A surgical system includes a surgical instrument having a shaft and an end effector extending distally from the shaft. The end effector includes a plurality of ultrasound sensors supported about a support ring. The ultrasonic sensors are rotatable between an imaging orientation, wherein, the ultrasound sensors are directed in generally parallel orientations relative to one another for imaging tissue in an imaging mode, and at least one treatment orientation, wherein the ultrasound sensors are directed towards a common focus point for treating tissue in a treatment mode.

A patient bearing system and a robotic system are disclosed. The patient bearing system includes a patient bearing and at least one ultrasound transducer with an ultrasound head at least partly located in the patient bearing and being spatially located to transmit ultrasound signals to a target space. The ultrasound head is at least partly located in the patient bearing. The robotic system includes a patient bearing system and a robot configured for at least partly operate the system and the computer system is programmed for performing image acquisitions and analysis of a body part at least partly located in target space.

The following wires are connected to an actuator via a wire relay mechanism: the wire which acts to move a gas spring which restricts a movement of a parallel linkage which performs an up-down movement of the operation panel, the wire which acts to move a first lock pin which restricts a movement of a rotary pole which performs a first rotational movement of the operation panel, the wire which acts to move a second lock pin which restricts a movement of a mounting unit which performs a second rotational movement of the operation panel, and the wire which acts to move a third lock pin which restricts a movement of a slidable plate which performs a front-rear movement of the operation panel.

A system for detecting/quantifying the conductance of a right-to-left cardiac shunt includes a mouthpiece assembly, a solenoid-driven vacuum/pressurization assembly; a controller for operating the solenoid-driven vacuum/pressurization assembly; and a monitor for displaying the instructions from the controller. A microbubble counting cell and digital image sensor are combined with software-based image analysis to determine a number of microbubbles contained in a microbubble counting zone. A monitor enables operator specification of total volume of contrast agent to be injected into the patient. One or more first Doppler ultrasound transducer arrays are positioned adjacent to targeted intracranial arteries at one side of the skull or a pair of first Doppler ultrasound transducer arrays positioned adjacent to targeted intracranial arteries at both sides of the skull. A second Doppler ultrasound transducer is positioned on the precordium of the patient to detect the arrival of microbubble-containing contrast agent in the right atrium of the patient.

A breast screening equipment includes: a support table to support a subject in a prone position; and an examination mechanism having a cylinder which has an opening at an upper end so that a breast to be examiner is inserted and be protruded from an upper surface of the support table, wherein the examination mechanism conducts an ultrasound examination of the inserted breast in the cylinder. The cylinder includes a hollow portion which is located inside of a wall constituting the cylinder and is extended above the upper surface of the support table. The examination mechanism includes a ring-shaped ultrasound transmission reception mechanism being movable inside of the hollow portion vertically.

Systems and methods for visualizing two-dimensional (2D), three-dimensional (3D), and four-dimensional (4D) ultrasound images generated by an ultrasound device are disclosed. In one aspect, the method includes displaying a display state selection on a user interface of a display screen in communication with a computing device, the display state selection indicating to receive 2D or 3D images. The method further includes receiving, from the user interface, a display state user selection indicating to generate 2D or 3D images. The method further includes, in response to receiving the display state user selection, controlling the ultrasound device to generate ultrasound images of the selected display state and communicate the generated ultrasound images to the computing device. The method further includes displaying the received ultrasound images on a portion of the display screen.

Embodiments provide for a support system for a portable ultrasound machine. In one example, the support system includes a carrier for an imaging display and a bracket for a beamformer, where the bracket mechanically couples to the carrier in a plurality of positions depending on a desired use of an operator of the portable ultrasound machine. In this way, operational aspects related to use of the portable ultrasound machine, and satisfaction of a user thereof, may be improved.

Handheld ultrasound imaging devices for identification of target regions are generally described. Medical ultrasound is a popular medical imaging modality primarily used for diagnostic imaging of soft tissue but also for interventional procedures such as guidance of a needle or catheter placement. Examples include diagnostic imaging of organs, such cardiac or liver structures. Common interventional procedures that rely on ultrasound guidance are central line placement and guidance of nerve blocks, both of which are high volume procedures in certain hospital settings such as the intensive care unit (ICU). Handheld ultrasound imaging devices with integral display screens and improve portability are described, along with systems and methods for orienting displayed ultrasound images so as to improve their usefulness in guiding interventional procedures.

Programmable ultrasound probes and methods of operation are described. The ultrasound probe may include memory storing parameter data and may also include a parameter loader which loads the parameter data into programmable circuitry of the ultrasound probe. In some instances, the ultrasound probe may include circuitry grouped into modules which may be repeatable and which may be coupled together to allow data to be exchanged between the modules.

Described herein are methods and apparatuses for packaging an ultrasound-on-a-chip. An ultrasound-on-a-chip may be coupled to a redistribution layer and to an interposer layer. Encapsulation may encapsulate the ultrasound-on-a-chip device and first metal pillars may extend through the encapsulation and electrically couple to the redistribution layer. Second metal pillars may extend through the interposer layer. The interposer layer may include aluminum nitride. The first metal pillars may be electrically coupled to the second metal pillars. A printed circuit board may be coupled to the interposer layer.