Fact-checked by Grok 2 weeks ago

Ophthalmosaurus

Ophthalmosaurus is an extinct genus of ophthalmosaurid ichthyosaur, a group of streamlined marine reptiles that superficially resembled dolphins, known from the Middle to Late Jurassic periods approximately 165 to 145 million years ago.^[1] Named for its disproportionately large eyes—reaching diameters of up to 23 cm, among the largest recorded in any vertebrate—this medium-sized predator measured about 4 meters in length and weighed roughly 950 kg.^[2]^[3]^[4] The genus is characterized by features such as three distal facets on the humerus, a ventral notch on the basioccipital bone, and a concave extracondylar area, adaptations suited to its aquatic lifestyle in ancient epicontinental seas.^[1] The type species, O. icenicus, was first described by Harry Govier Seeley in 1874 based on specimens from the Oxford Clay Formation in England, with abundant fossils also recovered from the Kimmeridge Clay Formation (England) and the Sundance Formation (United States).^[1] Other species include O. natans from North America, though taxonomic revisions have restricted the genus to the Callovian through possibly Berriasian stages, excluding later Cretaceous records previously attributed to it.^[1] Ophthalmosaurus likely inhabited warm, shallow marine environments across Laurasia, preying primarily on soft-bodied cephalopods like squid, as evidenced by gastric contents containing coleoid hooklets from O. natans specimens,^[5] supplemented by fish in its mixed diet.^[1] The genus went extinct by the Early Cretaceous, though the broader Ophthalmosauridae family persisted until the Cenomanian stage, succumbing to the Late Cretaceous marine reptile decline.^[1]

Description

Body plan

Ophthalmosaurus exhibited a streamlined, torpedo-shaped body that facilitated rapid and efficient movement through ancient marine environments. This form, typical of derived ichthyosaurs, measured approximately 3.5 to 4 meters in total length and weighed around 940 kg, enabling a balance between speed and maneuverability without excessive bulk.^[6] The skeletal structure emphasized hydrodynamic efficiency, with a fusiform profile that minimized drag during propulsion.^[7] The vertebral column comprised approximately 100 centra, displaying regional differentiation that supported distinct functional zones along the body axis. The cervical region included about 9 to 13 short centra for neck flexibility, transitioning into a dorsal section of 26 to 35 centra that formed a relatively rigid trunk for stability. Caudal vertebrae further divided into a tail stock of 30 to 45 centra for power generation and numerous smaller fluke centra exceeding 28 in preserved specimens, contributing to the overall elongated posterior. This segmentation allowed for coordinated undulation while maintaining structural integrity during swimming.^[8]^[7] The limbs were adapted as steering paddles rather than primary propulsors, with short, rounded forelimbs larger than the hind limbs and both exhibiting hyperphalangy— an excess of phalanges beyond the ancestral reptilian count—for enhanced surface area and flexibility. Propulsion relied primarily on a robust, bi-lobed caudal fluke with a straight trailing edge, which generated thrust through lateral oscillation of the compressed tail stock.^[9]^[8]^[10] Preserved skin impressions reveal a smooth, scaleless integument akin to that of modern cetaceans, promoting laminar flow over the body and reducing frictional resistance in water. This texture, devoid of scales and featuring supple, wrinkle-like patterns, supported the animal's fully aquatic lifestyle. Notably, the large eye size relative to body proportions further complemented these adaptations, aiding in low-light underwater navigation.^[10]

Skull and sensory adaptations

The skull of Ophthalmosaurus features a slender, elongated rostrum that comprises over half the total skull length, formed primarily by the premaxillae with extensive overlapping of the nasals and vomers creating a tubular structure suited for piercing through water.^[11] This rostrum houses small, conical teeth with pointed, slightly recurved crowns bearing fine longitudinal ridges and swollen, cementum-covered roots, numbering approximately 40 per upper jaw ramus and adapted for grasping rather than crushing prey.^[11] The teeth exhibit isodonty, with the largest reaching about 3.7 cm in length and decreasing in size anteriorly, emphasizing a design for securing soft-bodied or elusive marine organisms.^[11] The most striking feature is the massive orbits, which accommodate exceptionally large eyes measuring 22–23 cm in diameter, protected by a robust sclerotic ring composed of 14–15 ossicles that maintain structural integrity under pressure. These orbits occupy a significant portion of the posterior skull, with an orbital ratio (orbit diameter to jaw length) of approximately 0.28 in large specimens, indicating specialized visual adaptations for dimly lit underwater environments.^[11] The braincase further underscores this visual emphasis, featuring a large optic region with prominent impressions for optic lobes on the parietal and basisphenoid, while the olfactory bulbs appear reduced relative to the expanded visual processing areas, suggesting primary reliance on sight over smell for navigation and foraging.^[11] A single superior temporal fenestra, bounded by the squamosal, parietal, postfrontal, and prefrontal bones, contributes to the lightweight yet sturdy cranial architecture.^[11] The jaw articulation, involving a quadrate condyle with two elongate bosses and a central groove fitting into a concave articular surface on the surangular and articular, enables rapid closure for quick strikes, enhanced by the firmly embedded quadrate in a deep squamosal groove for stability.^[11]

Discovery and species

Historical discoveries

The genus Ophthalmosaurus was first established in 1874 by British paleontologist Harry Govier Seeley, who named it based on a partial skeleton from the Oxford Clay Formation near Peterborough, England, highlighting the exceptionally large sclerotic ring impressions suggestive of keen visual adaptations. Seeley designated the type species O. icenicus from this material, emphasizing features of the pectoral girdle and forelimb that distinguished it from contemporary ichthyosaurs like Ichthyosaurus. Throughout the late 19th century, additional fossils emerged from the Oxford Clay exposures in Cambridgeshire and the Peterborough brick pits, largely through collections by the Leeds brothers, Alfred and Charles. These specimens, including well-preserved skulls and vertebrae, were described in subsequent publications by Seeley in the 1880s, which expanded on the genus's skeletal morphology and confirmed its presence in the Callovian-Oxfordian stages of the Middle-Late Jurassic.^[12] Early taxonomic challenges arose as some fragments were initially confused with other ichthyosaurs, but these UK finds solidified Ophthalmosaurus as a key Jurassic marine reptile. In the 20th century, expeditions uncovered further material in continental Europe, including isolated elements from Jurassic deposits in Germany and the Volga region of Russia, though many were fragmentary and subject to later scrutiny.^[13] Canadian paleontologist Charles McGowan's reassessments in the 1970s, drawing on museum collections, provided critical revisions through detailed studies of the braincase and overall osteology, clarifying diagnostic traits and resolving ambiguities in prior identifications. The early 21st century brought new insights via partial skeletons from the Kimmeridge Clay Formation in southern England, excavated during the 2010s, which enabled analyses of ontogenetic growth series and refined species distinctions within the genus. Taxonomic hurdles persisted, with some Jurassic specimens previously misassigned to the Cretaceous genus Platypterygius undergoing revisions around 2012 that reaffirmed their placement in Ophthalmosaurus based on shared cranial and humeral features.^[14]

Valid species and synonyms

The type species of Ophthalmosaurus is O. icenicus Seeley, 1874, established on holotype specimen NHMUK PV R2133 from the Callovian Oxford Clay Formation near Peterborough, Cambridgeshire, England. This species is diagnosed by features including a large sclerotic ring enclosing an orbit up to 23 cm in diameter, a humerus with a posteriorly deflected ulnar facet, and a vertebral column comprising approximately 40 presacral and 60 postsacral elements.^[2] A second valid species, O. natans Marsh, 1879, is recognized from the Oxfordian Sundance Formation in Wyoming, USA, based on material including YPM 1529. It differs from O. icenicus in autapomorphies such as a more elongate humerus and reduced forefin hyperphalangy, though its generic assignment remains debated, with some analyses suggesting separation into a distinct genus like Baptanodon.^[15] Several taxa have been synonymized with Ophthalmosaurus icenicus. Ancanamunia Rusconi, 1942, originally from Argentine material, is considered a junior subjective synonym due to overlapping forefin and humeral morphology consistent with O. icenicus. Khudiakovia calloviensis Arkhangelsky, 1999, based on a partial skeleton from the Callovian of Russia, shares vertebral proportions and sclerotic ring size with O. icenicus and is similarly synonymized.^[16] Other proposed species within Ophthalmosaurus are invalid or reassigned. O. monocharactus and O. pleydelli are junior subjective synonyms of O. icenicus, lacking diagnostic traits beyond potential pathologies. O. chrisorum Russell, 1994, from the Upper Jurassic of Canada, was reassigned to the new genus Arthropterygius in cladistic analyses emphasizing distinct postcranial proportions, rendering it invalid under Ophthalmosaurus. Species delimitation in Ophthalmosaurus relies on cladistic criteria, including shared autapomorphies in skull and appendicular elements, while accounting for ontogenetic variation in ossification levels and potential geographic isolation between European and North American populations. Post-2010 phylogenetic studies, incorporating up to 150 characters, have refined these boundaries by resolving paraphyly risks in earlier classifications.^[15]

Taxonomy and classification

Placement within Ichthyosauria

Ophthalmosaurus is classified within the order Ichthyosauria de Blainville, 1835, specifically as a member of the clade Thunnosauria Motani, 1999, which encompasses advanced ichthyosaurs characterized by a streamlined body plan, including a dorsal fin and a heterocercal caudal fluke adapted for thunniform swimming.^[17] This placement reflects the evolutionary progression of ichthyosaurs toward more efficient aquatic locomotion during the Mesozoic era.^[3] Within Thunnosauria, Ophthalmosaurus belongs to the family Ophthalmosauridae Baur, 1887, a group defined by synapomorphies such as reduced forelimbs with three distal facets on the humerus, large orbits housing a prominent sclerotic ring for enhanced vision in deep-water environments, and a concave extracondylar area on the basioccipital bone.^[17] The family was established based on these distinctive cranial and postcranial features observed in Jurassic specimens, distinguishing ophthalmosaurids from earlier ichthyosaur lineages.^[18] Ophthalmosauridae further diversified into two subfamilies, with Ophthalmosaurus assigned to Ophthalmosaurinae Baur, 1887, which shares traits like tightly interlocking vertebral centra with posterolateral lamellae and a specialized sclerotic ring structure supporting the oversized eyes.^[17] This subfamily includes genera such as Acamptonectes, characterized by similar forelimb reductions and vertebral histology, while Platypterygius represents the sister subfamily Platypterygiinae.^[19] The evolutionary context of Ophthalmosaurus highlights the Late Jurassic radiation of ophthalmosaurids, which followed a Middle Jurassic diversification phase where basal forms like Mollesaurus emerged, leading to the dominance of this clade through the Jurassic-Cretaceous boundary.^[3] This radiation is marked by adaptations for pelagic lifestyles, including elongated rostra and reduced dorsal ribs, enabling ophthalmosaurids to occupy diverse marine niches until their decline in the Early Cretaceous.^[17]

Phylogenetic relationships

Phylogenetic analyses have positioned Ophthalmosaurus as a basal member of the subfamily Ophthalmosaurinae within the family Ophthalmosauridae. A key study by Fischer et al. (2012) utilized a character matrix of 14 taxa and 36 characters, recovering Ophthalmosaurus icenicus near the base of Ophthalmosaurinae, sister to a clade including more derived forms like Acamptonectes densus, supported by synapomorphies such as a large extracondylar area on the basioccipital and a plate-like dorsal trochanter on the femur.^[14] This analysis highlighted the early divergence of Ophthalmosauridae into Ophthalmosaurinae and Platypterygiinae during the Middle Jurassic, with Ophthalmosaurus exemplifying the former clade's persistence into the Late Jurassic.^[14] Sister taxa to Ophthalmosaurus include Mollesaurus periallus from the Early Bajocian of Argentina, identified as its closest relative in preliminary cladistic analyses based on shared features like an elongated rostrum and a large sclerotic ring relative to orbit size. These synapomorphies suggest close evolutionary affinities, with Mollesaurus also exhibiting a narrow temporal fenestra and reduced dentition, traits consistent with basal ophthalmosaurine morphology. Within Ophthalmosauridae, recent updates from the 2020s refine Ophthalmosaurus' position as closer to Acamptonectes than to Platypterygius, based on expanded matrices incorporating cranial and postcranial characters. Zverkov and Jacobs (2020) analyzed 44 taxa with 134 characters, placing Ophthalmosaurus in a polytomy with Acamptonectes and basal forms like Nannopterygius, distinguished from the more derived, short-snouted Platypterygius by features such as a proportionally longer premaxilla and narrower humeral facets.^[20] The description of Thalassodraco etchesi in 2020 has influenced tree topology, reinforcing a European-North American clade encompassing Ophthalmosaurus, Acamptonectes, and Thalassodraco, supported by shared narial complex morphology and vertebral counts in a matrix of 34 taxa and 112 characters.^[21] This clade emerges as basal to more southern hemisphere ophthalmosaurids, indicating transatlantic dispersal during the Late Jurassic.^[21] Debates persist regarding the monophyly of Ophthalmosaurinae, with some analyses suggesting paraphyly due to the unstable placement of Ophthalmosaurus natans relative to O. icenicus. For instance, Druckenmiller and Maxwell (2010) and subsequent studies found O. natans nesting outside core Ophthalmosaurinae, closer to Platypterygiinae, challenging the subfamily's integrity and prompting calls for taxonomic revision.^[22]

Distribution and paleoecology

Fossil sites and temporal range

Ophthalmosaurus fossils are primarily known from the Late Jurassic, spanning the late Callovian to early Tithonian stages, approximately 165 to 152 million years ago.^[14] This temporal range is well-documented in European deposits, with the earliest reliable records from the Callovian Oxford Clay Formation in England and the latest from the early Tithonian Kimmeridge Clay Formation in the same region.^[14] Questionable extensions into the Berriasian stage of the Early Cretaceous (around 145–140 Ma) have been reported from the Spilsby Sandstone in England and Prince Patrick Island in Canada, though these assignments remain debated due to fragmentary material and potential misidentification.^[14] The genus exhibits a predominantly Laurasian distribution, with major fossil sites concentrated in Europe and North America. In England, abundant specimens occur in the marine shales of the Oxford Clay (late Callovian to Oxfordian) and Kimmeridge Clay (Kimmeridgian to early Tithonian) Formations, particularly around Peterborough and Dorset.^[14] Continental European records include the Solnhofen Limestone (early Tithonian) in Bavaria, Germany, where ophthalmosaurid remains closely allied to Ophthalmosaurus have been recovered, and the Oxfordian–Kimmeridgian beds of the Volga Basin in European Russia, south of Syzran in the Samara region.^[23]^[24] North American occurrences are represented by the Oxfordian Redwater Shale Member of the Sundance Formation in Wyoming, USA, where specimens potentially attributable to O. natans have been found, and additional material from the Canadian Arctic. In Mexico, Tithonian material from the La Casita Formation in Coahuila was initially referred to Ophthalmosaurus but later described as the distinct genus Jabalisaurus meztli in 2021, underscoring the broader ophthalmosaurid presence across northern Gondwana margins.^[25]^[26] Most Ophthalmosaurus fossils derive from shallow marine shelf deposits, reflecting deposition in low-energy, epicontinental seaways with periodic anoxic conditions that favored preservation.^[27] Taphonomic evidence indicates that skeletons are typically disarticulated, with bones scattered by currents, scavenging, and bioerosion prior to burial, as seen in a well-studied ichthyosaur fall from the upper Oxfordian Sandsfoot Formation in Dorset, England.^[28] Articulated skeletons are rare, comprising only a small fraction of known specimens, likely due to the offshore shelf environment's exposure to post-mortem transport and decay.^[28]

Habitat and environment

Ophthalmosaurus primarily inhabited epicontinental seas of the Anglo-Paris Basin during the Late Jurassic, where sedimentary deposits such as the Oxford Clay and Kimmeridge Clay formations indicate warm, shallow marine environments with water depths of approximately 50–200 meters.^[16]^[19] These settings were characterized by productive, nutrient-rich waters supporting diverse marine life, as evidenced by the co-occurrence of Ophthalmosaurus fossils with plesiosaurs such as Liopleurodon, alongside abundant ammonites and belemnites that point to a thriving pelagic ecosystem.^[19] The climatic conditions in these Laurasian seaways were humid and subtropical, with oxygen isotope analyses of oyster shells from the Paris Basin revealing sea surface temperatures averaging around 24°C, fluctuating between approximately 20°C and 25°C across the Oxfordian to Early Kimmeridgian stages.^[29] Seasonal variations of about 5°C in these shallow waters further suggest a stable, greenhouse-like climate conducive to the survival of warm-adapted marine reptiles.^[29] Fossil evidence supports potential migration patterns for Ophthalmosaurus between European and North American seaways, facilitated by the Viking Corridor—an epicontinental pathway connecting the Tethys Ocean to the Boreal Sea during the Late Jurassic. While the genus shows strong northern hemisphere dominance, with major occurrences in the UK, Germany, and western North America, records from the southern hemisphere remain sparse and largely limited to indeterminate ophthalmosaurids, highlighting a biogeographic bias toward Laurasian habitats; as of 2025, no additional major sites or species have been described.^[21]^[30]

Paleobiology

Feeding and diet

Ophthalmosaurus exhibited a specialized piscivorous and carnivorous diet, primarily consisting of soft-bodied cephalopods such as coleoids, with opportunistic consumption of fish.^[31]^[32] Stomach contents preserved in specimens of O. natans from the Sundance Formation reveal fragmented coleoid cephalopod hooklets cemented in calcite, indicating these prey items were ingested whole or in large pieces without extensive processing.^[33] Gut contents in Ophthalmosaurus comprise soft, unshelled coleoid remains, though the broader Ophthalmosauridae shows dietary diversity including harder prey in some taxa.^[31] The dentition of Ophthalmosaurus supported this feeding strategy, featuring numerous small, conical teeth with crowns measuring 10–12 mm in height and 5–7 mm in basal diameter, adapted for piercing and grasping slippery, soft-bodied prey.^[16] These teeth, characterized by smooth, slender, recurved crowns lacking wear facets, were loosely attached to the jaws and unlikely to handle large or hard prey, aligning with the observed stomach contents.^[31] The slender rostrum and jaw structure facilitated a wide gape sufficient to engulf cephalopods and small fish, emphasizing rapid capture over powerful crushing.^[34] As an ambush predator, Ophthalmosaurus likely relied on its exceptionally large eyes—adapted for enhanced vision in low-light deep-water environments—to detect and target elusive prey like schooling fish or drifting cephalopods.^[2] This visual acuity complemented its streamlined body for short bursts of speed during strikes. Ontogenetic shifts in diet may have occurred, with juveniles potentially specializing in smaller planktonic prey before transitioning to larger cephalopods as adults.

Locomotion and behavior

Ophthalmosaurus utilized thunniform swimming, characterized by lateral oscillation of a lunate caudal fluke as the primary propulsor, with minimal involvement of the body trunk and stabilized anterior regions for hydrodynamic efficiency.^[35] This style was facilitated by a fusiform body plan, compressed caudal peduncle, and vertebral adaptations such as wedge-shaped centra at the tail bend, enabling sustained cruising through reduced drag and optimized thrust generation.^[36] Estimated cruising speeds, derived from body proportions and vertebral morphology, reached approximately 2.5 m/s (9 km/h), comparable to modern thunniform swimmers like tuna, though burst speeds may have been higher during pursuits.^[37] The species exhibited adaptations for deep diving, with bone microstructure revealing a spongious internal organization in long bones like the humerus, lacking a true medullary cavity and featuring high compactness (around 77%) for neutral buoyancy control via gas-filled lungs.^[38] This pachyosteosclerotic-like condition supported dives to depths exceeding 600 m, as inferred from the disproportionately large eyes (up to 23 cm in diameter) protected by sclerotic rings, which enhanced sensitivity in low-light conditions and countered pressure at depth. Reproduction in Ophthalmosaurus likely involved viviparity, as evidenced by fossil embryos associated with adult ophthalmosaurids such as Platypterygius and Acamptonectes, indicating live birth in water without needing to return to land. This strategy, widespread among ichthyosaurs, allowed females to carry multiple offspring (typically 2–5) to term, with tail-first birth orientations preserved in related taxa to prevent drowning. Mass mortality assemblages of ophthalmosaurids, including 46 individuals in a single Early Cretaceous site, suggest gregarious behavior and possible schooling at the family level, where groups may have traveled together for protection or migration before catastrophic events like storms or oxygen depletion.^[39] Sensory capabilities emphasized vision, with enlarged optic lobes and massive eyeballs enabling detection in dim, deep-sea environments, supplemented by a lateral line system along the body for sensing water movements and navigating turbid coastal waters.^[40]

References

[1]
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3250416/
[2]
My, what big eyes you have . . - PMC - NIH
Ichthyosaurs had the largest eyes ever known, with Temnodontosaurus reaching 264mm and Ophthalmosaurus 230mm, larger than footballs.
[3]
A large new Middle Jurassic ichthyosaur shows the importance of ...
Mar 16, 2024 · Ophthalmosaurus icenicus is smaller, at only 4 m estimated length [16]. Argovisaurus is therefore large compared to other Middle Jurassic taxa ...
[4]
ICHTHYOSAUR SIZE / WEIGHT - Earth Science Australia
Stenopterygius sp. 2.40, 163-168. Ophthalmosaurus icenicus, 4.0, 930-950. Some larger ichthyosaurs were surely much heavier, but it is difficult to ...
[5]
(PDF) Vertebral morphology of Ophthalmosaurus natans (Reptilia
Feb 25, 2015 · Although similar in body portions and count to the European species O. icenicus, shape differences in the vertebrae of the posterior trunk and ...Missing: plan | Show results with:plan
[6]
[PDF] Swimming Styles in Jurassic Ichthyosaurs
in life. The vertebral column is composed of 44 precaudal, 45 tail stock, and 98 fluke vertebrae, for a total count ...
[7]
Microanatomy and histology of the distal limb elements of ...
In this study, we describe and interpret the microstructure of distal limb elements of six specimens of ichthyosaur, five ophthalmosaurids and one non- ...Missing: anatomy | Show results with:anatomy
[8]
A review of ichthyosaur (Reptilia, Ichthyopterygia) soft tissues with ...
We present a review of ichthyosaur research and life style iconography with particular focus on soft-tissue structures and inferences made from these.Missing: plan | Show results with:plan
[9]
None
Below is a merged summary of the Ophthalmosaurus skull features based on all provided segments. To retain all details efficiently and densely, I will use a table in CSV format for the key features, followed by a narrative summary for additional context and information not easily tabularized. This approach ensures comprehensive coverage while maintaining clarity and organization.
[10]
[PDF] the alfred leeds fossil vertebrate collection of the national
Discussion. The genus Ophthalmosaurus is characterised by a flared proximal end of its scapula (Maisch and. Matzke 2000) and in the morphology of the humerus.
[11]
On the First Reliable Record of the Ichthyosaur Ophthalmosaurus ...
Mar 10, 2018 · An incomplete skeleton of the ichthyosaur Ophthalmosaurus icenicus Seeley, 1874 excavated in the Oxfordian–Kimmeridgian beds south of the town ...Missing: key facts
[12]
New Ophthalmosaurid Ichthyosaurs from the European Lower ...
... Ophthalmosaurus sp. and McGowan & Motani [2] mentioned the presence of isolated basioccipitals and humeri referable to Ophthalmosaurus in the early ...
[13]
New Ophthalmosaurid Ichthyosaurs from the European Lower ...
Jan 3, 2012 · Ophthalmosaurid ichthyosaurs remained diverse from their rapid radiation in the Middle Jurassic to their total extinction at the beginning of ...
[14]
Ichthyosaurs of the British Middle and Upper Jurassic. Part 1 ...
Aug 5, 2025 · Our model can explain normal joint morphology in wildtype limbs, hyperphalangy in cetacean flippers, mutant phenotypes with misoriented ...
[15]
https://pmc.ncbi.nlm.nih.gov/articles/PMC3250416/
[16]
redescription and phylogenetic position of caypullisaurus - jstor
BAUR, G. 1887. On the morphology and origin of the Ichthyopterygian. American Naturalist, 21:837-840. DE LA BECHE, H. T., ...
[17]
A new ophthalmosaurid ichthyosaur from the Upper Jurassic (Early ...
Dec 9, 2020 · It comprises a near complete skull in articulation with associated anterior vertebral column and dorsal ribs, complete pectoral girdle, fully ...
[18]
None
Nothing is retrieved...<|control11|><|separator|>
[19]
A new ophthalmosaurid ichthyosaur from the Upper Jurassic (Early ...
Dec 9, 2020 · It has an estimated orbital ratio (diameter of orbit/ length of ... A partially articulated sclerotic ring is present within the orbit.
[20]
The first ophthalmosaurid ichthyosaur from the Upper Jurassic of the ...
Jul 11, 2016 · Motani (1999) identified a short dorsal centrum length relative to the height as a diagnostic vertebral feature in Ophthalmosaurus icenicus; ...
[21]
A NEW ICHTHYOSAUR FROM THE UPPER JURASSIC ...
Two ichthyosaurian specimens from the Upper Jurassic lithographic limestones of Bavaria, namely an almost complete skeleton with soft tissue impression and ...
[22]
(PDF) On the First Reliable Record of the Ichthyosaur ...
Feb 16, 2018 · An incomplete skeleton of the ichthyosaur Ophthalmosaurus icenicus Seeley, 1874 excavated in the Oxfordian-Kimmeridgian beds south of the town ...Missing: key facts
[23]
Ichthyosauria) from the Tithonian (Upper Jurassic) of Mexico
Jul 14, 2015 · On the pectoral arch and fore limb of Ophthalmosaurus, a new ichthyosaurian genus from the Oxford Clay. ... Kimmeridge Clay of Dorset, UK ...
[24]
A new ophthalmosaurid (Ichthyosauria) from the Upper ...
Redescription of the Kimmeridgian ophthalmosaurid from Mexico. · Four diagnostic characters and a unique combination of characters allows the erection of ...
[25]
Ecological succession of a Jurassic shallow-water ichthyosaur fall
Sep 10, 2014 · In this paper, we report the first detailed study of ecological succession of a shallow-water ichthyosaur fall community from the Late Jurassic ...
[26]
(PDF) Climatic fluctuations and seasonality during the Late Jurassic ...
Aug 6, 2025 · Oxygen isotope data from biostratigraphically well-dated oyster shells from the Late Jurassic of the eastern Paris Basin are used to ...Missing: Anglo- | Show results with:Anglo-
[27]
(PDF) Ophthalmosaurian (Ichthyosauria) records from the Aalenian ...
Aug 6, 2025 · The oldest ophthalmosaurian records worldwide have been recovered from the Aalenian-Bajocian boundary of the Neuquen Basin in Central-West ...
[28]
Extinction of fish-shaped marine reptiles associated with reduced ...
Mar 8, 2016 · Two of them are ophthalmosaurines, with a large sclerotic aperture, and preserved gut content in one of them (Ophthalmosaurus natans) consists ...<|separator|>
[29]
Is the hyoid a constraint on innovation? A study in convergence ...
Mar 15, 2023 · Fossilized stomach contents show that cephalo- pods were a major food source but also that ichthyosaurs were opportunistic feeders, simi- lar to ...<|control11|><|separator|>
[30]
Gastric contents of an ichthyosaur from the Sundance Formation ...
The gastric material consists of badly fragmented coleoid cephalopod hooklets, loosely cemented by calcite crystals. The stomach contents are comparable to ...Missing: diet | Show results with:diet
[31]
The osteology and taxonomy of the fossil reptile Ophthalmosaurus
Aug 7, 2025 · Detailed examinations of two hitherto unknown collections of ophthalmosaurs have been made. Highly ossified specimens have been used to make a restoration of ...Missing: chrisssae | Show results with:chrisssae
[32]
Dietary niche partitioning in Early Jurassic ichthyosaurs from ...
Sep 29, 2022 · Further, ichthyosaurs evidently showed ontogenetic dietary partitioning, with some species at least switching from an exclusive diet of surface ...
[33]
Swimming styles in Jurassic ichthyosaurs | Request PDF
Aug 10, 2025 · Many of the distinctions between modes of swimming are dependent on lifestyle as well as morphology; carangiform, and carcharhiniform swimmers ...
[34]
Skeletal convergence in thunniform sharks, ichthyosaurs, whales ...
Oct 4, 2023 · Thunniform vertebrates represent an iconic example of evolutionary convergence in which body plan and swimming style of large cruising marine ...
[35]
Swimming speed estimation of extinct marine reptiles
Mar 3, 2017 · Stenopterygius, a thunniform ichthyosaur, was probably capable of cruising at a speed at least comparable to those reported for some extant ...
[36]
A New Look at Ichthyosaur Long Bone Microanatomy and Histology
Apr 21, 2014 · The present contribution discusses the histological and microanatomical variation observed within ichthyosaurs and the peculiarities of some taxa.
[37]
A Lower Cretaceous ichthyosaur graveyard in deep marine slope ...
Sep 1, 2014 · Remnants of ophthalmosaurid ichthyosaurs recently discovered in the vicinity of the Tyndall Glacier in the Torres del Paine National Park of southern Chile are ...
[38]
The skull and endocranium of a Lower Jurassic ichthyosaur based ...
Jun 15, 2015 · The contribution of the supra-temporal to the foramen magnum is much larger in the ophthalmosaurids Ophthalmosaurus and Platypterygius ...