Artificial meniscal scaffolds characterized by a composite of circumferential polymer fiber network and orthogonal polymer fiber network embedded in an arcuate bioresorbable matrix comprised of collagen and hyaluronic acid. The orthogonal polymer fiber network prevents separation of the circumferential polymer fiber networks. The polymer fiber networks convert axial compressive forces on the scaffolds to tensile loads on the circumferential polymer fibers. The composite scaffold can be anchored to bone by novel anchoring components that protect the polymer fibers and ensure immediate securement of the artificial meniscal scaffold to bone.

A tendon/ligament repair implant for treatment of tears or lesions of tendons and ligaments, including capsular reconstruction, and compositions for delivering calcium and/or phosphate ions in combination with a collagen solution that can be placed between soft tissue and bone to facilitate healing of the soft tissue-bone interface are provided. The implant may incorporate features of rapid deployment and fixation by arthroscopic means that complement current procedures; tensile properties that result in desired sharing of anatomical load between the implant and native tendon during rehabilitation, or, in situations where the native tissue cannot be repaired tensile properties that provide for substitution of the native tissue selected porosity and longitudinal pathways for tissue in-growth; and may include an at least partially bioabsorbable construction to provide transfer of additional load to new tendon-like tissue and native tendon over time. The compositions can be pre-dried into a thin sheet of material and delivered as a pre-formed matrix, or as a gel or paste which sets in place to form the matrix between the soft tissue and bone.

Medical devices, substrates and biologic therapies for bone repair and guided tissue regeneration are disclosed. More particularly, bone graft substitutes and bone void fillers which comprise a porous collagen matrix and calcium deficient hydroxyapatite ceramic granules for delivery of osteoinductive or other therapeutic agents are disclosed.

Medical devices, substrates and biologic therapies for bone repair and guided tissue regeneration are disclosed. More particularly, bone graft substitutes and bone void fillers which comprise a porous collagen matrix and calcium deficient hydroxyapatite ceramic granules for delivery of osteoinductive or other therapeutic agents are disclosed.

Provided herein are scaffold biomaterials including a decellularized plant or fungal tissue from which cellular materials and nucleic acids of the tissue are removed, the decellularized plant or fungal tissue having a 3-dimensional porous structure; wherein the decellularized plant or fungal tissue may optionally be at least partially coated or mineralized, wherein the scaffold biomaterial may optionally further include a protein-based hydrogel and/or a polysaccharide-based hydrogel, or both. Also provided herein are methods and uses of such scaffold biomaterials, including methods of manufacture as well as methods and uses for bone tissue engineering, for example.

Provided herein are scaffold biomaterials including a decellularized plant or fungal tissue from which cellular materials and nucleic acids of the tissue are removed, the decellularized plant or fungal tissue having a 3-dimensional porous structure; wherein the decellularized plant or fungal tissue may optionally be at least partially coated or mineralized, wherein the scaffold biomaterial may optionally further include a protein-based hydrogel and/or a polysaccharide-based hydrogel, or both. Also provided herein are methods and uses of such scaffold biomaterials, including methods of manufacture as well as methods and uses for bone tissue engineering, for example.

The particle (1) is suitable for the manufacture of an implantable soft tissue engineering material and comprises: a three-dimensionally warped and branched sheet (2) where (i) the three-dimensionally warped and branched sheet (2) is made from a biocompatible material having a Young's modulus of 1 kPa to 1 GPa; (ii) the three-dimensionally warped and branched sheet (2) has an irregular shape which is encompassed in a virtual three-dimensional envelope (3) having a volume V.sub.E; (iii) the three-dimensionally warped and branched sheet (2) has a mean sheet thickness T; iv) the three-dimensionally warped and branched sheet (2) has a volume V.sub.S; (v) the particle (1) has a Young's modulus of 100 Pa to 15 kPa; and (vi) the particle (1) further comprises a number of protrusions where the three-dimensionally warped and branched sheet (2) reaches the envelope (3); (vii) the particle (1) has a number of interconnected channel-type conduits (5) defined by the branching of the sheet (2) and/or by voids in the sheet (2); and (viii) where the conduits (5) have (a) a mean diameter D.sub.C; and (b) an anisotropicity index of 1.01 to 5.00.

The particle (1) is suitable for the manufacture of an implantable soft tissue engineering material and comprises: a three-dimensionally warped and branched sheet (2) where (i) the three-dimensionally warped and branched sheet (2) is made from a biocompatible material having a Young's modulus of 1 kPa to 1 GPa; (ii) the three-dimensionally warped and branched sheet (2) has an irregular shape which is encompassed in a virtual three-dimensional envelope (3) having a volume V.sub.E; (iii) the three-dimensionally warped and branched sheet (2) has a mean sheet thickness T; iv) the three-dimensionally warped and branched sheet (2) has a volume V.sub.S; (v) the particle (1) has a Young's modulus of 100 Pa to 15 kPa; and (vi) the particle (1) further comprises a number of protrusions where the three-dimensionally warped and branched sheet (2) reaches the envelope (3); (vii) the particle (1) has a number of interconnected channel-type conduits (5) defined by the branching of the sheet (2) and/or by voids in the sheet (2); and (viii) where the conduits (5) have (a) a mean diameter D.sub.C; and (b) an anisotropicity index of 1.01 to 5.00.

Embodiments of this disclosure relate to bioinks and bioink compositions. These bioinks may be 3D printed into a hydrogel. The printed hydrogel may support primary cell and induced pluripotent stem cell attachment, proliferation, and spreading. Compounds in the bioink may be modified to incorporate chemical functionality, such as by chemical synthesis means. Incorporating chemical functionality may allow the incorporation of modified material as a component in the bioink. The modifications may allow chemical conjugation of a desired component. The desired component may maintain its cell interactive feature to aid in cell attachment and proliferation. Such incorporation may allow modulation of the bioprinted object's mechanical properties without interfering with cell adhesion.

Embodiments of this disclosure relate to bioinks and bioink compositions. These bioinks may be 3D printed into a hydrogel. The printed hydrogel may support primary cell and induced pluripotent stem cell attachment, proliferation, and spreading. Compounds in the bioink may be modified to incorporate chemical functionality, such as by chemical synthesis means. Incorporating chemical functionality may allow the incorporation of modified material as a component in the bioink. The modifications may allow chemical conjugation of a desired component. The desired component may maintain its cell interactive feature to aid in cell attachment and proliferation. Such incorporation may allow modulation of the bioprinted object's mechanical properties without interfering with cell adhesion.