Imperial News

Cheetahs’ unrivalled speed explained by their ‘sweet spot’ size, finds study

by Caroline Brogan

A new Imperial College London study has answered a long-held question about why medium-sized land animals like cheetahs tend to be fastest.

There’s a discrepancy in the animal kingdom. While many key traits such as strength, limb length, lifespan and brain size tend to increase with animals’ size, maximum running speeds tend to be greatest in medium-sized animals.

The fastest animals are neither large elephants nor tiny ants, but intermediately sized, like cheetahs. Dr David Labonte Department of Bioengineering

To explore why, an international team of researchers including Imperial, Harvard University, The University of Queensland and University of the Sunshine Coast, developed a physical model of how muscles, the universal animal motor, set limits on land animals’ top running speeds.

Lead author Dr David Labonte, from Imperial College London’s Department of Bioengineering, said: “The fastest animals are neither large elephants nor tiny ants, but intermediately sized, like cheetahs. Why does running speed break with the regular patterns that govern most other aspects of animal anatomy and performance?”

Their findings suggest that there is not one limit to maximum running speed, as previously thought, but two: how fast, by how far, muscles contract. The maximum speed an animal can reach is determined by whichever limit is reached first – and that limit is dictated by an animal’s size.

Co-author Professor Christofer Clemente, from University of the Sunshine Coast and The University of Queensland, said: “The key to our model is understanding that maximum running speed is constrained both by how fast muscles contract, as well as by how much they can shorten during a contraction.

“Animals about the size of a cheetah exist in a physical sweet spot at around 50kg, where these two limits coincide. These animals are consequently the fastest, reaching speeds of up to 65 miles per hour.”

The results are published in Nature Communications.

Testing the limits

Heavier animals' muscles produce less force relative to their weight

The first limit, termed the ‘kinetic energy capacity limit’, suggests that the muscles of smaller animals are restrained by how quickly they can contract. Because small animals generate large forces relative to their weight, running for a small animal is a bit like trying to accelerate in a low gear when cycling downhill.

The second limit, called the ‘work capacity limit’, suggests that the muscles of larger animals are restrained by how far their muscles can contract. Because large animals are heavier, their muscles produce less force in relation to their weight, and running is more akin to trying to accelerate when cycling up a hill in a high gear.

Co-author Dr Peter Bishop from Harvard University said: “For large animals like rhinos or elephants, running might feel like lifting an enormous weight, because their muscles are relatively weaker and gravity demands a larger cost. As a result of both, animals eventually have to slow down as they get bigger.”

To test the accuracy of their model, the team compared its predictions to data on land animal speed and size collected from more than 400 species, from large mammals, birds and lizards to tiny spiders and insects.

The team compared its predictions to data on more than 400 species, from large mammals, birds and lizards to tiny spiders and insects

The model accurately predicted how maximum running speeds vary with body size for animals that differ by more than 10 orders of magnitude in body mass – from tiny 0.1 milligram mites to six-tonne elephants.

Need for speed

The findings shed light on the physical principles behind how muscles evolved and could inform future designs for robots that match the athleticism of the best animal runners.

They may also provide critical clues for understanding differences between groups of animals. Large reptiles, such as lizards and crocodiles, are generally smaller and slower than large mammals.

The data suggest that extinct giants, like the Patagotitan dinosaur, might have evolved unique muscular anatomies

Co-author Dr Taylor Dick, from The University of Queensland, said: “One possible explanation for this may be that limb muscle is a smaller percentage of reptiles’ bodies, by weight, meaning that they hit the work limit at a smaller body weight, and thus have to remain small to move quickly.”

The model, combined with data from modern species, also predicted that land animals weighing heavier than 40 tonnes would be unable to move. The heaviest land mammal alive today is the African elephant at around 6.6 tonnes – yet some land dinosaurs, like the Patagotitan, likely weighed much more than 40 tonnes.

The researchers say this indicates that we should be cautious to estimate the muscular anatomy of extinct animals from data on non-extinct ones. Instead, the data suggest that extinct giants might have evolved unique muscular anatomies, which warrant more study.

Our study raises lots of interesting questions about the muscle physiology of both extinct animals and those that are alive today, including human athletes. Dr David Labonte Department of Bioengineering

The study raises questions on how massive dinosaurs managed to move, as well as questions that require more targeted data collection on specific animal groups, like in reptiles or spiders.

While the study looked only at land animals, the researchers will next apply their methods to animals that fly and swim.

Dr Labonte said: “Our study raises lots of interesting questions about the muscle physiology of both extinct animals and those that are alive today, including human athletes. Physical constraints affect swimming and flying animals as much as running animals – and unlocking these limits is next on our agenda.”

This research was funded by Australian Research Council, Human Frontier Science Program, and European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme.

Dynamic similarity and the peculiar allometry of maximum running speed” by David Labonte, Peter J Bishop, Taylor JM Dick & Christofer J Clemente. Published 11 March in Nature Communications.

Images: Shutterstock

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