A medical device for treating an aneurysm in a blood vessel includes a hollow shaft for insertion into the blood vessel, an exit port at a distal end of the shaft, a deflection element, and a position sensor. The hollow shaft encompasses a wire-insertion channel for leading a wire to be inserted into the aneurysm. The exit port is configured for exiting the wire from the wire-insertion channel and into the aneurysm. The deflection element is located adjacent to the exit port and configured to deflect the wire from the wire-insertion channel to the exit port. The position sensor, which is coupled to the distal end of the shaft, is configured to produce signals indicative of a position and orientation of the exit port in the blood vessel.

A medical device and methods for altering lung volume are disclosed. The medical device includes a coil formed of a biodegradable material including a first bioabsorbable material that is configured to deactivate a portion of a lung as the coil degrades. The method includes positioning a first coil adjacent a first target within a patient and permitting the first coil to degenerate such that a first bioabsorbable material deactivates a first portion of a lung. The first coil is formed of a biodegradable material and includes the first bioabsorbable material.

A method for treating a genetically associated chronic obstructive pulmonary disease. At least one implant is advanced into an airway of a lung having a genetically associated chronic obstructive pulmonary disease. The at least one implant is delivered into the lung to increase tension of the lung and thereby improve breathing function of the lung.

Body lumen occlusion apparatus and methods are described.

A method of constructing a detachment system for delivering an implantable medical device to a target location of a body vessel is presented. The method includes forming a compressible portion on a distal tube, engaging an implantable medical device with an engagement system, extending the engagement system through the distal tube such that the implantable medical device is distal of a distal end of the distal tube, applying a force to the engagement system to compress the compressible portion to a compressed state, fixing the engagement system to the distal tube to maintain the compressed state of the compressible portion, and joining a proximal end of the distal tube to a distal end of a proximal tube. The engagement system can include a loop wire that is fixed to the distal tube and engages the medical device.

Embodiments include, for example, mechanical release systems for implantable medical devices.

The present invention relates generally to systems and methods for delivering embolic devices into a body lumen of a patient. These embolic devices are applicable to a variety of neurological and/or peripheral applications. In particular, the embolic devices may be used to occlude a vessel within a patient, and/or to treat aneurysms, arteriovenous malformations, traumatic fistulas, uterine fibroids or cancer.

Several embodiments are set forth of devices, systems and methods for modifying an atrial appendage such as a left atrial appendage (LAA). In one embodiment, a medical device includes a frame member and a tissue growth member. The frame member includes a unitary, seamless central portion having a plurality of struts defining a multi-cellular structure and an anchoring system, the plurality of struts extending between and configured to self-expand and directly bias the anchor system to anchor the frame member at least partially within the LAA. With this arrangement, the tissue growth member is attached to the frame member to occlude the LAA.

The invention relates to an aneurysm coil that is made up of a single wire of a noncircular cross-sectional shape. The wire is coiled in a helical configuration to have an outer surface and an inner surface. The outer surface of the wire does not have a round outer surface. The aneurysm coil of the present invention is designed to encourage cellular adhesion and tissue growth along the coil surface by employing a wire having a substantially non-circular cross sectional area, such as a T shape, a triangle, square, rectangle, oval, pentagon, hexagon, septagon, octagon, star, rhombus, as well as a variety of non-geometric shapes. The use of a wire having such a cross sectional shape promotes endothelial cells to adhere and grow within the gaps created by the juxtaposition of the wire forming a coil, thus anchoring the coil to its intended location, promoting thrombosis, endothelial growth across the opening of the aneurysm, and eventual healing of the aneurysm.

An endovascular treatment system includes a delivery sleeve that is insertable into an intravascular catheter. A therapeutic device is housed coaxially within the delivery sleeve and both are advanced within the catheter in combination. An advancement mechanism is connected to the therapeutic device to advance the therapeutic device out of the delivery sleeve and into a patient. The delivery sleeve includes a stop positioned on the proximal end. The stop contacts the proximal end of the catheter, limiting the distance the delivery sleeve is inserted into a catheter.