The invention provides method for preparing amnion tissue grafts, as well as the grafts themselves. In specific embodiments, the tissue graft comprises a single layer of dried amnion from an umbilical cord.

The present invention relates to a decellularized nerve graft using allogeneic and heterologous nervous tissues and a method of manufacturing the same.

In the present invention, by using a low-concentration basic solution and a surfactant as a decellularization solution, cell and tissue toxicity caused by a solvent or surfactant remaining in the tissue may be minimized by minimizing the use of a basic solution and an anionic surfactant in the entire manufacturing process. In addition, a peristaltic pump may be used to maintain the tissue structure and effectively remove lipid and cells.

A method of producing an osteoinductive composition for in vivo use, in which the method includes obtaining bone tissue; cleaning the bone tissue with a plurality of washes; milling, grinding, and/or cutting the cleaned bone tissue into a plurality of bone pieces or fibers of a desired size; and demineralizing the plurality of bone pieces or fibers of a desired size to expose one or more native bone proteins, with demineralizing including combining the plurality of bone pieces or fibers in a reaction vessel with an ionic acid solution, soaking the plurality of bone pieces or fibers in the ionic acid solution, and exposing the one or more native proteins in the bone pieces or fibers.

Compositions of matter comprising decellularized omentum are disclosed. The compositions may be scaffolds, hydrogels or hydrogel precursor compositions. Methods of generating the compositions are disclosed as well as uses thereof.

The present invention relates to an allogeneic and heterologous adipose tissue-derived extracellular matrix scaffold, and a method for producing the same.

An adipose tissue-derived extracellular matrix scaffold according to the present invention has a composition similar to the human body, a large surface area, and an interconnected porous structure, and thus has high cell affinity and allows cells to survive for long periods.

A method of corneal implantation with cross-linking is disclosed herein. In one or more embodiments, the method includes the steps of: (i) prior to implantation, treating an implant formed from donor corneal tissue or a tissue culture grown corneal stroma with a solution of sodium dodecyl sulfate (SDS), Triton X-100, benzalkonium chloride (BAK), Igepal, genipin, 100% glycerol, or alcohol for making the implant acellular, and for killing any bacteria, viruses, or parasites prior to implantation; (ii) implanting the implant into a recipient cornea; (iii) applying laser energy to the implant so as to modify the refractive power of the implant while being monitored using a Shack-Hartmann wavefront system so as to achieve a desired refractive power for the implant; and (iv) applying a cross-linking solution and irradiating the implant to cross-link the implant to prevent an immune response to the implant and/or rejection of the implant by a patient.

Systems, instruments, methods, and compositions are described involving removing a portion of the epidermis within a donor site on a subject, and harvesting dermal plugs within the donor site. An injectable filler is formed by mincing the dermal plugs. The injectable filler is configured for injecting into a recipient site on the subject.

An antibacterial medical biomaterial includes an acellular small intestinal submucosal matrix material, an antibacterial gel layer located on a surface of the acellular small intestinal submucosal matrix material, and an absorbable fiber layer located on a surface of the antibacterial gel layer. Sulfadiazine silver is on the surface of the acellular small intestinal submucosal matrix material and/or within the acellular small intestinal submucosal matrix material. An absorbable fiber layer to which the sulfadiazine silver is attached, wherein the content of sulfadiazine silver in the absorbable fiber is 1 wt. %˜2 wt. %. The medical biomaterial is usable as an external medicine for treating wound infections relayed by burns or wounds, and for reducing the incidence of infection by using a conventional central venous catheter with a sulfadiazine silver antibacterial coating, so that the medical biomaterial loaded with sulfadiazine silver also has antibacterial activity consistent with sulfadiazine silver.

A fetal-origin decellularized nucleus pulposus (NP) allogenic material to regenerate a host's Intervertebral Disc (IVD). The decellularized NP material, obtained from a vertebrate fetus and characterized by comprising high levels of collagen 12 and 14, is used in a pharmacological composition for the treatment of IVD degeneration. The advance is based on the increased ability of the fetal decellularized NP material to stimulate the host constituent cell's to increase the expression of collagen 2 and aggrecan, promoting intrinsic IVD regeneration. A related method includes preparing the pharmaceutical compositions of fetal decellularized material in the form of fragments/microparticles and hydrogel for an injectable mode of administration. The involved material, pharmaceutical compositions and methods may be advantageously used for the prevention and treatment of IVD degeneration and back pain in human and veterinary settings.

Object of the present invention is a drug delivery system comprising a decellularized corneal stroma scaffold having dispersed within and/or bound to its surface microparticles containing at least one pharmaceutically active molecule dispersed in a matrix having a composition consisting for at least 70% of polylactic co-glycolic acid (PLGA).