Abstract: Systems and methods for visualizing microbubbles for contrast-enhanced imaging are described herein. Microbubbles may be visualized by multi-pixel spots by identifying and localizing individual microbubbles. Motion compensation may be provided for localized microbubbles or for contrast images prior to microbubble identification and localization. Users may determine the size of the multi-pixel spot by adjusting a filter, for example, adjusting a threshold value of the filter. Altering the size of the multi-pixel spot may alter the resolution. As the number of pixels increases, the resolution decreases, but the acquisition time may also decrease. As the number of pixels decreases, the resolution increases, but the acquisition time may increase.

Abstract: The present disclosure describes imaging systems configured to generate index information to indicate which image frames in a plurality of image frames include one or more target anatomical features, such as a head or femur of a fetus. The confidence levels of the presence of the target anatomical features are also determined. The system may be configured to determine if the target anatomical feature is present in an image frame by implementing at least one neural network. Merit levels based on the quality of the image frames may also be determined. Measurements of the one or more items of interest may be acquired. Visual representations (500) of the index information (502), confidence levels, merit levels, and/or measurements may be provided via a user interface. A user interface may receive user inputs based on the visual representations to navigate to specific image frames (508) of the plurality of image frames.

Abstract: The present disclosure describes ultrasound systems configured to enhance flow imaging and analysis by adaptively adjusting one or more imaging parameters in response to acquired flow measurements. Example systems can include an ultrasound transducer and one or more processors. Using the system components, mean flow velocity magnitude and acceleration can be determined within a target region during an acquisition phase, which may include a cardiac cycle. One or more adjusted flow imaging parameters, such as adjusted ensemble length, temporal smoothing filter length and/or step size, can be determined based on the acquired flow measurements to increase the signal quality of newly acquired ultrasound echo signals. The adjusted flow imaging parameters can then be applied by the ultrasound transducer during a second acquisition phase.

Abstract: An ultrasound system produces persisted images in response to both persistence coefficients and noise bias coefficients. The persistence coefficients control the degree of persistence, which reduces noise variance by persistence processing. The noise bias coefficients are produced in correspondence with the likelihood that an image pixel is noise, and operate to reduce the noise floor of the persisted images. A single user control enables a user to control both the noise variance and the noise level of images in tandem or, alternatively, dedicated controls can become available to adjust noise variance and noise level separately.

Abstract: An ultrasound imaging system for needle insertion guidance uses a curved array transducer to scan an image field with unsteered beams as a needle is inserted into the image field. Due to differences in the angle of incidence between the radially directed beams and the needle, echoes will return most strongly from only a section of the needle. This section is identified in an image, and the angle of incidence producing the strongest returns is identified. Beams with this optimal angle of incidence are then steered in parallel from the curved array transducer to produce the best needle image. The steep steering angles of some of the steered beams can give rise to side lobe clutter artifacts, which can be identified and removed from the image data using dual apodization processing of the image data.

Abstract: A method for performing shear wave elastography imaging of an observation field in a medium, the method comprising a plurality of shear wave imaging steps (30) to acquire a plurality of sets of shear wave propagation parameters, the method further comprising a reliability indicator determining step (40) during which a reliability indicator of the shear wave elastography imaging of the observation field is determined.

Abstract: A method for performing shear wave elastography imaging of an observation field in a medium, the method including shear wave imaging steps to acquire sets of shear wave propagation parameters, the method further including a reliability indicator determining step during which a reliability indicator of the shear wave elastography imaging of the observation field is determined.

Abstract: An ultrasound system performs duplex colorflow and spectral Doppler imaging, with the spectral Doppler interrogation performed at a sample volume location shown on the colorflow image. The colorflow image is displayed in a color box overlaid on a co-registered B mode image. A color box position and steering angle processor analyzes the spatial Doppler data and automatically sets the color box angle and location over a blood vessel for optimal Doppler sensitivity and accuracy. The processor may also automatically set the flow angle correction cursor in alignment with the direction of flow. In a preferred embodiment these optimization adjustments are made automatically and continuously as a user pauses at points for Doppler measurements along a length of the blood vessel.

Abstract: An ultrasound system performs duplex colorflow and spectral Doppler imaging, with the spectral Doppler interrogation performed at a sample volume location shown on the colorflow image. The colorflow image is displayed in a color box overlaid on a co-registered B mode image. A color box position and steering angle processor analyzes the spatial Doppler data and automatically sets the color box angle and location over a blood vessel for optimal Doppler sensitivity and accuracy. The processor may also automatically set the flow angle correction cursor in alignment with the direction of flow. In a preferred embodiment these optimization adjustments are made automatically and continuously as a user pauses at points for Doppler measurements along a length of the blood vessel.

Abstract: An ultrasound system performs duplex colorflow and spectral Doppler imaging, with the spectral Doppler interrogation performed at a sample volume location shown on the colorflow image. The colorflow image is displayed in a color box overlaid on a co-registered B mode image. A color box position and steering angle processor analyzes the spatial Doppler data and automatically sets the color box angle and location over a blood vessel for optimal Doppler sensitivity and accuracy. The processor may also automatically set the flow angle correction cursor in alignment with the direction of flow. In a preferred embodiment these optimization adjustments are made automatically and continuously as a user pauses at points for Doppler measurements along a length of the blood vessel.

Abstract: A method for performing shear wave elastography imaging of an observation field in a medium, the method including shear wave imaging steps to acquire sets of shear wave propagation parameters, the method further including a reliability indicator determining step during which a reliability indicator of the shear wave elastography imaging of the observation field is determined.

Abstract: In a medical diagnostic imaging system, a method for adjusting image gain compensation during a transition from a first imaging state to a second imaging state, including the steps of determining a first image power value based an image acquired in a first imaging state with a first image gain compensation; determining a second image power value based on an image acquired in a second imaging state with an initial second image gain compensation; determining an image power change value based on the first image power value and the second image power value; and determining an adjusted second image gain compensation based on the initial second image gain compensation and the image power change value.

Abstract: An ultrasound system performs duplex colorflow and spectral Doppler imaging, with the spectral Doppler interrogation performed at a sample volume location shown on the colorflow image. The colorflow image is displayed in a color box overlaid on a co-registered B mode image. A color box position and steering angle processor analyzes the spatial Doppler data and automatically sets the color box angle and location over a blood vessel for optimal Doppler sensitivity and accuracy. The processor may also automatically set the flow angle correction cursor in alignment with the direction of flow. In a preferred embodiment these optimization adjustments are made automatically and continuously as a user pauses at points for Doppler measurements along a length of the blood vessel.

Abstract: An ultrasound system performs duplex colorflow and spectral Doppler imaging, with the spectral Doppler interrogation performed at a sample volume location shown on the colorflow image. The colorflow image is displayed in a color box overlaid on a co-registered B mode image. A color box position and steering angle processor analyzes the spatial Doppler data and automatically sets the color box angle and location over a blood vessel for optimal Doppler sensitivity and accuracy. The processor may also automatically set the flow angle correction cursor in alignment with the direction of flow. In a preferred embodiment these optimization adjustments are made automatically and continuously as a user pauses at points for Doppler measurements along a length of the blood vessel.

Abstract: An ultrasonic diagnostic imaging system and method are described by which a user can delineate a region of interest (122, 128) in a colorflow Doppler image. The ultrasound system processes the Doppler pixel information of the region of interest (122, 128) to produce a spectrogram illustrating motion at the region of interest (122, 128) as a function of time. In a preferred embodiment the Doppler pixel information is processed by histograms to produce the spectrogram data.

Abstract: A method for automatic gain adjustment in spectral (pulsed wave—PW, and/or continuous wave—CW) Doppler for medical ultrasound includes separating a two-dimensional (2D) array of spectral levels (spectrogram) to be analyzed into signal and noise subsets. For each of the signal and noise subsets, a delta gain is calculated for achieving a predetermined display-based design specification. Subsequently, the separate signal and noise delta gains are combined into a single delta gain value, which is then applied to subsequent spectral Doppler signals or the spectrogram data stored in image memory, depending on whether the spectral Doppler mode is in a live or frozen state.

Abstract: An ultrasound imaging system comprising: a probe (10) with an array of transducer elements (12) for acquiring ultrasound data of a body, including moving tissue and fluid flow; a beamforming system (10, 12, 14, 16) for emitting and receiving ultrasound beams in said body, which uses, for each transmission beam, an ensemble length of more than two temporal samples and less than eight; processing means (40, 50) to process flow Doppler signals comprising adaptive clutter demodulation (21) applied on amplitude signals and mean clutter demodulation applied on phase signals followed by high-pass filtering (22, 32); and display means (55,70) to display images based on said processed flow Doppler signals.

Abstract: An ultrasonic diagnostic imaging system and method are described by which a user can delineate a region of interest (122, 128) in a colorflow Doppler image. The ultrasound system processes the Doppler pixel information of the region of interest (122, 128) to produce a spectrogram illustrating motion at the region of interest (122, 128) as a function of time. In a preferred embodiment the Doppler pixel information is processed by histograms to produce the spectrogram data.

Abstract: An ultrasonic diagnostic imaging system and method are described which perform spatial compounding of tissue motion or flow information. The resultant images not only reduce speckle artifacts, but also reduce dropout caused by the angular dependence of Doppler information. Compound images may be formed using both B mode and Doppler information acquired in a time interleaved manner, either one or both of which may be spatially compounded. The techniques of the present invention may be employed to reduce multiline artifacts and to produce real time compound images at high frame rates of display.

Abstract: Multi-mode ultrasonic images are formed by processing the ultrasonic echoes from a single transmit pulse in parallel to display both tissue and motion. In a preferred embodiment short transmit bursts are employed to produce echo ensembles for tissue motion imaging. At least one sequence of echoes of the ensemble is also B mode processed for display of tissue structure. Preferably both the B mode and motion processing are performed in parallel. A substantially constant pulse repetition frequency reduces artifact development when imaging in the two modes from the same transmit pulse.