A method and system of monitoring environmental exposure of stents using radiofrequency identification is disclosed.

Assemblies are provided comprising a stent and a sensor positioned on and/or in the stent. Within certain aspects the sensors are wireless sensors, and include for example one or more fluid pressure sensors, contact sensors, position sensors, accelerometers, pulse pressure sensors, blood volume sensors, blood flow sensors, blood chemistry sensors, blood metabolic sensors, mechanical stress sensors and/or temperature sensors. Within certain aspects these stents may be utilized to assist in stent placement, monitor stent function, identify complications of stent treatment, monitor physiologic parameters and/or medically image a body passageway, e.g., a vascular lumen.

A prosthesis system comprises plates that can be positioned against vertebrae and a selected resilient core that can be positioned between the plates to allow the plates to articulate. The selected resilient core can be chosen from a plurality of cores in response to patient characteristics, such as age and/or intervertebral mobility, such that the prosthesis implanted in the patient is tailored to the needs of the patient. The plurality of cores may comprise cores with different resiliencies, and one of the cores can be selected such that the upper and lower plates articulate with the desired shock absorbing resiliency and/or maximum angle of inclination when the one selected core is positioned between the plates.

A prosthesis system comprises plates that can be positioned against vertebrae and a selected resilient core that can be positioned between the plates to allow the plates to articulate. The selected resilient core can be chosen from a plurality of cores in response to patient characteristics, such as age and/or intervertebral mobility, such that the prosthesis implanted in the patient is tailored to the needs of the patient. The plurality of cores may comprise cores with different resiliencies, and one of the cores can be selected such that the upper and lower plates articulate with the desired shock absorbing resiliency and/or maximum angle of inclination when the one selected core is positioned between the plates.

Medical implants comprising biocompatible materials and having surface features that may assist in biocompatibility upon implantation in the body are described. Methods for manufacturing such implants are also described. The manufacturing process may include applying a biocompatible material to a texturized surface of a mold. The implants may include various features to assist their positioning, fixation, and/or identification during and/or after implantation.

An intraocular implant device includes: (1) a lens portion; and (2) a peripheral portion surrounding the lens portion, wherein the peripheral portion includes multiple fiducials including a first fiducial, a second fiducial, and a third fiducial, the first fiducial, the second fiducial, and the third fiducial are positioned in the peripheral portion so that the third fiducial is displaced from a line segment connecting the first fiducial and the second fiducial.

A lens including a posterior surface, an anterior surface, and at least one identification marking on the lens. The at least one identification marking exhibits a first degree of visibility in an ambient lighting condition and a second degree of visibility greater than the first degree of visibility in a lighting condition different than the ambient lighting condition.

An enclosure device is disclosed for delivering an implantable sheet-like support or repair device, such as ligament, tendon or other soft tissue support or repair device, to a surgical site. The enclosure device protects the support or repair device from unwanted adhesion and deformation during delivery and facilitates its optimal positioning at the injury or repair site where the support or repair device will be implanted. The enclosure device has a planar body foldable along one or more fold lines into at least two panels configured to contain the repair device between the panels; an optional cutout in one or more panels of the planar body at the panel edge opposite the fold line configured to expose a portion of the repair device; an optional positioning tab extending out from the fold line; and an optional securing mechanism to secure the enclosure device in a folded position. Methods of using the enclosure device are described.

Improvements to accommodating intraocular optic assemblies are disclosed herein. The accommodating intraocular optic assembly can include an optic and at least one stanchion. The at least one stanchion can extend a length between a base end and a distal end. The distal end can be operably engaged with the optic directly or indirectly. The at least one stanchion can include an outer sleeve defining a through-aperture. The at least one stanchion can also include at least one inner member positioned within the through-aperture.

A prosthetic heart valve configured to replace a native heart valve and for post-implant expansion and having a valve-type indicator thereon visible from outside the body post-implant. The indicator communicates information about the valve, such as the size or orifice diameter of the valve, and/or that the valve has the capacity for post-implant expansion. The indicator can be an alphanumeric symbol or other symbol or combination of symbols that represent information about the characteristics of the valve such as the valve size. The capacity for post-implant expansion facilitates a valve-in-valve procedure, where the valve-type indicator conveys information to the surgeon about whether the implanted valve is suitable for the procedure and informs the choice of the secondary valve.