A system and method for decellularizing tissue is provided. The system includes a pretreatment chamber including a pretreatment solution (e.g., a surfactant), a decellularization solution comprising carbon dioxide and one or more polar solvents, as well as an environmental chamber comprising a treatment chamber. The environmental chamber is maintained at a temperature greater than 31.1° C. and the carbon dioxide is maintained at a pressure greater than 7.38 megapascals to form supercritical CO.sub.2. Tissue treated with the decellularization system and method can contain less than 0.05 micrograms of DNA per milligram of dry tissue after the tissue is exposed to the decellularization solution for a time period ranging from about 1 minute to about 2 hours with minimal ECM fiber disruption. A two-part decellularization solution comprising a surfactant as well as supercritical CO.sub.2 and one or more polar solvents is also provided.

The presently disclosed subject matter provides a scalable and electrostretching approach for generating hydrogel microfibers exhibiting uniaxial alignment from aqueous polymer solutions. Such hydrogel microfibers can be generated from a variety of water-soluble natural polymers or synthetic polymers. The hydrogel microfibers can be used for controlled release of bioactive agents. The internal uniaxial alignment exhibited by the presently disclosed hydrogel fibers provides improved mechanical properties to hydrogel microfibers, and contact guidance cues and induces alignment for cells seeded on or within the hydrogel microfibers.

Described herein are compositions comprising decellularized extracellular matrix derived from skeletal muscle or other suitable tissue, and therapeutic uses thereof. Methods for treating, repairing or regenerating defective, diseased, damage, ischemic, ulcer cells, tissues or organs in a subject preferably a human, with diseases associated with muscular degeneration, using a decellularized extracellular matrix of the invention are provided. Methods of preparing culture surfaces and culturing cells with absorbed decellularized extracellular matrix are provided.

A composition for use in treating penile defects, including erectile dysfunction and Peyronie's disease, is provided. The composition includes adipose tissue and stem cells. The stem cells may be derived from adipose tissue. In embodiments the composition includes additional additives such as growth factors, anti-inflammatories, antioxidants, compositions useful for wound healing, and collagenases. Also provided is a method of treating a penile defect in a patient. The method includes providing a composition containing adipose tissue and stem cells, and implanting that composition into a patient in need of treatment for a penile defect. In some embodiments the patient has Peyronie's disease. In other embodiments, the patient has erectile dysfunction.

An object of the invention is to provide a cartilage regenerative material that suppresses infiltration of fibrous soft tissue and brings about satisfactory cartilage regeneration, and a method for producing the cartilage regenerative material. Provided is a cartilage regenerative material including a porous body of a biocompatible polymer and a biocompatible polymer film, in which the porous body contains chondrocytes and cartilage matrix, and the cartilage matrix exists in a region of 10% or more of a region extending from the surface of the transplant face of the porous body to a depth of 150 μm along the thickness.

The present invention provides a series of injectable bionanocomposites that may be delivered via injection to various tissue repair sites including myocardial infarction, intervertebral disc reconstruction, reconstruction of skeletal muscle, and musculoskeletal applications, urinary incontinence, adipose tissue engineering, and orthopedic applications such as osteoporosis, and meniscus and articular cartilage repair.

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.

The present application provides methods of functionalizing an organ or tissue of a mammal by administering a nutrient (e.g., peracetylated N-azido galactosamine Ac4GalNAz) to the mammal or by culturing an organ or tissue in a bioreactor containing such nutrient. The present application also provides methods of selectively functionalizing extracellular matrix (ECM) of an organ or tissue of a mammal by administering a nutrient (e.g., peracetylated N-azido galactosamine Ac4GalNAz) to the mammal. In some aspects, the present application provides a decellularized scaffold of a mammalian organ or tissue comprising an extracellular matrix, wherein the extracellular matrix of the decellularized scaffold is functionalized with a chemical group that is reactive in a bioorthogonal chemical reaction, such as an azide chemical group. The present application also provides biological prosthetic mesh and mammalian organs and tissues for transplantation prepared according to the methods of the application.

Methods for decellularizing organs and tissues in vitro and in vivo are provided, as are methods of maintaining organ and tissue frameworks and methods of recellularizing organs and tissues, thereby providing an approach to needed organs or tissues.

Porcine scaffolds are provided that include decellularized, porcine placental extracellular matrix. Methods of preparing decellularized, porcine placental extracellular matrix as well as methods of treatment are also provided.