In certain described embodiments, implantable medical materials comprise a scaffolding material, a liquid organic binder, and entrapped calcium-containing particles. The medical materials can incorporate an osteoinductive factor such as a protein. The scaffolding material can bind the factor. In additional described embodiments, implantable medical materials include an osteoconductive scaffolding material, an incorporated osteoinductive factor, and a biodegradable barrier material effective to delay release of the factor from the scaffolding material. The scaffolding material can bind the factor. Also described a methods for preparing and implanting the described medical materials.

In certain described embodiments, implantable medical materials comprise a scaffolding material, a liquid organic binder, and entrapped calcium-containing particles. The medical materials can incorporate an osteoinductive factor such as a protein. The scaffolding material can bind the factor. In additional described embodiments, implantable medical materials include an osteoconductive scaffolding material, an incorporated osteoinductive factor, and a biodegradable barrier material effective to delay release of the factor from the scaffolding material. The scaffolding material can bind the factor. Also described a methods for preparing and implanting the described medical materials.

A bone-repair composite includes a core and a sheath. The core is a first primary unit including a combination of a first set of yarns coated with a calcium phosphate mineral layer. The first set of yarns being made from a first group of one or more polymers. The sheath is a second primary unit a combination of a second set of yarns or one or more polymer coatings. The second set of yarns being made from a second group of one or more polymers, wherein the composite is made by covering the core with the sheath, and the composite is compression molded to allow the sheath to bond to the core. The bone-repair composite has a bending modulus comparable to that of a mammalian bone, such that the ratio of the core to the sheath is provided to maximize the mechanical strength of the bone-repair composite to mimic the mammalian bone.

A bone-repair composite includes a core and a sheath. The core is a first primary unit including a combination of a first set of yarns coated with a calcium phosphate mineral layer. The first set of yarns being made from a first group of one or more polymers. The sheath is a second primary unit a combination of a second set of yarns or one or more polymer coatings. The second set of yarns being made from a second group of one or more polymers, wherein the composite is made by covering the core with the sheath, and the composite is compression molded to allow the sheath to bond to the core. The bone-repair composite has a bending modulus comparable to that of a mammalian bone, such that the ratio of the core to the sheath is provided to maximize the mechanical strength of the bone-repair composite to mimic the mammalian bone.

The present invention provides protein-polymer conjugates, and methods for generating biocompatible scaffolds formed of hydrogels comprising the conjugates and use of the scaffolds for tissue regeneration. The present invention provides improved processes for the preparation of the conjugates, wherein the conjugates of the invention are preferably produced in an environmentally friendly process avoiding polar organic solvents.

The present invention provides protein-polymer conjugates, and methods for generating biocompatible scaffolds formed of hydrogels comprising the conjugates and use of the scaffolds for tissue regeneration. The present invention provides improved processes for the preparation of the conjugates, wherein the conjugates of the invention are preferably produced in an environmentally friendly process avoiding polar organic solvents.

The present disclosure provides a bone-implantable device and methods of use. The bone-implantable device comprises a body having an exterior surface, wherein a portion of the exterior surface includes a cured osteostimulative material comprising MgO.

The present disclosure provides a bone-implantable device and methods of use. The bone-implantable device comprises a body having an exterior surface, wherein a portion of the exterior surface includes a cured osteostimulative material comprising MgO.

A gallium silica glass composition is described. The glass can be used in variety of biomedical applications.

A gallium silica glass composition is described. The glass can be used in variety of biomedical applications.