The invention relates to a measurement device for the blood flow of an individual, for example for the detection of bubbles. The device comprises an acoustic emitter and a case with an emission surface capping the acoustic emitter. The emission surface is terminated at one end by a clavicular contact portion perpendicular to the emission surface and suited for coming to rest against a clavicle bone of the individual and is terminated at another end by a shoulder contact portion perpendicular to the emission surface and suited for coming to rest against a bone of the shoulder of the individual. A vertical distance between the middle of an active zone of the emission surface and the clavicular contact portion is less than 20 mm. A transverse distance between the middle of the active zone and the shoulder contact portion is included between 20 and 50 mm.

Various embodiments of the present invention disclose A method and an apparatus for an ultrasound diagnosis based on an electronic device. According to various embodiments of the present invention, the electronic device includes: a display; a camera; a first communication circuit for probe connection; a second communication circuit for communication with at least one external device; and a processor electrically connected with the display, the camera, the first communication circuit, and the second communication circuit, wherein the processor can be configured to detect an ultrasonic diagnosis mode, execute the ultrasonic diagnosis mode and establish communication with the external device in response to the detection of the ultrasonic diagnosis mode, acquire data in the ultrasonic diagnosis mode, display the data on the display and transmit the data streaming to the external device using the second communication circuit, and provide an control guide for the probe in response to reception of control information from the external device. Various embodiments are possible.

Handheld ultrasound devices with display-retaining designs that allow the processor/display assembly to be removed and/or repositioned are provided. According to one embodiment, a handheld ultrasound scanning device includes a main body housing having a first side and a second side. An ultrasound transducer is coupled to the second side and is configured to obtain ultrasound data. A communication interface is communicatively coupled to the ultrasound transducer and configured to transmit the ultrasound data obtained by the ultrasound transducer to a processor and display assembly. The first side of the main body housing includes a retention feature that is configured to retain the processor and display assembly in contact with the main body housing at a position and orientation relative to the main body housing.

This disclosure relates to a portable medical device comprising:

a medical equipment for the acquisition of data and a carrier system, wherein the medical equipment comprises:
a processing unit configured to process the data acquired using a probe linked to a processing unit,
and wherein the carrier system is configured to equip the body of the user of the device with the medical equipment.

An application running in a mobile device displays an ultrasound image obtained by a connected ultrasound scanner. A button is displayed on the device, which, when activated, automatically connects the device to a remote reviewer in a virtual videoconferencing room, without the operator of the scanner needing to input user credentials. Upon activating the button, or otherwise triggering the request for a review, pre-stored login credentials are automatically retrieved and used for connecting the operator to the room. The remote reviewer may be connected to the room upon accepting the request for review, without having to input user credentials, which are pre-stored and automatically retrieved.

Provided is a non-invasive system and method of determining muscle tissue size based on image processing. The method includes receiving at least one ultrasound scan image of at least a portion of a skin layer as disposed above one or more additional tissue layers, the image provided by a plurality of pixels. The method continues by introducing noise into the pixels of the image and thresholding the pixels of the image to provide a binary image having a plurality of structural elements of different sizes. The method continues with morphing the structural elements of the binary image to remove small structural elements and connect large structural elements. With this resulting image, the method distinguishes muscle tissue from remaining elements and determines the muscle tissue size. Associated apparatuses and computer program products are also disclosed.

The present embodiments relate generally to systems and methods for securing operation of an ultrasound scanner for use with a multi-use electronic display device. In some embodiments, the multi-use electronic display device can control whether the ultrasound scanner is permitted to generate ultrasound image data for display based on an institution affiliation status of the ultrasound scanner retrieved from a server. In some embodiments, the multi-use electronic display device can control whether the ultrasound scanner is permitted to generate ultrasound image data for display based on whether a digital certificate provided by a server is successfully validated.

A medical device for injecting fat while simultaneously allowing the injection site to be viewed with ultrasound. The device may comprise a handle with a front portion and a rear portion, a cannula having a cannula tip, extending from the front portion of the handle, and an ultrasound probe attached to the handle, the ultrasound probe comprising an ultrasound head. The ultrasound head is aligned with and spaced apart from the cannula tip, and remains so aligned during the injection process so that the injection area may be continuously viewed during the procedure.

An ultrasound image processing apparatus (10) is disclosed comprising a processor arrangement (16) adapted to map a model (1) of an anatomical feature of interest onto an ultrasound image showing at least a section of said anatomical feature of interest and to segment said ultrasound image in accordance with the mapped model; and a touchscreen display (18, 19) adapted to display said ultrasound image including the mapped anatomical model. The processor arrangement is responsive to the touchscreen display and adapted to recognize a type of a user touch motion (3) provided through the touchscreen display (18, 19), each type of user touch motion being associated with a particular type of alteration of said mapping and alter said mapping in accordance with the recognized type of user touch motion. Also disclosed are an ultrasound imaging system, a computer-implemented method and a computer program product.

A system and method for improved medical device navigation is disclosed. An example system can include a processor configured to determine an emplacement of a 2D medical image in a 3D virtual space, determine an emplacement of a virtual medical device in the 3D space, determine an intersection based on the emplacement of the 2D medical image and the emplacement of the virtual medical device, and/or determine a dynamic point-of-projection location for the virtual medical device based at least in part on the determined intersection. The processor can cause a display to display a rendering of the 2D medical image and a projection of the virtual medical device onto the 2D medical image from a perspective of the dynamic point-of-projection location. The display can be communicatively coupled to an imaging medical device. The viewing area can be parallel to a 2D region associated with the 2D medical image.