Abstract: An ultrasound imaging system according to the present disclosure may include an ultrasound probe, a display unit, and a processor configured to receive source image data having a first dynamic range, wherein the source image data comprises log compressed echo intensity values based on the ultrasound echoes detected by the ultrasound probe, generate a histogram of at least a portion of source image data, generate a cumulative density function for the histogram, receive an indication of at least two points on the cumulative density function (CDF), and cause the display unit to display an ultrasound image representative of the source image data displayed in accordance with the second dynamic range.

Abstract: A system for tracking a medical device includes an introducer. Two or more sensors are disposed along a length of the introducer and are spaced apart along the length. An interface 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: Certain exemplary embodiments relate to entertainment systems that interact with users so as to provide for social networking and/or other services. In certain exemplary embodiments, an entertainment system is configured to provide jukebox-related and entertainment system mediated services that are accessible from within and from the outside of the location, coordinating social networking services among and between patrons within and outside of the location and also providing for advertisement opportunities. In certain exemplary embodiments, the entertainment system within a location may serve as and/or be connected to a jukebox. The entertainment system within the location may be connected to one or more client devices, one or more displays, one or more bar-top or hand-held gaming devices, etc., in certain exemplary embodiments.

Abstract: A controller for determining orientation of an interventional medical device includes a memory that stores instructions, and a processor that executes the instructions. When executed by the processor, the instructions cause the controller to execute a process that includes controlling emission, by an ultrasound probe, of multiple beams each at a different combination of time of emission and angle of emission relative to the ultrasound probe. The process also includes determining, based on receipt of a response to a subset of the multiple beams at a sensor at a location on the interventional medical device, the combination of time of emission and angle of emission relative to the ultrasound probe of one of the subset of the multiple beams. The process also includes determining orientation of the interventional medical device based on the time of emission and angle of emission relative to the ultrasound probe of the one the subset of the multiple beams.

Abstract: A tool navigation system employing an ultrasound probe (20), an ultrasound scanner (60), an interventional tool (30) (e.g., a needle or a catheter), a plurality of ultrasound transducers (21, 31), a tool tracker (70) and an image navigator. In operation, the ultrasound probe (20) generates an acoustic image plane for scanning an anatomical region, and the ultrasound scanner (60) generates an ultrasound image of the anatomical region from a scan of the anatomical region. During the scan, the interventional tool (30) is navigated within the anatomical region relative to the acoustic image plane, and the ultrasound transducers (21, 31) facilitate a tracks by the tool tracker (70) of a position of the interventional tool (30) relative to the acoustic image plane.

Abstract: An ultrasound system produces high quality images at a high framerate of display. A plane or volume to be imaged is scanned by different diverging transmit beams to acquire a series of different sub-frames, the number of sub-frame acquisitions comprising a total number of transmit beams which would produce a high quality image. The echoes received in response to the transmit beams of a sub-frame are coherently combined with the echoes received in other sub-frames. Each time the echoes of a new sub-frame have been coherently combined with the echoes of all other different sub-frames, a full image is produced. After a complete series of sub-frames has been received and the echoes combined, another series of sub-frame acquisition is commenced and a new series of sub-frames acquired. As each new sub-frame is acquired, it is coherently combined with all the other different and most recently acquired sub-frames.

Abstract: System (10) for determining a position of an interventional device (11) respective an image plane (12) defined by an ultrasound imaging probe (13). The position is determined based on ultrasound signals transmitted between the ultrasound imaging probe (13) and an ultrasound transducer (15) attached to the interventional device (11). An image reconstruction unit (IRU) provides a reconstructed ultrasound image (RUI). A position determination unit (PDU) computes a position (LAPTOFSmax, ?IPA) of the ultrasound transducer (15) respective the image plane (12). The position determination unit (PDU) indicates the computed position (LAPTOFSmax, ?IPA) in the reconstructed ultrasound image (RUI). The position determination unit (PDU) suppresses the indication of the computed position (LAPTOFSmax, ?IPA) under specified conditions relating to the computed position (LAPTOFSmax, ?IPA) and the ultrasound signals.

Abstract: An imaging system and method include a medical device (102) having a tracking element (106) mounted thereon. An array (109) of transducers is spaced apart from one another for exchanging energy in a subject between tracking element and the array of transducers. A trilateration module (104) is configured to interpret signals sensed between tracking element and the array of transducers to compute times of flight of signals associated with the transducers in the array such that a position of tracking element is determined in at least two dimensions to locate a position of the medical device in a visual image.

Abstract: An interventional device includes an elongate shaft (101) with a longitudinal axis (A-A?), and an ultrasound detector (102). The ultrasound detector (102) comprises a PVDF homopolymer foil strip (103). The foil strip (103) is wrapped around the longitudinal axis (A-A?) of the elongate shaft (101) to provide a band having an axial length (L) along the longitudinal axis (A-A?). The axial length (L) is in the range 80-120 microns.

Abstract: A controller (310) for identifying positioning of an intravascular ultrasound probe (952) includes a memory (362) that stores instructions (884) and a processor (361) that executes the instructions (884). When executed by the processor (361), the instructions (884) cause the controller (310) to execute a process that includes receiving first signals from at least one element of the intravascular ultrasound probe (952). The process also includes receiving second signals from an external ultrasound probe. Based on the first signals and the second signals, the controller (310) determines a position of the intravascular ultrasound probe (952) in a tracking space that includes the intravascular ultrasound probe (952) and the external ultrasound probe.

Abstract: An ultrasound imaging system according to the present disclosure may include an ultrasound probe, a display unit, and a processor configured to receive source image data having a first dynamic range, wherein the source image data comprises log compressed echo intensity values based on the ultrasound echoes detected by the ultrasound probe, generate a histogram of at least a portion of source image data, generate a cumulative density function for the histogram, receive an indication of at least two points on the cumulative density function (CDF), and cause the display unit to display an ultrasound image representative of the source image data displayed in accordance with the second dynamic range.

Abstract: Ultrasound imaging devices, systems, and methods are provided. In one embodiment, an ultrasound imaging system comprising a processor configured to receive ultrasound channel data representative of a subject's anatomy generated from an ultrasound transducer; apply a predictive network to the ultrasound channel data to generate an image of the subjects anatomy; and output, to a display in communication with the processor, the image of the subjects anatomy. In one embodiment, a system for generating an image, the system comprising a memory storing at least one machine learning network; and a processor in communication with the memory, the processor configured to receive raw channel data generated from an ultrasound transducer; apply the machine learning network to the raw channel data to replace one or more image processing steps, thereby generating modified data; and generate an image using the modified data.

Abstract: The present disclosure describes systems and methods configured to determine shear wave velocity and tissue stiffness levels of thin tissue of finite size, also referred to as bounded tissue, via shear wave elastography. Systems can include an ultrasound transducer configured to acquire echoes responsive to pulses transmitted toward a tissue. Systems can also transmit a push pulse into the tissue for generating shear waves, and tracking pulses intersecting the shear waves. The system can also apply a directional filter to received echo data and generate directionally filtered shear wave data based on a dimension and angular orientation of the bounded target relative to the ultrasound transducer. The system can estimate velocities of the shear waves at different shear wave frequencies based on the filtered shear wave data and angular orientation relative to the transducer, and determine a tissue stiffness value independent of the shape or form of the tissue.

Abstract: A tool navigation system employing an ultrasound probe, an ultrasound scanner, an interventional tool, a tool tracker and an image navigator. In operation, the ultrasound probe generates an acoustic image plane for scanning an anatomical region, and the ultrasound scanner generates an ultrasound image of the anatomical region from a scan of the anatomical region. During the scan, the interventional tool is navigated within the anatomical region relative to the acoustic image plane, and the tool tracker tracks a position of the interventional tool relative to the acoustic image plane. The image navigator displays a graphical icon within the ultrasound image for illustrating a tracking of the interventional tool relative to the acoustic image plane by the tool tracker. Additionally, a special attachment on the US probe with PZT type sensors can help this navigation by emitting acoustic waves off the central axis of the imaging plane.

Abstract: An ultrasound imaging system produces images with enhanced resolution or contrast by extrapolation of two ultrasound images of different imaging characteristics, such as aperture size, imaging frequency, or degree of image compounding. In order to prevent the display of image artifacts, extrapolation is accompanied by artifact removal and image smoothing.

Abstract: An acoustic imaging apparatus and method: produce acoustic images of an area of interest in response to one or more receive signals received from an acoustic probe in response to acoustic echoes received by the acoustic probe from the area of interest; 5 identify one or more candidate locations for a passive sensor disposed on a surface of an intervention device in the area of interest based on magnitudes of the acoustic echoes received by the acoustic probe from the candidate locations in the area of interest; use intra-procedural context-specific information to identify a one of the candidate locations which best matches the intra-procedural context-specific information as the estimated 10 location of the passive sensor; displaying the acoustic images on a display device; and display on the display device a marker in the acoustic images to indicate the estimated location of the passive sensor.

Abstract: A controller (210) for tracking an interventional medical device (252) in three dimensions includes a memory (212) that stores instructions, and a processor (211) that executes the instructions. When executed by the processor (211), the instructions cause the controller (210) to execute a process. The process includes determining (S320/S420), based on an elevation plane in an ultrasound X-plane mode, a first two-dimensional location of the interventional medical device (252) in the elevation plane. The process also includes determining (S320/S422), based on an azimuthal plane in the ultrasound X-plane mode, a second two-dimensional location of the interventional medical device (252) in the azimuthal plane. The process moreover includes determining (S330/S430), based on the first two-dimensional location and the second two-dimensional location, a three-dimensional location of the interventional medical device (252).

Abstract: Certain exemplary embodiments relate to entertainment systems that interact with users so as to provide for social networking and/or other services. In certain exemplary embodiments, an entertainment system is configured to provide jukebox-related and entertainment system mediated services that are accessible from within and from the outside of the location, coordinating social networking services among and between patrons within and outside of the location and also providing for advertisement opportunities. In certain exemplary embodiments, the entertainment system within a location may serve as and/or be connected to a jukebox. The entertainment system within the location may be connected to one or more client devices, one or more displays, one or more bar-top or hand-held gaming devices, etc., in certain exemplary embodiments.

Abstract: An ultrasound imaging system has an improved dynamic range control which enables a user to reduce image haze with substantially no effect on bright tissue in the image and without increasing speckle variance. A dynamic range processor processes an input image to produce an approximation image which is a spatially low pass filtered version of the input image. The dynamic range of the approximation image is compressed, and image detail, unaffected by the compression, is added back to produce a dynamically compressed image for display.

Abstract: The invention provides a method for generating a compound ultrasound image. The method includes acquiring and beamforming channel data. Using the beamformed channel data a plurality of images, each image comprising a plurality of pixels, of a region of interest are obtained and an image information metric, wherein the image metric is associated with a pixel of the plurality of pixels, is assessed. The acquiring of the plurality of images and the assessment of the image metric are performed in parallel. For each image of the plurality of images: a per-pixel weighting for each pixel of the plurality of pixels based on the assessment of the image information metric is determined and applied to each pixel of the plurality of pixels. Finally a compound ultrasound image is generated based on the plurality of weighted pixels of the plurality of images.