A balloon catheter may include a shaft having a distal side and a proximal side and a balloon provided at the distal side of the shaft. The balloon may have a plurality of wings in a deflated state, with each of the wings having a projection on an outer surface in a wrapped state, and each of the projections having a projecting direction, which is opposite to a wrapping direction of the wing. In a cross section that is perpendicular to a long axis direction of the balloon, a base of the projection may have a base first end part farther from a tip of the wing and a base second end part closer to the tip of the wing, and a tip of the projection may be closer to a base of the wing with respect to a line passing through the base first end part which is perpendicular to a line passing through the base first end part and the base second end part.

A system for infusing fluid into a body of a subject includes an expandable medical device and a balloon catheter. The expandable medical device includes an expandable section that may be expanded and contracted and, when expanded, score a wall of a vessel or another open space within the body of the subject. The balloon catheter includes a balloon that expands when pressurized and can expand the expandable section. When pressure within the balloon is reduced, the expandable section can resiliently contract the balloon. The balloon may be shorter than the expandable section, enabling the balloon to be positioned at a plurality of locations along the length of the expandable section and to expand the expandable section to a plurality of different configurations. The system may be used to limit the flow of infused fluid beyond a target location within the body and/or to force fluid into the target location.

Devices and methods are disclosed for preventing distal embolisms during endovascular interventions. Representative devices are kits that include a first catheter comprising a proximal part and distal part having a principal through lumen, at least one lumen for filling at least one balloon, at least one inflated balloon that closes the lumen of the right or left carotid artery, and a proximal end configured to allow blood to flow through the principal lumen but to block the passage of emboli. The kits include a second catheter in the form of a single-lumen tube with a proximal end and a distal end. The proximal and distal parts of the first catheter may have diameters that are sufficient to allow passage through the lumen of the second catheter and may be sufficiently long when combined to allow at least the distal part of the first catheter to extend beyond the limits of the distal end of the second catheter, when the first catheter passes through the second catheter. Moreover, the internal diameter of the lumen of the second catheter may exceed the external diameter of the distal part of the first catheter.

A cutting balloon catheter including a balloon mounted on a distal portion of a catheter shaft. The balloon includes a cutting member mounted on an exterior surface of the balloon which includes one or more features for providing the cutting member with enhanced flexibility for navigating tortuous anatomy and more closely conforms to the expansion characteristics of the balloon to which the cutting member is mounted.

Active Energy Facilitated Drug Delivery platform for delivering therapeutics to biological tissue through electrical conductivity. This delivery method is comprised of an elastic alloy to encase a balloon or drug deposition, where the alloy acts to emit an electric field in aiding and actively allowing the pharmaceutical agent to have enhanced permeation, binding and internalization to cells and the biological matrix. A therapeutic agent is deposited onto a balloon to embody the drug deposition, reservoir whereby the electrical field facilitates the active transfer of a pharmaceutical agent to the target tissue is described.

A system has a balloon guide catheter for use in mechanical thrombectomy procedures which requires very little preparation to inflate the balloon compared to most contemporary designs. The balloon guide catheter can have an elongated tubular member and a proximal luer. The elongated tubular member of the catheter can have two internal lumens. A first inner hollow lumen can have a large opening for aspiration and the advancement of auxiliary devices, and a second inflation lumen can provide a fluidic passageway to inflate the balloon. The proximal luer can have a luer lumen, an inflation port, and a mandrel hub. A removable mandrel can extend distally from the mandrel hub to occupy the full length and volume of the inflation lumen of the tubular member. A tab of the mandrel can extend external to the luer to facilitate removal of the mandrel from the catheter prior to inflating the balloon.

An example cutting balloon is disclosed. The example cutting balloon includes an expandable member having an outer surface and longitudinal axis, a first cutting member disposed along the outer surface of the expandable member and a covering encapsulating the expandable member and the first cutting member.

Methods and devices are disclosed for treating neurovascular venous outflow obstructions, with or without implantation of a prosthetic valve. The valve may be carried by a support, such as a stent, which may be self-expandable or balloon expandable. Both transvascular and direct surgical access is contemplated.

A catheter for scoring or slicing a lesion. The catheter has a first receiver at a distal end of an expandable portion of the catheter shaft. A first carrier at least partially within the first receiver is moveable axially along the catheter shaft to deploy a first cutter along the expandable portion for cutting or scoring the lesion. In an alternative embodiment, the first carrier may be a wire having a loop, and thus forming a first length including the first cutter and a second length including a second cutter. Actuation of the wire thus causes simultaneous, reciprocal movement of the first and second cutters. Related methods are also disclosed.

Disclosed herein are medical instrument and medical method for localized drug delivery. The medical instrument can comprise a catheter shaft assembly, a hub coupled to the proximal end of the catheter shaft assembly, an inflatable component at the distal end of the catheter shaft assembly, a tissue penetrating member coupled to the inflatable component in an orientation transverse to the longitudinal axis of the catheter shaft assembly, and at least one protective element coupled to the inflatable component in proximity to the tissue penetrating member. The protective element can be configured to prevent any damage of the inflatable body during a placement of the medical instrument and an actuation of the inflatable component.