Device for the treatment of tissue calcification, in particular aortic valve leaflets, characterized by the fact that it comprises a first ultrasound emission source that is adapted to provide ultrasound waves with MHz frequencies and a second ultrasound emission source that is adapted to provide ultrasound waves with KHz frequencies, both MHz and KHz waves being used for the said treatment. The invention also includes a method for the treatment of tissue calcification that is characterized by the simultaneous use of ultrasound waves with MHz frequencies and ultrasound waves with KHz frequencies.

A catheter assembly includes a catheter comprising a flexible elongated member including a distal portion that includes a tubular body defining an inner lumen and a plurality of body apertures that extend through a sidewall of the tubular body into the inner lumen, and a plurality of primary electrodes positioned along the tubular body. The catheter assembly includes a wire defining at least one secondary electrode, the wire being configured to be slidably moved through the inner lumen of the tubular body, where the wire and the plurality of primary electrodes are configured to electrically couple to an energy source that delivers an electrical pulse to a fluid in contact with the plurality of primary electrodes and the at least one secondary electrode to cause the fluid to undergo cavitation to generate a pressure pulse wave within the fluid.

According to some embodiments there is provided a method for controlling a treatment effect on blood vessel tissue during an ultrasonic treatment, the method comprising positioning an ultrasonic transducer device in the blood vessel lumen; controlling a treatment effect by controlling fluid flow, wherein controlling comprises deploying a fluid restrictor at a location relative to the transducer effective to block at least a portion of fluid flowing upstream, downstream or adjacent the transducer. According to some embodiments there is provided an ultrasonic transducer device sized for placement in a body lumen, and comprising a fluid restrictor effective to block at least a portion of fluid flowing upstream, downstream or adjacent the transducer. In some embodiments, the fluid is blood.

A method for generating a mechanical wave, including generating a high amplitude mechanical pulse; coupling the mechanical pulse in a proximal end of a transmission member; propagating the mechanical pulse into the transmission member from the proximal end and a distal end thereof; and transmitting the mechanical pulse at the distal end.

Applications related to non-invasive magnetic resonance guided focused ultrasound (MRgFUS) in a patient's vasculature are described. For example, the applications can include an ablation procedure, an occlusion procedure, a cauterization procedure, and the like. Accordingly, one aspect of the present disclosure is directed to a method for performing an MRgFUS application that includes selecting a target area within a patient's vasculature, configuring multifocal acoustic waves, and applying the multifocal acoustic waves to the target area to heat sequential locations in the target area simultaneously to facilitate the MRgFUS application.

Shockwaves or modulated pressure waves are applied to targeted lung tissue of humans or animals, including lung tissue having a viral or bacterial infection or a chronic lung condition, to destroy or render innocuous different pathogens and treat the underlying chronic or acute medical conditions.

A cavitation seed for drug delivery, and a drug delivery method using the same are disclosed. The cavitation seed according to the present invention comprises: a shell which forms the outer surface thereof to maintain the outer shape thereof within a fluid; and a core which is located inside the shell to determine buoyancy of the cavitation seed within the fluid. The cavitation seed can improve an effect of delivering a drug into a body since cavitation is induced by ultrasound at a position close to the epidermis. In addition, the cavitation seed can be applied in the delivery of various drugs as well as skin cosmetics, such as skin tone lightening agents, depilatories, hair restorers and skin fillers, skin analgesics, local anesthetics, agents for genetic diseases such as psoriasis, and agents for treatment of skin disease such as skin cancer.

The present invention provides methods and devices for treating endovascular disease. Vibrational energy is delivered to change compliance and increase permeability at the treatment area. To improve clinical outcomes, one or more therapeutic drugs may be delivered to the treatment area.

A method for generating a mechanical wave, including generating a high amplitude mechanical pulse; coupling the mechanical pulse in a proximal end of a transmission member; propagating the mechanical pulse into the transmission member from the proximal end and a distal end thereof; and transmitting the mechanical pulse at the distal end.

In some examples, a medical device includes a flexible elongate member configured for navigation through vasculature of a patient to a target treatment site. A distal portion of the elongate member including a first balloon portion that is inflatable to an expanded state, a second balloon portion that is inflatable to an expanded state, and a cavitation generator. When the balloon portions are in their expanded states within the vasculature, a cavity is defined between the elongate member and the target treatment site and exterior to the first and second balloon portions. The cavitation generator is configured to deliver energy to a fluid within the cavity to cause the fluid to undergo cavitation to generate a pressure pulse wave within the fluid.