A composite nerve conduit comprising an elongated body comprising one or more hollow elongated internal channels for guiding and promoting nerve regeneration. The conduit is a three-dimensional scaffold comprising a crosslinked hybrid/composite matrix of collagen and soy protein isolate having improved mechanical and biocompatibility properties. Methods of using the conduit for promoting nerve regeneration at a site of neural tissue damage by bridging wounded, severed, or damaged nerve sections in a peripheral and/or central nervous system. Methods of fabricating composite neural conduits are also disclosed.

A composite nerve conduit comprising an elongated body comprising one or more hollow elongated internal channels for guiding and promoting nerve regeneration. The conduit is a three-dimensional scaffold comprising a crosslinked hybrid/composite matrix of collagen and soy protein isolate having improved mechanical and biocompatibility properties. Methods of using the conduit for promoting nerve regeneration at a site of neural tissue damage by bridging wounded, severed, or damaged nerve sections in a peripheral and/or central nervous system. Methods of fabricating composite neural conduits are also disclosed.

An artificial meniscus using a thermoplastic for the base material, which is reinforced with an inert material. In a preferred embodiment, the reinforcement is provided by Kevlar® fibers, and the matrix is made out of polycarbonate-urethane (PCU). In an alternate embodiment, the PCU can also be surrounded by a polycaprolactone (PCL) scaffold that is infused with human growth proteins so that when the artificial meniscus is implanted, stem cells in the body are stimulated to ensure the meniscus is properly secured.

An artificial meniscus using a thermoplastic for the base material, which is reinforced with an inert material. In a preferred embodiment, the reinforcement is provided by Kevlar® fibers, and the matrix is made out of polycarbonate-urethane (PCU). In an alternate embodiment, the PCU can also be surrounded by a polycaprolactone (PCL) scaffold that is infused with human growth proteins so that when the artificial meniscus is implanted, stem cells in the body are stimulated to ensure the meniscus is properly secured.

The present invention relates to a macroscopically alignable, injectable, soft hydrogel composition which is able to form an anisotropic structure in vivo, after injection, to generate healthy functioning tissue and regenerate injured or diseased soft tissue.

The present invention relates to a macroscopically alignable, injectable, soft hydrogel composition which is able to form an anisotropic structure in vivo, after injection, to generate healthy functioning tissue and regenerate injured or diseased soft tissue.

The present disclosure relates to compositions comprising hydrogels and solid particles and their use. More specifically, the proposed technique relates to methods for manufacturing of a composition comprising solid particles encapsulated within crosslinked polysaccharide molecules forming hydrogel particles, the method comprising mixing water-soluble polysaccharide molecules comprising one or more carboxyl groups, water insoluble solid particles, a di- or multinucleophilic functional crosslinker, and a coupling agent, in a water suspension at pH between 5 and 9, to form a composition comprising a hydrogel of crosslinked polysaccharide molecules encapsulating the solid particles. The disclosure comprises the composition, methods for producing the composition and use of the composition as a dermal filler.

The present disclosure relates to compositions comprising hydrogels and solid particles and their use. More specifically, the proposed technique relates to methods for manufacturing of a composition comprising solid particles encapsulated within crosslinked polysaccharide molecules forming hydrogel particles, the method comprising mixing water-soluble polysaccharide molecules comprising one or more carboxyl groups, water insoluble solid particles, a di- or multinucleophilic functional crosslinker, and a coupling agent, in a water suspension at pH between 5 and 9, to form a composition comprising a hydrogel of crosslinked polysaccharide molecules encapsulating the solid particles. The disclosure comprises the composition, methods for producing the composition and use of the composition as a dermal filler.

The present disclosure relates to compositions comprising hydrogels and solid particles and their use. More specifically, the proposed technique relates to methods for manufacturing of a composition comprising solid particles encapsulated within crosslinked polysaccharide molecules forming hydrogel particles, the method comprising mixing water-soluble polysaccharide molecules comprising one or more carboxyl groups, water insoluble solid particles, a di- or multinucleophilic functional crosslinker, and a coupling agent, in a water suspension at pH between 5 and 9, to form a composition comprising a hydrogel of crosslinked polysaccharide molecules encapsulating the solid particles. The disclosure comprises the composition, methods for producing the composition and use of the composition as a dermal filler.

A composite comprising: a barrier, said barrier being configured to selectively pass water, and said barrier being degradable in the presence of water; a matrix material for disposition within said barrier, wherein said matrix material has a flowable state and a set state, and wherein said matrix material is degradable in the presence of water; and at least one reinforcing element for disposition within said barrier and integration with said matrix material, wherein said at least one reinforcing element is degradable in the presence of water, and further wherein, upon the degradation of said at least one reinforcing element in the presence of water, provides an agent for modulating the degradation rate of said matrix material in the presence of water.