Structure-Property Correlation in Genetically-Engineered Mouse Enamel

Abstract

Dental enamel is the most durable bioceramics produced by a vertebrate as it is designed to perform masticatory functions throughout its lifetime. The understanding of the mechanism of enamel formation and effects of proteins during the biomineralization process are fundamental issues, essential for both potential enamel regeneration and as a base for synthesis, via self-assembly, of biomimetic composites.The biomineralization process of enamel is carried out by ameloblast cells that line the inner enamel epithelium and secrete an extracellular protein matrix onto a mineralized dentin surface at the dentin-enamel junction (DEJ). A major matrix protein, amelogenin, is believed to regulate the mineralization of hydroxyapatite (HAP) in the enamel tissue. It has been shown to undergo self-assembly in vitro and in vivo to form nanospheres of ∼20nm in diameter. Previous TEM studies have shown that the nanospheres align along the length (c-axis) of hydroxyapatite (HA) crystals. There are two domains, namely A (residues 1-42) and B (residues 157-173), that control the self-assembly behavior of the nanospheres.