Recently published research reveals Triceratops possessed a surprisingly complex nose.  Famed for its huge size and impressive horns, “three horned face” had specialised structures that helped regulate heat and conserve moisture.  The Triceratops nasal cavity study has been published in the journal “The Anatomical Record.” Triceratops is one of the most recognisable dinosaurs ever discovered. It lived during the Late Cretaceous in North America, and two species have been named.  This ceratopsian regularly tops our dinosaur popularity polls.  Fossils of Triceratops are on display in museums all over the world.  However, this new research demonstrates that there is still much to learn about this dinosaur.

A Triceratops dinosaur poster. This Late Cretaceous dinosaur is one of the most easily recognisable of all the dinosaurs. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

Investigating the Triceratops Nasal Cavity

The new study suggests the Triceratops nasal cavity was far more complex than previously thought. Scientists now think its enormous snout housed specialised tissues linked to breathing, moisture regulation and temperature control. Researchers examined several fossil skulls of Triceratops and other horned dinosaurs. First, they used CT scans to look inside the bones. Next, they created sophisticated 3D computer models of the nasal region. The team then compared these fossils with the noses of extant reptiles, birds and crocodilians. Extant phylogenetic bracketing was employed to model the probable soft tissues associated with the nasal region.

As a result, the researchers produced the first comprehensive hypothesis for the soft tissues inside the ceratopsid snout.

A cast of a Triceratops skeleton on display at the Naturmuseum Senckenberg (Natural History Museum – Frankfurt). On the left a wall mounted example of a Plateosaurus can be seen. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

Nerves, Blood Vessels and Nasal Glands

The results suggest the Triceratops nasal cavity contained an intricate network of nerves and blood vessels. In addition, the scientists identified pathways for neurovascular structures within the narial region. They also inferred the locations of a nasal gland and a nasolacrimal duct. Interestingly, the pattern of nerve supply in ceratopsids appears unique among reptiles. Researchers suggest this unusual arrangement evolved as the nostril openings became larger during ceratopsian evolution. Therefore, the enlarged snout of Triceratops likely supported more than just breathing.

Acquisition of such a structure might have mitigated a thermal problem associated with the large size of the ceratopsid head. After all ceratopsians such as Pentaceratops, Torosaurus and Triceratops are famed for their super-sized skulls.

Two spectacular Haolonggood horned dinosaur models. The two Triceratops figures (Qin Ming and Hu Yan Zhuo). Triceratops is represented by dozens of dinosaur models. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

The picture (above) shows two recent Triceratops figures produced by Haolonggood.  Collectors and dinosaur fans have dozens of Triceratops figures to choose from; this horned dinosaur is extremely popular.

To view the Haolonggood range of prehistoric animal figures: Haolonggood Dinosaur Models.

Evidence for Respiratory Turbinates

The study also suggests the presence of respiratory turbinates in ceratopsid dinosaurs. Respiratory turbinates are delicate, curled structures found inside the noses of birds and mammals today. They help warm and moisten incoming air. In addition, they reduce water loss when animals breathe out. The researchers identified an osteological correlate that suggests these structures may have existed in ceratopsids. If correct, this would represent the first evidence for respiratory turbinates in these dinosaurs.

Cooling a Horned Giant

Respiratory turbinates may have played another important role. In living animals, these structures can help regulate body temperature. This function may have been especially useful for Triceratops. The dinosaur possessed a very large skull, which could potentially trap heat in warm environments. Blood vessels within the nasal tissues may have helped cool the head as air passed through the nose. Consequently, the nasal cavity may have helped prevent overheating in such a large animal.

The magnificent Triceratops skull on display in the “Dinosaurs! Age of the Giant Lizards” gallery at the Berlin Naturkundemuseum. Picture credit: Lukasz Papierak.

Picture credit: Lukasz Papierak

The horns and frill of Triceratops often attract the most attention. Yet this new research highlights another remarkable feature. The Triceratops nasal cavity appears to have been a complex biological system. It likely supported breathing, moisture balance and temperature control. As a result, this famous dinosaur’s impressive snout was not just for show. Instead, it helped the animal maintain stable internal conditions in the Late Cretaceous world.

The scientific paper: “Nasal soft-tissue anatomy of Triceratops and other horned dinosaurs” by Seishiro Tada, Takanobu Tsuihiji, Hiroki Ishikawa, Noriyuki Wakimizu, Soichiro Kawabe and Kodai Sakane published in The Anatomical Record.

The award-winning Everything Dinosaur website: Triceratops Models.

Sophisticated dating of zircon crystals found in volcanic ash has demonstrated that the famous Bromacker fossil site is four million years older than previously thought. The Bromacker fossil site is located in the Thuringian Forest near the village of Tambach-Dietharz (Germany).  The study, published in the journal “Gondwana Research” indicates that the fossil-bearing rocks are 294 million years old.  These rocks record a terrestrial ecosystem from the Early Permian (Asselian faunal stage).

The volcanic ash tuff layer which contained the zircon crystals is only a few millimetres thick.  It was discovered during field work in 2024.

One of the co-authors of the paper, Sophie König (Friedenstein Foundation) commented:

“When we uncovered the dark, reddish-purple ash layer, the difference to the surrounding rock was immediately apparent, and we were very hopeful that we had finally found material that could be dated. The fact that the rock sample actually contained usable zircons still came as a surprise to me. We are delighted to have added an important scientific building block to the highly successful Bromacker project.”

A photograph of zircon crystals. Picture credit: Jakob Stubenrauch.

Picture credit: Jakob Stubenrauch

Dating the Bromacker Fossil Site

Zircon crystals are durable and inert. They naturally trap radioactive uranium in their crystal lattice but exclude lead. As uranium naturally decays into lead at a known constant rate, measuring the ratio of uranium to lead found in a crystal is an accurate method of calculating the absolute age of the crystal. This permits volcanic deposits that contain zircon crystals to be accurately dated. In turn, this provides geologists with a benchmark against which associated sediments can be dated.  The ratio of U to Pb acts as an internal clock.

In order to date the age of the ash layer zircon crystals were extracted from rock samples and analysed radiometrically at the TU Bergakademie Freiberg.  The scientists could then determine the age of the famous Bromacker fossil site with a high degree of precision.

The results of the dating study have significant implications for research. They will help to date ecosystems and fossils from other fossil deposits of similar age that, like Bromacker, formed on the supercontinent Pangaea. The age of these fossils can now be better determined thanks to the correlation with the precisely dated Bromacker fossils.

Providing Information About Permian Ecosystems

Lead author of the research, Dr Lorenzo Marchetti (Museum für Naturkunde Berlin) explained:

“This extraordinary fossil deposit, which provides so much information about Permian ecosystems, needed precise dating in order to become a global reference for biostratigraphic, palaeoclimatic and evolutionary biology studies. Careful exploration of the Bromacker site led to this unexpected but urgently needed discovery of a layer of ash containing well-preserved zircon crystals.”

The new age of 294 mya has implications for the scientific understanding of early ecosystems and terrestrial vertebrates.  For example, the food pyramid as we know it today developed earlier than previously thought. The time span between the first appearance of herbivores and the development of modern food webs was shorter, proving that the evolution of Bromacker organisms proceeded more rapidly than previously thought. Thanks to the new age dating, it is now clear that all these evolutionary innovations and the transition to a more seasonal climate occurred much earlier than the scientific community had previously assumed.

Remarkable fossil discoveries at the famous Bromacker fossil site: Spectacular Fossil Finds for the Bromacker Project Team.

Everything Dinosaur acknowledges the assistance of a media release from the Museum für Naturkunde Berlin in the compilation of this article.

The scientific paper: “First high-precision radioisotopic age from the Permian Bromacker lagerstätte (Tambach Formation, Germany) and implications for biochronology and biota evolution” by Lorenzo Marchetti, Jakob Stubenrauch, Alexandra Käßner, Marion Tichomirowa, Sophie König, Anna Pint and Thomas Voigt published in Gondwana Research.

The award-winning Everything Dinosaur website: Models of Prehistoric Animals.

An international team of palaeontologists has described a new species of early land vertebrate from Brazil. The species is named Tanyka amnicola. Researchers identified this unusual animal from fossils discovered in north-eastern Brazil. Their findings appear as an open access paper in the journal Proceedings of the Royal Society B. Importantly, the fossils reveal an amphibian with a very unusual jaw. The unique jaw morphology suggests adaptations to either specialised processing of small invertebrates or consumption of plants. This demonstrates that some stem tetrapods were exploring niches in ecosystems in the Southern Hemisphere during the Permian.

Fossils from the Pedra de Fogo Formation

The fossils come from the Pedra de Fogo Formation. This formation lies within the Parnaíba Basin of Brazil. Scientists recovered nine isolated lower jaws, each about fifteen centimetres long. Although researchers have not yet found other bones, these jaws reveal important clues. Professor Jörg Fröbisch from the Museum für Naturkunde Berlin played a key role in this study.

Professor Fröbisch commented that the discovery followed many years of work in the region. In fact, the first jaw was discovered during one of the earliest expeditions. For more than fifteen years, researchers have studied the fossils of the Parnaíba Basin. The project involves scientists from Brazil, Argentina, South Africa, the USA, the UK (London Natural History Museum) and Germany.

Life reconstruction of Tanyka amnicola grazing on some plants. Picture credit: Vitor Silva.

Picture credit: Vitor Silva

Tanyka amnicola An Ancient “Living Fossil”

Interestingly, Tanyka amnicola belonged to a very old lineage. As a result, the animal could already be considered a “living fossil” in its own time.

Professor Fröbisch explained:

“What is particularly exciting is that even during its lifetime around 275 million years ago, it could have been described as a living fossil, as it belongs to an archaic group that actually lived 30-50 million years earlier.”

During this period in Earth’s history Brazil was part of a supercontinent called Gondwana. This enormous landmass included South America, Africa, Antarctica and Australia.

A Remarkably Twisted Jaw

The lower jaw of Tanyka amnicola shows a very unusual structure. Lead author Jason Pardo explained that the twisted jaw initially puzzled the researchers. However, every fossil jaw shows the same shape. Therefore, the feature represents normal anatomy rather than damage or taphonomy.

The teeth point sideways rather than straight upwards. Meanwhile, the inner surface of the jaw tilts towards the palate. Furthermore, the jaw surface carries many small teeth. These teeth may have formed a rough grinding surface. When the mouth closed, the teeth probably rubbed against each other. Consequently, the animal could crush or shred food. Hence, the theory that this tetrapod may have been herbivorous, or at least plants made up a proportion of its diet.

Professor Juan Cisneros from the Federal University of Piauí, a co-author of the study believes the animal ate plants at least part of the time.

He stated:

“Based on the structure of its teeth, we assume that Tanyka ate plants at least some of the time. This is surprising, as most of its relatives were carnivores.”

Therefore, Tanyka amnicola may represent an early experiment in herbivory among early tetrapods.

A Window into Early Permian Ecosystems

Fossils from the early Permian are relatively rare. Consequently, every discovery provides valuable information. The Pedra de Fogo Formation offers one of the few windows into Gondwana’s ecosystems at that time.

Co-author Dr Kenneth Angielczyk commented:

“The Pedra de Fogo Formation offers one of the few windows into the animal world of Gondwana during the early Permian period. Tanyka shows us which animals lived there and what ecological roles they played.”

Fossils from this Formation also help scientists understand how early tetrapods interacted.

Tanyka amnicola probably lived close to rivers and lakes. The species name reflects its habitat, the word “amnicola” translates as “river dweller”.  The genus name is derived from the local Guaraní language, it translates as “jaw”.

Researchers estimate that Tanyka amnicola may have reached around one metre in length.

More Discoveries May Follow

At present, scientists only know the animal from jawbones. However, future discoveries could change that. For example, researchers hope to find skulls or articulated skeletons. Such fossils would help reconstruct the entire animal.

Nevertheless, even these isolated jaws provide remarkable insight.

For now, Tanyka amnicola offers a fascinating glimpse into early tetrapod evolution. Moreover, it highlights the importance of the Pedra de Fogo Formation in revealing an ancient ecosystem from Gondwana.

Everything Dinosaur acknowledges the assistance of the Museum für Naturkunde Berlin in the compilation of this article.

The scientific paper: “An aberrant stem tetrapod from the early Permian of Brazil” by Jason D. Pardo, Claudia A. Marsicano, Roger Smith, Juan Carlos Cisneros, Kenneth D. Angielczyk, Jörg Fröbisch, Christian F. Kammerer and Martha Richter published in the Royal Society Proceedings B.

The award-winning Everything Dinosaur website: Prehistoric Animal Figures.