Some embodiments of the disclosure provide a decellularized heart valve (DHV) composite, a preparation method of the DHV composite, and a use of the DHV composite. In some examples, the preparation method of the DHV composite includes the following steps: S1, conducting a reaction I on a DHV with a copper chloride-dopamine hydrochloride mixed solution to obtain a copper ion-modified DHV; and S2, conducting a reaction II on the copper ion-modified DHV with a GDF11 solution to obtain the DHV composite. In other examples, the present disclosure provides a use of the DHV composite in preparation of a tissue-engineered heart valve (TEHV). In further examples, the TEHV is a heart valve (HV) with remodeling and regeneration capabilities.

A cardiac patch for treatment of a mammalian heart including perfusable vessels embedded integratedly between two layers of anisotropically oriented myocardial fibers. The cardiac patch is made using a dual 3D bioprinting technique using stereolithography to form an anisotropic construct and extrusion printing to form perfusion vessels. A nutrient and oxygen containing media can be provided within the perfusion vessels for growth of cells in the cardiac patch. The technique permits larger patches to be made for the treatment of cardiac damage in both small and large mammalian hearts.

Provided in this disclosure are various composite grafts having a trabecular synthetic scaffold with voids defined in at least a portion of the scaffold and a biological component positioned in at least some of the voids of the scaffold. The grafts may be osteogenic, chondrogenic, osteochondrogenic, or vulnerary in nature. Also provided are methods of using the composite grafts to treat a tissue defect in a subject. Methods of manufacturing are also provided. Grafts are manufactured by additive manufacturing. Agitation may be used to combine composite grafts with additional biological component.

The present invention is drawn to a 3-dimensional cell-produced scaffold construct comprising cells and the extracellular matrix that has been produced and arranged by these cells.

Systems and methods for producing biologic tissues are described. For example, this document provides electrospinning systems and culturing techniques to make biologic heart valve leaflets and fibrosa layers of native valve leaflet having nanofibrous substrate layer(s). In some implementations, a tri-layered leaflet with circumferentially, randomly, and radially oriented nanofibers that mimics morphologies of native leaflets.

A prosthetic valve comprising a conical shaped sheet member comprising an extracellular matrix (ECM) composition, the sheet member having a plurality of ribbons projecting the sheet member proximal end, the distal ends of the ribbons being positioned proximate each other, wherein the sheet member comprises a conical shape.

An object of the present invention is to provide a laminate containing a cell sheet which has hardness and is easy to handle at the time of transplantation or transport, an agent for treating cardiac diseases using the laminate, and a film for being laminated on a cell sheet. According to the present invention there are provided a laminate including a biocompatible polymer film having a density of 500 g/cm.sup.2 to 10 mg/cm.sup.2 and a cell sheet disposed on at least one surface of the biocompatible polymer film, an agent for treating cardiac diseases using the laminate, and a film for being laminated on a cell sheet.

A prosthetic valve comprising a conical shaped ribbon structure comprising an extracellular matrix (ECM) composition. The ribbon structure comprises a plurality of elongated ribbon members that are positioned proximate each other in a joined relationship, wherein the ribbon members are positioned adjacent each other and form a plurality of fluid flow modulating regions that open when fluid flow through the valve exhibits a negative flow pressure and open when fluid flow through the valve exhibits a positive flow pressure.

Disclosed herein are contractile cell constructs comprising contractile cells, or progenitors thereof, adhered to a surface of a three dimensional fibroblast containing scaffold (3DFCS) and methods for using them to treat disease. In one aspect, the present invention provides methods for preparing a contractile construct, comprising (a) seeding immature contractile cells onto the surface of a three dimensional fibroblast containing scaffold (3DFCS) to produce a contractile construct; and (b) culturing the contractile construct under conditions to promote differentiation of the immature contractile cells into mature contractile cells, wherein the mature contractile cells form striations. In a further aspect, the invention provides methods for treating a disorder characterized by a lack of functioning contractile cells, comprising contacting a patient with a contractile cell-based disorder with an amount effective to treat the disorder with the construct of any embodiment or combination of embodiments of the invention.

Methods of treating a complex wound by administering to a complex wound in the individual a therapeutically effective amount of a fetal support tissue product to treat the complex wound. Methods of treating a complex lower extremity ulcer by administering to a complex lower extremity ulcer in the individual a therapeutically effective amount of a fetal support tissue product to treat the complex lower extremity ulcer. Methods of reducing or preventing scar formation from granulation tissue by administering a fetal support tissue product to granulation tissue. Methods of repairing a spina bifida defect by administering to the defect in the individual a therapeutically effective amount of an umbilical cord product.