A patient interface device includes: a first interface port configured to be interfaced with a laser surgery apparatus; a second interface port configured to be interfaced with a patient's eye, the second interface port including an applanating lens for application to a patient's eye during a laser surgery procedure; a chamber extending between the first interface port and the second interface port and defining a chamber therein, wherein air may be evacuated from the chamber by the laser surgery apparatus via the first interface port. The second interface port also includes a retaining ring on which the applanating lens is provided, the retaining ring having through channels extending through the retaining ring from the chamber above the applanating lens to a space below the applanating lens.

A tool has a handle and an elongate shaft that extends distally from the handle. A distal portion of the shaft is inserted into a subject during a surgical procedure. An optical fiber delivers laser energy to a tip at the distal portion of the shaft. The tip includes a mechanical cutting mechanism including a moving part that absorbs the laser energy, thermally conducts the absorbed energy to tissue that is disposed between the moving part and another part, and moves with respect to the other part in order to cut tissue that is disposed between the parts using a mechanical force that is lower than a mechanical force that would be required to cut the tissue in the absence of the laser energy. Other embodiments are also described.

A shock wave generating device includes an optical fiber and a reflective part, and is configured to reflect and converge the shock wave generated inside the reflective part to an outside of the reflective part. The reflective part includes: a reflector having a concave surface having a cut surface-of-revolution shape, and a through hole, which is formed coaxially with a rotating axis of the concave surface, and into which the optical fiber is to be inserted; a sealing body configured to seal an opening portion of the concave surface; and a liquid to be charged between the concave surface and the sealing body. The optical fiber has a distal end arranged at a position on a rear side of a focal point of the concave surface, at which the shock wave reflected by the concave surface is convergeable outside the reflective part.

Surgical devices and methods of operation thereof are provided herein. The surgical devices include interior walls defining a cavity that extends along a first axis and having an aperture at a first end of the surgical devices. The surgical devices include a backstop spaced apart from the aperture and having a surface opposing the aperture. The surgical devices include an arm that extends from the surgical device. The surgical devices are configured to receive a fiber waveguide into the cavity at a second end. The surgical devices of some embodiments include a surface for reflecting laser light from the fiber waveguide.

A catheter system (100) for treating one or more treatment sites (106) within or adjacent to the heart valve (108) includes an energy source (124), a plurality of energy guides (122A), and a balloon assembly (104). The energy source (124) generates energy. The plurality of energy guides (122A) are configured to receive energy from the energy source (124). The balloon assembly (104) includes a plurality of balloons (104A) that are each positionable substantially adjacent to one or more treatment site(s) (106). Each of the plurality of balloons (104A) has a balloon wall (130) that defines a balloon interior (146). Each of the plurality of balloons (104A) is configured to retain a balloon fluid (132) within the balloon interior (146). A portion of at least one of the plurality of energy guides (122A) that receive the energy from the energy source (124) is positioned within the balloon interior (146) of each of the plurality of balloons (104A) so that plasma is formed in the balloon fluid (132) within the balloon interior (146).

Described is a method and device for dilating a tubular anatomical structure. The device and method can be useful for extracting a blood clot in an artery of a mammal by concentrically irradiating an inner wall of the occluded artery using an ultraviolet (UV) laser beam delivered by an optical fiber. Dilation results from photophysical production and release of nitric oxide from the cells lining the arterial wall when UV laser light is projected as a ring beam onto the inner arterial wall.

A system to treat a patient comprises a user interface that allows a physician to view an image of tissue to be treated in order to develop a treatment plan to resect tissue with a predefined removal profile. The image may comprise a plurality of images, and the planned treatment is shown on the images. The treatment probe may comprise an anchor, and the image shown on the screen may have a reference image marker shown on the screen corresponding to the anchor. The planned tissue removal profile can be displayed and scaled to the image of the target tissue of an organ such as the prostate, and the physician can adjust the treatment profile based on the scaled images to provide a treatment profile in three dimensions. The images shown on the display may comprise segmented images of the patient with treatment plan overlaid on the images.

Described herein are methods, devices, and support structures for assembling optical fibers in catheter tips and facilitating alignment and structural support. A method for assembling a plurality of optical fibers and lenses in a support structure for an ablation catheter includes providing a support structure with a proximal end, a body, and a distal end, wherein the distal end includes a plurality of alignment orifices or slits. A plurality of optical fibers are threaded through the alignment orifices or slits, such that each optical fiber is threaded through a corresponding alignment orifice or slit. An adhesive material is applied at each alignment orifice or slit to secure the optical fibers, and the plurality of optical fibers are then cleaved at the distal end to remove portions of the fibers extending out of the distal end. Finally, a lens is attached to each of the ends of the plurality of optical fibers.

A method for treating a treatment site within a body of a patient with a catheter system includes generating energy with an energy source; positioning an inflatable balloon substantially adjacent to the treatment site, the inflatable balloon having a balloon wall that defines a balloon interior that receives a balloon fluid; receiving energy from the energy source with an energy guide; guiding the energy with the energy guide into the balloon interior; sensing acoustic sound waves generated in the balloon fluid with an acoustic sensor that is positioned outside of the body of the patient; generating a sensor signal with the acoustic sensor based at least in part on the sensed acoustic sound waves; electrically coupling a system controller to the acoustic sensor; receiving the sensor signal from the acoustic sensor with the system controller; and controlling operation of the catheter system with the system controller based at least in part on the sensor signal, the system controller being configured to recognize one of: (i) normal operation of the catheter system, and (ii) potential damage to the energy guide.

A catheter system for treating a treatment site within or adjacent to a vessel wall or a heart valve includes an energy source, a balloon, an energy guide, and an electrical analyzer assembly. The energy source generates energy. The balloon is positionable substantially adjacent to the treatment site. The balloon has a balloon wall that defines a balloon interior that receives a balloon fluid. The energy guide is configured to receive energy from the energy source and guide the energy into the balloon interior. The electrical analyzer assembly is configured to monitor a balloon condition during use of the catheter system. The electrical analyzer assembly can include a first electrode, a second electrode, and an impedance detector that is electrically coupled to the first electrode and the second electrode. The impedance detector is configured to detect impedance between the first electrode and the second electrode.