A composition for an acoustic lens contains the following components (A) to (C): (A) a polysiloxane having a vinyl group; (B) a polysiloxane having two or more Si—H groups in a molecular chain thereof; and (C) zinc oxide surface-treated with at least one surface treatment agent of an aminosilane compound, a mercaptosilane compound, an isocyanatosilane compound, a thiocyanatosilane compound, an aluminum alkoxide compound, a zirconium alkoxide compound, or a titanium alkoxide compound, provided that the aminosilane compound does not have a Si—N—Si structure.

An acoustic imaging system responsive to an acoustic wave emitted from an object is disclosed. The system detects a deflection angle of an electromagnetic probe beam as it passes through a coupling element. The coupling element also couples the acoustic wave emitted from the object to an acoustic detector. The probe beam deflection angle is related to an angle of propagation of the acoustic wave through the coupling element. A filtering unit is configured to remove components of the signal from the acoustic detector that are outside of a range of angles, thereby improving the angular resolution of the acoustic detector. The acoustic wave may be generated by an acoustic source, such as an ultrasound transmitter, or an electromagnetic source such as a laser.

Described herein are accelerator devices for providing a couplant while moving an ultrasound probe over a surface. The devices may include a reservoir configured to hold ultrasound couplant. The reservoir may attach to a probe so as to dispense the couplant at one or more locations along a perimeter of the probe while moving the ultrasound probe over the surface. The devices may additionally, or alternatively, include a membrane configured to hold ultrasound couplant. The membrane may charge a couplant layer of an ultrashield prior to or while moving the ultrasound probe over a surface during an ultrasound procedure.

Systems and methods for noninvasive tissue tightening are disclosed. Thermal treatment of tissues such as superficial muscular aponeurosis system (SMAS) tissue, muscle, adipose tissue, dermal tissue, and combinations thereof are described. In one aspect, a system is configured for treating tissue through delivery of ultrasound energy at a depth, distribution, temperature, and energy level to achieve a desired cosmetic effect.

A skin-mountable device (10) is disclosed comprising a surface (11) carrying an adhesive layer (20) for adhering the device to a skin region (1) and a removable non-adhesive cover layer (30) shaped as a loop having a first loop portion (31) covering the entire adhesive layer and a second loop portion (35) returning over the first loop portion, the second loop portion containing a pull tab (37) for pulling the cover layer from the adhesive layer when the skin-mountable device is positioned on said skin region. Also disclosed is a method of affixing such a skin-mountable device (10) to a skin region (1).

Systems, devices, and methods are disclosed for acquiring and providing information about orthopedic features of a body using acoustic energy. In some aspects, an acoustic orthopedic tracking system includes portable acoustic transducers to obtain orthopedic position information for feeding the information to an orthopedic surgical system for surgical operations.

A method and system for optimizing RF energy delivery to a tissue ROI with a thermoacoustic system includes directing with a RF applicator, RF energy pulses into the tissue ROI having an object of interest and a reference separated by a boundary; detecting with a thermoacoustic transducer, a multi-polar thermoacoustic signal generated at the boundary in response to the RF energy pulses and processing the multi-polar acoustic signal to determine a peak-to-peak amplitude; detecting with the thermoacoustic transducer, an artifact multi-polar thermoacoustic signal generated at a location other than the boundary and processing it to determine a peak-to-peak amplitude; utilizing an electromagnetic model coupled with a model of patient anatomy to place dielectric or conducting materials near the thermoacoustic transducer or the RF applicator to optimize a signal-to-noise ratio of the multi-polar thermoacoustic signal generated at the boundary or minimize the artifact multi-polar thermoacoustic signal generated at a location other than the boundary; and directing with the RF applicator, RF energy pulses into the ROI for a thermoacoustic measurement and determine a parameter of the object of interest.

The present invention provides an acoustic coupling interface (1) for use between a flexible ultrasound transducing device (2) and a curved object (3) to be examined. The interface (1) is in the form of a sheet (4) having a bending flexibility that permits the sheet (4) to form a continuous contact with said curved object (3) during operation of the flexible ultrasound transducing device (2). Further, the sheet (4) comprises a bulk material (5) and a plurality of acoustic waveguiding structures (6) arranged in said bulk material (5), wherein the plurality of acoustic waveguiding structures (6) is for providing bidirectional coupling of ultrasound signals (7) emitted by the ultrasound transducing device (2).

A device is provided for automatically assessing functional hemodynamic properties of a patient is provided, the device comprising: a housing; an ultrasound unit coupled to the housing and adapted for adducing ultrasonic waves into the patient at a vessel; a detector adapted to sense signals obtained as a result of adducing ultrasonic waves into the patient at the vessel and to record the; and a processor adapted for receiving the recorded signals as data and transforming the data for output at an interface. Other devices, systems, methods, and/or computer-readable media may be provided in relation to assessing functional hemodynamics of a patient.

Devices and method are provided for ultrasound transmission without the need for external couplants, such as gels, which are typically used in conventional ultrasound procedures. In particular, ultrashields are provided for use with ultrasound probes, wherein the ultrashields have specialized layers to provide an uninterrupted pathway of acoustic conductance from the probe to the surface of the body throughout the procedure while introducing minimal to no attenuation of ultrasound wave transmission. In addition, combinations of ultrashields and probe covers are provided to provide additional features such as a microbial barrier.