Various embodiments provide methods and systems for ultrasound treatment of tissue are provided. Accordingly, a method can include locating an implant in a site in a body, directing a medicant to at least one of the implant and the site, directing ultrasound energy to the site, and accelerating healing of the implant and/or native tissue at the site.

Systems and methods for non-invasive fat reduction can include targeting a region of interest below a surface of skin, which contains fat and delivering ultrasound energy to the region of interest. The ultrasound energy generates a thermal lesion with said ultrasound energy on a fat cell. The lesion can create an opening in the surface of the fat cell, which allows the draining of a fluid out of the fat cell and through the opening. In addition, by applying ultrasound energy to fat cells to increase the temperature to between 43 degrees and 49 degrees, cell apoptosis can be realized, thereby resulting in reduction of fat.

A probe for ultrasound treatment of skin laxity are provided. Systems and methods can include ultrasound imaging of the region of interest for localization of the treatment area, delivering ultrasound energy at a depth and pattern to achieve the desired therapeutic effects, and/or monitoring the treatment area to assess the results and/or provide feedback. In an embodiment, a treatment system and method can be configured for producing arrays of sub-millimeter and larger zones of thermal ablation to treat the epidermal, superficial dermal, mid-dermal or deep dermal components of tissue.

Systems and 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. Lifting sagging tissue on a face, neck, and/or body are described. Treatment with heat is provided in several embodiments.

Implementations described herein include a device including a stimulation transducer operably coupled to a stimulation controller. The stimulation transducer focally delivers energy to a target tissue at a selected depth below the surface of the skin of a subject and the stimulation controller generates a signal indicating a selected pulse intensity, a selected pulse duration, and a selected treatment session duration sufficient to heat the target tissue to a temperature from 40 to 45 degrees Celsius via application of energy by the stimulation transducer. When the stimulation transducer receives the signal from the stimulation controller, the stimulation transducer focally delivers energy having the selected pulse intensity, the selected pulse duration, and the selected treatment session duration to heat the target tissue to selectively and reversibly activate afferent nerve fibers having thermo-sensitive ion channels to send sensory information to the central nervous system without causing any permanent changes to the target tissue.

The present invention discloses an therapeutic ultrasonic device consisting of at least one arc ultrasonic transducer that can be assembled. The arc ultrasonic transducer comprises a protruding part, a concave part and a plurality of piezoelectric vibrating parts. The protruding part and the concave part are disposed at two ends of the arc ultrasonic transducer respectively, and the piezoelectric vibrating parts are disposed at the inner arc face of the arc ultrasonic transducer. Various numbers of arc ultrasonic transducers can be used in assembled structure or non-assembled structure according to different body size and focal zones of various target tissue. Thus the therapeutic ultrasonic device of the present invention is widely used in treatment of various indications.

Lung tumors are treated in-vitro and in-vivo by an apparatus and method for operating the apparatus wherein the lung being treated is made receptive to ultrasound in order to allow the ultrasound waves to be guided through the healthy lung tissue to the tumor tissue in an optimized manner for the use of FUS therapy.

Disclosed are a multi-focusing device for each ultrasonic depth including a micro-machined ultrasonic transducer array and a method of operating the same. The multi-focusing device includes a micro-machined ultrasonic transducer (MUT) array arranged in an annular form and formed of a plurality of vibration elements that apply a low or high frequency corresponding to an application depth inside the skin, wherein the MUT array includes an upper electrode parallel connection line configured for each channel of the vibration element, and a lower electrode connection line arranged in a longitudinal direction.

A probe for ultrasound treatment of skin laxity are provided. Systems and methods can include ultrasound imaging of the region of interest for localization of the treatment area, delivering ultrasound energy at a depth and pattern to achieve the desired therapeutic effects, and/or monitoring the treatment area to assess the results and/or provide feedback. In an embodiment, a treatment system and method can be configured for producing arrays of sub-millimeter and larger zones of thermal ablation to treat the epidermal, superficial dermal, mid-dermal or deep dermal components of tissue.

Systems and methods for non-invasive fat reduction can include targeting a region of interest below a surface of skin, which contains fat and delivering ultrasound energy to the region of interest. The ultrasound energy generates a thermal lesion with said ultrasound energy on a fat cell. The lesion can create an opening in the surface of the fat cell, which allows the draining of a fluid out of the fat cell and through the opening. In addition, by applying ultrasound energy to fat cells to increase the temperature to between 43 degrees and 49 degrees, cell apoptosis can be realized, thereby resulting in reduction of fat.