This is the pre-publication version which was subsequently revised to appear in Creation32(3):53.
Our teeth are surprisingly tough—they usually remain uncracked through decades of biting and chewing. Yet the surface coating called enamel, while the hardest substance in the human body, is as brittle as glass. This coats the main tooth material, the yellowish dentine (elephant ivory is solid dentin).1 What is the secret of enamel’s staying crack-free despite its brittleness?
In glass, once even a tiny crack starts, it propagates through the material. But recent research, applying a compressive load to human and sea otter teeth, has shown how enamel has a number of features that prevent crack propagation.2
The major reason is tufts, crack-like “defects” where the enamel joins the dentine, which arise during tooth development. They become the starting point for cracks, but they are deep within the tooth, so protected from decay. And the crack stabilizes because of “stress shielding” from neighbouring tufts. One report states:
Acting together like a forest of small flaws, tufts suppress the growth of these cracks by distributing the stress amongst themselves.3
Another crack-resistant feature is the arrangement of the rods, the basic units of enamel. Bundles of rods criss-cross each other on the length of the enamel-dentine junction to the enamel’s outside surface, a pattern called decussation. This also hinders crack propagation.
Finally, the enamel is not a static material like glass, but dynamic. As a crack expands, the tooth heals itself by filling the space with organic material, which glues the crack walls and prevents further expansion.
The report summarizes:
“This is the first time that enigmatic developmental features, such as enamel tufts, have been shown to have any significance in tooth function” said GW researcher Paul Constantino. “Crack growth is also hampered by the ‘basket weave’ microstructure of enamel, and by a ‘self-healing’ process whereby organic material fills cracks extended from the tufts, which themselves also become closed by organic matter. This type of infilling bonds the opposing crack walls, which increases the amount of force required to extend the crack later on.”
This is hardly the first time that Nature—or rather, the Designer of Nature—has surprised scientists with extremely tough structures built from brittle materials (see articles below4).5
Enamel is comprises 96% mineral, mainly hydroxyapatite Ca10(PO4)6(OH)2. Dentine (and bone) comprise only about 70% hydroxyapatite, and also the protein collagen. Enamel contains no collagen but has two unique classes of proteins called amelogenins and enamelins. Return to text.
Enamel is comprises 96% mineral, mainly hydroxyapatite Ca10(PO4)6(OH)2. Dentine (and bone) comprise only about 70% hydroxyapatite, and also the protein collagen. Enamel contains no collagen but has two unique classes of proteins called amelogenins and enamelins.
Herzl Chai, James J.-W. Lee, Paul J. Constantino, Peter W. Lucas, and Brian R. Lawn,
I was first alerted to this remarkable tooth design in