Abstract: Systems and methods are disclosed for an ultrasound system. In various embodiments, a system is configured to receive echo data corresponding to a detection of an echo of a pulse signal, generate a set of transformations based on the echo data, and generate a set of point estimates for a frequency dependent filtering coefficient of a spectral response. The system is further configured to extract a set of attenuation coefficients based on the set of point estimates for the frequency dependent filtering coefficient and generate image data for the material of interest based on the set of attenuation coefficients.

Abstract: A hierarchical workflow is configured to associate examination information captured using an imaging platform with contextual metadata. The examination information may include ultrasound image data, which may be associated with annotations, measurements, pathology, body markers, and/or the like. The hierarchical workflow may comprise templates associated with respective anatomical regions, locations, volumes, and/or surfaces. A template may define configuration data to automatically adapt the imaging platform to capture imaging data in the corresponding anatomical region. The template may further include guidance information for the operator, including processing steps for capturing relevant examination information. Additional examination information may be captured and included in the hierarchical workflow.

Abstract: Systems and methods are disclosed for remotely controlling a main processing console of an ultrasound system. In various embodiments, an ultrasound remote controller can be used to remotely control a main processing console of an ultrasound system. The ultrasound remote controller can include a user interface controller configured to provide one or more ultrasound control functions to a user remote from the main processing console. The control functions can be used to remotely control operation of the main console. Further, the user interface controller can be configured to receive input for the one or more ultrasound control functions from the user. The ultrasound remote controller can include a communication interface configured to transmit operational instructions to the main processing console for remotely controlling the operation of the main processing console through the ultrasound remote controller based on the user input for the one or more ultrasound control functions.

Abstract: The present disclosure provides systems and methods for predicting a disease state of a subject using ultrasound imaging and ancillary information to the ultrasound imaging. At least two quantitative measurements of a subject, including at least one measurement taken using ultrasound imaging, as part of quantified information can be identified. One of the quantitative measurements can be compared to a first predetermined standard, included as part of ancillary information to the quantified information, in order to identify a first initial value. Further, another of the quantitative measurements can be compared to a second predetermined standard, included as part of the ancillary information, in order to identify a second initial value. Subsequently, the quantitative information can be correlated with the ancillary information using the first initial value and the second initial value to determine a final value that is predictive of a disease state of the subject.

Abstract: The present disclosure provides systems and methods for receiving ultrasound image data corresponding to an ultrasound image with a master dynamic range and displaying a globally tone-mapped version of the ultrasound image on an electronic display. A region of interest (ROI) within the ultrasound image may be regionally tone mapped to provide an enhanced, optimized, and/or otherwise improved image of the ROI. The regional tone mapping may allow for features within the ROI to be more easily distinguishable that are not or at least not easily distinguishable in the global tone mapping of the same region.

Abstract: An ultrasonic imaging method includes activating a transmit aperture within a multi-element transducer array, transmitting one or more ultrasonic beams along scan direction(s) that span the region of interest, for each transmit event, receiving ultrasound echoes from each element of a receive aperture, grouping the receive channel echo data into two or more sets corresponding to different receive sub-apertures, combining each sub-aperture data set to generate partially focused echo-location data for one or more reconstruction lines, and storing all the sub-aperture echo data sets during a storage period in a format that can be retrieved for later analysis.

Abstract: An ultrasonic imaging method includes activating a transmit aperture within a multi-element transducer array, transmitting one or more ultrasonic beams along scan direction(s) that span the region of interest, for each transmit event, receiving ultrasound echoes from each element of a receive aperture, grouping the receive channel echo data into two or more sets corresponding to different receive sub-apertures, combining each sub-aperture data set to generate partially focused echo-location data for one or more reconstruction lines, and storing all the sub-aperture echo data sets during a storage period in a format that can be retrieved for later analysis.

Abstract: A restorative health and wellness system that provides an immersive environment is provided herein. In some embodiments, the system includes one or more sensors configured to measure physiological properties of an individual and/or the properties of the individual's surroundings, one or more actuators configured to create the immersive environment for the individual, a control loop module configured to receive and analyze input from the one or more sensors, and to provide information to the actuators to create the immersive environment for the individual, wherein the one or more actuators dynamically create or adjust the immersive environment based on at least one of (A) the physiological properties measured or (B) the properties of the individual's surroundings, and at least one of (A) a pre-determined individual priority balance set for the individual or (B) an optimized set of parameters determined through advanced analytic techniques.

Abstract: The present disclosure provides systems and methods for receiving ultrasound image data corresponding to an ultrasound image with a master dynamic range and displaying a globally tone-mapped version of the ultrasound image on an electronic display. A region of interest (ROI) within the ultrasound image may be regionally tone mapped to provide an enhanced, optimized, and/or otherwise improved image of the ROI. The regional tone mapping may allow for features within the ROI to be more easily distinguishable that are not or at least not easily distinguishable in the global tone mapping of the same region.

Abstract: The present disclosure provides systems and methods for receiving ultrasound image data corresponding to an ultrasound image with a master dynamic range and displaying a globally tone-mapped version of the ultrasound image on an electronic display. A region of interest (ROI) within the ultrasound image may be regionally tone mapped to provide an enhanced, optimized, and/or otherwise improved image of the ROI. The regional tone mapping may allow for features within the ROI to be more easily distinguishable that are not or at least not easily distinguishable in the global tone mapping of the same region.

Abstract: Embodiments of the present invention provide an ultrasound scanner equipped with an image data processing unit that can perform adaptive parameter optimization during image formation and processing. In one embodiment, an ultrasound system comprises a channel data memory to store channel data obtained by digitizing ultrasound image data produced by an image scan; an image data processor configured to process the stored channel data in the memory to reconstruct an ultrasound image for each of a plurality of trial values of at least one parameter to be optimized; and a parameter optimization unit configured to evaluate an image quality of the reconstructed ultrasound image for each trial value of the at least one parameter, and to determine the optimized value of the at least one parameter based on the evaluated image quality.

Abstract: A hierarchical workflow is configured to associate examination information captured using an imaging platform with contextual metadata. The examination information may include ultrasound image data, which may be associated with annotations, measurements, pathology, body markers, and/or the like. The hierarchical workflow may comprise templates associated with respective anatomical regions, locations, volumes, and/or surfaces. A template may define configuration data to automatically adapt the imaging platform to capture imaging data in the corresponding anatomical region. The template may further include guidance information for the operator, including processing steps for capturing relevant examination information. Additional examination information may be captured and included in the hierarchical workflow.

Abstract: The present disclosure provides systems and methods for receiving ultrasound image data corresponding to an ultrasound image with a master dynamic range and displaying a globally tone-mapped version of the ultrasound image on an electronic display. A region of interest (ROI) within the ultrasound image may be regionally tone mapped to provide an enhanced, optimized, and/or otherwise improved image of the ROI. The regional tone mapping may allow for features within the ROI to be more easily distinguishable that are not or at least not easily distinguishable in the global tone mapping of the same region.

Abstract: The present disclosure provides systems and methods for receiving ultrasound image data corresponding to an ultrasound image with a master dynamic range and displaying a globally tone-mapped version of the ultrasound image on an electronic display. A region of interest (ROI) within the ultrasound image may be regionally tone mapped to provide an enhanced, optimized, and/or otherwise improved image of the ROI. The regional tone mapping may allow for features within the ROI to be more easily distinguishable that are not or at least not easily distinguishable in the global tone mapping of the same region.

Abstract: An ultrasonic imaging method includes activating a transmit aperture within a multi-element transducer array, transmitting one or more ultrasonic beams along scan direction(s) that span the region of interest, for each transmit event, receiving ultrasound echoes from each element of a receive aperture, grouping the receive channel echo data into two or more sets corresponding to different receive sub-apertures, combining each sub-aperture data set to generate partially focused echo-location data for one or more reconstruction lines, and storing all the sub-aperture echo data sets during a storage period in a format that can be retrieved for later analysis.

Abstract: Methods of probing a material under investigation using an ultrasound beam. Echolocation data is generated using a multi-dimensional transform capable of using phase and magnitude information to distinguish echoes resulting from ultrasound beam components produced using different ultrasound transducers. Since the multi-dimensional transform does not depend on using receive or transmit beam lines, a multi-dimensional area can be imaged using a single ultrasound transmission. In some embodiments, this ability increases image frame rate and reduces the amount of ultrasound energy required to generate an image.

Abstract: The present disclosure provides systems and methods for receiving ultrasound image data corresponding to an ultrasound image with a master dynamic range and displaying a globally tone-mapped version of the ultrasound image on an electronic display. A region of interest (ROI) within the ultrasound image may be regionally tone mapped to provide an enhanced, optimized, and/or otherwise improved image of the ROI. The regional tone mapping may allow for features within the ROI to be more easily distinguishable that are not or at least not easily distinguishable in the global tone mapping of the same region.

Abstract: An ultrasound imaging method comprises: providing a probe that includes one or more transducer elements for transmitting and receiving ultrasound waves; generating a sequence of spatially distinct transmit beams which differ in one or more of origin and angle; determining a transmit beam spacing substantially based upon a combination of actual and desired transmit beam characteristics, thereby achieving a faster echo acquisition rate compared to a transmit beam spacing based upon round-trip transmit-receive beam sampling requirements; storing coherent receive echo data, from two or more transmit beams of the spatially distinct transmit beams; combining coherent receive echo data from at least two or more transmit beams to achieve a substantially spatially invariant synthesized transmit focus at each echo location; and combining coherent receive echo data from each transmit firing to achieve dynamic receive focusing at each echo location.

Abstract: An ultrasonic imaging method includes activating a transmit aperture within a multi-element transducer array, transmitting one or more ultrasonic beams along scan direction(s) that span the region of interest, for each transmit event, receiving ultrasound echoes from each element of a receive aperture, grouping the receive channel echo data into two or more sets corresponding to different receive sub-apertures, combining each sub-aperture data set to generate partially focused echo-location data for one or more reconstruction lines, and storing all the sub-aperture echo data sets during a storage period in a format that can be retrieved for later analysis.

Abstract: Embodiments of the present invention provide an ultrasound scanner equipped with an image data processing unit that can perform adaptive parameter optimization during image formation and processing. In one embodiment, an ultrasound system comprises a channel data memory to store channel data obtained by digitizing ultrasound image data produced by an image scan; an image data processor configured to process the stored channel data in the memory to reconstruct an ultrasound image for each of a plurality of trial values of at least one parameter to be optimized; and a parameter optimization unit configured to evaluate an image quality of the reconstructed ultrasound image for each trial value of the at least one parameter, and to determine the optimized value of the at least one parameter based on the evaluated image quality.