The present disclosure relates generally to thrombectomy devices. An exemplary catheter comprises: a central tube; an emitter assembly mounted over the central tube, wherein the emitter assembly comprises: a conductive sheath; a first insulated wire having a first curved distal portion; and a second insulated wire having a second curved distal portion, wherein the first curved distal portion and the second curved distal portion are positioned within the conductive sheath, and wherein the emitter assembly is configured to generate a plurality of cavitation bubbles or shockwaves when a pulsed voltage is applied to the emitter assembly; and an outer tube housing the emitter assembly, wherein the outer tube is configured to receive a conductive fluid, wherein the outer tube comprises a distal opening for releasing the plurality of cavitation bubbles or shockwaves and the conductive fluid in a forward direction to treat thrombus at a treatment site.

Apparatus and methods for creating tissue necrosis include an energy delivery apparatus that can be positioned adjacent a target treatment site such as a vessel without direct contact with the treatment site tissue. Collimated energy is then directed to the vessel to create necrotic regions in the tissue. Exemplary use in renal vessels creates necrotic regions in adjacent nerves which can alleviate hypertension in a patient.

A method for cleaning an isthmus of a Eustachian tube (ET) of a patient includes using an instrument. The instrument includes a proximal portion, a distal portion, and a shaft extending therebetween, and a treatment feature disposed at the distal portion. The method includes directing the instrument into an oro-nasal cavity of the patient and advancing at least the distal portion of the instrument into an opening of the ET. The method further includes further advancing the instrument within the ET so that the treatment feature is disposed past, or is coincident with, the isthmus. The method further includes moving the treatment feature relative to the isthmus to clean the isthmus.

Systems and methods for treating a blood clot positioned within a blood vessel are disclosed. In one embodiment, a balloon member is positioned on a distal end region of a catheter and an ultrasound emitting element is positioned within the balloon member and arranged for actively emitting ultrasound. In some exemplary embodiments, the disclosure provides a multi-wall balloon member and a multi-lumen catheter with at least one and/or all cavities of the balloon member arranged for heat transfer with the ultrasound emitting element. The disclosure also provides catheter arrangements with an ultrasound emitting element arranged to heat tissue adjacent to the balloon member. Additionally, in some embodiments, at least one and/or all walls of the balloon member have apertures arranged to release a therapeutic agent such as a thrombolytic drug.

Described here are devices and methods for forming shock waves. The devices may comprise an axially extending elongate member. A first electrode pair may comprise a first electrode and a second electrode. The first electrode pair may be provided on the elongate member and positioned within a conductive fluid. A controller may be coupled to the first electrode pair. The controller may be configured to deliver a series of individual pulses to the first electrode pair, where each pulse creates a shock wave. The controller may cause current to flow through the electrode pair in a first direction for some of the pulses in the series and in a second direction opposite the first direction for the remaining pulses in the series.

Described herein are low-profile electrodes for use with an angioplasty shockwave catheter. A low-profile electrode assembly may have an inner electrode, an insulating layer disposed over the inner electrode such that an opening in the insulating layer is aligned with the inner electrode, and an outer electrode sheath disposed over the insulating layer such that an opening in the outer electrode sheath is coaxially aligned with the opening in the insulating layer. This layered configuration allows for the generation of shockwaves that propagate outward from the side of the catheter. In some variations, the electrode assembly has a second inner electrode, and the insulating layer and outer electrode may each have a second opening that are coaxially aligned with the second inner electrode. An angioplasty shockwave catheter may have a plurality of such low-profile electrode assemblies along its length to break up calcified plaques along a length of a vessel.

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.

The invention provides a device for generating shock waves. The device may comprise an elongated tube and a conductive sheath circumferentially mounted around the elongated tube. The device may further comprise first and second insulated wires extending along the outer surface of the elongated tube. A portion of the first insulated wire is removed to form a first inner electrode, which is adjacent to a first side edge of the conductive sheath. A portion of the second insulated wire is removed to form a second inner electrode, which is adjacent to a second side edge of the conductive sheath. Responsive to a high voltage being applied across the first inner electrode and the second inner electrode, a first shock wave is created across the first side edge and the first inner electrode, and a second shock wave is created across the second side edge and the second inner electrode.

Apparatus and methods for creating tissue necrosis include an energy delivery apparatus that can be positioned adjacent a target treatment site such as a vessel without direct contact with the treatment site tissue. Collimated energy is then directed to the vessel to create necrotic regions in the tissue. Exemplary use in renal vessels creates necrotic regions in adjacent nerves which can alleviate hypertension in a patient.

The present invention relates to a calculus removing device used in medical fields and, more particularly, to a calculus removing device having a calculus crushing probe, which can simultaneously crush and remove a calculus formed inside a human body selectively using a drawing force or electricity through the calculus crushing probe, regardless of the size of the calculus. A calculus removing device according to an aspect of the present invention may comprise: a first tube having an inner space formed therein; a second tube inserted into the inner space of the first tube so as to move inside the inner tube; a capturing means having an end coupled to an end of the second tube such that the capturing means is introduced into the inner space of the first tube in response to a movement of the second tube, thereby capturing and retaining a calculus; a calculus crushing probe inserted into the inner space of the second tube so as to contact the calculus, which is retained by the capturing means, and to apply an electric impact thereto; and a handle coupled to an end of the first tube so as to independently move the second tube and the calculus crushing probe.