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.

In some examples, a catheter includes an elongated member including at least one balloon connected to the elongated member, the at least one balloon being configured to inflate to an expanded state. In the expanded state, the at least one balloon forms at least a portion of a cavity with a wall of a vessel of the patient. The catheter including at least one electrode carried by the elongated member and having at least one surface exposed to the cavity formed by the at least one balloon. The electrode is configured to connect to an energy source that is configured to deliver, via the electrode, an electrical signal to a fluid contained in the cavity and in contact with the electrode to cause the fluid to undergo cavitation to generate a pressure pulse wave within the fluid.

A catheter system (100) for treating a vascular lesion (106) within or adjacent to a heart valve (108) within a body (107) of a patient (109), includes an energy source (124), and a plurality of spaced apart treatment devices (143). The energy source (124) generates energy. Each treatment device (143) includes (i) a balloon (104) that is positionable substantially adjacent to the vascular lesion (106), the balloon (104) having a balloon wall (130) that defines a balloon interior (146), the balloon (104) being configured to retain a balloon fluid (132) within the balloon interior (146); and (ii) at least one of a plurality of energy guides (122A) that receive energy from the energy source (124) so that plasma (134) is formed in the balloon fluid (132) within the balloon interior (146).

MRI interference with a concurrently operated system may be reduced or corrected by subtracting the MRI interference from signals measured using the concurrently operated system. Various approaches for performing MRI of an anatomic region in conjunction with a radio-frequency-sensitive (RF-sensitive) measurement of the region using the concurrently operated system include the steps of simultaneously performing an MR scan sequence including MR pulses and the RF-sensitive measurements; recording the RF-sensitive measurements as they are made; detecting intervals during the MR scan sequence when an RF level is sufficient to interfere with the RF-sensitive measurements; and retaining only the RF-sensitive measurements performed outside the detected intervals.

Various approaches to focusing an ultrasound transducer includes causing the ultrasound transducer to transmit ultrasound waves to the target region; causing the detection system to indirectly measure the focusing properties; and based at least in part on the indirectly measured focusing properties, adjusting a parameter value associated with at least one of the transducer elements so as to achieve a target treatment power at the target region.

Various approaches for microbubble-enhanced ultrasound treatment of target tissue include receiving a desired characteristic of the microbubbles for treating the target tissue; causing the microbubbles to be dispensed from the administration device; and comparing a characteristic of the dispensed microbubbles to the desired characteristic so as to validate a match therebetween.

A method of treating a mobile target tissue with a laser beam includes: providing a laser device for generating a laser beam and providing an optical fiber having a delivery end for guiding the laser beam to the target tissue; a controller causes the laser device to generate one or more laser pulses substantially along the same longitudinal axis. The controller causes the laser device to provide one or more laser pulses. The one or more pulses are selected to allow a vapor bubble formed by the one or more pulse to expand an amount sufficient to displace a substantial portion of the liquid medium from the space between the delivery end of the fiber and the target tissue. The one or more pulses are delivered to the target tissue through the vapor bubble after the vapor bubble has reached its maximum extent and has begun to collapse to reduce retropulsion of the mobile target tissue.

A method and system for secure ultrasound treatment of living tissues using an ultrasound probe comprising a reflective cavity in acoustic communication with living tissues, a transducer to emit an ultrasound wave in the reflective cavity and a transducer to acquire a backscattered signal in the reflective cavity. The method comprises the steps of a) emitting a first ultrasound wave in the reflective cavity that generates a backscattered ultrasound wave in the reflective cavity, b) acquiring a backscattered signal in the reflective cavity, c) determining whether an insonification can be safely performed by computing a similarity value between the backscattered signal and a predefined reference signal, and d) if an insonification can be safely performed, treating the living tissues with a second ultrasound wave emitted in the reflective cavity. The second ultrasound wave is focused a target point of the living tissues and generates a pressure point resulting in cavitation at this target point.

Ultrasonic sonothrombolysis systems to produce two acoustic pressure levels of insonation during stroke therapy, mid/high acoustic pressure insonation directed to the site of a blood clot where microbubbles are present to induce microbubble-mediated blood clot lysis, and low acoustic insonation directed to the region surrounding the site of the blood clot where microbubbles are present to stimulate microvascular reperfusion of the surrounding tissue. The systems simultaneously produce blood clot lysis at the site of an occlusion and stimulate reperfusion of tissue affected by the occlusion.