An apparatus may include an ultrasonic receiver array, an ultrasonic transmitter and a control system capable of controlling the ultrasonic transmitter to transmit first ultrasonic waves in a first direction and to simultaneously transmit second ultrasonic waves in a second direction that is opposite the first direction. The control system may be capable of distinguishing first reflected waves from second reflected waves, the first reflected waves corresponding to reflections of the first ultrasonic waves that are received by the ultrasonic receiver array and the second reflected waves corresponding to reflections of the second ultrasonic waves that are received by the ultrasonic receiver array. The control system may be capable of determining first image data corresponding to the first reflected waves and of determining second image data corresponding to the second reflected waves.

A wearable ultrasound device for signalling changes in human or animal body, and use of such a wearable device for signalling over a prolonged period of time. In an example the changes occur in a bladder. Such is especially relevant for elderly persons, women after delivery of a baby, lesion patients, demented people, children, and others, have a difficulty to control functioning of the bladder, and to be at the toilet on time to urinate.

A system and a method of non-invasive continuous echocardiographic monitoring is provided with an ultrasound transducer and a bedside monitor. The beside monitor includes a monitor central processing unit (CPU). First, the ultrasound transducer is attached onto a specific skin portion of a patient. The specific skin portion is positioned adjacent to a patient's heart. Next, continuous echocardiographic data is sensed with the ultrasound transducer. After relaying the continuous echocardiographic data from the ultrasound transducer to the monitor CPU, the monitor CPU generates a real-time ultrasound image of the heart from the continuous echocardiographic data. Finally, the real-time ultrasound image is outputted with the bedside monitor. If the bedside monitor has a main screen, then the real-time ultrasound image is displayed through a picture-in-picture format with the main screen. Otherwise, if the beside monitor has an ancillary screen, then the real-time ultrasound image is exclusively displayed with the ancillary screen.

A wearable patch (10) comprising an ultrasound transducer (30) mounted on the patch, the ultrasound transducer comprising a major surface for contacting the skin of a wearer of the patch, said major surface being covered by a layer (33) of a soluble adhesive precursor, the wearable patch further comprising a seal ring (40) extending from the patch, said seal ring surrounding the ultrasound transducer. Also disclosed are a wearable patch kit, assembly and application method.

A liner associated with an adhesive skin patch of a physiological characteristic sensor includes a first end opposite a second end. The liner includes a first side opposite a second side. The liner includes a surface to couple to the adhesive skin patch, at least a portion of which extends from the first end to the second end. The liner includes at least one graspable member defined between the first side and the second side that extends beyond the first end or the second end to initiate a peel of the liner from the adhesive patch at a center of the liner.

A method for determining a geometry of an ear canal or a portion of an ear of a person may include filling the ear canal and/or the portion of the ear with a liquid or a gel, inserting a capacitive micromachined ultrasonic transducer probe or a piezoelectric micromachined ultrasonic transducer probe, acquiring data using the probe, and processing the acquired data to obtain a 2D or 3D image of the ear canal and/or the portion of the ear.

A bladder monitoring system includes a scanning system and a wearable bladder monitoring device (or patch). The scanning system obtains scan data that shows a bladder in a patient and identifies, based on the scan data, a placement location on the patient for the wearable bladder monitoring device. The scanning system indicates the placement location to a user; and identifies customization settings for one or more sensors of the wearable bladder monitoring device to enable the one or more sensors to detect extents of the bladder when the wearable bladder monitoring device is attached at the placement location.

Disclosed herein is an ultrasound probe securement device to secure an ultrasound probe to a patient. The securement device can include a probe coupling mechanism to couple an ultrasound probe to the securement device, a patient coupling mechanism to couple the securement device to a patient, and a constraining mechanism to maintain an acoustic coupling of the ultrasound probe with the patient during an ultrasound procedure without user intervention.

A method for monitoring a patient using an ultrasonic probe includes attaching a conformable two-dimensional piezoelectric transducer array having a plurality of phased array piezoelectric transducer elements on an epidermal surface of a patient so that the conformable two-dimensional piezoelectric transducer array conforms to a shape of the epidermal surface. The conformable two-dimensional piezoelectric transducer array is attachable to the epidermal surface by van der Waals forces alone. The plurality of phased array piezoelectric transducer elements is operated as a phased array to transmit a focused ultrasonic beam to a specified location in the patient to be monitored. Ultrasound waves are received from the patient using the array. An indication of the received ultrasound waves is displayed.

A piezoelectric actuator includes a vibrating plate including a first surface that closes an opening provided in a substrate and a second surface in which a plurality of piezoelectric elements is provided, a suppression part configured to suppress a vibration of the vibrating plate, and a first wall and a second wall protruding from the first surface to the opening. When a portion where the first electrode, the piezoelectric layer and the second electrode overlap each other is an active part of the piezoelectric element, the first wall and the second wall are provided to sandwich the active part in plan view from the stacking direction of the first electrode, the piezoelectric layer and the second electrode, and the second wall is different from the first wall at least in one of the width, height, length and physical property.