A catheter system (100) includes an inflatable balloon (104), an optical fiber (122), and a laser (124). The optical fiber (122) has a distal end positioned within the inflatable balloon (104). The optical fiber (122) receives an energy pulse (431) to emit light energy in a direction away from the optical fiber (122) to generate a plasma pulse (134) within the inflatable balloon (104). The laser (124) includes a seed source (126) that emits a seed pulse (342) and an amplifier (128) that increases energy of the seed pulse (342) so that the laser (124) generates the energy pulse (431) that is received by the optical fiber (122), the energy pulse (431) having a waveform with a duration T, a minimum power PO, a peak power PP, and a time from PO to PP equal to TP.

A catheter system (100) for treating a treatment site (106) within or adjacent to a vessel wall (108A) or a heart valve includes a light source (124), a first light guide (122A), a second light guide (122A), and a guide bundle (152). The light source (124) generates light energy. The first light guide (122A) receives the light energy from the light source (124) and has a guide proximal end (122P). The second light guide (122A) receives the light energy from the light source (124) and has a guide proximal end (122P). A guide bundle (152) is in optical communication with the light source (124). The guide bundle (152) bundles the first light guide (122A) and the second light guide (122A). The guide bundle (152) includes a first ferrule (778) that engages the guide proximal end (122P) of the first light guide (122A) and a second ferrule (778) that engages the guide proximal end (122P) of the second light guide (122A). At least one of the ferrules (778) can be formed at least partially from a ceramic material or a metallic material.

A photoacoustic catheter can include an elongate shaft and a first photoacoustic transducer. The elongate shaft can extend from a proximal region to a distal region and can include a first light guide that is in optical communication with a light source. The first photoacoustic transducer can be disposed within the distal region of the elongate shaft and can be in optical communication with the first light guide. The first photoacoustic transducer can impart acoustic pressure waves upon a calcified lesion to induce fractures. The first photoacoustic transducer can include a light-absorbing material and a thermal expansion material that can be in contact with one another.

A catheter system (100) includes a light guide (122A) and a light source (124). The light guide (122A) is configured to selectively receive light energy. The light source (124) generates the light energy. The light source (124) is in optical communication with the light guide (122A). The light source can include (i) a seed source (260) that outputs the light energy, (ii) a pre-amplifier (262) that receives the light energy from the seed source (260), the pre-amplifier (262) being in optical communication with the seed source (260), and (iii) an amplifier (264) that receives the light energy from the pre-amplifier (262), the amplifier (264) being in optical communication with the pre-amplifier (262) and the light guide (122A).

A catheter system (100) for treating a vascular lesion (106A) within or adjacent to a vessel wall (108A) within a body (107) of a patient (109). The catheter system (100) includes a light source (124), a receptacle assembly (274), a first light guide (122A) and a second light guide (122A), a multiplexer (128), and an alignment assembly (256). The light source (124) generates a source beam (124A) of light energy. The first light guide (122A) and the second light guide (122A) are coupled to the receptacle assembly (274), each light guide (122A) having a guide proximal end (122P). The multiplexer (128) receives the source beam (124A) from the light source (124), the multiplexer (128) directing individual guide beams (124B) from the source beam (124A) to each of the guide proximal end (122P) of the first light guide (122A) and the guide proximal end (122P) of the second light guide (122A). The alignment assembly (256) adjusts the position of the receptacle assembly (274) relative to the individual guide beams (124B).

A tapered fiber optoacoustic emitter includes a nanosecond laser configured to emit laser pulses and an optic fiber. The optic fiber includes a tip configured to guide the laser pulses. The tip has a coating including a diffusion layer and a thermal expansion layer, wherein the diffusion layer includes epoxy and zinc oxide nanoparticles configured to diffuse the light while restricting localized heating. The thermal expansion layer includes carbon nanotubes (CNTs) and Polydimethylsiloxane (PDMS) configured to convert the laser pulses to generate ultrasound. The frequency of the ultrasound is tuned with a thickness of the diffusion layer and a CNT concentration of the expansion layer.

A catheter system and method for treating a treatment site within or adjacent to a vessel wall or a heart valve within a body of a patient includes an energy source, an inflatable balloon, an energy guide, and an acoustic sensor. The inflatable balloon is positionable substantially adjacent to the treatment site. The inflatable balloon has a balloon wall that defines a balloon interior that receives a balloon fluid. The energy guide receives energy from the energy source and guides the energy into the balloon interior. The acoustic sensor is positioned outside the body of the patient. The acoustic sensor senses acoustic sound waves generated in the balloon fluid within the balloon interior. The acoustic sensor generates a sensor signal based at least in part on the sensed acoustic sound waves.

A catheter system includes an inflatable balloon, an optical fiber and a laser. The optical fiber has a distal end positioned within the inflatable balloon. The optical fiber receives an energy pulse to emit light energy in a direction away from the optical fiber to generate a plasma pulse within the inflatable balloon. The laser includes a seed source that emits a seed pulse, and an amplifier that increases energy of the seed pulse. The energy pulse can have a somewhat square or triangular waveform with a duration T, a minimum power P.sub.0, a peak power P.sub.P, and a time from P.sub.0 to P.sub.P equal to T.sub.P, wherein T.sub.P is not greater than 40% of T. T can be within the range of greater than 50 ns and less than 3 μs. T.sub.P can be within the range of greater than 2.5 ns and less than 1 μs. P.sub.P can be within the range of greater than 50 kW and less than 1000 kW. A ratio in kW to ns of P.sub.P to T.sub.P can be greater than 1:5. The seed pulse can at least partially increase in amplitude over time.

The present disclosure relates generally to the use of medical devices for the treatment of vascular conditions. In particular, the present disclosure provides devices and methods for using laser-induced pressure waves created within a sheath to disrupt intimal and medial calcium within the vasculature.

The present disclosure relates generally to the use of medical devices for the treatment of vascular conditions. In particular, the present disclosure provides devices and methods for using laser-induced pressure waves created within a sheath to disrupt intimal and medial calcium within the vasculature.