A method of manufacturing a tissue expander for implanting into a body of a living subject can include mixing granules of a solute with an elastomer. The method can further include forming a matrix with the elastomer. The granules can be embedded within the elastomer. The elastomer can define boundaries of a plurality of chambers within the matrix. The method can further include curing the elastomer, such that the boundaries of the matrix are permeable to water at a temperature between a desired temperature range.

A composite scaffold having a highly porous interior with increased surface area and void volume is surrounded by a flexible support structure that substantially maintains its three-dimensional shape under tension and provides mechanical reinforcement during repair or reconstruction of soft tissue while simultaneously facilitating regeneration of functional tissue.

A composite scaffold having a highly porous interior with increased surface area and void volume is surrounded by a flexible support structure that substantially maintains its three-dimensional shape under tension and provides mechanical reinforcement during repair or reconstruction of soft tissue while simultaneously facilitating regeneration of functional tissue.

Disclosed is a method for preparing a cell growth scaffold having a structural memory feature, comprising a step of preparing a micro-fibrous or flocculent acellular tissue matrix material; a step of preparing an acidification-treated hydrogel-like acellular tissue matrix particles; proportionally mixing the micro-fibrous or flocculent acellular tissue matrix material with the acidification-treated hydrogel-like acellular tissue matrix particles, followed by injection-molding, freezing treatment, radiation treatment, and ultimately preparing a porous cell growth scaffold that can be stored at room temperature. The prepared cell growth scaffold is a porous cell growth scaffold that has no chemical crosslinking, and has a biological activity, a stable three-dimensional structure and a structural memory feature. The cell growth scaffold has an excellent biocompatibility and complete biodegradability, and supports the growth of cells and the growth of tissues and organs in vitro and in vivo, thereby being suitable for repair of human soft tissue traumas and defects.

Disclosed is a method for preparing a cell growth scaffold having a structural memory feature, comprising a step of preparing a micro-fibrous or flocculent acellular tissue matrix material; a step of preparing an acidification-treated hydrogel-like acellular tissue matrix particles; proportionally mixing the micro-fibrous or flocculent acellular tissue matrix material with the acidification-treated hydrogel-like acellular tissue matrix particles, followed by injection-molding, freezing treatment, radiation treatment, and ultimately preparing a porous cell growth scaffold that can be stored at room temperature. The prepared cell growth scaffold is a porous cell growth scaffold that has no chemical crosslinking, and has a biological activity, a stable three-dimensional structure and a structural memory feature. The cell growth scaffold has an excellent biocompatibility and complete biodegradability, and supports the growth of cells and the growth of tissues and organs in vitro and in vivo, thereby being suitable for repair of human soft tissue traumas and defects.

A method of manufacturing a tubular graft may include the steps of: providing a textile including a tubular wall disposed between a first open end and an opposed second open end, an inner surface and an opposed outer surface defining an interior wall portion therein between, the tubular wall including a textile construction of one or more filaments or yarns, the textile construction by itself being permeable to liquid; applying a substantially water-soluble material to at least a portion of the tubular wall; and applying a substantially water-insoluble sealant to at least a part of the outer surface of the tubular wall, the substantially water-insoluble sealant being configured to mitigate movement of fluid through the wall of the conduit; where the water-soluble material is configured to mitigate penetration of the sealant to the inner surface of the conduit.

A method of manufacturing a tubular graft may include the steps of: providing a textile including a tubular wall disposed between a first open end and an opposed second open end, an inner surface and an opposed outer surface defining an interior wall portion therein between, the tubular wall including a textile construction of one or more filaments or yarns, the textile construction by itself being permeable to liquid; applying a substantially water-soluble material to at least a portion of the tubular wall; and applying a substantially water-insoluble sealant to at least a part of the outer surface of the tubular wall, the substantially water-insoluble sealant being configured to mitigate movement of fluid through the wall of the conduit; where the water-soluble material is configured to mitigate penetration of the sealant to the inner surface of the conduit.

Provided herein are meniscus implant compositions, as well as method for making and using the same. The subject meniscus implants find use in repairing and/or replacing damaged or diseased meniscal tissue in a mammalian subject.

Provided herein are meniscus implant compositions, as well as method for making and using the same. The subject meniscus implants find use in repairing and/or replacing damaged or diseased meniscal tissue in a mammalian subject.

Provided herein are meniscus implant compositions, as well as method for making and using the same. The subject meniscus implants find use in repairing and/or replacing damaged or diseased meniscal tissue in a mammalian subject.