An intravascular catheter system for treating a condition in a body includes a catheter shaft, a first inflatable balloon and a plurality of electrodes. The first inflatable balloon is positioned near a distal end of the catheter shaft. The first inflatable balloon moves between an inflated state and a substantially deflated state. In the inflated state, the first inflatable balloon has a maximum circumference. The plurality of electrodes are attached to the first inflatable balloon away from the maximum circumference of the first inflatable balloon. In some embodiments, the plurality of electrodes are attached to the inner surface of the first inflatable balloon. In various embodiments, the intravascular catheter system can also include two or more flex circuits that substantially face one another when the first inflatable balloon is in the substantially deflated state.

The present invention relates to an intra-aortic dual balloon pump catheter device. The intra-aortic dual balloon pump comprises: a catheter (2); a first balloon (4) and a second balloon (6) arranged to successively surrounding the catheter along the longitudinal direction of the catheter (2), wherein the position of the first balloon (4) is closer to a catheter end (5) of the catheter (2) than the position of the second balloon (6); the first balloon (4) and the second balloon (6) are periodically expanded to a dimension that blocks the aortic blood flow and contracted to a dimension that does not prevent the blood flow from passing through; wherein the first balloon (4) begins and finishes the inflation earlier than the second balloon (6) in each period of expansion and contraction.

An irrigation balloon catheter includes one or more inner balloons inside of an irrigation balloon. The inner balloon(s) can be compliant with a volume that is dynamically adjustable for rapid inflation, rapid deflation, complete deflation, and/or irrigation flow adjustment. An inflator tool can be configured to inflate or deflate the inner balloon to adjust flow from the outer, irrigation balloon to affect temperature at electrodes of the irrigation balloon.

A clot removal device for removal of an occlusion from a lumen in a patient's body is provided. The clot removal device has a lumen, an elongated member positioned within the lumen and extending axially from a proximal end to a distal end of the lumen, a handle attached to the proximal end of the lumen, a first expandable member positioned along a length of the elongated member, a second expandable member positioned along the length of the elongated member, wherein the second expandable member is distal to the first expandable member relative to the handle. The handle has at least one actuation mechanism and at least one of the following applies: a) the first expandable member is coupled to the at least one actuation mechanism and is configured to be moveable relative to the second expandable member upon manipulation of the at least one actuation mechanism; b) the first expandable member is configured to mechanically expand or contract by manipulating the at least one actuation mechanism; c) the second expandable member is coupled to the at least one actuation mechanism and is configured to be moveable relative to the first expandable member upon manipulation of the at least one actuation mechanism; or d) the second expandable member is configured to mechanically expand or contract by manipulating the at least one actuation mechanism.

Described herein are systems and methods from delivering prosthetic devices, such as prosthetic heart valves, through the body and into the heart for implantation therein. The prosthetic devices delivered with the delivery systems disclosed herein are, for example, radially expandable from a radially compressed state mounted on the delivery system to a radially expanded state for implantation using an inflatable balloon of the delivery system. Exemplary delivery routes through the body and into the heart include transfemoral routes, transapical routes, and transaortic routes, among others.

A metal balloon catheter having a main tubular body, a metal balloon proximate a distal end of the main tubular body, a central annulus extending along an entire longitudinal aspect of the catheter for accommodating a guidewire therethrough and an inflation annulus adjacent the central annulus which extends along the longitudinal axis of the main tubular body and terminates in fluid flow communication with an inflation chamber of the metal balloon. The metal balloon catheter may be either unitary integral metal catheter in which the main tubular body and the balloon are fabricated of metal, or it may consist of a polymeric main tubular body and a metal balloon.

An apparatus includes a flexible catheter which may have a plurality of lumens extending from a proximal end to a distal end, a suction opening in fluid communication with a first lumen, a plurality of irrigating openings in fluid communication with a second lumen, a dilator in fluid communication with a third lumen and an occluding balloon in fluid communication with the fourth lumen. The catheter may be used to dilate an ostium, occlude the ostium, irrigate a sinus, and suction a sinus.

An apparatus for providing at least one treatment to at least one tissue having a first structural arrangement configured to expand a first portion at a distal end of the apparatus, a second structural arrangement configured to expand a second portion at the distal end and at least one lumen associated with at least one of the first structural arrangement and/or the second structural arrangement. The first structural arrangement and/or the second structural arrangement can be configured to position the at least one lumen at a particular position with respect to the tissue. A tip is configured to aid in the insertion of the apparatus into the tissue(s).

A balloon catheter includes a first balloon positioned inside of a second balloon, both of which are mounted about a catheter and fluidly connected to respective inflation lumens. In a first inflated configuration, the second balloon is inflated and has a shape that includes a plurality of bulb segments, with each two consecutive bulb segments being separated by a waist hoop. In a second inflated configuration both the inner and outer balloons are inflated, and the inner balloon bears radially outwardly against the waist hoop of the outer balloon such that the waist hoop of the outer balloon has a larger diameter in the second inflated configuration than in the first inflated configuration. The bulb segment separated by waist hoops enable the balloon catheter to conform to curved passageways, such as during the implementation of a stent.

Medical devices are described. More particularly, medical devices and methods for the identification and treatment of bodily passages, such as sinus cavities, are described herein. An exemplary medical device comprises an elongate member, a handle, and a wire member. The elongate member is moveable between a first straight, or substantially straight, configuration to a second curved configuration.