A system and method is provided for obtaining ultrasound images of an interior of an object that includes an image processing unit that receives and processes acquired ultrasound scan data to create ultrasound images derived from ultrasound image data, a motion detection system configured to detect a pattern of inactivity time frames within movement cycles of the object and an ultrasound imaging probe operably connected to the image processing unit to acquire the ultrasound scan data for use by the image processing unit to form the ultrasound images. The motion detection system detects a pattern of one or more inactivity time frames within a first cycle of movement of the object, obtains ultrasound volumetric scan data of the object during the inactivity time frame within a second cycle of movement of the object, and calibrates a location of a scan plane of the ultrasound image within the volumetric ultrasound image.

A method of generating a 3D ultrasound image includes acquiring a 3D volumetric data set corresponding to a 3D imaging volume of an ultrasound probe in a 3D detection volume; acquiring a position of the ultrasound probe with respect to the 3D detection volume; acquiring a position of an interventional medical device with respect to the 3D detection volume; determining a position of the interventional medical device relative to the 3D imaging volume of the ultrasound probe; determining an interventional medical device-aligned plane that intersects with a longitudinal axis of the interventional medical device; extracting a texture slice from the 3D imaging volume for a corresponding interventional medical device-aligned plane positional and rotational orientation; mapping the texture slice onto the interventional medical device-aligned plane; and rendering the interventional medical device-aligned plane as a 3D ultrasound image and displaying the rendered 3D ultrasound image on a display screen.

A plurality of ultrasound frames of a fetus are acquired using an ultrasound scanner, which may be oriented arbitrarily with respect to the fetus during the acquisition. The ultrasound frames are processed against an artificial intelligence model to predict a different cut line on each of the ultrasound frames. Each cut line is predicted to be exterior to an image of the fetus appearing on the ultrasound frame. The different cut lines on the plurality of ultrasound frames are then used to identify ultrasound data in the image frames to generate a 3D representation of the fetus.

Provided are a CEUS imaging method, an ultrasound imaging apparatus and a storage medium. The method includes: controlling an ultrasonic probe to transmit an ultrasonic wave to a target tissue containing a contrast agent, receive an echo of the ultrasonic wave, and acquire a first contrast data and a first tissue data in real time based on the echo of the ultrasonic wave, the first contrast data and the first tissue data being volumetric data; rendering a second contrast data and a second tissue data in real time to acquire a hybrid rendered image of the second contrast data and the second tissue data, the second contrast data containing all or part data of the first contrast data, and the second tissue data containing all or part data of the first tissue data; and displaying the hybrid rendered image in real time. The CEUS imaging method and the ultrasound imaging apparatus according to embodiments of the present disclosure help users more intuitively understand and observe the real-time spatial position relationship of a contrast agent in tissues, and further acquire more clinical information.

A system and method for automatically setting an elevational tilt angle of a mechanically wobbling ultrasound probe is provided. The method includes acquiring, by a mechanically wobbling ultrasound probe of an ultrasound system, an ultrasound volume of a region of interest. The method includes analyzing, by at least one processor of the ultrasound system, the ultrasound volume to identify an ultrasound image slice depicting an anatomical object of interest. The ultrasound image slice corresponds with an elevational tilt angle. The method includes setting, by the at least one processor, the mechanically wobbling ultrasound probe to the elevational tilt angle corresponding with the ultrasound image slice depicting the anatomical object of interest. The method includes acquiring, by the mechanically wobbling ultrasound probe, a two-dimensional (2D) ultrasound image at the elevational tilt angle. The method includes causing, by the at least one processor, a display system to present the 2D ultrasound image.

Provided in the present application is an ultrasonic imaging method, including: generating a plurality of anatomical plane schematics, and causing a display to display the same, each one of the plurality of anatomical plane schematics respectively corresponding to a different anatomical plane of interest; acquiring an ultrasonic image of the anatomical plane of interest; and automatically generating an ultrasonic image thumbnail of the anatomical plane of interest, automatically replacing the anatomical plane schematic corresponding to the anatomical plane of interest with the ultrasonic image thumbnail, and causing the display to display the same. Also provided in the present application are an ultrasonic imaging system and a non-transitory computer-readable medium.

An ultrasonic imaging system produces more diagnostic cardiac images of the left ventricle by plotting the longitudinal medial axis of the chamber between the apex and mitral valve plane as a curved line evenly spaced between the opposite walls of the myocardium. Transverse image planes are positioned orthogonal to the curved medial axis with control points positioned in the short axis view on lines evenly spaced around and emanating from the medial axis. If the short axis view is of an oval shaped chamber the transverse image is stretched to give the heart a more rounded appearance resulting in better positioning of editing control points.

In one embodiment a system includes a ultrasound probe to capture 2D ultrasonic images of a body part of a living subject, a process to generate a 3D anatomical map of the body part, the 3D anatomical map and the 2D ultrasonic images being registered with a 3D coordinate space, add a 3D indication of an anatomical structure to the 3D anatomical map, render to a display the 3D anatomical map including the 3D indication of the anatomical structure, and render to the display a given one of the 2D ultrasonic images with a 2D indication of the anatomical structure on the given 2D ultrasonic image responsively to the 3D indication of the anatomical structure.

The present disclosure describes ultrasound imaging systems and methods, which may enable the automatic identification of an image plane in a pre-operative volume corresponding to a real-time image of a moving region of interest. An example method includes receiving real-time ultrasound image data from a probe associated with a position-tracking sensor, generating real-time images based on the real-time ultrasound data and deriving a motion model from the real-time ultrasound image data. The method may further include automatically identifying an image plane in a pre-operative data set to correspond to the real-time ultrasound image by correcting for motion-induced misalignment between the real-time data and the pre-operative data.

An ultrasound device (10) includes a probe (12) including a tube (14) sized for insertion into a patient and an ultrasound transducer (18) disposed at a distal end (16) of the tube. A camera (20) is mounted at the distal end of the tube in a fixed spatial relationship to the ultrasound transducer. At least one electronic processor (28) is programmed to: control the ultrasound transducer and the camera to acquire ultrasound images (19) and camera images (21) respectively while the ultrasound transducer is disposed in vivo inside the patient; and construct a keyframe (36) representative of an in vivo position of the ultrasound transducer including at least ultrasound image features (38) extracted from at least one of the ultrasound images acquired at the in vivo position of the ultrasound transducer and camera image features (40) extracted from one of the camera images acquired at the in vivo position of the ultrasound transducer.