To provide a stent delivery system configured to prevent twisting of a strut during expansion of a stent. A balloon has a plurality of limb portions folded at a plurality of folding pleats in a deflated state. The limb portions are folded in a first circumferential direction to surround the shaft as seen from a proximal end side of an axial direction of the shaft. The strut of the stent has helical portions formed in a helical shape extending along a second circumferential direction opposite to the first circumferential direction as seen from the proximal end side of the axial direction with being centered on an axis extending along the axial direction of the shaft.

A luminal prosthesis comprises a plurality of radially expandable prosthetic stent segments arranged axially. Two or more of the prosthetic stent segments are separable upon expansion from the remaining prosthetic stent segments and a coupling structure connects at least some of the adjacent prosthetic stent segments to each other. The coupling structure permits a first group of the adjacent prosthetic stent segments to separate from a second group of the prosthetic stent segments upon differential radial expansion of the first group relative to the second group and the coupling structure maintains or forms an attachment between the adjacent prosthetic stent segments in the first group which have been expanded together. A delivery system and methods for deploying the multiple coupled prosthetic stent segments are also disclosed.

This invention is a system for the treatment of body passageways; in particular, vessels with vascular disease. The system includes an endovascular graft with a low-profile delivery configuration and a deployed configuration in which it conforms to the morphology of the vessel or body passageway to be treated as well as various connector members and stents. The graft is made from an inflatable graft body section and may be bifurcated. One or more inflatable cuffs may be disposed at either end of the graft body section. At least one inflatable channel is disposed between and in fluid communication with the inflatable cuffs.

The invention is directed to an expandable stent for implanting in a body lumen, such as a coronary artery, peripheral artery, or other body lumen. The invention provides for an intravascular stent having a plurality of cylindrical rings connected by undulating links. The stent has a high degree of flexibility in the longitudinal direction, yet has adequate vessel wall coverage and radial strength sufficient to hold open an artery or other body lumen. The stent can be compressed or crimped onto a catheter to a very low profile since the peaks that are adjacent the curved portion of the undulating link are shorter than other peaks in the same cylindrical ring to prevent overlap yet still achieve a very low profile, tightly crimped stent onto a catheter.

A stent including a plurality of curved sections and a connector. The curved sections surround a longitudinal axis to define a tube portion and are distributed along the longitudinal axis to form a helix. The connector includes a bioresorbable material and is positioned between two adjacent curved sections. The stent has a spring constant that changes to a different spring constant after exposure to biological material.

A stent including a plurality of curved sections and a connector. The curved sections surround a longitudinal axis to define a tube portion and are distributed along the longitudinal axis to form a helix. The connector includes a bioresorbable material and is positioned between two adjacent curved sections. The stent has a spring constant that changes to a different spring constant after exposure to biological material.

Bioabsorbable scaffolds having high crush recoverability, high fracture resistance, and reduced or no recoil due to self expanding properties at physiological conditions are disclosed. The scaffolds are made from a random copolymer of PLLA and a rubbery polymer such as polycaprolactone.

A stent defining a longitudinal axis is disclosed. A plurality of circumferential support structures are spaced-apart along the longitudinal axis. At least some of the circumferential support structures are interconnected by connection members that extend generally in a circumferential direction.

A stent including a plurality of curved sections and a connector. The curved sections surround a longitudinal axis to define a tube portion and are distributed along the longitudinal axis to form a helix. The connector includes a bioresorbable material and is positioned between two adjacent curved sections. The stent has a spring constant that changes to a different spring constant after exposure to biological material.

A tubular stent has first and second ends and a longitudinal axis therebetween. The tubular stent is formed from a network of struts which defines a cylindrical surface about the longitudinal axis, the struts delineating a plurality of cells within the network, there being rows of cells parallel to the longitudinal axis. At least one cell in each row is a nodal cell. There is an increase in the maximum length parallel to the longitudinal axis of cells from the nodal cell to a first distal cell in the row that is closer to the first or second end of the tubular stent. There is a second distal cell in the row which has a different maximum length parallel to the longitudinal axis from the nodal cell and the first distal cell. The network of struts comprises a plurality of circumferential rings. Each ring extends perpendicularly to the longitudinal axis and the rings are located adjacent to each other parallel to the longitudinal axis to define the cylindrical surface. The circumferential rings are of a wave form. Each circumferential ring has an amplitude parallel to the longitudinal axis, such that each wave form comprises a plurality of peaks which extend towards the axial center of the tubular stent and a plurality of troughs which extend away from the axial center of the tubular stent.