A catheter system (100) for treating a treatment site (106) within or adjacent to a vessel wall (208A) or a heart valve within a body (107) of a patient (109) includes an energy source (124), a balloon (104), an energy guide (122A), and a tissue identification system (142). The energy source (124) generates energy. The balloon (104) is positionable substantially adjacent to the treatment site (106). The balloon (104) includes a balloon wall (130) that defines a balloon interior (146). The balloon (104) can be configured to retain a balloon fluid (132) within the balloon interior (146). The energy guide (122A) is configured to receive energy from the energy source (124) and guide the energy into the balloon interior (146) so that plasma bubbles (134) are formed in the balloon fluid (132) within the balloon interior (146). The tissue identification system (142) can be configured to acoustically analyze tissue within the treatment site (106).

A system to deliver energy to treat a mobile calculus, the system can include a drill and a lateral energy emitter. The drill can be configured to drill a recess into the mobile calculus or a passage through the mobile calculus. The lateral energy emitter can be configured to be advanced into the recess or the passage and to transmit the energy internal to the mobile calculus to fragment the mobile calculus. In some examples, the system can include a deployable capture portion to constrain a stone relative to the capture portion.

A valvuloplasty system comprises a balloon adapted to be placed adjacent leaflets of a valve. The balloon is inflatable with a liquid. The system further includes a shock wave generator within the balloon that produces shock waves. The shock waves propagate through the liquid and impinge upon the valve to decalcify and open the valve.

The present invention provides a catheter for treating an occlusion in a body lumen. The catheter includes an elongated tube, a first electrode pair and a second electrode pair each configured to generate shock waves. The catheter also includes a flexible polymer enclosure that is fillable with conductive fluid and wrapped circumferentially around at least a portion of the elongated tube such that it surrounds the first and second electrode pairs. The first and second electrode pairs can be arranged relative to one another to promote interference between shock waves generated at the electrode pairs when voltage is delivered across the electrodes of each pair. Electrode pairs can be longitudinally adjacent (spaced a relatively small longitudinal distance apart), longitudinally aligned (at the same longitudinal location), circumferentially offset (offset about the circumference of the catheter), circumferentially aligned (at the same circumferential location), or any combination of any of the above.

A balloon aortic lithotripsy assembly for placement adjacent an aortic valve. The balloon aortic lithotripsy assembly includes multiple balloon chambers, a shell, and a shock wave generator. The balloon chambers are arranged to establish an open interior residing inboard of the balloon chambers. The shell is located around the balloon chambers. The shock wave generator can be situated on one or more of the balloon chambers, the shell, or both of the balloon chamber(s) and shell. In use, blood is free to travel through the open interior, and the shock wave generator can produce shock waves that are intended to impinge calcified tissues residing at the aortic valve.

A surgical laser system comprises a laser source configured to generate laser energy; a laser fiber optically coupled to the laser source and configured to discharge the laser energy generated by the laser source; a rocker arm configured to control an orientation of the discharged laser energy; and a controller configured to control a movement of the rocker arm in response to feedback of the discharged laser energy or to pre-defined settings of the laser source.

A system that breaks calcium in a liquid includes a catheter including first and second electrodes arranged to receive there-across a high electrical voltage at an initial low current. The high electrical voltage causes an electrical arc to form across the electrodes creating a gas bubble within the liquid, a high current to flow through the electrodes, and a mechanical shock wave. A power source provides the electrodes with the high electrical voltage at the initial current and terminates the high electrical voltage in response to the high current flow through the electrodes.

An apparatus includes a balloon adapted to be placed adjacent a calcified region of a body. The balloon is inflatable with a liquid. The apparatus further includes a shock wave generator within the balloon that produces shock waves that propagate through the liquid for impinging upon the calcified region adjacent the balloon. The shock wave generator includes a plurality of shock wave sources distributed within the balloon.

A method for treating a treatment site (106) within or adjacent to a heart valve (108) within a body of a patient includes the steps of generating energy with an energy source (124); receiving energy from the energy source (124) with an energy guide (122A); positioning a balloon assembly (104) adjacent to the treatment site (106), the balloon assembly (104) including an outer balloon (104B) and an inner balloon (104A) that is positioned within and at least partially spaced-apart from the outer balloon (104B) to define an interstitial space (146A) therebetween that is configured to retain a balloon fluid (132); and positioning a portion of the energy guide (122A) that receives the energy from the energy source (124) within the interstitial space (146A) between the balloons (104A, 104B) so that a plasma-induced bubble (134) is formed in the balloon fluid (132) within the interstitial space (146A).

An invasive electrohydraulic lithotripter probe may comprise a lithotripter tip that comprises a first electrode and a second electrode. The lithotripter tip has a length in excess of 250 cm and is dimensioned to be inserted into a long channel having a length in excess of 250 cm. The lithotripter probe may include a material that reinforces a linear strength of at least a portion of the lithotripter probe.