The invention relates to the field of tissue engineering and regenerative medicine, and particularly to a three-dimensional biomimetic tissue scaffold that exploits the use of three-dimensional print technology. Surface energy is controlled by precisely placing polymers with differing surface chemistry, and using surface texture and bulk composition to pattern absorbable and non-absorbable polymers for the purpose of promoting functional healing in a mammalian body.

The present invention provides a technological platform for bone regeneration. More specifically, the invention provides an implant comprising a plurality of polymeric casings at least one of which encases a bone void filler and at least one reinforcement component. Also provided is a method of regenerating bone by implanting one or more implants according to the present invention to a bone repair site.

The present invention provides a technological platform for bone regeneration. More specifically, the invention provides an implant comprising a plurality of polymeric casings at least one of which encases a bone void filler and at least one reinforcement component. Also provided is a method of regenerating bone by implanting one or more implants according to the present invention to a bone repair site.

The present invention concerns a hydrogel comprising hyaluronic acid (HA) or a derivative thereof, loaded with at least one positively charged antimicrobial peptide, wherein said HA or derivative thereof is cross-linked with a cross-linking agent at the level of its hydroxyl moieties while the carboxyl moieties of HA or derivative thereof remain free and said HA or derivative thereof remains negatively charged; and a method for preparing said loaded hydrogel.

The present invention concerns a hydrogel comprising hyaluronic acid (HA) or a derivative thereof, loaded with at least one positively charged antimicrobial peptide, wherein said HA or derivative thereof is cross-linked with a cross-linking agent at the level of its hydroxyl moieties while the carboxyl moieties of HA or derivative thereof remain free and said HA or derivative thereof remains negatively charged; and a method for preparing said loaded hydrogel.

A method of producing an injectable gel product is provided, comprising (a) cross-linking a first glycosaminoglycan (GAG) with a first crosslinking agent to produce a gel, wherein the charging ratio of crosslinking agent to disaccharide unit is below 0.15; (b) preparing particles of the gel; (c) mixing the glycosaminoglycan (GAG) gel particles with a second GAG to provide a mixture; (d) cross-linking the mixture with a second crosslinking agent to obtain cross-linking between the GAGs of the second, outer phase, thereby providing a gel having a first, inner phase of the cross-linked GAG gel particles, embedded in a gel of the second GAG outer phase; and (e) preparing injectable particles, each such particle containing a plurality of the cross-linked GAG gel particles of the first, inner phase. An injectable gel product, an aqueous composition, and a pre-filled syringe as also provided.

A method of producing an injectable gel product is provided, comprising (a) cross-linking a first glycosaminoglycan (GAG) with a first crosslinking agent to produce a gel, wherein the charging ratio of crosslinking agent to disaccharide unit is below 0.15; (b) preparing particles of the gel; (c) mixing the glycosaminoglycan (GAG) gel particles with a second GAG to provide a mixture; (d) cross-linking the mixture with a second crosslinking agent to obtain cross-linking between the GAGs of the second, outer phase, thereby providing a gel having a first, inner phase of the cross-linked GAG gel particles, embedded in a gel of the second GAG outer phase; and (e) preparing injectable particles, each such particle containing a plurality of the cross-linked GAG gel particles of the first, inner phase. An injectable gel product, an aqueous composition, and a pre-filled syringe as also provided.

A method of producing an injectable gel product is provided, comprising (a) cross-linking a first glycosaminoglycan (GAG) with a first crosslinking agent to produce a gel, wherein the charging ratio of crosslinking agent to disaccharide unit is below 0.15; (b) preparing particles of the gel; (c) mixing the glycosaminoglycan (GAG) gel particles with a second GAG to provide a mixture; (d) cross-linking the mixture with a second crosslinking agent to obtain cross-linking between the GAGs of the second, outer phase, thereby providing a gel having a first, inner phase of the cross-linked GAG gel particles, embedded in a gel of the second GAG outer phase; and (e) preparing injectable particles, each such particle containing a plurality of the cross-linked GAG gel particles of the first, inner phase. An injectable gel product, an aqueous composition, and a pre-filled syringe as also provided.

A non-biodegradable plug-shaped implant (1) for the replacement and regeneration of biological tissue is described. The implant comprises a base section (2) configured for anchoring in bone tissue, and a top section (4) configured for growing cartilage tissue onto and into. The top section comprises a thermoplastic elastomeric material, which is porous. The thermoplastic elastomeric material comprises a linear block copolymer comprising urethane and urea groups, and may be substantially free of an added peptide compound having cartilage regenerative properties. The base section material further comprises one of a biocompatible metal, ceramic, mineral, such as phosphate mineral, and polymer, optionally a hydrogel polymer, and combinations thereof, wherein the thermoplastic elastomeric material further comprises carbonate groups.

A non-biodegradable plug-shaped implant (1) for the replacement and regeneration of biological tissue is described. The implant comprises a base section (2) configured for anchoring in bone tissue, and a top section (4) configured for growing cartilage tissue onto and into. The top section comprises a thermoplastic elastomeric material, which is porous. The thermoplastic elastomeric material comprises a linear block copolymer comprising urethane and urea groups, and may be substantially free of an added peptide compound having cartilage regenerative properties. The base section material further comprises one of a biocompatible metal, ceramic, mineral, such as phosphate mineral, and polymer, optionally a hydrogel polymer, and combinations thereof, wherein the thermoplastic elastomeric material further comprises carbonate groups.