The present disclosure provides an ultrasonic transducer and a focused ultrasound treatment device. The ultrasonic transducer includes a sound generation unit and a sound emitting surface, the sound emitting surface being a spherical surface having a first notch, a second notch and a third notch, wherein one great circle of a sphere corresponding to the sound emitting surface is a main great circle, the first notch and the second notch are respectively positioned at two intersections of the spherical surface and a diameter perpendicular to the main great circle, and the third notch connects the first notch with the second notch; each cross-section of the sound emitting surface parallel to the main great circle is in a shape of an arc; and the ultrasonic wave generated by the sound generation unit is focused on a center of the sphere corresponding to the sound emitting surface.

The present invention relates to a therapeutic ultrasonic wave generating device. The present invention includes: a rotating motor; an ultrasonic wave generating unit being provided with a transducer generating ultrasonic waves; and a focus rotation movement unit moving the focus of the ultrasonic waves generated by the ultrasonic wave generating unit in a circle on the same plane by receiving a transmission of rotational force of the rotating motor. The present invention enables: the focus of ultrasonic waves to be moved in the circle having a constant radius at a uniform depth under the skin; and energy to be applied uniformly and evenly within the movement radius, thereby enabling enhancement of therapeutic performance.

An ultrasonic apparatus (100) for creating a holographic ultrasound field (1) comprises an ultrasound source device (10) being adapted for creating an ultrasound wave, and a transmission hologram device (20) having a transmission hologram (21) and an exposed acoustic emitter surface (22), said transmission hologram device (20) being acoustically coupled with the ultrasound source device (10) and being arranged for transmitting the ultrasound wave through the acoustic emitter surface (22) and creating the holographic ultrasound field in a surrounding space, wherein the acoustic emitter surface (22) is a smooth surface which do not influence the field distribution of the ultrasound wave. Furthermore, a method of creating a holographic ultrasound field in an object (3), wherein the ultrasonic apparatus (100) is used, and applications of the ultrasonic apparatus (100) are described.

We provide a novel technique for coupling focused ultrasound into the brain. The ultrasound beam can be used for therapy or neuro-modulation. We excite a selected Lamb wave mode in the skull that mode converts into longitudinal waves in the brain. The benefits of our approach is in improved efficiency, reduction in heating of the skull, and the ability to address regions in the brain that are close or far from the skull.

Various approaches for microbubble-enhanced ultrasound treatment of target tissue include retrieving a treatment plan stored in memory; causing administration of an exogenous agent in accordance with the treatment plan; causing, in accordance with the treatment plan, an ultrasound transducer to transmit ultrasound waves to the target tissue and generate a focus therein in the presence of administered exogenous agent; receiving, from a monitoring system, a measured parameter value indicating a treatment condition in response to administration of the exogenous agent and transmission of the ultrasound waves during treatment; and adjusting the treatment plan based at least in part on the measured parameter value.

Methods and systems for treating skin, such as stretch marks through deep tissue tightening with ultrasound are provided. An exemplary method and system comprise a therapeutic ultrasound system configured for providing ultrasound treatment to a shallow tissue region, such as a region comprising an epidermis, a dermis or a deep dermis. In accordance with various exemplary embodiments, a therapeutic ultrasound system can be configured to achieve depth with a conformal selective deposition of ultrasound energy without damaging an intervening tissue. In addition, a therapeutic ultrasound can also be configured in combination with ultrasound imaging or imaging/monitoring capabilities, either separately configured with imaging, therapy and monitoring systems or any level of integration thereof.

An ultrasound system includes transmit circuitry configured to produce a push pulse electrical excitation signal and a transducer array configured to receive the push pulse electrical excitation signal and transmit a push pulse that produces acoustic and shear wave propagation in tissue of interest, where the push pulse is based on a pre-determined set of parameters stored in computer readable medium. A computer-implemented method includes producing a push pulse electrical excitation signal and includes transmitting, based on the push pulse electrical excitation signal, a push pulse that produces acoustic and shear wave propagation in tissue of interest. A computer readable medium is encoded with computer executable instructions, which, when executed by a processor, cause the processor to perform the method. In one instance, the push pulse promotes shedding of lining cells of the tissue of interest in connection with a biopsy of shed cells for the tissue of interest.

According to an exemplary embodiment of the present disclosure, high intensity focused ultrasound device delivering high intensity focused ultrasound is disclosed. The high intensity focused ultrasound device comprising: a gripping part constituting a part of an outer housing of the high intensity focused ultrasound device and forming a grippable shape by a user, and an action part positioned at least partially on an extension line of a vertical cross-section of the gripping part and transmitting high intensity focused ultrasound generated from the high intensity focused ultrasound device to an outside.

Systems and methods can include wearable, non-invasive ultrasound modalities for treating a variety of medical conditions, including but not limited to peripheral vascular disease. The modality could be therapeutic ultrasound (TUS), and be configured to promote angiogenesis within a patient via stimulation of cavitation and shear stress, among other mechanisms.

The invention provides for a medical apparatus (200, 400, 500) comprising a high intensity focused ultrasound system (206). Machine executable instructions (260, 262, 264, 266, 408, 526) in a memory (250) cause a processor (244) to: receive (100) location data (252) descriptive of multiple sonication points (224, 226, 228, 230); determine (102) a sonication path (254) for each of the multiple sonication points using a geometric transducer element model (262); detect (104) an overlap region (256, 306) using the sonication path in the near field region; determine (106) transducer control commands (258) using the overlap region, wherein the transducer commands are operable to control the multiple transducer elements to reduce the deposition of ultrasonic energy in the overlap region during sonication of the two or more sonication points; and control (108) the high intensity focused ultrasound system using the transducer control commands.