Photos/Pictures of Fossils

Pictures of fossils, fossil hunting trips, fossil sites and photographs relating to fossil hunting and fossil finds.

31 05, 2024

Unique Insight into an Ancient Late Triassic Landscape

By Mike|2024-05-30T10:24:58+01:00May 31st, 2024|Dinosaur and Prehistoric Animal News Stories, Dinosaur Fans, Geology, Main Page, Photos/Pictures of Fossils|0 Comments

Researchers, including scientists from the University of Bristol have undertaken extensive fieldwork to determine the fauna of a Late Triassic landscape. The excavation and study of hundreds of microvertebrate fossils from Lavernock Point (close to Cardiff and Penarth), has enabled the research team to construct a picture of the palaeoenvironment of South Wales around 200 million years ago.

A Terrestrial Environment Close to a Tropical Sea

Dinosaurs and other tetrapods lived on a tropical lowland beside the sea. Dinosaur trackways are known from Barry and other sites close to Lavernock Point. These trace fossils and the recent discovery of dinosaur bones has helped shed light on the history of dinosaurs in Wales.

Evidence of dinosaurs in the Late Triassic landscape of Wales.

Evidence of dinosaurs in the Late Triassic landscape of South Wales. A tridactyl (three-toed) footprint, one of many trackways and prints associated with the Dinosauria known from South Wales. Picture credit: Cindy Howells at the National Museum of Wales.

A Late Triassic Landscape

The cliffs at Lavernock Point contain shales and limestone deposits that were laid down in a warm, tropical sea. Bonebeds are found at several levels of the strata. These locations contain the remains of fish including sharks, marine reptiles and occasionally dinosaurs.

Whilst most of the dinosaurs were small, when compared to their Jurassic descendants, recent marine reptile discoveries indicate that there were giants in the ecosystem. For example, fossilised jawbones indicate the presence of enormous ichthyosaurs, some of which may have been the size of the largest extant whales.

To read a recent blog post about giant Triassic ichthyosaurs: Ichthyotitan A Colossus of the Late Triassic.

Owain Evans, a former student at Bristol University led the research.

He explained:

“The bone bed paints the picture of a tropical archipelago, which was subjected to frequent storms, that washed material from around the surrounding area, both in land and out at sea, into a tidal zone. This means that from just one fossil horizon, we can reconstruct a complex ecological system, with a diverse array of marine reptiles like ichthyosaurs, plesiosaurs and placodonts in the water, and dinosaurs on land.”

A life reconstruction of a pair of Ichthyotitan severnensis.

A giant pair of Ichthyotitan severnensis. Giant marine reptiles swam in the shallow seas surround a tropical archipelago. Picture credit: Gabriel Ugueto.

The researcher added:

“I had visited the coast at Penarth all my life, growing up in Cardiff, but never noticed the fossils. Then, the more I read, the more amazing it became. Local geologists had been collecting bones since the 1870s, and most of these are in the National Museum of Wales in Cardiff.”

Continuing the Research Begun in the 19th Century

Cindy Howells, the Curator of Palaeontology at the National Museum of Wales (Cardiff) highlighted the significance of the fossil discoveries at Lavernock Point. The strata and the fossils contained therein have been studied since the 19th century.

Cindy commented:

“The presence of dinosaur fossils at the site ensure that it remains one of the most significant localities for palaeontology in Wales.”

Two Important Discoveries

Two significant discoveries were made by the research team during the fieldwork at Lavernock. Firstly, an osteoderm from a placodont was discovered. Placodonts were a type of marine reptile that thrived during the Triassic. Secondly, a gular bone from the skull of a coelacanth was found.

Co-author of the scientific paper and the research supervisor Dr Chris Duffin explained:

“The remains of coelacanths and placodonts are relatively rare in the UK, which makes these finds even more remarkable. These two fossils alone help build a broader picture of what the Rhaetian in the UK would have looked like.”

Scale drawing of a Coelacanth. What is a Coelacanth?

A scale drawing of a Coelacanth. The gular bone is located between the dentaries of primitive fish such as Coelacanths. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

Dinosaurs of the Late Triassic Landscape

Professor Michael Benton from Bristol’s School of Earth Sciences, another co-author of the study added:

“The volume of dinosaur remains found at Lavernock is extremely exciting, and is a chance to study a complex, and often mysterious period in their evolutionary history. We have identified the remains of a large Plateosaurus like animal, along with several bones which likely belonged to a predatory theropod.”

This is exciting news, team members at Everything Dinosaur are looking forward to hearing more about these recent dinosaur fossil discoveries. Perhaps, a new species of Welsh sauropodomorph will be described.

The majority of the study focuses on the abundant microfossils found in the cliffs. These fossils include fish teeth, scales and bone fragments. By studying thousands of fossils, the research team were able to identify the key species that lived in the tropical sea. In addition, the team can estimate relative population densities. This permits them to construct food webs and learn more about the fauna present in the Late Triassic landscape. It is likely that more dinosaur fossil discoveries will be made in the future.

Everything Dinosaur acknowledges the assistance of a media release from the University of Bristol in the compilation of this article.

The scientific paper: “Microvertebrates from the basal Rhaetian Bone Bed (Late Triassic) at Lavernock, South Wales” by Owain Evans, Christopher J. Duffin, Claudia Hildebrandt, and Michael J. Benton published in the Proceedings of the Geologist’s Association.

The Everything Dinosaur website: Dinosaur and Prehistoric Animal Toys.

28 05, 2024

Pterosaur Bone and Amazing Adaptations for Powered Flight

By Mike|2024-06-16T12:39:17+01:00May 28th, 2024|Dinosaur Fans, Main Page, Photos/Pictures of Fossils|0 Comments

Pterosaur bone fossils show some remarkable adaptations for powered flight. The bones were light, air-filled and often they had extremely thin walls. The Pterosauria comprises the first vertebrates to have evolved powered flight. The wings of pterosaurs were formed by a membrane of skin and tissue that stretched from the ankles to an enormous fourth digit on the hand. Their evolutionary origins remain unclear. Some palaeontologists postulate that the first flying pterosaurs evolved during the Middle Triassic.

To read an article about the possible ancestry of the Pterosauria: Unravelling the Ancestry of the Pterosaurs.

The shape of the pterosaur wing and evidence of wing membranes. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

The image (above) shows the shape and the anatomy of the pterosaur wing. This is a photograph of an exhibit on display at the Manchester Museum of Natural History. We suspect that this is a cast. The pterosaur genus represented by this exhibit is probably Rhamphorhynchus. The thin and delicate wing bones can be clearly observed.

Wild Safari Dinos Rhamphorhynchus figure.

The picture (above) shows a Rhamphorhynchus pterosaur model. It is a long-tailed flying reptile. The figure is from the Wild Safari Prehistoric World model range.

To view the Wild Safari Prehistoric World range: Safari Ltd Dinosaur and Prehistoric Animal Models.

Pterosaur Bone Structure

Pterosaur bones were lightweight but strong. Their skeletons show a number of adaptations for powered flight. For example, they possessed large, keeled breastbones that anchored powerful flight muscles. The bones were hollow and air-filled similar to those of birds. The bone walls were extremely thin.

A close-up view of the thin-walled and hollow pterosaur bone model on display at the Frankfurt Museum of Natural History. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

The picture (above) shows the internal structure of a pterosaur bone. It is probably a cast. The bone contains struts that help to strengthen it, but most of the internal space would have been filled with air. The walls of the bone are extremely thin. The large notch on the underside would have been for muscle attachment. Pterosaur bones provide a proportionately higher muscle attachment surface area compared to most other reptiles.

An enormous Quetzalcoatlus fossil cast on display. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

Visit the award-winning Everything Dinosaur website: Dinosaur and Pterosaur Models and Toys.

11 05, 2024

Glaswegian Prehistoric Shrimp Fossil Revealed to be New Species

By Mike|2024-05-09T22:03:19+01:00May 11th, 2024|Main Page, Palaeontological articles, Photos/Pictures of Fossils|0 Comments

The people of Glasgow have been recognised as a new species of prehistoric crustacean has been named in their honour. The newly described taxon has been named Tealliocaris weegie. The small but robust shrimp was part of a marine ecosystem that thrived in what was to eventually become Scotland over 330 million years ago. The scientific paper describing this “wee beastie” was published in the Royal Society of Edinburgh’s journal Earth and Environmental Science Transactions.

The Tealliocaris weegie fossil. Picture credit: The Hunterian/University of Glasgow.

Tealliocaris weegie

This little shrimp was preserved in shale, the remnants of an ancient Carboniferous seabed. The fossil comes from the world-famous site from which the Bearsden Shark (Akmonistion zangerii) was excavated in the early 1980s.

To read an article from 2015 on the Bearsden Shark: Rare Scottish Prehistoric Shark is Honoured.

Both the Bearsden Shark specimen and an example of the Tealliocaris weegie shrimp fossil can be seen on display at The Hunterian, University of Glasgow.

The Glaswegian shrimp was originally thought to be a variant of another species but is now known to belong to a different genus, which meant it warranted its own scientific name. The authors of the paper (Dr Neil Clark and Dr Andrew Ross) thought that it would be appropriate to name the new species in honour of the people of Greater Glasgow and in the local dialect.

Dr Neil Clark examines a dinosaur footprint.

Dr Neil Clark Curator of Palaeontology at the Hunterian University of Glasgow. Picture credit; The Hunterian/University of Glasgow.

Dr Neil Clark, Curator of Palaeontology at The Hunterian, explained:

“It is quite rare that any fossil is recognised as a new species and particularly the fossilised remains of a shrimp. I am especially proud, as a Glaswegian myself, that we were able to name a fossil shrimp Tealliocaris weegie. Named after the people of Glasgow, this must surely be one of the oldest ‘Weegies’ at over 330 million years old.”

Professor Rob Ellam FRSE, Emeritus Professor at the University of Glasgow and Editor of the Transactions journal added:

“This new species of fossil crustacean is basically a tiny fossil version of what we eat as scampi today. This paper goes to show that there is still great science to be done with fossils that can be discovered on our own doorstep. Moreover, naming one of the new species Tealliocaris weegie shows that there is still room in the serious world of professional palaeontology and scientific publishing for a welcome bit of light-hearted Glaswegian banter.”

Professor Rob Ellam. Picture credit: The Hunterian/University of Glasgow.

An Exceptionally Rare Form of Fossil Preservation

These prehistoric shrimps, fish, sharks, and other animals lived in an equatorial lagoon when Scotland straddled the equator during the Carboniferous. The exceptional preservation suggests that the bottom of the lagoon was anoxic (low in oxygen) thus preventing scavengers from destroying the remains and allowing the fossils to remain intact through the millions of years before being excavated. Bacterial decay of the shrimps in anoxic conditions has promoted the replacement of the soft tissues by calcium phosphate. This very rare form of preservation can be found in deposits known as Konservat Lagerstätte. This is a German term used to describe a highly fossiliferous deposit with exceptional specimen preservation.

Co-author Dr Andre Ross, the Principal Curator of Palaeobiology at National Museums Scotland stated:

“This new species of crustacean, along with others collected recently from the Scottish Borders, now in the collections of National Museums Scotland, add to our knowledge of life at the beginning of the Carboniferous, 350-330 million years ago, when back-boned animals were starting to colonise the land.”

Co-author of the scientific paper Dr Andrew Ross Principal Curator of Palaeontology at National Museums Scotland. Picture credit: Phil Wilkinson.

The Bearsden site and other nearby locations are extremely important to palaeontologists. The preservation of specimens is remarkable. In some fossils, the muscles and blood vessels can be observed in the partially decayed bodies of the crustaceans as a result of being preserved in phosphates.

Everything Dinosaur acknowledges the assistance of a media release from The Hunterian Museum (Scotland) in the compilation of this article.

The scientific paper: “Caridoid crustaceans from the Ballagan Formation (Tournaisian, Lower Carboniferous) of Willie’s Hole, Chirnside, Scottish Borders, UK” by Neil D. L. Clark and Andrew J. Ross published in the Royal Society of Edinburgh’s journal Earth and Environmental Science Transactions.

The award-winning Everything Dinosaur website: Prehistoric Animal Models and Toys.

9 05, 2024

Tyrannosaurus rex Was Not as Clever as a Primate According to New Research

By Mike|2024-05-07T12:48:53+01:00May 9th, 2024|Adobe CS5, Dinosaur Fans, Main Page, Palaeontological articles, Photos/Pictures of Fossils, Teaching|0 Comments

New scientific research has challenged the findings of a 2023 study that concluded T. rex may have been as clever as a primate. How smart was T. rex? That is a fascinating question, one that body and trace fossils cannot really answer. The idea that the Dinosauria were slow, lumbering, stupid giants has largely been debunked. However, scientists have continued to puzzle over their cognitive abilities.

In April 2023, Everything Dinosaur blogged about a controversial study by Dr Suzana Herculano-Houzel from the Department of Psychology at Vanderbilt University (Tennessee). Doctor Herculano-Houzel postulated that Tyrannosaurus rex had around 3 billion cerebral neurons. The Brazilian neuroscientist implied that this super-sized predator had cognitive capabilities that matched primates.

Titus the T.rex exhibit. A T. rex skeleton on display.

The spectacular Titus the T. rex exhibit at Wollaton Hall. How smart was T. rex? A newly published paper challenges an earlier study that postulated that this theropod was as clever as an extant primate. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

The earlier paper proposed that large theropods such as Tyrannosaurus rex were long-lived, and remarkably intelligent. It was postulated that these animals had “macaque or baboon-like cognition”.

To read Everything Dinosaur’s blog post about this paper: How Big was a T. rex Brain?

Challenging Established Views About Dinosaur Intelligence

The research challenged established views on dinosaur biology and inferred behaviours. In addition, the earlier paper raised questions about whether neuron count estimates could benefit research on extinct animals in general. However, a team of international scientists, including Dr Darren Naish (University of Southampton), have refuted these claims. In a study published in “The Anatomical Record”, the researchers conclude that Tyrannosaurus rex was probably about as smart as a modern crocodile.

Their work reaffirms older theories about the intelligence of large theropods. Soft tissue structures like dinosaur brains rarely survive as fossils. Scientists can use endocasts, moulds made of the brain cavity to estimate brain size and structure. This is imperfect. For example, in extant crocodilians the brain only occupies about a third of the cranial cavity. In mammals and birds nearly 100% of this cavity is occupied by the brain. By revisiting Herculano-Houzel’s (2023) work, the researchers identified several crucial discrepancies regarding interpretation and analysis of data.

Dr Herculano-Houzel probably overestimated the size of the brain of T. rex. It was assumed that the brain filled the whole of the endocranial cavity. In essence, the brain size of T. rex was modelled on mammals and birds, but this new study suggests crocodilians are a better analogy.

Blue: olfactory bulb and tracts, Green: pallium (homologous to the mammalian cerebral cortex), Orange: cerebellum, Yellow: diencephalon and optic tectum, Violet: brain stem. Olfactory structures, pallium and subpallium comprise the telencephalon. The overlay in grey indicates extinct taxa, the brain morphologies of which are estimated. The brain morphology of extinct ornithodirans is similar when compared to living reptiles. Picture credit: Caspar et al.

How Smart was T. rex?

The data used by Dr Herculano-Houzel was found to be inconsistent. For instance, brain size estimates had included other structures that are located in the cranium, but not part of the brain, the olfactory bulb for example. In addition, the earlier study had used a mixture of both juvenile and adult tyrannosaurs. The use of not fully mature animals in the study could have led to inaccurate results.

The team revised the estimates of encephalisation and telencephalic neuron counts in the Dinosauria. For large-bodied theropods in particular, this study estimated significantly lower neuron counts than previously proposed. Their phylogenetic modelling indicated a neuron count for T. rex at between 250 million and 1.7 billion neurons. Although the data spread was substantial, the results modelled reflect the neuron counts found in extant crocodilians. This dataset did not produce neuron counts approaching those found in primates.

A close-up view of the Rebor T. rex Tusk figure.

A close-up view of the detail on the head of the Rebor T. rex Tusk dinosaur model. Although this theropod was a formidable predator, its intelligence may have been overestimated. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

The image (above) shows a close-up view of a 1:35 scale model of a Rebor Tyrannosaurus rex.

To view the Rebor range of prehistoric animals available from Everything Dinosaur: Rebor Dinosaur and Prehistoric Animal Figures.

Brain Size May Not Represent the Best Measure of Cognitive Abilities

Furthermore, the researchers reviewed the suitability of neurological variables such as neuron numbers and relative brain size to predict cognitive complexity, metabolic rate and life history traits in dinosaurs. They concluded that these measures are not helpful when trying to assess the cognition of extinct creatures.

The team stated that trying to gauge the cognitive abilities of dinosaurs without close living analogues is extremely challenging. Neuron numbers might be considered a minor component in an assessment of intelligence and much more work is required to build a robust framework to better understand the level of cognition in extinct animals. In addition, the team concluded that given the depiction of dinosaurs in the popular media, researchers should acknowledge the limitations of the presented inferences to allow their audience to delineate between reasoned conclusions and speculation.

So, when it comes to calculating how smart was T. rex? Scientists have yet to devise robust models to explore dinosaur intelligence.

Everything Dinosaur acknowledges the assistance of the open-source paper (Caspar et al) published in the journal The Anatomical Record in the compilation of this article.

The scientific paper: “How smart was T. rex? Testing claims of exceptional cognition in dinosaurs and the application of neuron count estimates in palaeontological research” by Kai R. Caspar, Cristián Gutiérrez-Ibáñez, Ornella C. Bertrand, Thomas Carr, Jennifer A. D. Colbourne, Arthur Erb, Hady George, Thomas R. Holtz Jr, Darren Naish, Douglas R. Wylie and Grant R. Hurlburt published in The Anatomical Record.

Visit the award-winning Everything Dinosaur website: Dinosaur Models and Toys.

6 05, 2024

Researchers Discover World’s First Tapeworm Body Fossil

By Mike|2024-05-06T15:02:47+01:00May 6th, 2024|Dinosaur and Prehistoric Animal News Stories, Main Page, Palaeontological articles, Photos/Pictures of Fossils|0 Comments

International researchers including scientists from Nanjing Institute of Geology and Palaeontology (China) have found a tapeworm fossil preserved in amber. The amber was mined in Myanmar and is believed to date from approximately 99 million years ago. The three-dimensionally preserved fossil displays unique external and internal features. These features most closely resemble the tentacles of the trypanorhynch tapeworms that parasitise marine elasmobranchs (sharks and rays).

It is a mystery as to how the marine parasite ended up preserved in tree resin. One theory is that the carcase of an elasmobranch was scavenged by a theropod dinosaur. The dinosaur fed on the carcase close to where a pine tree was exuding resin. As the dinosaur tore the carcase apart part of the parasite was flung at the tree and entombed in the resin as it seeped from the bark.

How as a marine tapeworm preserved in tree resin?

A hypothetical ecological reconstruction of the fossil trypanorhynch tapeworm (drawn by YANG Dinghua). The fossil tapeworm was lodged in the intestine of an elasmobranch and the dead host was possibly scavenged by a dinosaur on a strandline with pine resin extruding nearby. Picture credit: Cihang Luo.

Studying a Tapeworm Fossil

Tapeworms are a type of parasitic flatworm (Class Cestoda). Many have complex life cycles, with larvae developing in one host before invading a secondary host in which they grow to adults and produce eggs. Some six thousand species are known, and they infect all major groups of vertebrates including mammals and ourselves. Their fossil record is extremely sparse. However, there is a record of possible tapeworm eggs having been preserved in the coprolite of a Permian shark.

Researcher Wang Bo (Nanjing Institute of Geology and Palaeontology), commented that the fossil is the first ever tapeworm body fossil found. The specimen provides direct evidence of the evolution of the Cestoda.

Fossil tapeworm compared to an extant tapeworm.

The fossil tapeworm from mid-Cretaceous Kachin amber (circa 99 million years ago) and the comparison with the tentacle of an extant trypanorhynch tapeworm. (A) Microscopic image of fossil tapeworm. (B) Micro-CT image of fossil tapeworm. (C) Scanning electron microscopy image of an extant trypanorhynch tapeworm. Picture credit: Cihang Luo.

The discovery demonstrates the remarkable preservation properties of amber.

How Did the Marine Tapeworm Become Trapped in Tree Resin?

PhD student Luo Cihang (Nanjing Institute of Geology and Palaeontology), suggested how a marine tapeworm became trapped in tree resin.

He proposed:

“It may have parasitised the intestines of a ray. The ray’s body was washed ashore and was preyed upon by a dinosaur. As the dinosaur consumed the internal organs of the ray, the worm fell out and become enveloped in nearby resin.”

The research, conducted by scientists from multiple countries including China, Germany, the United Kingdom and Myanmar, was recently published in the academic journal Geology.

Internal structure of fossil tapeworm compared to an extant tapeworm.

The comparison of the internal structure of the fossil (A) with the tentacle of an extant trypanorhynch tapeworm (B). Abbreviation: ivt—invaginated tentacle. Picture credit: Cihang Luo.

A Remarkable Fossil Find

A spokesperson from Everything Dinosaur commented that this was a remarkable and unique fossil discovery. To find a tapeworm fossil preserved in amber is astonishing. Furthermore, it added to the growing body of evidence that amber from Myanmar was produced from Cretaceous trees growing close to the coast. Amber from Myanmar has yielded some amazing fossils, including the shell of an ammonite. The ammonite shell preserved in the tree resin is further evidence that this Cretaceous forest was close to a marine environment.

To read Everything Dinosaur’s early blog post about the ammonite shell preserved in amber: Ammonite Shell Preserved in Amber from Myanmar.

The scientists conclude that the exquisite preservation provides and exceptional example of a marine endoparasite. The study provides, arguably the most convincing body fossil of a flatworm discovered to date.

Everything Dinosaur acknowledges the assistance of a media release requested from the Chinese Academy of Sciences in the compilation of this article.

The scientific paper: “Exceptional preservation of a marine tapeworm tentacle in Cretaceous amber” by Cihang Luo, Harry W. Palm, Yuhui Zhuang, Edmund A. Jarzembowski, Thet Tin Nyunt and Bo Wang published in Geology.

The Everything Dinosaur website: Prehistoric Animal Models and Fossil Replicas.

4 05, 2024

Spotting Jurassic Fossils During a Trip to London

By Mike|2024-05-04T13:02:05+01:00May 4th, 2024|Adobe CS5, Dinosaur Fans, Geology, Main Page, Photos/Pictures of Fossils|0 Comments

Team members at Everything Dinosaur spotted some Jurassic fossils whilst on a recent trip to London. It might be surprising to learn that you can see fossils in our capital city, but you can if you know where to look. You do not have to visit a museum to see fossilised remains of prehistoric animals. Many of the buildings in London are made from Portland stone. This limestone, famed for its quality is quarried in Dorset. Dorset is famous of having much of the “Jurassic Coast” within it. Other famous buildings are also constructed from limestone. These rocks too, also contain lots of fossils of marine invertebrates.

The Victoria and Albert Museum, also known as the V&A is built from limestone. The front facade and the low walls surrounding the building are full of Jurassic fossils. They are easy to spot.

Jurassic fossils preserved in Portland stone.

The stones used to build the Victoria and Albert Museum (V&A Museum) in London contain fossils. The stone is probably similar to Portland stone from Dorset (southern England). Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

Jurassic Fossils in London

The Museum was founded in 1852. Like many Victorian buildings in Britain, it was constructed from Jurassic limestone. It is located in South Kensington, a short distance from the London Natural History Museum.

To read an article from Everything Dinosaur about fossil hunting in London: Fossil Hunting in London A Guide to Finding Fossils in the Capital.

These stones contain the fossilised remains of thousands of marine gastropods, brachiopods and bivalves. These stones preserve a record of a devastating event. An immense natural disaster such as a tropical storm or tsunami smashed a shallow marine habitat. The shallow seascape took the full force of this natural disaster. The jumbled remains of the invertebrates can be clearly seen in the building stones.

The stones may also contain fragmentary remains of Jurassic ammonites.

A selection of ammonite fossils fragments of ammonites and other marine invertebrates can be found in stones used for building materials. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

Visitors to London can find evidence of the destruction of an ancient marine ecosystem preserved in the buildings.

Visit the Everything Dinosaur website: Dinosaur Models and Prehistoric Animal Toys.

17 04, 2024

Ichthyotitan severnensis – A Colossus of the Late Triassic

By Mike|2024-04-17T19:03:57+01:00April 17th, 2024|Adobe CS5, Dinosaur and Prehistoric Animal News Stories, Dinosaur Fans, Main Page, Palaeontological articles, Photos/Pictures of Fossils|0 Comments

A scientific paper has just been published in the open-access journal PLOS ONE that describes a new species of giant ichthyosaur. This huge marine reptile, named Ichthyotitan severnensis could have been about as big as a blue whale (Balaenoptera musculus). The discovery of the fragmentary remains of a second gigantic jawbone in Somerset supports the hypothesis that giant ichthyosaurs were present in the Late Triassic ecosystem.

A washed-up Ichthyotitan severnensis carcase on the beach being visited by two hungry theropod dinosaurs and a flock of curious pterosaurs. Picture credit: Sergey Krasovskiy.

Giant Ichthyosaurs from Somerset

Fossil collector and co-author of this study Paul de la Salle, found a portion of fossil jaw in May 2016. He later returned to the location (the beach at Lilstock, west Somerset) and found more pieces that together formed a partial surangular more than a metre in length. The second fragmentary jawbone, also a surangular was found on a beach a few miles to the east of the original fossil discovery.

In May 2020, Father and daughter, Justin and Ruby Reynolds from Braunton, Devon found the first pieces of the second surangular. They were fossil hunting on the beach at Blue Anchor. Ruby, then aged eleven found the first chunk of fossil bone and went onto to find several more fragments.

Realising that Ruby may have discovered something of considerable scientific value, the family contacted leading ichthyosaur expert, Dr Dean Lomax, a palaeontologist at The University of Manchester. Dr Lomax, who is also a 1851 Research Fellow at the University of Bristol, contacted Paul de la Salle as he recognised the striking similarity between the two fossil finds.

Dr Dean Lomax commented:

“I was amazed by the find. In 2018, my team (including Paul de la Salle) studied and described Paul’s giant jawbone and we had hoped that one day another would come to light. This new specimen is more complete, better preserved, and shows that we now have two of these giant bones – called a surangular – that have a unique shape and structure. I became very excited, to say the least.”

Photographs of the surangular bones associated with the giant marine reptile Ichthyotitan severnensis.

Photograph of the nearly complete giant jawbone (surangular), along with a comparison with the 2018 bone (middle and bottom) found by Paul de la Salle. Picture credit: Dr Dean Lomax.

Hunting for More Fossil Evidence

Justin and Ruby, together with Paul, Dr Lomax, and several family members, visited the site to hunt for more pieces of fossil bone. Over time, the team found additional fragments of the same jaw which fit together perfectly, like a multimillion-year-old ichthyosaur jigsaw.

Father Justin explained:

“When Ruby and I found the first two pieces we were very excited as we realised that this was something important and unusual. When I found the back part of the jaw, I was thrilled because that is one of the defining parts of Paul’s earlier discovery.”

The last piece of bone was recovered in October 2022.

Part of the research team in 2020 examining the initial finds (at the back) of the new discovery made by Ruby and Justin Reynolds. Additional sections of the bone were subsequently discovered. From left to right, Dr Dean Lomax, Ruby Reynolds, Justin Reynolds and Paul de la Salle. Picture credit: Dr Dean Lomax.

Ichthyotitan severnensis

Lead author of the study, Dr Lomax commented that the jaw fossils belong to a new species of enormous ichthyosaur. It would have measured perhaps as much as twenty-five metres in length. Ichthyotitan severnensis was probably larger than any extant toothed whale. Based on comparisons with better known shastasaurid ichthyosaurs, it could have been as big as a blue whale. Analysis of the geology of the two fossil sites along with a detailed comparison of the two surangular fossils supports the team’s hypothesis that these fossils represent an enormous ichthyosaur that is new to science.

An Ichthyotitan severnensis scale drawing. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

The genus and species name translates as “giant fish lizard of the Severn”.

The fossil material is estimated to be around 202 million years old, dating to the end of the Triassic (Rhaetian faunal stage). Gigantic ichthyosaurs (Shastasauridae) swam in the seas while the Dinosauria were beginning to dominate terrestrial environments. Ichthyotitan was one of the last of the shastasaurids, these Somerset fossils represent the last of their kind. The Shastasauridae family are thought to have become extinct at the end of the Triassic.

Ichthyotitan severnensis was not the world’s first giant marine reptile, but de la Salles’ and Reynolds’ discoveries are unique among those known to science. These two bones appear to be approximately thirteen million years younger than their latest geologic relatives, including Shonisaurus sikanniensis (British Columbia, Canada), and Himalayasaurus tibetensis from Tibet, China.

Dr Lomax added:

“I was highly impressed that Ruby and Justin correctly identified the discovery as another enormous jawbone from an ichthyosaur. They recognised that it matched the one we described in 2018. I asked them whether they would like to join my team to study and describe this fossil, including naming it. They jumped at the chance. For Ruby, especially, she is now a published scientist who not only found but also helped to name a type of gigantic prehistoric reptile. There are probably not many 15-year-olds who can say that! A Mary Anning in the making, perhaps.”

Ruby exclaimed:

“It was so cool to discover part of this gigantic ichthyosaur. I am very proud to have played a part in a scientific discovery like this.”

A giant pair of swimming Ichthyotitan severnensis. Picture credit: Gabriel Ugueto.

Not Yet Fully Grown

Further examinations of the bones’ internal structures have been carried out by master’s student, Marcello Perillo, from the University of Bonn, Germany. His research confirmed the ichthyosaur origin of the bones and also revealed that the animal was still growing at the time of death.

He said:

“We could confirm the unique set of histological characters typical of giant ichthyosaur lower jaws: the anomalous periosteal growth of these bones hints at yet to be understood bone developmental strategies, now lost in the deep time, that likely allowed Late Triassic ichthyosaurs to reach the known biological limits of vertebrates in terms of size. So much about these giants is still shrouded by mystery, but one fossil at a time we will be able to unravel their secret.”

Concluding the work, Paul de la Salle added:

“To think that my discovery in 2016 would spark so much interest in these enormous creatures fills me with joy. When I found the first jawbone, I knew it was something special. To have a second that confirms our findings is incredible. I am overjoyed.”

Ichthyotitan severnensis Fossils on Public Display

The fossilised remains will soon be put on display at the Bristol Museum and Art Gallery (Bristol).

Dr Lomax summarised the study:

“This research has been ongoing for almost eight years. It is quite remarkable to think that gigantic, blue whale-sized ichthyosaurs were swimming in the oceans around what was the UK during the Triassic Period. These jawbones provide tantalising evidence that perhaps one day a complete skull or skeleton of one of these giants might be found. You never know.”

To read Everything Dinosaur’s 2018 article about the first surangular fossil discovery: Late Triassic Giant Ichthyosaurs.

Everything Dinosaur acknowledges the assistance of a media release from the University of Manchester in the compilation of this article.

The scientific paper “The last giants: New evidence for giant Late Triassic (Rhaetian) ichthyosaurs from the UK” by Lomax D. R., de la Salle, P., Perillo, M., Reynolds, J., Reynolds, R. and Waldron, J. F. published in PLOS ONE.

Visit the website of Dr Dean Lomax: British Palaeontologist Dr Dean Lomax.

12 04, 2024

New CollectA Polacanthus YouTube Video Nears Completion

By Mike|2024-04-12T15:41:00+01:00April 12th, 2024|Adobe CS5, Dinosaur Fans, Everything Dinosaur News and Updates, Everything Dinosaur videos, Main Page, Photos/Pictures of Fossils, Press Releases|0 Comments

The new CollectA Polacanthus YouTube video is nearly complete. This video review will examine how accurately the model reflects the known fossil material. A review of armoured dinosaur fossil specimens associated with the Wealden Group is continuing. Isolated dermal armour fossils from southern England and the Isle of Wight may not necessarily represent the Polacanthus taxon. With the arrival of a new CollectA Polacanthus figure this year, team members have taken the opportunity to create a short YouTube video outlining the changing perceptions regarding Polacanthus foxii.

How accurate is the new CollectA Polacanthus?

How accurate is the new for 2024 CollectA Polacanthus? In a new video Everything Dinosaur team members take a look at the science behind this new CollectA Deluxe scale model. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

Reviewing the CollectA Polacanthus

Everything Dinosaur were fortunate to be sent an early prototype of the figure. This figure has been used in our video review. It is a 3D print, and it has been painted in accordance with the production figure’s approved colour scheme. However, it is approximately the same size as the production model, albeit the model has two drainage holes located on its underside.

To view the current range of CollectA Deluxe prehistoric animal figures in stock: CollectA Prehistoric Animal Scale Models.

A spokesperson explained that as the material representing members of the Thyreophora was being reviewed, so it was likely that more taxa of British armoured dinosaurs would be erected. The spokesperson outlined that the Thyreophora was a clade. It consists of ornithischian armoured dinosaurs. To date, three armoured dinosaur taxa are associated with the Wealden Group, these dinosaurs are:

Hylaeosaurus (H. armatus) named by Mantell in 1833.
Polacanthus (P. foxii) named in 1865.
Vectipelta (V. barretti) named in 2023.

To read Everything Dinosaur’s blog post about the scientific description of Vectipelta barretti: Vectipelta Honours Natural History Museum Palaeontologist.

Fragmentary and eroded armoured dinosaur fossils on display at Liverpool Museum. These fossils have been assigned to Polacanthus foxii. However, palaeontologists have become less confident over assigning armoured dinosaur fossils from the Wealden Group to a specific taxon. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

Completing the CollectA Deluxe Polacanthus Video

The video consists of several pieces of narration including a short segment that explains the history of Polacanthus research. In addition, the video highlights some of the confusing perceptions that arose following the first scientific reconstruction of Polacanthus in 1905 (Nopcsa). Fortunately, the review of the figure has been concluded. This section has proved to be the most difficult part of the video to create. The work entailed undertaking an examination of the CollectA model and comparing it to the holotype fossil material.

The CollectA Polacanthus YouTube video review should be live on Everything Dinosaur’s YouTube site in a few days.

Visit the Everything Dinosaur website: Dinosaur Toys and Models.

To visit Everything Dinosaur’s YouTube channel: Everything Dinosaur’s YouTube Channel.

11 04, 2024

New Study of Ancient Jawless Fish Suggests They were Filter-feeders

By Mike|2024-04-10T14:47:06+01:00April 11th, 2024|Adobe CS5, Dinosaur and Prehistoric Animal News Stories, Main Page, Palaeontological articles, Photos/Pictures of Fossils|0 Comments

Newly published research has demonstrated that early, jawless fish (agnathans), used bony plates surrounding their mouths to modify the mouth’s shape whilst feeding. CT scans of a three-dimensionally preserved Rhinopteraspis fossil suggest that these early vertebrates were suspension feeders, not hunters or scavengers. The study, led by scientists from the University of Birmingham helps to improve our understanding of the evolution of feeding ecology. The Devonian pteraspidid heterostracan Rhinopteraspis dunensis, the jawless fish studied, was probably a nektonic filter-feeder.

The anterior portion of a three-dimensionally preserved Rhinopteraspis dunensis specimen. CT scans of the fossilised remains of this Devonian fish enabled scientists to study feeding ecology. Picture credit: University of Birmingham.

Studying the Feeding Behaviours of Early Vertebrates

Scientists often use the inferred feeding behaviours of early vertebrates to help piece together the evolution of Vertebrata. Different jaw morphologies and jaw composition can suggest a wide range of feeding strategies. In the jawless fishes many competing theories have been proposed for their feeding habits. For example, scientists have examined whether these animals were passive feeders or active hunters.

A new paper, published in the Proceedings of the Royal Society B reconstructs the feeding apparatus of the Devonian pteraspidid Rhinopteraspis dunensis. Computerised tomography enabled the research team to construct 3D models of the fish’s mouth. The images revealed the structure and arrangement of finger-like bones that project from the lower “lip” of the animal’s mouth. The researchers suggest that these projections controlled the mouth’s size and shape as it filtered food particles from the water.

Senior author and project lead Dr Ivan Sansom (University of Birmingham) stated:

“The application of CT scanning techniques to the study of fossil fish is revealing so much new information about these ancient vertebrates and giving us the opportunity to study precious and unique specimens without destructive investigation.”

Three-dimensional reconstruction of the oral region of Rhinopteraspis dunensis (NHMUK PV P 73217). Picture credit: University of Birmingham.

A Remarkable Rhinopteraspis Fossil

The Rhinopteraspis fossil used in the study is part of the London Natural History Museum fossil collection. It is specimen number NHMUK PV P 73217. It consists of an almost complete anterior portion of the animal. The entire headshield is present along with body scales. Although the Rhinopteraspis fossil has been compressed laterally, elements associated with the oral cavity appear to have maintained their original shape and relative location.

Dr Richard Dearden (University of Birmingham) and lead author of the study explained:

“In this case, these methods have allowed us to fit all of the small bones of this animal’s mouth together, and try and understand how it fed from this integrated system rather than by using isolated bones. Instead of a steady trend towards ‘active food acquisition’ – scavenging or hunting – we see a real diversity and range of feeding behaviours among our earliest vertebrate relatives.”

To read a related article that questioned whether heterostracans were suspension feeders: New Study Features Extremely Old Vertebrate.

Bony Plates with Limited Movement

The mineralised plates around the mouth had limited movement. It is unlikely that these early vertebrates were hunters capable of biting. Many Pteraspidiformes had elongated, bony snouts this would have made it difficult to strain food particles from sediment. However, the mouth plates would have allowed it to control the opening of the mouth, and perhaps strain food from water in a way also used by animals such as flamingos or mussels.

This new study offers a new perspective on the evolution of feeding strategies in early vertebrates. Many current hypotheses argue that there was a long-term evolutionary trend away from passive food collection and consumption to predatory behaviour. This research challenges these earlier theories and suggests that primitive fish had a broad range of different feeding behaviours long before the evolution of a jaw structure.

Everything Dinosaur acknowledges the assistance of a media release from the University of Birmingham in the compilation of this article.

The scientific paper: “The three-dimensionally articulated oral apparatus of a Devonian heterostracan sheds light on feeding in Palaeozoic jawless fishes” by Richard P. Dearden, Andy S. Jones, Sam Giles, Agnese Lanzetti, Madleen Grohganz, Zerina Johanson, Stephan Lautenschlager, Emma Randle, Philip C. J. Donoghue and Ivan J. Sansom published in the Proceedings of the Royal Society B.

The Everything Dinosaur website: Prehistoric Animal Models and Figures.

10 04, 2024

Twelve New Australian Sauropods Described

By Mike|2024-04-10T19:08:17+01:00April 10th, 2024|Adobe CS5, Dinosaur and Prehistoric Animal News Stories, Dinosaur Fans, Main Page, Palaeontological articles, Photos/Pictures of Fossils|0 Comments

Twelve new Australian sauropods have been classified following a comprehensive reassessment of Winton Formation fossil remains. Twelve new sauropod fossil specimens from the Winton Formation (Queensland, Australia) have been described. The extensive review, which involved CT scanning hundreds of fossil bones, has resolved the known sauropods from the Winton Formation into three distinct taxa.

Assessment of Twelve New Australian Sauropods Confirms Three Taxa

The taxa are Diamantinasaurus matildae, Savannasaurus elliottorum and Wintonotitan wattsi. A fourth sauropod, Australotitan cooperensis is now considered an indeterminate diamantinasaurian. The review suggests that the material previously assigned to A. cooperensis might represent a Diamantinasaurus. If this is the case, then Diamantinasaurus was capable of growing much larger than earlier studies indicated. A. cooperensis may become nomen dubium (dubious scientific name not widely recognised).

PhD candidate Samantha Beeston scanning Diamantinasaurus fossil material. Picture credit: Australian Age of Dinosaurs Museum of Natural History.

Picture credit: Australian Age of Dinosaurs Museum of Natural History

The ground-breaking study into these enormous, ground-shaking dinosaurs was led by University of College London PhD candidate Samantha Beeston in collaboration with the Australian Age of Dinosaurs Museum of Natural History. Beeston’s research was conducted as part of her Master’s thesis at Swinburne University of Technology, under the supervision of Dr Stephen Poropat (now at the Western Australian Organic and Isotope Geochemistry Centre, Curtin University). The paper has been published in the open-access journal PeerJ.

Australotitan cooperensis life reconstruction

A life reconstruction of Australotitan cooperensis, the largest known animal to have ever lived in Australia. A reassessment of the fossilised bones suggests that A. cooperensis might be nomen dubium as the fossil remains could represent a very large specimen of Diamantinasaurus matildae. Picture credit: Queensland Museum.

Picture credit: Queensland Museum

To read an earlier blog article (2015) about titanosaur fossil remains later named A. cooperensis awaiting scientific description: Super-sized Aussie Titanosaur Awaits Scientific Description.

Twelve new Australian sauropods described.

A sauropod excavation site photographed in 2011. Picture credit: Australian Age of Dinosaurs Museum of Natural History.

Picture credit: Australian Age of Dinosaurs Museum of Natural History

Three Australian Sauropods

The researchers were able to assign two new specimens to Diamantinasaurus matildae. In addition, two specimens were assigned to Savannasaurus elliottorum with three more being assigned to Wintonotitan wattsi. The other five specimens are too incomplete to classify at the genus level. They have been described as indeterminate diamantinasaurians. A lack of comparable specimens with overlapping bones has hampered precise classification of these five specimens.

The three recognised Winton Formation sauropod taxa are:

Diamantinasaurus matildae – named in 2009 (Hocknull et al).
Savannasaurus elliottorum – named in 2016 (Poropat et al).
Wintonotitan wattsi – named in 2009 in the same scientific paper as D. matildae and the theropod Australovenator wintonensis (Hocknull et al).

Over five hundred sauropod bones were scanned as part of this research. This innovative approach enabled the scientists to evaluate each bone and compare it to other fossil specimens in the Museum’s extensive collection. The study has led to a better understanding of the unique traits that help to separate known species. Student Samantha Beeston explained that as there are so few bones preserved for Australotitan it makes it very difficult, if not impossible to assign new specimens to it, or to differentiate it from any of the other Winton Formation sauropod taxa.

She added: “Due to the limited fossil evidence for Australotitan, resolving its classification will be challenging.”

Twevel new Australian sauropods described in new study.

Student Samantha Beeston scanning the toe bone of Diamantinasaurus. Picture credit: Australian Age of Dinosaurs Museum of Natural History.

Picture credit: Australian Age of Dinosaurs Museum of Natural History

Significant for Australian Palaeontology

David Elliott, the Executive Chairman of the Australian Age of Dinosaurs Museum of Natural History commented that he was delighted to have more sauropod specimens in the Museum’s collection assigned to distinct species. He explained that having a better understanding of autapomorphies and anatomical traits leading to more confident assignment of taxa was a significant leap forward in Australian palaeontological research. The twelve new Australian sauropods would provide the basis for further research into the dinosaurs of the Winton Formation.

He added:

“These dinosaurs help demonstrate the diverse natural history of Australia during the Cretaceous Period and will become important exhibits at the new Australian Age of Dinosaurs Museum of Natural History.”

Volunteers work at the “Devil Dave” sauropod excavation site (2017). Picture credit: Australian Age of Dinosaurs Museum of Natural History.

Picture credit: Australian Age of Dinosaurs Museum of Natural History

Everything Dinosaur acknowledges the assistance of a media release from the Australia Age of Dinosaurs Museum of Natural History in the compilation of this article.

The scientific paper: “Reappraisal of sauropod dinosaur diversity in the Upper Cretaceous Winton Formation of Queensland, Australia, through 3D digitisation and description of new specimens” by Samantha L. Beeston, Stephen F. Poropat, Philip D. Mannion, Adele H. Pentland, Mackenzie J. Enchelmaier, Trish Sloan and David A. Elliott published in PeerJ.

The Everything Dinosaur website: Dinosaur Models and Toys.