A kind of bioactive bone composite material and its preparation method and application
A technology of composite materials and modified materials, which is applied in the field of composite materials for bone and its preparation, can solve the problems of immune rejection, mismatch of mechanical properties, low bioactivity of osteoconduction and osteoinduction, etc., and achieve the promotion of bone formation and effective bone Effect of defect repair, high compressive strength and compressive modulus
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Embodiment 1
[0072] Example 1 Porous scaffolds were prepared using low-temperature deposition rapid prototyping 3D printing technology.
[0073]Using the established and optimized computer model of the structure and composition, the controllable preparation is carried out through the control of the manufacturing process parameters of the low-temperature deposition rapid prototyping 3D printing technology, so as to meet the special needs of various osteogenic material structures.
[0074] Forming raw material preparation: Dissolve the biodegradable polymer PLGA in the organic solvent 1,4-dioxane, stir to make it fully dissolved, and then pour the mixed solution into a low-temperature rapid deposition system for 3D printing to prepare magnesium silicide composite porous stand.
[0075] Molding and preparation of porous scaffolds: According to the selected ingredients, the preparation raw materials are mixed and placed in the material tank of the low-temperature deposition rapid prototyping s...
Embodiment 2
[0077] Example 2: PLGA / χMS magnesium silicide composite porous scaffold: the mass fraction of magnesium silicide is 10%.
[0078] The composite porous scaffold was prepared by the same preparation method as in Example 1. The difference from the preparation method in Example 1 is that in the preparation process of the molding raw materials, after dissolving the biodegradable polymer PLGA in the organic solvent 1,4-dioxane and stirring to fully dissolve it, magnesium silicide is added The particles are evenly dispersed in it, and then the mixed solution is poured into a low-temperature rapid deposition system for 3D printing to prepare a composite porous scaffold of magnesium silicide. The added amount of magnesium silicide particles is 10% of the mass of the composite porous support.
Embodiment 3
[0079] Example 3: PLGA / χMS magnesium silicide composite porous scaffold: the mass fraction of magnesium silicide is 20%.
[0080] The composite porous scaffold was prepared by the same preparation method as in Example 1. The difference from the preparation method in Example 1 is that in the preparation process of the molding raw materials, after dissolving the biodegradable polymer PLGA in the organic solvent 1,4-dioxane and stirring to fully dissolve it, magnesium silicide is added The particles are evenly dispersed in it, and then the mixed solution is poured into a low-temperature rapid deposition system for 3D printing to prepare a composite porous scaffold of magnesium silicide. The added amount of magnesium silicide particles is 20% of the mass of the composite porous support.
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