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Dolphins may use their teeth to hear underwater

The teeth of dolphins and other toothed whales are connected to a uniquely thick bundle of nerve fibres, which might play a role in sound detection
Bottlenose dolphins have teeth unlike those of many other mammals
Jeff Mondragon/Alamy Stock Photo

A study of dolphin jaw anatomy suggests their teeth might act as antennae for sound waves, potentially helping to explain how they hear and use echolocation underwater.

“Our findings support the hypothesis that dolphins utilise their teeth as part of an advanced sound reception system,” says at Tsurumi University in Japan. “This finding provides insight into how dentition may be helpful for dolphins’ underwater life.”

èƵs have long known that dolphins and other members of the toothed whales group of species, called odontocetes, have unique teeth, many of which aren’t used for chewing. The reason they have so many teeth is a mystery.

Many researchers hypothesise that dolphin teeth are well-suited to receive sound waves, says Kodera. The dolphin cochlear nerve, a vital part of the inner ear which processes auditory stimuli, connects to fat in the mandible, or lower jaw, of the dolphin, suggesting that their teeth might act as an interface between sound vibrations in the water and the pathway to the brain.

To better understand dolphin teeth and their relationship to the underlying jaw, Kodera and his team investigated mandibles from several odontocete species, including the bottlenose dolphin (Tursiops truncatus), striped dolphin (Stenella coeruleoalba), Pacific white-sided dolphin (Lagenorhynchus obliquidens) and false killer whale (Pseudorca crassidens). They also examined the jaws of domestic pigs (Sus scrofa domesticus) as a comparison.

They identified several unusual features in odontocete jaws. The teeth sit more loosely within the jaw than in other mammals, and the alveolar sockets, which hold the teeth, are spongier and more porous than those in land mammals. Most importantly, they discovered that long and thick bundles of nerve fibres connect to the teeth through these porous structures.

“These long fibres indicate significant tooth mobility, while the thick nerve bundles suggest heightened sensitivity to tooth movement,” says Kodera.

The nerve bundles in dolphins had many sensory receptors at their ends and were wrapped in a thick layer of fatty insulation, which is a feature that helps electrochemical signals travel more quickly through nerve fibres. The fibres are thicker than those in land mammals, suggesting the teeth might have a sensitivity comparable with tactile hairs used by some animals to sense touch, says Kodera.

at the University of Bath, UK, who wasn’t involved with the study, says the results don’t necessarily show which senses the fibres might aid. “This would need to be borne out from other studies,” he says.

Kodera acknowledges the findings aren’t conclusive evidence of a direct role in echolocation or underwater hearing. “Future research should focus on direct physiological and biomechanical studies,” he says.

The results are “eye-opening”, says at the University of California Museum of Paleontology in Berkeley. He would like to see the fibres tested in living dolphins to better understand their purpose. “I will certainly have this study in mind any time I’m looking at dolphin mandibles and tooth sockets moving forward,” he says.

Journal reference:

The Anatomical Record

Topics: Animals / marine biology