Caltech
geochemists Rob Eagle (left) and John Eiler adjust equipment used to
analyze the isotopic concentrations in dinosaur teeth and reveal the
body temperature of the extinct creatures. (Credit: Caltech / Lance
Hayashida)
ScienceDaily (June 23, 2011)
— Were dinosaurs slow and lumbering, or quick and agile? It depends
largely on whether they were cold or warm blooded. When dinosaurs were
first discovered in the mid-19th century, paleontologists thought they
were plodding beasts that had to rely on their environments to keep
warm, like modern-day reptiles. But research during the last few decades
suggests that they were faster creatures, nimble like the velociraptors
or T. rex depicted in the movie Jurassic Park, requiring warmer, regulated body temperatures like in mammals.
Now, a team of researchers led by the California Institute of
Technology (Caltech) has developed a new approach to take body
temperatures of dinosaurs for the first time, providing new insights
into whether dinosaurs were cold or warm blooded. By analyzing isotopic
concentrations in teeth of sauropods, the long-tailed, long-necked
dinosaurs that were the biggest land animals to have ever lived -- think
Apatosaurus (also known as
Brontosaurus) -- the team found that the dinosaurs were about as warm as most modern mammals.
"This is like being able to stick a thermometer in an animal that has
been extinct for 150 million years," says Robert Eagle, a postdoctoral
scholar at Caltech and lead author on the paper to be published online
in the June 23 issue of
Science Express.
"The consensus was that no one would ever measure dinosaur body
temperatures, that it's impossible to do," says John Eiler, a coauthor
and the Robert P. Sharp Professor of Geology and professor of
geochemistry. And yet, using a technique pioneered in Eiler's lab, the
team did just that.
The researchers analyzed 11 teeth, dug up in Tanzania, Wyoming, and Oklahoma, that belonged to
Brachiosaurus brancai and
Camarasaurus. They found that the
Brachiosaurus
had a temperature of about 38.2 degrees Celsius (100.8 degrees
Fahrenheit) and the Camarasaurus had one of about 35.7 degrees Celsius
(96.3 degrees Fahrenheit), warmer than modern and extinct crocodiles and
alligators but cooler than birds. The measurements are accurate to
within one or two degrees, Celsius.
"Nobody has used this approach to look at dinosaur body temperatures
before, so our study provides a completely different angle on the
longstanding debate about dinosaur physiology," Eagle says.
The fact that the temperatures were similar to those of most modern
mammals might seem to imply that dinosaurs had a warm-blooded
metabolism. But, the researchers say, the issue is more complex. Because
large sauropod dinosaurs were so huge, they could retain their body
heat much more efficiently than smaller mammals like humans. "If you're
an animal that you can approximate as a sphere of meat the size of a
room, you can't be cold unless you're dead," Eiler explains. So even if
dinosaurs were "cold blooded" in the sense that they depended on their
environments for heat, they would still have warm body temperatures.
"The body temperatures we've estimated now provide a key piece of
data that any model of dinosaur physiology has to be able to explain,"
says Aradhna Tripati, a coauthor who's an assistant professor at UCLA
and visiting researcher in geochemistry at Caltech. "As a result, the
data can help scientists test physiological models to explain how these
organisms lived."
The measured temperatures are lower than what's predicted by some
models of body temperatures, suggesting there is something missing in
scientists' understanding of dinosaur physiology. These models imply
dinosaurs were so-called gigantotherms, that they maintained warm
temperatures by their sheer size. To explain the lower temperatures, the
researchers suggest that the dinosaurs could have had some
physiological or behavioral adaptations that allowed them to avoid
getting too hot. The dinosaurs could have had lower metabolic rates to
reduce the amount of internal heat, particularly as large adults. They
could also have had something like an air-sac system to dissipate heat.
Alternatively, they could have dispelled heat through their long necks
and tails.
Previously, researchers have only been able to use indirect ways to
gauge dinosaur metabolism or body temperatures. For example, they infer
dinosaur behavior and physiology by figuring out how fast they ran based
on the spacing of dinosaur tracks, studying the ratio of predators to
prey in the fossil record, or measuring the growth rates of bone. But
these various lines of evidence were often in conflict. "For any
position you take, you can easily find counterexamples," Eiler says.
"How an organism budgets the energy supply that it gets from food and
creates and stores the energy in its muscles -- there are no fossil
remains for that," he says. "So you just sort of have to make your best
guess based on indirect arguments."
But Eagle, Eiler, and their colleagues have developed a so-called
clumped-isotope technique that shows that it is possible to take body
temperatures of dinosaurs -- and there's no guessing involved. "We're
getting at body temperature through a line of reasoning that I think is
relatively bullet proof, provided you can find well-preserved samples,"
Eiler says. In this method, the researchers measure the concentrations
of the rare isotopes carbon-13 and oxygen-18 in bioapatite, a mineral
found in teeth and bone. How often these isotopes bond with each other
-- or "clump" -- depends on temperature. The lower the temperature, the
more carbon-13 and oxygen-18 tend to bond in bioapatite. So measuring
the clumping of these isotopes is a direct way to determine the
temperature of the environment in which the mineral formed -- in this
case, inside the dinosaur.
"What we're doing is special in that it's thermodynamically based,"
Eiler explains. "Thermodynamics, like the laws of gravity, is
independent of setting, time, and context." Because thermodynamics
worked the same way 150 million years ago as it does today, measuring
isotope clumping is a robust technique.
Identifying the most well-preserved samples of dinosaur teeth was one
of the major challenges of the analysis, the researchers say, and they
used several ways to find the best samples. For example, they compared
the isotopic compositions of resistant parts of teeth -- the enamel --
with easily altered materials -- dentin and fossil bones of related
animals. Well-preserved enamel would preserve both physiologically
possible temperatures and be isotopically distinct from dentin and bone.
The next step is to take temperatures of more dinosaur samples and
extend the study to other species of extinct vertebrates, the
researchers say. In particular, taking the temperature of unusually
small and young dinosaurs would help test whether dinosaurs were indeed
gigantotherms.
Knowing the body temperatures of more dinosaurs and other
extinct animals would also allow scientists to learn more about how the
physiology of modern mammals and birds evolved.
In addition to Eagle, Eiler, and Tripati, the other authors are
Thomas Tütken from the University of Bonn, Germany; Caltech
undergraduate Taylor Martin; Henry Fricke from Colorado College; Melissa
Connely from the Tate Geological Museum in Casper, Wyoming; and Richard
Cifelli from the University of Oklahoma. Eagle also has a research
affiliation with UCLA.
This research was supported by the National Science Foundation and the German Research Foundation.
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