R. Wang scite author profile

This paper considers the use of bioinspired functionally graded structures in the design of dental multi-layers that are more resistant to sub-surface crack nucleation. Unlike existing dental crown restorations that give rise to high stress concentration, the functionally graded layers (between crown materials and the joins that attach them to dentin) are shown to promote significant reductions in stress and improvements in the critical crack size. Special inspiration is drawn from the low stress concentrations associated with the graded distributions in the dentin-enamel-junction (DEJ). The implications of such functionally graded structures are also discussed for the design of dental restorations.

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Bioinspired design of dental multilayers

Huang

Rahbar

Wang

et al. 2007

Materials Science and Engineering: A

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Preparation and Physical Characterization of Gelatin—Starch/Hydroxyapatite Porous Composite Scaffold Fabricated Using Novel Microwave Energy under Vacuum Technique

Jaya

Durance

Wang

2009

Journal of Composite Materials

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This work was initiated to explore the possibility of preparing porous scaffold, using microwave energy under vacuum technique. The hypothesis was that microwave energy under vacuum may promote effective cross-linking of the biopolymers during drying as well as to lead desirable physical characteristics of composites for hard tissue-like bone regeneration. Three different percentages of hydroxyapatite (HA) was reinforced with gelatin—starch polymer network to prepare porous scaffolds. EDS result of the prepared scaffold composite showed that Ca/P ratio of the HA phase was the same for all the HA percentages, 1.7, which is slightly higher than the standard value of 1.67. FTIR results showed the existence of a carbonate group along with the peaks of phosphate groups and hydroxyls, the functional group of HA. The scaffold composite obtained by microwave energy under vacuum technique had good mechanical and structural properties, which showed a promising potential for bone-substitution applications.

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R. Wang

Mechanisms governing the inelastic deformation of cortical bone and application to trabecular bone

A comprehensive review of primary strategies for tar removal in biomass gasification

Bioinspired design of dental multilayers

Bioinspired design of dental multilayers

Preparation and Physical Characterization of Gelatin—Starch/Hydroxyapatite Porous Composite Scaffold Fabricated Using Novel Microwave Energy under Vacuum Technique

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