Methods for diagnosing a pathologic tissue membrane, as well as a focused ultrasound apparatus and methods of treatment are disclosed to perform ureterocele puncture noninvasively using focused ultrasound-generated cavitation or boiling bubbles to controllably erode a hole through the tissue. An example ultrasound apparatus may include (a) a therapy transducer having a treatment surface, wherein the therapy transducer comprises a plurality of electrically isolated sections, (b) at least one concave acoustic lens defining a therapy aperture in the treatment surface of the therapy transducer, (c) an imaging aperture defined by either the treatment surface of the therapy transducer or by the at least one concave acoustic lens and (d) an ultrasound imaging probe axially aligned with a central axis of the therapy aperture.

A portable defibrillator according to embodiments of the present invention includes a defibrillator engine configured to receive defibrillator information from defibrillator sensors coupled to a patient and display the defibrillator information; an external device engine configured to receive information from medical device sensors coupled to the patient; a medical device virtual machine configured to display the patient parameter information from the external device engine; and a display screen operating a user interface through which the defibrillator engine displays the defibrillator information and the medical device virtual machine displays the patient parameter information from the external device engine.

An ultrasound probe includes: an ultrasound transducer provided on a distal end side of an outer tube; an actuator including a movable portion configured to perform a reciprocating motion; and a conversion mechanism. The conversion mechanism is arranged in the longitudinal direction of the outer tube in series with the actuator in the longitudinal direction, arranged in parallel to the ultrasound transducer in the longitudinal direction, and configured to convert the reciprocating motion of the movable portion to a swing motion of the ultrasound transducer. A working point in the mechanism is positioned off a center axis of the outer tube and a center axis of driving force of the reciprocating motion in the movable portion, and the center axis of the driving force of the reciprocating motion in the movable portion is displaced to the working point side by a predetermined distance relative to the center axis.

Systems and methods of real-time augmented visualization of anatomical features are disclosed herein. The systems and methods can use concurrently collected and/or preexisting data regarding an anatomical structure to present an image of the anatomical structure to an operator in virtual space as overlayed in real space. The systems and methods can include acquiring image data from an anatomical structure of a subject. Visual image data of the subject can then be received, including non-rigid deformation of the subject. The device pose of the ultrasound device in real space can be determined using device pose data. Image pose of the image data can then be determined in virtual space. Then, a perspective pose of the image of at least a portion of the anatomical structure in virtual space can be mapped to the subject in real space.

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 rotational intravascular ultrasound probe for insertion into a vasculature and a method of manufacturing the same. The rotational intravascular ultrasound probe comprises an elongate catheter having a flexible body and an elongate transducer shaft disposed within the flexible body. The transducer shaft comprises a proximal end portion, a distal end portion, a drive shaft extending from the proximal end portion to the distal end portion, an ultrasonic transducer disposed near the distal end portion for obtaining a circumferential image through rotation, and a transducer housing molded to the drive shaft and the ultrasonic transducer.

An apparatus comprises a sensor for measuring a physiological parameter of a subject, wherein the physiological parameter sensor is adapted to be worn by the subject; an actuator comprising an electro-active polymer material, EAP, portion for adjusting the position of the physiological parameter sensor relative to the subject; a feedback sensor for measuring movement of the physiological parameter sensor and/or the subject; a controller configured to process the measurements of the feedback sensor and to adjust the position of the actuator based on information from the feedback sensor.

A panel may include an inner edge, an outer edge opposite the inner edge, and a probe holder apparatus formed in the panel between the inner edge and the outer edge. The probe holder apparatus may have a generally rectangular shape comprising a front outer corner, a rear outer corner, a front inner corner, and a rear inner corner. The probe holder apparatus may include a slot, at least one surface within the probe holder apparatus, and a cable guide. The slot may extend from a center of the probe holder apparatus through the outer edge of the panel. The at least one surface may be configured to receive a body of an ultrasound probe. The at least one surface may have a diameter. The cable guide may include an inclined surface protruding from the front outer corner of the probe holder apparatus.

A method of changing a user interface (UI), which is used for diagnosis of a target object via a medical device, based on user motion information. The method including obtaining motion information regarding a user; changing the UI based on the obtained motion information regarding the user; and displaying the changed UI.

The present disclosure relates to an ultrasonic imaging apparatus that has a tolerance for easy assembly and reduces shaking and noise by reducing the tolerance after assembly. The ultrasonic imaging apparatus includes a main body, a probe connected to the main body to irradiate and receive ultrasonic waves and to transmit the ultrasonic signals to the main body, a control panel configured to control the main body or the probe, and a moving device configured to connect the control panel and the main body and to move the control panel with respect to the main body in the upward and downward directions, wherein the moving device includes a housing fixed to the main body, a moving member configured to be movable with respect to the housing in the upward and downward directions, and a regulating bearing installed in the housing and configured to assist the upward and downward movement of the moving member by coming into rolling contact with the moving member and to regulate a gap with the moving member.