Abstract: Described here are systems and method for using ultrasound to localize a medical device to which an active ultrasound element that can transmits ultrasound energy is attached. Doppler signal data of the medical device are acquired while the active element is transmitting acoustic energy, and the Doppler signal data are processed to detect symmetric Doppler shifts associated with the active element. The systems and methods described in the present disclosure enable tracking and display of one or more locations on or associated with the medical device.

Abstract: Described here are systems and methods for quantifying vessel features in non-contrast microvasculature images obtained with an ultrasound imaging system. Vessel features that are quantified include, but are not limited to, vessel structure features (e.g., number of vessels, vessel density, number of branch points), vessel diameter, and vessel tortuosity. Morphological filtering is used to generate vessel segments from which the quantitative vessel features can be reliably quantified.

Abstract: Described here are systems and methods for generating microvessel images from image data acquired with an ultrasound system while analyzing the image data in real-time, or retrospectively, to generate a performance descriptor that can be used to assess data quality and/or motion correction quality; to adaptively suppress noise in the data; or both.

Abstract: Systems and methods for reconstructing, estimating, or otherwise generating unacquired, undetected, unreconstructed, or otherwise unknown ultrasound data using machine learning algorithms are provided. Thus, the systems and methods described in the present disclosure provide for generating unacquired, undetected, unreconstructed, or otherwise unknown data that are not actually and physically acquired with an ultrasound transducer and/or front-end receiver of an ultrasound system.

Abstract: Described here are systems and methods for generating microvessel images from image data acquired with an ultrasound system while analyzing the image data in realtime, or retrospectively, to generate a performance descriptor that can be used to assess data quality and/or motion correction quality; to adaptively suppress noise in the data; or both.

Abstract: The present disclosure addresses a quantitative analysis of tumor vascularity patterns, with the goal of identifying biomarkers correlated with malignancy. Herein, we identify new types of quantitative ultrasound biomarkers of microvessel morphology that correlate with the state of the disease in question. We propose a novel method to automatically extract quantitative features related to the morphology and distribution of the vascular networks reconstructed from contrast-free ultrasound data. For instance, spatial vascularity pattern, bifurcation angle, Murray's deviation, fractal dimension and closet vessel distance were clearly depicted.

Abstract: Systems and methods are provided for a mechanical analysis for determining a kinetic value, such as pressure, from ultrasonically measured Lamb wave speed in a pressurized biological compartment. Acoustoclastic analysis of Lamb waves may be used to determine pressure in a biological compartment, such as with a spherical pressure-vessel analysis. Non-invasive pressure estimation is provided in biological compartments which is relevant to a range of biological structures.

Abstract: Ultrasound systems and methods are provided using mass characterization frequency methods that provide for predicting benign or malignant lesions, a response to treatment, tumor grading, and/or the expressions of immunohistochemical biomarkers, which are currently used for breast cancer classification and hormone therapy determination. The systems and methods are based on the shear wave parameter, mass characteristic frequency. The status of malignancy, treatment response, grade, and/or each immunohistochemical biomarker may be determined based on a corresponding mass characteristic frequency threshold.

Abstract: Described here are systems and methods for generating microvessel images from image data acquired with an ultrasound system while analyzing the image data in real-time, or retrospectively, to adaptively suppress noise in the data.

Abstract: System and method configured to characterize viscoelasticity of a target medium by directly determining phase difference between real and imaginary parts of the complex shear modulus of the tissue (determined as a result of applying a compression force to the tissue), without any fitting of data and independent from distribution of strain in the tissue caused by the application of compression force.

Abstract: Systems and methods for determining viscoelasticity of curved tissue walls using ultrasound bladder vibrometry (UBV) to determine detrusor overactivity are provided. The UBV is a non-invasive technique utilizing, in a specific case, a focused ultrasound radiation force to excite Lamb waves in a curved bladder wall and pulse-echo techniques to track the tissue deformation propagating through such curved wall.

Abstract: Described here are systems and methods for generating images from image data acquired with an ultrasound system while analyzing the image data in real-time, or retrospectively, to generate a performance descriptor that can be used to assess a motion correction quality.

Abstract: Described here are systems and method for using ultrasound to localize a medical device to which an active ultrasound element that can transmits ultrasound energy is attached. Doppler signal data of the medical device are acquired while the active element is transmitting acoustic energy, and the Doppler signal data are processed to detect symmetric Doppler shifts associated with the active element. The systems and methods described in the present disclosure enable tracking and display of one or more locations on or associated with the medical device.

Abstract: Methods and systems for producing a visually-perceived representation of a sub-millimeter-sized blood vessel located at a depth of many centimeters in the biological tissue, in which the background clutter is suppressed (by at least 30 dB using SVT and additional 23 dB using a combination of morphology filtering and vessel enhancement filtering) as compared to an image obtained with the use of a B-mode ultrasound imaging, while at the same time maintaining the morphology of the blood vessel.

Abstract: Described here are systems and method for using ultrasound to localize a medical device to which an active ultrasound element that can transmits ultrasound energy is attached. Doppler signal data of the medical device are acquired while the active element is transmitting acoustic energy, and the Doppler signal data are processed to detect symmetric Doppler shifts associated with the active element. The systems and methods described in the present disclosure enable tracking and display of one or more locations on or associated with the medical device.

Abstract: Ultrasound systems and methods are provided using mass characterization frequency methods that provide for predicting benign or malignant lesions, a response to treatment, tumor grading, and/or the expressions of immunohistochemical biomarkers, which are currently used for breast cancer classification and hormone therapy determination. The systems and methods are based on the shear wave parameter, mass characteristic frequency. The status of malignancy, treatment response, grade, and/or each immunohistochemical biomarker may be determined based on a corresponding mass characteristic frequency threshold.

Abstract: Systems and methods are provided for suppressing the side-lobe artifacts in ultrasound imaging with plane wave compounding. The use of discrete angles in transmitting plane waves may be used to suppress side-lobes and the resulting side-lobe artifacts without increasing the number of firings required. A method is provided that utilizes nulls in Rx beam pattern to suppress side-lobes based on the beam pattern formula. An apodization technique that uses window functions according to Tx angles and/or Rx aperture may also be used. A method using aperiodic sampling angles may also be used to suppress artifacts. Application to arbitrary interval sampling angles may be found. Suppressing artifacts according to the present disclosure may provide for wider field of view imaging without resorting to increasing the number of firings required (NFR).

Abstract: Methods and systems for producing a visually-perceived representation of a sub-millimeter-sized blood vessel located at a depth of many centimeters in the biological tissue, in which the background clutter is suppressed (by at least 30 dB using SVT and additional 23 dB using a combination of morphology filtering and vessel enhancement filtering) as compared to an image obtained with the use of a B-mode ultrasound imaging, while at the same time maintaining the morphology of the blood vessel.

Abstract: Described here are systems and methods for generating microvessel images from image data acquired with an ultrasound system while analyzing the image data in realtime, or retrospectively, to generate a performance descriptor that can be used to assess data quality and/or motion correction quality; to adaptively suppress noise in the data; or both.

Abstract: The present disclosure addresses a quantitative analysis of tumor vascularity patterns, with the goal of identifying biomarkers correlated with malignancy. Herein, we identify new types of quantitative ultrasound biomarkers of microvessel morphology that correlate with the state of the disease in question. We propose a novel method to automatically extract quantitative features related to the morphology and distribution of the vascular networks reconstructed from contrast-free ultrasound data. For instance, spatial vascularity pattern, bifurcation angle, Murray's deviation, fractal dimension and closet vessel distance were clearly depicted.