In some implementations, an intravascular gas exchange catheter includes (a) a catheter wall extending from a proximal end to a distal end; (b) a first internal lumen coupled to a first lumen port at the proximal end and adjacent at least a portion of the catheter wall, and a second internal lumen coupled to a second lumen port at the proximal end; and (c) an interior space enclosed by the catheter wall and disposed at the distal end, wherein the first internal lumen and second interior lumen are fluidly isolated from each other along a length of catheter wall but fluidly coupled to each other at the interior space. The catheter wall may include a porous material that facilitates diffusion of a target gas through the catheter wall, from or to a space exterior to the catheter wall, to or from the first lumen.

An apparatus for performing a medical procedure includes a balloon comprising an inflatable body. A first releasable or frangible connection is provided to maintain the body at a first diameter up to a first inflation pressure, and to release, such as by disconnecting, and thus allow the body to assume a second diameter, such as at a second inflation pressure greater than the first inflation pressure or upon a manual release of the connection by a clinician. Multiple releasable or frangible connections may be provided, including between portions (folds) of the inflatable body of the balloon. This disclosure also pertains to a non-compliant or semi-compliant balloon having a first inflation diameter corresponding to a first range of inflation pressures and a second inflation diameter corresponding to a second inflation pressure greater than the first range of inflation pressures.

Described herein are methods and devices for delivering a drug to the frontal sinus system. An inflatable implant is positioned within the frontal sinus system using an anchoring means secured within the frontal sinus cavity. A drug-containing fluid is released directly into the frontal sinus drainage system.

The present invention relates to a pharmaceutical composition for intravascular delivery of a therapeutic agent, such as paclitaxel, rapamycin, or an analog thereof. The composition includes the therapeutic agent and a biocompatible solvent, such as glycofurol. The composition can aid tissue penetration by the therapeutic agent. A catheter assembly that protects the pharmaceutical composition from the surroundings can be used for its intravascular delivery.

A multi-layered balloon is provided where each layer is formed such that each layer is made from tubing that optimizes the inner wall stretch thus providing maximum balloon strength. The high pressure, multi-layer balloon is provided with layers that allow for slipping, such that the balloon has a very high pressure rating and toughness, yet excellent folding characteristics. Methods for producing such multi-layer balloons using existing balloon forming equipment are also provided. The multi-layer balloons can have alternating structural and lubricating layers, or layers with low-friction surfaces. The multi-layer balloons are preferably manufactured using a variety of methods including nesting, co-extrusion, or a combination of nesting and co-extrusion. The multi-layer balloons have balloon layers having substantially similar, or the same, high degree of biaxial orientation of their polymer molecules such that each balloon layer of the multi-layer balloon will fail at approximately the same applied pressure.

Everting balloon systems and methods for using the same are disclosed herein. The systems can be configured to access and dilate body lumen and cavities. For example, the systems can be used to dilate the cervix and access the uterine cavity. The systems can also be used to occlude the cervix. The systems can also be used to occlude the urethra.

The disclosure provides insertion tools and articles that facilitate entry of a medical device, such as a balloon catheter, into the body, and that can provide advantages in terms of balloon insertion, safety, and drug delivery. The insertion tool includes a tubular portion that accommodates a balloon portion of a balloon catheter, and one or more separation margin(s) in the wall of the tubular portion or one or more split(s) in the tubular wall. The insertion tool also includes a proximal tab that extends from a second lengthwise half having a portion at an angle skew to the lengthwise axis, or that is in the form of a solid article comprising a concave surface that is fastened to an outer surface of the second lengthwise half of the tubular portion; or first and second tabs that extend from first and second lengthwise halves of the tubular portion, respectively.

A balloon for medical treatments such as percutaneous transluminal coronary angioplasty (PTCA), delivery of a vascular stents or stent grafts, employs reinforcement materials that are patterned so as to promote consistent folding of the balloon. Also disclosed are methods and apparatus for biocidal treatment using a balloon, including balloons with fiber fabric reinforcements.

The present disclosure describes implantable medical devices comprising covers, such as a balloon cover. Such devices can comprise a first layer of a porous polymeric material, such as ePTFE, surrounded by layers of a porous polymeric material having an imbibed elastomer, such as polyurethane. The cover can be used to assist in deployment of an expandable implant, such as a stent-graft, within the body of the patient.

A diametrically adjustable endoprosthesis includes a controlled expansion element extending along at least a portion of a graft and is supported by a stent. The controlled expansion element diametrically constrains and limits expansion of the endoprosthesis. Upon deployment from a smaller, delivery configuration, the endoprosthesis can expand to the initial diameter set by the controlled expansion element. Thereafter, the endoprosthesis can be further diametrically expanded (e.g., using balloon dilation) by mechanically altering the controlled expansion element.