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Lifestyle
Stephen Beech

Arctic Seals Survive Freezing Conditions With Bigger Nostrils

Seals survive in the Arctic by growing bigger nostrils, reveals new research. PHOTO BY SIGNE KIELSTRUP/SWNS 

Seals survive in the Arctic by growing bigger nostrils, reveals new research.

The blubbery mammals stay warm and hydrated in the freezing conditions with larger, more convoluted nasal passages, say scientists.

They hope to use the discovery to design more efficient heating and ventilation systems.

The researchers explained that Arctic seals have evolved many adaptations to cope with their frosty environment.

But one that people might not immediately think of is the bones in their nasal cavities.

The Norwegian research team found that Arctic seals have more convoluted nasal passages than seal species that live in milder environments.

The blubbery mammals stay warm and hydrated in the freezing conditions with larger, more convoluted nasal passages, say scientists. PHOTO BY MIKE PENNINGTON/WIKIMEDIA COMMONS 

Their findings, published in the Biophysical Journal, show that the nasal structures help the seals more efficiently retain heat and moisture as they breathe in and out.

Corresponding author Professor Signe Kjelstrup said: “Thanks to this elaborate structure in their nasal cavities, Arctic seals lose less heat through nasal heat exchange than subtropical seals when both are exposed to the same conditions.

“This provides an evolutionary advantage, especially in the Arctic where heat loss is energy dissipation, which must be replenished by food.

“What’s so amazing is that these Arctic seals retain 94 percent of the water when they breathe in and out.

“This means that most of the water added to the air during inhalation is then recovered during exhalation.”

She explained that in cold, dry environments, animals lose heat and moisture just by breathing.

Most mammals and birds have complex bones called maxilloturbinates inside their nasal cavities that help to minimize the risk.

Kjelstrup says the porous, bony shelves are covered with a richly vascularised layer of mucosal tissues that warm and humidify inhaled air, which is important for lung function and reduces the amount of heat and moisture lost during exhalation.

The Norwegian research team found that Arctic seals have more convoluted nasal passages than seal species that live in milder environments. PHOTO  BY MIKE PENNINGTON/WIKIMEDIA 

However, the structure of the bones varies between species.

The research team previously showed that reindeer noses enable efficient heat exchange in cold conditions, but because reindeer don’t live in diverse environments, they turned to seals to test whether there was anything special about the noses of Arctic animals.

Kjelstrup, of the Norwegian University of Science and Technology, said: “You can’t find reindeer in the middle of the Mediterranean, but seals live in many different environments, so they allowed us to test this question.

“And we knew from a previous study that Arctic seal noses are sponge-like and very dense, whereas the Mediterranean seal nose has a more open structure.”

The research team used computer tomography to make 3D models of the nasal cavities of an Arctic species of seal, the bearded seal (Erignathus barbatus), and a subtropical species, the Mediterranean monk seal (Monachus monachus).

They then used energy dissipation models to compare the seals’ ability to warm and moisten air during inhalation and to reduce heat and moisture loss during exhalation.

The researchers tested both seals under Arctic conditions (−30°C), and at 10° C (50.00 °F) , which would represent a cold day for a Mediterranean monk seal.

They also tweaked different parameters within the model to identify geometrical features of the nasal cavity that are important for its function.

The model indicated that Arctic seals are much more efficient than subtropical seals at retaining heat and water exchange in both Arctic and Mediterranean ambient temperatures.

At −30°C, the subterranean seals lost 1.45 times as much heat and 3.5 times as much water per breath cycle as the Arctic seals, and at 10° C (50.00 °F) , the subterranean seals lost 1.5 times as much heat and 1.7 times as much water.

The advantage was due to the Arctic seal’s more complex, dense nasal cavity, say the researchers.

They showed that the increased perimeter of the Arctic seal’s maxilloturbinates is key to limiting energy dissipation at low ambient temperatures.

The study investigated moisture and heat loss per breath cycle, but the role of breathing rate remains unclear.

The researchers said that is particularly complicated for seals, who pause their breathing for minutes at a time when they dive.

They hope to study the nasal structures of other species to see if different structures provide evolutionary advantages in other environments.

Kjelstrup said: “The camel, for instance, doesn’t need to save much on heat, but it does need to save on water, so one may speculate that it could tell us something about relative importance of the two.”

The research team plan to use the information to engineer more efficient heat exchangers and ventilation systems.

Kjelstrup added: “If nature manages to create such great heat exchangers, I think we should copy that in engineering to create more efficient processes, for instance, in air conditioners.”

 

Produced in association with SWNS Talker

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