A method of corneal and scleral inlay crosslinking and preservation is disclosed herein. The method includes cross-linking at least a portion of a donor cornea or a donor sclera so as to kill cellular elements in the portion of the donor cornea or the donor sclera, and make the portion of the donor cornea or the donor sclera less antigenic to a body portion of a recipient patient in which the portion of the donor cornea or the donor sclera is to be implanted; and storing the cross-linked donor cornea or the donor sclera for a long period of time prior to implanting the portion of the donor cornea or the donor sclera into the body portion of the recipient patient.

A method for preparing tissue, in particular pericardial tissue, in particular for a heart valve prosthesis, the method including: decellularizing the tissue; subjecting the decellularized tissue to a cross-linking solution including glutaraldehyde; subjecting the tissue to a shape- and structure-stabilizing step, in which the tissue is exposed to a first solution containing glycerol and is exposed to a second solution containing polyethylene glycol; and drying the tissue after the shape- and structure-stabilizing step.

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.

Allograft biomaterials, implants made therefrom, methods of making the biomaterial and implants, methods of promoting cartilage, tissue, bone or wound healing in a mammal by administering the biomaterial or implant to the mammal, and kits that include such biomaterials, implants, or components thereof. For example, the allograft may include viable cells, for example, which were native to intervertebral discs and/or umbilical cords that the allograft was derived from.

A method of making infused non-demineralized cartilage particles employs the following steps: cutting or shaving cartilage tissue into cartilage particles, washing the particles, and infusing the particles with a supernatant of biologic material or a polyampholyte cryoprotectant or a combination of both to create infused particles.

A tissue graft for soft tissue repair or reconstruction comprising a sheet of a biopolymer-based matrix having a plurality of small perforations and a plurality of large perforations. The small perforations are sized to facilitate clotting and granulation tissue development within the perforations which, in turn, facilitates revascularization and cell repopulation in the patient. The large perforations are sized to reduce the occurrence of clotting and granulation tissue development within the perforations so that extravascular tissue fluids accumulating at the implant site can drain through the tissue graft. The large perforations enhance mammal tissue anchoring by permitting mammal tissue to compress into the perforations increasing mammal tissue contact area.

The present invention provides a method of manufacturing a coral scaffold for use as a bone graft substitute. The method comprises growing coral in a growth medium having a carbonate hardness, dKH, of 10 or more; removing at least a portion of the coral from the growth medium; devitalising coral removed from the growth medium and sizing the devitalised coral to form the coral scaffold.

Disclosed herein are compositions and methods to decellularize an isolated organ or portion thereof. Also disclosed herein are compositions and methods for treatment of disease utilizing a decellularized or recellularized organ. Also disclosed herein are methods of improving decellularization and/or recellularization of an isolated organ or portion thereof.

A method is provided for preparing an ECM material, including an ECM gel, from regenerative or regenerating tissue. ECM material prepared from regenerative or regenerating materials also is provided.

Systems, methods, and devices include techniques for generating and using a demineralized bone matrix (DBM)-gelatin matrix allograft material. The DBM-gelatin material can be used to form an implant (e.g., for sternal closure operations) and/or a gel (e.g., for wound/fracture treatment). A method for forming the implant or bone graft can include forming the DBM from an initial bone material; and mixing, in a solution, the DBM with a gelatin carrier to form a DBM-gelatin solution. The gelatin carrier can include an animal-based collagen, such as a porcine-based collagen or a bovine-based collagen. Additionally, the method of forming the bone graft can include performing a crosslinking reaction with the DBM-gelatin solution. The implant can be packaged in a sterile hydration container prior to use.