|
人工骨微纳制造技术 内容简介
《人工骨微纳制造技术(英文版)》是国家自然科学基金项目资助项目,采用激光微纳制造技术制造人工骨。目前常用的人造骨只能起到功能替代的作用,无法实现受损后自我修复,主要是因为人工骨成型过程中无法实现其微纳结构的控制,从而难以实现成骨分化的诱导作用。《人工骨微纳制造技术(英文版)》在国家自然科学基金(5项)等项目的支持下,开展降解可控的多孔人工骨支架结构设计和精细制造及与之对应的诱导成骨的机理研究,构建了具有自我修复功能的纳米晶粒陶瓷人工骨的激光微纳制造理论与方法。
人工骨微纳制造技术 目录
Chapter 1 Laser sintering system
Development of a novel laser-sintering machine for fabrication of artificial bone
Structural analysis and design optimization of a selective laser sintering system
Control software development of a novel rapid prototype laser sintering system for fabricating artificial bone
Realization of NURBS forcranium in a laser sintering machine
Simulation of temperature field during the laser sintering process of nano-hydroxyapatite powder
Chapter 2 Laser sintering process experiments
Microstructure, mechanical properties and in vitro bioactivity of akermanite scaffolds fabricated by laser sintering
Microstructure evolution and mechanical properties improvement in liquid-phase-sintered hydroxyapatite by laser sintering
Laser sintering of nano 13-93 glass scaffolds: microstructure, mechanical properties and bioactivity
Improvement of mechanical properties by the addition of akermauite and 45S5 bioglass in 13-tricalcium phosphate
Akermanite scaffolds reinforced with boron nitride nanosheets in bone tissue engineering
Chapter 3 Micro-nano structure of artificial bone
A novel two-step sintering for nano-hydroxyapatite scaffolds for bone tissue engineering
Preparation of micro/nanometer-sized porous surface structure of calcium phosphate scaffolds and the influence on biocompatibility
Graphene oxide reinforced poly (vinyl alcohol) : nanocomposite scaffolds for tissue engineering applications
Silicon carbide whiskers reinforced akermanite scaffolds for tissue engineering
Effect of nano-zirconia on the mechanical and biological properties of calcium silicate scaffolds
Chapter 4 Mechanical properties of artificial bone
Liquid phase sintered ceramic bone scaffolds by combined laser and furnace
Mechanisms of tetraneedlelike ZnO whiskers reinforced forsterite/bioglass scaffolds
Mechanical reinforcement of diopside bone scaffolds with carbon nanotnbes
A bioactive glass nanocomposite scaffold tougbed by multi-wall carbon nanotubes for tissue engineering
Toughening and strengthening mechanisms of porous akermanite scaffolds reinforced with nano-titania
Chapter 5 Biological properties of artificial bone
Nano SiO2 and MgO improve the properties of porous B-TCP scaffolds via advanced manufacturing technology
Calcium silicate ceramic scaffolds toughened with hydroxyapatite whiskers for bone tissue engineering
Bioactivity improvement of forsterite-based scaffolds with nano-58S bioactive glass
Hydroxyapatite whisker reinforced 63s glass scaffolds for bone tissue engineering
|
