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Styxosaurus

Styxosaurus is a genus of elasmosaurid plesiosaur, characterized by its exceptionally long neck that often comprised more than half of its total body length, which could exceed 12 meters (40 feet) in the largest specimens. These marine reptiles inhabited the shallow waters of the Western Interior Seaway in North America during the Late Cretaceous period, spanning the Cenomanian to Campanian stages (approximately 28 million years). With small heads, sharp pointed teeth for grasping prey, and four large flipper-like paddles used in a figure-eight swimming motion, Styxosaurus species were carnivorous, primarily feeding on fish swallowed whole, and often contained gastroliths in their stomachs for digestion or ballast. The genus includes three recognized species: S. snowii (the type species, based on holotype KUVP 1301), S. browni, and the recently described S. rezaci (2023), all distinguished by their high counts of 60 or more, a defining trait of the Styxosaurinae. A notable referred specimen of S. snowii (SDSMT 451), discovered in 1945 near , , measures about 11 meters (36 feet) long with a roughly 5.5 meters (18 feet) in length and over 250 gastroliths preserved in its . Other notable specimens, such as those formerly classified under Hydralmosaurus (now a ), have been reassigned to Styxosaurus, highlighting ongoing taxonomic refinements based on vertebral morphology like "can-shaped" centra with lateral keels. Styxosaurus represents an endemic clade within the , evolving alongside other elasmosaurids but distinguished by its extreme neck elongation, which may have aided in for prey in open water without requiring full body turns. Fossils, including skulls, necks, and partial skeletons, have been found primarily in formations like the Pierre Shale and Niobrara Chalk, providing insights into the biodiversity of marine ecosystems. Despite their formidable size, these plesiosaurs were preyed upon by larger predators such as the shark and .

Discovery and research history

Initial discoveries

The holotype specimen of Styxosaurus snowii (KUVP 1301), consisting of a complete but transversely compressed skull and an articulated series of 29–30 cervical vertebrae, was discovered in the summer of 1890 near Hell Creek in Logan County, , by Judge Elias Putnam West. The fossil was embedded within the Smoky Hill Chalk Member of the , representing lowermost () deposits of the . West, an amateur collector and local fossil enthusiast, recovered the specimen during prospecting in the chalk beds, which were then being actively explored for marine reptiles amid the late 19th-century "Bone Wars" rivalry between paleontologists and . Samuel Wendell Williston, a paleontologist at the , described the find later that year in a brief publication, naming it as a new , Cimoliasaurus snowii, in honor of university chancellor Francis Huntington Snow. The measured approximately 18 inches (46 cm) in length, with the preserved in a hard matrix that required careful preparation to expose the cranium and anterior neck. Williston noted the specimen's significance as the first intact from North American rocks, providing key insights into the group's and cranial during a period when fragmentary remains dominated collections from the Seaway. Williston initially interpreted C. snowii as a relatively short-necked plesiosaur compared to contemporaries like Elasmosaurus, based on the elongated cervical centra (up to 3⅝ inches long in the posterior neck), which suggested a more compact vertebral column than the diminutive centra of typical elasmosaurids. This discovery contributed to early understandings of plesiosaur diversity in the Niobrara, highlighting the Seaway's role as a hotspot for large marine reptiles and spurring further excavations in Kansas chalk outcrops. The specimen was later reclassified as the type of Styxosaurus snowii.

Type material and species designation

The genus Styxosaurus was formally established by Samuel P. Welles in 1943, when he transferred the species Elasmosaurus snowii (originally named Cimoliasaurus snowii by Samuel W. Williston in 1890) to the new genus as the type species Styxosaurus snowii. The holotype specimen, KUVP 1301, consists of an articulated skull, lower jaws, and an associated series of 29–30 cervical vertebrae, collected from the Smoky Hill Chalk Member of the Niobrara Formation (lower Campanian) in Logan County, Kansas. Welles justified the generic separation from Elasmosaurus primarily on the basis of neck length, noting that Styxosaurus possesses a higher cervical vertebral count (estimated at 72–76 based on the holotype and referred material) compared to the 71 cervicals in Elasmosaurus platyurus, resulting in a proportionally longer neck relative to body size. A second species, S. browni, was named by Welles in 1952 based on holotype AMNH 5835, a partial skeleton including a skull and 75 associated vertebrae collected from the Sharon Springs Member of the Pierre Shale (upper Campanian) in Niobrara County, Wyoming. This species was subsequently synonymized with Hydralmosaurus serpentinus due to similarities in axial morphology but was revalidated in 2016 on account of its distinct vertebral counts (72 cervicals) and other diagnostic features of the presacral column that differentiate it from S. snowii and Elasmosaurus. Among referred specimens, SDSMT 451—discovered in 1945 near , , in the Sharon Springs Member of the Pierre —represents a nearly complete of an adult S. snowii, preserving approximately 250 gastroliths in association with the abdominal region and preserving 72 ; it was initially described as the holotype of Alzadasaurus pembertoni but later referred to Styxosaurus snowii and designated as a . Taxonomic debates in the early to mid-20th century centered on the validity of Styxosaurus as distinct from and other elasmosaurids, with concerns over incomplete specimens and overlapping vertebral metrics leading to proposed synonymies; these were largely resolved in Welles' 1962 review of plesiosaurs, which reaffirmed S. snowii as the valid based on the diagnostic and consistent neck elongation across referred material.

Recent findings and reclassifications

In 2023, a new of Styxosaurus, S. rezaci, was named based on a partial (UNSM 50132) consisting of a nearly complete , 36 , dorsal vertebrae, ribs, and elements of the pectoral girdle and , collected from the Codell Sandstone Member (Carlile ) in . This Cenomanian-aged (approximately 93.9 million years old) specimen represents the earliest known occurrence of Styxosaurus and the earliest elasmosaurid in the , extending the temporal range of the genus by about 12 million years and suggesting it was a long-lived in the region. The Styxosaurus browni, long considered a junior synonym of S. snowii, was revalidated in through a detailed morphometric analysis of from the (AMNH 5835). This study compared vertebral elongation patterns, length indices, and neural arch features across elasmosaurids, revealing consistent differences in the mid-cervical region that distinguished S. browni from S. snowii, such as relatively shorter and broader in the former. The revalidation emphasized evolutionary trends in neck elongation among Late Cretaceous elasmosaurids from the . Additional referred material has expanded the known diversity of Styxosaurus from the Campanian Pierre Shale in South Dakota and Kansas. In Kansas, excavations in the 2010s from the Sharon Springs Member yielded another partial skeleton with over 40 associated gastroliths near the abdominal region, interpreted as stomach stones aiding digestion of fish prey, though no soft tissue contents were preserved. Modern imaging techniques, including CT scanning, have influenced reclassifications of Styxosaurinae in the 2020s by enabling non-destructive analysis of vertebral internal structures. For example, histological examinations of thin-sectioned vertebrae from related elasmosaurids have confirmed ontogenetic and taxonomic distinctions through growth patterns in bone tissue, supporting the separation of Styxosaurus from contemporaneous genera like Elasmosaurus.

Anatomy

Skull and dentition

The skull of Styxosaurus snowii is elongated and triangular in dorsal view, measuring 42 cm in length in the holotype specimen (KUVP 1301). It possesses a prominent dorsomedian crest extending from the premaxillary rostrum tip and expanding into a low mound-like boss between the external nares and orbits. The temporal region is elongated, featuring a large temporal fossa that occupies approximately one-third of the total skull length, along with a pronounced convex projection on the posterolateral edge of the squamosals. The orbits are large, reniform, and dorsally constricted, situated near the maxillary-premaxillary suture, with an interorbital width of no more than 7.62 cm between their upper borders. The external nares are positioned anteriorly, adjacent to the anterior margin of the orbits. The quadrate is located posteriorly, contributing to the mandibular articulation beneath the constricted temporal bar. The measures approximately 50 cm in length and is slender, with a straight extending 7 cm anteriorly. It exhibits a sigmoidal tooth row and a high coronoid process formed primarily by the dentary, with the posterior ramus lowered relative to this process; the preserved elements include the dentary, surangular, , and an incomplete retroarticular process. Each mandibular ramus houses 14–16 alveoli. is anisodont, with conical, unserrated that are lightly recurved and sharply pointed, bearing fine apicobasally oriented striations on the lingual surface. The upper includes five premaxillary alveoli and 15 maxillary alveoli per side, while the lower has a comparable number; the largest , such as the anterior premaxillary and fourth maxillary examples, reach up to 5.3 cm in crown height and 1.3 cm in basal width, with laterally expanded roots accommodated by the . Posterior dentary are elongate and overlap the upper tooth row, suggesting interlocking during occlusion; replacement follows a pattern typical of plesiosaurs, with developing visible in some alveoli of the .

Neck and axial skeleton

The neck of Styxosaurus snowii is characteristically elongated, comprising 72 that collectively measure up to 5.25 meters in length and account for roughly 50% of the animal's total body length of approximately 10.5–11 meters. These vertebrae exhibit low neural spines and facets for attachment, adaptations that contributed to the neck's flexibility while maintaining structural integrity during underwater movement. The are double-headed, facilitating robust muscle attachments essential for neck maneuverability. The trunk region features approximately 20 dorsal vertebrae, which are notably short and robust compared to the cervical series, providing a stable core for the body and supporting the attachment of the limb girdles. Transitioning posteriorly, the tail consists of 25–30 caudal vertebrae that progressively taper toward a small pygal region, ending in a relatively short, streamlined fin typical of elasmosaurids. In terms of , the cervical centra display an shape in ventral view, with pronounced lateral keels and a ventral ; their size increases gradually from anterior to posterior, reflecting a pattern of elongation optimized for extension. This morphology contrasts with the more compact dorsal centra, which have higher neural spines and broader transverse processes for enhanced rigidity. Across species, variations occur; for instance, S. rezaci exhibits slightly fewer cervical vertebrae (60-63), as documented in a 2023 specimen from the of , suggesting subtle evolutionary differences within the genus.

Limbs and girdles

The pectoral girdle of Styxosaurus features broad scapulae and enlarged coracoids that articulate to form a robust, diamond-shaped bony plate, providing for the large foreflippers essential for aquatic . In specimens such as AMNH 5835 (S. browni), the coracoids display a cordiform (heart-shaped) between them and a narrow for articulation with the , while the overall lacks a continuous pectoral bar typical of more basal plesiosaurs. This configuration enhances stability during underwater maneuvers by distributing forces across the broadened chest region. The pelvic girdle is comparatively smaller and more compact than the pectoral girdle, with the and pubes fused along the midline to form a stable ventral plate that anchors the hindflippers. In AMNH 1495 (Styxosaurus sp.), the right ilium exhibits a distinctive triangular outline, and the is as long as it is broad, contributing to a reinforced for femoral attachment. These elements collectively provide a firm base for the rear limbs, aiding in balance and thrust generation without the expansive breadth seen anteriorly. Limb elements in Styxosaurus are highly specialized into hydrofoil-like flippers, characterized by hyperphalangy with 12–14 phalanges per , far exceeding the ancestral condition and allowing for elongated, flexible paddles that optimize hydrodynamic efficiency through increased surface area and streamlined between digits. The is elongated and sigmoidal in shape with an expanded postaxial margin, as observed in AMNH 5835, facilitating powerful extension during swimming strokes; the , preserved in AMNH 1495, possesses a straight shaft and broadened distal facets for robust with the and . Proximal elements like the , , , and are flattened and interlocking, forming a rigid yet lightweight structure that interlocks with spool-shaped, dorsoventrally compressed phalanges to create an profile for and reduced in water. Specimen SDSMT 451, a nearly complete Styxosaurus individual from the Pierre Shale, reveals particularly robust propodials ( and ) indicative of strong muscular attachments for forceful paddling motions, underscoring adaptations for sustained open-ocean . These limb features align with the overall elongated body proportions of elasmosaurids, emphasizing appendicular specialization for over terrestrial capabilities.

Systematics

Etymology and nomenclature

The genus name Styxosaurus was coined by Samuel P. Welles in 1943, combining "Styx," the name of the river in that forms the boundary between the world of the living and the underworld of , with the Greek term sauros meaning "lizard" or "reptile." This nomenclature was selected to capture the eerie, otherworldly appearance of the animal's exceptionally long neck, with the type specimen having been discovered near Hell Creek in Logan County, Kansas—a location evoking infernal imagery consistent with the mythological reference. The , S. snowii, honors Francis H. Snow, the professor of at the who facilitated the initial study of the specimen, originally described as Cimoliosaurus snowii by Samuel W. Williston in 1890 and later referred to snowii by Williston in 1906. A second species, S. browni, was named by Welles in 1952 in recognition of the paleontologist , who collected the specimen (AMNH 5835) from the Sharon Springs Member of the Pierre in . More recently, S. rezaci was designated in for a specimen from the Graneros in , honoring the Rezac family, local landowners on whose property the was discovered in 1964 and subsequently donated to science. Nomenclaturally, the of S. snowii (KUVP 1301) was reclassified by Welles (), who erected Styxosaurus as a distinct genus based on diagnostic vertebral and cranial differences from the Elasmosaurus platyurus.

Phylogenetic relationships

Styxosaurus is classified within the family Elasmosauridae, a monophyletic of plesiosauroids characterized by elongated necks and comprising a significant portion of marine reptile diversity. Phylogenetic analyses, including those utilizing extensive character matrices, consistently position Styxosaurus as a derived elasmosaurid, often nested within the subfamily Styxosaurinae alongside genera such as Terminonatator, , and . This placement reflects its adaptation for extreme neck elongation, a hallmark of advanced elasmosaurids evolving from earlier plesiosauroids near the Triassic-Jurassic boundary. In most cladistic frameworks, Styxosaurus forms a to , supported by shared synapomorphies including an extreme number of exceeding 70 and a proportionally reduced size relative to the , which enhance maneuverability in environments. These traits distinguish Styxosaurinae from basal elasmosaurids and underscore the iterative of neck length within the family, as initially outlined in early matrices. For instance, Styxosaurus snowii exhibits approximately 66-72 cervicals, while related taxa push this beyond 72. At the species level, S. snowii and S. browni represent North American endemics primarily from deposits of the , forming a tightly knit within Styxosaurinae with high bootstrap support (around 81-87%). A 2023 analysis reassigns Cenomanian material to S. rezaci, positioning it as the basalmost species and evidencing a divergence within the genus during the early , extending the lineage's temporal range by over 10 million years. Broader phylogenetic context situates Styxosaurus as part of the elasmosaurid radiation, a diverse assemblage potentially monophyletic with moderate support (67% bootstrap), highlighting regional and temporal succession in n plesiosaur evolution.

Paleobiology

Habitat and distribution

Styxosaurus inhabited the , an epicontinental sea that divided during the , spanning from the to the stages approximately 100.5 to 72.1 million years ago. The genus includes species such as S. rezaci from the early (around 100.5–93.9 million years ago) and S. snowii from the early (approximately 83.6–80 million years ago). Fossils of Styxosaurus are primarily known from the central and and , within the , with key specimens recovered from in the Niobrara Chalk Formation (Smoky Hill Chalk Member), in the Pierre Shale (including the Sharon Springs Member), and in the Graneros Shale and Codell Sandstone. These deposits represent marine environments across a broad latitudinal extent of the seaway, from subtropical to temperate zones. The of Styxosaurus was tied to the warm, shallow waters of the , where surface temperatures ranged from 20–30°C, supporting a highly productive driven by nutrient along the seaway's margins. This featured diverse and vertebrate assemblages, including ammonites and early mosasaurs, indicative of open marine conditions with periodic oxygenation variations. Taphonomic evidence suggests that Styxosaurus fossils were typically deposited in offshore settings, preserved in chalky limestones and organic-rich shales that reflect low-energy, sedimentation away from coastal influences. Many specimens exhibit mediolateral due to sediment compaction, but some retain articulated skeletal elements, pointing to rapid burial in fine-grained, calcareous deposits.

Diet and feeding ecology

Styxosaurus was primarily a piscivorous predator, targeting small schooling fish in the Late Cretaceous Western Interior Seaway. Stomach contents preserved in the abdominal region of the specimen NJSM 15435, a nearly complete Styxosaurus from the Sharon Springs Member of the Pierre Shale (middle Campanian, Kansas), include fragmented remains of Enchodus and small clupeomorph fishes measuring 35–45 cm in length, based on vertebral dimensions of approximately 8 mm long and 6 mm in diameter. These fish bones show signs of mechanical breakdown and partial digestion, with some adhering directly to associated gastroliths, confirming active processing of vertebrate prey shortly before death. Dental morphology further supports a diet incorporating soft-bodied cephalopods, such as and belemnites, alongside . The interlocking, needle-like teeth of Styxosaurus, lacking serrations or robust crowns, were adapted for grasping and piercing elusive, soft prey rather than crushing hard-shelled organisms, allowing whole or partial swallowing of items up to 45–60 cm long. This is corroborated by general elasmosaurid evidence, including isolated tooth punctures on belemnite guards and coprolites from related plesiosauroids containing scales, bones, and cephalopod fragments, indicating opportunistic feeding on abundant mid-water prey. A single (Squalicorax cf. S. pristodontus) in the NJSM 15435 gut contents may represent scavenging rather than active predation. Gastroliths played a key role in , functioning as a to grind ingested material. The specimen SDSMT 451, a well-preserved Styxosaurus snowii from the same formation in , contained 253 such stones (totaling several kilograms) in its abdominal cavity, primarily composed of sourced from distant river systems. Similarly, NJSM 15435 preserved 95 gastroliths (6.8 kg total, largest measuring 15.1 × 8.5 × 5.7 cm), with adhered fragments demonstrating their role in pulverizing bones and scales for nutrient extraction. Feeding likely involved ambush tactics, leveraging the elongated neck—up to 5.25 m in length—for rapid lateral strikes on prey schools while the body remained stationary to minimize detection. The small skull and grasping dentition suited this strategy, targeting mid-water niches with small pelagic vertebrates and invertebrates to avoid overlap with apex predators like mosasaurs. Stable carbon isotope (δ¹³C) analyses of elasmosaur tooth enamel from comparable Late Cretaceous settings yield values around -8 to -10‰, signaling offshore foraging in stratified, open-marine waters where prey resources were abundant but vertically partitioned. This mid-trophic position is reinforced by δ¹⁵N values of approximately 11‰ in Pierre Shale plesiosaurs, consistent with a diet 2–3 trophic levels above primary producers.

Locomotion and life history

Styxosaurus, like other elasmosaurids, employed a four-flipper style akin to underwater flight, with all limbs functioning as hydrofoils to generate and for . Pectoral flippers likely dominated the propulsive effort due to their larger size relative to the pelvics, while the elongated facilitated steering and maneuvering in three dimensions during cruising. Estimated sustained speeds ranged from 5 to 10 km/h, enabling efficient travel across open environments. control was aided by lightweight, porous limb bones that reduced overall density, allowing without excessive energy expenditure on depth regulation. Growth in Styxosaurus followed an ontogenetic trajectory typical of elasmosaurids, with juveniles reaching approximately 3 m in total length and adults attaining 10–12 m. Histological analyses of long s reveal rapid early rates, characterized by fibrolamellar with high vascularity, indicative of accelerated somatic development in juveniles to achieve large body sizes quickly. likely occurred at subadult sizes around 7–8 m, based on allometric changes in vertebral proportions and fusion patterns observed in elasmosaurid series. Inferred behaviors suggest Styxosaurus lived solitarily or in small groups, consistent with the ecology of other large marine reptiles that foraged independently over vast seaways. Viviparity is probable, drawing from direct fossil evidence of embryonic development in related plesiosaurs, implying live birth without returning to land. Seasonal migrations along coastal seaways for breeding may have occurred, analogous to patterns in modern marine megafauna, though direct evidence remains elusive. Predation risks were significant, particularly from mosasaurs, with healed bite marks on plesiosaur propodials indicating defensive interactions possibly involving neck thrashing to deter attackers.

References

  1. [1]
    Sea Monster Pictures, Styxosaurus Photos, Facts, Animals Reports ...
    Styxosaurus was an elasmosaur, a long-necked marine reptile, growing up to 40 feet long. It had long, pointed teeth and used flipper-like paddles to move.
  2. [2]
    Taxonomic reassessment of Hydralmosaurus as Styxosaurus
    Mar 15, 2016 · Description of plesiosaurs (Reptilia: Sauropterygia) from the Bearpaw Formation (Campanian—Maastrichtian) and a phylogenetic analysis of the ...
  3. [3]
    Occurrence of Styxosaurus (Sauropterygia: Plesiosauria) in the ...
    Aug 23, 2023 · We conclude that the genus Styxosaurus was a long-lived clade that inhabited the Western Interior Seaway for at least 12 million years.
  4. [4]
    Styxosaurus - Oceans of Kansas Paleontology
    Sep 23, 2000 · Styxosaurus snowii is a 36-foot long elasmosaur, the most complete one found, that ate small fish whole, and had a neck about half its body ...
  5. [5]
    Styxosaurus snowii, an iconic Late Cretaceous plesiosaur​
    KUVP 1301 was found in the upper section of the Smoky Hill Chalk Member of the lowermost Campanian (Late Cretaceous) Niobrara Formation (Williston 1906, Sachs ...Missing: date | Show results with:date
  6. [6]
    https://doi.org/10.1080/03115518.2018.1508613
  7. [7]
    Williston 1890 - Oceans of Kansas Paleontology
    Jan 15, 2003 · Wherein, S.W. Williston describes, for the first time, an intact skull of an American plesiosaur (Styxosaurus snowii, KUVP 1301, currently in ...
  8. [8]
    [PDF] Revision of the Genus Styxosaurus and Relationships of the Late ...
    May 20, 2020 · 'Cimoliosaurus' snowii by Williston (1890), he reported a complete skull of the animal and the first 28 cervical vertebrae. The skull of ...
  9. [9]
    Catalog Record: Elasmosaurid plesiosaurs with description of...
    Elasmosaurid plesiosaurs with description of new material from California and Colorado, by Samuel Paul Welles. ; Published: Berkeley, University of California ...Missing: Styxosaurus pdf
  10. [10]
    Taxonomic reassessment of Hydralmosaurus as Styxosaurus: new insights on the elasmosaurid neck evolution throughout the Cretaceous
    ### Summary of Key Points
  11. [11]
    https://peerj.com/articles/1777/
  12. [12]
    https://doi.org/10.1080/14772019.2023.2242846
  13. [13]
    Where Elasmosaurs Roam - Oceans of Kansas Paleontology
    Sep 18, 2009 · Although plesiosaurs have five 'fingers', they exhibit a condition called hyperphalangy ... However, a nearly complete specimen of Styxosaurus ...
  14. [14]
    https://doi.org/10.7717/peerj.1777
  15. [15]
    https://mds.marshall.edu/etd/1335
  16. [16]
    https://artsandculture.google.com/asset/styxosaurus-canadian-fossil-discovery-centre/mwEVi-NMJX5tgg?hl=en
  17. [17]
    https://pubs.usgs.gov/pp/1561/report.pdf
  18. [18]
    [PDF] Paleogeography and the Late Cretaceous of the Western Interior of ...
    This paper by Laura N. Robinson Roberts and Mark A. Kirschbaum discusses paleogeography of the Late Cretaceous of the western interior of middle North America, ...
  19. [19]
    Reconstructing paleoenvironments of the Late Cretaceous Western ...
    Jul 12, 2024 · (20–30 °C), which may have been adapted to mid-to-lower water column and nektobenthic habitats (Landman et al., 2018a; Tsujita and Westermann, ...
  20. [20]
    Productivity-induced redox transition within the Niobrara formation ...
    The transition from oxic to anoxic conditions coincides with greater enrichments in TOC, Cu and Ni, suggesting enhanced productivity is associated with redox ...
  21. [21]
    [PDF] PLESIOSAURIA) IN THE NIOBRARA CHALK OF WESTERN KANSAS
    Sternberg discovered two additional, partial specimens in the ... The skull of the type specimen of Styxosaurus snowii (KUVP 1301) in right lateral view.Missing: George 1885
  22. [22]
    An Elasmosaur with Stomach Contents and Gastroliths from the ...
    Sep 22, 2025 · The diet of elasmosauroids and pliosauroids is evidenced by rare fossil stomach contents and the body cavity of some specimens also contains ...
  23. [23]
    Tooth morphology and prey preference of Mesozoic marine reptiles
    Tooth morphology and prey preference of Mesozoic marine reptiles. Judy A. Massare Department of Geological Sciences , University of Rochester , Rochester, New ...
  24. [24]
    Reassessment of the Styxosaurus snowii (Williston, 1890) holotype ...
    The holotype (KUVP 1301) of Styxosaurus snowii—one of the earliest described elasmosaurid plesiosaurians—consists of a well-preserved cranium, mandible and ...
  25. [25]
    Stable isotopes, niche partitioning and the paucity of elasmosaur ...
    Jun 30, 2016 · The δ13C signal is a proxy for foraging area, trophic level and diving behaviour, the net value of which in these rare elasmosaurs turns out to ...
  26. [26]
    Assessment of trophic structure of Cretaceous communities based ...
    Jun 2, 2017 · Stable carbon and nitrogen isotope analyses were performed on high molecular weight organic material isolated from 22 taxa of Late Cretaceous ...
  27. [27]
    The four-flipper swimming method of plesiosaurs enabled efficient ...
    Aug 30, 2017 · We show that plesiosaur hind flippers generated up to 60% more thrust and 40% higher efficiency when operating in harmony with their forward counterparts.
  28. [28]
    Rethinking the four-wing problem in plesiosaur swimming using bio ...
    Oct 28, 2024 · As many extant quadrupeds exhibit variable gait patterns by varying their locomotor frequency to achieve fast and energy-efficient locomotion ...Missing: elasmosaurid | Show results with:elasmosaurid
  29. [29]
    Swimming capabilities of Mesozoic marine reptiles
    Calculated sustained swimming speeds range from 1.8 to 2.7 m/sec, but are probably too high by as much as a factor of two. Mesozoic marine reptiles were ...
  30. [30]
    [PDF] Gross internal structure and microstructure of plesiosaur limb bones ...
    Very light bones occur in ani- mals that live in the open sea and use rapid and sustained swimming. Their bones are very porous, because com- pact bone is ...Missing: lightweight | Show results with:lightweight
  31. [31]
    [PDF] MORPHOLOGIC AND ONTOGENETIC PATTERNS IN ...
    Indeed, there is some debate as to the correct number of cervicals in. Styxosaurus, with Carpenter (1999) counting 62 in both specimens while Welles counted 63 ...
  32. [32]
    Quantitative histological models suggest endothermy in plesiosaurs
    Jun 6, 2018 · Our models reveal bone growth rates and RMRs for plesiosaurs that are in the range of birds, suggesting that plesiosaurs were endotherm.
  33. [33]
    Prediction confirmed: plesiosaurs were viviparous | Scientific American
    Aug 12, 2011 · latipinnus, was preserved with some of its bones tightly adhering to the inside surface of the mother's pelvis, lacks signs of maceration or ...
  34. [34]
    Mosasaur bite marks on a plesiosaur propodial from the Campanian ...
    The discovery of deeply incised scars on a limb bone of an immature polycotylid plesiosaur from the latest early Campanian (in the European two-fold division ...Missing: elasmosaurus | Show results with:elasmosaurus