Abstract: To provide a differentiation-inducing composition and a method for producing the differentiation-inducing composition, the present disclosure describes use of a degradation product containing at least a portion of the triple helical domain of collagen or atelocollagen.

Abstract: To provide a differentiation-inducing composition and a method for producing the differentiation-inducing composition, the present disclosure describes use of a degradation product containing at least a portion of the triple helical domain of collagen or atelocollagen.

Abstract: A medical material 10 used for an artificial tooth root (FIG. 1b) or an artificial bone (FIG. 1c). The medical material comprises a support 11 composed of titanium web and an outer layer 12 composed of bioabsorbable calcium phosphate compound formed in the periphery thereof.

Abstract: [Problems] To provide a medical material having such a structure that enables even diffusion and distribution in the material of a sufficient amount a substance necessary for a medical treatment. [Means for Solving Problems] A medical material 10 composed of a porous three-dimensional construct 11, which is a rectangular parallelepiped having a porosity of from 20 to 97% and pores 12, 13, 14 and 15 provided in the main body. From this pore 12, a substance such as calcium phosphate or ceramics apatite and/or a physiologically active cell, tissue or protein and a substance suitable for exerting the functions thereof are introduced.

Abstract: It is intended to provide a scaffold whereby a bone and a metallic material can three dimensionally form together a stereoscopic binding layer. Thus, a geometric space sufficient for cell actions is provided. As a result, the time required for the formation of a stereoscopic bond can be shortened and, moreover, a bond can be self-repaired owning to cell actions even in the case where a pair of the bond is injured by a wound, etc. As a material for designing a scaffold, titanium fibers of less than 100 ?m in size and having an aspect ratio of 20 or more are selected. Then these fibers are entangled together to form a layer which is integrally fixed by vacuum sintering to a periphery surface of the various implant bodies, and coated with apatite. The fact that the layer contains spaces of an excellent ability to induce a biological hard tissue and fix the same is proved by the material, in which the layer is fixed to the periphery of an implant.

Abstract: To provide an implant material which exhibits relatively high mechanical binding with an osteoblast and also high strength. [MEANS FOR SOLVING PROBLEMS] A scaffold material (10) capable of inducing a biological hard tissue, which comprises a rod (11) having a trunk portion (21) and bride girders (22), a binding layer (13) formed on the periphery of the rod and a metal fiber layer (14) formed on the periphery of the binding layer, and which further has a reinforcing layer (15) formed on the periphery of the metal fiber layer (14). The binding layer (13) has pores having an average pore size of less than 100 m, and the metal fiber layer (14) has pores having an average pore size of 100 to 400 m.

Abstract: It is intended to provide a scaffold whereby a bone and a metallic material can three dimensionally form together a stereoscopic binding layer. Thus, a geometric space sufficient for cell actions is provided. As a result, the time required for the formation of a stereoscopic bond can be shortened and, moreover, a bond can be self-repaired owning to cell actions even in the case where a pair of the bond is injured by a wound, etc. As a material for designing a scaffold, titanium fibers of less than 100 ?m in size and having an aspect ratio of 20 or more are selected. Then these fibers are entangled together to form a layer which is integrally fixed by vacuum sintering to a periphery surface of the various implant bodies, and coated with apatite. The fact that the layer contains spaces of an excellent ability to induce a biological hard tissue and fix the same is proved by the material, in which the layer is fixed to the periphery of an implant.

Abstract: A fine filling method for dental purposes is characterized in that a fine filler in the form of a powder, a granulate, a suspension or paste, containing finely divided particles of hydroxy-apatite or tetracalcium phosphate, with or without an adjuvant, is rubbed on the surface of a tooth and contacted with saliva. The fine filler for use in this method may contain a calcification-promoting protein.

Abstract: A fine filling method for dental purposes is characterized in that a powder, a granulate, a solution (suspension) or paste containing hydroxy-apatite with or without an adjuvant is rubbed on the surface of teeth. A fine filler for use in this method is characterized in that a calcification-promoting protein is incorporated in hydroxy-apatite or tetracalcium phosphate.

Abstract: Apatite containing immobilized glucanase for decomposition of polysaccharies associated with dental carries is prepared by adding dropwise glutaraldehyde to an aqueous solution in which glucanase, protein and apatite are present in a mixed state. The protein in preferably lysozyme.