The invention relates to compositions comprising a keratin pigment material. The keratin pigment material comprises dyed keratin particles. Compositions comprising keratin pigment material such as inks, paints and cosmetic formulations have advantageous properties compared to similar compositions in which conventional pigment materials are used as colourants.

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.

This application relates to biologically compatible porous cartilage templates for in vitro and in vivo generation of bone with enhanced structural characteristics. Provided herein are compositions having an internal structure desirable for the generation and regeneration of bone, along with methods of preparation and use.

This application relates to biologically compatible porous cartilage templates for in vitro and in vivo generation of bone with enhanced structural characteristics. Provided herein are compositions having an internal structure desirable for the generation and regeneration of bone, along with methods of preparation and use.

Methods and compositions for fabricating 3D perfusable networks are described. The methods utilize (1) printable compositions comprising gelatin microgels or Pluronic F-127, and crosslinking initiators; and (2) support materials comprising crosslinkable polymers and gelling agents. In some embodiments, the support material further comprises a co-initiator.

Methods and compositions for fabricating 3D perfusable networks are described. The methods utilize (1) printable compositions comprising gelatin microgels or Pluronic F-127, and crosslinking initiators; and (2) support materials comprising crosslinkable polymers and gelling agents. In some embodiments, the support material further comprises a co-initiator.

The present invention relates to biomaterial in the form of dispersion of cellulose nanofibrils with extraordinary shear thinning properties which can be converted into desire 3D shape using 3D Bioprinting technology. In this invention cellulose nanofibril dispersion, is processed through different mechanical, enzymatic and chemical steps to yield dispersion with desired morphological and rheological properties to be used as bioink in 3D Bioprinter. The processes are followed by purification, adjusting of osmolarity of the material and sterilization to yield biomaterial which has cytocompatibility and can be combined with living cells. Cellulose nanofibrils can be produced by microbial process but can also be isolated from plant secondary or primary cell wall, animals such as tunicates, algae and fungi. The present invention describes applications of this novel cellulose nanofibrillar bioink for 3D Bioprinting of tissue and organs with desired architecture.

The present invention relates to biomaterial in the form of dispersion of cellulose nanofibrils with extraordinary shear thinning properties which can be converted into desire 3D shape using 3D Bioprinting technology. In this invention cellulose nanofibril dispersion, is processed through different mechanical, enzymatic and chemical steps to yield dispersion with desired morphological and rheological properties to be used as bioink in 3D Bioprinter. The processes are followed by purification, adjusting of osmolarity of the material and sterilization to yield biomaterial which has cytocompatibility and can be combined with living cells. Cellulose nanofibrils can be produced by microbial process but can also be isolated from plant secondary or primary cell wall, animals such as tunicates, algae and fungi. The present invention describes applications of this novel cellulose nanofibrillar bioink for 3D Bioprinting of tissue and organs with desired architecture.

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.