Abstract: Accurate tissue motion systems and methods are provided. Motion of the ultrasound transducer is accounted for in estimates at tissue motion. Correcting for transducer motion better isolates localized tissue contractions or expansions, such as motion of the myocardial muscle or fibers. Accurate motion estimation is also provided by determining an angle of motion from the ultrasound data. The angle of motion is used to adjust velocity estimates, providing two-dimensional velocity vectors (i.e. motion estimates comprising motion in at least two dimensions). Movement of tissue is determined by correlating speckle or a feature represented by two different sets of ultrasound data obtained at different times. Additional aspects include tracking the location of a tissue of interest. A characteristic of strain, such as the strain rate or strain, is calculated for the tracked tissue of interest.

Abstract: The preferred embodiments described herein provide a method and system for displaying medical data at an automatically-selected display resolution. In one preferred embodiment, medical data is automatically analyzed, and based on the analysis, a display resolution is automatically selected. The medical data is then displayed with the automatically-selected display resolution. By automatically selecting a display resolution based on an analysis of medical data, the appearance of medical data is optimized without conscious effort by a user. Other preferred embodiments are provided.

Abstract: A medical ultrasonic imaging method uses transmitted plane waves, or transmitted wavefronts that are substantially planar, to improve contrast agent imaging by generating peak pressures that are more uniform over depth. Depending on the type of contrast agent, the returned frequencies of interest, and the desired strength of the non-linear response, multiple wavefronts can be generated at substantially the same time to increase peak pressures.

Abstract: A method and system for identifying constrictions in a vessel are provided. Total blood volume flow is measured at various locations along the vessel. The total volume flow must be conserved. Regions with a different volume flow than expected (e.g. areas associated with a lower volume that violates conservation of flow) are identified as suspicious. Suspicious regions are likely associated with dropout artifact. Actual constrictions are determined from the geometry of images where the region is not suspicious.

Abstract: The preferred embodiments described herein relate to voice-enhanced diagnostic medical ultrasound imaging systems and review stations as well as to voice-related user interfaces. With these preferred embodiments, a user can interact with an imaging system or review station by issuing verbal commands instead of using a mouse, keyboard, or other user interface that requires physical manipulation by the user. This provides a very user-friendly interface, especially to those users who have difficulty navigating complex window and menu hierarchies or who have trouble manipulating pointing devices. This also improves patient flow and provides a more efficient report generation system. Voice feedback can also be used to allow the imaging system or review station to better communicate with a user.

Abstract: A method and system for reducing speckle for two and three-dimensional images is disclosed. For two-dimensional imaging, a one and a half or a two-dimensional transducer is used to obtain sequential, parallel or related frames of elevation spaced data. The frames are compounded to derive a two-dimensional image. For three-dimensional imaging, various pluralities of two-dimensional frames of data spaced in elevation are compounded into one plurality of spaced two-dimensional frames of data. The frames of data are then used to derive a three dimensional set of data, such as by interpolation. Alternatively, the various pluralities are used to derive a three-dimensional set of data. An anisotropic filter is applied to the set of data. The anisotropic filter filters at least along the elevation dimension. In either situation, various displays may be generated from the final three-dimensional set of data. A method and system for adjustably generating two and three-dimensional representations is also disclosed.

Abstract: A system and method for diagnostic ultrasound imaging with a probe combining one or more ultrasound imaging transducer elements and a body-tissue parameter measurement mechanism to detect body-tissue properties. At least one ultrasound transducer element provides an ultrasound image field of view of at least a portion of the body-tissue being measured by the parameter measurement mechanism. The parameter measurement mechanism is typically a mechanically or electrically operated mechanism attached to the probe near at least one ultrasound transducer element in order to combine information from the body-tissue parameter measurement mechanism and ultrasound transducer element for easier identification of abnormal body-tissue properties (e.g., tumors, dead, or diseased body-tissue).

Abstract: A medical diagnostic ultrasonic imaging system acquires receive beams from spatially distinct transmit beams. The receive beams alternate in type between at least first and second types across the region being imaged. The first and second types of receive beams differ in at least one scan parameter other than transmit and receive line geometry, and can for example differ in transmit phase, transmit or receive aperture, system frequency, transmit focus, complex phase angle, transmit code or transmit gain. Receive beams associated with spatially distinct ones of the transmit beams (including at least one beam of the first type and at least one beam of the second type) are then combined. In this way, many two-pulse techniques, including, for example, phase inversion techniques, synthetic aperture techniques, synthetic frequency techniques, and synthetic focus techniques, can be used while substantially reducing the frame rate penalty normally associated with such techniques.

Abstract: Speckle is reduced by compounding data associated with different aperture positions. The data is responsive to transmission and reception along the same scan lines. The data is detected and then combined.

Abstract: Two-dimensional transducer arrays used for one-, two- and three-dimensional medical diagnostic ultrasonic imaging. The transducer arrays have transducer elements that are arranged in a non-rectangular, and preferably hexagonal grid. In a preferred embodiment, the transducer array has hexagonally shaped transducer elements. The transducer arrays may be fabricated as single or multiple layer structures. Sparse transducer arrays may be fabricated in a hexagonal grid by connecting selected transducer elements to the imaging system. Also, the transducer array may comprise random, vernier and spiral arrays fabricated in a hexagonal grid.

Abstract: A medical ultrasonic imaging system transmits a set of two or more substantially identical transmit pulses into a tissue containing a contrast agent. The associated received pulses are filtered with a broadband filter that passes both the fundamental and at least one harmonic component of the echoes. The filtered received pulses are then applied to a clutter filter that suppresses harmonic and fundamental responses from slowly moving and stationary tissue, while clearly showing contrast agent response due to the loss of correlation effect. The disclosed system includes other signal paths for generating conventional B-mode images as well as combined images that include both components from the contrast-specific image as well as components from the B-mode image. An improved user interface allows the user to switch among these three images.

Abstract: A medical diagnostic ultrasound imaging method fires a sequence of pulses into a body and then receives, beamforms, weights and sums the resulting echo signals to suppress first order echoes. The sequence of pulses includes at least two pulses that differ in amplitude and phase. In one form, no two pulses of the sequence have the same amplitude and opposite phase. In another form, only linear echoes are suppressed. In a third form, second and third order echoes are preserved while linear echoes are suppressed.

Abstract: A method and system for contrast agent image beamformation is provided. The acoustic energy of transmit beams is spread laterally to reduce contrast agent destruction. For example, a smaller aperture is provided for contrast agent imaging than for a default imaging mode. As another example, an apodization profile with a low amplitude for edge elements for contrast agent imaging is used as compared to the edge elements for a default imaging mode. As yet another example, the focal point used for contrast agent imaging is set to be outside of the region of interest (e.g. a shallow or deep focal point).

Abstract: A plurality of piezomaterial bodies, such as panels or slices, are merged together to form a larger piezomaterial body. For example, a 0.75×22 cm polycrystalline piezomaterial body is formed, where the distances are along lateral or footprint dimensions. The thickness of the piezomaterial body is substantially less than either of the distances along first and second lateral dimensions that define the footprint. Preferably, each piezomaterial body has a panel shape, and a plurality of panels are merged to form a large multi-panel.

Abstract: An ultrasound method and system are presented for enabling an ultrasound device feature. An ultrasound device is installed with features that are not immediately available for use (i.e., the features are installed disabled). To enable these features, a key is locally or remotely supplied to the ultrasound device. With these preferred embodiments, hardware or software features of an ultrasound device can be enabled on demand for evaluation purposes. Further, if the feature is enable for a limited amount of time, a user can pay a reduced fee for the temporary use of the feature. Additionally, because the necessary hardware is factory-installed in and shipped with the ultrasound device, a user who desires the temporary or permanent use of a hardware feature can enable the feature without taking the ultrasound device off-line.

Abstract: Medical diagnostic ultrasound methods and systems for automated structure analysis are provided. Where the vessel bifurcates, such as the carotid artery, the common portion (i.e. the bifurcation bulb) is divided between the branches. For example, the common portion is divided as a function of a ratio of (1) the integral of ultrasound flow data at a cross-section of a first branch to (2) the integral of ultrasound flow data at a cross-section of a second branch. As another example, the intersection of three-dimensional surfaces perpendicular to the center axis of each branch within the common area divides the common portion. The ultrasound data representing the common portion is associated with each branch as a function of the division. This association assists with flow and structural analysis. For use with the bifurcation division discussed above or for other vessels, a method and system for automatically assigning a center (i.e. medial) axis of the vessel is provided.

Abstract: The preferred embodiments described herein provide an improved ultrasound transducer and method of manufacture thereof. In one preferred embodiment, a method of manufacturing an ultrasound transducer is provided comprising the acts of supporting a layer of piezoelectric material with a window and separating the layer of piezoelectric material into at least two elements by dicing through the layer of piezoelectric material and at least partially into the window. In another preferred embodiment, an ultrasound transducer is provided comprising a first transducer element, a second transducer element, and a window coupled with the first and second transducer elements and comprising a kerf positioned between the first and second transducer elements.

Abstract: A method and apparatus is provided for annotating an image captured by an ultrasound system, which has an input device with a plurality of console keys for receiving input from an operator. The plurality of console keys includes an alphanumeric input device, such as a keyboard, used for placing characters on the image. An annotation function is invoked by pressing a key of the alphanumeric input device. The annotation function is for placing a character on the image in response to a character code from the alphanumeric input device. In a further aspect of the invention, the input device is provided with a pointing device, such as a track ball, which is spaced apart from the alphanumeric input device such that unintentional invocation of the annotation function is minimized. According to the method of the present invention, a key of the alphanumeric input device is pressed. In response to a character code generated by pressing the key, the annotation function is invoked.

Abstract: A method and system is provided for delivering drugs carried by microspheres. A medical diagnostic ultrasound system destroys microspheres in a specific localized area or at a specific time. A region of interest that is a subset of an imaged area is identified for destroying drug-carrying microspheres. The transmit beamformer is configured to transmit acoustic energy for destroying microspheres within that area while minimizing the destruction of microspheres outside of the region of interest. A multidimensional transducer array may provide focusing in three-dimensions for accurately destroying microspheres in the specific region while minimizing the destruction of microspheres outside that region. A trigger responsive to a heart or breathing cycle may control when microspheres are destroyed, providing delivery of drugs at the most opportune time in the cycle.

Abstract: Vessel border detection is provided. A top border or border closer to a transducer of a vessel is detected using Doppler data. Since little flowing fluid is provided between the top border of the vessel and the transducer, reverberation artifacts are minimized. A bottom border or border of the vessel farther from the transducer is detected from B-mode data. Since few tissue layers are provided immediately adjacent the bottom border between the bottom border and the transducer, reverberation artifacts are minimized. The detected borders are used for further calculation or display, such as automatically estimating vessel diameter for endothelial function assessment. In alternate embodiments, different techniques for identifying fluid or tissue data are used, such as magnetic resonance imaging, CAT scan, x-ray or other techniques for imaging interior portions of a patient. Borders for other fluid regions in a patient may be detected, such as a heart border or other organ borders.