A method for preparing tissue, in particular pericardial tissue, in particular for use as a sealing means for a heart valve prosthesis for paravalvular leaks, characterised in that the tissue, in particular pericardial tissue, is decellularized (4), subjected to a cross-linking (6) with a glutaraldehyde-containing solution, and subjected to a shape- and a structure-stabilising step (7, 8, 9). The invention also relates to a heart valve prosthesis.

This invention relates to the field of surgical implants, and in particular to a method of treating biomedical material, and more particularly bioprosthetic heart valves and tracheas, to mitigate calcification when implanted in a mammalian body.

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.

The present invention is directed to compositions and methods for the prevention or treatment of treatment of heterotopic ossification, vascular calcification, or pathologic calcification.

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.

This invention relates to a method for hiding stains in medical dressings and other textile substrates. The method includes applying a metallic silver coating to a textile substrate via a plasma enhanced chemical vapor deposition (PECVP) process. The metallic silver coating effectively hides any stain that comes into direct contact with the treated substrate by transferring the liquid beneath the surface of the coating. The invention also relates to textile substrates containing metallic silver coatings.

The present invention is directed to compositions and methods for the prevention or treatment of treatment of heterotopic ossification, vascular calcification, or pathologic calcification.

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.

The subject invention concerns non-degradable three dimensional porous collagen scaffolds and coatings. These scaffolds can be prepared around sensors for implantation into a body. A specific embodiment of the invention concerns implantable glucose sensors. Sensors comprising a collagen scaffold of the invention have improved biocompatibility by minimizing tissue reactions while stimulating angiogenesis. The subject invention also concerns methods for preparing collagen scaffolds of the invention. The subject invention also concerns sensors that have a collagen scaffold of the invention around the exterior of the sensor.

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.