Provided herein are enzymatically decellularized cells, and methods of producing said cells, that can be used in a scaffold. The scaffolds featured herein are biocompatible and can comprise decellularized cells that have been modified to express a bioactive agent or molecule.

The present invention provides an enhanced osteogenic composition comprising of connective tissue proteins having molecular weights greater than or equal to 3.5 kDa wherein the composition is prepared by treating demineralized bone material in an acidic extraction medium at a pH between about 0.10 to 0.45 at an extraction temperature between greater than 25° C. and less than 80° C. for a predetermined time period. The present invention further provides a method of making the enhanced osteogenic composition.

Methods of forming a connective tissue-to-bone interface scaffolds (e.g., ligament-to-bone interface scaffolds, tendon-to-bone interface scaffolds, etc.). These scaffolds (grafts) may be formed from in such a way as to provide both a mineralized and demineralized layer in which the entire graft is flexible, compressible and compliant.

Provided herein are soluble soft tissue protein compositions that can contain one or more soft-tissue bioactive factors, methods of making the soluble soft tissue protein compositions, and methods of using the soluble soft tissue protein compositions.

Provided herein are methods and compositions for cardiac therapy. Such compositions include extracellular-matrix (ECM)-based products that can be used to support tissue repair. The compositions can be used for various purposes. In some cases, they can be introduced into a subject in order to preserve and/or repair damaged heart tissue.

Isolated composites are disclosed comprising collagen fibers isolated from a Sarcophyton sp. coral. An exemplary composite comprises as a first component a bundle of collagen fibers, the collagen fibers being isolated from a Sarcophyton sp. coral, and a second component selected from the group consisting of a polysaccharide, a polypeptide, polylipid, a synthetic polymer, a metal and a mineral, wherein the bundle of collagen fibers comprise woven fibers, twisted fibers, braided fibers, knitted fibers, tied fibers, or sutured fibers. Uses thereof and method of generating are also disclosed.

A neural repair construct fabricated from human birth tissue comprising at least one cross-linked amniotic membrane, or at least one cross-linked chorionic membrane, or at least one amniotic membrane, or at least one chorionic membrane, or any combination thereof wherein the membrane(s) is/are treated with at least one alcohol composition followed by terminal sterilization is provided. Methods of processing a membrane to form a neural repair construct, methods of repairing a nerve and associated kits are also provided.

One aspect of the present invention is a method of producing a decellularized composite tissue bioscaffold for musculoskeletal tissue interface reconstruction by physicochemically treating a musculoskeletal tissue interface isolated from allogeneic sources. In certain embodiments, such musculoskeletal tissue interfaces can also be isolated from xenogeneic sources. The method comprises treatment of the interface with detergents, chemical oxidants and ultrasonic energy, and wash steps in between to remove residual detergents as well as oxidants. The resulting bioscaffold may be freeze-dried or lyophilized, sterilized and aseptically packaged for subsequent use.

A bone implant comprising cancellous bone that is essentially free of blood cells, and which has been treated with at least one loosening agent, such as collagenase or a digestive enzyme, for a time and at a concentration to loosen the osteogenic cells in the cancellous bone matrix. The osteogenic cells in the matrix are viable cells. The treatment of the cancellous bone with at least one loosening agent enables the osteogenic cells to be more available for carrying out their osteogenic function and to provide for an increased rate of bone formation. Such implant also may include demineralized bone, such as demineralized cortical bone, which enhances the bone regenerative capacity of the cancellous bone.

Decellularized muscle matrices are provided for use as implants and grafts to repair, regenerate, supplement, reinforce and replace muscle tissue. The decellularized muscle matrices are derived from muscle tissue having preserved extracellular matrix components, retained muscle-forming potential, and from which immunogenic components have been removed. The decellularized muscle matrices are produced in various physical forms and combinations. Methods for making and using the decellularized muscle matrices are also provided.