The invention relates to a method for predicting or diagnosing a risk of bioprosthetic valve degeneration. Further, the invention relates to a medical device, in particular a bioprosthetic valve coated with EPCR less prone to degeneration and/or calcification once implanted.

Methods for inhibiting stenosis, obstruction and/or calcification of a heart valve following implantation in a vessel having a wall are disclosed. In one aspect the method includes providing a bioprosthetic heart valve mounted on an elastical stent; treating the bioprosthetic heart valve with a tissue fixative; coating the stent and the bioprosthetic valve with a coating composition including one or more therapeutic agents; implanting the bioprosthetic valve into the vessel in a diseased natural valve site; eluting the coating composition from the bioprosthetic valve; and inhibiting stenosis, obstruction and/or calcification of the bioprosthetic heart valve by preventing the attachment of stem cells to the bioprosthetic heart valve, the stem cells circulating external and proximate to the bioprosthetic heart valve by activating nitric oxide production (i) in the circulating stem cells, (ii) in an endothelial cell lining covering the bioprosthetic heart valve tissue, (iii) or both.

An implantable or insertable medical device can include a silicone substrate and a plasma-enhanced chemical vapor deposition coating on the silicone substrate. The coating may include a silicon-containing compound. A method of forming the coating is also provided.

Various aspects of the present disclosure are directed toward apparatuses, systems, and methods that include a cord that is flexible and elongated defining a length. The cord may include a core having a porous surface and a porosity-reducing element on at least a portion of the core.

There is disclosed a process for treatment to avert enzymatic degradation and tissue degeneration of bovine pericardium tissue, used for making bioprosthesis for implant application, comprising the steps of collecting and harvesting raw bovine pericardial tissue; chemically cross-linking the rinsed tissue to generate fixed tissue; laser cutting said fixed tissue to produce tissue leaflet; chemically treating said tissue leaflet with AAS; chemically sterilising and storing the fixed bovine pericardium tissue to maintain the structural integrity and characteristics; and wherein all the above steps are carried out in a low-oxygen and controlled temperature environment.

Described herein are tissue grafts derived from the placenta that possess good adhesion to biological tissues and are useful in wound healing applications. In one aspect, the tissue graft includes (1) two or more layers of amnion, wherein at least one layer of amnion is cross-linked, (2) two or more layers of chorion, wherein at least one layer of chorion is cross-linked, or (3) one or more layers of amnion and chorion, wherein at least one layer of amnion and/or chorion is cross-linked. In another aspect, the grafts are composed of amnion and chorion cross-linked with one another. In a further aspect, the grafts have one or more layers sandwiched between the amnion and chorion membranes. The amnion and/or the chorion are treated with a cross-linking agent prior to the formation of the graft. The presence of the cross-linking agent present on the graft also enhances adhesion to the biological tissue of interest. Also described herein are methods for making and using the tissue grafts.

The invention pertains to intraocular lens compositions comprising a polymeric mixture of monomers, a product comprising such compositions and uses thereof. The compositions of the inventions are completely vacuole-free, therefore resulting in a truly glistening free material. Moreover, they are soft enough to be easy to fold, have a properly tuned hardness to provide comfortable unfolding speed, require a low injection force, do not present prohibitive tackiness, and have good optical properties. Finally, the present intraocular lens compositions do not suffer from calcification.

A bioprosthetic tissue having a reduced propensity to calcify in vivo, the bioprosthetic tissue. The bioprosthetic tissue comprises an aldehyde cross-linked and stressed bioprosthetic tissue comprising exposed calcium, phosphate or immunogenic binding sites that have been reacted with a calcification mitigant. The bioprosthetic tissue has a reduced propensity to calcify in vivo as compared to aldehyde cross-linked bioprosthetic tissue that has not been stressed and reacted with the calcification mitigant.

Tissue prostheses having a base structure and a physiological sensor system. The tissue prostheses are adapted and configured to induce remodeling of damaged tissue and regeneration of new tissue and concurrently detect and monitor physiological characteristics when implanted in the subject.

A prosthetic tissue valve and a method of treating the prosthetic tissue valve are provided. The method includes: decreasing a temperature of a chamber carrying the prosthetic tissue valve from a first preset temperature to a second preset temperature in a first cooling rate; decreasing the temperature of the chamber carrying the prosthetic tissue valve from the second preset temperature to a third preset temperature in a second cooling rate; and performing a drying process to the prosthetic tissue valve. The second preset temperature is a critical crystallization temperature and is greater than a crystallization temperature of the prosthetic tissue valve. The third preset temperature is lower than the crystallization temperature of the prosthetic tissue valve, and the second cooling rate is greater than the first cooling rate.