Abstract: Systems and graphical user interfaces for analyzing body images. In an exemplary embodiment, the present invention provides a graphical user interface having a display coupled to a microprocessing device and a memory device. The graphical user interface has an electronic representation of a first body image and a second body image and an electronic map representing the position of nodules on the first body image and second body image.

Abstract: Systems and graphical user interfaces for analyzing body images. In an exemplary embodiment, the present invention provides a graphical user interface having a display coupled to a microprocessing device and a memory device. The graphical user interface has an electronic representation of a first body image and a second body image and an electronic map representing the position of nodules on the first body image and second body image.

Abstract: Methods and systems for remotely monitoring an imaging facility's compliance with accreditation requirements. In a particular embodiment, the present invention remotely monitors the status of an MRI facility. In some configurations, the MRI unit is coupled to a server station. Information from the MRI unit is transmitted and stored on the server station. The information can be transmitted over a network, such as the internet, to a remote server. The remote server can collect and evaluate the accreditation data.

Abstract: Software, methods and user interfaces for viewing and generating a lung report. In exemplary methods, a first baseline image is analyzed to localize lung nodules. The lung nodule information can be stored and used to relocate the previously localized lung nodules in a second, follow-up imaging scan. The follow-up scan can be analyzed—either manually or automatically—to generate statistics for the lung nodules localized in the follow-up scan. Information derived from the baseline scan can be used to ease the localization of the lung nodules in the follow-up scan. In some exemplary methods, both the baseline scan and follow-up scan are displayed and the nodules are selected for comparison. Typically, the graphical user interface can display a third, composite image that displays the change of size of the nodules.

Abstract: Software, methods and user interfaces for viewing and generating a lung report. In exemplary methods, a first baseline image is analyzed to localize lung nodules. The lung nodule information can be stored and used to relocate the previously localized lung nodules in a second, follow-up imaging scan. The follow-up scan can be analyzed—either manually or automatically—to generate statistics for the lung nodules localized in the follow-up scan. Information derived from the baseline scan can be used to ease the localization of the lung nodules in the follow-up scan. In some exemplary methods, both the baseline scan and follow-up scan are displayed and the nodules are selected for comparison. Typically, the graphical user interface can display a third, composite image that displays the change of size of the nodules.

Abstract: The present invention provides methods, databases, and software code for generating a customizable body report. The software allows an operator to customize a report layout and to customize a decision tree or logic steps that allow the operator to specify what fixed information and patient information can be incorporated into the body report. Exemplary methods are for customizing a lung report.

Abstract: Systems and graphical user interfaces for analyzing body images. In an exemplary embodiment, the present invention provides a graphical user interface having a display coupled to a microprocessing device and a memory device. The graphical user interface has an electronic representation of a first body image and a second body image and an electronic map representing the position of nodules on the first body image and second body image.

Abstract: Software, methods and user interfaces for viewing and generating a lung report. In exemplary methods, a first baseline image is analyzed to localize lung nodules. The lung nodule information can be stored and used to relocate the previously localized lung nodules in a second, follow-up imaging scan. The follow-up scan can be analyzed—either manually or automatically—to generate statistics for the lung nodules localized in the follow-up scan. Information derived from the baseline scan can be used to ease the localization of the lung nodules in the follow-up scan. In some exemplary methods, both the baseline scan and follow-up scan are displayed and the nodules are selected for comparison. Typically, the graphical user interface can display a third, composite image that displays the change of size of the nodules.

Abstract: Methods and systems for remotely monitoring an imaging facility's compliance with accreditation requirements. In a particular embodiment, the present invention remotely monitors the status of an MRI facility. In some configurations, the MRI unit is coupled to a server station. Information from the MRI unit is transmitted and stored on the server station. The information can be transmitted over a network, such as the internet, to a remote server. The remote server can collect and evaluate the accreditation data.