Abdarainurus barsboldi – A New Species of Late Cretaceous Sauropod from Mongolia
A researcher from the Zoological Institute of the Russian Academy of Sciences (St Petersburg, Russia), in collaboration with a colleague from the Borissiak Paleontological Institute of the Russian Academy of Sciences located in Moscow, have published a description of a new type of long-necked dinosaur from Mongolia. The dinosaur has been named Abdarainurus barsboldi (pronounced Ab-darah-in-you-rus bars-bold-eye). Named from fragmentary caudal material (fossil tail bones), the scientists conclude that this new long-necked dinosaur represents a highly specialised lineage of Asian sauropods that was previously unknown to science.
A Life Reconstruction of the Newly Described Mongolian Sauropod A. barsboldi
Abdarainurus barsboldi life reconstruction.
Picture credit: Andrey Atuchin
Abdarainurus barsboldi
The picture (above), shows a speculative life reconstruction of Abdarainurus barsboldi wandering across a floodplain with the soft-shelled turtle (Trionychidae spp.) in the foreground close to the bleached tree stump, whilst a pair of unconcerned ankylosaurus (Pinacosaurus) wander past in the background. Described from a series of eight caudal vertebrae from the base of the tail, along with some middle tail bones and associated chevrons, the fossil material was originally discovered during an expedition to the northern Gobi Desert in 1970, however, the fossils remained unstudied until recently. Tail bones of sauropods can be very diagnostic with numerous autapomorphies (distinctive features), that can help the identification of fossil remains down to the species level (in this case a new species).
The Alagteeg Formation of Mongolia
The Upper Cretaceous deposits that make up the Alagteeg Formation, from whence the fossil material came, represent an extensive, low-lying floodplain. A number of dinosaur species have been identified from these Campanian-aged rocks, including Protoceratops, as well as the armoured dinosaur Pinacosaurus. The genus name for this new sauropod is derived from the Russian spelling for the Abdrant Nuru locality (Abdarain Nuru) and urus, the Latinised term for the tail, a reference to the holotype fossil material.
The species name honours Dr Rinchen Barsbold, a Mongolian vertebrate palaeontologist who has done much to improve understanding regarding the geology of Mongolia and worked tirelessly to excavate the fossil rich deposits of the Gobi Desert and better understand the ancient palaeofauna of Asia.
A phylogenetic analysis carried out by the authors of the scientific paper places A. barsboldi as a basal titanosaurian sauropod, but the researchers urge caution with regards to this placement due to a lack of consensus with regards to the taxonomy of basal titanosaurs. They conclude that it is likely that Abdarainurus represents a highly specialised lineage of Asian macronarian sauropods that was unknown to science previously.
The scientific paper: “An unusual new sauropod dinosaur from the Late Cretaceous of Mongolia” by Alexander O. Averianov and Alexey V. Lopatin published in the Journal of Systematic Palaeontology.
By Mike|2024-01-17T07:37:34+00:00February 12th, 2020|General Teaching|Comments Off on New Dinosaur Model Wins Award
Wild Safari Prehistoric World Camarasaurus Model Wins Award
Readers of the magazine “Prehistoric Times” have voted the Wild Safari Prehistoric World Camarasaurus model the best dinosaur model of 2019. The discerning readers of the magazine selected this dinosaur figure based on its scientific accuracy and its suitability for permitting creative, imaginative play.
Camarasaurus Model
The Wild Safari Prehistoric World Camarasaurus Model Wins an Award
The award-winning Wild Safari Prehistoric World Camarasaurus dinosaur model.
An Extensive and Diverse Prehistoric Animal Model Range
The Wild Safari Prehistoric World model range from Safari Ltd features an extensive range of extinct animals and other prehistoric creatures. The Camarasaurus figure, the largest dinosaur introduced by this American company last year, has been voted the best dinosaur toy of 2019 by readers of “Prehistoric Times” magazine.
The Camarasaurus model (pronounced KAM-are-oh-sore-us ), measures around thirty-five centimetres long and that carefully sculpted head stands some sixteen centimetres high. The model is not too heavy and ideal for little hands and creative minds. The design team at Safari Ltd work hard to ensure that the dinosaur models that they create are scientifically accurate, utilising the latest research from palaeontologists to assist them in this process.
Voted the Best Dinosaur Toy of 2019 – The Wild Safari Prehistoric World Camarasaurus Dinosaur Model
The award-winning Wild Safari Prehistoric World Camarasaurus dinosaur model.
Picture credit: Everything Dinosaur
Wild Safari Prehistoric World Camarasaurus Model
“Prehistoric Times” readers praised the model for its intricate paint detail and the pose of the dinosaur with its foot raised as if the animal was in motion. Whether on the shelf or in the toy chest, the Wild Safari Prehistoric World Camarasaurus makes an excellent accessory helping to encourage children to have fun and play whilst learning about dinosaurs and life in the past.
Commenting on the award, a spokesperson for UK-based Everything Dinosaur stated:
“Our teaching team recognises the benefits of creative, imaginative play. It is wonderful to see that the great care and attention to detail that Safari Ltd put into their dinosaurs has been acknowledged by readers of the magazine. At the heart of everything that Safari Ltd do, is the desire to develop toys that teach, helping to educate young learners, fostering their curiosity and their respect for the environment and conservation. Learning about long extinct creatures such as the Camarasaurus can help children become enthusiastic environmental activists and provide a perspective on climate issues affecting our planet today.”
Eggshell Geochemistry Suggests Endothermy Deeply Rooted in the Dinosauria
The puzzle of dinosaur metabolism has been a subject of debate amongst vertebrate palaeontologists for a very long time. Numerous studies have been published, drawing on a variety of research methods and lines of enquiry to determine whether the non-avian dinosaurs were warm-blooded like their avian (bird) relatives, or whether they were cold-blooded like today’s crocodilians. A study published in the journal “Science Advances”, one that looked at the geophysical and chemical properties of dinosaur eggshell, has concluded that non-avian dinosaurs had the ability to metabolically raise their temperatures above their environment – in essence they were endothermic, that is to say “warm-blooded”.
A Thin Cross-section of Fossilised Eggshell Viewed under Cross-polarising Light to Reveal Internal Structure
A dinosaur eggshell fossil in cross-section under a microscope using cross-polarising light. Eggshell analysis has provided compelling evidence to suggest that dinosaurs were endothermic. Note scale is 500 microns.
Picture credit: Robin Dawson/University of Yale
Non-avian Dinosaurs were they Cold-blooded or Warm-blooded?
The terms cold-blooded and warm-blooded are found frequently in articles about dinosaurs. These terms are very misleading and have been disregarded for a long time by most of the scientific community. For example, most lizards, regarded as cold-blooded, actually maintain a surprisingly high body temperature in their normal environment during the daytime. Internal body temperatures around 42 degrees Celsius have been recorded in some species, much higher than the normal 37˚ Celsius associated with our own “warm-blooded” species.
In simple terms, cold-blooded animals (ectotherms), are largely unable to regulate their own body temperature without the assistance of external sources. Lizards bask in the early morning sun to warm up and then during the heat of the day, they seek shade to help them to keep cool. In contrast, “warm-blooded” organisms such as mammals and birds (endotherms), are able to maintain a body temperature that is higher than the temperature of the environment. They can generate their own body heat. This heat comes from the animal’s metabolism, the chemical reactions that take place in the body (although there are other methods of keeping cool and warming up).
The Debate over Endothermic or Ectothermic Dinosaurs
Where on the spectrum between endothermic and ectothermic are the Dinosauria? Organisms can demonstrate a range of adaptations to assist them in maintaining an optimal body temperature. Picture credit: Everything Dinosaur.
Picture credit: Everything Dinosaur
Understanding the Metabolism – So What?
Understanding the metabolism of a long extinct group of animals such as the non-avian members of the Dinosauria, can provide valuable insight into all sorts of areas, such as energy requirements, food consumption, behavioural traits and activity levels. It can also help scientists to understand how extinct animals adapted to a wide range of environments, such as non-avian dinosaurs being found at high latitudes. Dinosaur fossils being discovered in Antarctica for example.
In this newly published study, the researchers used a technique known as clumped isotope palaeothermometry. It is based on the fact that the ordering of oxygen and carbon atoms in a fossil eggshell are determined by temperature. Once the order of the atoms has been plotted, the scientists can calculate the internal body temperature of the egg-layer.
Based on this analysis, the research team were able to demonstrate that potentially, the three major clades of dinosaurs, Ornithischia, Sauropodomorpha and Theropoda, were characterised by warm body temperatures.
Non-avian Dinosaurs Characterised by Warm Body Temperatures
Commenting on the significance of this study, lead author of the research Robin Dawson, who conducted the research while she was a doctoral student in geology and geophysics at Yale University stated:
“Dinosaurs sit at an evolutionary point between birds, which are warm-blooded, and reptiles, which are cold-blooded. Our results suggest that all major groups of dinosaurs had warmer body temperatures than their environment.”
Eggshell ascribed to a troodontid (theropod) tested at 38˚, 27˚, and 28˚ Celsius (100.4, 80.6, and 82.4 degrees Fahrenheit). Eggshells from the large, duck-billed dinosaur Maiasaura (an ornithischian dinosaur), yielded a temperature of 44˚ Celsius (111.2 degrees Fahrenheit). Both the troodontid and Maiasaura eggshells were collected from Alberta, Canada.
Studying Fossil Eggshells
In addition, the fossilised eggs associated with the oospecies Megaloolithus from the Hateg Formation of Romania tested at 36˚ Celsius (96.8 degrees Fahrenheit). The taxonomy of the Romanian material remains uncertain. The eggshells could represent the dwarf titanosaur Magyarosaurus, the much larger titanosaur Paludititan or indeed, the dwarf hadrosauroid Telmatosaurus. If this fossil material does represent a sauropodomorph, then these results could suggest that metabolically controlled thermoregulation was the ancestral condition for the Dinosauria.
The Taxonomic Relationships of the Taxa Involved in the Study
The phylogeny of the taxa involved in the study.
Picture credit: Science Advances
The picture (above), shows living ectotherms in blue, whilst extant endotherms (birds) are shown in orange. The Maiasaura silhouette represents the major dinosaurian subclade Ornithischia. The asterisk (*) indicates the uncertainty over the taxonomy of the oospecies Megaloolithus, but the fossil eggshells could represent the dwarf sauropod Magyarosaurus. The troodontid material is assigned to the Theropoda.
Fossil Shells Compared with Fossil Eggshells
The researchers conducted the same analysis on cold-blooded invertebrate shell fossils (molluscs) from the same locations as the dinosaur eggshells. This helped the scientists determine the temperature of the local environment — and whether dinosaur body temperatures were higher or lower.
Dawson, now a postdoctoral research associate at the University of Massachusetts-Amherst, explained that the troodontid samples were as much as 10˚ Celsius (50 degrees Fahrenheit), warmer than their environment, the Maiasaura samples were 15˚ Celsius warmer (59 degrees Fahrenheit) and the Megaloolithus samples were 3 to 6˚ Celsius (37.4-42.8 degrees Fahrenheit) warmer.
She added:
“What we found indicates that the ability to metabolically raise their temperatures above the environment was an early, evolved trait for dinosaurs.”
Other Implications
This new research may have other implications as well. For instance, the study shows that a dinosaur’s body size and growth rate may not necessarily be a good indicator of body temperature. The researchers also stated that their findings might add to the ongoing discussion about the role of feathers in early bird evolution. Dense coats of feathers may have evolved to help insulate the bodies of dinosaurs, secondary functions such as for use in visual displays or as part of adaptations towards powered flight occurred later.
Everything Dinosaur acknowledges the assistance of a press release from Yale University in the compilation of this article.
The scientific paper: “Eggshell geochemistry reveals ancestral metabolic thermoregulation in Dinosauria” by Robin R. Dawson, Daniel J. Field, Pincelli M. Hull, Darla K. Zelenitsky, François Therrien and Hagit P. Affek published in the journal Science Advances.
Wild Safari Prehistoric World Camarasaurus Dinosaur Model Wins Award
Prehistoric Times magazine readers have voted the Wild Safari Prehistoric World Camarasaurus dinosaur model the best dinosaur figure of 2019. Subscribers to the quarterly magazine have acknowledged the hard work and dedication of the design team at Safari Ltd by awarding the 2019 Camarasaurus figure the accolade of best dinosaur model of the year.
The Wild Safari Prehistoric World Camarasaurus Dinosaur Model Wins Award
The award-winning Wild Safari Prehistoric World Camarasaurus dinosaur model.
Visit the Everything Dinosaur website for prehistoric animal models: Everything Dinosaur.
Camarasaurus Model
The sauropod replica measures approximately 35 cm long and the head stands some 16 cm in the air. The Camarasaurus model was one of eleven prehistoric animal figures introduced in 2019, although Everything Dinosaur was able to get some stock earlier, prior to the end of 2018.
The Reptilian Models Introduced by Safari Ltd for 2019
Some of the new for 2019 prehistoric animal figures from the Wild Safari Prehistoric World range. The Camarasaurus figure was the largest dinosaur model introduced by Safari Ltd last year. Safari Ltd also introduced a model of a Woolly Rhinoceros (not shown). Picture credit: Everything Dinosaur.
Picture credit: Everything Dinosaur
The 2019 figure replaced the earlier production model, a Camarasaurus figure, a 1:40 scale model that was introduced into the Carnegie Collection range in 2002 and retired back in 2015.
The Now Retired Carnegie Collection Camarasaurus Model
Camarasaurus – the Carnegie Collection 1:40 scale dinosaur model.
Picture credit: Everything Dinosaur
A Special Award
Commenting on the award, a spokesperson from Everything Dinosaur said:
“Safari Ltd have won this special award in previous years. It is great to see the 2019 Camarasaurus figure continuing this trend. The Wild Safari Prehistoric World range of models are ideal for creative, imaginative play as well as being extremely popular with collectors. It is a fantastic collection, representing a wide variety of ancient creatures and long extinct animals.”
The team members at Everything Dinosaur congratulate Safari Ltd for having their Camarasaurus declared the best dinosaur figure of 2019 by readers of Prehistoric Times magazine.
A Dinosaur Model Wins a Prestigious Award
The award-winning Wild Safari Prehistoric World Camarasaurus dinosaur model.
Rhamphorhynchids – “Good Climbers and Rare Walkers”
One of the great mysteries regarding the Pterosauria may have finally be solved. Palaeontologists are one “step” closer to better understanding how these flying reptiles moved about on the ground. Researchers studying six pterosaur trackways preserved in the sandstone that once comprised part of a Late Jurassic beach have been able to examine the locomotive abilities of non-pterodactyloid pterosaurs for the first time.
Fossilised Pterosaur Tracks
This is a big deal, tracks of pterosaurs have been known about for some time, but all the trace fossils suggesting tracks up until now were believed to have been made by pterodactyloid pterosaurs, (Pterodactyloidea), essentially flying reptiles with short tails, relatively long metacarpal bones and a fifth toe that is greatly reduced or absent. Virtually nothing was known about the terrestrial abilities of other types of pterosaur that dominated the skies of the Jurassic, the dimorphodonts, Anurognathidae and the rhamphorhynchids for example.
However, scientists from the remarkable Musée de la Plage aux Ptérosaures, writing in the academic journal “Geobios”, describe six trackways related to three non-pterodactyloid new ichnotaxa and determine that these animals moved quadrupedally and that they were quite at home on the ground.
A Life Reconstruction of a Rhamphorhynchid Pterosaur Walking Across a Beach
The long-tailed Rhamphorhynchus leaves a series of five-toed tracks on the Jurassic beach.
Picture credit: Mark Witton
“Good Climbers and Bad Walkers”
Over the last two hundred years or so, a variety of theories have been put forward by palaeontologists regarding the way in which these flying reptiles moved about on the ground. For most of that time, these ideas were based on anatomical analysis of fossil bones. Trackways preserving evidence of a flying reptile moving about on the ground were exceptionally rare. Ironically, when such evidence did come to light, such as the trackway found in Wyoming in 1952 (Sundance Formation), these trace fossils received little scientific scrutiny.
The lack of tracks from non-pterodactyloid pterosaurs preserved in the fossil record, led many palaeontologists to believe that these animals rarely left the trees or the water and moved around on land. When they did, it was thought that they would have been clumsy and slow-moving, very vulnerable to predation.
A Non-pterodactyloid Trackway from the Upper Jurassic (Plage aux Ptérosaures)
Pterosaur trackway (non-pterodactyloid) from south-western France.
Picture credit: Musée de la Plage aux Ptérosaures/Geobios
“The Pterosaur Beach of Crayssac”
The fossil finds come from the remarkable “la Plage aux Ptérosaures” (the pterosaur beach), located close to the village of Crayssac in the Occitanie region of south-western France. The site provides a trace fossil record of activity on a Late Jurassic beach around 150 million years ago (lower Tithonian faunal stage). Both dinosaur and pterosaur trackways are preserved.
The authors of the scientific paper, conclude that the tracks may have been made by rhamphorhynchids and they propose that non-pterodactyloids, at least during the Late Jurassic, were quadrupedal with digitigrade hands and plantigrade to digitigrade feet. Analysis of the tracks indicates that these animals were good walkers, even if their hind legs were hampered by the uropatagium (the membrane of skin that spanned the back legs). The idea that these types of flying reptiles were “good climbers but bad walkers”, seems to have been refuted.
Studying the Pterosaur Tracks
The authors state that based on this new study and contrary to current hypotheses, non-pterodactyloid pterosaurs seem to have been good walkers even though their trackways are very rare or unidentified to date. Each of the trackways is around a metre in length, the individual prints measuring approximately three centimetres long. Jean-Michel Mazin and his co-author Joane Pouech (from the museum at la Plage aux Ptérosaures), were aware of the significance of these trace fossils as pterodactyloids tracks tend to produce four toe marks in the trace fossil, whereas, non-pterodactyloids had five toes, so five toe marks would be expected in the majority of the hind prints.
Pterosaur expert Mark Witton provides a well-written and comprehensive overview of pterosaur anatomy and discusses the theories associated with their terrestrial locomotion in his excellent book simply entitled “Pterosaurs”.
The Front Cover of the Comprehensive Book on Pterosaurs by Mark Witton
A very well researched and documented publication from an authority on the Pterosauria.
The scientific paper: “The first non-pterodactyloid pterosaurian trackways and the terrestrial ability of non-pterodactyloid pterosaurs” by Jean-Michel Mazin and Joane Pouech published in Geobios.
Lots of Different Types of Theropod Dinosaur Identified from a German Quarry
During the Late Jurassic, much of the landmass we now know as Europe was covered by shallow, tropical seas. The islands that dotted this seascape were dominated by dinosaurs and a great deal of research has been undertaken to identify and map the ancient terrestrial fauna. A new study published in the journal PeerJ, reveals that there were a wide variety of different types of meat-eating dinosaur present on these islands. Fossils associated with allosauroids, ceratosaurs and megalosauroids have been identified in a single bonebed dominated by the dwarf sauropod Europasaurus.
Views of a Single Claw (Pedal Ungual) and Toe Bones (Pedal Phalanges) Tentatively Ascribed to the Allosauroidea
A fossilised foot claw and fossil toe bones tentatively ascribed to the Allosauroidea.
Picture credit: PeerJ
Dwarfism in the Dinosauria
Scientists from the University of Fribourg (Switzerland) in association with the Martin-Luther-Universität (Germany), examined the fragmentary theropod dinosaur remains associated with the Europasaurus bonebed found at the Langenberg Quarry site in Germany’s Harz Mountains, near the town of Goslar (Lower Saxony). These marine deposits have yielded a variety of vertebrate fossils, representing the corpses of terrestrial fauna washed into the marine depositional environment from a nearby island.
All the meat-eating dinosaur fossils described represent relatively small individuals. It is not known whether these fossils represent juveniles or whether they might be evidence of insular dwarfism. Animals living on islands with limited food resources can evolve into dwarf forms, becoming much smaller in size than their mainland relatives.
The incompleteness of the theropod fossil remains and their rarity when compared to the Europasaurus material had discouraged scientific analysis. This is the first academic paper to describe these types of fossils from the Langenberg Quarry. The fragmentary material can only be classified on higher taxonomic levels, the new occurrences reported add to our understanding of the regional tetrapod fauna and to theropod diversity in Europe in general.
Partial Fibulae (Lower Leg Bones) Ascribed to the Theropoda
Partial left fibula (top) and partial right fibula (below) both assigned to the Theropoda and described as potentially megalosauroid.
Picture credit: PeerJ
Several Different Types of Theropod Dinosaur Present
This research confirms the presence of several different types of theropod dinosaur in the Late Jurassic northern European archipelago and will help palaeontologists to better understand the diversity and evolution of the Theropoda during the Late Jurassic of Europe. The incomplete material can be assigned to ceratosaurian, megalosauroid, and allosauroid theropods.
These identifications agree with previous reports of the presence of these theropod groups in the Late Jurassic of Northern Germany based on fossil teeth. Although the Langenberg theropod fauna is not as rich as some other European localities, such as the Lourinhã Formation of Portugal, these findings confirm a varied dinosaur fauna in central Europe during the Late Jurassic.
The scientific paper: “Late Jurassic theropod dinosaur bones from the Langenberg Quarry (Lower Saxony, Germany) provide evidence for several theropod lineages in the central European archipelago” by Serjoscha W. Evans and Oliver Wings published in the journal PeerJ.
The 1:35 scale Rebor Broodlord figure, a cross between an alien and a tyrannosaurid, has wowed collectors and model fans. It is the first of four figures to be introduced in this series. A second Broodlord is planned, the second model will have an “organic” colour scheme. The other two figures will be known as “Swarm” and just like Broodlord, two colour variants will be offered “plague” and “radioactive”.
In order to protect the carefully sculpted back spikes, the typically tyrannosaurid arms and that beautiful, intricate extended jaw, during transit, Rebor has not attached them to the replica, the model has to be assembled, but this does not take too long. Everything Dinosaur has created a short video that explains how to assemble the model and provides a few tips and tricks along the way.
How to Assemble the 1:35 Scale Rebor Broodlord X-REX
The model measures an impressive 43 cm in length and Broodlord stands around 14 cm high at the shoulders. In our video, (it lasts a fraction over 9 and 1/2 minutes), we examine the model in detail, discuss the other figures in this xenomorph/tyrannosaurid line and explain how to fix the four back spikes into their slots behind the animal’s shoulders without them wobbling. We also demonstrate how to insert the two-fingered, small arms and then we show how the top of a ballpoint pen can be used to help secure the jaw extension into the lower jaw.
The Rebor Broodlord X-REX Model (Metallic Variant)
The Rebor 1:35 scale Broodlord X-REX replica is one of the biggest figures that Rebor has made to date. The figure measures approximately 43 cm long.Picture credit: Everything Dinosaur.
Picture credit: Everything Dinosaur
Insert the Tail Before Adding the Arms
The narrator provides plenty of help and advice to assist with figure assembly. For example, it is recommended that the tail is inserted in place prior to adding the arms. To secure the tail requires a firm push and by not adding the arms you can give yourself a greater purchase on the body to help you ensure that the flexible tail piece is inserted neatly and securely into place.
It is fitting that we have made one of our longest videos featuring one of Rebor’s longest (if not the longest replica) produced by this exciting company to date. This video is available on Everything Dinosaur’s YouTube channel, a channel dedicated to dinosaur and prehistoric animal model collecting.
Everything Dinosaur team members have been busy over the last few days posting up pictures of the new for 2020 Papo prehistoric animal models. They have featured the new colour variant feathered Velociraptor, Chilesaurus, the pachycephalosaur Stygimoloch, Megaloceros and have even made a short video featuring the new colour variant Parasaurolophus dinosaur model. The largest dinosaur figure to be introduced this year by Papo is the Giganotosaurus, naturally our staff have posted up plenty of pictures of this new replica too.
In addition, we have produced a short video on this new model, a dinosaur replica that has divided opinions. In our video (it lasts three minutes), we show the prototype production model and then discuss some of the features of this new sculpt.
The New for 2020 Papo Giganotosaurus Dinosaur Model (Sneaky Peek)
Named and described in 1995, this South American theropod (Giganotosaurus carolinii), is regarded as one of the largest, if not the largest, meat-eating dinosaurs known to science. Whilst waiting for news of this Papo figure, our team members checked the correct pronunciation of the genus name. Thanks to the scientists who specialise in the Dinosauria from the Society of Vertebrate Paleontology (SVP), we can confidently state that the accepted scientific pronunciation is Gig-ah-note-oh-sore-us, think of terms like gigabyte or for that matter, gigametre.
The Papo Giganotosaurus (Gig-ah-note-oh-sore-us) Dinosaur Model
The new for 2020 Papo Giganotosaurus dinosaur model. It has an articulated lower jaw.Picture credit: Everything Dinosaur.
Picture credit: Everything Dinosaur
The Papo Giganotosaurus – A Controversial Dinosaur Model
When the first images of this new model were released, the pose of this dinosaur attracted a lot of comments. In Everything Dinosaur’s brief video review, we look at the prototype figure and then discuss some of the other features of the sculpt, such as the detailed paint scheme and the quality of the skin tone and texture. The detail on the head of the dinosaur is remarked upon. The narrator comments on the skull shape and the attention to detail that can be seen in the depiction of the skull fenestrae.
A View of the Papo Giganotosaurus Dinosaur Model (Prototype)
A photograph of the Papo Giganotosaurus prototype model in a display case. Can you see the head of the new for 2020 Papo Chilesaurus by the right foot of the theropod?Picture credit: Everything Dinosaur.
Picture credit: Everything Dinosaur
The video can also be found on Everything Dinosaur’s YouTube channel. Our YouTube channel contains lots of helpful videos about prehistoric animal models and figures. To visit our YouTube channel and to subscribe: Everything Dinosaur on YouTube.
Pterosaur Tooth Discovered in Jurassic Squid Fossil
The pterosaur Rhamphorhynchus, probably fed by grabbing soft-bodied creatures such as squid as it flew close to the surface of the sea. That is the conclusion made by a group of researchers reporting on the remarkable fossil of a squid-like animal with a pterosaur tooth embedded in its body found in Germany. Writing in the academic journal Scientific Reports, the authors of the paper, describe the beautifully preserved remains of the octobrachian (eight-armed) cephalopod Plesioteuthis subovata which has a pterosaur tooth embedded in its left flank.
Reconstruction of the Hunting Behaviour of Rhamphorhynchus muensteri
Reconstruction of the hunting behaviour of Rhamphorhynchus muensteri.
Picture credit: C. Klug and Beat Scheffold
Discovered in 2012
The cephalopod fossil was found in 2012 and it heralds from the world-renowned Solnhofen Lagerstätte in south-eastern Germany. The strata from which the remarkable specimen was gathered has been dated to the Upper Jurassic Altmühltal Formation (lower Tithonian faunal stage – ammonite Hybonoticeras hybonotum biozone). The fossil is kept at the Paläontologisches Institut und Museum, Universität Zürich, Switzerland (PIMUZ 37358).
Views of the Plesioteuthis subovata Specimen Showing the Pterosaur Tooth
Views of the Plesioteuthis subovata specimen in natural and UV light showing the embedded pterosaur tooth.
Picture credit: R. Hoffmann et al (Scientific Reports)
The picture above shows (A), the 28 cm long fossil of the coleoid Plesioteuthis subovata with highlighted areas (B and D). The pterosaur tooth measures 19 mm long and picture (C) shows the tooth viewed under ultraviolet (UV) light. The tip of the tooth is partially covered with phosphatised mantle tissue, thus ruling out the association of the tooth during the fossilisation process. Insert (D), shows the posterior portion of the mantle with faint imprints probably representing a terminal fin. Under UV light analysis no evidence of fin musculature could be identified (E).
Direct Evidence of Hunting/Feeding Behaviour
Such direct evidence of hunting/feeding behaviour is rarely preserved in the fossil record. The authors of the scientific paper, which include a researcher from the University of Leicester (UK), suggest that the adult Plesioteuthis subovata was swimming close to the surface when a pterosaur (suspected of being Rhamphorhynchus muensteri), made a grab for it. It is not known whether the injury sustained to the squid proved fatal, or whether the animal lived for a period of time before finally dying and becoming preserved in the fine-grained sediments associated with the Solnhofen Archipelago.
The tooth most likely came from the front or middle regions of either the upper or lower jaw. As rhamphorhynchid teeth associated with very young or juveniles tend to be much smaller and straighter, the researchers conclude that the tooth came from a mature adult pterosaur with a wingspan of at least one metre.
A Model of Rhamphorhynchus (Wild Safari Prehistoric World)
Wild Safari Prehistoric World Rhamphorhynchus figure.
Picture credit: Everything Dinosaur
The image (above) shows a Rhamphorhynchus model from Safari Ltd.
Pterosaur Tooth Helps to Construct Ancient Food Webs
The coleoid/pterosaur fossil will help scientists to better understand the palaeo-ecosystem associated with the Solnhofen Lagerstätte. Whilst it is true that many different types of predator may have fed upon Plesioteuthis subovata, the size, shape and the lack of longitudinal ridges discounts marine reptiles such as ichthyosaurs, pliosaurs and crocodyliformes. The tooth coming from a type of predatory fish has also been discounted.
The single tooth is most likely from a mature Rhamphorhynchus in a failed hunting attempt. This seems to be the most plausible interpretation of the fossil evidence. Furthermore, several Rhamphorhynchus fossils are known where the pterosaur is entangled within the jaws of the predatory fish Aspidorhynchus. It has been assumed that these types of fish hunted close to the water surface and would have grabbed pterosaurs as they swooped to feed. These fossils indirectly corroborate the suggestion that this pterosaur-cephalopod interaction occurred near the water surface.
Sometimes the Hunter Became the Hunted (Rhamphorhynchus Entangled with the Jaws of Fish)
A fatal encounter between two Jurassic hunters. The Rhamphorhynchus is entangled within the jaws of a predatory fish (Aspidorhynchus acutirostris).
Picture credit: PLOS One
Skim-feeding had been proposed for marine pterosaurs such as Rhamphorhynchus but subsequent studies suggested that this was too energy expensive. It is more likely that Rhamphorhynchus captured prey on the wing just above the water surface or while floating on the water surface.
The scientific paper: “Pterosaurs ate soft-bodied cephalopods (Coleoidea)” by R. Hoffmann, J. Bestwick, G. Berndt, R. Berndt, D. Fuchs and C. Klug published in Scientific Reports.
Dynamosuchus collisensis – Late Triassic Bone Crushing Scavenger
A new species of ancient reptile, a distant relative of modern crocodilians has been named and described. The two-metre-long, terrestrial predator has been named Dynamosuchus collisensis and it is the first member of the Ornithosuchidae family of archosaurs to have been discovered in Brazil. The fossilised remains of the fearsome Dynamosuchus were found in March 2019 in the municipality of Agudo, Rio Grande do Sol in southern Brazil. This is only the fourth ornithosuchid to have been described, the first was found in Scotland (Ornithosuchus) and described in 1894, whilst the other two genera (Riojasuchus and Venaticosuchus), were named and described in 1969 and 1971 respectively, from fossil discoveries made in Argentina.
Dynamosuchus collisensis is the first ornithosuchid to have been found for nearly five decades.
A Life Reconstruction of the Fearsome Dynamosuchus collisensis
Life reconstruction of the fearsome ornithosuchid Dynamosuchus.
Picture credit: Márcio L. Castro
Dynamosuchus collisensis
Writing in the academic journal Acta Palaeontologica Polonica, the researchers from the Universidade Federal de Santa Maria (Brazil), Museo de la Plata (Argentina) and Virginia Tech (USA), estimate that Dynamosuchus roamed Gondwana around 230 million years ago (Carnian faunal stage of the Triassic) and that it may have been a scavenger.
Members of the Ornithosuchidae are characterised by the shape of their snout. The premaxilla tends to project forward and they have two pairs substantial, conical teeth located in the anterior portion of the lower jaw (dentary). Like modern crocodilians these animals were covered in bony armour (osteoderms), but unlike today’s crocodiles, caiman and alligators, they were much more at home on the land than in water.
Like other ornithosuchids, Dynamosuchus probably spent most of its time on all fours, but it may have been capable of adopting a bipedal stance, perhaps when a turn of speed was required to escape from other bipedal predators such as the recently described herrerasaurid Gnathovorax (G.cabreirai).
One of the Osteoderms (Bony Scales) Found at the Fossil Quarry
An osteoderm (bony armour) recovered from the excavation site.
Picture credit: Rodrigo Temp Müller (Universidade Federal de Santa Maria)
A Specialised Scavenger
Studies of the skulls of these archosaurs indicate that they had strong jaws, but a relatively slow bite speed and the projecting premaxilla was not well suited to handling struggling prey. As a result, it is has been speculated that ornithosuchids were specialised scavengers, using their powerful jaws and their curved, serrated teeth in the upper jaw to consume carcasses. The genus name is from the Latin meaning “powerful crocodile”, whereas the trivial name is a Latinised form of “morro” a reference to the fossil quarry located at the base of the “Morro Agudo”.
A Close-up View of the Head of Dynamosuchus collisensis
Dynamosuchus collisensis (view of the head).
Picture credit: Márcio L. Castro
The Santa Maria Formation
The fossil material from the Santa Maria Formation adds to the number of fossil vertebrates known from the Late Triassic of Brazil. The terrestrial ecosystem was complex with synapsids, rauischians, rhynchosaurs, aetosaurs and numerous dinosauromorphs as well as some of the earliest types of dinosaur known. Dynamosuchus collisensis represents the first reptile with specialised anatomical adaptations for scavenging (necrophagy), to be discovered in a single fossiliferous site along with fossil remains of dinosaurs. The new ornithosuchid further demonstrates a link between the animals associated with the Argentinean and Brazilian basins during the Carnian stage of the Triassic.
Everything Dinosaur acknowledges the assistance of a media release from the Universidade Federal de Santa Maria in the compilation of this article.
The scientific paper: “The first ornithosuchid from Brazil and its macroevolutionary and phylogenetic implications for Late Triassic faunas in Gondwana” by Rodrigo T. Müller, M. Belén Von Baczko, Julia B. Desojo, and Sterling J. Nesbitt published in Acta Palaeontologica Polonica.
