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2023 in paleoichthyology

From Wikipedia, the free encyclopedia

List of years in paleoichthyology
In paleontology
2020
2021
2022
2023
2024
2025
2026
In paleobotany
2020
2021
2022
2023
2024
2025
2026
In arthropod paleontology
2020
2021
2022
2023
2024
2025
2026
In paleoentomology
2020
2021
2022
2023
2024
2025
2026
In paleomalacology
2020
2021
2022
2023
2024
2025
2026
In reptile paleontology
2020
2021
2022
2023
2024
2025
2026
In archosaur paleontology
2020
2021
2022
2023
2024
2025
2026
In mammal paleontology
2020
2021
2022
2023
2024
2025
2026

This list of fossil fish research presented in 2023 is a list of new fossil taxa of jawless vertebrates, placoderms, cartilaginous fishes, bony fishes, and other fishes that were described during the year, as well as other significant discoveries and events related to paleoichthyology that occurred in 2023.

Jawless vertebrates

[edit]
Name Novelty Status Authors Age Type locality Location Notes Images

Amaltheolepis terranovi[1]

Sp. nov

Valid

Blom et al.

Devonian (Emsian)

Shevchenkinskaya Formation

 Russia
( Arkhangelsk Oblast)

A member of Thelodonti belonging to the group Thelodontiformes and the family Turiniidae.

Caeruleum[2]

Gen. et sp. nov

Huang

Early Cretaceous

 China

A lamprey. The type species is C. miraculum.

Dayongaspis colubra[3]

Sp. nov

Valid

Zhang et al.

Silurian (Telychian)

Xiushan Formation

 China

A member of Galeaspida belonging to the family Dayongaspidae.

Foxaspis[4]

Gen. et sp. nov

Gai et al.

Devonian (Pragian)

Xiaoshan Formation

 China
(Guangxi)

A member of Galeaspida belonging to the group Polybranchiaspidiformes and the family Duyunolepididae. The type species is F. novemura.

Jiangxialepis rongi[5]

Sp. nov

Liu et al.

Silurian (Telychian)

Tataertag Formation

 China

A member of Galeaspida belonging to the family Shuyuidae.

Squirmarius[6]

Gen. et sp. nov

Valid

McCoy et al.

Carboniferous (Pennsylvanian)

Mazon Creek fossil beds

 United States
( Illinois)

A member of Cyclostomi. The type species is S. testai.

Xiyuichthys[7]

Nom. et sp. nov

Shan et al.

Silurian

Tataertag Formation

 China

A member of Galeaspida belonging to the family Xiushuiaspidae; a replacement name for Xiyuaspis Liu et al. (2019). Shan et al. (2023) also named a new species X. lixiensis from the Telychian Qingshui Formation (Jiangxi, China).

Yanliaomyzon[8]

Gen. 2 sp. nov

Wu, Janvier & Zhang

Jurassic (Callovian and Oxfordian)

Tiaojishan Formation

 China

A lamprey. The type species is Y. occisor; genus also includes Y. ingensdentes.

Jawless vertebrate research

[edit]
  • A study on the anatomy and affinities of Lasanius is published by Reeves et al. (2023), who interpret this vertebrate as a stem-cyclostome.[9]
  • Dearden et al. (2023) describe the cranial anatomy of Eriptychius americanus, provide evidence of the presence of a symmetrical set of cartilages interpreted as the preorbital neurocranium, and report that the studied cartilages filled out the head and closely supported the dermal skeleton (in that they were closer to the cranial anatomy of osteostracans and galeaspids than cyclostomes), but were not fused into a single unit around the brain (more closely resembling the cranial anatomy of cyclostomes than osteostracans, galeaspids and jawed vertebrates in that aspect).[10]
  • A study on the interaction of fluid flow with 2D models of heterostracan oral plate denticles is published by Grohganz et al. (2023), who interpret their findings as indicating that the studied denticles were not an adaptation to suspension feeding.[11]

Placoderms

[edit]
Name Novelty Status Authors Age Type locality Location Notes Images

Bothriolepis dairbhrensis[12]

Sp. nov

Valid

Dupret et al.

Devonian (Givetian)

Valentia Slate Formation

 Ireland

Chahuaqingolepis[13]

Gen. et sp. nov

Valid

Liu et al.

Devonian

Tanglishu Formation

 China

A member of the family Bothriolepididae. The type species is C. magniporus.

Dunkleosteus tuderensis[14]

Sp. nov

Lebedev in Lebedev et al.

Devonian (Famennian)

Bilovo Formation

 Russia
( Tver Oblast)

Sherbonaspis talimaae[15]

Sp. nov

Valid

Plax & Lukševičs

Devonian (probably Emsian)

Lepel Beds

 Belarus

A member of Asterolepidoidei belonging to the family Pterichthyodidae.

Valentinaspis[16]

Gen. et sp. nov

Valid

Plax & Newman

Devonian (Emsian)

 Belarus
 Estonia

A member of the family Arctolepididae. The type species is V. profundus.

Placoderm research

[edit]
  • Evidence from the study of the skull of Kolymaspis sibirica, interpreted as indicating that the sixth branchial arch was probably the one that was incorporated into the vertebrate shoulder girdle, is presented by Brazeau et al. (2023).[17]
  • Brazeau et al. (2023) describe a near-complete "acanthothoracid" upper jaw from the Devonian (Pragian) Yamaat Gol locality (Mongolia), and interpret this finding as indicating that the morphology and function of "acanthoracid" jaws resemble generalized "placoderm" conditions seen also in arthrodires and rhenanids.[18]
  • Redescription and a study on the affinities of Bothriolepis sinensis is published by Luo et al. (2023).[19]
  • Evidence of different patterns of phylogenetic and taxic diversity of Arthrodira throughout their evolutionary history is presented by Xue et al. (2023), who find evidence robust correlation between declines of phylogenetic diversity and significant global events during the Devonian, especially the late Givetian event, the Late Devonian extinction and the Hangenberg event.[20]
  • Engelman (2023) attempts to determine body size of Dunkleosteus terrelli, recovering the body lengths of between 3.1 and 3.5 m for typical adults and ~4.1 m for the largest individuals;[21] in a subsequent study the author reevaluates the methodology and length estimates used by Ferrón, Martinez-Perez & Botella (2017),[22] and argues that length estimates for Dunkleosteus based on the mouth dimensions of extant sharks are not reliable, as arthrodires have proportionally larger mouths than sharks.[23]
  • Cui et al. (2023) describe a near-complete post-thoracic exoskeleton of Entelognathus primordialis from the Silurian Kuanti Formation (China), reporting the presence of an anal fin spine in the studied specimen, previously known only in stem cartilaginous fishes, as well as striking similarities of the scales and squamation of the studied specimen to those of bony fishes, including the presence of rhomboid scales with the peg-and-socket articulation previously considered a synapomorphy of bony fishes.[24]

Cartilaginous fishes

[edit]
Name Novelty Status Authors Age Type locality Location Notes Images

Atlantobatis[25]

Gen. et sp. nov

Guinot et al.

Late Cretaceous

 Senegal

A batomorph elasmobranch. The type species is A. acrodonta.

Cavusodus[26]

Gen. et sp. nov

Valid

Itano

Carboniferous (late Viséan–early Serpukhovian)

 United States
( Alabama)

A member of Petalodontiformes belonging to the family Janassidae. The type species is C. whitei.

Corysodon multicristatus[27]

Sp. nov

Valid

Batchelor & Duffin

Early Cretaceous (Aptian)

Atherfield Clay Formation

 United Kingdom

A neoselachian shark.

Possibly a Carcharhiniforme.

Coupatezia casei[25]

Sp. nov

Guinot et al.

Late Cretaceous

 Senegal

A batomorph elasmobranch.

Crioselache[28]

Gen. et sp. nov

Valid

Pauliv et al.

Permian (Asselian)

Campo Mourão Formation

 Brazil

Possibly a member of the family Symmoriidae. The type species is C. wittigi.

‘Dasyatis’ reticulata[25]

Sp. nov

Guinot et al.

Late Cretaceous

 Senegal

A batomorph elasmobranch.

Dasyomyliobatis[29]

Gen. et sp. nov

Valid

Marramà et al.

Eocene (Ypresian)

Monte Bolca Lagerstätte

 Italy

A member of Myliobatiformes belonging to the new family Dasyomyliobatidae. The type species is D. thomyorkei.

Denaea patula[30]

Sp. nov

Ivanov in Ivanov, Alekseev & Nikolaeva

Carboniferous (Viséan)

 Russia

A member of Symmoriiformes.

Desinia[31]

Gen. et sp. nov

Valid

Ivanov in Ivanov et al.

Permian

 Russia
( Kirov Oblast
 Komi Republic
 Mari El
 Tatarstan)

A member of the family Sphenacanthidae. The type species is D. radiata. Published online in 2023, but the issue date is listed as December 2022.[31]

Fairchildodus[32]

Gen. et sp. nov

Chahud

Permian (Cisuralian)

Irati Formation

 Brazil

A member of Holocephali. The type species is F. rioclarensis.

Funicristata[33]

Gen. et sp. nov

Valid

Burrow in Burrow, Murphy & Turner

Silurian (Přidolí)

Roberts Mountains Formation

 United States
( Nevada)

An acanthodian of uncertain affinities. The type species is F. nevadaensis.

Hemipristis tanakai[34]

Sp. nov

Tomita, Yabumoto & Kuga

Oligocene

Yamaga Formation

 Japan

A species of Hemipristis.

Karpinskiprion[35]

Gen. et comb. nov

Valid

Lebedev & Itano in Lebedev et al.

Carboniferous

 Russia
( Moscow Oblast
 Volgograd Oblast)

A member of the family Helicoprionidae. The type species is "Helicoprion" ivanovi Karpinsky (1924).

Lissodus tumidoclavus[36]

Sp. nov

Valid

Duffin, Heckert & Hancox

Early Triassic

Burgersdorp Formation

 South Africa

A member of Hybodontoidea.

Luopingselache[37]

Gen. et sp. nov

Wen et al.

Middle Triassic (Anisian)

 China

A member of the family Lonchidiidae. Genus includes new species L. striata.

Maghriboselache[38] Gen. et sp. nov Klug et al. Late Devonian  Morocco A member of the family Cladoselachidae. The type species is M. mohamezanei.

Orcadacanthus[39]

Gen. et comb. nov

Valid

Newman et al.

Devonian

Orcadian Basin

 United Kingdom

A member of Acanthodiformes belonging to the family Mesacanthidae. The type species is "Acanthodes" pusillus Agassiz (1844).

Phosphatodon cretaceus[25]

Sp. nov

Guinot et al.

Late Cretaceous

 Senegal

A batomorph elasmobranch.

Physogaleus onkensis[40]

Sp. nov

Boulemia & Adnet

Paleogene

Kef Esnoun Formation

 Algeria

Ptychotrygon ameghinorum[41]

Sp. nov

Begat et al.

Late Cretaceous (Cenomanian)

Mata Amarilla Formation

 Argentina

Ptychotrygon nazeensis[25]

Sp. nov

Guinot et al.

Late Cretaceous

 Senegal

A batomorph elasmobranch.

‘Rhinobatos’ popenguinensis[25]

Sp. nov

Guinot et al.

Late Cretaceous

 Senegal

A batomorph elasmobranch.

Sowibatos[25]

Gen. et sp. nov

Guinot et al.

Late Cretaceous

 Senegal

A batomorph elasmobranch. The type species is S. minimus.

Squatinactis multicuspidatus[30]

Sp. nov

Ivanov in Ivanov, Alekseev & Nikolaeva

Carboniferous (Viséan)

 Russia

Strigilodus[42]

Gen. et sp. nov

Valid

Hodnett et al.

Carboniferous (Viséan)

Ste. Genevieve Formation

 United States
( Kentucky)

A member of Petalodontiformes belonging to the family Janassidae. The type species is S. tollesonae.

Strophodus atlasensis[43]

Sp. nov

Valid

Stumpf et al.

Middle Jurassic (Bajocian)

Agoudim Formation

 Morocco

A member of Hybodontiformes belonging to the family Hybodontidae and the subfamily Acrodontinae.

Sulcacanthus[44]

Gen. et sp. nov

Valid

Itano & Duffin

Carboniferous (Viséan)

St. Louis Formation

 United States
( Indiana)

A chimaera belonging to the group Squalorajoidei. The type species is S. schachti.

Terangabatis[25]

Gen. et sp. nov

Guinot et al.

Late Cretaceous

 Senegal

A batomorph elasmobranch. The type species is T. thiami.

Cartilaginous fish research

[edit]
  • Fossil material of members of the genera Pucapampella and Zamponiopteron is described from the Devonian (Eifelian) Chagrapi Formation by Zevallos-Valdivia et al. (2023), representing the first record of Paleozoic vertebrates from Peru reported to date.[45]
  • Burrow & Desbiens (2023) describe dental elements of Doliodus latispinosus from the Devonian York River Formation (Quebec, Canada), finding no justification for assigning the studied isolated dental elements to a species distinct from D. latispinosus from the Atholville beds (New Brunswick, Canada).[46]
  • A study on the musculoskeletal anatomy of Iniopera is published by Dearden, Herrel & Pradel (2023), who interpret the anatomy of Iniopera as unsuited to durophagy, and consider it to be likely a high-performance suction-feeder.[47]
  • Fossil material of members of at least seven species belonging to the genus Ptychodus is described from the ?Cenomanian–Santonian of the Malyy Prolom area (Ryazan Oblast, Russia) by Amadori et al. (2023), who also report the northernmost occurrence of Ptychodus in Europe from the Cenomanian of Varavinsky ravine area (Moscow Oblast, Russia), and interpret the studied fossils as indicating that Late Cretaceous epicontinental seas of the Russian platform were important areas of diversification and spread of Ptychodus.[48]
  • Amadori et al. (2023) report the discovery of teeth of various species belonging to the genus Ptychodus from the Cenomanian and Turonian deposits of Ukraine, including teeth of cuspidate (P. altior) and un-cuspidate species (P. decurrens, P. latissimus, P. marginalis and P. polygyrus), and argue that the availability of diverse shelled invertebrates in epicontinental seas might have favored the diversification of Ptychodus.[49]
  • Ghosh et al. (2023) report the discovery of a new assemblage of lamniform shark teeth from the Aptian Habur Formation (India), including teeth of Dwardius and possibly of Eostriatolamia which may be some of the globally oldest record of these taxa.[50]
  • A study on the teeth of Megachasma applegatei is published by Krak & Shimada (2023), who find that the range of the morphometric variation of teeth of M. applegatei is larger than that of teeth of extant megamouth shark, with different tooth types corresponding to tooth types present in the smalltooth sand tiger.[51]
  • Shimada et al. (2023) describe tessellated calcified cartilage and placoid scale associated with a tooth set of Otodus megalodon from the Miocene strata in Japan, and interpret the morphology of the studied material as indicating that O. megalodon was generally a slow cruising shark.[52]
  • A study on the thermoregulation in Otodus megalodon is published by Griffiths et al. (2023), who argue that O. megalodon had an overall warmer body temperature compared with other coexisting shark species, and that its large body size coupled with high metabolic costs associated with having at least partial endothermy might have made it vulnerable to extinction.[53]
  • Collareta, Casati & Di Cencio (2023) describe new fossil material of Parotodus benedenii from the Valdelsa Basin (Italy), providing evidence of the survival of the species at least until the Late Pliocene, and interpret P. benedenii as a large-bodied carnivorous shark living in pelagic settings.[54]
  • Collareta et al. (2023) report the discovery of teeth of Alopias grandis from the Miocene deposits in southern Italy, possibly including the geologically youngest record of the species and extending its known geographic range.[55]
  • Villafaña et al. (2023) describe fossil material of the common thresher and the porbeagle from the Bahía Inglesa Formation (Caldera Basin, Chile), confirming the abundance of lamniform sharks in the Eastern Pacific of South America during the Neogene.[56]
  • Ehret et al. (2023) provisionally refer the species Cosmopolitodus planus/Isurus planus to the genus Carcharodon, and describe fossil material of C. planus and Carcharodon hubbelli from Miocene deposits in the South Island, representing the first records of both species from New Zealand reported to date.[57]
  • A study on the anatomy and affinities of Protospinax annectans, based on data from both known and previously undescribed specimens from the Tithonian Altmühltal Formation (Germany), is published by Jambura et al. (2023).[58]
  • Ferrón (2023) argues that, although representatives of most squalomorph groups colonized deep waters independently during the Late Jurassic and Early Cretaceous, bioluminescence evolved only once among sharks in a bathydemersal ancestor.[59]
  • A fossil egg case containing a well-preserved batoid (possibly stem-myliobatiform) embryo, with a unique combination of characters indicating that the embryo represents a previously unknown batoid form, is described from the Cenomanian Sannine limestone of Hjoula (Lebanon) by Capasso & Yamaguchi (2023).[60]
  • Reinecke et al. (2023) study the anatomy and affinities of whiptail stingray teeth from the Chattian of northern Germany and the Burdigalian of southern France, transferring the species Dasyatis probsti to the genus Bathytoshia.[61]
  • Pollerspöck et al. (2023) describe an assemblage of deep-sea shark fossils from the Eocene (Ypresian) Lillebælt Clay Formation (Denmark), showing highest similarities with deep-sea shark faunas of France, Austria and northern Morocco in spite of the North Sea Basin having lost direct connections to the neighbouring marine areas in the Eocene.[62]
  • Kovalchuk et al. (2023) revise the taxonomic composition of the cartilaginous fish assemblage from the Eocene (Lutetian-Bartonian) Kyiv Formation (Ukraine), interpreting the studied taxa as inhabiting shallow, warm waters and confined to the continental shelf.[63]
  • Verma (2023) describes new fossil material of elasmobranchs from the Eocene (Bartonian) Harudi Formation (India), providing evidence of replacement of earlier Eocene assemblages of elasmobranchs from western India by an assemblage dominated by members of the genera Brachycarcharias, Striatolamia, Galeocerdo and Carcharhinus, which might have been linked to the Middle Eocene Climatic Optimum.[64]
  • An assemblage of shark and ray teeth, interpreted as indicative of a warm, shallow water community, is described from the Lower Miocene deposits of the Upper Marine Molasse near Ballendorf (Germany) by Höltke et al. (2023).[65]
  • A study on changes of diversity of European chondrichthyans during the Neogene is published by Villafaña et al. (2023).[66]
  • A study on the impact of the Cretaceous–Paleogene extinction event on elasmobranchs is published by Guinot & Condamine (2023), who find rays and durophagous species to be more affected by the extinction than sharks and nondurophagous species, and find taxa with large geographic ranges or restricted to high-latitude settings to show higher survival.[67]

Ray-finned fishes

[edit]
Name Novelty Status Authors Age Type locality Location Notes Images

Amblyeleotris robusta[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A species of Amblyeleotris.

Amelangia[69]

Gen. et sp. nov

Valid

Štamberg & Werneburg

Permian (Asselian)

Lower Goldlauter Formation

 Germany

A member of the family Aeduellidae. The type species is A. ornata.

Archaeotolithus aptychoides[70]

Sp. nov

Pindakiewicz, Hryniewicz & Kaim

Early Cretaceous (Valanginian)

 Poland

Archaeus solus[71]

Sp. nov

Valid

Bannikov & Erebakan

Oligocene

 Russia
( Krasnodar Krai)

A member of the family Carangidae.

Armigatus plinii[72]

Sp. nov

Valid

Marramà & Carnevale

Early Cretaceous (Albian)

Pietraroja Plattenkalk

 Italy

A member of Clupeomorpha belonging to the group Ellimmichthyiformes and the family Armigatidae.

Arnoglossus kerichensis[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A scaldfish.

Arnoglossus scitulus[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A scaldfish.

Aseraggodes azovensis[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A species of Aseraggodes.

Benthosema duanformis[73]

Sp. nov

Lin in Lin et al.

Pliocene

Gutingkeng Formation

Taiwan

A species of Benthosema.

Benthosema parafibulatum[73]

Sp. nov

Lin in Lin et al.

Pliocene

Gutingkeng Formation

Taiwan

A species of Benthosema.

Bolcaperca[74]

Gen. et sp. nov

Valid

Bannikov & Zorzin

Eocene (Ypresian)

Monte Bolca

 Italy

A member of Percoidei of uncertain affinities. The type species is B. craccorum.

Boreiosturion[75]

Gen. et sp. nov

Murray, Nelson & Brinkman

Late Cretaceous (Campanian)

Horseshoe Canyon Formation

 Canada
( Alberta)

A sturgeon. The type species is B. labyrinthicus.

Bothus isselburgensis[76]

Sp. nov

Valid

Schwarzhans & von der Hocht

Miocene

A species of Bothus.

Bregmaceros danicus[77]

Sp. nov

Valid

Schwarzhans & Nielsen

Eocene

Lillebælt Clay Formation

 Denmark

A codlet.

Butyrumichthys[78]

Gen. et sp. nov

Schrøder et al.

Eocene

Fur Formation

 Denmark

A stromateoiform, possibly a medusafish. The type species is B. henricii.

Callionymus bessarabianus[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A species of Callionymus.

Callionymus kalinus[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A species of Callionymus.

Capros crudus[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A species of Capros.

Caranx rharbensis[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Caranx.

Cataetyx alpersi[76]

Sp. nov

Valid

Schwarzhans & von der Hocht

Miocene

A species of Cataetyx.

Centroberyx vonderhochti[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Centroberyx.

Cepola lombartei[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Cepola.

Chelon jurkinensis[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A species of Chelon.

Cladocynodon[80]

Gen. et sp. nov

Valid

De Mayrinck et al.

Early Cretaceous (Aptian)

Barbalha Formation

 Brazil

A member of the family Cladocyclidae. The type species is C. araripensis.

Congiopodus? inopinatus[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

Possibly a species of Congiopodus.

Deltentosteus planus[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Deltentosteus.

Dercetis magnificus[81]

Sp. nov

Chida, Brinkman & Murray

Late Cretaceous (Campanian)

Bearpaw Formation

 Canada
( Alberta)

A member of the family Dercetidae.

Diandongichthys[82]

Gen. et sp. nov

Xu & Ma

Middle Triassic (Anisian)

Guanling Formation

 China

A basal member of Ginglymodi. The type species is D. ocellatus.

Diaphus? duplex[77]

Sp. nov

Valid

Schwarzhans & Nielsen

Eocene

Lillebælt Clay Formation

 Denmark

Possibly a species of Diaphus.

Diaphus maghrebensis[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Diaphus.

Dicologlossa postpatens[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A species of Dicologlossa.

Galaxias crassus[83]

Sp. nov

Valid

Schwarzhans et al.

Early Miocene

Bannockburn Formation

 New Zealand

A species of Galaxias.

Galaxias naviculus[83]

Sp. nov

Valid

Schwarzhans et al.

Early Miocene

Bannockburn Formation

 New Zealand

A species of Galaxias.

Galaxias nitidus[83]

Sp. nov

Valid

Schwarzhans et al.

Early Miocene

Bannockburn Formation

 New Zealand

A species of Galaxias.

Galaxias polei[83]

Sp. nov

Valid

Schwarzhans et al.

Early Miocene

Bannockburn Formation

 New Zealand

A species of Galaxias.

Galaxias tholus[83]

Sp. nov

Valid

Schwarzhans et al.

Early Miocene

Bannockburn Formation

 New Zealand

A species of Galaxias.

Globogobius[68]

Gen. et 2 sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A goby belonging to the subfamily Gobiinae and to the Aphia lineage. The type species is G. globulosus; genus also includes G. depressus.

Grandemarinus[84]

Gen. et sp. nov

Cooper et al.

Late Cretaceous (Turonian)

Akrabou Formation

 Morocco

A gar. The type species is G. gherisensis.

Gutingichthys[73]

Gen. et sp. nov

Lin in Lin et al.

Pliocene

Gutingkeng Formation

Taiwan

A viviparous brotula. The type species is G. changi.

Hygophum kentnielseni[76]

Sp. nov

Valid

Schwarzhans & von der Hocht

Miocene

A species of Hygophum.

Hyrcanogobius eccentricus[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A species of Hyrcanogobius.

Iridopristis parrisi[85]

Gen. et sp. nov

Valid

Andrews et al.

Danian

Hornerstown Formation

 United States ( New Jersey)

A stem-lineage member of Holocentridae.

Khoratamia[86]

Gen. et sp. nov

Valid

Deesri et al.

Early Cretaceous (Aptian)

Khok Kruat Formation

 Thailand

A member of the family Amiidae belonging to the subfamily Sinamiinae. The type species is K. phattharajani.

Kokenichthys kuteki[70]

Sp. nov

Pindakiewicz, Hryniewicz & Kaim

Early Cretaceous (Valanginian)

 Poland

Kutaichthys[87]

Gen et 2 sp. nov

Valid

Bakaev in Esin & Bakaev

Permian

 Russia
( Komi Republic
 Perm Krai
 Samara Oblast)

An early ray-finned fish belonging to the group Palaeonisciformes and the family Palaeoniscidae. The type species is K. gubini Esin & Bakaev; genus also includes K. dozmerensis Esin & Bakaev. Published online in 2023, but the issue date is listed as December 2022.[87]

Macabi[88]

Gen. et sp. nov

Valid

Recinos et al.

Late Cretaceous (Campanian)

 Mexico

A bonefish. The type species is M. tojolabalensis.

Maeotichthys[68]

Gen. et comb. et sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

 Azerbaijan
 Bulgaria
Crimea

A member of the family Clupeidae belonging to the subfamily Alosinae. The type species is "Otolithus (Osmeridarum)" wilhelmi Djafarova (2006); genus also includes "Clupea" gomotartziensis Strashimirov (1985), as well as new species Maeotichthys salebrosus Schwarzhans & Bratishko in Schwarzhans, Bratishko & Vernyhorova (2023).[89]

Mataichthys asymmetricus[83]

Sp. nov

Valid

Schwarzhans et al.

Early Miocene

Bannockburn Formation

 New Zealand

A species of Mataichthys.

Mesogobius chersonesus[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A species of Mesogobius.

Minicholepis[90]

Gen et sp. nov

Valid

Bulanov, Minikh & Golubev

Permian

 Russia
( Kirov Oblast)

A member of Eurynotoidiformes. The type species is M. primus. Published online in 2023, but the issue date is listed as December 2022.[90]

Myripristis ouarredi[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Myripristis.

Neogobius ignotus[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A species of Neogobius.

Neogobius uncinatus[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A species of Neogobius.

Nursallia fenestrata[91]

Sp. nov

Valid

Capasso

Late Cretaceous (Turonian)

Akrabou Formation

 Morocco

A member of Pycnodontiformes belonging to the family Pycnodontidae.

Odontobutis hayashitokuei[92]

Sp. nov

In press

Yabumoto & Zhang

Miocene

Chojabaru Formation

 Japan

A species of Odontobutis.

Ophidion tuseti[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Ophidion.

Opsodentex mordax[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A member of the family Sparidae.

Otarionichthys hofstedtae[76]

Sp. nov

Valid

Schwarzhans & von der Hocht

Miocene

A viviparous brotula.

Palaeoargentina[70]

Gen. et sp. nov

Pindakiewicz, Hryniewicz & Kaim

Early Cretaceous (Valanginian)

 Poland

Genus includes new species P. plicata.

Palaeogadus? belli[93]

Sp. nov

Valid

Stringer & Sloan

Late Cretaceous (Maastrichtian)

Arkadelphia Marl

 United States
( Arkansas)

A member of the family Merlucciidae.

Paleocharacodon[94]

Gen. et sp. nov

Valid

Caballero-Viñas, Alvarado-Ortega & Cantalice Severiano

Pliocene

Atotonilco El Grande Formation

 Mexico

A member of the family Goodeidae belonging to the subfamily Goodeinae. The type species is P. guzmanae.

Palimphemus cimmerius[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A member of the family Gadidae.

Paraclupea pietrarojae[72]

Sp. nov

Valid

Marramà & Carnevale

Early Cretaceous (Albian)

Pietraroja Plattenkalk

 Italy

A member of Clupeomorpha belonging to the group Ellimmichthyiformes and the family Paraclupeidae.

Paramacroramphosus[68]

Gen. et sp. et comb. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

 Azerbaijan
Crimea

A member of the family Macroramphosidae. The type species is P. pumilis; genus also includes "Оtolithus (inc. sedis)" platessaeformis Pobedina (1956).

Parapristipoma bethensis[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Parapristipoma.

Parapsephurus[95]

Gen. et sp. nov

Valid

Hilton et al.

Late Cretaceous (Maastrichtian)

Hell Creek Formation

 United States
( North Dakota)

A paddlefish. The type species is P. willybemisi.

Parascolopsis septentrionalis[76]

Sp. nov

Valid

Schwarzhans & von der Hocht

Miocene

A species of Parascolopsis.

Paroxymetopon[68]

Gen. et sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A dartfish. The type species is P. alienus.

Phoebeannaia[96]

Gen. et sp. nov

Valid

Caron et al.

Carboniferous (Bashkirian)

Marsden Formation

 United Kingdom

An early ray-finned fish, possibly stem-neopterygian. The type species is P. mossae.

Pleuropholis danielae[97]

Sp. nov

Brito & Vullo

Late Cretaceous (Cenomanian)

Akrabou Formation

 Morocco

Pomadasys zemmourensis[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Pomadasys.

Pontogobius[68]

Gen. et 3 sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A goby belonging to the subfamily Gobiinae and to the Benthophilus lineage. The type species is P. ahnelti; genus also includes P. trigonus and P. zonatus.

Pronobythites[77]

Gen. et sp. et comb. nov

Valid

Schwarzhans & Nielsen

Eocene

Lillebælt Clay Formation

 Denmark
 France

A cusk-eel. The type species is P. schnetleri; genus also includes "Neobythites" bozzolo Lin, Nolf & Girone in Lin et al. (2016) and "Neobythites" leonardi Lin, Nolf & Girone in Lin et al. (2016).

Protalbula pentangularis[70]

Sp. nov

Pindakiewicz, Hryniewicz & Kaim

Early Cretaceous (Valanginian)

 Poland

Protoelops gracilis[70]

Sp. nov

Pindakiewicz, Hryniewicz & Kaim

Early Cretaceous (Valanginian)

 Poland

Pteralbula polonica[70]

Sp. nov

Pindakiewicz, Hryniewicz & Kaim

Early Cretaceous (Valanginian)

 Poland

Pugiopsephurus[95]

Gen. et sp. nov

Valid

Hilton et al.

Late Cretaceous (Maastrichtian)

Hell Creek Formation

 United States
( North Dakota)

A paddlefish. The type species is P. inundatus.

Rhamphoichthys[98]

Gen. et sp. nov

Valid

El Hossny et al.

Late Cretaceous (Cenomanian)

Hesseltal Formation

 Germany
 Italy
 Lebanon
 United Kingdom

A member of the family Plethodidae. The type species is R. taxidiotis. El Hossny et al. (2023) also interpret fossils of "Protosphyraena" minor and "Protosphyraena" stebbingi as fossil material of Rhamphoichthys sp., but don't consider these to be valid taxa due to the incompleteness of their fossil material.

Rhamphosus bloti[99]

Sp. nov

Valid

Calzoni et al.

Eocene (Ypresian)

Monte Bolca

 Italy

A member of Syngnathiformes belonging to the group Dactylopteroidei and the family Rhamphosidae.

Rhamphosus brevirostris[99]

Sp. nov

Valid

Calzoni et al.

Eocene (Ypresian)

Monte Bolca

 Italy

A member of Syngnathiformes belonging to the group Dactylopteroidei and the family Rhamphosidae.

Rhamphosus longispinatus[99]

Sp. nov

Valid

Calzoni et al.

Eocene (Ypresian)

Monte Bolca

 Italy

A member of Syngnathiformes belonging to the group Dactylopteroidei and the family Rhamphosidae.

Rhamphosus tubulirostris[99]

Sp. nov

Valid

Calzoni et al.

Eocene (Ypresian)

Monte Bolca

 Italy

A member of Syngnathiformes belonging to the group Dactylopteroidei and the family Rhamphosidae.

Rhynchoconger carnevalei[79]

Sp. nov

Schwarzhans

Miocene (Tortonian) and Pliocene (Zanclean)

 Italy

A species of Rhynchoconger.

Saurichthys taotie[100]

Sp. nov

Valid

Fang et al.

Late Triassic (Carnian)

Xiaowa Formation

 China

Announced in 2022; the final article version was published in 2023.

Sciades maldonadonis[101]

Sp. nov

Valid

Carrillo-Briceño et al.

Miocene

La Victoria Formation

 Colombia

A species of Sciades.

Scomber qirimensis[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A species of Scomber.

Scythogobius[89]

Gen. et sp. nov

Valid

Schwarzhans & Bratishko in Schwarzhans, Bratishko & Vernyhorova

Miocene

Crimea

A member of the family Gobiidae belonging to the tribe Benthophilini. The type species is S. spissus.

Serrivomer glehni[102]

Sp. nov

Valid

Nazarkin

Miocene

Kurasi Formation

 Russia
( Sakhalin Oblast)

A species of Serrivomer.

Spondyliosoma tingitana[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Spondyliosoma.

Stanhopella[103]

Gen. et sp. nov

Valid

Capasso

Late Cretaceous (Cenomanian)

Sannine Formation

 Lebanon

A member of Pycnodontiformes. The type species is S. elongata.

Surlykus[104]

Gen. et sp. nov

Valid

Schrøder & Carnevale

Eocene (Ypresian)

Fur Formation

 Denmark

A member of Argentiniformes. The type is species S. longigracilis.

Thorecichthys fideli[105]

Sp. nov

Than-Marchese et al.

Late Cretaceous (Cenomanian)

Cintalapa Formation

 Mexico

A member of Clupeomorpha belonging to the group Ellimmichthyiformes.

Trachinus maroccanus[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Trachinus.

Trachinus wernlii[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Trachinus.

Trachurus gramensis[76]

Sp. nov

Valid

Schwarzhans & von der Hocht

Miocene

A species of Trachurus.

Trachurus insectus[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Trachurus.

Trachurus reineckei[106]

Sp. nov

Valid

Hoedemakers in De Schutter et al.

Oligocene (Rupelian)

Boom Formation

 Belgium

A species of Trachurus.

Treldeichthys[77]

Gen. et comb. nov

Valid

Schwarzhans & Nielsen

Eocene

Lillebælt Clay Formation

 Denmark

A member of Acanthopterygii of uncertain affinities. The type species is "Caproidarum" madseni Schwarzhans (2007).

Uranoscopus hoedemakersi[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Uranoscopus.

Uranoscopus vanhinsberghi[79]

Sp. nov

Schwarzhans

Pliocene (Zanclean)

 Morocco

A species of Uranoscopus.

Vango[107]

Gen. et sp. nov.

Murray et al.

Late Cretaceous (Maastrichtian)

Mahajanga Basin

 Madagascar

A member of the family Chanidae. The type species is V. fahiny.

Vologdinia[90]

Gen et comb. nov

Valid

Bulanov, Minikh & Golubev

Permian

Poldarsa/Poldarskaya Formation

 Russia
( Orenburg Oblast
 Vologda Oblast)

A member of Eurynotoidiformes. The type species is "Isadia" opokiensis Minikh & Andrushkevich (2017). Published online in 2023, but the issue date is listed as December 2022.[90]

Ypsiloichthys[108]

Gen. et sp. nov

Valid

El Hossny & Cavin

Late Cretaceous (Cenomanian)

Sannine Formation

 Lebanon

A teleost of uncertain affinities. The type species is Y. sibelleae.

Zaiaichthys[109]

Gen. et 2 sp. nov

Valid

Bannikov & Zorzin

Eocene (Ypresian)

 Italy

A member of the family Monodactylidae. The type species is Z. postalensis; genus also includes Z. watersi.

Zosterisessor pontikapaionensis[68]

Sp. nov

Valid

Bratishko & Schwarzhans in Bratishko, Schwarzhans & Vernyhorova

Miocene

Crimea

A species of Zosterisessor.

Ray-finned fish research

[edit]
  • Figueroa et al. (2023) report brain and cranial nerve soft-tissue preservation in the type specimen of Coccocephalus wildi from the Carboniferous strata in the Mountain Fourfoot Mine (Pennine Lower Coal Measures; Lancashire, United Kingdom).[110]
  • Bakaev, Johanson & LeBlanc (2023) study the dental system of Kazanichthys viatkensis, reporting the presence of morphological similarities to the dental systems of extant sparids, and interpreting K. viatkensis as a generalist durophagous feeder.[111]
  • Revision of the fossil material of Permian ray-finned fishes from the Kazankovo-Markino Formation (Kemerovo Oblast, Russia) is published by Bakaev (2023), who considers Heterolepis Sergienko (1974) to be a junior synonym of Eurynotoides Berg (1940).[112]
  • Martill (2023) describes a bony scute of a sturgeon from the Maastrichtian marine phosphatites of central Morocco, representing the first record of an acipenseriform fish from Africa reported to date.[113]
  • New information on the morphology of the scales of members of the family Pseudobeaconiidae, based on new fossil material from the Triassic Santa Clara Abajo Formation (Argentina), is presented by Giordano, Benavente & Suárez (2023).[114]
  • Putative eugnathid amiiform Sinoeugnathus kueichowensis is reinterpreted as a small-sized member of Ionoscopiformes by Feng et al. (2023), who name a new family Subortichthyidae including the genera Subortichthys, Sinoeugnathus, Allolepidotus and Eoeugnathus.[115]
  • Sullivan, Jasinski & Williamson (2023) describe an exceptionally well-preserved articulated skull roof and braincase of Melvius chauliodous from the Upper Cretaceous Kirtland Formation (New Mexico, United States), revise the characters that defin the genus and its two recognized species, and study the phylogenetic affinities of Melvius.[116]
  • A study on the microstructure of teeth of Late Jurassic pachycormids and caturoids from the Owadów-Brzezinki site (Poland) is published by Weryński, Błażejowski & Kędzierski (2023), who report structural differences interpreted as suggestive of different adaptations for predation and possible niche partitioning between the studied taxa.[117]
  • Systematic revision of the Late Jurassic species of Caturidae is published by López-Arbarello & Ebert (2023).[118]
  • Fossil material of a putative member of the genus Caturus reported by Bogan, Taverne & Agnolin (2013) as found in the Triassic Los Menucos Group,[119] is reinterpreted by López-Arbarello et al. (2023) as actually collected in outcrops of the Jurassic Vaca Muerta Formation, and excluded from the genus Caturus.[120]
  • Cooper & Maxwell (2023) describe a specimen of Pachycormus macropterus from the Toarcian Posidonia Shale (Germany) preserved with an unusually large ammonite inside its gut, interpreted as ingested immediately prior to and directly responsible for the fish's death.[121]
  • A study on the bone histology of Araripichthys castilhoi, interpreted as corroborating its placement within basal Teleostei, is published by Mayrinck et al. (2023).[122]
  • Stinnesbeck et al. (2023) report the presence of two different body shape types of specimens of Tselfatia formosa from the Turonian platy limestone deposit of Vallecillo (Mexico), interpreted as evidence of sexual dimorphism, and interpret the anatomy of its fins as indicating that T. formosa lived in a deep water environment and that its lifestyle resembled that of extant fan fishes.[123]
  • Cooper & Norton (2023) describe fossil material of an indeterminate plethodid from the Maastrichtian deposits from the Plateau des Phosphates (Morocco), representing the youngest occurrence of a plethodid reported to date.[124]
  • Redescription and a study on the affinities of Sorbinichthys elusivo is published by Taverne & Capasso (2023).[125]
  • Fossil material of a catfish, representing the first record of a bony fish from the Maastrichtian of the Marília Formation (Brazil) and extending known Late Cretaceous catfish distribution, is described by Candeiro et al. (2023).[126]
  • A study on the fossil record of acanthomorphs from the MaastrichtianPaleocene strata is published by Friedman et al. (2023), who find that the majority of the principal acanthomorph groups appear in the fossil record before the end of the Paleocene.[127]
  • A study on the variety of the morphology of the first abdominal vertebral centrum in extant acanthomorphs is published by Murray & Brinkman (2023), who interpret their findings as indicating that the overall morphology of the first centrum is conservative within acanthomorph families, and that it is possible to assign many fossil acanthomorph centra to extant families, suborders or orders.[128]
  • Rust & Robinson (2023) redescribe Eothyrsites holosquamatus, and interpret this taxon as likely representing an ancestral form of gempylid.[129]
  • Fossil material representing one of the oldest records of marlins reported to date is described from the Miocene (Aquitanian) Northern Alpine Foreland Basin (Austria) by De Gracia, Berning & Kriwet (2023), who report evidence of coexistence of marlins, xiphiorhynchine xiphiids and aglyptorhynchine palaeorhynchids from the Northern Alpine Foreland Basin and from the Oligocene Chandler Bridge Formation (South Carolina, United States).[130]
  • Bannikov & Zorzin (2023) interpret the percomorph genus Callipteryx as a probable member of Percoidei of uncertain affinities, and interpret Callipteryx recticaudus as a junior synonym of Callipteryx speciosus.[131]
  • Ngoepe et al. (2023) reconstruct the history of arrival order and relative abundances of major fish groups from Lake Victoria, using data from the continuous fossil record from the preceding 17,000 years, and report that cichlids did not dominate the assemblage until several thousand years into its history, but they were the only major group that had the ecological versatility that allowed them to persist once the new deep and open-water habitats emerged.[132]
  • Evidence from (mostly lanternfish) otoliths from the Lindos Bay Formation (Rhodes, Greece), interpreted as indicative of an overall decline of the median size of lanternfishes in the eastern Mediterranean during MIS 19 interglacial, but also as indicative of different trends in size in individual mesopelagic species across the studied time interval, is presented by Agiadi et al. (2023).[133]

Lobe-finned fishes

[edit]
Name Novelty Status Authors Age Type locality Location Notes Images

Braccodus[134]

Gen. et sp. nov

Valid

Elliott, Challands & Smithson

Carboniferous

 United Kingdom

A lungfish. The type species is B. kerri.

Ceratodus shishkini[135]

Sp. nov

Valid

Minikh

Triassic

 Russia
( Orenburg Oblast)

A lungfish. Published online in 2023, but the issue date is listed as December 2022.[135]

Eusthenodon leganihanne[136]

Sp. nov

Downs et al.

Devonian (Famennian)

Catskill Formation

 United States
( Pennsylvania)

Hyneria udlezinye[137]

Sp. nov

Valid

Gess & Ahlberg

Devonian (Famennian)

Witpoort Formation

 South Africa

Janvierpaucidentes[138]

Gen. et sp. nov

Valid

Johanson et al.

Devonian (Pragian)

Wood Bay Formation

 Norway

A lungfish. The type species is J. tuulingi.

Lanarkodus[134]

Gen. et sp. nov

Valid

Elliott, Challands & Smithson

Carboniferous

 United Kingdom

A lungfish. The type species is L. clarki.

Rhizodopsis rankini[139]

Sp. nov

Elliott

Carboniferous

 United Kingdom

A member of the family Megalichthyidae.

Rieppelia[140]

Gen. et sp. nov

Valid

Ferrante & Cavin

Middle Triassic (Anisian)

Besano Formation

  Switzerland

A coelacanth belonging to the family Latimeriidae. The type species is R. heinzfurreri.

Ticinepomis ducanensis[141]

Sp. nov

Valid

Ferrante et al.

Middle Triassic

Prosanto Formation

  Switzerland

A coelacanth belonging to the family Latimeriidae.

Whiteia giganteus[142] Sp. nov Brownstein Late Triassic Dockum Group  United States ( Texas) A coelacanth.

Lobe-finned fish research

[edit]
  • Dupret et al. (2023) describe new fossil material of sarcopterygians from the Devonian (Givetian) Valentia Slate Formation (Republic of Ireland), including a tooth plate of a lungfish with a derived morphology otherwise only known from Late Devonian and later taxa, and a possible rhizodontid fossil material, which might indicate that a dispersal of rhizodontids from Gondwana into Euramerica happened as early as middle Givetian.[143]

General research

[edit]

References

[edit]
  1. ^ Blom, H.; Vaškaninová, V.; Karatajūtė-Talimaa, V.; Žigaitė, Ž. (2023). "Thelodont scales from the Lower Devonian of Novaya Zemlya Archipelago, Arctic Russia". Spanish Journal of Palaeontology. 38 (1): 9–14. doi:10.7203/sjp.26231. S2CID 257676099.
  2. ^ Huang, W. (2023). "A new species of fossil lamprey (Petromyzontida: Petromyzontiformes) from Hebei, China". Historical Biology: An International Journal of Paleobiology: 1–13. doi:10.1080/08912963.2023.2252443. S2CID 261473806.
  3. ^ Zhang, Y.; Li, X.; Shan, X.; Lin, X.; Tan, K.; Li, Q.; Zhao, W.; Tang, L.; Zhu, M.; Gai, Z. (2023). "The first galeaspid fish (stem-Gnathostomata) from the Silurian Xiushan formation of Hunan Province, China". Historical Biology: An International Journal of Paleobiology: 1–12. doi:10.1080/08912963.2023.2225083. S2CID 259469524.
  4. ^ Gai, Z.; Lin, X.; Shan, X.; Ferrón, H. G.; Donoghue, P. C. J. (2023). "Postcranial disparity of galeaspids and the evolution of swimming speeds in stem-gnathostomes". National Science Review. 10 (7). nwad050. doi:10.1093/nsr/nwad050. PMC 10232041. PMID 37266551.
  5. ^ Liu, W.; Shan, X.; Lin, X.; Shen, Y.; Liu, Y.; Zhang, Z.; Gai, Z. (2023). "The first Eugaleaspiforme fish from the Silurian of the Tarim Basin reveals a close relationship between the Tarim and South China blocks at 438 mya". Palaeogeography, Palaeoclimatology, Palaeoecology. 628. 111774. Bibcode:2023PPP...62811774L. doi:10.1016/j.palaeo.2023.111774. S2CID 260874354.
  6. ^ McCoy, V. E.; Wittry, J.; Sadabadi, H.; Mayer, P. (2023). "A reappraisal of Nemavermes mackeei from the Mazon Creek fossil site expands Carboniferous cyclostome diversity". Journal of Paleontology. 97 (5): 1116–1132. Bibcode:2023JPal...97.1116M. doi:10.1017/jpa.2023.72.
  7. ^ Shan, X.-R.; Lin, X.-H.; Zhang, Y.-M.; Li, X.-T.; Gai, Z.-K. (2023). "New findings of Xiyuichthys (Xiushuiaspidae, Galeaspida) from the Silurian of Jiangxi Province and Tarim Basin". Vertebrata PalAsiatica. 61 (4): 245–260. doi:10.19615/j.cnki.2096-9899.230904.
  8. ^ Wu, F.; Janvier, P.; Zhang, C. (2023). "The rise of predation in Jurassic lampreys". Nature Communications. 14 (1). 6652. Bibcode:2023NatCo..14.6652W. doi:10.1038/s41467-023-42251-0. PMC 10618186. PMID 37907522.
  9. ^ Reeves, J. C.; Wogelius, R. A.; Keating, J. N.; Sansom, R. S. (2023). "Lasanius, an exceptionally preserved Silurian jawless fish from Scotland". Palaeontology. 66 (2). e12643. Bibcode:2023Palgy..6612643R. doi:10.1111/pala.12643. S2CID 258066900.
  10. ^ Dearden, R. P.; Lanzetti, A.; Giles, S.; Johanson, Z.; Jones, A. S.; Lautenschlager, S.; Randle, E.; Sansom, I. J. (2023). "The oldest three-dimensionally preserved vertebrate neurocranium". Nature. 621 (7980): 782–787. Bibcode:2023Natur.621..782D. doi:10.1038/s41586-023-06538-y. PMC 10533405. PMID 37730987.
  11. ^ Grohganz, M.; Ferrón, H. G.; Johanson, Z.; Donoghue, P. C. J. (2023). "Testing hypotheses of pteraspid heterostracan feeding using computational fluid dynamics". Journal of Vertebrate Paleontology. 43 (2). e2272974. doi:10.1080/02724634.2023.2272974.
  12. ^ Dupret, V.; Byrne, H. M.; Castro, N.; Hammer, Ø.; Higgs, K. T.; Long, J. A.; Niedźwiedzki, G.; Qvarnström, M.; Stössel, I.; Ahlberg, P. E. (2023). "The Bothriolepis (Placodermi, Antiarcha) material from the Valentia Slate Formation of the Iveragh Peninsula (middle Givetian, Ireland): Morphology, evolutionary and systematic considerations, phylogenetic and palaeogeographic implications". PLOS ONE. 18 (2). e0280208. Bibcode:2023PLoSO..1880208D. doi:10.1371/journal.pone.0280208. PMC 9949654. PMID 36821588.
  13. ^ Liu, S.; Pan, Z.; Zhu, M.; Jia, L.; Zhao, W. (2023). "A New Bothriolepid Antiarch from the Middle Devonian in Luquan, Yunnan, South China and Its Stratigraphic and Biogeographic Significances". Journal of Earth Science. 34 (4): 1176–1188. Bibcode:2023JEaSc..34.1176L. doi:10.1007/s12583-022-1775-1. S2CID 260813014.
  14. ^ Lebedev, O. A.; Engelman, R. K.; Skutschas, P. P.; Johanson, Z.; Smith, M. M.; Kolchanov, V. V.; Trinajstic, K.; Linkevich, V. V. (2023). "Structure, Growth and Histology of Gnathal Elements in Dunkleosteus (Arthrodira, Placodermi), with a Description of a New Species from the Famennian (Upper Devonian) of the Tver Region (North-Western Russia)". Diversity. 15 (5). 648. doi:10.3390/d15050648.
  15. ^ Plax, D. P.; Lukševičs, E. (2023). "A new Early Devonian antiarch placoderm from Belarus, and the phylogeny of Asterolepidoidei". Acta Palaeontologica Polonica. 68 (3): 513–527. doi:10.4202/app.01075.2023. S2CID 261546695.
  16. ^ Plax, D. P.; Newman, M. J. (2023). "Formal description of Valentinaspis profundus gen. et sp. nov., a placoderm fish and zone fossil from the Emsian of Belarus and Estonia". New Mexico Museum of Natural History and Science Bulletin. 94: 525–532.
  17. ^ Brazeau, M.; Castiello, M.; El Fassi El Fehri, A.; Hamilton, L.; Ivanov, A. O.; Johanson, Z.; Friedman, M. (2023). "Fossil evidence for a pharyngeal origin of the vertebrate pectoral girdle". Nature. 623 (7987): 550–554. Bibcode:2023Natur.623..550B. doi:10.1038/s41586-023-06702-4. PMC 10651482. PMID 37914937.
  18. ^ Brazeau, M. D.; Yuan, H.; Giles, S.; Jerve, A. L.; Zorig, E.; Ariunchimeg, Ya.; Sansom, R. S.; Atwood, R. C. (2023). "A well-preserved 'placoderm' (stem-group Gnathostomata) upper jaw from the Early Devonian of Mongolia clarifies jaw evolution". Royal Society Open Science. 10 (2). 221452. Bibcode:2023RSOS...1021452B. doi:10.1098/rsos.221452. PMC 9943883. PMID 36844806.
  19. ^ Luo, Y.-C.; Zhu, M.; Lu, L.-W.; Pan, Z.-H. (2023). "Reappraisal of Bothriolepis sinensis Chi, 1940 from the Tiaomachien Formation, Hunan, China". Vertebrata PalAsiatica. 61 (4): 261–276. doi:10.19615/j.cnki.2096-9899.230901.
  20. ^ Xue, Q.-Y.; Yu, Y.-L.; Pan, Z.-H.; Zhu, Y.-A.; Zhu, M. (2023). "Decline in phylogenetic diversity of Arthrodira (stem-group Gnathostomata) correlates with major Devonian bioevents". Vertebrata PalAsiatica. 62 (1): 1–12. doi:10.19615/j.cnki.2096-9899.231124.
  21. ^ Engelman, R. K. (2023). "A Devonian Fish Tale: A New Method of Body Length Estimation Suggests Much Smaller Sizes for Dunkleosteus terrelli (Placodermi: Arthrodira)". Diversity. 15 (3). 318. doi:10.3390/d15030318.
  22. ^ Ferrón, H. G.; Martínez-Pérez, C.; Botella, H. (2017). "Ecomorphological inferences in early vertebrates: reconstructing Dunkleosteus terrelli (Arthrodira, Placodermi) caudal fin from palaeoecological data". PeerJ. 5. e4081. doi:10.7717/peerj.4081. PMC 5723140. PMID 29230354.
  23. ^ Engelman, R. (2023). "Giant, swimming mouths: oral dimensions of extant sharks do not accurately predict body size in Dunkleosteus terrelli (Placodermi: Arthrodira)". PeerJ. 11. e15131. doi:10.7717/peerj.15131. PMC 10100833. PMID 37065696.
  24. ^ Cui, X.; Friedman, M.; Yu, Y.; Zhu, Y.A.; Zhu, M. (2023). "Bony-fish-like scales in a Silurian maxillate placoderm". Nature Communications. 14 (1). 7622. Bibcode:2023NatCo..14.7622C. doi:10.1038/s41467-023-43557-9. PMC 10665347. PMID 37993457.
  25. ^ a b c d e f g h Guinot, G.; Hautier, L.; Sambou, B. S.; Sarr, R.; Martin, J. E. (2023). "The Upper Cretaceous elasmobranch fauna from Senegal" (PDF). Cretaceous Research. 146. 105480. Bibcode:2023CrRes.14605480G. doi:10.1016/j.cretres.2023.105480. S2CID 256290517.
  26. ^ Itano, W. M. (2023). "A new janassid (Chondrichthyes, Petalodontiformes) from the Late Mississippian of Alabama, USA". Historical Biology: An International Journal of Paleobiology. 36 (4): 872–881. doi:10.1080/08912963.2023.2194902. S2CID 258201137.
  27. ^ Batchelor, T. J.; Duffin, C. J. (2023). "A new neoselachian shark from the marine Early Cretaceous of Southern England". Proceedings of the Geologists' Association. 134 (3): 276–282. Bibcode:2023PrGA..134..276B. doi:10.1016/j.pgeola.2023.03.003. S2CID 258127397.
  28. ^ Pauliv, V. E.; Dias, E. V.; Sedor, F. A.; Weinschütz, L. C.; Ribeiro, A. M. (2023). "A new symmoriiform shark and other chondrichthyan teeth from the earliest Permian of southern Brazil". Revista Brasileira de Paleontologia. 26 (3): 227–237. doi:10.4072/rbp.2023.3.07.
  29. ^ Marramà, G.; Villalobos-Segura, E.; Zorzin, R.; Kriwet, J.; Carnevale, G. (2023). "The evolutionary origin of the durophagous pelagic stingray ecomorph". Palaeontology. 66 (4). e12669. Bibcode:2023Palgy..6612669M. doi:10.1111/pala.12669. PMC 7614867. PMID 37533696.
  30. ^ a b Ivanov, A. O.; Alekseev, A. S.; Nikolaeva, S. V. (2023). "New fishes from the Viséan–Serpukhovian boundary beds (Carboniferous) of the Verkhnyaya Kardailovka section (South Urals, Russia)". Palaeoworld. doi:10.1016/j.palwor.2023.06.009. S2CID 259605980.
  31. ^ a b Ivanov, A. O.; Kovalenko, E. S.; Murashev, M. M.; Podurets, K. M. (2022). "Euselachian Sharks (Elasmobranchii, Chondrichthyes) from the Middle and Late Permian of European Russia". Paleontological Journal. 56 (11): 1372–1384. Bibcode:2022PalJ...56.1372I. doi:10.1134/S0031030122110065. S2CID 256618403.
  32. ^ Chahud, A. (2023). "Holocephali from the Irati Formation (Paraná Basin), Brazil: Origin, paleogeographical and paleoenvironmental considerations". Estudios Geológicos. 79 (2). e155. doi:10.3989/egeol.44987.632. S2CID 261376731.
  33. ^ Burrow, C. J.; Murphy, M. A.; Turner, S. (2023). "Late Silurian to earliest Devonian vertebrate biostratigraphy of the Birch Creek II section, Roberts Mountains, Nevada, U.S.A." PaleoBios. 40 (4): 1–32. doi:10.5070/P940454153. S2CID 259789213.
  34. ^ Tomita, T.; Yabumoto, Y.; Kuga, N. (2023). "A New Snaggletooth Shark Species, Hemipristis tanakai Sp. Nov., from the Ashiya Group (Oligocene), Northern Kyushu, Japan". Paleontological Research. 28 (3): 273–278. doi:10.2517/PR220021.
  35. ^ Lebedev, O. A.; Itano, W. M.; Johanson, Z.; Alekseev, A. S.; Smith, M. M.; Ivanov, A. V.; Novikov, I. V. (2023). "Tooth whorl structure, growth and function in a helicoprionid chondrichthyan Karpinskiprion (nom. nov.) (Eugeneodontiformes) with a revision of the family composition". Earth and Environmental Science Transactions of the Royal Society of Edinburgh. 113 (4): 337–360. doi:10.1017/S1755691022000251. S2CID 256533799.
  36. ^ Duffin, C. J.; Heckert, A. B.; Hancox, P. J. (2023). "A new low diversity lacustrine elasmobranch fauna from the Lower Triassic Burgersdorp Formation of South Africa with descriptions of Lissodus tumidoclavus n. sp. (Chondrichthyes: Hybodontoidea)". Neues Jahrbuch für Geologie und Paläontologie – Abhandlungen. 308 (2): 151–169. doi:10.1127/njgpa/2023/1134. S2CID 259393271.
  37. ^ Wen, W.; Zhang, Q.; Benton, M. J.; Kriwet, J.; Hu, S.; Huang, J.; Zhou, C.; Cui, X.; Ma, Z.; Min, X. (2023). "First occurrence of hybodontid teeth in the Luoping Biota (Middle Triassic, Anisian), emphasizing recovery of the marine ecosystem after the end-Permian mass extinction". Palaeogeography, Palaeoclimatology, Palaeoecology. 617. 111471. doi:10.1016/j.palaeo.2023.111471. S2CID 257248890.
  38. ^ Klug, Christian; Coates, Michael; Frey, Linda; Greif, Merle; Jobbins, Melina; Pohle, Alexander; Lagnaoui, Abdelouahed; Haouz, Wahiba Bel; Ginter, Michal (2023-03-28). "Broad snouted cladoselachian with sensory specialization at the base of modern chondrichthyans". Swiss Journal of Palaeontology. 142 (1): 2. Bibcode:2023SwJP..142....2K. doi:10.1186/s13358-023-00266-6. ISSN 1664-2384. PMC 10050047. PMID 37009301.
  39. ^ Newman, M. J.; den Blaauwen, J. L.; Burrow, C. J.; Jones, R.; Davidson, R. G. (2023). "The Middle Devonian acanthodian Orcadacanthus n. gen. from the Orcadian Basin of Scotland". Palaeontologia Electronica. 26 (1). 26.1.a5. doi:10.26879/1240.
  40. ^ Boulemia, S.; Adnet, S. (2023). "A new Palaeogene elasmobranch fauna (Tebessa region, eastern Algeria) and the importance of Algerian-Tunisian phosphates for the North African fossil record". Annales de Paléontologie. 109 (3). 102632. Bibcode:2023AnPal.10902632B. doi:10.1016/j.annpal.2023.102632.
  41. ^ Begat, A.; Kriwet, J.; Gelfo, J. N.; Gouiric Cavalli, S.; Schultz, J. A.; Martin, T. (2023). "The first southern hemisphere occurrence of the extinct Cretaceous sclerorhynchoid sawfish Ptychotrygon (Chondrichthyes, Batoidea), with a review of Ptychotrygon taxonomy". Journal of Vertebrate Paleontology. 42 (2). e2162411. doi:10.1080/02724634.2022.2162411. PMC 7614936. PMID 37564697. S2CID 256750575.
  42. ^ Hodnett, J.-P. M.; Toomey, R.; Olson, R.; Tweet, J. S.; Santucci, V. L. (2023). "Janassid petalodonts (Chondrichthyes, Petalodontiformes, Janassidae) from the middle Mississippian (Viséan) Ste. Genevieve Formation, Mammoth Cave National Park, Kentucky, USA". Historical Biology: An International Journal of Paleobiology: 1–10. doi:10.1080/08912963.2023.2231955. S2CID 259523231.
  43. ^ Stumpf, S.; Kettler, C.; Kindlimann, R.; Cuny, G.; Kriwet, J. (2023). "The oldest Gondwanan record of the extinct durophagous hybodontiform chondrichthyan, Strophodus from the Bajocian of Morocco". Swiss Journal of Palaeontology. 142 (1). 5. Bibcode:2023SwJP..142....5S. doi:10.1186/s13358-023-00270-w.
  44. ^ Itano, W. M.; Duffin, C. J. (2023). "An enigmatic chondrichthyan spine from the Visean of Indiana, USA that resembles a median rostral cartilage of Squaloraja (Holocephali, Chimaeriformes)". Spanish Journal of Palaeontology. 38 (1): 57–68. doi:10.7203/sjp.26305. S2CID 257793552.
  45. ^ Zevallos-Valdivia, L.; Martínez-Pérez, C.; García-Flores, V.; Chávez-Valencia, A.; Botella, H. (2023). "First record of palaeozoic vertebrates from Peru". Spanish Journal of Palaeontology. 38 (1): 95–100. doi:10.7203/sjp.25691. S2CID 256585278.
  46. ^ Burrow, C. J.; Desbiens, S. (2023). "Teeth and tooth whorls of the stem chondrichthyan Doliodus from the Early Devonian of the Gaspé Sandstone Group, Gaspé Peninsula, Quebec, Canada". Spanish Journal of Palaeontology. 38 (1): 15–22. doi:10.7203/sjp.26372. S2CID 257995090.
  47. ^ Dearden, R. P.; Herrel, A.; Pradel, A. (2023). "Evidence for high-performance suction feeding in the Pennsylvanian stem-group holocephalan Iniopera". Proceedings of the National Academy of Sciences of the United States of America. 120 (4). e2207854119. Bibcode:2023PNAS..12007854D. doi:10.1073/pnas.2207854119. PMC 9942859. PMID 36649436.
  48. ^ Amadori, M.; Solonin, S. V.; Vodorezov, A. V.; Shell, R.; Niedźwiedzki, R.; Kriwet, J. (2023). "The extinct shark, Ptychodus (Elasmobranchii, Ptychodontidae) in the Upper Cretaceous of central-western Russia—The road to easternmost peri-Tethyan seas". Journal of Vertebrate Paleontology. 42 (2). e2162909. doi:10.1080/02724634.2022.2162909. PMC 7614918. PMID 37559798. S2CID 256756251.
  49. ^ Amadori, M.; Kovalchuk, O.; Barkaszi, Z.; Giusberti, L.; Kindlimann, R.; Kriwet, J. (2023). "A diverse assemblage of Ptychodus species (Elasmobranchii: Ptychodontidae) from the Upper Cretaceous of Ukraine, with comments on possible diversification drivers during the Cenomanian". Cretaceous Research. 151. 105659. Bibcode:2023CrRes.15105659A. doi:10.1016/j.cretres.2023.105659. hdl:11577/3490720. S2CID 260049184.
  50. ^ Ghosh, T.; Bajpai, S.; Kumar, K.; Maurya, A. S.; Bhattacharya, D. (2023). "First Early Cretaceous sharks from India". Historical Biology: An International Journal of Paleobiology: 1–9. doi:10.1080/08912963.2023.2280623.
  51. ^ Krak, A. M.; Shimada, K. (2023). "The dentition of the extinct megamouth shark, Megachasma applegatei (Lamniformes: Megachasmidae), from southern California, USA, based on geometric morphometrics". PaleoBios. 40 (1): 1–10. doi:10.5070/P940160139. S2CID 256801266.
  52. ^ Shimada, K.; Yamaoka, Y.; Kurihara, Y.; Takakuwa, Y.; Maisch, H. M.; Becker, M. A.; Eagle, R. A.; Griffiths, M. L. (2023). "Tessellated calcified cartilage and placoid scales of the Neogene megatooth shark, Otodus megalodon (Lamniformes: Otodontidae), offer new insights into its biology and the evolution of regional endothermy and gigantism in the otodontid clade". Historical Biology: An International Journal of Paleobiology: 1–15. doi:10.1080/08912963.2023.2211597. S2CID 259597157.
  53. ^ Griffiths, M. L.; Eagle, R. A.; Kim, S. L.; Flores, R. J.; Becker, M. A.; Maisch, H. M.; Trayler, R. B.; Chan, R. L.; McCormack, J.; Akhtar, A. A.; Tripati, A. K.; Shimada, K. (2023). "Endothermic physiology of extinct megatooth sharks". Proceedings of the National Academy of Sciences of the United States of America. 120 (27): e2218153120. Bibcode:2023PNAS..12018153G. doi:10.1073/pnas.2218153120. PMC 10318976. PMID 37364100.
  54. ^ Collareta, A.; Casati, S.; Di Cencio, A. (2023). "The Palaeobiology of the False Mako Shark, Parotodus benedenii (Le Hon, 1871): A View from the Pliocene Mediterranean Sea". Journal of Marine Science and Engineering. 11 (10). 1990. doi:10.3390/jmse11101990.
  55. ^ Collareta, A.; Merella, M.; Nobile, F.; Peri, E.; Bianucci, G. (2023). "Alopias grandis (Leriche, 1942) from the Miocene of Italy: insights on a rare species of giant thresher shark". Neues Jahrbuch für Geologie und Paläontologie – Abhandlungen. 309 (2): 93–103. doi:10.1127/njgpa/2023/1151. hdl:11568/1208627.
  56. ^ Villafaña, J. A.; Chávez-Hoffmeister, M. F.; Cumplido, N.; Campos-Medina, J.; Oyanadel-Urbina, P.; Rivadeneira, M. M. (2023). "The fossil distribution of two pelagic lamniform sharks Alopias vulpinus and Lamna nasus, from South America". Historical Biology: An International Journal of Paleobiology: 1–9. doi:10.1080/08912963.2023.2259409.
  57. ^ Ehret, D. J.; Tennyson, A. J. D.; Richards, M. D.; Boessenecker, R. W. (2023). "First records of two mackerel shark species (Carcharodon planus comb. nov. and Carcharodon hubbelli; Lamnidae) from New Zealand". Journal of the Royal Society of New Zealand: 1–11. doi:10.1080/03036758.2023.2278730. PMC 11459750.
  58. ^ Jambura, P. L.; Villalobos-Segura, E.; Türtscher, J.; Begat, A.; Staggl, M. A.; Stumpf, S.; Kindlimann, R.; Klug, S.; Lacombat, F.; Pohl, B.; Maisey, J. G.; Naylor, G. J. P.; Kriwet, J. (2023). "Systematics and Phylogenetic Interrelationships of the Enigmatic Late Jurassic Shark Protospinax annectans Woodward, 1918 with Comments on the Shark–Ray Sister Group Relationship". Diversity. 15 (3). 311. doi:10.3390/d15030311. PMC 7614347. PMID 36950326.
  59. ^ Ferrón, H. G. (2023). "Illuminating the evolution of bioluminescence in sharks". Palaeontology. 66 (1). e12641. Bibcode:2023Palgy..6612641F. doi:10.1111/pala.12641. hdl:10550/85586. S2CID 257206719.
  60. ^ Capasso, L.; Yamaguchi, A. (2023). "A batoid hembryo (Chondrichthyes: Batoidea), from the marine upper Cenomanian (Late Cretaceous) Sannine limestone of Hjoula, Lebanon". Historical Biology: An International Journal of Paleobiology. 36 (2): 293–308. doi:10.1080/08912963.2022.2162395. S2CID 256433989.
  61. ^ Reinecke, T.; Mollen, F. H.; Seitz, J. C.; Motomura, H.; Hovestadt, D.; Hoedemakers, K. (2023). "Iconography of jaws and representative teeth of extant rhinopristiform and dasyatoid batoids (Chondrichthyes, Elasmobranchii) for comparison with fossil batoid material". Palaeontos. 34: 3–158.
  62. ^ Pollerspöck, J.; Nielsen, K. A.; Feichtinger, I.; Straube, N. (2023). "New records of fossil deep-sea shark teeth from the Lillebælt Clay (Early–Middle Eocene) of Denmark". Bulletin of the Geological Society of Denmark. 72: 153–173. doi:10.37570/bgsd-2023-72-06. S2CID 261051166.
  63. ^ Kovalchuk, O.; Kriwet, J.; Shimada, K.; Ryabokon, T.; Barkaszi, Z.; Dubikovska, A.; Anfimova, G.; Davydenko, S. (2023). "Middle Eocene cartilaginous fishes (Vertebrata: Chondrichthyes) of the Dnieper–Donets Basin, northern Ukraine". Palaeontologia Electronica. 26 (2). 26.2.a32. doi:10.26879/1283. PMC 7616602.
  64. ^ Verma, S. K. (2023). "A new Bartonian elasmobranch assemblage from the Kutch Basin, western India, and its significance in the context of paleoclimate change". Historical Biology: An International Journal of Paleobiology: 1–24. doi:10.1080/08912963.2023.2238736. S2CID 260833551.
  65. ^ Höltke, O.; Maxwell, E. E.; Bracher, H.; Rasser, M. W. (2023). "The shark and ray teeth of the Lower Miocene (Upper Marine Molasse) from Ballendorf, Baden-Württemberg, Southern Germany". Palaeobiodiversity and Palaeoenvironments. 104: 153–180. doi:10.1007/s12549-023-00582-2. S2CID 260654351.
  66. ^ Villafaña, J. A.; Rivadeneira, M. M.; Pimiento, C.; Kriwet, J. (2023). "Diversification trajectories and paleobiogeography of Neogene chondrichthyans from Europe". Paleobiology. 49 (2): 329–341. Bibcode:2023Pbio...49..329V. doi:10.1017/pab.2022.40. PMC 7614935. PMID 37564372. S2CID 256722926.
  67. ^ Guinot, G.; Condamine, F. L. (2023). "Global impact and selectivity of the Cretaceous-Paleogene mass extinction among sharks, skates, and rays". Science. 379 (6634): 802–806. Bibcode:2023Sci...379..802G. doi:10.1126/science.abn2080. PMID 36821692. S2CID 257103123.
  68. ^ a b c d e f g h i j k l m n o p q r s t u v Bratishko, A.; Schwarzhans, W.; Vernyhorova, Y. (2023). "The endemic marine fish fauna from the Eastern Paratethys re-constructed from otoliths from the Miocene (middle Sarmatian s.l.; Bessarabian) of Jurkine (Kerch Peninsula, Crimea)". Rivista Italiana di Paleontologia e Stratigrafia. 129 (1): 111–184. doi:10.54103/2039-4942/18877. S2CID 257149317.
  69. ^ Štamberg, S.; Werneburg, R. (2023). "New genus and species of the family Aeduellidae (Actinopterygii) from the Lower Goldlauter Formation (Asselian, Lower Permian) of the Thuringian Forest (Germany)". Fossil Imprint. 79 (2): 144–151. doi:10.37520/fi.2023.008.
  70. ^ a b c d e f Pindakiewicz, M. K.; Hryniewicz, K.; Kaim, A. (2023). "Early Cretaceous radiation of teleosts recorded by the otolith-based ichthyofauna from the Valanginian of Wąwał, central Poland". Journal of Vertebrate Paleontology. 42 (6). e2232008. doi:10.1080/02724634.2023.2232008. S2CID 260293671.
  71. ^ Bannikov, A. F.; Erebakan, I. G. (2023). "A new species of horse mackerel fish of the genus Archaeus (Carangidae, Percomorpha) from the Lower Oligocene of the North Caucasus". Paleontological Journal. 57 (2): 199–205. Bibcode:2023PalJ...57..199B. doi:10.1134/S0031030123020041. S2CID 258640336.
  72. ^ a b Marramà, G.; Carnevale, G. (2023). "Double-armoured herrings (Clupeomorpha: Ellimmichthyiformes) from the Lower Cretaceous of Pietraroja (Southern Italy)". Journal of Systematic Palaeontology. 21 (1). 2181109. Bibcode:2023JSPal..2181109M. doi:10.1080/14772019.2023.2181109. S2CID 257475609.
  73. ^ a b c Lin, C.-H.; Wu, S.-M.; Lin, C.-Y.; Chien, C.-W. (2023). "Early Pliocene otolith assemblages from the outer-shelf environment reveal the establishment of mesopelagic fish fauna over 3 million years ago in southwestern Taiwan". Swiss Journal of Palaeontology. 142 (1). 23. Bibcode:2023SwJP..142...23L. doi:10.1186/s13358-023-00288-0.
  74. ^ Bannikov, A. F.; Zorzin, R. (2023). "† Bolcaperca craccorum, a new genus and species of incertae sedis percoid fish (Perciformes s.l.) from the Eocene of Bolca in northern Italy" (PDF). Studi e ricerche sui giacimenti terziari di Bolca, XXIII - Miscellanea Paleontologica. 20: 21–34.
  75. ^ Murray, A. M.; Nelson, L. E.; Brinkman, D. B. (2023). "A new sturgeon from the Upper Cretaceous Horseshoe Canyon Formation in central Alberta, Canada". Journal of Vertebrate Paleontology. 43 (1). e2232846. doi:10.1080/02724634.2023.2232846. S2CID 260752194.
  76. ^ a b c d e f Schwarzhans, W.; von der Hocht, F. (2023). "New otolith assemblages from the Miocene of the North Sea Basin and their biostratigraphic significance". Cainozoic Research. 23 (2): 189–227.
  77. ^ a b c d Schwarzhans, W. W.; Nielsen, K. A. (2023). "Fish otoliths from the bathyal Eocene Lillebælt Clay Formation of Denmark". Bulletin of the Geological Society of Denmark. 72: 207–219. doi:10.37570/bgsd-2023-72-08.
  78. ^ Schrøder, A. E.; Rasmussen, J. A.; Møller, P. R.; Carnevale, G. (2023). "Butyrumichthys henricii gen. et sp. nov.: a new stromateiform fish from the lower Eocene Fur Formation, Denmark". Journal of Vertebrate Paleontology. 42 (3). e2171798. doi:10.1080/02724634.2023.2171798. S2CID 257371994.
  79. ^ a b c d e f g h i j k l m n o p q Schwarzhans, W. (2023). "Geology and stratigraphy of the Neogene section along the Oued Beth between Dar bel Hamri and El Kansera (Rharb Basin, northwestern Morocco) and its otolith-based fish fauna: a faunal inventory for the Early Pliocene remigration into the Mediterranean". Swiss Journal of Palaeontology. 142 (1). 4. Bibcode:2023SwJP..142....4S. doi:10.1186/s13358-023-00268-4.
  80. ^ de Mayrinck, D.; Ribeiro, A. C.; Assine, M. L.; Spigolon, A. L. D. (2023). "A New Genus and Species of †Cladocyclidae (Teleostei: †Ichthyodectiformes) from the Lower Cretaceous "Batateira Beds", Barbalha Formation, Araripe Basin: The First Vertebrate Record in a Still Poorly Explored Fossil Site". Diversity. 15 (3). 413. doi:10.3390/d15030413.
  81. ^ Chida, M.; Brinkman, D. B.; Murray, A. M. (2023). "A large, new dercetid fish (Teleostei: Aulopiformes) from the Campanian Bearpaw Formation of Alberta, Canada". Cretaceous Research. 150. 105579. Bibcode:2023CrRes.15005579C. doi:10.1016/j.cretres.2023.105579. S2CID 258803963.
  82. ^ Xu, G.-H.; Ma, X.-Y. (2023). "A new basal ginglymodian fish (Holostei: Neopterygii) from the Middle Triassic (Anisian) Luoping Biota, Yunnan, China". Zoological Journal of the Linnean Society. doi:10.1093/zoolinnean/zlad144.
  83. ^ a b c d e f Schwarzhans, W.; Scofield, R. P.; Tennyson, A. J. D.; Worthy, J. P.; Worthy, T. H. (2023). "The 'Gulliver' fish fauna of an early Miocene freshwater system of New Zealand; new insights from otoliths from the Bannockburn Formation". New Zealand Journal of Geology and Geophysics. 66 (1): 102–129. Bibcode:2023NZJGG..66..102S. doi:10.1080/00288306.2022.2153878. S2CID 256152843.
  84. ^ Cooper, S. L. A.; Gunn, J.; Brito, P. M.; Zouhri, S.; Martill, D. M. (2023). "A new fully marine, short-snouted lepisosteid gar from the Upper Cretaceous (Turonian) of North Africa". Cretaceous Research. 151. 105650. Bibcode:2023CrRes.15105650C. doi:10.1016/j.cretres.2023.105650. S2CID 259520870.
  85. ^ Andrews, J. V.; Schein, J. P.; Friedman, M. (2023). "An earliest Paleocene squirrelfish (Teleostei: Beryciformes: Holocentroidea) and its bearing on the timescale of holocentroid evolution". Journal of Systematic Palaeontology. 21 (1). Bibcode:2023JSPal..2168571A. doi:10.1080/14772019.2023.2168571. S2CID 257336234.
  86. ^ Deesri, U.; Naksri, W.; Jintasakul, P.; Noda, Y.; Yukawa, H.; El Hossny, T.; Cavin, L. (2023). "A New Sinamiin Fish (Actinopterygii) from the Early Cretaceous of Thailand: Implications on the Evolutionary History of the Amiid Lineage". Diversity. 15 (4). 491. doi:10.3390/d15040491.
  87. ^ a b Esin, D. N.; Bakaev, A. S. (2022). "New Ray-Finned Fishes (Actinopterygii, Osteichthyes) from the Permian of European Russia". Paleontological Journal. 56 (11): 1352–1362. Bibcode:2022PalJ...56.1352E. doi:10.1134/S0031030122110053. S2CID 256618248.
  88. ^ Recinos, M.; Cantalice, K. M.; Caballero-Viñas, C.; Alvarado-Ortega, J. (2023). "A new Mesozoic teleost of the subfamily Albulinae (Albuliformes: Albulidae) highlights the proto-Gulf of Mexico in the early diversification of extant bonefishes". Journal of Systematic Palaeontology. 21 (1). 2223797. Bibcode:2023JSPal..2123797L. doi:10.1080/14772019.2023.2223797. S2CID 259896770.
  89. ^ a b Schwarzhans, W. W.; Bratishko, A.; Vernyhorova, Y. V. (2023). "Approaching the Khersonian Crisis: Fish otoliths from the upper Bessarabian (middle Sarmatian s.l.; Late Miocene) of Jurkine (Kerch Peninsula, Crimea)". Palaeontologia Electronica. 26 (2). 26.2.a31. doi:10.26879/1300.
  90. ^ a b c d Bulanov, V. V.; Minikh, A. V.; Golubev, V. K. (2022). "Minicholepis primus gen. et sp. nov., a New Eurynotoidiform Fish (Actinopterygii) from the Permian of European Russia". Paleontological Journal. 56 (11): 1363–1371. Bibcode:2022PalJ...56.1363B. doi:10.1134/S0031030122110041. S2CID 256618572.
  91. ^ Capasso, L. (2023). "Nursallia fenestrata n. sp. (Actinopterygii: Pycnodontiformes) dal Turoniano inferiore della Formazione di Akrabou, Marocco sudorientale". Thalassia Salentina. 45: 41–56. doi:10.1285/i15910725v45p41.
  92. ^ Yabumoto, Y.; Zhang, C. (2023). "A New Miocene Gobiiform Fish, Odontobutis hayashitokuei from Iki, Nagasaki, Japan". Paleontological Research. 27 (4): 383–395. doi:10.2517/PR210039. S2CID 257430557.
  93. ^ Stringer, G. L.; Sloan, J. C. (2023). "First Cretaceous telostean otolith assemblage (Arkadelphia Formation, upper Maastrichtian) from Arkansas, USA, early Gadiformes, and the Western Interior Seaway". PaleoBios. 40 (3): 1–39. doi:10.5070/P940361192. S2CID 258913941.
  94. ^ Caballero-Viñas, C.; Alvarado-Ortega, J.; Cantalice Severiano, K. M. (2023). "A Pliocene goodeid fish of the Paleolake Amajac, Sanctórum, Hidalgo, Mexico". Palaeontologia Electronica. 26 (2). 26.2.a30. doi:10.26879/1259.
  95. ^ a b Hilton, E. J.; During, M. A. D.; Grande, L.; Ahlberg, P. E. (2023). "New paddlefishes (Acipenseriformes, Polyodontidae) from the Late Cretaceous Tanis Site of the Hell Creek Formation in North Dakota, USA". Journal of Paleontology. 97 (3): 675–692. Bibcode:2023JPal...97..675H. doi:10.1017/jpa.2023.19. S2CID 258095684.
  96. ^ Caron, A.; Venkataraman, V.; Tietjen, K.; Coates, M. (2023). "A fish for Phoebe: a new actinopterygian from the Upper Carboniferous Coal Measures of Saddleworth, Greater Manchester, UK, and a revision of Kansasiella eatoni". Zoological Journal of the Linnean Society. 198 (4): 957–981. doi:10.1093/zoolinnean/zlad011.
  97. ^ Brito, P. M.; Vullo, R. (2023). "A new species of Pleuropholis (Teleostei: Pleuropholidae) from the Upper Cretaceous Akrabou Formation of southeastern Morocco, with comments on the evolutionary history of the genus" (PDF). Cretaceous Research. 148. 105500. Bibcode:2023CrRes.14805500B. doi:10.1016/j.cretres.2023.105500. S2CID 256784101.
  98. ^ El Hossny, T.; Cavin, L.; Kaplan, U.; Schwermann, A. H.; Samankassou, E.; Friedman, M. (2023). "The first articulated skeletons of enigmatic Late Cretaceous billfish-like actinopterygians". Royal Society Open Science. 10 (12). 231296. Bibcode:2023RSOS...1031296E. doi:10.1098/rsos.231296. PMC 10698480. PMID 38077217.
  99. ^ a b c d Calzoni, P.; Amalfitano, J.; Giusberti, L.; Marramà, G.; Carnevale, G. (2023). "Eocene Rhamphosidae (Teleostei: Syngnathiformes) from the Bolca Lagerstätte, Italy". Rivista Italiana di Paleontologia e Stratigrafia. 129 (3): 573–607. doi:10.54103/2039-4942/20707. hdl:11577/3496820.
  100. ^ Fang, G.-Y.; Sun, Y.-L.; Ji, C.; Wu, F.-X. (2022). "First record of Saurichthys (Actinopterygii: Saurichthyidae) from the Late Triassic of eastern Paleo-Tethys". Vertebrata PalAsiatica. 61 (1): 1–16. doi:10.19615/j.cnki.2096-9899.221013.
  101. ^ Carrillo-Briceño, J. D.; Mora-Rojas, L.; Hendricks, K.; Vanegas, A.; Aguilera, O. (2023). "New clues on the palaeodiversity of the middle Miocene freshwater ichthyofauna from the Tatacoa Desert, Colombia". Geodiversitas. 45 (10): 327–351. doi:10.5252/geodiversitas2023v45a10. S2CID 259212958.
  102. ^ Nazarkin, M. V. (2023). "A saw-toothed eel †Serrivomer glehni sp. nov. from the Miocene of Sakhalin Island, north-western Pacific". Journal of Vertebrate Paleontology. 43 (2). e2261505. doi:10.1080/02724634.2023.2261505.
  103. ^ Capasso, L. (2023). "Stanhopella elongata n. gn. et n. sp. (Actinopterygii, †Pycnodontiformes) from the marine upper Cenomanian (Late Cretaceous) of En Nammoura (Central Lebanon)" (PDF). Bollettino del Museo Civico di Storia Naturale di Verona. 47: 89–102.
  104. ^ Schrøder, A. E.; Carnevale, G. (2023). "The argentiniform Surlykus longigracilis gen. et sp. nov., the most abundant fish from the Eocene Fur Formation of Denmark". Bulletin of the Geological Society of Denmark. 72: 1–18. doi:10.37570/bgsd-2023-72-01. S2CID 256352870.
  105. ^ Than-Marchese, B. A.; Alvarado-Ortega, J.; Murray, A. M.; Velázquez-Velázquez, E.; Domínguez Domínguez, O. (2023). "First report of the genus Thorectichthys (Ellimmichthyiformes) in America, from the Cenomanian deposits of the Cintalapa Formation, Chiapas, southeastern Mexico". Cretaceous Research. 154. 105739. doi:10.1016/j.cretres.2023.105739.
  106. ^ De Schutter, P. J.; Everaert, S.; Gale, A.; Van Remoortel, W.; De Borger, G.; Sakala, J.; Koutecký, V.; Hoedemakers, K. (2023). "An exceptional concentration of marine fossils associated with wood-fall in the Terhagen Member (Boom Formation; Schelle, Belgium), Rupelian of the southern North Sea Basin". Geologica Belgica. 26 (1–2): 41–78. doi:10.20341/gb.2023.003. S2CID 260401823.
  107. ^ Murray, A. M.; Brinkman, D. B.; Friedman, M.; Krause, D. W. (2023). "A large, freshwater chanid fish (Ostariophysi: Gonorynchiformes) from the Upper Cretaceous of Madagascar". Journal of Vertebrate Paleontology. 43 (2). e2255630. doi:10.1080/02724634.2023.2255630.
  108. ^ El Hossny, T.; Cavin, L. (2023). "A New Enigmatic Teleost Fish from the Mid-Cretaceous of Lebanon". Diversity. 15 (7). 839. doi:10.3390/d15070839.
  109. ^ Bannikov, A. F.; Zorzin, R. (2023). "A new genus and two new species of Monodactylidae (Perciformes s.l.) from the Eocene of northern Italy (Bolca: Monte Postale and Pesciara)" (PDF). Studi e ricerche sui giacimenti terziari di Bolca, XXIII - Miscellanea Paleontologica. 20: 5–20.
  110. ^ Figueroa, R. T.; Goodvin, D.; Kolmann, M. A.; Coates, M. I.; Caron, A. M.; Friedman, M.; Giles, S. (2023). "Exceptional fossil preservation and evolution of the ray-finned fish brain". Nature. 614 (7948): 486–491. Bibcode:2023Natur.614..486F. doi:10.1038/s41586-022-05666-1. PMID 36725931. S2CID 249475791.
  111. ^ Bakaev, A. S.; Johanson, Z.; LeBlanc, A. (2023). "The dental system of †Kazanichthys viatkensis (Actinopterygii, Acrolepididae) from the middle Permian of European Russia: palaeobiological and palaeoecological inferences". Papers in Palaeontology. 9 (4). e1512. Bibcode:2023PPal....9E1512B. doi:10.1002/spp2.1512. S2CID 260008805.
  112. ^ Bakaev, A. S. (2023). "Revision of Permian Ray-Finned Fishes from the Kazankovo-Markino Formation of the Kuznetsk Basin". Paleontological Journal. 57 (3): 335–342. Bibcode:2023PalJ...57..335B. doi:10.1134/S0031030123030036. S2CID 259336344.
  113. ^ Martill, D. M. (2023). "A sturgeon (Actinopterygii, Acipenseriformes) from the Upper Cretaceous of Africa". Cretaceous Research. 148. 105546. Bibcode:2023CrRes.14805546M. doi:10.1016/j.cretres.2023.105546. S2CID 257863907.
  114. ^ Giordano, P. G.; Benavente, C. A.; Suárez, S. A. (2023). "Macro- and micromorphology of scales from an endemic South American actinopterygian family (Pseudobeaconiidae, Triassic, Cuyana Basin)". Ameghiniana. 60 (2): 164–177. doi:10.5710/AMGH.03.02.2023.3540. S2CID 256622326.
  115. ^ Feng, D.-H.; Xu, G.-H.; Ma, X.-Y.; Ren, Y. (2023). "Taxonomic revision of Sinoeugnathus kueichowensis (Halecomorphi, Holostei) from the Middle Triassic of Guizhou and Yunnan, China". Vertebrata PalAsiatica. 61 (3): 161–181. doi:10.19615/j.cnki.2096-9899.230703.
  116. ^ Sullivan, R. M.; Jasinski, S. E.; Williamson, T. E. (2023). "The first articulated skull roof and braincase of Melvius chauliodous (Amiidae, Vidalamiinae) from the Upper Cretaceous Kirtland Formation, San Juan Basin, New Mexico". Journal of Vertebrate Paleontology. 43 (2). e2264341. doi:10.1080/02724634.2023.2264341.
  117. ^ Weryński, Ł.; Błażejowski, B.; Kędzierski, M. (2023). "A comparison of teeth in Tithonian, Late Jurassic, predatory actinopterygian fishes from Owadów-Brzezinki Lägerstatte and its palaeoecological implications". Acta Palaeontologica Polonica. 68 (3): 493–512. doi:10.4202/app.01058.2023.
  118. ^ López-Arbarello, A.; Ebert, M. (2023). "Taxonomic status of the caturid genera (Halecomorphi, Caturidae) and their Late Jurassic species". Royal Society Open Science. 10 (1). 221318. Bibcode:2023RSOS...1021318L. doi:10.1098/rsos.221318. PMC 9832298. PMID 36686548.
  119. ^ Bogan, S.; Taverne, L.; Agnolin, F. (2013). "First Triassic and oldest record of a South American amiiform fish: Caturus sp. from the Los Menucos Group (lower Upper Triassic), Río Negro province, Argentina". Geologica Belgica. 16 (3): 191–195.
  120. ^ López-Arbarello, A.; Concheyro, A.; Palma, R. M.; Aguirre-Urreta, B. (2023). "The early fossil record of Caturoidea (Halecomorphi: Amiiformes): biogeographic implications". Swiss Journal of Palaeontology. 142 (1). 33. Bibcode:2023SwJP..142...33L. doi:10.1186/s13358-023-00297-z.
  121. ^ Cooper, S. L. A.; Maxwell, E. E. (2023). "Death by ammonite: fatal ingestion of an ammonoid shell by an Early Jurassic bony fish". Geological Magazine. 160 (7): 1254–1261. Bibcode:2023GeoM..160.1254C. doi:10.1017/S0016756823000456. S2CID 260230492.
  122. ^ Mayrinck, D.; Meunier, F. J.; Cupello, C.; Brito, P. M. (2023). "The paleohistology of †Araripichthys castilhoi from the Lower Cretaceous of Araripe Basin, Northeastern Brazil: a typical case of basal teleost". Journal of Vertebrate Paleontology. 42 (2). e2157732. doi:10.1080/02724634.2022.2157732. S2CID 255660485.
  123. ^ Stinnesbeck, E. S.; Herder, F.; Rust, J.; Stinnesbeck, W. (2023). "Taphonomy of the teleost Tselfatia formosa Arambourg, 1943 from Vallecillo, NE Mexico". PLOS ONE. 18 (2). e0280797. Bibcode:2023PLoSO..1880797S. doi:10.1371/journal.pone.0280797. PMC 9891505. PMID 36724176.
  124. ^ Cooper, S. L. A.; Norton, J. L. (2023). "Youngest occurrence of a plethodid fish (Teleostei: Tselfatiiformes: Plethodidae) from the Maastrichtian of North Africa". Cretaceous Research. 152. 105673. Bibcode:2023CrRes.15205673C. doi:10.1016/j.cretres.2023.105673. S2CID 260798016.
  125. ^ Taverne, L.; Capasso, L. (2023). "New data on the osteology of Sorbinichthys elusivo (Teleostei, Clupeomorpha, Ellimmichthyiformes) from the marine Cenomanian (Upper Cretaceous) of Lebanon and on the phylogenetic relationships of the genus Sorbinichthys" (PDF). Geo-Eco-Trop. 46 (2): 159–174.
  126. ^ Candeiro, C. R. A.; Brito, P. M.; Cavin, L.; Alves, Y. M.; Canile, F.; Muniz, F.; Queiroz, G. K.; Santos, D.; Toriño, P. (2023). "First record of Siluriformes from the northernmost portion of the Bauru Group (Upper Cretaceous) in the center-west region of Brazil". Journal of South American Earth Sciences. 133. 104690. doi:10.1016/j.jsames.2023.104690.
  127. ^ Friedman, M.; Andrews, J. V.; Saad, H.; El-Sayed, S. (2023). "The Cretaceous–Paleogene transition in spiny-rayed fishes: surveying "Patterson's Gap" in the acanthomorph skeletal record". Geologica Belgica. 26 (1–2): 1–23. doi:10.20341/gb.2023.002. S2CID 259477507.
  128. ^ Murray, A. M.; Brinkman, D. B. (2023). "Morphological variation in the first abdominal vertebra among acanthomorph fishes – a guide for identifying fossil centra from microvertebrate sites". Vertebrate Anatomy Morphology Palaeontology. 11: 42–90. doi:10.18435/vamp29392. S2CID 260942423.
  129. ^ Rust, S.; Robinson, J. H. (2023). "Revisiting Eothyrsites holosquamatus Chapman (Trichiuroidea: Gempylidae), an Eocene gemfish from the Burnside Mudstone, Dunedin, New Zealand". Journal of the Royal Society of New Zealand: 1–18. doi:10.1080/03036758.2023.2228211. PMC 11459795. S2CID 259880404.
  130. ^ De Gracia, C.; Berning, B.; Kriwet, J. (2023). "The origin of modern marlins (Teleostei: Istiophoridae): new fossil evidence from the Lower Miocene of Austria". Journal of Vertebrate Paleontology. 43 (2). e2281490. doi:10.1080/02724634.2023.2281490.
  131. ^ Bannikov, A. F.; Zorzin, R. (2023). "On the osteology and relationships of the genus †Callipteryx Agassiz (Perciformes s.l.) from the Eocene of Bolca in northern Italy" (PDF). Studi e ricerche sui giacimenti terziari di Bolca, XXIII - Miscellanea Paleontologica. 20: 35–44.
  132. ^ Ngoepe, N.; Muschick, M.; Kishe, M. A.; Mwaiko, S.; Temoltzin-Loranca, Y.; King, L.; Courtney Mustaphi, C.; Heiri, O.; Wienhues, G.; Vogel, H.; Cuenca-Cambronero, M.; Tinner, W.; Grosjean, M.; Matthews, B.; Seehausen, O. (2023). "A continuous fish fossil record reveals key insights into adaptive radiation". Nature. 622 (7982): 315–320. Bibcode:2023Natur.622..315N. doi:10.1038/s41586-023-06603-6. PMC 10567567. PMID 37794187.
  133. ^ Agiadi, K.; Quillévéré, F.; Nawrot, R.; Sommeville, T.; Coll, M.; Koskeridou, E.; Fietzke, J.; Zuschin, M. (2023). "Palaeontological evidence for community-level decrease in mesopelagic fish size during Pleistocene climate warming in the eastern Mediterranean". Proceedings of the Royal Society B: Biological Sciences. 290 (1990). 20221994. doi:10.1098/rspb.2022.1994. PMC 9832546. PMID 36629116.
  134. ^ a b Elliott, F. M.; Challands, T. J.; Smithson, T. R. (2023). "Dipnoan diversity in the early Pennsylvanian of Scotland: new lungfish from the Lower Coal Measures of North Lanarkshire". Scottish Journal of Geology. 59 (1–2). sjg2023-006. Bibcode:2023ScJG...59....6E. doi:10.1144/sjg2023-006. S2CID 259577823.
  135. ^ a b Minikh, A. O. (2022). "A New Species of the Genus Ceratodus (Dipnoi, Ceratodontidae) from the Triassic of the Southern Cis-Urals". Paleontological Journal. 56 (11): 1385–1390. Bibcode:2022PalJ...56.1385M. doi:10.1134/S0031030122110090. S2CID 256618440.
  136. ^ Downs, J. P.; Osatchuck, M. M.; Goodchild, O. A.; Daeschler, E. B. (2023). "Second species of Eusthenodon (Tristichopteridae, Sarcopterygii) from the Upper Devonian (Famennian) Catskill Formation of Pennsylvania, U.S.A., and a review of global Eusthenodon occurrence". Journal of Vertebrate Paleontology. 42 (5). e2201627. doi:10.1080/02724634.2023.2201627. S2CID 258780944.
  137. ^ Gess, R. W.; Ahlberg, P. E. (2023). "A high latitude Gondwanan species of the Late Devonian tristichopterid Hyneria (Osteichthyes: Sarcopterygii)". PLOS ONE. 18 (2). e0281333. Bibcode:2023PLoSO..1881333G. doi:10.1371/journal.pone.0281333. PMC 9946258. PMID 36812170.
  138. ^ Johanson, Z.; Newman, M. J.; Rangel-De Lazaro, G.; Smith, M. M.; Jones, R. (2023). "A new dipnoan species Janvierpaucidentes tuulingi gen. et sp. nov. from the Pragian (Early Devonian) of Mimerdalen, Svalbard (Norway), with an unusual dentition". Spanish Journal of Palaeontology. 38 (1): 69–80. doi:10.7203/sjp.26647. S2CID 258855502.
  139. ^ Elliott, F. M. (2023). "On a new species of Rhizodopsis from the Carboniferous of Scotland". Scottish Journal of Geology. 59 (1–2). sjg2023-008. Bibcode:2023ScJG...59....8E. doi:10.1144/sjg2023-008. S2CID 259563349.
  140. ^ Ferrante, C.; Cavin, L. (2023). "Early Mesozoic burst of morphological disparity in the slow-evolving coelacanth fish lineage". Scientific Reports. 13 (1). 11356. Bibcode:2023NatSR..1311356F. doi:10.1038/s41598-023-37849-9. PMC 10345187. PMID 37443368.
  141. ^ Ferrante, C.; Furrer, H.; Martini, R.; Cavin, L. (2023). "Revision of the Middle Triassic coelacanth Ticinepomis Rieppel 1980 (Actinistia, Latimeriidae) with paleobiological and paleoecological considerations". Swiss Journal of Palaeontology. 142 (1). 18. Bibcode:2023SwJP..142...18F. doi:10.1186/s13358-023-00276-4. PMC 10495523. PMID 37706074.
  142. ^ Brownstein, Chase D. (2023-03-30). "A large coelacanth, †Whiteia giganteus sp. nov., from the Triassic of Texas, USA, establishes a Pangean radiation of early Mesozoic actinistians". Palaeontologia Electronica. 26 (1): 1–12. doi:10.26879/1254. ISSN 1094-8074. S2CID 257883832.
  143. ^ Dupret, V.; Byrne, H.; Challands, T.; Hammer, Ø.; Higgs, K.; Long, J.; Niedźwiedzki, G.; Qvarnström, M.; Stössel, I.; Ahlberg, P. E. (2023). "Non-tetrapod sarcopterygians from the Valentia Slate Formation (Givetian, Devonian) of the Iveragh Peninsula, south-western Ireland: systematic reappraisal and palaeobiogeographic implications". Spanish Journal of Palaeontology. 38 (1): 37–45. doi:10.7203/sjp.26527. hdl:20.500.11850/621947. S2CID 259033690.
  144. ^ Kuznetsov, A. N.; Kryukova, N. V. (2023). "Reconstructing the subcephalic musculature in Pucapampella and Ichthyostega". Journal of Morphology. 284 (12). e21648. doi:10.1002/jmor.21648. PMID 37990766.
  145. ^ Baucon, A.; Ferretti, A.; Fioroni, C.; Pandolfi, L.; Serpagli, E.; Piccinini, A.; de Carvalho, C. N.; Cachão, M.; Linley, T.; Muñiz, F.; Belaústegui, Z.; Jamieson, A.; Lo Russo, G.; Guerrini, F.; Ferrando, S.; Priede, I. (2023). "The earliest evidence of deep-sea vertebrates". Proceedings of the National Academy of Sciences of the United States of America. 120 (37). e2306164120. Bibcode:2023PNAS..12006164B. doi:10.1073/pnas.2306164120. PMC 10500276. PMID 37669391. S2CID 261556179.
  146. ^ Trif, N.; Codrea, V. A.; Pleș, G.; Bordeianu, M. (2023). "The Priabonian fish from Leghia (Transylvanian Basin, Romania)". Historical Biology: An International Journal of Paleobiology: 1–14. doi:10.1080/08912963.2023.2253273.