Systems, methods and computer program products are provided for analyzing at least one of ultrasound (US) images or optoacoustic (OA) images (US/OA images), comprising: a display configured to display at least a first image from at least one of OA images or US images acquired in connection with an examination for a region of interest (ROI), the first image including a lesion, the first image overlaid with an interior ROI outline separating an internal zone from a boundary zone of the ROI, the first image overlaid with an exterior ROI outline separating the boundary zone from a peripheral zone; a graphical user interface (GUI); memory configured to store program instructions; and one or more processors configured to execute the programmable instructions to: obtain feature scores in connection with at least the boundary zone and peripheral zone of the first image; apply the feature scores to a classification model to obtain predictive result indicative of a trait of the lesion, the predictive result indicating at least one of a presence or absence of metastasis lymph nodes and several lymph nodal metastasis; and output the predictive result.

A processor of an ultrasound diagnostic apparatus acquires first ultrasound image data of a lower abdomen of a subject, derives a size of a bladder region included in the first ultrasound image data based on the first ultrasound image data, determines presence or absence of an organ, other than a bladder, that is to be examined, in the lower abdomen based on the size of the bladder region, and in a case where determination is made that there is an organ to be examined, displays first information on an examination of the organ on a display.

A method of displaying an ultrasound image includes determining a direction of a fetus's head based on a first ultrasound image obtained by scanning a pregnant woman's body in a first direction; determining a direction of a fetus's spine based on a second ultrasound image obtained by scanning the pregnant woman's body in a second direction; determining an orientation of the fetus within the pregnant woman's body based on the directions of the fetus's head and the fetus's spine; and displaying an image representing the orientation of the fetus, together with an ultrasound image obtained by scanning the pregnant woman's body.

Aspects of the disclosed technology provide ways to detect the object of ultrasound scanning and to automatically, load system settings and image preferences necessary to generate high quality output images. In some aspects, an ultrasound system can be configured to perform steps including receiving a selection of a first transducer, identifying a body structure or organ based on a signal received in response to an activation of the first transducer, retrieving a first set of parameters corresponding with the body structure, and configuring the first transducer based on the first set of parameters. Methods and machine-readable media are also provided.

An imaging conditions acquisition unit acquires imaging conditions relevant to the positioning of an irradiation device and a radiation detector for acquiring a medical image. An imaging control unit controls the irradiation device and the like so as to acquire a pre-shot image or the medical image of the subject. A correction amount calculation unit calculates the correction amount of the imaging conditions based on the pre-shot image. A notification unit sends notification of the correction amount.

A 3D ultrasound imaging device including an ultrasound probe assembly and echo analyzer. The ultrasound probe assembly includes a housing and an acoustic window abutted against the housing to form a sealed chamber, wherein the surface of the acoustic window contacts with the breast of the human body to be examined; an ultrasound transducer moves at a first speed back and forth within the sealed chamber and performs high-speed pre-scanning through the acoustic window to obtain initial ultrasound signals; the echo analyzer analyzes the initial ultrasound signals to determine a quality of a ultrasound image acquired by the high speed pre-scanning; and the ultrasound transducer then moves at a second speed to perform another scan to acquire new ultrasound signals. A 3D ultrasound imaging method is also disclosed.

An ultrasound diagnostic apparatus includes an ultrasound probe that performs transmission and reception of an ultrasonic wave to and from a subject, a head-mounted display having a camera unit configured to acquire a camera image obtained by imaging a field of view in front of a user and a display unit, a measurement spot decision unit that, in a case where subject information including at least one of a symptom or a disease of the subject is input, decides a measurement spot where the transmission and reception of the ultrasonic wave is desired, based on the spot subject information, and a navigation image generation unit that recognizes the subject from the camera image, generates a navigation image indicating a position of the measurement spot decided by the measurement spot decision unit with respect to the recognized subject, and displays the generated navigation image on the display unit of the head-mounted display.

An ultrasound diagnostic apparatus includes: an imaging unit that converts a received signal output from an ultrasound probe into an image to generate an ultrasound image; an input unit that is used by a user to input patient information; a memory unit that stores content of an examination for continuously examining a plurality of examination parts so as to be associated with the patient information; an examination situation determination unit that, in a case in which new patient information is input to the input unit during the continuous examination, determines whether the examination of all of the plurality of examination parts related to the content of the examination associated with the patient information has ended; and a tag giving unit that gives an examination interruption tag to the patient information in a case in which it is determined that the examination of all of the plurality of examination parts has not ended and gives an examination end tag to the patient information in a case in which it is determined that the examination of all of the plurality of examination parts has ended.

The present disclosure describes ultrasound imaging systems and methods for ultrasonically inspecting biological tissue. An ultrasound imaging system according to the present disclosure may be configured to automatically apply tissue-specific imaging parameter settings (312, 314) based upon the automatic identification of the type of tissue being scanned. Tissue type identification (315) may be performed automatically for the images in the live image stream (304) and thus adjustments to the imaging settings may be applied automatically by using a neural network (320) and thus dynamically during the exam obviating the need for the sonographer to manually switch presets or adjust the imaging settings when moving to different portion of the anatomy.

Techniques are provided for detection and treatment of tumors using ultrasound. An early detection test may be performed on a patient. A location of a tumor may be determined based on the early detection test. Properties of the tumor may be determined based on the early detection test. Moieties may be functionalized based on the properties of the tumor. The moieties maybe introduced into the patient. The location of the tumor may be imaged using ultrasound, magnetic resonance elastography, or computed tomography to generate images of the location of the tumor. A treatment plan based on the images of the location of the tumor may be implemented using ultrasound.