregistered medical image of the anatomical structure with the composite image. The unregistered medical image has at least one of a higher resolution and a larger form factor than the registered medical image.

Abstract: Various embodiments include systems and methods for utilizing depth from ultrasound volume rendering for 3D printing. Volumetric ultrasound dataset may be generated, based on echo ultrasound signals, and one or more volume rendered ultrasound images, based on the volumetric ultrasound dataset, may be displayed. Based on the one or more volume rendered ultrasound images and/or the volumetric ultrasound dataset, three-dimensional (3D) printing data may be generated. The 3D printing data may be configured to enable producing, via a 3D printer, a physical volume representation of one or more objects and/or structures in the one or more volume rendered ultrasound images. The 3D printing data may be based on 3D modeling of at least a portion of at least one of the one or more volume rendered ultrasound images. The 3D modeling may comprise a surface mesh representation.

Abstract: Various embodiments include systems and methods for utilizing depth from ultrasound volume rendering for 3D printing. Volumetric ultrasound dataset may be generated, based on echo ultrasound signals, and one or more volume rendered ultrasound images, based on the volumetric ultrasound dataset, may be displayed. Based on the one or more volume rendered ultrasound images and/or the volumetric ultrasound dataset, three-dimensional (3D) printing data may be generated. The 3D printing data may be configured to enable producing, via a 3D printer, a physical volume representation of one or more objects and/or structures in the one or more volume rendered ultrasound images. The 3D printing data may be based on 3D modeling of at least a portion of at least one of the one or more volume rendered ultrasound images. The 3D modeling may comprise a surface mesh representation.

Abstract: Systems and methods are provided for utilizing depth from volume rendering for 3D printing. Three-dimensional (3D) mesh data may be generated based on one or more volume rendered images and/or volumetric datasets corresponding thereto, obtained during medical imaging (e.g., based on echo ultrasound signals during ultrasound imaging). Generating the 3D mesh data may comprise computing a plurality of depth values, where each depth value corresponds to a particular voxel in the volumetric medical imaging datasets. The 3D mesh data may be configured to enable producing a physical volume representation of one or more objects and/or structures in the one or more volume rendered images. Thus, the 3D mesh data may be used for 3D printing. For example, 3D printing data may be generated based on the 3D mesh data. The 3D printing data may be configured and formatted based on a pre-defined 3D printing standard or file format.

Abstract: Various embodiments include systems and methods for utilizing depth from ultrasound volume rendering for 3D printing. Volumetric ultrasound dataset may be generated, based on echo ultrasound signals, and one or more volume rendered ultrasound images, based on the volumetric ultrasound dataset, may be displayed. Based on the one or more volume rendered ultrasound images and/or the volumetric ultrasound dataset, three-dimensional (3D) printing data may be generated. The 3D printing data may be configured to enable producing, via a 3D printer, a physical volume representation of one or more objects and/or structures in the one or more volume rendered ultrasound images. The 3D printing data may be based on 3D modeling of at least a portion of at least one of the one or more volume rendered ultrasound images. The 3D modeling may comprise a surface mesh representation.

Abstract: Systems and methods are provided for utilizing depth from volume rendering for 3D printing. Three-dimensional (3D) mesh data may be generated based on one or more volume rendered images and/or volumetric datasets corresponding thereto, obtained during medical imaging (e.g., based on echo ultrasound signals during ultrasound imaging). Generating the 3D mesh data may comprise computing a plurality of depth values, where each depth value corresponds to a particular voxel in the volumetric medical imaging datasets. The 3D mesh data may be configured to enable producing a physical volume representation of one or more objects and/or structures in the one or more volume rendered images. Thus, the 3D mesh data may be used for 3D printing. For example, 3D printing data may be generated based on the 3D mesh data. The 3D printing data may be configured and formatted based on a pre-defined 3D printing standard or file format.

Abstract: An ultrasound imaging system and method includes accessing a graphical model of a representative patient, accessing a medical image of an anatomical structure, and registering the medical image with the graphical model to generate a composite image. The imaging system and method includes displaying the composite image and simultaneously displaying an unregistered medical image of the anatomical structure with the composite image. The unregistered medical image has at least one of a higher resolution and a larger form factor than the registered medical image.

Abstract: A method and ultrasound imaging system for selecting an examination workflow for ultrasound imaging. The method and system include displaying a graphical model on a display device, selecting a modeled anatomical region in the graphical model that corresponds to an anatomical region in a patient. The method and system include automatically loading an examination workflow for the anatomical region, executing the examination workflow to acquire ultrasound data of the anatomical region, and generating and displaying a graphical output based on the ultrasound data on the display device.

Abstract: Methods and systems for displaying system parameter information are provided. One method includes determining a value for a system parameter using the ultrasound system and comparing the determined value to a defined value for a system processing guideline using a processor of the ultrasound system. The method further includes providing system parameter confirmation information based on the comparing when the determined value is not within the defined value.

Abstract: Methods and systems for displaying system parameter information are provided. One method includes determining a value for a system parameter using the ultrasound system and comparing the determined value to a defined value for a system processing guideline using a processor of the ultrasound system. The method further includes providing system parameter confirmation information based on the comparing when the determined value is not within the defined value.

Abstract: Method and apparatus for detecting a contour of an object within an image is provided. A user interface is used to select first and second points within the object. A processor detects first and second subcontours based on the first and second points, respectively; and the first and second subcontours are based on detected edges. The detected edges are representative of non-uniformities within the image. The processor defines subcontours around each of the points, and the subcontours are combined into a contour.

Abstract: A method and apparatus for performing multi-mode imaging are provided. The includes performing a first volume scan using a first mode to acquire a first data set and performing a second scan using a second mode to acquire a second data set. The first and second modes are different.

Abstract: Method and apparatus for detecting a contour of an object within an image is provided. A user interface is used to select first and second points within the object. A processor detects first and second subcontours based on the first and second points, respectively; and the first and second subcontours are based on detected edges. The detected edges are representative of non-uniformities within the image. The processor defines subcontours around each of the points, and the subcontours are combined into a contour.

Abstract: Method and apparatus for presenting multiple enhanced images of different anatomic features is provided. An ultrasonic volume data set having multiple anatomic features is acquired. Multiple enhanced images are presented simultaneously based on the multiple anatomic features within the data set.

Abstract: An object separating method separates a target object from an ultrasound image. Specifically, first of all, a set of two dimensional (2D) ultrasound images are combined to provide volume data. Then, a rotational axis to rotate the volume data and two points as reference points are set, wherein the two points are points where the rotational axis and the target object intersect. Thereafter, the volume data is rotated by a predetermined angle around the rotational axis to generate a 2D ultrasound image for each rotated angle, wherein the rotating process is repeatedly performed until the volume data is rotated by a preset angle. A contour of each 2D ultrasound image is extracted and vertices on the contour are set to thereby provide contours with vertices. The vertices of each of the contours are wired and processed to provide a 3D image of the target object.

Abstract: With a method for determination of the direction of introduction (4) and for controlling the introduction path of biopsy needles, probes and similar in organisms (2) by using an ultrasound imaging machine, a scanning unit (1) of the ultrasound is placed onto the introduction range of the organism (2) in order to display an image (3a) according to a sectional plane (3) in which or along which the directional axis (4) of the introduction path runs and the biopsy needle or similar is controlled during its actual introduction in the corresponding image display (3a, 6). For improvement of the accuracy of introduction and for an easier procedure a larger volume range (3) of the organism (2) is scanned by using a 3D-imaging and with a contingent interim storage of the derived signals by a volume storage the sectional plane (3a) to be displayed is selected according to predeterminable criteria from the volume (3), after which selection the intended introduction path (4) is virtually displayed in this image and an e.

Abstract: For that method to examine an object by using ultrasound waves a spatial region of the object is scanned by a 3D probe. From the reflected echo signals just signals are processed which fulfil certain selectable criteria and taken to display it according to their position on at least one display device. For the representation of one or more objects with one or more interesting layers the geometrical selection criterion is a shell which approximates a surface of the object or of a layer and which can have a certain thickness, and only signals which are selected by this shell will be processed and displayed. This results in a undisturbed representation of the object and allows better view to the characteristic of the surface regarding structure or perfusion.

Abstract: A method and systems for obtaining 2D ultrasound images. The methods may comprise the steps of receiving ultrasonic information from a volumetric region of a body, volume scan converting the ultrasonic information from the volumetric region for processing a rendering box, and volume rendering the rendering box for projecting the rendering box onto a 2D slice by using volume rendering techniques. The systems may comprise an ultrasonic transducer for receiving ultrasonic information from a volumetric region of a body, a volume scan converter for processing a rendering box obtained from the volumetric region, and a volume rendering processor for projecting the rendering box onto a 2D slice by using volume rendering techniques for contrast enhancement.

Abstract: The invention describes a procedure for the examination of objects by the means of ultrasound waves whereby a volume-of-interest is scanned by a 3D-ultrasound-probe by moving a transmitter/receiver beam in a scan plane within selectable limits. This B-mode scan plane is also simultaneously moved in a direction across to this scan plane. The transmitting of sound pulses and acquiring the echo-signals is done more or less continuously during the movement in B-plane and across to it The echo-signals are stored in a volume memory on addresses which correspond to the spatial position of the echo-generating structure inside the object. These stored data-sets are evaluated by a 3D-processor and are represented on at least one display unit by different algorithms with selectable parameters. Important is that the acquisition and the representation is done continuously.