A method for manufacturing a cardiac valve prosthesis is disclosed. This method comprises the following steps: a) shaping human or animal body tissue in a shaping process to give the body tissue a shape of a cardiac valve, and b) fixation and stabilization of the body tissue by a cross-linking agent, thereby preserving the shape given to the body tissue by the shaping process and thus obtaining a cardiac valve prosthesis. Furthermore, a method of implanting an autologous or allogenic cardiac valve prosthesis to an individual in need thereof is disclosed.

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.

This disclosure provides a tissue-engineered transcatheter vein valve and methods of making such a tissue-engineered transcatheter vein valve. Methods of making the valve include casting or molding a polymer into a tubular structure having a first end and a second end, where the first end of the tubular structure is cast or molded around a tubular support structure and where the second end of the tubular structure is cast or molded in the absence of the support structure; everting the polymer at the second end through the support structure; anchoring the second end of the tubular structure to the support structure at a first position and a second position, where the anchored first position and the anchored second position result in commissures, forming leaflets therebetween.

The present invention provides methods for cellular seeding onto three-dimensional fibroblast constructs, three-dimensional fibroblast constructs seeded with muscle cells, and uses therefore.

A paravalvular leak resistant prosthetic heart valve system including a stent frame, a valve structure and a sealing mechanism. The stent frame has a surface. The valve structure is associated with the stent frame. The sealing mechanism at least partially extends over the surface of the stent frame. The sealing mechanism includes at least one semi-permeable membrane and an osmotic gradient driving material.

The present invention relates to novel compositions and methods for reducing or eliminating the thrombogenicity of a graft by modifying the graft with a cell-derived extracellular matrix lacking thrombospondin-2 (TSP2-null ECM) to render it non-thrombogenic when transplanted to a subject in need thereof. The invention also provides a method for improving the biocompatibility of a medical device or an implant by modifying the medical device or implant with a cell-derived TSP2-null ECM, whereby the medical device or implant is rendered non-thrombogenic and pro-migratory.

Embodiments herein relate to a method of providing features (LCD, HD, HD_IN, HD_OUT) on an implantable material (ID), the method comprising: providing an implantable material (ID) comprising a decellularized sterilized mammalian tissue having an extracellular matrix, wherein a plurality of interstitial spaces of the extracellular matrix include a solution of one or more polyols, providing one or more features (LCD, HD, HD_IN, HD_OUT) on said implantable material (ID) by laser treatment.

There is provided a method for decreasing leakage of matter from an object to a surrounding, said object being coated with a coating at least partially applied on the object, said coating comprising an at least partially covering layer comprising silver, said object optionally comprising area(s) without said layer, said coating comprising metal particles applied on the layer and optionally on areas without said layer, said metal particles comprising palladium and at least one metal selected from the group consisting of gold, ruthenium, rhodium, osmium, iridium, niobium, neodymium and platinum and wherein the amount of the metal particles is in the interval 0.01-8 μg/cm.sup.2. Advantages include that leakage of matter such as latex allergens of metal ions can be reduced while the coating is both biocompatible and antimicrobial. Further, the blood clotting can be reduced.

A heart valve replacement device comprises a stent having a first end, a second end, an outer surface, and an inner surface, the inner surface defining a lumen; and a valve disposed within the lumen of the stent, the valve formed from a single sheet of tissue, the valve having an outer surface, an inner surface, and a thickness between the outer surface and the inner surface, the valve comprising at least three leaflets, wherein, the valve is attached to the stent with minimal sutures. The leaflets are formed with a curvilinear surface.

The present disclosure provides patterned biomaterials having organized cords and extracellular matrix embedded in a 3D scaffold. According, the present disclosure provides compositions and applications for patterned biomaterials. Pre-patterning of these biomaterials can lead to enhanced integration of these materials into host organisms, providing a strategy for enhancing the viability of engineered tissues by promoting vascularization.