Abstract: An ultrasound imaging apparatus configured with a touch screen display and computer aided measurement and/or diagnosis capability. In response to a touch input, image parameters for the computer aided measurement and/or diagnosis are determined from an analysis of the ultrasound image. A touch screen user interface allows the user to further adjust the parameters and/or other system parameters for the computer aided measurement and/or diagnosis in an interactive way. The computer aided measurement can be used directly for the computer aided diagnosis for improved accuracy and user experience.

Abstract: A modular, flexible architecture for offering full-field breast ultrasound (FFBU) functionality and general-purpose ultrasound functionality in a single system is described. A conventional, general-purpose ultrasound system (202) is modified with an FFBU toolkit to create a dual-capability ultrasound system (200), the dual-capability ultrasound system (200) being able to accommodate both general-purpose ultrasound functionality and FFBU functionality, using a single ultrasound engine (112). Among other advantages, real-world clinical environments may enjoy cost savings for initial system procurement, space savings on clinic floors, easier and less expensive system upgrades, and the ability to use a single system and user interface for both FFBU screening and for follow-up diagnosis, biopsy, etc.

Abstract: An ultrasound imaging apparatus configured with a touch screen display that includes an image area displaying at least a portion of an ultrasound image. The image area of the touch screen is configured to receive touch input. In response to the touch input, the ultrasound image can be adjusted, manipulated, edited, processed and/or measured. For example, certain properties of the ultrasound image can be quantified or determined, and used to intelligently identify a context-sensitive function to be invoked as a response to the touch input in the image area Thus, the control buttons in the control area can be simplified; and the user interface is more user friendly than a conventional user interface for ultrasound imaging.

Abstract: A modular, flexible architecture for offering full-field breast ultrasound (FFBU) functionality and general-purpose ultrasound functionality in a single system is described. A conventional, general-purpose ultrasound system (202) is modified with an FFBU toolkit to create a dual-capability ultrasound system (200), the dual-capability ultrasound system (200) being able to accommodate both general-purpose ultrasound functionality and FFBU functionality, using a single ultrasound engine (112). Among other advantages, real-world clinical environments may enjoy cost savings for initial system procurement, space savings on clinic floors, easier and less expensive system upgrades, and the ability to use a single system and user interface for both FFBU screening and for follow-up diagnosis, biopsy, etc.

Abstract: Image processing adapts to speckle. Speckle is identified from signal transitions. For example, peaks, valleys or mean crossings of image signals as a function of space or spatial location are identified. A speckle characteristic, such as speckle size, is estimated from the signal transitions. The estimation may be limited to soft tissue regions to reduce the effects of specular targets and noise on speckle estimation. The speckle is estimated for local regions or an entire image. By estimating speckle for local regions, image processing may account adaptively for regional variation in speckle size.

Abstract: A modular, flexible architecture for offering full-field breast ultrasound (FFBU) functionality and general-purpose ultrasound functionality in a single system is described. A conventional, general-purpose ultrasound system (202) is modified with an FFBU toolkit to create a dual-capability ultrasound system (200), the dual-capability ultrasound system (200) being able to accommodate both general-purpose ultrasound functionality and FFBU functionality, using a single ultrasound engine (112). Among other advantages, real-world clinical environments may enjoy cost savings for initial system procurement, space savings on clinic floors, easier and less expensive system upgrades, and the ability to use a single system and user interface for both FFBU screening and for follow-up diagnosis, biopsy, etc.

Abstract: Image processing adapts to speckle. Speckle is identified from signal transitions. For example, peaks, valleys or mean crossings of image signals as a function of space or spatial location are identified. A speckle characteristic, such as speckle size, is estimated from the signal transitions. The estimation may be limited to soft tissue regions to reduce the effects of specular targets and noise on speckle estimation. The speckle is estimated for local regions or an entire image. By estimating speckle for local regions, image processing may account adaptively for regional variation in speckle size.

Abstract: An SNR-adaptive method for processing a plurality of post-detection medical diagnostic ultrasonic images determines a cross-correlation parameter from corresponding multi-dimensional regions of first and second post-detection ultrasonic images, and then uses the cross-correlation parameter to suppress electronic noise in ultrasonic image processing. In some cases the multi-dimensional region of the first and second images are registered prior to cross-correlation to compensate for relative movement between the transducer and the imaged tissue between the first and second images.

Abstract: A medical diagnostic ultrasonic imaging system analyzes receive signals generated by the system to adaptively set the interline delay and/or the transmit power to optimize frame rate while reducing or eliminating the wraparound artifact associated with transmit events that are too closely spaced in time for currently prevailing imaging conditions.

Abstract: An ultrasound system that generates compound images from component frames having decorrelated speckle patterns. Successive sets of distinct, speckle-affecting parameters are used to generate successive component frames for compounding, and are selected such that the successive component frames have decorrelated speckle patterns. The speckle-affecting parameters that are changed from frame to frame may be selected from a wide variety of parameters, including transmit beamformer parameters, receive beamformer parameters, and demodulator parameters. According to a preferred embodiment, the successive sets of speckle-affecting parameters differ from each other by at least two speckle-affecting parameters.

Abstract: A method, system, computer program product, and user interface for real-time ultrasonic visualization enhancement of a biopsy needle are disclosed in which a wide range of needle positions with respect to the ultrasound probe axis and with respect to the imaged plane are accommodated. Ordinary frames are compounded with special purpose frames, the special purpose frames having transmit and receive parameters adapted to highlight reception of echoes from the biopsy needle. Preferably, an elevation beam width associated with the special purpose ultrasound frames is wider than an elevation beam width associated with the ordinary ultrasound frames. Preferably, the beams of the special purpose ultrasound frames are steered such that they are incident upon the biopsy needle at an increased angle as compared to the angle of incidence for ordinary ultrasound frames.

Abstract: A method, system, computer program product, and user interface for real-time ultrasonic visualization enhancement of a biopsy needle are disclosed in which a wide range of needle positions with respect to the ultrasound probe axis and with respect to the imaged plane are accommodated. Ordinary frames are compounded with special purpose frames, the special purpose frames having transmit and receive parameters adapted to highlight reception of echoes from the biopsy needle. Preferably, an elevation beam width associated with the special purpose ultrasound frames is wider than an elevation beam width associated with the ordinary ultrasound frames. Preferably, the beams of the special purpose ultrasound frames are steered such that they are incident upon the biopsy needle at an increased angle as compared to the angle of incidence for ordinary ultrasound frames.

Abstract: A medical diagnostic ultrasonic imaging method and system subdivide the transmit aperture into two or more subapertures, each subaperture having at least four adjacent transducer elements. The subapertures are phased differently with respect to one another to selectively reduce either fundamental components or harmonic components of echoes from tissue. These techniques can be used to improve contrast agent harmonic imaging as well as tissue harmonic imaging, depending upon the phase shift selected.

Abstract: An improvement to the method for harmonic imaging including the steps of (a) transmitting ultrasonic energy at a fundamental frequency and (b) receiving reflected ultrasonic energy at a harmonic of the fundamental frequency is provided. The transmitting step includes the step of: applying the plurality of waveforms to a respective plurality of transducer elements, a first waveform of the plurality of waveforms characterized by a first value of a harmonic power ratio, waveforms transmitted from the transducer elements and corresponding to the plurality of waveforms summing as an acoustic waveform substantially at the point, the acoustic waveform characterized by a second value of the harmonic power ratio less than the first value. The imaging method can also include a step for subdividing the transmit aperture into two or more subapertures, each subaperture having at least four adjacent transducer elements.

Abstract: An ultrasonic imaging system and method acquire fundamental mode and harmonic mode ultrasonic image signals with a transducer from a subject under examination. These image signals are then combined to form a composite image. This composite image includes two lateral edgefield image regions modulated primarily as a function of the fundamental mode ultrasonic image signals, and a centerfield image region modulated primarily as a function of the harmonic mode image signals. In this way, improved image quality can be obtained throughout the imaged field of view.

Abstract: An ultrasonic imaging system and method acquire fundamental mode and harmonic mode ultrasonic image signals from a subject with a transducer. These image signals are then combined to form a composite image. This composite image includes a nearfield image region modulated primarily as a function of the fundamental mode ultrasonic image signals, and a middlefield or farfield image region modulated primarily as a function of the harmonic mode image signals. In this way, excellent images can be obtained throughout the imaged range.