Compositions and methods for treating tissue are provided. The compositions may include tissue matrix derived from adipose tissue suitable for injection, small-volume implantation, or use as a soft-tissue regenerative material. Also provided are methods for producing such compositions.

Compositions and methods for treating tissue are provided. The compositions may include tissue matrix derived from adipose tissue suitable for injection, small-volume implantation, or use as a soft-tissue regenerative material. Also provided are methods for producing such compositions.

A process providing a method to create 3D scaffolds using nano-scale fibers, comprising: deposition and alignment of a plurality of electrospun fiber layers on a substrate; application of a photosensitive biomedical polymer liquid to each fiber layer deposited on said substrate; deposition and cross-alignment of a plurality of electrospun fiber layers on said substrate; retaining said polymer liquid in place using said cross-aligned fiber layers; curing said polymer liquid on top of each fiber layer using UV light.

A process providing a method to create 3D scaffolds using nano-scale fibers, comprising: deposition and alignment of a plurality of electrospun fiber layers on a substrate; application of a photosensitive biomedical polymer liquid to each fiber layer deposited on said substrate; deposition and cross-alignment of a plurality of electrospun fiber layers on said substrate; retaining said polymer liquid in place using said cross-aligned fiber layers; curing said polymer liquid on top of each fiber layer using UV light.

A process providing a method to create 3D scaffolds using nano-scale fibers, comprising: deposition and alignment of a plurality of electrospun fiber layers on a substrate; application of a photosensitive biomedical polymer liquid to each fiber layer deposited on said substrate; deposition and cross-alignment of a plurality of electrospun fiber layers on said substrate; retaining said polymer liquid in place using said cross-aligned fiber layers; curing said polymer liquid on top of each fiber layer using UV light.

A textile graft includes a tubular wall disposed between a first open end and an opposed second open end and having an inner surface and an opposed outer surface. The tubular wall includes a textile construction of one or more filaments or yarns, the textile construction by itself being permeable to liquid. A portion of the inner surface of the tubular wall includes a coating of a substantially water-soluble material thereon. The outer surface includes a coating of a substantially water-insoluble elastomeric sealant disposed thereon. The tubular wall having the coating of the substantially water-insoluble elastomeric sealant is, after curing thereof, substantially impermeable to liquid.

A textile graft includes a tubular wall disposed between a first open end and an opposed second open end and having an inner surface and an opposed outer surface. The tubular wall includes a textile construction of one or more filaments or yarns, the textile construction by itself being permeable to liquid. A portion of the inner surface of the tubular wall includes a coating of a substantially water-soluble material thereon. The outer surface includes a coating of a substantially water-insoluble elastomeric sealant disposed thereon. The tubular wall having the coating of the substantially water-insoluble elastomeric sealant is, after curing thereof, substantially impermeable to liquid.

A porous bionic skull repairing material includes a polymer material, whose structure is consistent with that of a human skull. The surface layers of the porous bionic skull repairing material are dense layers which are composed of non-degradable or degradable polymer materials and has blind holes having an asymmetric structure, and the inner layer of the porous bionic skull repairing material is a loose layer which has a porous structure. The repairing material can be molded by adopting a mixed mould pressing method or a 3D printing method, simulates a bone structure, with two dense sides and a loose middle, of a human skull to the greatest extent.

A porous bionic skull repairing material includes a polymer material, whose structure is consistent with that of a human skull. The surface layers of the porous bionic skull repairing material are dense layers which are composed of non-degradable or degradable polymer materials and has blind holes having an asymmetric structure, and the inner layer of the porous bionic skull repairing material is a loose layer which has a porous structure. The repairing material can be molded by adopting a mixed mould pressing method or a 3D printing method, simulates a bone structure, with two dense sides and a loose middle, of a human skull to the greatest extent.

Some variations of the invention provide a bioink composition for 3D bioprinting, comprising: nanocellulose in the form of nanocellulose crystals, nanocellulose fibrils, or preferably a combination thereof; alginate that is ionically crosslinkable in the presence of an ionic crosslinking agent; and water. The nanocellulose-alginate bioinks have favorable rheological, swelling, and biocompatibility properties for extrusion-based bioprinting. It is experimentally demonstrated that nanocellulose-alginate bioinks with human nasoseptal chondrocytes enable cartilage bioprinting at high resolution. The disclosed nanocellulose has been proven to be compatible with cell survival and proliferation; to possess nanoscale and microscale architectures mimicking the native extracellular environment, encouraging differentiation and tissue formation; and to have ideal rheological properties to allow extrusion 3D bioprinting. Bioink with a unique blend of crystal and fibril nanocellulose produces a very stable construct volume in culture.