Scaffolds for use in bone tissue engineering include a skeleton and a host component. Methods of preparation of scaffolds include identification of biodegradation properties for the skeleton and the host component. The skeleton is constructed to form a three-dimensional shape. The skeleton is constructed of a first material and has a first rate of biodegradation. The host component fills the three-dimensional shape formed by the skeleton. The host component is constructed of a second material and has a second rate of biodegradation. The first rate of biodegradation is slower than the second rate of biodegradation.

Scaffolds for use in bone tissue engineering include a skeleton and a host component. Methods of preparation of scaffolds include identification of biodegradation properties for the skeleton and the host component. The skeleton is constructed to form a three-dimensional shape. The skeleton is constructed of a first material and has a first rate of biodegradation. The host component fills the three-dimensional shape formed by the skeleton. The host component is constructed of a second material and has a second rate of biodegradation. The first rate of biodegradation is slower than the second rate of biodegradation.

Scaffolds for use in bone tissue engineering include a skeleton and a host component. Methods of preparation of scaffolds include identification of biodegradation properties for the skeleton and the host component. The skeleton is constructed to form a three-dimensional shape. The skeleton is constructed of a first material and has a first rate of biodegradation. The host component fills the three-dimensional shape formed by the skeleton. The host component is constructed of a second material and has a second rate of biodegradation. The first rate of biodegradation is slower than the second rate of biodegradation.

The present application provides compositions configured to be provided in a flowable, liquid form but that are configured to transition to a solid or semi-solid gel based upon a change in pH. The change in pH can arise from one or more materials utilized in the composition itself or based upon encountering an environment with a significantly different pH. The compositions are particularly suited for use as a teat sealant in non-human mammals, particularly cattle.

The present application provides compositions configured to be provided in a flowable, liquid form but that are configured to transition to a solid or semi-solid gel based upon a change in pH. The change in pH can arise from one or more materials utilized in the composition itself or based upon encountering an environment with a significantly different pH. The compositions are particularly suited for use as a teat sealant in non-human mammals, particularly cattle.

The present disclosure relates to a porous inorganic particle which comprises a sintered body of calcium-based particles, and pores distributed in the sintered body, and has a core-shell structure of a core having a high porosity and a shell having a porosity lower than that of the core, wherein the calcium-based particles comprise first calcium-based particles having a maximum diameter of 10 nm to 500 nm, and second calcium-based particles having a maximum diameter of 1 ?m to 10 ?m, and to a composite fillers and product using the same.

The present disclosure relates to a porous inorganic particle which comprises a sintered body of calcium-based particles, and pores distributed in the sintered body, and has a core-shell structure of a core having a high porosity and a shell having a porosity lower than that of the core, wherein the calcium-based particles comprise first calcium-based particles having a maximum diameter of 10 nm to 500 nm, and second calcium-based particles having a maximum diameter of 1 ?m to 10 ?m, and to a composite fillers and product using the same.

A polymer scaffold structure is created as a result of the proportional combination of ?-Tricalcium Phosphate (?-TCP) that will increase the 3D and osteoconductive effect allowing/supporting cell infiltration by using extrusion deposition, in other words, added manufacturing process, and with physiological buffered HA solution with the Deep Coating Method and by increasing the transmission rate of growth factors as a result of coating and expanding their areas with the biological tissue implant, which allows its use with titanium mesh plates or contoured structures.

A polymer scaffold structure is created as a result of the proportional combination of ?-Tricalcium Phosphate (?-TCP) that will increase the 3D and osteoconductive effect allowing/supporting cell infiltration by using extrusion deposition, in other words, added manufacturing process, and with physiological buffered HA solution with the Deep Coating Method and by increasing the transmission rate of growth factors as a result of coating and expanding their areas with the biological tissue implant, which allows its use with titanium mesh plates or contoured structures.

A polymer scaffold structure is created as a result of the proportional combination of ?-Tricalcium Phosphate (?-TCP) that will increase the 3D and osteoconductive effect allowing/supporting cell infiltration by using extrusion deposition, in other words, added manufacturing process, and with physiological buffered HA solution with the Deep Coating Method and by increasing the transmission rate of growth factors as a result of coating and expanding their areas with the biological tissue implant, which allows its use with titanium mesh plates or contoured structures.