A stent graft configured to facilitate the placement of a secondary stent is provided and a method thereof. The stent graft can include an elongated body with a frame structure, a lumen, and apertures at both ends of the elongated body. The frame structure can be covered by a graft material. At least one station can be located in the graft material. The at least one station has a perimeter defined by a ring structure connected to the graft material and an aperture bounded by the perimeter. The aperture can be covered by graft material. The at least one station can be fenestrated to facilitate placement of a secondary stent.

A multi-piece IOL assembly is provided that includes a platform and an optic. The platform has an inner periphery surrounding an inner zone of the platform. The optic has an optical zone, an outer periphery and a retention mechanism disposed on the outer periphery. The optic is configured to be disposed in the inner zone of the platform and to extend to a location between the inner periphery and the outer periphery of the platform to be secured to the platform at the location. The platform can be secured to an inner periphery of the eye or can be formed into a natural lens by cutting the lens using a laser or other energy source.

A mesh element having a mesh gauge selected to control flow of materials therethrough. The mesh element is implantable into an anatomical structure upstream of a body passage or within a body passage to control flow of materials through the body passage. The mesh element may be coupled to a support structure to facilitate anchoring of the mesh element in place relative to the body passage. The support structure may have a lumen defined therethrough to allow flow of materials through the body passage, with the mesh element regulating the flow of materials into the lumen. The mesh element alternatively may be directly coupled to an anatomical structure upstream of a body passage to regulate or determine flow of materials through the body passage.

Devices, systems, and methods to improve both the reliability of soft tissue repair procedures and the speed at which the procedures are completed are provided. The devices and systems include one or more structured tissue augmentation constructs, which include constructs that are configured to increase a footprint across which suture applied force to tissue when the suture is tied down onto the tissue. The tissue augmentation constructs can be quickly and easily associated with the repair suture and can be useful in many different tissue repair procedures that are disclosed in the application. The present disclosure includes structured tissue augmentation blocks for tendon repair that have a flexible or semi-flexible skeleton integrated into the block. The skeleton can be bioabsorbable and can create both in-plane and out-of-plane curvature in the block.

A mesh element having a mesh gauge selected to control flow of materials therethrough. The mesh element is implantable into an anatomical structure upstream of a body passage or within a body passage to control flow of materials through the body passage. The mesh element may be coupled to a support structure to facilitate anchoring of the mesh element in place relative to the body passage. The support structure may have a lumen defined therethrough to allow flow of materials through the body passage, with the mesh element regulating the flow of materials into the lumen. The mesh element alternatively may be directly coupled to an anatomical structure upstream of a body passage to regulate or determine flow of materials through the body passage.

A bone implant for enclosing bone material is provided. The bone implant comprises a nonwoven mesh having an inner surface and an outer surface opposing the inner surface and configured to receive a bone material when the inner surface of the mesh is in an open configuration. A plurality of projections are disposed on or in at least a portion of the inner surface of the mesh, the outer surface of the mesh or both the inner and outer surfaces of the mesh, the plurality of projections extending from at least the portion of the inner surface, the outer surface of the mesh or both the inner and outer surfaces of the mesh and are configured to engage a section of the inner surface of the mesh or a section of the outer surface of the mesh or both in a closed configuration so as to enclose the bone material.

An elbow prosthesis according to the present teachings can include a stem structure and an articulating component. The stem structure can be operable to be positioned in a bone of a joint. The stem structure can include a stem portion that is operable to be positioned in the bone and a C-shaped body portion having a first retaining mechanism formed thereon. The articulating component can have a second retaining mechanism formed thereon. One of the first and second retaining mechanisms can comprise an extension portion and a first anti-rotation portion. The other retaining mechanism can comprise a receiving portion and a second anti-rotation portion. The articulating component can be advanced from an insertion position to an assembled position, such that the first and second mechanisms cooperatively interlock to inhibit translation and rotation of the articulating component relative to the C-shaped body portion of the stem structure.

An elbow prosthesis includes a stem structure and an articulating component. The stem structure is operable to be positioned in a bone of a joint and includes a stem portion and a C-shaped body portion. The stem portion is operable to be positioned in the bone. The C-shaped body portion includes a first articulating surface bound by a medial wall and a lateral wall. The medial and lateral walls are separated by a first distance. The articulating component includes a second articulating surface positioned between a medial side surface and a lateral side surface. The medial and lateral side surfaces are separated by a second distance that is less than the first distance. The second articulating surface is configured to slidably communicate in a medial/lateral direction along the first articulating surface of the C-shaped body portion.

A kit of stents and an adjustable multi-lumen stent for adjustable interventional reduction of blood flow in a blood vessel. The kit includes: a first reduction stent having in an expanded conformation at least one widened section and a narrowed section, the narrowed section defining a central lumen providing reduced fluid communication between an upstream end and a downstream end of the first reduction stent; at least one expandable dilatation stent having a tubular form insertable into and expandable in the central lumen of the first reduction stent to define an enlarged central lumen; at least one second reduction stent having a narrowed tubular section insertable into the central lumen of the first reduction stent or the central lumen of the dilatation stent to define an reduced central lumen, and having an anchoring element at its upstream end.

There is provided herein a breast implant comprising: a base having a first diameter, the base is configured to rest against a subject's chest wall when implanted; a dome having a second diameter, the dome is configured to be positioned within breast parenchyma underneath a nipple-areola complex when implanted; and an elongated projecting structure extending between the base and the dome, wherein the implant is configured to be inserted into a subject's breast as an internal supporting skeleton and to affect the projection of breast.