Development of Novel Polyanhydride/Nanoceramics Composite Bone Grafts with Suitable Mechanical Strength and Long Durability

Ding Wei Hong; Po Liang Lai; Tsang Hao Liu; I Ming Chu

doi:10.4028/www.scientific.net/AMR.622-623.551

Paper Titles

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Catalytic Deoxygenation Derived from Pyrolysis of Oil Palm Shell
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Early Cost Estimate of Product during Design Stage Using Design for Manufacturing and Assembly (DFMA) Principles
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A Novel Quantum-Dot Cellular Automata XOR Design
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Development of Novel Polyanhydride/Nanoceramics Composite Bone Grafts with Suitable Mechanical Strength and Long Durability
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Polymer to Electrode Adhesion Enhancement Based on Novel PI/Au (Nanolayer)/Polypyrrole Three-Bending-Beam Actuator Fabrication
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The Preparation and Tribological Behaviors of Boron-Nitrogen Containing Modified Soybean Oil as Additives for Lubricating Oil
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An Analytical Study on Laser Forming Process of Sheet Metals, Using New Elasto-Plastic Temperature Dependent Material Model
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Virtual Simulation Applications in Manufacturing Process of High-Speed Trains
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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 622-623Development of Novel Polyanhydride/Nanoceramics...

Development of Novel Polyanhydride/Nanoceramics Composite Bone Grafts with Suitable Mechanical Strength and Long Durability

Abstract:

Different mole ratios of sebacic acid (SA) and 1,6-bis(p-carboxyphenoxy) hexane (CPH) were used to make copolymer. g-HAP, hydroxyapatite (HAP) nanopowder surface-modified by polycaprolactone (PCL), was added with the copolymer to enhance the mechanical strength. Because of surface erosion, polyanhydride sustained the mechanical properties with time. The degradation of copolymer did not cause obvious decline in pH, and was thus less harmful to the osseous tissue. HAP is the main components of human bone and a good osteoinductive substance to help bone mineralization. The result of our study showed that CPH:SA = 7:3 added with10 wt% g-HAP was the best condition with maximum compress strength of 103 MPa. With slow degradation rate and durable mechanical strength, the novel biomaterial was suitable bone repair in future clinical application.