Described are methods for producing multi-layered tubular tissue structures, tissue structures produced by the methods, and their use.

A prosthetic valve comprising a conical shaped sheet structure and a support structure, the sheet structure having a closed distal end and a plurality of elongated ribbon members that are positioned proximate each other in a joined relationship, whereby the ribbon members form a plurality of fluid flow modulating regions that close when fluid flow through the valve exhibits a negative flow pressure and open when fluid flow through the valve exhibits a positive flow pressure, the support structure having at least one elongated cardiovascular structure engagement member that is associated with one of the ribbon members and adapted to engage a cardiovascular structure.

A matrix, including epithelial basement membrane, for inducing repair of mammalian tissue defects and in vitro cell propagation derived from epithelial tissues of a warm-blooded vertebrate.

Vascular grafts for treating, reconstructing and replacing damaged or diseased cardiovascular vessels that are formed from decellularized extracellular matrix (ECM). The vascular grafts include outer or outer and inner coatings that provide structural reinforcement.

A method is provided for implanting a valve having at least one valve leaflet within the cardiovascular system of a subject. One step of the method includes preparing a substantially dehydrated bioprosthetic valve and then providing an expandable support member having oppositely disposed first and second ends and a main body portion extending between the ends. Next, the substantially dehydrated bioprosthetic valve is attached to the expandable support member so that the substantially dehydrated bioprosthetic valve is operably secured within the main body portion of the expandable support member. The expandable support member is then crimped into a compressed configuration and placed at a desired location within the cardiovascular system of the subject. Either before or after placement at the desired location, fluid or blood re-hydrates the substantially dehydrated bioprosthetic valve.

An optical method for determining collagen bundle orientation in bovine pericardium includes the use of a system having a light source which transmits light through a first polarizer, a tissue for making a prosthetic valve leaflet, and a second polarizer, where the light then illuminates a detector plate. The light that illuminates the detector plate is used to determine the orientation of collagen fiber bundles. The orientation of the collagen fiber bundles is used to determine where to cut the leaflet edges.

Prosthetic heart valves having a conical shaped base valve structure formed from collagenous mammalian tissue and an expandable stent structure. The base valve structure includes a plurality of elongated ribbon members that are positioned proximate each other in a joined relationship, wherein the elongated ribbon members are positioned adjacent each other and form a plurality of fluid flow modulating regions that open when fluid into and through the base valve structure exhibits a positive pressure relative to the exterior pressure, i.e., a positive pressure differential, wherein the fluid is allowed to be transmitted out of the base valve structure, and transition to a closed configuration when the pressure differential between the interior valve pressure and exterior pressure reduces, wherein the fluid is restricted from flowing out of the base valve structure. The expandable stent structure includes a plurality of tethers adapted to pierce cardiovascular tissue and, thereby, position the base valve structure and, thereby, prosthetic valves formed therewith on said heart valve annulus.

Prosthetic valves that include conical shaped base valve members having an annular engagement end, a closed distal end region that restricts fluid flow therethrough, and a plurality of elongated ribbon members, which transition from an open fluid flow configuration to a closed fluid flow configuration in response to expansion and contraction of the base valve member, and a support structure that is configured and adapted to exert retaining forces on the annular engagement ends of the base valve members, whereby the support structure (i) conforms to the shape of the annular engagement ends of the base valve members, (ii) securely positions the annular engagement ends of the base valve members adjacent to and, thereby, in contact with a valve annulus, whereby the annular engagement ends of the base valve members conform to the shape of the valve annulus, and (iii) the annular engagement ends of the base valve members adapt to at least one fluctuation in the configuration and/or dimension of the valve annulus, whereby the annular engagement ends of the base valve members maintain contact therewith.

Described are methods for producing multi-layered tubular tissue structures, tissue structures produced by the methods, and their use.

A sterile, packaged bioprosthetic heart valve includes an expandable support member, a bioprosthetic valve attached to the expandable support member, a layer of biocompatible material covering at least a portion of the expandable support member, and a microorganism-resistant container in which the bioprosthetic valve is sealed. The bioprosthetic valve includes a tissue component comprising glutaraldehyde-fixed bovine pericardium including interstices containing a dimensional stabilizer comprising an aqueous solution of propylene glycol.