X-Ray Analysis Sheds New Light On Prehistoric Predator’s Last Meal
|Eddie Gonzales Jr. – MessageToEagle.com – We now know more about the diet of a prehistoric creature that grew up to two and a half meters long and lived in Australian waters during the time of the dinosaurs, thanks to the power of X-rays and a team of scientists at The Australian National University (ANU) and the Australian Museum Research Institute (AMRI).
A, Holotype (AM F.99374) skeleton of Umoonasaurus demoscyllus as mounted for display at AM. B, Segmented and rendered model of the described ‘Sample 1’ gastric mass recovered with AM F.99374. C, ‘Sample 2’ gastric mass from AM F.99374. D, ‘Sample 1’ gastrolith accumulation. E, ‘Sample 2’ gastrolith accumulation. F, Isolated teleost vertebrae visualized from within the AM F.99374 gastric mass. Credit: Alcheringa: An Australasian Journal of Palaeontology (2023). DOI: 10.1080/03115518.2023.2194944
The researchers used micro-CT scans to peer inside the fossilized stomach remains of a small marine reptile—a plesiosaur nicknamed ‘Eric’ after a song from the comedy group Monty Python—to determine what the creature ate in the lead up to its death.
The researchers were able to find 17 previously undescribed fish vertebrae inside Eric’s gut, confirming the plesiosaur’s diet consisted mostly of fish—reinforcing findings from previous studies conducted in 2006.
The findings could help scientists learn more about the evolutionary history of extinct organisms such as Eric, as well as help predict what the future might look like for our marine life. According to the researchers, the study demonstrates the potential to use X-rays to reconstruct the diets of other extinct organisms that inhabited Earth hundreds of millions of years ago.
“Previous studies examined the exterior surface of Eric’s opalized skeleton to find clues,” Ph.D. researcher Joshua White, from the ANU Research School of Physics and the AMRI, said.
“But this approach can be difficult and limiting as fossilized stomach contents are rare to find and there can more hidden beneath the surface that would be near impossible for paleontologists to see without destroying the fossil.”
“We believe our study is the first in Australia to use X-rays to study the gut contents of a prehistoric marine reptile.”
A micro-CT scan showing evidence of fish bones inside Eric the plesiosaur’s gut. Credit: Joshua White/ANU
“Our research employed very powerful X-rays to help us see the animal’s stomach contents in never-before-seen detail, including finding fish bones in its gut.”
“The benefit of using X-rays to study these prehistoric animals is that it does not damage the fossil, which is incredibly important when dealing with valuable and delicate specimens such as Eric.”
White sifted through mountains of data and CT imagery to differentiate between what he believed to be evidence of fish bones, gastroliths, also known as stomach stones, and other materials that the reptile had consumed. The data was used to create a 3D model of Eric’s gut contents.
“Eric was a mid-tier predator, sort of like a sea lion equivalent, that ate small fish and was likely preyed upon by larger, apex predators,” White said.
“We are also lucky in the sense that Eric is one of the most complete opalised vertebrae skeletons in Australia. The fossil is approximately 93 percent complete which is pretty much unheard of in any fossil record.”
“There is practically nowhere else other than Australia that can actually get opalized vertebrae fossils.”
The ANU scientists say learning more about the diet of extinct organisms is an important step in understanding their evolutionary past, but it can also help us understand how animals alive today might be impacted by things such as climate change.
“As environments change, so too does a marine reptile’s diet and understanding these changes can be used to help predict how animals of today will respond to current and emerging climate challenges,” White said.
“If there’s any change to an animals’ diet, we want to look at why this change occurred and by some measure we can compare this to modern animals such as dolphins or whales and try to predict how their diets might change due to climate change and why.”
Eric was first discovered in the opal mines in Coober Pedy in South Australia in 1987. The prehistoric predator is on display at the Australian Museum in Sydney.
The research is published in Alcheringa: An Australasian Journal of Palaeontology.
Written by Eddie Gonzales Jr. – MessageToEagle.com Staff