Palatal Biomechanics and Its Significance for Cranial Kinesis in Tyrannosaurus rex

ABSTRACT The extinct nonavian dinosaur Tyrannosaurus rex, considered one of the hardest biting animals ever, is often hypothesized to have exhibited cranial kinesis, or, mobility of cranial joints relative to the braincase. Cranial kinesis in T. rex is a biomechanical paradox in that forcefully biti...

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Bibliographic Details
Published in:Anatomical record (Hoboken, N.J. : 2007) N.J. : 2007), 2020-04, Vol.303 (4), p.999-1017
Main Authors: Cost, Ian N., Middleton, Kevin M., Sellers, Kaleb C., Echols, Michael Scott, Witmer, Lawrence M., Davis, Julian L., Holliday, Casey M.
Format: Article
Language:English
Subjects:
Animals
Biomechanical Phenomena - physiology
Biomechanics
bird
Bite Force
Biting
cranial kinesis
Dinosaurs
Dinosaurs - anatomy & histology
Dinosaurs - physiology
finite element model
Fossils
Jaw
jaw muscles
Kinesis
lizard
Mathematical models
Mimicry
Movement - physiology
Muscles
Palate
Palate - anatomy & histology
Palate - physiology
Phylogenetics
Phylogeny
Posture
Sensitivity analysis
Skull
Skull - anatomy & histology
Skull - physiology
Tyrannosaurus
Tyrannosaurus rex
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Summary:ABSTRACT The extinct nonavian dinosaur Tyrannosaurus rex, considered one of the hardest biting animals ever, is often hypothesized to have exhibited cranial kinesis, or, mobility of cranial joints relative to the braincase. Cranial kinesis in T. rex is a biomechanical paradox in that forcefully biting tetrapods usually possess rigid skulls instead of skulls with movable joints. We tested the biomechanical performance of a tyrannosaur skull using a series of static positions mimicking possible excursions of the palate to evaluate Postural Kinetic Competency in Tyrannosaurus. A functional extant phylogenetic bracket was employed using taxa, which exhibit measurable palatal excursions: Psittacus erithacus (fore–aft movement) and Gekko gecko (mediolateral movement). Static finite element models of Psittacus, Gekko, and Tyrannosaurus were constructed and tested with different palatal postures using anatomically informed material properties, loaded with muscle forces derived from dissection, phylogenetic bracketing, and a sensitivity analysis of muscle architecture and tested in orthal biting simulations using element strain as a proxy for model performance. Extant species models showed lower strains in naturally occurring postures compared to alternatives. We found that fore–aft and neutral models of Tyrannosaurus experienced lower overall strains than mediolaterally shifted models. Protractor muscles dampened palatal strains, while occipital constraints increased strains about palatocranial joints compared to jaw joint constraints. These loading behaviors suggest that even small excursions can strain elements beyond structural failure. Thus, these postural tests of kinesis, along with the robusticity of other cranial features, suggest that the skull of Tyrannosaurus was functionally akinetic. Anat Rec, 303:999–1017, 2020. © 2019 Wiley Periodicals, Inc.
ISSN:1932-8486
1932-8494
DOI:10.1002/ar.24219