A plaque tack can be used for holding plaque against blood vessel walls such as in treating atherosclerotic occlusive disease. The plaque tack can be formed as a thin, annular band for holding loose plaque under a spring or other expansion force against a blood vessel wall. Focal elevating elements and/or other features, such as anchors, can be used to exert a holding force on a plaque position while minimizing the amount of material surface area in contact with the plaque or blood vessel wall and reducing the potential of friction with the endoluminal surface. This approach offers clinicians the ability to perform a minimally invasive post-angioplasty treatment and produce a stent-like result without using a stent.

Side-chain crystallizable (SCC) polymers are useful in various medical applications. In certain applications, heavy atom containing side-chain crystallizable polymers (HACSCCP's) are particularly useful. An example of a HACSCCP is a polymer that comprises a main chain, a plurality of crystallizable side chains, and a plurality of heavy atoms attached to the polymer. In certain configurations, the heavy atoms are present in an amount that is effective to render the polymer radiopaque. A polymeric material that includes an HACSCCP may be fabricated into a medical device useful for at least partially occluding a body cavity. For example, such a medical device may be an embolotherapy product. A polymeric material that includes a SCC polymer may also be fabricated into other medical devices, such as stents.

A wire stent assembly that has a first ring defining one end of the stent assembly, a second ring defining the second end of the stent assembly. Each ring is formed of wire. The wire of each ring also has a second section that extends parallel to the longitudinal axis of the wire stent assembly and perpendicular to the rings. Each of the rings has a loop that is parallel to the longitudinal axis and parallel to the rings. The stent assembly may form the support structure for a stent graft.

A wire stent assembly that has a first ring defining one end of the stent assembly, a second ring defining the second end of the stent assembly. Each ring is formed of wire. The wire of each ring also has a second section that extends parallel to the longitudinal axis of the wire stent assembly and perpendicular to the rings. Each of the rings has a loop that is parallel to the longitudinal axis and parallel to the rings. The stent assembly may form the support structure for a stent graft.

A stent is configured so that the length during expansion is unlikely reduced and has satisfactory flexibility so as to be able to pass through a biological lumen. In the stent, the number of mountains in a first annular portion and the number of mountains in a second annular portion between the first link portions adjacent to each other in a circumferential direction differ from each other. The first link portions are positioned on a first line parallel to an axial direction and the second link portions are positioned on a second line parallel to the axial direction, in a state where a plurality of annular reference bodies are repeatedly arranged in the axial direction.

A stent is configured so that the length during expansion is unlikely reduced and has satisfactory flexibility so as to be able to pass through a biological lumen. In the stent, the number of mountains in a first annular portion and the number of mountains in a second annular portion between the first link portions adjacent to each other in a circumferential direction differ from each other. The first link portions are positioned on a first line parallel to an axial direction and the second link portions are positioned on a second line parallel to the axial direction, in a state where a plurality of annular reference bodies are repeatedly arranged in the axial direction.

Devices that can be delivered into a vascular system to divert flow are disclosed herein. According to some embodiments, devices are provided for treating aneurysms by diverting flow. A flow-diverting device can comprise, for example, a frame and mesh immovably attached to and extending over a portion of the frame. The mesh can include a plurality of pores that are sized to inhibit the flow of blood through the frame into an aneurysm to a degree sufficient to lead to thrombosis and healing of the aneurysm when the device is positioned in a blood vessel and adjacent to the aneurysm.

An endoluminal prosthesis system for a branched body lumen comprises a branch vessel prosthesis. The branch vessel prosthesis is deployable within a branch vessel body lumen and comprises a stent having a generally tubular body portion, a flareable proximal end portion, and a coupling portion disposed intermediate the body portion and the flareable portion. The coupling portion is more crush-resistant than the body portion. The flareable proximal end may be disposed within a fenestrated stent graft with coupling portion disposed in the fenestration of the fenestrated stent graft.

An endoluminal prosthesis system for a branched body lumen comprises a branch vessel prosthesis. The branch vessel prosthesis is deployable within a branch vessel body lumen and comprises a stent having a generally tubular body portion, a flareable proximal end portion, and a coupling portion disposed intermediate the body portion and the flareable portion. The coupling portion is more crush-resistant than the body portion. The flareable proximal end may be disposed within a fenestrated stent graft with coupling portion disposed in the fenestration of the fenestrated stent graft.

An expandable member that is configured to engage an interior region of a prosthetic valve and capable of transitioning from a pre-deployment configuration at a pre-deployment temperature, where the expandable member is capable of being positioned in the valve at an interior valve region when the valve is disposed in a cardiovascular structure, to a post-deployment configuration when the expandable member is subjected to cardiovascular tissue temperature, where an outer surface region of the valve proximate the interior valve region is placed in intimate contact with host cardiovascular tissue of the cardiovascular structure at a first position and seals perivalvular leaks present at the first cardiovascular structure position.