An ultrasound transducer assembly is connectable to an ultrasound system and comprises one or more ultrasound transducer elements supported by a cap. The ultrasound transducer elements are operable to direct ultrasound energy toward brain tissue of a subject and/or to receive echo ultrasound energy when the ultrasound transducer assembly is mounted on the head of the subject. Some embodiments include a fillable jacket coupled to the inner surface of the cap and in acoustic contact with the one or more transducer elements.

A sonic inspection device according to an embodiment includes: a sonic probe that includes a transducer configured to perform at least one of transmitting a sound wave and receiving a sound wave and has a sonic function surface constituting at least one of a transmitting surface of the sound wave and a receiving surface of the sound wave; a contact member that includes a couplant and a sheet-shaped member, the couplant having a first surface, which is in contact with the sonic function surface of the sonic probe directly or while interposing an intermediate member, and a second surface on an opposite side of the first surface, and containing an elastomer, and the sheet-shaped member laminated with the couplant to be in contact with the second surface and containing a polymer; and a loading mechanism configured to apply a load to the contact member.

This disclosure concerns a device for an ultrasound probe for acquiring ultrasound data from a medium, wherein the device is configured to be linked to the probe in a swiveling manner, so that the angle between the probe and the surface of the medium can be adjusted and/or set by swiveling the device.

A pliable cover adapted to cover an active area of an ultrasound probe is described. The ultrasound probe includes a plurality of ultrasound transducer elements. The pliable cover includes a polymer layer that holds a coupling agent (4) that couples the ultrasound transducer elements to a body surface and a regular pattern of channels extending through the pliable cover. An ultrasound probe arrangement is also described and includes the pliable cover. An ultrasound system including the ultrasound probe arrangement, and a method of positioning the ultrasound probe in a region of a body are also described.

An optoacoustic system and method for providing enhanced laser safety includes a laser light source, a control and processing system, a laser override, and an array of optoacoustic transducers. The laser light source is capable of generating a laser light pulse upon receiving a laser light source trigger. The control and processing system is configured to generate a laser light source trigger, to receive and process ultrasound data, and to control operation of the optoacoustic system. The control and processing system determines whether received ultrasound data reflects acoustic coupling between the transducer array and the volume. The laser override is configured to automatically prevent the generation of a laser light pulse if received ultrasound data does not reflect acoustic coupling between the optoacoustic transducer array and the volume.

An ultrasound imaging system which uses multiline receive beamforming for synthetic transmit focusing are phase adjusted to account for speed of sound variation in the transmission medium. The phase discrepancy of the received multilines caused by speed of sound variation in the medium is estimated in the frequency domain for both the transmit angular spectrum and the receive angular spectrum. The phase variation is removed in the frequency domain, then an inverse Fourier transform is used to transform the frequency domain results to the spatial domain. In another implementation, the phase discrepancy of the received multilines is estimated and corrected entirely in the spatial domain.

Arrangements described herein relate to systems, apparatuses, and methods for an enclosure for a device having a probe supported by a housing. The housing defines a cavity through which the probe protrudes. The probe is configured to move within the cavity. The enclosure includes a removable enclosure body. The enclosure body is configured to enclose at least a portion of the housing while covering an entirety of the cavity. The enclosure further includes a probe interaction portion in the enclosure body. The probe interaction portion is configured to be operatively engaged with the probe such that the probe is configured to transmit acoustic energy to a subject from within the enclosure.

A wearable ultrasound apparatus is disclosed for use in connection with various biomedical applications, including musculoskeletal (“MSK”) imaging and analysis, In at least one embodiment, the apparatus provides at least one of an ultrasound module configured for obtaining an at least one ultrasound image of a portion of a user’s body on which the at least one ultrasound module is positioned (hereinafter referred to as the “target site” for simplicity purposes), a electrophysiological (“EP”) module configured for detecting bioelectric signals of the target site, and a near-infrared spectroscopy (“NIRS”) module configured for monitoring oxygenation status and/or biochemical measurements of the target site.

An ultrasonic diagnostic apparatus of an embodiment includes a processing circuitry. The a processing circuitry acquires contact information detected by a plurality of contact sensors provided at different positions on an ultrasonic probe inserted into a body cavity of a subject and causes an output interface to output information representing a state of the ultrasonic probe in the body cavity on the basis of the contact information and the positions of the contact sensors provided on the ultrasonic probe.

A catheter that comprises a catheter configured for housing at least a portion of a catheter configured for insertion into a body lumen in proximity of a targeted anatomical site and having an imager at a distal end thereof and an adjustable chamber configured for covering the imager. The catheter is configured for introducing a wave conductive medium to the adjustable chamber to increase wave conductivity between the targeted anatomical site and the imager.