Catheters with weeping balloons can be used for various medical purposes. For example, in some embodiments provided herein weeping balloons are used for catheter visualization devices. In some embodiments, weeping balloons are used to deliver therapeutic agents. Weeping balloons can include openings of a selected size and shape through which a fluid gradually flows or “weeps.” The design of the openings can affect performance characteristics such as, but not limited to, fluid flow rate, tear resistance, and mitigation of counter-flow.

A device for interventional surgical or medical procedures is presented. The device is generally in the form of a balloon and is used to position itself or other working elements up against or through lumen walls in the body. The balloon is comprised of at least two materials of different elastic modulus, which allows for a flexible but relatively non-distensible, unfolding component of the balloon as well as an elastomeric, inflatable component of the balloon. The elastomeric component is fixedly attached to the flexible but relatively non-distensible component and together they form a pressure vessel that can be inflated within the lumens of the body.

A balloon catheter includes a catheter tube and an inflatable balloon. The ends of the balloon are attached to the catheter tube. The outside surface of the balloon in an uninflated state is provided with a relief structure which in an inflated state of the balloon is substantially disappeared. A method for producing such a relief structure is by winding a wire helically around the outer surface of the balloon.

The invention relates to a method for producing a catheter (1) having a proximal segment, a distal segment, and an expandable element (2) arranged in the distal segment, it being possible to bring the expandable element (2) from a contracted state into an expanded state by supply of a fluid and there being arranged around the expandable element (2) in the contracted state a removable protector in the form of a tube (5), and the tube (5) being pulled over the expandable element (2) and being guided with the catheter (1) through one or more nozzles (6), stretching the tube (5) and reducing the inner diameter of the tube (5). Furthermore, the invention relates to a corresponding catheter (1) having a tube (5) pulled over the expandable element (2). The invention provides a catheter (1) having a particularly small cross section in the region of the distal segment.

A joint-spacing balloon catheter comprising: a shaft having a distal end and a proximal end; first and second balloons mounted to the distal end of the shaft, the first balloon being disposed distal to, and spaced from, the second balloon, with the portion of the shaft between the first and second balloons being flexible; and a handle attached to the proximal end of the shaft.

A dilator device including an elongated flexible material sleeve having a hollow interior extending along a distal portion and a proximal portion thereof. An expandable or inflatable bladder is connected to the distal portion and disposable radially outward from an exterior of the sleeve when in an expanded and/or inflated orientation. The elongated sleeve comprising a tip having a predetermined configuration that facilitates positioning the elongated sleeve within an intended body part. A fluid input is structured for removable connection to a fluid source and is disposed on the sleeve, in fluid communication with the bladder. An access opening is formed on the proximal portion and is cooperatively dimensioned with the hollow interior to removably receive any one of a plurality of different types of positioning instruments within the sleeve.

Various methods for optimizing coating of medical devices, such as balloon catheters are disclosed. One method configures catheter balloon folds based on balloon diameter and volume. Other methods include using a specifically-sized protective sheath, using a vacuum, using pressure, pulling the balloon through a coating solution, using at least one spacer or a wick between at least one fold for metering a therapeutic coating into the folds of the balloon, placing an intermediate layer between the balloon and the therapeutic coating, placing a soluble film having a therapeutic agent around the catheter balloon or inside the folds, and any combination thereof. Balloon catheters and catheter balloons having a specific folding configuration, a specifically-sized protective sheath, an intermediate layer, or a soluble film are also disclosed.

A user-operable controlled furling balloon assembly including a furlable balloon sheath, an elongate furling driving element which is retractable and rotatable about an elongate axis thereof relative to a base element for furling the furlable balloon sheath about the elongate axis, the furlable balloon sheath surrounding the elongate furling driving element and coupled at a first end thereof to the elongate furling driving element and at a second end thereof to the base element and a furling/retraction controlling assembly coupled to the elongate furling driving element and to the base element for limiting an extent of retraction of the elongate furling driving element to be a function of an extent of furling of the balloon sheath, thereby limiting a maximum outer diameter of the balloon sheath when furled and preventing stacking of the balloon sheath.

A method and apparatus for delivery of cell therapies, introduced via percutaneous access to the circulation, and delivered to the site of vascular injury or intervention.

Systems, apparatus and methods are disclosed for medical treatment comprising bone access and dilatation and/or cavity creation or enlargement using a narrow gauge, preferably 11-gauge or smaller, cannula wherein a catheter/expandable element assembly meeting medical protocols is designed, adapted and fabricated to fit through the interior of the associated 11-gauge or smaller cannula.