A system includes ultrasound transducers configured to generate and direct ultrasound beams at a region within a portion of a subject's brain, sensors configured to measure a response from the portion of the subject's brain in response to one or more ultrasound beams, and an electronic controller in communication with the ultrasound transducers configured to generate, based on a measured response from the portion of the subject's brain in response to two or more ultrasound beams generated from two or more different angles, a model of the portion of the subject's brain, wherein the model has a higher resolution than a maximum resolution of a single ultrasound beam, and generate, based on the model of the portion of the subject's brain, stimulation parameters for the ultrasound transducers to generate and direct a stimulation ultrasound beam at the region within the portion of the subject's brain.

To uniformly extract a secondary flow based on quantitative calculation even in a complicated blood flow in a heart chamber or a blood vessel. There is provided a secondary flow detection device, including: a degree-of-swirl map calculation unit that obtains a velocity vector map calculated based on an echo signal reflected by an inspection target, calculates, as a value indicating a degree of a spatial change of a velocity vector, a degree of swirl based on the velocity vector map, and calculates, as a degree-of-swirl map, a spatial distribution of an iso-degree-of-swirl line obtained by connecting the degree of swirl of an equal value; a secondary flow candidate extraction unit that extracts, as a secondary flow candidate, an iso-degree-of-swirl line satisfying a predetermined condition among the iso-degree-of-swirl line indicated in the degree-of-swirl map; a feature amount calculation unit that calculates a feature amount of the velocity vector inside the secondary flow candidate; a secondary flow determination unit that determines whether the secondary flow candidate is a desired secondary flow based on the feature amount; and a secondary flow extraction unit that extracts and outputs the secondary flow determined by the secondary flow determination unit.

For deploying a stent at a coronary ostium, an integrated intravascular ultrasound (IVUS) ostial stent delivery apparatus can include a balloon catheter and an elongate shaft defining (1) a longitudinal inflation lumen and (2) a longitudinal IVUS lumen. A balloon can be located at and about the distal shaft portion and inflated with the inflation lumen. The shaft further defines a longitudinal guidewire lumen, extending at least through the distal shaft portion underlaying the balloon for at least a length of the balloon along the shaft. The IVUS lumen can include removable IVUS ultrasound imaging transducer with a signal conduit to external processing and display componentry. The imaging can help ensure proper stent location before placement and deployment, or for post-placement and stent deployment confirmation, without requiring removal of the stent delivery device to deploy a separate IVUS imaging probe.

Ultrasound image devices, systems, and methods are provided. An ultrasound imaging system, comprising an intraluminal imaging device comprising a flexible elongate member configured to be positioned within a patient's body lumen and an ultrasound transducer array coupled to the flexible elongate member, the ultrasound transducer array configured to transmit ultrasound energy into the body lumen and to receive ultrasound echoes associated with the body lumen; and a processor circuit in communication with the intraluminal imaging device and configured to receive, from the ultrasound transducer array, first signal data corresponding to the received ultrasound echoes; transform the first signal data based on a first parameter associated with a reference tissue characterization data; characterize the transformed first signal data based on the reference tissue characterization data; generate a first image of the body lumen based on the characterization; and output, to a display in communication with the processor circuit, the first image.

An ultrasound diagnosis apparatus includes: a two-dimensional (2D) transducer array in which a plurality of transducers that transmit/receive an ultrasound signal to/from an object are arranged in two dimensions; an analog beamformer configured to perform analog beamforming in a first direction, and perform analog beamforming in a second direction perpendicular to the first direction on signals respectively received by the plurality of transducers; and a digital beamformer configured to perform digital beamforming on the signals that are analog-beamformed in the first direction, and perform digital beamforming on the signals that are analog-beamformed in the second direction.

Intraluminal ultrasound devices, systems and methods are provided. In one embodiment, an intraluminal ultrasound device includes a flexible elongate member configured to be positioned within a body lumen of a patient, the flexible elongate member including a distal portion and a longitudinal axis; and a transducer array disposed at the distal portion of the flexible elongate member and circumferentially positioned around the longitudinal axis of the flexible elongate member. The transducer array includes a plurality of micromachined ultrasound transducers (MUTs). In addition, the transducer array is configured to obtain ultrasound imaging data of the body lumen in response to a first electrical signal, and apply an ultrasound therapy within the body lumen in response to a second electrical signal.

Provided is an ultrasound diagnostic apparatus including a probe configured to induce displacement in tissue of an object by irradiating a first focused beam of a first frequency to the object; and a processor configured to obtain a first ultrasound image of the object in which displacement has been induced; to determine whether the induced displacement is appropriate based on the obtained first ultrasound image; when the induced displacement is not appropriate, to control the probe to irradiate a second focused beam of a second frequency different from the first frequency to the object, so as to induce displacement in the tissue of the object; and to process a second ultrasound image of the object in which displacement has been induced by the second focused beam.

An imaging assembly for an intraluminal device is provided. In one embodiment, the imaging assembly includes: an array of ultrasound transducer elements spaced apart by air kerfs; a plurality of buffer elements surrounding the array of ultrasound transducer elements, wherein the plurality of buffer elements are spaced apart by gaps; and a sealing material filling portions of the gaps between the plurality of buffer elements.

An ultrasound probe is disclosed including a body (102), a lens included on head portion (44) of the body, a stabilizing portion (146) extending from the body and configured to stabilize the body on a skin surface of a patient without user assistance, and a finger-grip portion (110) configured to enable a user of the ultrasound probe to grasp and maneuver the ultrasound probe during use thereof with no more than two or three fingers on a single hand of the user. The ultrasound probe may further include a cable conduit (194) and a cable boot (195) configured to house a distal-end portion of a power-and-data cable and to keep the cable away from the head portion. The stabilizing portion may include a latitudinal channel (147) that reduces a surface area of the stabilizing portion intended to face the skin surface of the patient, in order to facilitate movement of the ultrasound probe across the skin surface and to reduce suction hen gel is present and the ultrasound probe is removed from the patient.

The invention provides an ultrasound system comprising an ultrasound probe, adapted to transmit and receive ultrasound signals, and an interventional device for insertion into a vessel of a subject. The interventional device includes an ultrasound transducer adapted to acquire a first set of ultrasound data at a first ultrasound frequency, wherein the first set of ultrasound data relates to flow data. The ultrasound system is further adapted exchange a second set of ultrasound data between the ultrasound probe and the interventional device at a second ultrasound frequency different from the first ultrasound frequency, wherein the second ultrasound data relates to interventional device positioning data.