A biodegradable and biocompatible three dimensional construct comprising a combination of a nano silicate (e.g., laponite) and two different polymers, the two polymers each individually providing at least one covalently linked polymer chain and at least one ionically linked polymer chain, the polymeric chains forming a dual strengthening intertwined polymeric system. The constructs demonstrate improved mechanical and strength properties, while the bioinks provide a material having superior printability characteristics suitable for printing a three dimensional biodegradable construct having an aspect ratio of greater than 2.0. The bioink may also comprise cells or combinations of cells. Methods of using the constructs and bioinks for wound healing preparations and tissue regeneration are also provided.

A biodegradable and biocompatible three dimensional construct comprising a combination of a nano silicate (e.g., laponite) and two different polymers, the two polymers each individually providing at least one covalently linked polymer chain and at least one ionically linked polymer chain, the polymeric chains forming a dual strengthening intertwined polymeric system. The constructs demonstrate improved mechanical and strength properties, while the bioinks provide a material having superior printability characteristics suitable for printing a three dimensional biodegradable construct having an aspect ratio of greater than 2.0. The bioink may also comprise cells or combinations of cells. Methods of using the constructs and bioinks for wound healing preparations and tissue regeneration are also provided.

A type of composite material where the matrix material and additive are held together by covalently or non-covalently bound ligands is described. A particularly useful composite material covered by the present invention is a carbon nanotube-reinforced composite material where the matrix consists of a polymer, covalently attached to a linker, where said linker is non-covalently attached to the carbon nanotube. Methods for the preparation of such composite materials are provided.

A type of composite material where the matrix material and additive are held together by covalently or non-covalently bound ligands is described. A particularly useful composite material covered by the present invention is a carbon nanotube-reinforced composite material where the matrix consists of a polymer, covalently attached to a linker, where said linker is non-covalently attached to the carbon nanotube. Methods for the preparation of such composite materials are provided.

A collagen ink for printing 3D structures includes a dispersion of native collagen fibers in an acid medium. The collagen ink can be obtained from a collagen-containing tissue. A method for 3-D printing includes neutralizing the collagen ink to a physiological pH, mixing the collagen ink with cells, and printing a 3D structure.

A collagen ink for printing 3D structures includes a dispersion of native collagen fibers in an acid medium. The collagen ink can be obtained from a collagen-containing tissue. A method for 3-D printing includes neutralizing the collagen ink to a physiological pH, mixing the collagen ink with cells, and printing a 3D structure.

Three-dimensional printing methods and systems for forming a three-dimensional protein article are disclosed. The methods and systems involve selecting article formation parameters, such as protein ink parameters, solvent bath parameters, shear force parameters, and mapping parameters. After these parameters are selected, the methods and systems iteratively introduce protein ink into a solvent bath via a three-dimensional printing outlet. The result is a three-dimensional protein article. One exemplary protein is silk fibroin. Further processing can be done, such as drying the article.

Three-dimensional printing methods and systems for forming a three-dimensional protein article are disclosed. The methods and systems involve selecting article formation parameters, such as protein ink parameters, solvent bath parameters, shear force parameters, and mapping parameters. After these parameters are selected, the methods and systems iteratively introduce protein ink into a solvent bath via a three-dimensional printing outlet. The result is a three-dimensional protein article. One exemplary protein is silk fibroin. Further processing can be done, such as drying the article.

Cellulose-based composite material comprising an electrically conductive material dispersed in a matrix comprising at least one plant-derived protein and a polymer of aleuritic acid, said composite material being obtainable by a process comprising the steps of dissolving at least one plant-derived protein and aleuritic acid in a dissolving solution to achieve a first mixture, dispersing an electrically conductive material in said first mixture to achieve a conductive ink, distributing said conductive ink on at least one side of a cellulose substrate to achieve a coated cellulose substrate, hot-pressing said coated cellulose substrate to obtain i) impregnation of the cellulose substrate with said conductive ink and ii) polymerization of aleuritic acid.

Cellulose-based composite material comprising an electrically conductive material dispersed in a matrix comprising at least one plant-derived protein and a polymer of aleuritic acid, said composite material being obtainable by a process comprising the steps of dissolving at least one plant-derived protein and aleuritic acid in a dissolving solution to achieve a first mixture, dispersing an electrically conductive material in said first mixture to achieve a conductive ink, distributing said conductive ink on at least one side of a cellulose substrate to achieve a coated cellulose substrate, hot-pressing said coated cellulose substrate to obtain i) impregnation of the cellulose substrate with said conductive ink and ii) polymerization of aleuritic acid.