A dual-mode ultrasound system provides real-time imaging and therapy delivery using the same transducer elements of a transducer array. The system may use a multichannel driver to drive the elements of the array. The system uses a real-time monitoring and feedback image control of the therapy based on imaging data acquired using the dual-mode ultrasound array (DMUA) of transducer elements. Further, for example, multimodal coded excitation may be used in both imaging and therapy modes. Still further, for example, adaptive, real-time refocusing for improved imaging and therapy can be achieved using, for example, array directivity vectors obtained from DMUA pulse-echo data.

A therapy apparatus for treating tissue by emission of focused ultrasound waves, including: a creation surface of a pressure field of focused ultrasound waves divided into at least N sectors having segments of asymmetrical concave curve with centres of curvature; centres of curvature asymmetrical to the extent where the centres of curvature are situated at different distances from the plane of symmetry or from at least one of the axis of symmetry and at different depths taken according to the axis of symmetry; the individual axes intersecting between the focal zones and the creation surface or beyond the focal zones such that the beams originating from the sectors intersect to create a focal coverage zone which is off-axis relative to the plane of symmetry or to the axis of symmetry; the sectors of this creation surface creating energy deposit zones with profiles corresponding to the focal coverage zones.

Methods for treating skin and subcutaneous tissue with energy such as ultrasound energy are disclosed. In various embodiments, ultrasound energy is applied at a region of interest to affect tissue by cutting, ablating, micro-ablating, coagulating, or otherwise affecting the subcutaneous tissue to conduct numerous procedures that are traditionally done invasively in a non-invasive manner. Methods of lifting sagging tissue are described.

A method of delivery of an ultrasound-guided drug-loaded microbubble, an electronic device, and a computer-readable storage medium are provided. The method includes: emitting a first ultrasonic signal by utilizing an array transducer, to break a drug-loaded microbubble in a current breaking region; emitting a second ultrasonic signal by utilizing the array transducer, to obtain an ultrasound image; identifying a contour of a blood vessel of the breaking region based on the ultrasound image; and updating a characteristic parameter of the breaking region based on the contour of the blood vessel. According to the method, the breaking region is updated in real time based on the contour of the blood vessel, so that delivery accuracy of a drug-loaded microbubble is improved, and avoiding unnecessary tissue damage.

Methods for treating skin and subcutaneous tissue with energy such as ultrasound energy are disclosed. In various embodiments, ultrasound energy is applied at a region of interest to affect tissue by cutting, ablating, micro-ablating, coagulating, or otherwise affecting the subcutaneous tissue to conduct numerous procedures that are traditionally done invasively in a non-invasive manner. Methods of lifting sagging tissue are described.

An ultrasound transmitter device for treating a patient is provided. The ultrasound transmitter device includes an imaging probe; an imaging array; and a therapeutic ultrasound device, wherein the imaging probe is configured to guide the therapeutic ultrasound device to the patients treatment site by use of ultrasound imaging with the imaging array, wherein the therapeutic ultrasound device is configured to produce a controlled intensity of ultrasound energy for treating the patients treatment site, and wherein the imaging probe and the therapeutic ultrasound device are configured to work in conjunction with one another to apply therapeutic ultrasound to tissue or bone graft sites in the patient.

An appendage cooling and heating system has a body with an outer layer, an inner layer, and an interstitial space for containing a thermo-regulator material. The inner layer and the outer layer are nested to form a joint. An appendage opening is formed in the appendage cooling and heating system to receive an appendage of the user. The joint forms an interlocking seal between the outer layer and the inner layer to contain the thermo-regulator material within the interstitial space.

A therapeutic ultrasound system transmits a staggered or interleaved pattern of therapy beams for use in sonothrombolysis and other Vascular Acoustic Resonators (VAR) mediated therapy. The inventive technique minimizes VAR, e.g. microbubble, destruction due to adjacent beams, ensures uniform sonication of the targeted region by filling in the spaces between the beams in subsequent passes, and further provides a means for bubble replenishment to maximize the clot lysis from ultrasound. The technique is also applicable to diagnostic ultrasound, VAR mediated drug delivery and blood brain barrier opening.

A system for delivering ultrasound energy to an internal anatomical target includes an ultrasound transducer having multiple transducer elements collectively operable as a phased array; multiple driver circuits, each being connected to at least one of the transducer elements; multiple phase circuits; a switch matrix selectably coupling the driver circuits to the phase circuits; and a controller configured for (i) receiving as input a target average intensity level and/or an energy level energy to be applied to the target and/or a temperature level in target, (ii) identifying multiple sets of the transducer elements, each of the sets corresponding to multiple transducer elements for shaping and/or focusing, as a phased array, ultrasound energy at the target across tissue intervening between the target and the ultrasound transducer, and (iii) sequentially operating the transducer-element sets to apply and maintain the target average energy level at the target. In various embodiments, the controller operates each of the transducer element sets in accordance with a pulse-width modulation pattern having a duty cycle selected to achieve the target average intensity level, energy level, and/or temperature level at the target in accordance with a time constant of the target tissue.

Various approaches to generating and maintaining an ultrasound focus at a target region include configuring a controller to cause transmission of treatment ultrasound pulses from a transducer having multiple transducer elements; cause the transducer to transmit focusing ultrasound pulses to the target region and generate an acoustic reflector therein; measure reflections of the focusing ultrasound pulses from the acoustic reflector; based at least in part on the measured reflections, adjust a parameter value associated with one or more transducer elements so as to maintain and/or improve the ultrasound focus at the target region.