The present application relates to a biocompatible composite and a manufacturing method therefor. Since the biocompatible composite is prepared by mixing a dispersion in which calcium phosphate particles are sufficiently dispersed and a biodegradable polymer dispersion, the calcium phosphate particles are more uniformly dispersed in a biodegradable polymer matrix, so that the calcium phosphate particles are uniformly released when composite is applied to the body.

The present application relates to a biocompatible composite and a manufacturing method therefor. Since the biocompatible composite is prepared by mixing a dispersion in which calcium phosphate particles are sufficiently dispersed and a biodegradable polymer dispersion, the calcium phosphate particles are more uniformly dispersed in a biodegradable polymer matrix, so that the calcium phosphate particles are uniformly released when composite is applied to the body.

The present application relates to a biocompatible composite and a manufacturing method therefor. Since the biocompatible composite is prepared by mixing a dispersion in which calcium phosphate particles are sufficiently dispersed and a biodegradable polymer dispersion, the calcium phosphate particles are more uniformly dispersed in a biodegradable polymer matrix, so that the calcium phosphate particles are uniformly released when composite is applied to the body.

The present invention provides, inter alia, compositions including at least one pliable layer comprising a plurality of silk fibroin nanofibrils, and at least one rigid layer comprising a plurality of mineral crystals, wherein each rigid layer is associated with at least one pliable layer, as well as methods for the production and use thereof.

Composites and scaffolds suitable for bone void filling comprising at least a recombinant gelatin and hydroxyapatite in which the recombinant gelatin comprises glutamic and aspartic acid residues that are distributed homogeneously along a gelatin chain, wherein: (i) the recombinant gelatin comprises a total of at least a 8% glutamic and/or aspartic acids amount per 60 amino acids in row with a standard deviation of at most 1.6; (ii) the hydroxyapatite is obtained by precipitation in the presence of the recombinant gelatin.

Composites and scaffolds suitable for bone void filling comprising at least a recombinant gelatin and hydroxyapatite in which the recombinant gelatin comprises glutamic and aspartic acid residues that are distributed homogeneously along a gelatin chain, wherein: (i) the recombinant gelatin comprises a total of at least a 8% glutamic and/or aspartic acids amount per 60 amino acids in row with a standard deviation of at most 1.6; (ii) the hydroxyapatite is obtained by precipitation in the presence of the recombinant gelatin.

Composites and scaffolds suitable for bone void filling comprising at least a recombinant gelatin and hydroxyapatite in which the recombinant gelatin comprises glutamic and aspartic acid residues that are distributed homogeneously along a gelatin chain, wherein: (i) the recombinant gelatin comprises a total of at least a 8% glutamic and/or aspartic acids amount per 60 amino acids in row with a standard deviation of at most 1.6; (ii) the hydroxyapatite is obtained by precipitation in the presence of the recombinant gelatin.

Provided herein are methods of making a biomimetic hydrogel scaffold comprising a polycation and a polyanion. Also provided are anisotropic biomimetic hydrogel scaffold compositions suitable for use in tissue growth, including bone, muscle, and nerve growth an optionally comprising a carbon allotrope such as graphene. Also provided are methods of producing tissue comprising growing tissue on the biomimetic hydrogel scaffold comprising a polycation and a polyanion.

Provided herein are methods of making a biomimetic hydrogel scaffold comprising a polycation and a polyanion. Also provided are anisotropic biomimetic hydrogel scaffold compositions suitable for use in tissue growth, including bone, muscle, and nerve growth an optionally comprising a carbon allotrope such as graphene. Also provided are methods of producing tissue comprising growing tissue on the biomimetic hydrogel scaffold comprising a polycation and a polyanion.

Provided herein are methods of making a biomimetic hydrogel scaffold comprising a polycation and a polyanion. Also provided are anisotropic biomimetic hydrogel scaffold compositions suitable for use in tissue growth, including bone, muscle, and nerve growth an optionally comprising a carbon allotrope such as graphene. Also provided are methods of producing tissue comprising growing tissue on the biomimetic hydrogel scaffold comprising a polycation and a polyanion.