The skull of Triceratops looks almost exaggerated, as if someone enlarged the front half without adjusting the rest. Paleontologists have long studied its horns and frill, yet the cavernous nasal region remained harder to explain. A new reconstruction suggests that space was not empty decoration. It likely housed a complex system for airflow, blood circulation, and temperature control.<\/p>\n
Researchers led by Project Research Associate Seishiro Tada of the University of Tokyo Museum<\/a> examined fossil skulls using high-resolution CT scans and comparisons with living reptiles and birds. By tracing canals inside the bone, they reconstructed where nerves, blood vessels, and soft tissues would have been located. Their work offers the first detailed hypothesis of nasal anatomy in horned dinosaurs, also known as ceratopsids.<\/p>\n \u201cI have been working on the evolution of reptilian heads and noses since my master’s degree,\u201d Tada said. \u201cTriceratops in particular had a very large and unusual nose, and I couldn\u2019t figure out how the organs fit within it even though I remember the basic patterns of reptiles. That made me interested in their nasal anatomy and its function and evolution.\u201d<\/p>\n CT scans reveal how Triceratops used its massive nose for temperature control and airflow regulation. (CREDIT: Shutterstock) A puzzle hidden inside bone<\/p>\n Ceratopsids were among the most diverse dinosaur groups in the Late Cretaceous. Their skulls rank among the most elaborate structures seen in vertebrates, with beaks, horns, frills, and large nasal openings. Previous studies explored the function of horns and frills extensively. The nasal region, despite its size, remained poorly understood.<\/p>\n To investigate, the team scanned a well-preserved Triceratops prorsus premaxilla collected from the Hell Creek Formation. The fossil was digitally segmented using imaging software, allowing researchers to visualize internal chambers and canals in three dimensions. They then compared those structures with anatomical patterns in modern reptiles, birds, and crocodilians using the Extant Phylogenetic Bracket<\/a> approach, which infers soft tissues from living relatives.<\/p>\n The results showed that Triceratops had an unusual arrangement of nerves and blood vessels. In most reptiles, sensory and vascular pathways reach the nose partly through the jaw. In Triceratops, skull shape blocked that route. Instead, nerves and vessels traveled primarily through the nasal branch.<\/p>\n \u201cTriceratops had unusual \u2018wiring\u2019 in their noses,\u201d Tada said. \u201cIn most reptiles, nerves and blood vessels reach the nostrils from the jaw and the nose. But in Triceratops, the skull shape blocks the jaw route, so nerves and vessels take the nasal branch.\u201d<\/p>\n He realized this while assembling 3D-printed skull sections. \u201cI came to realize this while piecing together some 3D-printed Triceratops<\/a> skull pieces like a puzzle,\u201d he said.<\/p>\n Illustration of researchers\u2019 hypothesized layout for the inside of Triceratops nasal cavity. (CREDIT: 2026 K. Sakane CC-BY-ND) A nerve system unlike other reptiles<\/p>\n The reconstruction suggests the lateral nasal nerve supplied much of the front of the snout, replacing the role usually played by another branch in reptiles. That shift appears linked to evolutionary enlargement of the nostril region. As the naris expanded and bones changed shape, the original nerve pathway became less practical.<\/p>\n Endocast evidence from ceratopsid braincases supports this interpretation. The ophthalmic branch of the trigeminal nerve appears unusually large compared with related species such as Protoceratops<\/a>, indicating greater functional importance in horned dinosaurs.<\/p>\n Researchers also proposed that blood vessels followed similar pathways, since arteries and veins often run alongside nerves in reptiles. A dense vascular network inside the nasal cavity would have supported heat exchange, a possibility raised in earlier work but not mapped in detail until now.<\/p>\n Evidence for a turbinate structure<\/p>\n One of the most intriguing findings involves a structure called a respiratory turbinate. These thin, curled tissues inside the nose increase surface area, helping regulate temperature and moisture during breathing. They are common in mammals and birds<\/a> but rarely identified in non-avian dinosaurs.<\/p>\n The team identified a ridge inside ceratopsid nasal bones that closely matches attachment sites for turbinates in birds. Although not all horned dinosaurs show clear evidence, related species in the centrosaurine subgroup possess similar ridges and a projecting narial spine that may have supported the structure.<\/p>\n Various other dinosaurs related to Triceratops show a similar range of features that led the researchers to their conclusion. (CREDIT: 2026 Tada et al. CC-BY-ND) <\/p>\n \u201cAlthough we\u2019re not 100% sure Triceratops had a respiratory turbinate, as most other dinosaurs don\u2019t have evidence for them, some birds have an attachment base (ridge) for the respiratory turbinate and horned dinosaurs have a similar ridge at the similar location in their nose as well,\u201d Tada said. \u201cThat\u2019s why we conclude they have the respiratory turbinate as birds do.\u201d<\/p>\n