In various embodiments, a device is provided comprising a balloon configured to expand to an expanded state in response to introduction of a fluid at a first pressure, wherein the fluid perfuses through the balloon above a second pressure, the second pressure being the same or greater than the first pressure. In various embodiments, a method comprising fabricating a balloon configured to expand to an expanded state in response to introduction of a fluid at a first pressure, wherein the fluid perfuses through the balloon above a second pressure, the second pressure being at or greater than the first pressure, disposing the balloon on an elongate member having a lumen, placing the lumen in fluid communication with an interior volume of the balloon.

Disclosed are a multi-guidewire balloon dilatation catheter structure, a dilatation catheter mechanism and a medical device. The multi-guidewire balloon dilatation catheter comprises a balloon, a first guidewire channel, a second guidewire channel and a third guidewire channel. The first guidewire channel is at least partially passed through the balloon. The second guidewire channel is at least partially located at the distal end of the balloon. The third guidewire channel is at least partially located at the proximal end of the balloon. In the multi-guidewire balloon dilatation catheter structure of this embodiment, each guidewire channel can be used for accommodating the guidewire by providing the first guidewire channel and the second/third guidewire channel to assemble various devices on the single catheter of the present invention, thereby realizing simultaneous execution of device guidance, plaque cutting, guidewire anchoring, etc. The structure is simple and good in use effect.

A system for treating a bifurcated vessel that includes a first delivery catheter and a second delivery catheter. The first delivery catheter carries a proximal first stent and a distal second stent. The first delivery catheter also has a first elongate shaft, a proximal first expandable member with the proximal first stent disposed thereover, and a distal second expandable member with the distal second stent disposed thereover. The proximal first expandable member and distal second expandable member are independently expandable of one another. The second delivery catheter carries a third stent. The second delivery catheter also has a second elongate shaft, and a third expandable member with the third stent disposed thereover. The third expandable member is independently expandable of the proximal first expandable member and the distal second expandable member.

Various embodiments of the systems, methods and devices are provided for breaking up calcified lesions in an anatomical conduit. More specifically, an electrical arc is generated between two spaced-apart electrodes disposed within a fluid-filled balloon, creating a subsonic pressure wave. In some embodiments, the electrodes comprise a plurality of points that allow the electrical arc to form at any one of the plurality of points to, among other things, extend the electrode life.

Balloon catheters with an elongate shaft defining a hollow body have an inflatable balloon at a distal end thereof. The balloon has a plurality of internal chambers that are inflatable to differing pressures. When inflated, the balloon has a generally hourglass shape having a neck between a distal end and a proximal end and a port at the neck that is in open communication the hollow body of the shaft and in open communication with an environment external to the balloon. The balloon catheter is inflated in a lumen of a patient to its hourglass shape with its proximal and distal ends in direct contact with normal endothelium juxtaposed to a target lesion with the neck of the balloon at the target lesion. A cutting tool is deployed through the port and an opening having a flap is cut into the target lesion and the plaque is removed thereof.

A system for treating heart disease, such as pulmonary hypertension or right heart failure, including an implantable component and external components for monitoring the implantable component is provided. The implantable component may include a compliant member, e.g., balloon, coupled to a reservoir via a conduit. Preferably, the compliant member is adapted to be implanted in a pulmonary artery and the reservoir is adapted to be implanted subcutaneously. The external components may include a clinical controller component, monitoring software configured to run a clinician's computer, a patient monitoring device, and a mobile application configured to run on a patient's mobile device.

An apparatus and methods for tissue restoration are provided. The apparatus may include a catheter shaft extending from a proximal end to a distal tip, the catheter shaft defining lumens including an inflation lumen and a light fiber lumen, a coated balloon positioned on a translucent distal segment of the catheter shaft proximal to the distal tip in fluid communication with the inflation lumen, the coated distal balloon comprising a translucent material and a coated material on an outer surface of the coated balloon, and a light fiber positioned in the catheter shaft in the light fiber lumen and extending through the translucent distal segment.

A device and method for intravascular treatment of atherosclerotic plaque prior to balloon angioplasty which microperforates the plaque with small sharp spikes acting as serrations for forming cleavage lines or planes in the plaque. The spikes may also be used to transport medication into the plaque. The plaque preparation treatment enables subsequent angioplasty to be performed at low balloon pressures of about 4 atmospheres or less, reduces dissections, and avoids injury to the arterial wall. The subsequent angioplasty may be performed with a drug-eluting balloon (DEB) or drug-coated balloon (DCB). The pre-angioplasty perforation procedure enables more drug to be absorbed during DEB or DCB angioplasty, and makes the need for a stent less likely. Alternatively, any local incidence of plaque dissection after balloon angioplasty may be treated by applying a thin, ring-shaped tack at the dissection site only, rather than applying a stent over the overall plaque site.

The invention relates to a balloon catheter comprising a shaft (2) extending in the longitudinal direction, which has at least a first and a second section (7, 8), with the first section (7) being arranged distal to the second section (8) and being more flexible than the second section (8), with the shaft (2) being provided with a first and a second hose-like tube (10, 11) and a balloon (3) being arranged at the distal end of the first tube (10), said balloon (3) being expandable by pressurization with a fluid led through said first tube (10), and said second tube (11) serving for accommodating a guidewire and terminating distally of said balloon (3) and being provided with an opening at said distal end, wherein both said first and second tubes (10, 11) extend along said first and second sections (7, 8), and both said first and second tubes (10, 11) are more flexible in said first section (7) than in said second section (8), wherein a transition section (9) is arranged between said first and second sections (7, 8), in which the first tube (10) has the same material properties as in the first section (7) and the second tube (11) has the same material properties as in the second section (8) or the first tube (10) has the same material properties as in the second section (8) and the second tube (11) has the same material properties as in the first section (7).

The guide catheter extension system for various intravascular procedures, including the reverse CART procedure, the thrombus removal, etc., has an enhanced ”capturing” capability. It is configured with a plastically expandable scaffold member forming an expandable “funnel-like” distal opening, and, once it has been advanced into the subintimal space, provides an enhanced capability of catching the retrograde wire or a thrombus, as required by the procedure. A balloon delivered to the target location in the blood vessel, by being inflated, opens the scaffold member to enhance the delivery of the retrograde wire or the thrombus into the guide catheter extension. When the guide catheter extension is no longer needed, the flared guide extension can be easily compressed and collapsed as it is drawn in the guiding catheter. For benefits of the thrombus removal, the balloon may be formed from a material loaded with a radiopaque material and prefabricated with micro pores. A thrombolytic agent can be delivered to the thrombus before the thrombus is conveniently captured in the expanded distal opening of the scaffold member and removed from the blood vessel by aspiration. The outer or inner catheter may be configured with a distal curved portion to enhance a rotational capability for displacement between the right and left pulmonary arteries.