The present disclosure describes a medical imaging and/or visualization system and method that provide a user interface enabling a user to visualize (e.g., via a volume rendering) a three dimensional (3D) dataset, manipulate the rendered volume to select a slice plane, and generate a diagnostic image at the selected slice plane, which is enhanced by depth colorized background information. The depth colorization of the background image is produced by blending, preferably based on the depth of structures in the volume, two differently colorized volume renderings, and then fusing the background image with a foreground diagnostic image to produce the enhanced diagnostic image.

Some embodiments relate to a system and method of estimating the viscoelasticity of a material. The system and method includes receiving a plurality of time-amplitude curves measured at a plurality of space points. The time-amplitude curves reflect time evolutions of a propagating mechanical wave. The system and method also include estimating the viscoelasticity of a material between any set of space points using the time-amplitude curves measured at those space points.

An ultrasound system produces maps of acoustic attenuation coefficients from pulse echo signals. Maps are produced using different attenuation coefficient or slope estimation methods, and a plurality of maps from different estimation methods are compounded to produce a final attenuation coefficient map. Confidence maps may also be produced for one or more attenuation coefficient maps, and the confidence map displayed or its measures used to determine weighting for the compounding process.

Provided are an ultrasonic signal processing device that can evaluate reliability of a velocity vector calculated by sub-pixel tracking, an ultrasonic diagnosis apparatus, and an ultrasonic signal arithmetic processing method. The ultrasonic signal processing device includes an echo signal acquisition unit that acquires an echo signal reflected by an object to be inspected, a velocity vector calculation unit that calculates a velocity vector using the echo signal, a post-parallel-movement signal generation unit that generates a post-parallel-movement signal obtained by approximately parallelly moving the echo signal, an image deformation component extraction unit that extracts an image deformation component which is a change component of a signal value due to deformation of an image from a deviation between the post-parallel-movement signal and the echo signal, and an error energy calculation unit that calculates an error energy of the velocity vector from the image deformation component.

An ultrasound imaging system includes an intraluminal ultrasound device configured to be positioned within a body lumen of a patient. The intraluminal ultrasound device includes a transducer array disposed along a distal portion of a flexible elongate member. The transducer array includes an aperture and is configured to obtain imaging data along one or more imaging planes. The system also includes a processor in communication with the transducer array. The processor is configured to: receive first imaging data from the transducer array along a first imaging plane at a first angular position with respect to an axial direction of the aperture; output, to a display device in communication with the processor, the first imaging data; and output, to the display device, a visual representation of the first angular position of the first imaging plane with respect to the axial direction of the aperture.

An ultrasound observation device includes a controller. The controller is configured to: calculate feature data of an ultrasound signal by analyzing the ultrasound signal; divide an area of interest preliminarily set on an ultrasound image into a plurality of sections; and set an attenuation rate for each of the sections; correct the attenuation rate in a range including at least a boundary between adjacent sections in a manner smoothly changing across the adjacent sections; and perform attenuation correction on the feature data using the corrected attenuation rate to calculate correction feature data.

A method for determining a physical characteristic on a punctual location inside a medium, comprising the steps of: sending an emitted sequence comprising emitted pulses having different amplitudes, receiving a received sequence comprising received pulses corresponding to echoes of said emitted pulses, calculating a phase difference between the received pulses relative to the emitted pulses, and determining the physical characteristic on the bases of said phase difference.

A signal processing device according to an embodiment includes adjustment circuitry and processing circuitry. The adjustment circuitry adjusts a received signal based on an echo of an ultrasonic wave transmitted to a subject with gain corresponding to a location at which the echo has been generated. The processing circuitry corrects the received signal that has been adjusted by the adjustment circuitry and calculates an index value relating to attenuation by using the corrected received signal.

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.

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.