Abstract: An ultrasonic diagnostic imaging system and method translates an aperture across an array transducer which is less that the size of the array. At each aperture location a transmit beam is focused above, or alternatively below, the array and a region of interest being scanned from the aperture location, resulting in broad insonification of the region of interest. At the lateral ends of the array the aperture is no longer translated but the focal point of the transmit beam is translated from the same aperture position, preferably with tilting of the beam direction. Multiple receive beams are processed in response to each transmit event and the overlapping receive beams and echo locations are spatially combined to produce synthetic transmit focusing over the center of the image field and noise reduction by spatial compounding at the lateral ends of the image field.

Abstract: An ultrasound transducer array (100) is disclosed comprising an array of elongate support members (110) displaceable and/or deformable relative to each other in the elongation direction of said elongate support members, each elongate support member having a patient facing surface carrying an ultrasound transducer tile (120); and a plurality of sensors (115), each adapted to detect the relative displacement and/or deformation of one of said elongate support members. An ultrasound system (10) including such an ultrasound transducer array and an operating method (200) of such an ultrasound system are also disclosed.

Abstract: A diagnostic ultrasound system has a 2D array transducer which is operated with 1×N patches, patches which are only a single element wide. The “N” length of the patches extends in the elevation direction of a scanned 2D image plane, with the single element width extending in the lateral (azimuth) direction. Focusing is done along each patch in the elevation direction by a microbeamformer, and focusing in the lateral (azimuth) direction is done by the system beamformer. The minimal width of each patch in the azimuth direction enables the production of images highly resolved in the azimuthal plane of a 2D image, including the reception of highly resolved multilines for high frame rate imaging.

Abstract: A system includes an acoustic probe and an acoustic imaging machine connected to the acoustic probe. The acoustic probe a substrate with first and second principal surfaces, at least one device insertion port comprising an opening passing through the substrate from the first principal surface to the second principal surface, and an array of acoustic transducer elements supported by the substrate and disposed around the at least one device insertion port. The acoustic imaging machine is configured systematically vary the size and/or position of the active acoustic aperture of the ultrasound probe by providing transmit signals to selected acoustic transducer elements to cause the array of acoustic transducer elements to transmit an acoustic probe signal to an area of interest, and recording a feedback signal of the transmit signals from an acoustic receiver (610) provided at a distal end of an interventional device passed through the device insertion port into the area of interest.

Abstract: A connector includes an inner conductive body for connecting to a sensor contact on a medical device. An insulator is formed on the inner conductive body. An outer conductive body is formed over the insulator and surrounds the inner conductive body but is electrically isolated from the inner conductive body. The outer conductive body is for making contact at two places on a medical needle on opposite sides of the inner conductive body.

Abstract: A system for tracking a medical device includes an introducer (20). Two or more sensors (22) are disposed along a length of the introducer and are spaced apart along the length. An interface (32) is configured to connect to the introducer such that the introducer and the interface operatively couple to and support the medical device wherein the two or more sensors are configured to provide feedback for positioning and orienting the medical device using medical imaging.

Abstract: A system for automatic configuration detection includes a medical device (250) including a sensor (246). A pattern (236) is coded into a portion of the medical device. The pattern is configured to store pertinent information about the device. A reader device (234) is coupled to a connector and configured to read the pattern to convey the pertinent information to determine one of a status, identity or manner of use for the medical device including the sensor.

Abstract: A medical device includes a conductive body (14) including a surface and a sensor (10) conformally formed on the surface and including a piezoelectric polymer formed about a portion of the surface and following a contour of the surface. The piezoelectric polymer is configured to generate or receive ultrasonic energy. Electrical connections (24) conform to the surface and are connected to an electrode in contact with the piezoelectric polymer. The electrical connections provide connections to the piezo electric polymer and are electrically isolated from the conductive body over a portion of the surface.

Abstract: A sensor device includes a flexible planar strip (40) including a plurality of layers. The strip is configured to at least partially encapsulate a medical device. The strip includes a first dielectric layer (10), a conductive shield layer (12) disposed on the first dielectric layer, a second dielectric layer (14) formed on the conductive shield layer; and a patterned conductive layer including a sensor electrode (26), a hub electrode (28) and a trace (18) connecting the sensor electrode and the hub electrode.

Abstract: A medical device includes a device body (14), a first sensor (10) formed on the device body and including a piezoelectric polymer as a sensor element, the piezoelectric polymer configured to receive ultrasonic energy and a first electrical trace (24) connecting to the first sensor and extending along the device body. A dummy sensor (11) is formed on the device body in proximity of the first sensor and includes a dummy sensor element. A second electrical trace (25) connects to the dummy sensor and extends along the device body in a configuration relative to the first electrical trace, wherein a signal event is discriminated between a signal and noise using a response measured on one or more of the first sensor, the dummy sensor or the second electrical trace.

Abstract: A connector includes an inner conductive body (34) for connecting to a sensor contact on a medical device. An insulator (40) is formed on the inner conductive body. An outer conductive body (32) is formed over the insulator and surrounds the inner conductive body but is electrically isolated from the inner conductive body. The outer conductive body is for making contact at two places on a medical device on opposite sides of the inner conductive body.

Abstract: A medical device includes an elongated body (14) and a plurality of sensors (10) conformally formed on the elongated body at a plurality of longitudinal positions along the elongated body. The plurality of sensors is configured to generate signals in accordance with detected energy for an imaging system. A single electrical trace (24) connects to each of the plurality of sensors, the plurality of sensors being connected in parallel to form an array of sensors along the elongated body.

Abstract: A medical ultrasound acquisition-data analysis device acquires channel data (144) via ultrasound received on the channels, uses the acquired channel data to estimate data coherence and derive dominance of an eigen-value of a channel covariance matrix and, based on the estimate and dominance, distinguishes microcalcifications (142) from background. Microcalcifications may then be made distinguishable visually on screen via highlighting, coloring, annotation, etc. The channel data operable upon by the estimating may have been subject to beamforming delays and may be summed in a beamforming procedure executed in the estimating. In the estimating and deriving, both field point-by-field point, multiple serial transmits (116, 118) may be used for each field point. In one embodiment results of the estimating and deriving are multiplied point-by-point and submitted to thresholding.

Abstract: A non-imaging diagnostic ultrasound system for carotid artery diagnosis has a two dimensional array probe (10) with a low element count and relatively large element size which can cover an area of the carotid artery at its bifurcation. The elements are operated independently with no phasing, and detect Doppler flow spatially beneath each element. The system produces maps of carotid blood flow in two or three dimensions and can assemble an extended view of the flow by matching segments of the carotid flow as the probe is moved over the vessel. Once the carotid artery has been localized, the degree of stenosis is assessed by automated measurements of peak systolic velocity and blood flow turbulence.

Abstract: A non-imaging diagnostic ultrasound system for carotid artery diagnosis has a two dimensional array probe with a low element count and relatively large element size which can cover an area of the carotid artery at its bifurcation. The elements are operated independently with no phasing, and detect Doppler flow spatially beneath each element. The system produces maps of carotid blood flow in two or three dimensions and can assemble an extended view of the flow by matching segments of the carotid flow as the probe is moved over the vessel. Once the carotid artery has been localized, the degree of stenosis is assessed by automated measurements of peak systolic velocity and blood flow turbulence.

Abstract: A method for aligning spatially different subvolumes of ultrasonic data of a blood vessel comprising: acquiring temporally discrete signals of a blood vessel with elements of a two dimensional array of ultrasonic transducer elements from spatially different depths of scanning opposed by each transducer element, said array being located in a first position with respect to the blood vessel during the acquiring; Doppler processing the temporally discrete signals received from each transducer element to produce spectral Doppler data of the scanning depth opposed by each transducer element; producing a first three dimensional map of the spectral Doppler data in spatial relationship to the position of the array with respect to the blood vessel; acquiring temporally discrete signals of the blood vessel with elements of the two dimensional array of ultrasonic transducer elements from spatially different depths of scanning opposed by each transducer element, said array being located in a second position with respect t

Abstract: Issuance of ultrasound pulses to a volume and receiving echo data is followed by estimating, based on the received data, center frequency subvolume-by-subvolume. Distinguishing between heart and lung tissue occurs based on a result of the estimating, and may include automatically identifying a spatial boundary (332) between the heart and lung tissue (324, 328), or a user display of center frequencies that allows for visual distinguishing. The issuance can include issuing, ray line by ray line, pair-wise identical, and/or pair-wise mutually inverted, ultrasound pulses. Center frequency calculations may be made for incremental sampling locations of respective imaging depth along each of the A-lines generated from echo data of the rays. The distinguishing might entail averaging center frequencies for locations along an A-line, and applying a central frequency threshold to the average. The leftmost of the qualifying A-lines, i.e.

Abstract: An interactive visual guidance tool for an imaging acquisition and display system and configured for user navigation with respect to a blockage of a field of view (216) detects, and spatially defines, the blockage. It also integrates, with the image for joint visualization, an indicium (244) that visually represents the definition. The indicium is moved dynamically according to movement, relative to the blockage, of the field of view. The indicium can be shaped like a line segment, or two indicia (244, 248) can be joined in a “V” shape to frame a region of non-blockage. The defining maybe based on determining whether ultrasound beams in respective directions are blocked. Included, for deriving the image, in some embodiments are imaging channels for receiving image data for which a metric of coherence, i.e., similarity among channel data, is computed. The determination for a direction is based on the metric for locations in that direction.

Abstract: An apparatus includes an imaging probe and is configured for dynamically arranging presentation of visual feedback (144) for guiding manual adjustment, via the probe, of a location, and orientation, associated with the probe. The arranging is selectively based on comparisons (321) between fields of view of the probe and respective results of segmenting image data acquired via the probe. In an embodiment, the feedback does not include (175) a grayscale depiction of the image data. Coordinate system trans formations corresponding to respective comparisons may be computed. The selecting may be based upon and dynamically responsive to content of imaging being dynamically acquired via the probe.

Abstract: An apparatus comprising a sensing unit configured to predict a release of urine using one or more prediction parameters, detect an actual release of urine and adapt at least one of the one or more prediction parameters based on the actual release of urine to increase prediction accuracy.