A malleable demineralized bone composition consists of cortical bone made from a first portion and a second portion. The first portion and second portion of cortical bone is made from cut pieces freeze dried then ground into particles and demineralized then freeze-dried. A volume of the second portion is placed in a solution of sterile water to create a mixture, the water volume being seven times the volume of the second portion, the mixture is autoclaved under heat and pressure to form a gelatin, and the first portion is mixed with the gelatin to form a malleable putty or paste.

A malleable demineralized bone composition consists of cortical bone made from a first portion and a second portion. The first portion and second portion of cortical bone is made from cut pieces freeze dried then ground into particles and demineralized then freeze-dried. A volume of the second portion is placed in a solution of sterile water to create a mixture, the water volume being seven times the volume of the second portion, the mixture is autoclaved under heat and pressure to form a gelatin, and the first portion is mixed with the gelatin to form a malleable putty or paste.

A method for structuring a surface of an implant (100) made from a plastic material by means of a counter-body (200) comprises the following steps: providing (S110) of a counter-body (200) including a surface (210); forming (S120) of a first surface structure (212) on the surface (210) of the counter-body, wherein a first surface structure (212) comprises a non-regular, randomly distributed pattern; and forming (S130) of a second surface structure (112) on the implant (100) by using the counter-body (200), wherein the second surface structure and the first surface structure (212) are complementary to each other.

A method for structuring a surface of an implant (100) made from a plastic material by means of a counter-body (200) comprises the following steps: providing (S110) of a counter-body (200) including a surface (210); forming (S120) of a first surface structure (212) on the surface (210) of the counter-body, wherein a first surface structure (212) comprises a non-regular, randomly distributed pattern; and forming (S130) of a second surface structure (112) on the implant (100) by using the counter-body (200), wherein the second surface structure and the first surface structure (212) are complementary to each other.

The invention relates to a biohybrid for the use thereof in the regeneration of neural tracts, comprising an implantable tubular hybrid structure which is degradable and biocompatible and characterized in that it comprises three layers of different porosity: an inner layer a), an intermediate layer b) and an outer layer c), with uninterrupted connection among them, the three layers consisting of the same porous hydrogel based on cross-linked hyaluronic acid, a biohybrid comprising the hybrid tubular structure described, which can contain a fibrous material, preferably poly-L-lactic acid, to a method for producing said tubular hybrid structure and said biohybrid, and to the use of same for regenerating neural tracts in diseases that affect the central nervous system, preferably Parkinson's disease.

A method of fabricating a material having a high concentration of a carbide constituent. The method may comprise adding a carbide source to a biocompatible material in which a weight of the carbide source is at least approximately 10% of the total weight, heating the carbide source and the biocompatible material to a predetermined temperature to melt the biocompatible material and allow the carbide source to go into solution to form a molten homogeneous solution, and impinging the molten homogeneous solution with a high pressure fluid to form spray atomized powder having carbide particles. The size of a particle of carbide in the atomized powder may be approximately 900 nanometers or less. The biocompatible material may be cobalt chrome, the carbide source may be graphite, and the fluid may be a gas or a liquid.

A prosthetic implant material for use in a prosthetic implant, comprising a gel and optionally a gas.

An implantable bioreactor containing a barrier which is designed to allow the release of cell-derived biomolecules, but restricts the entry of immunologic and other cells, or the egress of the cells contained within the bioreactor. Two broad classes of implantable bioreactors are envisioned, encompassing devices for both systemic delivery of the bio-products and local delivery at the target tissue. Bioreactors of both classes can be implanted via surgery, through percutaneous techniques, or other techniques which effect implantation.

The present invention relates to a prosthetic fabric comprising an arrangement of yarns defining at least two faces for said fabric, said fabric comprising, on at least one of its faces, one or more barbs that protrude outwards relative to said face, characterized in that said barbs are covered with a coating made of a water-soluble biocompatible material. The invention also relates to a process for obtaining such a fabric and to prostheses obtained from such a fabric.

A device containing transplanted tissue includes a housing, having a chamber configured for insertion into a body of a subject and protecting the transplanted tissue from the subject's immune system. The housing includes an oxygen supply container, a hydrogel layer, a port, and an access port. The oxygen supply container has a chamber defined by top and bottom surfaces and sides, disposed within the chamber of the housing. The top surface and the bottom surface of the oxygen supply container include a gas-permeable membrane. The hydrogel layer has inner and outer surfaces. The inner surface of the hydrogel layer contacts the top surface of the oxygen supply container or the bottom surface of the oxygen supply container. The port is configured to deliver oxygen to the oxygen supply container. The access port is configured to receive an exogenous supply of gas and is fluidly connected to the port.