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Bone’s strength down to “sacrificial bonds”

The secret of bone鹿s toughness appears to lie in bonds that are designed to break under stress

The secret of bone鹿s toughness appears to lie in 鈥渟acrificial bonds鈥 that are designed to break under stress. Paradoxically, rupturing these chemical bonds makes bone more durable.

Bone has to satisfy two nearly contradictory requirements 鈥 it must be stiff without being brittle. To avoid splintering, a stressed bone needs to dissipate energy, like a shock absorber. And nobody is sure how rigid bone manages to absorb the energy.

James Thompson and his team from the University of California, Santa Barbara, think the energy gets used up ripping apart tiny Velcro-like connections between tangled collagen molecules in the bone. When these sacrificial bonds break they soak up the energy that might otherwise crack the bone.

Delicate operation

To test their idea, the researchers used a delicate device called an atomic force microscope to repeatedly stretch individual collagen fibres attached to a glass slide, as well as similar ones sticking out of a sample of rat bone. The fibres soaked up more energy in each cycle of stretch and relaxation if there was more time between consecutive pulls.

This suggests that when the fibres are stretched, bonds between the coiled collagen molecules break until the molecules are more or less straight. As the fibre contracts again, the bonds need time to reform. If the bonds were simply stretching rather than breaking the fibres should soak up the same amount of energy no matter how long the interval between pulls.

The idea of sacrificial bonds is plausible, says John Currey, a biologist at the University of York, but he鈥檚 not convinced yet. He says it鈥檚 a nice result, but points out that the Santa Barbara researchers don鈥檛 know for certain that the fibres sticking out of the bone are in fact collagen.

鈥淭hey鈥檝e got to find out what it is they鈥檙e pulling on,鈥 he says, 鈥渁nd that may be difficult.鈥

More at: Nature (vol 414, p 773)

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