Abstract: Methods and systems are provided herein for displaying annotation panels in a medical imaging graphical user interface (GUI). In one example, a computing device comprising a display screen, the computing device being configured to display on the display screen a plurality of viewports within a GUI, each of the plurality of viewports displaying a respective medical image of a patient, and additionally being configured to display within the GUI one or more annotation icons and one or more annotation panels, the one or more annotation panels accessible directly from the one or more annotation icons and configured to display annotation data as a list of one or more annotations, wherein the each of the one or more annotation panels corresponds to a respective viewport of the GUI, and wherein the one or more annotation icons are displayed with the annotation data in an unlaunched state.

Abstract: A system may include a processor-based device storing or accessing an image review application, which when executed by the processor-based device, causes acts to be performed such as retrieving image data for populating a graphical user interface displayed on the processor-based device and receiving a user input selecting a workflow tool and a sampling tool. The sampling tool, when executed by the processor-based device, may also receiving an additional user input of a region of interest within the image data, determining values for a parameter of interest based on the pixels within the region of interest, automatically configuring the workflow tool based on the determined values for the parameter of interest, and generating preset parameters of the workflow tool. The image review application may also adjust the display of the image data on the GUI using the configured workflow tool.

Abstract: Various methods and systems are provided for a user interface of a medical imaging system. In one embodiment, a method may include displaying a slider bar comprising a track having a fixed range of values, a first slider thumb defining a maximum value of a first adjustable range on the track, and a second slider thumb defining a minimum value of a second adjustable range on the track; operating the first slider thumb and the second slider thumb in one of a linked mode and an unlinked mode; and adjusting one or both of the maximum value of the first adjustable range and the minimum value of the second adjustable range in response to receiving a single user input based on whether the first slider thumb and the second slider thumb are operating in the linked mode or the unlinked mode.

Abstract: Methods, apparatus, systems and articles of manufacture are disclosed to enable medical image visualization and interaction in a virtual environment. An example apparatus includes at least one processor and at least one memory including instructions. The instructions, when executed, cause the at least one processor to at least: generate a virtual environment for display of image content via a virtual reality display device; enable interaction with the image content in the virtual environment via an avatar; adjust the image content in the virtual environment based on the interaction; and generate an output of image content from the virtual environment.

Abstract: Methods, apparatus, systems and articles of manufacture are disclosed to enable medical image visualization and interaction in a virtual environment. An example apparatus includes at least one processor and at least one memory including instructions. The instructions, when executed, cause the at least one processor to at least: generate a virtual environment for display of image content via a virtual reality display device; enable interaction with the image content in the virtual environment via an avatar; adjust the image content in the virtual environment based on the interaction; and generate an output of image content from the virtual environment.

Abstract: Systems and methods are provided for automatically generating a three-dimensional (3D) polygonal model with color mapping from a volume rendering. The method includes generating a volume rendering from volumetric data. The method includes receiving a user selection to launch model and color generation. The method includes automatically generating a 3D mask from the volume rendering by segmenting at least one object in the volume rendering in response to the user selection. The method includes automatically generating a 3D mesh for the at least one object based on the 3D mask in response to the user selection. The method includes automatically computing mesh colors based on the volume rendering in response to the user selection. The mesh colors are applied to the 3D mesh to generate a multi-color 3D polygonal model. The method includes automatically outputting the multi-color 3D polygonal model in response to the user selection.

Abstract: Methods, apparatus, systems and articles of manufacture are disclosed to enable medical image visualization and interaction in a virtual environment. An example apparatus includes at least one processor and at least one memory including instructions. The instructions, when executed, cause the at least one processor to at least: generate a virtual environment for display of image content via a virtual reality display device, the image content to include a two-dimensional image overlaid on a three-dimensional volume; enable interaction with the image content in the virtual environment via an avatar, movement of the avatar to be correlated with an external input; adjust the image content in the virtual environment based on the interaction; and generate an output of image content from the virtual environment.

Abstract: Systems and methods are provided for three-dimensional (3D) printing with three-dimensional (3D) model cuts based on anatomy, in particular during medical imaging operations.

Abstract: Systems and methods are provided for automatically generating a three-dimensional (3D) polygonal model with color mapping from a volume rendering. The method includes generating a volume rendering from volumetric data. The method includes receiving a user selection to launch model and color generation. The method includes automatically generating a 3D mask from the volume rendering by segmenting at least one object in the volume rendering in response to the user selection. The method includes automatically generating a 3D mesh for the at least one object based on the 3D mask in response to the user selection. The method includes automatically computing mesh colors based on the volume rendering in response to the user selection. The mesh colors are applied to the 3D mesh to generate a multi-color 3D polygonal model. The method includes automatically outputting the multi-color 3D polygonal model in response to the user selection.

Abstract: Methods, apparatus, systems and articles of manufacture are disclosed to enable medical image visualization and interaction in a virtual environment. An example apparatus includes at least one processor and at least one memory including instructions. The instructions, when executed, cause the at least one processor to at least: generate a virtual environment for display of image content via a virtual reality display device, the image content to include a two-dimensional image overlaid on a three-dimensional volume; enable interaction with the image content in the virtual environment via an avatar, movement of the avatar to be correlated with an external input; adjust the image content in the virtual environment based on the interaction; and generate an output of image content from the virtual environment.