The present invention provides a preparation method of a three-dimensional construct for regenerating a cardiac muscle tissue comprising; a step of forming a three-dimensional construct by printing and crosslinking the first bioprinting composition comprising a tissue engineering construct forming solution containing decellularized extracellular matrix and a crosslinking agent, and cardiac progenitor cells, and the second bioprinting composition comprising the tissue engineering construct forming solution, mesenchymal stem cells and a vascular endothelial growth factor, to arrange the first bioprint layer and the second bioprint layer alternately; and a step of obtaining a crosslink-gelated three-dimensional construct by thermally gelating the crosslinked three-dimensional construct, and a three-dimensional construct for regenerating a cardiac muscle tissue, and the preparation method according to the present invention not only equally positions the cardiac progenitor cells in the construct but also implements a vascular network composed of vascular cells in the construct, so that the viability of cells can be maintained for a long time and the cell transfer efficiency into the myocardium can be significantly improved.

Tissue compositions and methods of preparation thereof are provided. The tissue compositions can be used to treat or regenerate muscle tissue. The compositions can be configured to provide increased strength compared to other muscle matrices.

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 method of producing organized skeletal muscle tissue from precursor muscle cells in vitro comprises: (a) providing precursor muscle cells on a support in a tissue media; then (b) cyclically stretching and relaxing the support at least twice along a first axis during a first time period; and then (c) optionally but preferably maintaining the support in a substantially static position during a second time period; and then (d) repeating steps (b) and (c) for a number of times sufficient to enhance the functionality of the tissue formed on the support and/or produce organized skeletal muscle tissue on the solid support from the precursor muscle cells.

A method of producing organized skeletal muscle tissue from precursor muscle cells in vitro comprises: (a) providing precursor muscle cells on a support in a tissue media; then (b) cyclically stretching and relaxing the support at least twice along a first axis during a first time period; and then (c) optionally but preferably maintaining the support in a substantially static position during a second time period; and then (d) repeating steps (b) and (c) for a number of times sufficient to enhance the functionality of the tissue formed on the support and/or produce organized skeletal muscle tissue on the solid support from the precursor muscle cells.

Artificial heart valve structures and methods of their fabrication are disclosed. The heart valve structures may be fabricated from a biocompatible polymer and include one or more heart valve leaflet structures incorporated within a conduit. The valve structures may incorporate one or more conduit sinuses, as well as a gap between the lower margin of the valve leaflets and the interior of the conduit. In addition, the valve structures may include one or more valve sinuses created in a space between the valve leaflets and the conduit inner surface. Computational fluid dynamics and mechanical modeling may be used to design the valve leaflets with optimal characteristics. A heart valve structure may also incorporate a biodegradable component to which cells may adhere The incorporated cells may arise from patient cells migrating to the biodegradable component, or the component may be pre-seeded with cells prior to implantation in a patient.

A prosthetic atrioventricular tissue valve comprising a continuous tubular member formed from a first biocompatible material, the tubular member having proximal and distal ends, and at least one valve leaflet formed therein, the distal end of the tubular member including cardiovascular structure engagement means for connecting the tubular member to a cardiovascular structure, the cardiovascular structure engagement means comprising a plurality of elongated members that extend distally from the distal end of the tubular member.

Cardiovascular prostheses for treating, reconstructing and replacing damaged or diseased cardiovascular tissue that are formed from acellular extracellular matrix (ECM). The cardiovascular prostheses comprise various compositions, such as ECM based compositions, and structures, such as particulate structures, mesh constructs, encasement structures, coated structures and multi-sheet laminate structures.

The present disclosure relates to methods for recellularization of valves in valve-bearing veins. This method is useful for producing an allogeneic venous valve, wherein a donor valve-bearing vein is decellularized and then recelluiarized using whole blood or bone marrow stem cells. The allogeneic valves produced by the methods disclosed herein are advantageous for implantation, transplantation, or grafting into patients with vascular diseases.

Artificial heart valve structures and methods of their fabrication are disclosed. The heart valve structures may be fabricated from a biocompatible polymer and include one or more heart valve leaflet structures incorporated within a conduit. The valve structures may incorporate one or more conduit sinuses, as well as a gap between the lower margin of the valve leaflets and the interior of the conduit. In addition, the valve structures may include one or more valve sinuses created in a space between the valve leaflets and the conduit inner surface. Computational fluid dynamics and mechanical modeling may be used to design the valve leaflets with optimal characteristics. A heart valve structure may also incorporate a biodegradable component to which cells may adhere The incorporated cells may arise from patient cells migrating to the biodegradable component, or the component may be pre-seeded with cells prior to implantation in a patient.