The invention relates to vesicles comprising Epidermal Growth Factor (EGF), a cationic surfactant and cholesterol or derivatives thereof. The invention also discloses a procedure for their preparation, based on compressed fluid technology (CFs). The vesicles of the invention are useful in the manufacture of drugs and cosmetics and in tissue engineering.

Provided are compositions and methods relating to methods and compositions to treat tendon injury.

The invention relates to a porous osteoinductive calcium phosphate material having an average grain size in a range of 0.1-1.50 μm, having a porosity consisting essentially only of micropores in a size range of 0.1-1.50 μm, and having a surface area percentage of micropores in a range of 10-40%.

The present invention relates to a nerve suture patch having a self-healing property, and a production method thereof, and more specifically, to a self-healing nerve suture patch containing a self-healing polymer and a hydrogel, and a production method thereof. The nerve suture patch may be rapidly attached to epineurium by the adhesiveness of the hydrogel and easily suture a damaged nerve.

A non-cellular root canal filler comprises a tetrahydroisoquinoline compound or a pharmaceutically acceptable salt thereof, or a solvate of the compound or the salt, and a dental tissue regeneration promotion kit comprises a pretreatment agent comprising a serine protease, and the non-cellular root canal filler.

Disclosed are various bioactive grafts and methods of making the same. In one embodiment, bone material is harvested from a donor. The harvested bone material is exposed to a lysing agent, the lysing agent configured to release growth factors and bioactive materials from cellular material of the harvested bone material. The harvested bone material is then rinsed with a rinsing agent. The pH of the harvested bone material is substantially neutralized.

Described herein are biomaterials, systems, and methods for guiding regeneration of an epiphyseal growth plate or similar interfacial tissue structures. In one aspect, the disclosed technology can include a biologic material that can comprise one or more of a hydrogel carrier for growth factors and MSCs, chondrogenic and immunomodulatory cytokines, microparticles for prolonged and spatially controlled growth factor delivery; and/or porous scaffold providing mechanical support. The implanted material can be applied via various different modalities depending on the nature of the physeal injury. One modality is an injectable hydrogel and another modality is an implantable hydrogel infused scaffold.

A tissue derived implant is provided having a configuration which is sized and shaped to be disposed within a reservoir of a handling or storage device, the implant having one or more liquid dispersion features for enabling effective hydration of the implant when the implant is disposed in the reservoir and contacted with a biocompatible liquid. The liquid dispersion features form at least one liquid pathway which facilitates collecting and distributing the biocompatible liquid to contact the substantially the entire implant. An implant assembly is also provided which comprises a handling or storage device comprising an elongated reservoir with the tissue derived implant disposed therein. Additionally, an implant kit is provided which comprises a handling or storage device with an elongated reservoir and the tissue derived implant having an elongated configuration sized and shaped to allow the implant to be disposed in the elongated reservoir at the time of use.

Disclosed herein are methods of producing a cartilaginous implant by producing a polymer scaffold composition by electrospinning a polymer solution onto a collector in order to obtain polymer fibers; crosslinking the polymer fibers; and adding a plurality of cells to the polymer scaffold composition, wherein the plurality of cells comprises cartilaginous cells to form a cartilaginous implant.

A system for administering biologically active substances produced by foaming techniques using compressed gases or supercritical fluids relates to a porous system containing biologically active substances. The system includes a polymer matrix of poly(D,L-lactic-co-glycolic acid) or a polymer mixture containing poly(D,L-lactic-co-glycolic acid) of an intrinsic viscosity of less than 0.5 dL/g with other biodegradable synthetic or semisynthetic polyesters, a release-regulating component (starch and derivatives), and at least one biologically active substance. The matrix is biodegradable with a solid or semisolid consistency and a homogeneous appearance. A method for producing these systems using foaming with compressed fluids, and the use for the production of implants and scaffolds having this system are also disclosed. Optionally, a porogenic agent can be used for the formation of macropores by thermal decomposition.