2024 in paleoichthyology

This list of fossil fish research presented in 2024 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 2024.

List of years in paleoichthyology
In paleontology
2021
2022
2023
2024
2025
2026
2027
In paleobotany
2021
2022
2023
2024
2025
2026
2027
In arthropod paleontology
2021
2022
2023
2024
2025
2026
2027
In paleoentomology
2021
2022
2023
2024
2025
2026
2027
In paleomalacology
2021
2022
2023
2024
2025
2026
2027
In reptile paleontology
2021
2022
2023
2024
2025
2026
2027
In archosaur paleontology
2021
2022
2023
2024
2025
2026
2027
In paleomammalogy
2021
2022
2023
2024
2025
2026
2027

Jawless vertebrates

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Name Novelty Status Authors Age Type locality Location Notes Images

Caeruleum gracilis[1]

Sp. nov

Valid

Huang et al.

Early Cretaceous

Jiufotang Formation

  China

A lamprey.

 

Changxingaspis nianzhongi[2]

Sp. nov

Valid

Li et al.

Silurian

Tataertag Formation

  China

A member of Galeaspida belonging to the family Xiushuiaspidae.

Miaojiaaspis[3]

Gen. et sp. nov

Valid

Chen et al.

Silurian (Telychian)

Huixingshao Formation

  China

A member of Galeaspida belonging to the group Eugaleaspiformes and the family Tujiaaspidae. The type species is M. dichotomus.

Orthogoniaspis amnicus[4]

Sp. nov

Elliott

Devonian

  Canada
(  Nunavut)

A member of Heterostraci belonging to the family Weigeltaspididae.

Jawless vertebrate research

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  • A study on the evolutionary history of hagfishes, as indicated by the fossil record and molecular data, is published by Brownstein & Near (2024), who consider the hagfish crown group to be a lineage with Early Permian origin and a long history in continental slope settings.[5]
  • Brookfield (2024) interprets Jamoytius kerwoodi as a probable detritivore or herbivore feeding on Dictyocaris (interpreted by the author as possible algal thalli).[6]
  • Evidence interpreted as indicating that oral plates of pteraspid heterostracans had a mechanical function and that the studied heterostracans likely had a bottom-dwelling feeding mode, such as deposit feeding or scavenging, is presented by Grohganz et al. (2024).[7]
  • Botella, Fariña & Huera-Huarte (2024) present evidence indicating that, in spite of lacking movable appendages other than tail fin, members of Pteraspidiformes were able to colonize the water column because the shape of their head shield made to possible for them attain high lift forces in a way similar to delta wings.[8]
  • Description of the feeding apparatus of Rhinopteraspis dunensis, interpreted as composed of 13 plates that were capable of rotating around the transverse axis, is published by Dearden et al. (2024), who interpret R. dunensis as a suspension or deposit feeder.[9]
  • Shan et al. (2024) describe new fossil material of "Dongfangaspis" qujingensis and Damaspis vartus from the Devonian Xishancun Formation (China), and reinterpret "D." qujingensis as a member of the genus Damaspis.[10]

Placoderms

edit

Placoderm research

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  • Jobbins et al. (2024) describe new fossil material of Alienacanthus malkowskii, providing evidence of elongation of the lower jaw which was twice as long as the skull.[11]
  • Engelman (2024) presents a new reconstruction of Dunkleosteus terrelli, and provides the anatomical basis for the reconstruction including a stout, deep trunk.[12]

Cartilaginous fishes

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Name Novelty Status Authors Age Type locality Country Notes Images

Aellopobatis[13]

Gen. et sp. nov

Valid

Türtscher et al.

Late Jurassic (Tithonian)

  Germany

A member of Batomorphii belonging to the family Spathobatidae. The type species is A. bavarica.

Amtaaguar[14]

Gen. et comb. nov

De Pasqua et al.

Neogene

  Argentina
  France
  United States

An eagle ray. The type species is "Myliobatis" crassus (Gervais, 1859).

Belgabatis[15]

Gen. et comb. nov

Valid

Reinecke et al.

Paleogene

  Belgium

A dasyatoid batomorph. The type species is "Dasyatis" thierryi Smith (1999).

Casierabatis[15]

Gen. et sp. comb. nov

Valid

Reinecke et al.

Paleogene

  Belgium

A dasyatoid batomorph. Genus includes new species C. lambrechtsi, as well as "Trygon" jaekeli Leriche (1905).

Centrodeania[16]

Gen. et 2 sp. nov

Valid

Feichtinger et al.

Paleocene (Danian)

Oiching Formation

  Austria

A member of the family Centrophoridae. The type species is C. rugosa; genus also includes C. annae.

Chlamydoselachus kamchaticus[17]

Sp. nov

Valid

Malyshkina & Nazarkin

Eocene

Peresheek Mountain Formation

  Russia
(  Kamchatka Krai)

A species of Chlamydoselachus.

Columnaodus[18]

Gen. et sp. nov

Valid

Cicimurri et al.

Carboniferous (Mississippian)

Contact horizon between Burlington and Keokuk Limestones

  United States
(  Illinois
  Iowa)

A member of Hybodontoidea of uncertain affinities. The type species is C. witzkei.

Cosmoselachus[19]

Gen. et sp. nov

Valid

Bronson et al.

Carboniferous (Mississippian)

Fayetteville Shale

  United States
(  Arkansas)

A member of the family Falcatidae. The type species is C. mehlingi.

Danodalatias[20]

Gen. et sp. et comb. nov

Valid

Popov, Lopyrev & Yarkov

Paleocene

  New Zealand
  Russia
(  Volgograd Oblast)

A member of the family Dalatiidae. Genus includes new species D. ochevi, as well as "Centroselachus" goordi Mannering & Hiller (2008).

Eostriatolamia iktensis[21]

Sp. nov

Valid

Duffin & Batchelor

Early Cretaceous (Aptian)

Vectis Formation

  United Kingdom

A member of Lamniformes.

Essexraja[15]

Gen. et sp. nov

Valid

Reinecke et al.

Eocene

London Clay

  United Kingdom

A batomorph. The type species is E. ypresiensis.

Eurasiabatis[15]

Gen. et sp. nov

Valid

Reinecke et al.

Paleogene

Tielt Formation

  Belgium

A batomorph. The type species is E. occlusostriata.

Glaucopristis[15]

Gen. et comb. nov

Valid

Reinecke et al.

Paleogene

  Belgium

A rhinopristiform batomorph. The type species is "Rhinobatus" bruxelliensis Jaekel (1894).

Glikmanius careforum[22]

Sp. nov

Valid

Hodnett et al.

Carboniferous (Mississippian)

  United States
(  Alabama
  Kentucky)

Gunnellia[23]

Gen. et sp. nov

Valid

Ivanov & Duffin

Carboniferous

  Russia
(  Moscow Oblast)

A member of the family Anachronistidae. The type species is G. tatianae.

Gyracanthides riniensis[24]

Sp. nov

Valid

Gess & Burrow

Devonian (Famennian)

Waterloo Farm lagerstätte

  South Africa

A gyracanthid acanthodian.

Gyracanthus? jasperi[25]

Sp. nov

Valid

Snyder, Burrow & Turner

Carboniferous (Mississippian)

Ste. Genevieve Formation

  United States
(  Iowa)

A gyracanthid acanthodian.

Heterodontus adneti[26]

Sp. nov

Valid

Migom

Eocene

  France

A bullhead shark.

Incognitorapax[16]

Gen. et sp. nov

Valid

Feichtinger et al.

Late Cretaceous (Maastrichtian) and Paleocene (Danian)

  Austria
  Germany

A member of the family Etmopteridae. The type species is I. fernsebneri.

Orthacanthus adamas[27]

Nom. nov

Valid

Babcock

Carboniferous

Upper Freeport Coal

  United States
(  Ohio)

A replacement name for Orthacanthus gracilis Newberry (1875).

Orthacanthus lintonensis[27]

Nom. nov

Valid

Babcock

Carboniferous

Upper Freeport Coal

  United States
(  Ohio)

A replacement name for Diplodus gracilis Newberry (1857).

Palaeohypotodus bizzocoi[28]

Sp. nov

Valid

Ebersole, Cicimurri & Harrell

Paleocene (Danian)

Porters Creek Formation

  United States
(  Alabama)

A member of Lamniformes belonging to the family Jaekelotodontidae.

Parvodus ominechonensis[29]

Sp. nov

Valid

Breeden et al.

Late Triassic (Carnian)

Momonoki Formation

  Japan

A lonchidiid hybodontiform.

Pteroscyllium downesi[30]

Sp. nov

Valid

Duffin & Batchelor

Early Cretaceous (Aptian)

Atherfield Clay Formation

  United Kingdom

A carcharhiniform shark with affinities with catsharks.

Pteroscyllium sweetmani[21]

Sp. nov

Valid

Duffin & Batchelor

Early Cretaceous (Aptian)

Vectis Formation

  United Kingdom

Scyliorhinus alaformis[16]

Sp. nov

Valid

Feichtinger et al.

Paleocene (Danian)

Oiching Formation

  Austria

A species of Scyliorhinus.

Serratodasyatis[15]

Gen. et comb. nov

Valid

Reinecke et al.

Paleogene

  Belgium

A dasyatoid batomorph. The type species is "Dasyatis" tricuspidatus Casier (1946).

Sheppeytrygon[15]

Gen. et comb. nov

Valid

Reinecke et al.

Eocene

London Clay

  United Kingdom

A dasyatoid batomorph. The type species is "Dasyatis" davisi Casier (1966).

Troglocladodus[22]

Gen. et sp. nov

Valid

Hodnett et al.

Carboniferous (Mississippian)

  United States
(  Alabama
  Kentucky)

A ctenacanthid. Genus includes T. trimblei.

Turovella[23]

Gen. et sp. nov

Valid

Ivanov & Duffin

Carboniferous

  Russia
(  Moscow Oblast)

A member of the family Anachronistidae. The type species is T. lebedevi.

Vectiscyllium[30]

Gen. et sp. nov

Valid

Duffin & Batchelor

Early Cretaceous (Aptian)

Atherfield Clay Formation

  United Kingdom

A carcharhiniform shark with affinities with catsharks. The type species is V. atherfieldensis.

Xampylodon diastemacron[31]

Sp. nov

Dos Santos et al.

Late Cretaceous (Maastrichtian)

Lopez de Bertodano Formation

Antarctica

A cow shark.

Cartilaginous fish research

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  • Schnetz et al. (2024) study the completeness of the Paleozoic fossil record of chondrichthyans, finding it to be significantly lower compared to other investigated vertebrate groups.[32]
  • A study on the diversification of chondrichthyans throughout the Paleozoic is published by Schnetz et al. (2024), who report evidence indicative of two increases of diversification rates in the earliest Devonian and in the earliest Carboniferous,and of dispersal into deeper-water environments in the aftermath of the Hangenberg event.[33]
  • A diverse assemblage of cartilaginous fish fossils is described from the Eocene Osinovaya Formation (Rostov Oblast, Russia) by Popov et al. (2024).[34]
  • A study on the anatomy of the pharynx of Acanthodes confusus, providing evidence of the presence of a mixture of characters seen in cartilaginous and bony fish, is published by Dearden, Herrel & Pradel (2024).[35]
  • The first fossil material of obruchevodid petalodonts found outside the Bear Gulch Limestone, including teeth of Fissodopsis robustus and Netsepoye hawesi providing information on their three-dimensional tooth morphology, is described from the Carboniferous (Mississippian) Bangor Limestone (Alabama, United States) by Egli et al. (2024).[36]
  • Brownstein, Near & Dearden (2024) reconstruct the evolutionary history of holocephalans, and argue that, while key features of the holocephalan body plan evolved in the Paleozoic, the group entered deep ocean waters and diversified there only after the Cretaceous–Paleogene extinction event.[37]
  • New hybodont assemblage, representing one of the oldest records of Jurassic hybodonts from Gondwana reported to date, is described from the Bajocian Jaisalmer Formation (India) by Ghosh et al. (2024).[38]
  • The oldest fossil material of members of the genus Strophodus from Gondwana reported to date is described from the ?Early to Middle Jurassic succession of Kachchh Basin (India) by Bhosale et al. (2024).[39]
  • Cuny & Chanthasit (2024) describe egg capsules of Palaeoxyris sp. from the Jurassic Phu Kradung Formation (Thailand), interpreted as indicating that at least some hybodont sharks in Jurassic Thailand reproduced in fresh waters.[40]
  • Fossil material of Aegyptobatus kuehnei, formerly known only from the Bahariya Formation (Egypt), is described from the Alcântara Formation (Brazil) by Neves et al. (2024).[41]
  • A study on the evolutionary history of selachians (modern sharks) is published by Sternes, Schmitz & Higham (2024), who argue that modern sharks expanded to the pelagic realm no later than the Barremian, that habitat influenced the morphology of their pectoral fins, and that the increase of sea surface temperature in the middle of the Cretaceous period was an important factor in driving the evolution of shark ecology and morphology.[42]
  • The first fossil material of a member of the wobbegong genus Cederstroemia from Asia reported to date is described from the Santonian Kashima Formation (Japan) by Kaneko & Solonin (2024).[43]
  • Vullo et al. (2024) describe new fossil material of Ptychodus from the Upper Cretaceous strata in Mexico, providing evidence that Ptychodus was a high-speed mackerel shark that likely fed on nektonic hard-shelled prey such as ammonites and sea turtles.[44]
  • Shimada et al. (2024) describe two isolated teeth of Megalolamna paradoxodon from the Miocene Calvert Formation (Maryland, United States), representing the northernmost record of Megalolamna reported to date, and a tooth from the Oligocene Chandler Bridge Formation (South Carolina, United States) which might represent the geologically oldest record of a member of the genus Megalolamna reported to date.[45]
  • Pollerspöck & Shimada (2024) describe fossil material of members of the genus Megalolamna from the Miocene strata in Austria, France, Germany and Italy, and interpret the type species of this genus, M. paradoxodon, as a junior synonym of "Otodus" serotinus Probst (1879), resulting in a new combination Megalolamna serotinus.[46]
  • Sternes et al. (2024) reevaluate the accuracy of the body form of Otodus megalodon inferred by Cooper et al. (2022),[47] compare an incomplete vertebral column of a specimen of O. megalodon from the Miocene of Belgium with corresponding parts of the vertebral columns of extant white sharks, and argue that O. megalodon had an elongated body relative to the body of the white shark.[48]
  • Paredes-Aliaga & Herraiz (2024) compare tooth microwear of the Miocene Otodus megalodon and the Pliocene great white shark from Spain, and interpret the two species as likely competing for similar prey, with the tooth wear of the great white shark possibly indicating the preference for a slightly more abrasive diet.[49]
  • The first fossil tooth of a shark (great white shark) embedded in a seal bone reported to date is described from the Peace River Formation (Florida, United States) by Godfrey et al. (2024).[50]
  • Greenfield (2024) coins the name Arthrobatidae as a replacement for the invalid name of the possible batomorph family Arthropteridae.[51]
  • Capasso et al. (2024) describe rostrum of a large specimen of Onchopristis from the Maastrichtian Dakhla Formation (Egypt), providing evidence of persistence of Onchopristis in the marine environments of North Africa until the end of the Cretaceous.[52]
  • Kocsis (2024) reviews the fossil record of Elasmobranchii from the Malay Archipelago and describes new fossils of elasmobranchs from the Miocene strata in Brunei and from the Sibuti Formation (Sarawak, Malaysia), including the first fossils of Chiloscyllium sp., cf. Hemitriakis sp., Paragaleus sp., the Borneo shark, the blacktip shark, Lamiopsis sp., Scoliodon sp. and Rhinobatos sp. from the Malay Archipelago reported to date.[53]
  • Evidence from the study of dental microwear in extant chondrichthyans, interpreted as indicating that dental microwear analysis can provide reliable information on the diet of fossil taxa, is presented by Paredes-Aliaga, Botella & Romero (2024).[54]
  • Cooper & Pimiento (2024) assess the functional diversity of sharks from 66 million years to the present using teeth, finding that shark functional diversity was high between the Palaeocene and its Miocene peak, and subsequently declined over the last 10 million years to its lowest value in the present. They interpret this decline as being due to the extinctions of functionally unique and specialised species such as †Otodus megalodon.[55]

Ray-finned fishes

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Name Novelty Status Authors Age Type locality Location Notes Images

Afrocascudo[56]

Gen. et sp. nov

Disputed

Brito et al.

Late Cretaceous

Kem Kem Group
(Douira Formation)

  Morocco

Originally described as a member of the family Loricariidae; Britz et al. (2024) considered the holotype specimen to be more likely a juvenile specimen of a species of the gar genus Obaichthys,[57] while Brito et al. (2024) reaffirmed the original identification.[58] The type species is A. saharaensis.

 

Amia basiloides[59]

Sp. nov

Brownstein & Near

Paleocene

Fort Union Formation

  United States
(  Montana)

A species of Amia.

Angiolinia[60]

Gen. et sp. nov

Valid

Carnevale & Tyler

Eocene

Monte Bolca Lagerstätte

  Italy

A member of the family Zanclidae. The type species is A. mirabilis.

Archaeotetraodon bemisae[61]

Sp. nov

Valid

Bannikov & Tyler

Miocene

Maikop Group

  Russia
(  Krasnodar Krai)

A member of the family Tetraodontidae.

Barschichthys[62]

Gen. et sp. nov

Valid

Arratia & Schultze

Middle Triassic (Anisian)

Muschelkalk

  Germany

A member of Teleosteomorpha, the type genus of the new family Barschichthyidae. The type species is B. ruedersdorfensis.

Beksinskiella[63]

Gen. et comb. nov

Valid

Granica, Bieńkowska-Wasiluk & Pałdyna

Oligocene

  Czech Republic
  Poland
  Ukraine

A member of Clupeoidei of uncertain affinities. The type species is "Meletta" longimana Heckel (1850).

Buapichthys[64]

Gen. et sp. nov

Medina-Castañeda, Cantalice & Castañeda-Posadas

Late Cretaceous (Turonian)

Mexcala Formation

  Mexico

A member of Crossognathiformes belonging to the group Pachyrhizodontoidei. The type species is B. gracilis.

Bunocephalus serranoi[65]

Sp. nov

Valid

Bogan & Agnolín

Miocene

Ituzaingó Formation

  Argentina

A species of Bunocephalus.

Cretapantodon[66]

Gen. et sp. nov

Valid

Taverne

Late Cretaceous (Cenomanian)

  Lebanon

A member of the family Pantodontidae. The type species is C. polli.

Dapalis absconditus[67]

Sp. nov

Valid

Bradić-Milinović & Ahnelt

Oligocene

  Serbia

Dapalis octospinus[67]

Sp. nov

Valid

Ahnelt & Bradić-Milinović

Oligocene

  Serbia

Dapalis parvus[67]

Sp. nov

Valid

Ahnelt & Bradić-Milinović

Oligocene

  Serbia

Dapalis pauciserratus[68]

Sp. nov

Valid

Ahnelt, Bradić-Milinović & Schwarzhans

Oligocene

  Serbia

Dapalis quintus[67]

Sp. nov

Valid

Bradić-Milinović & Ahnelt

Oligocene

  Serbia

Eosemionotus ratumensis[69]

Sp. nov

Valid

Diependaal et al.

Middle Triassic (Anisian)

Vossenveld Formation

  Netherlands

A member of the family Macrosemiidae.

Gregarialepis[70]

Gen. et sp. nov

Valid

Bakaev & Sergienko in Bakaev

Permian

Leninsk Formation

  Russia

A member of Elonichthyiformes. The type species is G. binaria.

Lates odessanus[71]

Sp. nov

Kovalchuk et al.

Miocene

  Ukraine

A species of Lates.

Laubeichthys[72]

Gen. et comb. nov

Reichenbacher & Přikryl

Oligocene

  Czech Republic
  Germany

A member of Gobioidei, possibly a member of the lineage of Pirskeniidae. The type species is "Lepidocottus" gracilis Laube (1901).

Macroprosopon[73]

Gen. et sp. nov

Valid

Capobianco, Zouhri & Friedman

Eocene (Ypresian)

Ouled Abdoun Basin

  Morocco

A member of the family Osteoglossidae belonging to the subfamily Phareodontinae. The type species is M. hiltoni.

Makaira adensa[74]

Sp. nov

Valid

De Gracia et al.

Miocene

Pietra Leccese Formation

  Italy

A marlin, a species of Makaira.

Makaira cyclovata[74]

Sp. nov

Valid

De Gracia et al.

Miocene

Pietra Leccese Formation

  Italy

A marlin, a species of Makaira.

Marcopoloichthys mirigioliensis[75][76]

Sp. nov

Valid

Arratia, Bürgin & Furrer

Middle Triassic (Anisian)

Besano Formation

   Switzerland

A stem teleosteomorph.

Megalomatia[77]

Gen. et sp. nov

Valid

Kim et al.

Late Triassic

Amisan Formation

  South Korea

A basal ray-finned fish. The type species is M. minima.

Mengius[78]

Gen. et sp. nov

Valid

Thies, Stevens & Ansorge

Early Jurassic (Toarcian)

Ciechocinek Formation

  Germany

A member of the family Lepidotidae. The type species is M. acutidens.

Mesolepis arabellae[79]

Sp. nov

Elliott & Giles

Carboniferous (Bashkirian)

Scottish Lower Coal Measure Formation

  United Kingdom

A member of Eurynotiformes.

Mioscomber[80]

Gen. et comb. nov

Valid

Bannikov & Erebakan

Miocene

  Croatia
  Russia

A member of the family Scombridae. The type species is "Auxis" caucasica Bogachev (1933); genus also includes "Auxis" vrabcensis Kramberger (1882), "A." thynnoides Kramberger (1882) and "Scomber" sujedanus Steindachner (1860).

Nasrinsotoudehichthys[81]

Gen. et comb. nov

Valid

Ebert & López-Arbarello

Late Jurassic (Tithonian)

Zandt Basin

  Germany

A member of Caturoidea of uncertain affinities. The type species is "Liodesmus" sprattiformis Wagner (1863).

Perledovatus[82]

Gen. et comb. nov

Valid

López-Arbarello & Brocke

Middle Triassic (Ladinian)

Perledo-Varenna Formation

  Italy

A member of Halecomorphi belonging to the family Subortichthyidae. The type species is "Allolepidotus" nothosomoides Deecke (1889).

Pizzikoskerma[74]

Gen. et sp. nov

Valid

De Gracia et al.

Miocene

Pietra Leccese Formation

  Italy

A marlin. The type species is P. salentina.

Planalepis[70]

Gen. et sp. nov

Valid

Bakaev & Sergienko in Bakaev

Permian

Tailugan Formation

  Russia

A member of Elonichthyiformes. The type species is P. diserta.

Pogonias blettleri[83]

Sp. nov

Valid

Noriega et al.

Miocene

Paraná Formation

  Argentina

A species of Pogonias.

Protosphyraena terminalis[84]

Sp. nov

Kanarkina, Zverkov & Polyakova

Late Cretaceous (Maastrichtian)

  Belgium

Pseudopholidoctenus[62]

Gen. et sp. nov

Valid

Arratia & Schultze

Middle Triassic (Anisian)

Muschelkalk

  Germany

A member of the family Pholidophoridae. The type species is P. germanicus.

Ruedersdorfia[62]

Gen. et sp. nov

Valid

Arratia & Schultze

Middle Triassic (Anisian)

Muschelkalk

  Germany

A member of Teleosteomorpha of uncertain affinities. The type species is R. berlinensis.

Sanalosa[85]

Gen. et sp. nov

Bienkowska-Wasiluk, Granica & Kovalchuk

Oligocene (Rupelian)

Menilite Formation

  Poland

A member of the family Alosidae. The type species is S. janulosa.

Sicophasma[74]

Gen. et sp. nov

Valid

De Gracia et al.

Miocene

Pietra Leccese Formation

  Italy

A marlin. The type species is S. macrocanalata.

Simpsonigobius[86]

Gen. et sp. nov

Valid

Dirnberger, Bauer & Reichenbacher

Miocene

Zeytindağ Group

  Turkey

A member of Gobiiformes. The type species is S. nerimanae.

Stambergichthys[87]

Gen. et sp. nov

Valid

Barták et al.

Carboniferous (Moscovian)

Kladno Formation

  Czech Republic

An early ray-finned fish. The type species is S. macrodens.

Stereolepis arcanum[88]

Sp. nov

Valid

Přikryl & Lin in Přikryl et al.

Pliocene

Upper Kueichulin Formation

Taiwan

A species of Stereolepis.

Teffichthys wui[89]

Sp. nov

Valid

Xu et al.

Early Triassic (Olenekian)

Lower Qinglong Formation

  China

Toarcocephalus[90]

Gen. et sp. nov

Valid

Cooper, López-Arbarello & Maxwell

Early Jurassic (Toarcian)

Posidonia Shale

  Germany

A member of the family Coccolepididae. The type species is T. morlok.

Vinciguerria shinjiensis[91]

Sp. nov

Yabumoto, Nomura & Nazarkin

Miocene

Kuri Formation

  Japan

A species of Vinciguerria.

Xeneichthys[92]

Gen. et sp. nov

Valid

Arratia & González-Rodríguez

Early Cretaceous (Albian)

El Doctor Formation

  Mexico

A member of Euteleosteomorpha of uncertain phylogenetic placement. The type species is X. yanesi.

 

Otolith taxa

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Name Novelty Status Authors Age Type locality Location Notes Images

Acromycter gratus[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Acromycter.

Advenasciaena[94]

Gen. et sp. nov

Valid

Kocsis et al.

Miocene

Miri Formation

  Brunei

A member of the family Sciaenidae. The type species is A. bruneiana.

Akko canoa[95]

Sp. nov

Schwarzhans & Aguilera

Pleistocene (Gelasian)

Canoa Formation

  Ecuador

A species of Akko.

Akko lobata[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian)

Yaviza Formation

  Panama

A species of Akko.

Alienocarapus[93]

Gen. et sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Bartonian)

Mission Valley Formation

  United States
(  California)

A member of the subfamily Carapinae. The type species is A. banana.

Ambassis californiensis[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Ambassis.

Ampheristus brevicaudatus[96]

Sp. nov

Valid

Lin, Steurbaut & Nolf

Eocene

Nanjemoy Formation

  United States
(  Alabama
  Maryland
  Virginia)

A cusk-eel.

Ampheristus turgidus[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A cusk-eel.

Antigonia transpacifica[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Antigonia.

Antilligobius collinsae[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian) to Pleistocene (Gelasian)

Escudo de Veraguas Formation

  Costa Rica
  Ecuador
  Panama
  Trinidad and Tobago
  Venezuela

A species of Antilligobius.

Apletodon conwayi[97]

Sp. nov

Valid

Schwarzhans, Klots & Kovalchuk in Schwarzhans et al.

Miocene

  Ukraine

A species of Apletodon.

Archaeotolithus eiggensis[98]

Sp. nov

Schwarzhans & Wakefield

Middle Jurassic (Bathonian)

Lealt Shale

  United Kingdom

Archaeotolithus invernizziae[98]

Sp. nov

Schwarzhans & Wakefield

Middle Jurassic (Bathonian)

Lealt Shale

  United Kingdom

Ariosoma ceppiensis[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Miocene (Burdigalian)

  Italy

A species of Ariosoma.

Arnoglossus dispar[97]

Sp. nov

Valid

Schwarzhans, Klots & Kovalchuk in Schwarzhans et al.

Miocene

  Ukraine

A scaldfish.

Aruma atlantica[95]

Sp. nov

Schwarzhans & Aguilera

Pliocene (Piacenzian) to Pleistocene (Calabrian)

Bastimentos Formation

  Panama

A species of Aruma.

Atrobucca borneensis[94]

Sp. nov

Valid

Kocsis et al.

Miocene

Seria Formation

  Brunei

A species of Atrobucca.

Avitamugil[93]

Gen. et sp. et comb. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene

Ardath Shale

  United Kingdom
  United States
(  California)

A mullet. The type species is A. scrippsi; genus also includes "Pentanemus" constrictus Stinton (1984).

Baobythites[93]

Gen. et sp. et comb. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene

Ardath Shale

  France
  United States
(  Alabama
  California
  Mississippi
  Texas)

A cusk-eel. The type species is B. pacificus; genus also includes "aff. Glyptophidium" stringeri Lin & Nolf (2022) and "Ophidium" biarritzense Sulc (1932).

Barbulifer amplus[95]

Sp. nov

Schwarzhans & Aguilera

Pleistocene (Gelasian and Calabrian)

Swan Cay Formation

  Panama

A species of Barbulifer.

Bathycongrus delfinoi[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Miocene (Burdigalian)

  Italy

A species of Bathycongrus.

Bauzaia gibbosa[96]

Sp. nov

Valid

Lin, Steurbaut & Nolf

Eocene

Nanjemoy Formation

  United States
(  Maryland)

A cusk-eel.

Bollmannia angosturae[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian and Messinian)

Angostura Formation

  Ecuador
  Panama

A species of Bollmannia.

Bollmannia baldwinae[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Langhian to Messinian)

Yaviza Formation

  Panama
  Trinidad and Tobago
  Venezuela

A species of Bollmannia.

Bollmannia cubaguana[95]

Sp. nov

Schwarzhans & Aguilera

Pliocene (Zanclean)

Cubagua Formation

  Venezuela

A species of Bollmannia.

Bollmannia ornatissima[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian and Messinian)

Yaviza Formation

  Panama
  Trinidad and Tobago

A species of Bollmannia.

Bollmannia? paraguanaensis[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Burdigalian)

Cantaure Formation

  Panama
  Venezuela

Possibly a species of Bollmannia.

Bollmannia propensa[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian and Messinian)

Onzole Formation

  Ecuador
  Panama

A species of Bollmannia.

Bollmannia trinidadensis[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Burdigalian and Langhian)

Brasso Formation

  Trinidad and Tobago
  Venezuela

A species of Bollmannia.

Bollmannia venezuelana[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Langhian to Tortonian)

Ojo de Agua Formation

  Trinidad and Tobago
  Venezuela

A species of Bollmannia.

Brassoichthys[95]

Gen. et sp. nov

Schwarzhans & Aguilera

Miocene (Langhian)

Brasso Formation

  Trinidad and Tobago

A goby. The type species is B. tornabenei.

Bregmaceros moersi[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Bartonian and Priabonian)

Yazoo Formation

  United States
(  Mississippi
  Texas)

A codlet.

Bruneisciaena[94]

Gen. et sp. nov

Valid

Kocsis et al.

Miocene

Miri Formation

  Brunei

A member of the family Sciaenidae. The type species is B. schwarzhansi.

Buenia gibba[97]

Sp. nov

Valid

Schwarzhans, Klots & Kovalchuk in Schwarzhans et al.

Miocene

  Ukraine

A species of Buenia.

Centroberyx predorsalis[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian and Bartonian)

Mission Valley Formation

  United States
(  California)

A species of Centroberyx.

Centroberyx pseudopulcher[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian and Bartonian)

Ardath Shale

  United States
(  California)

A species of Centroberyx.

Cepola macilenta[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Miocene (Burdigalian)

  Italy

A species of Cepola.

Chriolepis altus[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian)

Yaviza Formation

  Panama

A species of Chriolepis.

Chriolepis balboa[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian)

Angostura Formation

  Ecuador
  Panama

A species of Chriolepis.

"Conger" biaculeatus[96]

Sp. nov

Valid

Lin, Steurbaut & Nolf

Eocene

Bashi Formation

  United States
(  Alabama)

A member of the family Congridae.

Coryphaenoides delapierrei[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Miocene (Burdigalian)

  Italy

A species of Coryphaenoides.

Coryphopterus cuevae[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian)

Tuira Formation

  Panama

A species of Coryphopterus.

Coryphopterus rodriguezi[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian and Messinian)

Chucunaque Formation

  Panama

A species of Coryphopterus.

Coryphopterus xenosus[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Messinian) and Pliocene (Zanclean)

Cubagua Formation

  Trinidad and Tobago
  Venezuela

A species of Coryphopterus.

Ctenogobius darienensis[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian)

Yaviza Formation

  Panama

A species of Ctenogobius.

Cubaguanichthys[95]

Gen. et sp. nov

Schwarzhans & Aguilera

Pliocene (Zanclean)

Cubagua Formation

  Venezuela

A goby. The type species is C. lanceolatus.

Cubiceps lautus[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Cubiceps.

Diaphus cuneatus[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Miocene (Burdigalian)

  Italy

A species of Diaphus.

Diaphus hastaensis[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Oligocene (Chattian)

  Italy

A species of Diaphus.

Diaphus ichishiensis[100]

Sp. nov

Valid

Tsuchiya et al.

Miocene

  Japan

A species of Diaphus.

Diaphus pertinax[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Miocene (Burdigalian)

  Italy

A species of Diaphus.

Diaphus roederi[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Diaphus.

Diretmus fidelis[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Diretmus.

Electolapis[93]

Gen. et comb. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene

  Belgium
  France
  United Kingdom
  United States
(  California)

A teleost of uncertain phylogenetic placement. The type species is "Ambassis" electilis Stinton & Nolf (1970); genus also includes "genus Gerreidarum" aquitanicus Nolf (1988).

Encheliophis transversalis[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Encheliophis.

Eobidenichthys[93]

Gen. et comb. nov

Valid

Schwarzhans, Stringer & Takeuchi

Late Cretaceous (Campanian and Maastichtian) to Oligocene

  Belgium
  France
  Germany
  Netherlands
  Ukraine
  United Kingdom
  United States
(  Alabama
  California)

A viviparous brotula. The type species is "Otolithus (Ophidiidarum)" symmetricus Frost (1934); genus also includes Eobidenichthys crepidatus (Voigt, 1926), Eobidenichthys lapierrei (Nolf, 1978), Eobidenichthys midwayensis (Nolf & Docker, 1993) and Eobidenichthys boscheineni (Schwarzhans, 1994).

Eokrefftia paviai[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Oligocene (Chattian)

  Italy

A lanternfish belonging to the subfamily Eomyctophinae.

Eophichthus[93]

Gen. et 2 sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian and Bartonian), possibly also Oligocene

Ardath Shale

  United States
(  California)

A member of the family Ophichthidae. The type species is E. ardathensis; genus also includes E. gracilis and possibly also "Conger" brevior Koken (1888).

Eopterois[93]

Gen. et sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene

  United States
(  Mississippi)

A member of the family Scorpaenidae belonging to the tribe Pteroini. The type species is E. bandeli.

Epigonus liguriensis[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Miocene (Burdigalian)

  Italy

A species of Epigonus.

Evermannia chiriquiensis[95]

Sp. nov

Schwarzhans & Aguilera

Pliocene (Zanclean)

Cayo Agua Formation

  Panama

A species of Evermannia.

Evermannia? problematica[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Burdigalian and Tortonian)

Cantaure Formation

  Panama
  Venezuela

Possibly a species of Evermannia.

Fitchichthys[93]

Gen. et sp. et comb. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene

Ardath Shale

  Germany
  United States
(  California)

A teleost of uncertain phylogenetic placement. The type species is F. placidus; genus also includes Macroramphosidarum testuliformis Schwarzhans (2007).

Gillichthys caribbaeus[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian)

Manzanilla Formation

  Trinidad and Tobago

A species of Gillichthys.

Giuntellia[99]

Gen. et sp. nov

Valid

Schwarzhans & Carnevale

Miocene (Burdigalian)

  Italy

A member of the family Gobiidae. The type species is G. singularis.

Glyptophidium monoceros[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Miocene (Langhian)

  Czech Republic
  Italy

A species of Glyptophidium.

Gnatholepis gunae[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian)

Gatun Formation

  Panama

A species of Gnatholepis.

Gnathophis frizzelli[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Bartonian)

Mission Valley Formation

  United States
(  California)

A species of Gnathophis.

Gobiosoma emberae[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Messinian)

Chucunaque Formation

  Panama

A species of Gobiosoma.

Gobulus limonensis[95]

Sp. nov

Schwarzhans & Aguilera

Pleistocene (Gelasian)

Moin Formation

  Costa Rica

A species of Gobulus.

"Haemulon" ypresiensis[96]

Sp. nov

Valid

Lin, Steurbaut & Nolf

Eocene

Nanjemoy Formation

  United States
(  Alabama
  Maryland
  Mississippi
  Virginia)

A member of the family Haemulidae.

Hoplobrotula panicula[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Bartonian)

Mission Valley Formation

  United States
(  California)

A species of Hoplobrotula.

Hoplunnis diagonalis[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Hoplunnis.

Huddlestonichthys[93]

Gen. et sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A bonefish. The type species is H. profundicauda.

Ilypnus arayanensis[95]

Sp. nov

Schwarzhans & Aguilera

Pliocene (Zanclean)

Cubagua Formation

  Venezuela

A species of Ilypnus.

Ipaimuraena[93]

Gen. et 2 sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian and Bartonian)

Ardath Shale

  United States
(  California
  Mississippi)

A member of the family Ophichthidae. The type species is I. californiensis; genus also includes I. fusiformis.

Japonoconger asper[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Miocene (Burdigalian)

  Italy

A species of Japonoconger.

Lampanyctus rostratus[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Oligocene (Chattian)

  Italy

A species of Lampanyctus.

Leptolepis flexuosus[98]

Sp. nov

Schwarzhans & Wakefield

Middle Jurassic (Bathonian)

Lealt Shale

  United Kingdom

Leptolepis skyensis[98]

Sp. nov

Schwarzhans & Wakefield

Middle Jurassic (Bathonian)

Lealt Shale

  United Kingdom

Liparomorphus[93]

Gen. et sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A possible snailfish. The type species is L. gerringerae.

Magnogobius[95]

Gen. et 2 sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian) to Pleistocene (Gelasian)

Cercado Formation

  Costa Rica
  Dominican Republic
  Panama

A goby. The type species is M. grandis; genus also includes M. costaricensis.

Malacanthus? rugosus[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A tilefish of uncertain generic placement.

Microgobius aphioides[95]

Sp. nov

Schwarzhans & Aguilera

Pliocene (Zanclean)

Cubagua Formation

  Panama
  Trinidad and Tobago
  Venezuela

A species of Microgobius.

Microgobius camur[95]

Sp. nov

Schwarzhans & Aguilera

Pliocene (Zanclean) to Pleistocene (Calabrian)

Escudo de Veraguas Formation

  Costa Rica
  Panama

A species of Microgobius.

Microgobius cantaurensis[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Burdigalian to Tortonian)

Cantaure Formation

  Panama
  Venezuela

A species of Microgobius.

Microgobius chocorum[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian)

Tuira Formation

  Panama
  Trinidad and Tobago

A species of Microgobius.

Microgobius cumana[95]

Sp. nov

Schwarzhans & Aguilera

Pleistocene (Calabrian)

Cumaná Formation

  Venezuela

A species of Microgobius.

Microgobius ecuadorensis[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian)

Angostura Formation

  Ecuador
  Panama

A species of Microgobius.

Microgobius glaber[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian and Messinian)

Manzanilla Formation

  Dominican Republic
  Panama
  Trinidad and Tobago

A species of Microgobius.

Microgobius pezoldi[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian and Messinian)

Chucunaque Formation

  Costa Rica
  Ecuador
  Panama
  Trinidad and Tobago

A species of Microgobius.

Microgobius pirabasensis[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Aquitanian to Burdigalian)

Pirabas Formation

  Brazil

A species of Microgobius.

Microgobius praeglaber[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Langhian to Tortonian)

Brasso Formation

  Panama
  Trinidad and Tobago

A species of Microgobius.

Microgobius robertsoni[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Aquitanian to Burdigalian)

Cantaure Formation

  Brazil
  Dominican Republic
  Trinidad and Tobago
  Venezuela

A species of Microgobius.

Microgobius rohri[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Burdigalian)

Brasso Formation

  Trinidad and Tobago

A species of Microgobius.

Microgobius verecundus[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian to Messinian)

Tuira Formation

  Ecuador
  Panama
  Trinidad and Tobago

A species of Microgobius.

Micropomadasys[93]

Gen. et sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A member of the family Haemulidae. The type species is M. granulosus.

Myctophum isense[100]

Sp. nov

Valid

Tsuchiya et al.

Miocene

  Japan

A species of Myctophum.

Neobythites longesulcatus[96]

Sp. nov

Valid

Lin, Steurbaut & Nolf

Eocene

Nanjemoy Formation

  United States
(  Maryland
  Virginia)

A cusk-eel, a species of Neobythites.

"Neobythites" pamunkeyensis[96]

Sp. nov

Valid

Lin, Steurbaut & Nolf

Eocene

Nanjemoy Formation

  United States
(  Virginia)

A cusk-eel.

"Neobythites" stringeri[96]

Sp. nov

Valid

Lin, Steurbaut & Nolf

Eocene

Hatchetigbee Bluff Formation

  United States
(  Alabama)

A cusk-eel.

Nezumia armentrouti[101]

Sp. nov

Stringer & Welton

Oligocene

Lincoln Creek Formation

  United States
(  Washington)

A species of Nezumia.

Nezumia marramai[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Oligocene (Chattian)

  Italy

A species of Nezumia.

Nibea ambugensis[94]

Sp. nov

Valid

Kocsis et al.

Miocene

Seria Formation

  Brunei

A species of Nibea.

Nibea stintoni[94]

Sp. nov

Valid

Kocsis et al.

Miocene

Miri Formation

  Brunei

A species of Nibea.

Owstonia rhomboidea[99]

Sp. nov

Valid

Schwarzhans & Carnevale

Miocene (Burdigalian)

  Italy

A species of Owstonia.

Palaeolebias winogradskyi[97]

Sp. nov

Valid

Schwarzhans, Klots & Kovalchuk in Schwarzhans et al.

Miocene

  Ukraine

A pupfish.

Palatogobius magnus[95]

Sp. nov

Schwarzhans & Aguilera

Pliocene (Zanclean)

Cayo Agua Formation

  Panama

A species of Palatogobius.

Palatogobius pacificus[95]

Sp. nov

Schwarzhans & Aguilera

Pleistocene (Calabrian)

Armuelles Formation

  Panama

A species of Palatogobius.

Palatogobius vantasselli[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian and Messinian)

Manzanilla Formation

  Trinidad and Tobago

A species of Palatogobius.

Paracarapus californiensis[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Bartonian)

Mission Valley Formation

  United States
(  California)

A member of the subfamily Carapinae.

Paralabrax nolfi[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

  Belgium

A species of Paralabrax.

Parascombrops fragilis[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Parascombrops.

Parrella lucida[95]

Sp. nov

Schwarzhans & Aguilera

Pliocene (Zanclean)

Manzanilla Formation

  Trinidad and Tobago
  Venezuela

A species of Parrella.

Pauxillibrotula[93]

Gen. et comb. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene

  France
  United States
(  California)

A cusk-eel. The type species is "genus Neobythitinorum" dolinorum Nolf (1988).

Peprilus? muelleri[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Bartonian)

Mission Valley Formation

  United States
(  California)

Possibly a species of Peprilus.

Platygonostoma[93]

Gen. et comb. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene

  France
  United States
(  California)

A member of the family Sternoptychidae. The type species is "Danaphos" gibbsi Nolf (1988).

Plesiolithus[93]

Gen. et sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A teleost of uncertain phylogenetic placement. The type species is P. inornatus.

Polyipnus apicalis[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Polyipnus.

Porrolapis[93]

Gen. et comb. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene

  France
  United States
(  California)

A teleost of uncertain phylogenetic placement. The type species is "genus Cyprinodontoideorum" ornatissimus Nolf (1988).

Praearchirolithus altus[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian and Bartonian)

Mission Valley Formation

  United States
(  California)

A member of the family Soleidae.

Praearchirolithus confusus[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian and Bartonian)

Mission Valley Formation

  United States
(  California)

A member of the family Soleidae.

Prionotus kieli[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Priabonian)

Yazoo Clay

  United States
(  Mississippi)

A species of Prionotus.

Progonostoma torreyensis[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A member of the family Gonostomatidae.

Proparrella[95]

Gen. et 2 sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian) to Pliocene (Zanclean)

Tuira Formation

  Ecuador
  Panama
  Trinidad and Tobago
  Venezuela

A goby. The type species is P. darienensis; genus also includes P. pusilla.

Protanago[93]

Gen. et comb. et sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene

  Italy
  United States

A member of the family Congridae. The type species is "Otolithus (Platessae)" sector Koken (1888); genus also includes "Parbatmya" brazosensis Dante & Frizzell (1965), "Ariosoma" nonsector Nolf & Stringer (2003) "Paraconger" solidus Müller (1999) and "Paraconger" wechesensis Lin & Nolf (2022), as well as new species P. miramarensis.

Protaulopus[93]

Gen. et comb. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene

  France
  United States
(  California)

A member of the family Aulopidae. The type species is "genus Percoideorum" pseudolestidiops Nolf (1988).

Protobembrops[93]

Gen. et comb. et sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene

  Belgium
  France
  United Kingdom
  United States

A member of the family Trichonotidae. The type species is "Trachinus" laevigatus Koken (1888); genus also includes "Trachinus" janeti Priem (1911), as well as new species P. ascensus.

Protonibea nolfi[94]

Sp. nov

Valid

Kocsis et al.

Miocene

Miri Formation

  Brunei

A species of Protonibea.

Protopomadasys[93]

Gen. et 2 sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian and Bartonian)

Mission Valley Formation

  United States
(  California)

A member of the family Haemulidae. The type species is P. fitchi; genus also includes P. pacificus.

Pseudobrotulina[93]

Gen. et sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A viviparous brotula. The type species is P. fitchi.

Pseudolabrax[93]

Gen. et sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian and Bartonian)

Mission Valley Formation

  United States
(  California)

A member of the family Serranidae. The type species is P. missionis.

Ptereleotris tectus[97]

Sp. nov

Valid

Schwarzhans, Klots & Kovalchuk in Schwarzhans et al.

Miocene

  Ukraine

A species of Ptereleotris.

Quietula rueberi[95]

Sp. nov

Schwarzhans & Aguilera

Miocene (Tortonian)

Manzanilla Formation

  Trinidad and Tobago

A species of Quietula.

Saccogaster salebrosus[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Saccogaster.

Sarmatigobius cavatus[97]

Sp. nov

Valid

Schwarzhans, Klots & Kovalchuk in Schwarzhans et al.

Miocene

  Ukraine

A member of the family Gobiidae belonging to the Aphia lineage.

Scombrops americanus[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A gnomefish.

Scorpaenodes acronis[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Scorpaenodes.

Scorpaenodes huddlestoni[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene

Ardath Shale

  United States
(  California)

A species of Scorpaenodes.

Scorpaenodes starnesi[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Scorpaenodes.

Scythogobius minimus[97]

Sp. nov

Valid

Schwarzhans, Klots & Kovalchuk in Schwarzhans et al.

Miocene

  Ukraine

A member of the family Gobiidae belonging to the Benthophilus lineage.

Serranus? fongeri[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian and Bartonian)

Ardath Shale

  United States
(  California)

A member of the family Serranidae of uncertain generic placement.

Serranus? moratus[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian and Bartonian)

Ardath Shale

  United States
(  California)

A member of the family Serranidae of uncertain generic placement.

Serranus? strigosus[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian and Bartonian)

Mission Valley Formation

  United States
(  California)

A member of the family Serranidae of uncertain generic placement.

Sirembrotula[93]

Gen. et sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A cusk-eel. The type species is S. mediator.

Sparus? sparsus[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A member of the family Sparidae of uncertain generic placement.

Strongylauris[93]

Gen. et comb. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene

  United States

A member of the family Haemulidae. The type species is genus aff. Xenistius obliquus Müller (1999).

Symmetrosulcus virginicus[96]

Sp. nov

Valid

Lin, Steurbaut & Nolf

Eocene

Nanjemoy Formation

  United States
(  Alabama
  Maryland
  Virginia)

A cusk-eel.

Syngnathus vesculus[97]

Sp. nov

Valid

Schwarzhans, Klots & Kovalchuk in Schwarzhans et al.

Miocene

  Ukraine

A species of Syngnathus.

Synodus diadematus[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Bartonian)

Moodys Branch Formation

  United States
(  Mississippi)

A species of Synodus.

Synodus moodyensis[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Bartonian and Priabonian)

Moodys Branch Formation

  United States
(  Mississippi
(  Texas)

A species of Synodus.

Torreyichthys[93]

Gen. et sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A member of the family Serranidae. The type species is T. speciosus.

Umbra euronota[97]

Sp. nov

Valid

Schwarzhans, Klots & Kovalchuk in Schwarzhans et al.

Miocene

  Ukraine

A species of Umbra.

Uranoscopus? lini[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A stargazer of uncertain generic placement.

Uroconger priscus[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Bartonian)

Mission Valley Formation

  United States
(  California)

A species of Uroconger.

Varicus pliocenicus[95]

Sp. nov

Schwarzhans & Aguilera

Pliocene (Zanclean)

Cubagua Formation

  Venezuela

A species of Varicus.

Verilus lajollaensis[93]

Sp. nov

Valid

Schwarzhans, Stringer & Takeuchi

Eocene (Lutetian)

Ardath Shale

  United States
(  California)

A species of Verilus.

Vinciguerria rotunda[100]

Sp. nov

Valid

Tsuchiya et al.

Miocene

  Japan

A species of Vinciguerria.

Waitakia dorsogibbosa[96]

Sp. nov

Valid

Lin, Steurbaut & Nolf

Eocene

Nanjemoy Formation

  United States
(  Maryland
  Virginia)

A member of the family Percophidae belonging to the subfamily Hemerocoetinae.

Ray-finned fish research

edit
  • New, rank-free classification of extant and extinct ray-finned fishes is presented by Near & Thacker (2024).[102]
  • Dankina, Šečkus & Plax (2024) describe new fossil material of ray-finned fishes from the Devonian (Eifelian and Givetian) strata in Belarus and Lithuania, including scales of members of the genera Cheirolepis and Orvikuina, and improving biostratigraphic correlations within the studied region.[103]
  • New information on the evolution of the brain in the early ray-finned fishes, gained from the study of remains of the latest Carboniferous-earliest Permian ray-finned fishes from Brazil with extensive soft-tissue preservation of brains, cranial nerves, eyes and possible cardiovascular tissues, is presented by Figueroa et al. (2024).[104]
  • Redescription and study on the affinities of Westollia crassa is published by Štamberg (2024), who confirms the placement of this species as a distinct member of the family Aeduellidae.[105]
  • A study on teeth of members of Eurynotoidiformes is published by Bakaev et al. (2024), who interpret eurynotoidiforms as likely the oldest known actinopterygians specialized for herbivory.[106]
  • Revision of the fossil material of ray-finned fishes from the Permian-Triassic transition from the Kuznetsk Basin (Siberia, Russia) is published by Bakaev (2024).[107]
  • Kumar et al. (2024) describe fossil material of a member of the genus Cylindracanthus from the Eocene Naredi Formation (India), extending known geographical distribution of members of the genus.[108]
  • Cooper (2024) describes fossil material of an acipenseriform from the Kimmeridge Clay (United Kingdom), representing the first record of a Late Jurassic member of this group found outside Asia.[109]
  • Cavin et al. (2024) describe fossil material of a large-bodied ray-finned fish from a Lower Triassic outcrop in northern Dobrogea (Romania), with anatomy interpreted as indicative of affinities with Polzbergiidae, and interpret the studied fossils as belonging to the earliest known large, specialized, durophagous neopterygian.[110]
  • Review of the fossil record of non-marine members of Pycnodontiformes is published by Cawley & Kriwet (2024), who report that the incursions of pycnodontiforms into brackish and freshwater habitats increased during the Cretaceous period, when the rising sea levels might have made it easier for marine fishes to colonize continental environments.[111]
  • Revision of evidence of growth and aging in the fossil material of pycnodonts is published by Capasso (2024), who find no evidence for a single overall pattern of somatic growth, but reports evidence of specific changes which seem to be common in the studied pycnodonts.[112]
  • Capasso, Ebert & Witzmann (2024) review dental pathologies in pycnodonts, report uneven distribution of tooth anomalies in the pycnodont fossil record and interpret such distribution as suggesting that pycnodont teeth weren't initially ordered into distinct dental rows, which only appeared in the most derived forms.[113]
  • Review of pathologies in the skeletons and dermal scales of pycnodont specimens is published by Capasso, Ebert & Witzmann (2024).[114]
  • Capasso & Witzmann (2024) describe non-dental odontodes in two specimens of Haquelpycnodus picteti from the Cenomanian of Lebanon, representing the first record of dermal odontodes in pycnodonts reported to date, and interpret the anatomical position and structure of the studied structures as indicating that they functionally participated in the chewing process.[115]
  • New information on the anatomy of Tibetodus gyrodoides is provided by Fang & Wu (2024).[116]
  • Vullo & Frey (2024) describe specimens of Atractosteus messelensis and Cyclurus kehreri found with bat specimens in close contact with their jaws, and interpret this finding as evidence of opportunistic feeding on drowning or dead bats by Eocene amiids and gars from the Messel pit (Germany).[117]
  • Gouiric-Cavalli et al. (2024) describe new fossil material of Ameghinichthys antarcticus from the Tithonian strata of the Longing Member of the Ameghino/Nordenskjöld Formation (Antarctica), interpreted as supporting placement of Ameghinichthys in Dapediiformes.[118]
  • Nikolov et al. (2024) describe fossil material of gars from the Santonian–Campanian strata from the Vrabchov Dol locality (Bulgaria), expanding known geographical range of gars within the Late Cretaceous European Archipelago .[119]
  • Weis et al. (2024) study gut contents of pachycormid specimens from the Toarcian strata in Luxembourg, and report that the studied pachycormids fed on octobrachian cephalopods.[120]
  • Cooper (2024) describes fossil material of Pachycormus macropterus from the Toarcian strata in Normandy (France) representing the first direct evidence of cannibalism in a pachycormiform fish reported to date.[121]
  • Cooper, Maxwell & Martill (2024) describe fossil material of Asthenocormus cf. titanius from the Kimmeridge Clay, representing the first unambiguous record of Asthenocormus from the United Kingdom reported to date.[122]
  • Kanarkina, Zverkov & Polyakova (2024) identify fossil material of Protosphyraena ferox and P. tenuirostris from the Cenomanian Polpino Formation (Kursk Oblast, Russia), reinterpret Australopachycormus as a junior synonym of Protosphyraena, describe the first specimens of Protosphyraena from the Albian of the North Caucasus, and interpret the studied fossils as evidence of wide distribution of Protosphyraena already in the late Early Cretaceous.[84]
  • Redescription of Aphnelepis australis, based on data from a new specimen from the Talbragar fossil site (Australia), is published by Bean (2024), who assigns A. australis to the teleost family Archaeomaenidae.[123]
  • Bennett (2024) describes a series of caudal vertebrae of an ichthyodectiform from the Upper Cretaceous Niobrara Formation (Kansas, United States), preserved with pathologies unknown in extant and fossil fishes but sharing similarities with diffuse idiopathic skeletal hyperostosis and spondylosis deformans of mammals, and interprets the studied pathologies as caused by combined bacterial and fungal infections, affecting the swimming abilities of the studied fish and likely ultimately resulting in its death.[124]
  • Cantalice et al. (2024) describe fossil material of a previously unknown albuliform from the Campanian strata from the Múzquiz Lagerstätte (Austin Group; Coahuila, Mexico), estimated to be approximately 3,9 metres long and representing the largest albuliform reported to date.[125]
  • A study on the phylogenetic relationships and biogeography of extant and fossil osteoglossids is published by Capobianco & Friedman (2024), who interpret their findings as indicating that the last common ancestor of extant osteoglossids was marine, and that the group colonized freshwater settings at least four times.[126]
  • A study on the phylogenetic relationships of herring-like fossil fishes belonging to the group Clupei is published by Kevrekidis et al. (2024).[127]
  • Liu et al. (2024) revise Osteochilus sanshuiensis, Osteochilus longipinnatus and Osteochilus laticorpus from the Paleogene Buxin Formation (China), synonymizing them into a single species named Jianghanichthys sanshuiensis.[128]
  • Claeson et al. (2024) present a new reconstruction of Oncorhynchus rastrosus, interpreting its enlarged teeth as projecting laterally like tusks.[129]
  • Torres-Parada et al. (2024) report the discovery of fossil material of members of the genus Enchodus from the Upper Cretaceous strata of the La Luna Formation (Colombia).[130]
  • Redescription of Whitephippus tamensis is published by Davesne & Andrews et al. (2024), who interpret this taxon as an early member of Lampriformes, likely related to extant opahs and oarfishes and providing the earliest known evidence of adaptation of lampriforms to the pelagic environment.[131]
  • Laine et al. (2024) sequence three-spined stickleback genomes from Late Pleistocene sediments from the Jossavannet lake (Finnmark, Norway), who identify more marine- than freshwater-associated ancestry in the studied genomes, but also find evidence that freshwater-associated alleles were already established at known loci of large effect during the brackish phase of the formation of the lake.[132]
  • Miyata et al. (2024) describe an assemblage of marine fish otoliths from the Lower Cretaceous Kimigahama Formation (Japan), including the oldest known fossil material of members of the family Ichthyotringidae, as well as of otoliths of pterothrissine bonefishes, elopiforms and herring smelts indicative of cosmopolitan distribution of these groups during the Early Cretaceous.[133]
  • Evidence from the skeletal and otolith fossil record, interpreted as indicative of presence of rich and diverse teleost assemblages in known Maastrichtian marine settings which were significantly affected by the Cretaceous–Paleogene extinction event, is presented by Schwarzhans, Carnevale & Stringer (2024), who also find that perciforms and related groups, ophidiiforms and gadiforms underwent an explosive radiation and diversification in the early Paleogene.[134]
  • A study on the survivorship patterns of freshwater ray-finned fishes during the Cretaceous-Paleogene transition, based on data from the fossil record from the Denver Basin, is published by Wilson et al. (2024), who report evidence of previously unrecognized diversification of freshwater clades after the Cretaceous–Paleogene extinction event, as well as evidence of localized drops in diversity.[135]

Lobe-finned fishes

edit
Name Novelty Status Authors Age Type locality Location Notes Images

Ferganoceratodus edwardsi[136]

Sp. nov

Challands et al.

Late Triassic (Norian)

Pebbly Arkose Formation

  Zimbabwe

A lungfish belonging to the group Ceratodontoidei.

Graulia[137]

Gen. et sp. nov

Valid

Manuelli et al.

Middle Triassic

Calcaire à Cératites Formation

  France

A coelacanth belonging to the family Mawsoniidae. The type species is G. branchiodonta.

 

Harajicadectes[138]

Gen. et sp. nov

Valid

Choo et al.

Devonian (Givetian–Frasnian)

Parke Siltstone

  Australia

A basal member of Tetrapodomorpha. The type species is H. zhumini.

 

Jemalongia[139]

Gen. et sp. nov

Young

Devonian

Cloghnan Shale

  Australia

A probable member of Porolepiformes. The type species is J. ritchiei.

Ngamugawi[140]

Gen. et sp. nov

Valid

Clement et al.

Devonian (Frasnian)

Gogo Formation

  Australia

A coelacanth. The type species is N. wirngarri.

Lobe-finned fish research

edit
  • Toriño et al. (2024) reconstruct the skull of a specimen of Mawsonia from the Upper Jurassic strata in Uruguay.[141]
  • Cupello et al. (2024) describe pulmonary vessels in a calcified lung of a specimen of Macropoma mantelli from the Upper Cretaceous Chalk Formation (United Kingdom) and in extant coelacanth, confirming the air-breathing function of the tubular structure in the fossil coelacanth specimens called the calcified organ, and interpret coelacanths as having pulmonary arterie homologous to the same paired branches of the air-filled organs (including gas bladders) of other bony fishes.[142]
  • Redescription of the tooth plates of Atlantoceratodus iheringi, based on data from new and previously described fossil material, is published by Panzeri (2024).[143]
  • New information on the anatomy of Chaoceratodus portezuelensis, based on the study of the fossil material from the Portezuelo and Cerro Lisandro formations (Argentina), is provided by Panzeri & Guzmán (2024).[144]
  • Stewart et al. (2024) describe the anatomy of the axial skeleton of Tiktaalik roseae, providing evidence of the appearance of the evolution of increased mobility at the head-trunk boundary prior to the origin of limbs, as well as evidence of the presence of derived features of the anatomy of the ribs that were previously known only from limbed taxa, and interpret the anatomy of T. roseae as indicative of a locomotor capacity intermediate between those of other elpistostegalians and those of limbed vertebrates.[145]

General research

edit

References

edit
  1. ^ Huang, W.; Ma, Z.; Fu, L.; Guo, S. (2024). "A new species of lamprey from Cretaceous semisaline environment in China". Historical Biology: An International Journal of Paleobiology: 1–7. doi:10.1080/08912963.2024.2303350.
  2. ^ Li, X.; Zhang, Y.; Lin, X.; Zhu, M.; Zhao, W.; Tang, L.; Shan, X.; Gai, Z. (2024). "New findings of Changxingaspis (Xiushuiaspidae, Galeaspida) from the Silurian of Tarim Basin and Zhejiang Province". Acta Geologica Sinica (English Edition). 98 (3): 531–540. doi:10.1111/1755-6724.15168.
  3. ^ Chen, Y.; Li, Q.; Zhou, Z.-D.; Shan, X.-R.; Zhu, Y.-A.; Wang, Q.; Wei, G.-B.; Zhu, M. (2024). "A new genus of galeaspids (jawless stem-Gnathostomata) from the early Silurian Chongqing Lagerstätte, China". Vertebrata PalAsiatica. 62 (4): 245–261. doi:10.19615/j.cnki.2096-9899.240820.
  4. ^ Elliott, D. K. (2024). "A new weigeltaspid (Heterostraci) from the Early Devonian of Nunavut, Canadian Arctic, Canada, with comments on the relationships of the weigeltaspids". Historical Biology: An International Journal of Paleobiology: 1–7. doi:10.1080/08912963.2024.2386679.
  5. ^ Brownstein, C. D.; Near, T. (2024). "Colonization of the ocean floor by jawless vertebrates across three mass extinctions". BMC Ecology and Evolution. 24 (1). 79. Bibcode:2024BMCEE..24...79B. doi:10.1186/s12862-024-02253-y. PMC 11170801. PMID 38867201.
  6. ^ Brookfield, M. E. (2024). "The Life and Death of Jamoytius kerwoodi White; A Silurian Jawless Nektonic Herbivore?". Fossil Studies. 2 (2): 77–91. doi:10.3390/fossils2020003.
  7. ^ Grohganz, M.; Ballell, A.; Rayfield, E. J.; Ferrón, H. G.; Johanson, Z.; Donoghue, P. C. J. (2024). "Finite element and microstructural analyses indicate that pteraspid heterostracan oral plate microstructure was adapted to a mechanical function". Palaeontology. 67 (6). e12733. doi:10.1111/pala.12733.
  8. ^ Botella, H.; Fariña, R. A.; Huera-Huarte, F. (2024). "Delta wing design in earliest nektonic vertebrates". Communications Biology. 7 (1). 1153. doi:10.1038/s42003-024-06837-8. PMC 11405518. PMID 39284892.
  9. ^ Dearden, R. P.; Jones, A. S.; Giles, S.; Lanzetti, A.; Grohganz, M.; Johanson, Z.; Lautenschlager, S.; Randle, E.; Donoghue, P. C. J.; Sansom, I. J. (2024). "The three-dimensionally articulated oral apparatus of a Devonian heterostracan sheds light on feeding in Palaeozoic jawless fishes". Proceedings of the Royal Society B: Biological Sciences. 291 (2019). 20232258. doi:10.1098/rspb.2023.2258. PMC 10965320. PMID 38531402.
  10. ^ Shan, X.-R.; Zhu, M.; Li, Q.; Gai, Z.-K. (2024). "A taxonomical revision of 'Dongfangaspis qujingensis' from the Lower Devonian of Qujing, Yunnan Province". Vertebrata PalAsiatica. 62 (2): 85–98. doi:10.19615/j.cnki.2096-9899.240321.
  11. ^ Jobbins, M.; Rücklin, M.; Sánchez Villagra, M. R.; Lelièvre, H.; Grogan, E.; Szrek, P.; Klug, C. (2024). "Extreme lower jaw elongation in a placoderm reflects high disparity and modularity in early vertebrate evolution". Royal Society Open Science. 11 (1). 231747. doi:10.1098/rsos.231747. PMC 10827443. PMID 38298398.
  12. ^ Engelman, R. K. (2024). "Reconstructing Dunkleosteus terrelli (Placodermi: Arthrodira): A new look for an iconic Devonian predator". Palaeontologia Electronica. 27 (3). 27.3.a45. doi:10.26879/1343.
  13. ^ Türtscher, J.; Jambura, P. L.; Villalobos-Segura, E.; López-Romero, F. A.; Underwood, C. J.; Thies, D.; Lauer, B.; Lauer, R.; Kriwet, J. (2024). "Rostral and body shape analyses reveal cryptic diversity of Late Jurassic batomorphs (Chondrichthyes, Elasmobranchii) from Europe". Papers in Palaeontology. 10 (2). e1552. Bibcode:2024PPal...10E1552T. doi:10.1002/spp2.1552. PMC 7615989. PMID 38799546.
  14. ^ De Pasqua, J. J.; Aranciaga Rolando, A. M.; Agnolín, F. L.; Gaetano, L. C.; Bogan, S. (2024). "A new Myliobatiformes (Chondrichthyes, Batoidea) from the Miocene of Río Negro Province, Argentina and a review of the fossil Myliobatiformes of Argentina". Historical Biology: An International Journal of Paleobiology: 1–19. doi:10.1080/08912963.2024.2317326.
  15. ^ a b c d e f g Reinecke, T.; Mollen, F. H.; Gijsen, B.; D'Haeze, B.; Hoedemakers, K. (2024). "Batomorphs (Elasmobranchii: Rhinopristiformes, Rajiformes, Torpediniformes, Myliobatiformes) of the middle to late Ypresian, early Eocene, in the Anglo-Belgian Basin (south-western North Sea Basin) – a review and description of new taxa". Palaeontos. 35: 1–172.
  16. ^ a b c Feichtinger, I.; Pollerspöck, J.; Harzhauser, M.; Auer, G.; Ćorić, S.; Kranner, M.; Beaury, B.; Guinot, G. (2024). "Earliest Danian outer neritic elasmobranch assemblages reveal an environmentally controlled faunal turnover at the Cretaceous–Palaeogene boundary in the northern Tethyan Realm (Austria)". Papers in Palaeontology. 10 (1). e1547. Bibcode:2024PPal...10E1547F. doi:10.1002/spp2.1547.
  17. ^ Malyshkina, T. P.; Nazarkin, M. V. (2024). "Frilled Sharks (Hexanchiformes, Chlamydoselachidae): New Data on Their Diversity and Distribution". Paleontological Journal. 58 (5): 567–577. Bibcode:2024PalJ...58..567M. doi:10.1134/S0031030124600665.
  18. ^ Cicimurri, D.; Ciampaglio, C.; Hoenig, C.; Shell, R.; Fuelling, L.; Peterman, D.; Cline, D. A.; Jacquemin, S. (2024). "A Description of the New Hybodont Shark Genus, Columnaodus, from the Burlington and Keokuk Limestones (Carboniferous, Mississippian, Osagean) of Illinois and Iowa, USA". Diversity. 16 (5). 276. doi:10.3390/d16050276.
  19. ^ Bronson, A. W.; Pradel, A.; Denton, J. S. S.; Maisey, J. G. (2024). "A new operculate symmoriiform chondrichthyan from the Late Mississippian Fayetteville Shale (Arkansas, United States)". Geodiversitas. 46 (4): 101–117. doi:10.5252/geodiversitas2024v46a4.
  20. ^ Popov, E. V.; Lopyrev, V. A.; Yarkov, A. A. (2024). "A New Genus of Kitefin Sharks (Squaliformes, Dalatiidae) from the Berezovaya Strata (Lower Paleocene) of the Lower Volga Region". Paleontological Journal. 58 (5): 556–566. Bibcode:2024PalJ...58..556P. doi:10.1134/S0031030124600720.
  21. ^ a b Duffin, C. J.; Batchelor, T. J. (2024). "A chondrichthyan fauna from the Vectis Formation (Early Aptian, Early Cretaceous) of the Isle of Wight". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 312 (3): 325–354. doi:10.1127/njgpa/2024/1217.
  22. ^ a b Hodnett, J.-P. M.; Toomey, R.; Egli, H. C.; Ward, G.; Wood, J. R.; Olson, R.; Tolleson, K.; Tweet, J. S.; Santucci, V. L. (2024). "New ctenacanth sharks (Chondrichthyes; Elasmobranchii; Ctenacanthiformes) from the Middle to Late Mississippian of Kentucky and Alabama". Journal of Vertebrate Paleontology. 43 (3). e2292599. doi:10.1080/02724634.2023.2292599.
  23. ^ a b Ivanov, A. O.; Duffin, C. J. (2024). "Late Palaeozoic anachronistid chondrichthyans". Historical Biology: An International Journal of Paleobiology: 1–19. doi:10.1080/08912963.2024.2388208.
  24. ^ Gess, R. W.; Burrow, C. J. (2024). "A new gyracanthid (stem Chondrichthyes) from the Late Devonian (Famennian) of the Eastern Cape, South Africa". Journal of Vertebrate Paleontology. 43 (4). e2305888. doi:10.1080/02724634.2024.2305888.
  25. ^ Snyder, D.; Burrow, C. J.; Turner, S. (2024). "A new gyracanthid from the Mississippian of Delta, Iowa, U.S.A.". Journal of Vertebrate Paleontology. 43 (4). e2310721. doi:10.1080/02724634.2024.2310721.
  26. ^ Migom, F. (2024). "The genus Heterodontus in the Early Paleogene of the North Sea Basin and the Landes, France". Palaeo Ichthyologica. 17: 1–60. ISBN 978-3-89937-294-6.
  27. ^ a b Babcock, L. E. (2024). "Replacement names for two species of Orthacanthus Agassiz, 1843 (Chondrichthyes, Xenacanthiformes), and discussion of Giebelodus Whitley, 1940, replacement name for Chilodus Giebel, 1848 (Chondrichthyes, Xenacanthiformes), preoccupied by Chilodus Müller & Troschel, 1844 (Actinopterygii, Characiformes)". ZooKeys (1188): 219–226. doi:10.3897/zookeys.1188.108571. PMC 10790574. PMID 38230382.
  28. ^ Ebersole, J. A.; Cicimurri, D. J.; Harrell, T. L. (2024). "A new species of Palaeohypotodus Glückman, 1964 (Chondrichthyes, Lamniformes) from the lower Paleocene (Danian) Porters Creek Formation, Wilcox County, Alabama, USA". Fossil Record. 27 (1): 111–134. Bibcode:2024FossR..27..111E. doi:10.3897/fr.27.e112800.
  29. ^ Breeden, B. T.; Oyama, N.; Manabe, M.; Takahashi, H.; Sakata, C. (2024). "A new freshwater lonchidiid hybodontiform shark (Chondrichthyes, Elasmobranchii) from the Upper Triassic Momonoki Formation in Yamaguchi, Japan". Journal of Vertebrate Paleontology. 43 (5). e2322749. doi:10.1080/02724634.2024.2322749.
  30. ^ a b Duffin, C. J.; Batchelor, T. J. (2024). "New Carcharhiniform sharks from the marine Early Cretaceous of Southern England". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 310 (2): 161–181. doi:10.1127/njgpa/2023/1176.
  31. ^ dos Santos, R. O.; Riff, D.; Ramos, R. R. C.; Rodrigues, I. F.; Scheffler, S. M.; Sucerquia, P. A.; Carvalho, M. A. (2024). "A new species of cow shark (Hexanchiformes: Hexanchidae) from the Late Cretaceous of Seymour Island, Antarctica". Historical Biology: An International Journal of Paleobiology: 1–12. doi:10.1080/08912963.2024.2316047.
  32. ^ Schnetz, L.; Butler, R. J.; Coates, M. I.; Sansom, I. J. (2024). "The skeletal completeness of the Palaeozoic chondrichthyan fossil record". Royal Society Open Science. 11 (1). 231451. doi:10.1098/rsos.231451. PMC 10827434. PMID 38298400.
  33. ^ Schnetz, L.; Dunne, E. M.; Feichtinger, I.; Butler, R. J.; Coates, M. I.; Sansom, I. J. (2024). "Rise and diversification of chondrichthyans in the Paleozoic". Paleobiology. 50 (2): 271–284. Bibcode:2024Pbio...50..271S. doi:10.1017/pab.2024.1.
  34. ^ Popov, E. V.; Lopyrev, V. A.; Panteleev, A. V.; Biriukov, A. V.; Timirchev, F. K. (2024). "Chondrichthyan fishes from the Middle Eocene Osinovaya Formation of Rostov Region, Russia". Historical Biology: An International Journal of Paleobiology: 1–27. doi:10.1080/08912963.2023.2291774.
  35. ^ Dearden, R. P.; Herrel, A.; Pradel, A. (2024). "The pharynx of the iconic stem-group chondrichthyan Acanthodes Agassiz, 1833 revisited with micro-computed tomography". Zoological Journal of the Linnean Society. doi:10.1093/zoolinnean/zlae058. hdl:10067/2066470151162165141.
  36. ^ Egli, H. C.; Hodnett, J.-P. M.; Hodge, C. M.; Ward, G. V. (2024). "Obruchevodid petalodonts (Chondrichthyes, Holocephali) from the Upper Mississippian (Serpukhovian) Bangor Limestone of northern Alabama, U.S.A.". Historical Biology: An International Journal of Paleobiology: 1–10. doi:10.1080/08912963.2024.2412139.
  37. ^ Brownstein, C. D.; Near, T. J.; Dearden, R. P. (2024). "The Palaeozoic assembly of the holocephalan body plan far preceded post-Cretaceous radiations into the ocean depths". Proceedings of the Royal Society B: Biological Sciences. 291 (2033). 20241824. doi:10.1098/rspb.2024.1824. PMC 11521621. PMID 39471859.
  38. ^ Ghosh, T.; Swami, N. K.; Kumar, K.; Maurya, A. S.; Bajpai, S. (2024). "An assemblage of Middle Jurassic hybodonts from Jaisalmer Basin, western India". Historical Biology: An International Journal of Paleobiology: 1–10. doi:10.1080/08912963.2024.2412131.
  39. ^ Bhosale, S.; Rakshit, N.; Natarajan, A.; Chauhan, G.; Thakkar, M. (2024). "The oldest Gondwanan record of durophagous shark Strophodus Agassiz, 1838 (Hybodontiformes) from the Kachchh Basin, western India". Historical Biology: An International Journal of Paleobiology: 1–13. doi:10.1080/08912963.2024.2324430.
  40. ^ Cuny, G.; Chanthasit, P. (2024). "First record of hybodont egg capsules from the Jurassic of Thailand". Annales de Paléontologie. 109 (4). 102652. doi:10.1016/j.annpal.2023.102652.
  41. ^ Neves, G. S.; Medeiros, M. A.; Dutheil, D. B.; Brito, P. M. (2024). "First record of Aegyptobatus (Hybodontiformes: Distobatidae) in the Cretaceous Alcântara formation (?Albian-Cenomanian) of Maranhão, Northeastern Brazil". Historical Biology: An International Journal of Paleobiology: 1–7. doi:10.1080/08912963.2024.2379031.
  42. ^ Sternes, P. C.; Schmitz, L.; Higham, T. E. (2024). "The rise of pelagic sharks and adaptive evolution of pectoral fin morphology during the Cretaceous". Current Biology. 34 (12): 2764–2772.e3. Bibcode:2024CBio...34.2764S. doi:10.1016/j.cub.2024.05.016. PMID 38834065.
  43. ^ Kaneko, M.; Solonin, S. V. (2024). "The first record of the orectolobiform shark genus Cederstroemia (Elasmobranchii, Orectolobidae) in Asia (Kashima Formation, Upper Cretaceous; Yubari Area, Hokkaido, Japan". Rivista Italiana di Paleontologia e Stratigrafia. 130 (2): 285–297. doi:10.54103/2039-4942/22195.
  44. ^ Vullo, R.; Villalobos-Segura, E.; Amadori, M.; Kriwet, J.; Frey, E.; González González, M. A.; Padilla Gutiérrez, J. M.; Ifrim, C.; Stinnesbeck, E. S.; Stinnesbeck, W. (2024). "Exceptionally preserved shark fossils from Mexico elucidate the long-standing enigma of the Cretaceous elasmobranch Ptychodus". Proceedings of the Royal Society B: Biological Sciences. 291 (2021). 20240262. doi:10.1098/rspb.2024.0262. PMC 11040243. PMID 38654646.
  45. ^ Shimada, K.; Boessenecker, R. W.; Perez, V. J.; Kent, B. W. (2024). "New geographic and stratigraphic occurrences of the enigmatic extinct lamniform shark, Megalolamna (Lamniformes: Otodontidae), from the eastern USA". Historical Biology: An International Journal of Paleobiology: 1–7. doi:10.1080/08912963.2023.2282664.
  46. ^ Pollerspöck, J.; Shimada, K. (2024). "The first recognition of the enigmatic fossil shark genus Megalolamna (Lamniformes, Otodontidae) from the lower Miocene of Europe and M. serotinus (Probst, 1879) as the newly designated type species for the genus". Zitteliana. 98: 1–9. doi:10.3897/zitteliana.98.e131387.
  47. ^ Cooper, J. A.; Hutchinson, J. R.; Bernvi, D. C.; Cliff, G.; Wilson, R. P.; Dicken, M. L.; Menzel, J.; Wroe, S.; Pirlo, J.; Pimiento, C. (2022). "The extinct shark Otodus megalodon was a transoceanic superpredator: Inferences from 3D modeling". Science Advances. 8 (33): eabm9424. Bibcode:2022SciA....8M9424C. doi:10.1126/sciadv.abm9424. PMC 9385135. PMID 35977007.
  48. ^ Sternes, P. C.; Jambura, P. L.; Türtscher, J.; Kriwet, J.; Siversson, M.; Feichtinger, I.; Naylor, G. J. P.; Summers, A. P.; Maisey, J. G.; Tomita, T.; Moyer, J. K.; Higham, T. E.; da Silva, J. P. C. B.; Bornatowski, H.; Long, D. J.; Perez, V. J.; Collareta, A.; Underwood, C.; Ward, D. J.; Vullo, R.; González-Barba, G.; Maisch, H. M.; Griffiths, M. L.; Becker, M. A.; Wood, J. J.; Shimada, K. (2024). "White shark comparison reveals a slender body for the extinct megatooth shark, Otodus megalodon (Lamniformes: Otodontidae)". Palaeontologia Electronica. 27 (1). 27.1.7a. doi:10.26879/1345. PMC 7616624. PMID 39404696.
  49. ^ Paredes-Aliaga, M. V.; Herraiz, J. L. (2024). "Analysing Trophic Competition in †Otodus megalodon and Carcharodon carcharias through 2D-SEM Dental Microwear". Spanish Journal of Palaeontology. 39 (1): 91–102. doi:10.7203/sjp.28830.
  50. ^ Godfrey, S. J.; Murdoch, P.; Dewaele, L.; Perez, V. J.; Schumaker, C. (2024). "First report in the fossil record of a shark tooth embedded in a pinniped bone". Comptes Rendus Palevol. 23 (8): 107–118. Bibcode:2024CRPal..23.....G. doi:10.5852/cr-palevol2024v23a8.
  51. ^ Greenfield, T. (2024). "Arthrobatidae nom. nov., a replacement for the invalid name Arthropteridae Jordan, 1905 (?Chondrichthyes, ?Batomorphii)". Zootaxa. 5433 (2): 299–300. doi:10.11646/zootaxa.5433.2.9.
  52. ^ Capasso, L.; Abdel Aziz, S.; Tantawy, A. A.; Mousa, M. K.; Wahba, D. G. A.; Abu El-Kheir, G. A. (2024). "The first described Onchopristis Stromer, 1917, (Elasmobranchii: †Onchopristidae) from the Marine Maastrichtian of Dakhla Formation, Western Desert, Egypt". Journal of African Earth Sciences. 220. 105415. Bibcode:2024JAfES.22005415C. doi:10.1016/j.jafrearsci.2024.105415.
  53. ^ Kocsis, L. (2024). "The Elasmobranch Fossil Record of the Indo-Australian Archipelago since the Miocene: A Literature Review and New Discoveries from Northern Borneo". Diversity. 16 (6). 323. doi:10.3390/d16060323.
  54. ^ Paredes-Aliaga, M. V.; Botella, H.; Romero, A. (2024). "Testing dental microwear as a proxy for characterising trophic ecology in fossil elasmobranchs (chondrichthyans)". Swiss Journal of Palaeontology. 143 (1). 29. Bibcode:2024SwJP..143...29P. doi:10.1186/s13358-024-00322-9.
  55. ^ Cooper, J. A.; Pimiento, C. (2024). "The rise and fall of shark functional diversity over the last 66 million years". Global Ecology and Biogeography. 33 (9): e13881. Bibcode:2024GloEB..33E3881C. doi:10.1111/geb.13881.
  56. ^ Brito, P. M.; Dutheil, D. B.; Gueriau, P.; Keith, P.; Carnevale, G.; Britto, M.; Meunier, F. J.; Khalloufi, B.; King, A.; de Amorim, P. F.; Costa, W. J. E. M. (2024). "A Saharan fossil and the dawn of Neotropical armoured catfishes in Gondwana" (PDF). Gondwana Research. 132: 103–112. Bibcode:2024GondR.132..103B. doi:10.1016/j.gr.2024.04.008.
  57. ^ Britz, R.; Pinion, A. K.; Kubicek, K. M.; Conway, K. W. (2024). "Comment on "A Saharan fossil and the dawn of Neotropical armoured catfishes in Gondwana" by Brito et al". Gondwana Research. 133: 267–269. Bibcode:2024GondR.133..267B. doi:10.1016/j.gr.2024.06.014.
  58. ^ Brito, P. M.; Dutheil, D. B.; Keith, P.; Carnevale, G.; Meunier, F. J.; Khalloufi, B.; Gueriau, P. (2024). "A reply to a comment on Brito et al., 2024, A Saharan fossil and the dawn of the Neotropical armoured catfishes in Gondwana by Britz, Pinion, Kubicek and Conway". Gondwana Research. 133: 348–351. doi:10.1016/j.gr.2024.06.013.
  59. ^ Brownstein, C. D.; Near, T. J. (2024). "A giant bowfin from a Paleocene hothouse ecosystem in North America". Zoological Journal of the Linnean Society. doi:10.1093/zoolinnean/zlae042.
  60. ^ Carnevale, G.; Tyler, J. C. (2024). "A new moorish idol (Teleostei, Zanclidae) from the Eocene of Bolca, Italy". Rivista Italiana di Paleontologia e Stratigrafia. 130 (1): 19–33. doi:10.54103/2039-4942/21794.
  61. ^ Bannikov, A. F.; Tyler, J. C. (2024). "A new species of the fossil pufferfish genus †Archaeotetraodon (Tetraodontidae) from the Middle Miocene of the North Caucasus, Russia". Zootaxa. 5468 (1): 145–153. doi:10.11646/zootaxa.5468.1.5.
  62. ^ a b c Arratia, G.; Schultze, H.-P. (2024). "The oldest teleosts (Teleosteomorpha): their early taxonomic, phenotypic, and ecological diversification during the Triassic". Fossil Record. 27 (1): 29–53. Bibcode:2024FossR..27...29A. doi:10.3897/fr.27.115970.
  63. ^ Granica, M.; Bieńkowska-Wasiluk, M.; Pałdyna, M. (2024). "A new clupeoid genus from the Oligocene of Central Paratethys (Menilite Formation, Poland)". Acta Geologica Polonica. 74 (1). e5. doi:10.24425/agp.2023.148029.
  64. ^ Medina-Castañeda, C. I.; Cantalice, K. M.; Castañeda-Posadas, C. (2024). "A new crossognathiform fish (Teleostei: †Crossognathiformes) from San José de Gracia quarry reveals a great diversity in the Cretaceous outcrops of Mexico". Cretaceous Research. 166. 106026. doi:10.1016/j.cretres.2024.106026.
  65. ^ Bogan, S.; Agnolín, F. L. (2024). "First fossil record of Aspredinidae: a new species from the late Miocene of northeastern Argentina". Zootaxa. 5493 (4): 392–400. doi:10.11646/zootaxa.5493.4.5.
  66. ^ Taverne, L. (2024). "The Pantodontidae (Teleostei, Osteoglossomorpha) from the marine Cenomanian (Upper Cretaceous) of Lebanon. 6°. Cretapantodon polli gen. and sp. nov" (PDF). Geo-Eco-Trop. 46 (3): 435–443.
  67. ^ a b c d Ahnelt, H.; Bradić-Milinović, K. (2024). "A Unique and Species-Rich Assemblage of Freshwater Glassfishes (Teleostei: Ambassidae: Dapalis) from the lower Oligocene of the Central Paratethys with the Description of Four New Species". Taxonomy. 4 (4): 805–849. doi:10.3390/taxonomy4040044.
  68. ^ Ahnelt, H.; Bradić-Milinović, K.; Schwarzhans, W. (2024). "Dapalis pauciserratus, a new species of freshwater glassfishes (Teleostei, Ambassidae) from the Lower Oligocene of the Central Paratethys". Cybium. 48 (3): 195–209. doi:10.26028/cybium/2024-006.
  69. ^ Diependaal, H. J.; Winkelhorst, H.; Wijngaarden, C. L.; Reumer, J. W. F. (2024). "A new species of Eosemionotus (Holostei, Macrosemiidae) from the Anisian (Middle Triassic) of Winterswijk, the Netherlands" (PDF). Deinsea. 22: 1–22.
  70. ^ a b Bakaev, A. S. (2024). "Revision of Permian Ray-Finned Fishes from the Leninsk and Tailugan Formations of the Kuznetsk Basin". Paleontological Journal. 58 (1): 95–100. Bibcode:2024PalJ...58...95B. doi:10.1134/S0031030123060011.
  71. ^ Kovalchuk, O.; Otero, O.; Barkaszi, Z.; Murray, A. M.; Divay, J. D. (2024). "A new species of Lates (Perciformes, Latidae) from the Late Miocene of Ukraine and notes on the latest records of lates perches in the Eastern Paratethys". Journal of Vertebrate Paleontology. 43 (4). e2299314. doi:10.1080/02724634.2023.2299314.
  72. ^ Reichenbacher, B.; Přikryl, T. (2024). "Revision and phylogenetic placement of one of the earliest freshwater gobies from the Lower Oligocene of Central Europe". Historical Biology: An International Journal of Paleobiology: 1–19. doi:10.1080/08912963.2024.2406964.
  73. ^ Capobianco, A.; Zouhri, S.; Friedman, M. (2024). "A long-snouted marine bonytongue (Teleostei: Osteoglossidae) from the early Eocene of Morocco and the phylogenetic affinities of marine osteoglossids". Zoological Journal of the Linnean Society. doi:10.1093/zoolinnean/zlae015.
  74. ^ a b c d De Gracia, C.; Villalobos-Segura, E.; Ballen, G. A.; Carnevale, G.; Kriwet, J. (2024). "Phylogenetic patterns in fossil and living billfishes (Istiophoriformes, Istiophoridae): evidence from the Central Mediterranean". Papers in Palaeontology. 10 (4). e1559. Bibcode:2024PPal...10E1559D. doi:10.1002/spp2.1559.
  75. ^ Arratia, G.; Bürgin, T.; Furrer, H. (2024). "A new suction feeder and miniature teleosteomorph, Marcopoloichthys mirigioliensis, from the lower Besano Formation (late Anisian) of Monte San Giorgio". Swiss Journal of Palaeontology. 143 (1). 25. Bibcode:2024SwJP..143...25A. doi:10.1186/s13358-024-00318-5.
  76. ^ Arratia, G.; Bürgin, T.; Furrer, H. (2024). "Correction: A new suction feeder and miniature teleosteomorph, Marcopoloichthys mirigioliensis, from the lower Besano Formation (late Anisian) of Monte San Giorgio". Swiss Journal of Palaeontology. 143 (1). 28. Bibcode:2024SwJP..143...28A. doi:10.1186/s13358-024-00326-5.
  77. ^ Kim, S.H.; Lee, Y.N.; Nam, G.S.; Park, J.Y.; Lee, S.; Son, M. (2024). "A new exceptionally well-preserved basal actinopterygian fish in the juvenile stage from the Upper Triassic Amisan Formation of South Korea". Scientific Reports. 14 (1). 317. Bibcode:2024NatSR..14..317K. doi:10.1038/s41598-023-50803-z. PMC 10764774. PMID 38172381.
  78. ^ Thies, D.; Stevens, K.; Ansorge, J. (2024). "A new lepisosteiform neopterygian (Actinopterygii) from the lower Toarcian Grimmen Formation (Lower Jurassic) of Mecklenburg and Western Pomerania, Germany". PalZ. Bibcode:2024PalZ..tmp...23T. doi:10.1007/s12542-023-00683-5.{{cite journal}}: CS1 maint: bibcode (link)
  79. ^ Elliott, F. M.; Giles, S. (2024). "A new species of Mesolepis (Actinopterygii) from the Late Carboniferous of Scotland, with especial reference to Mesolepis wardi Young". Earth and Environmental Science Transactions of the Royal Society of Edinburgh: 1–12. doi:10.1017/S1755691024000094.
  80. ^ Bannikov, A. F.; Erebakan, I. G. (2024). "A New Genus for the Sarmatian (Uppermost Middle Miocene) Mackerels (Scombridae) from the North Caucasus". Paleontological Journal. 58 (3): 315–323. Bibcode:2024PalJ...58..315B. doi:10.1134/S0031030124700102.
  81. ^ Ebert, M.; López-Arbarello, A. (2024). "The Problematic Genus Liodesmus Wagner and a New Genus of Caturoidea (Halecomorphi, Neopterygii) from the Upper Jurassic Solnhofen-Archipelago". Diversity. 16 (9). 568. doi:10.3390/d16090568.
  82. ^ López-Arbarello, A.; Brocke, R. (2024). "New generic name for a small Triassic ray-finned fish from Perledo (Italy)". Swiss Journal of Palaeontology. 143 (1). 30. Bibcode:2024SwJP..143...30L. doi:10.1186/s13358-024-00325-6.
  83. ^ Noriega, J. I.; Peralta, M. J.; Monsalvo, S.; Brunetto, E.; Brandoni, D. (2024). "A new species of black drum (Acanthuriformes: Sciaenidae: Pogonias Lacépède, 1802) from the Upper Miocene of Argentina". Journal of Systematic Palaeontology. 22 (1). 2368182. Bibcode:2024JSPal..2268182N. doi:10.1080/14772019.2024.2368182.
  84. ^ a b Kanarkina, A.; Zverkov, N.; Polyakova, I. (2024). "New evidence of the global distribution of the swordfish-like pachycormid Protosphyraena in the late Early Cretaceous and a review of global records of the genus". Cretaceous Research. 166. 106019. doi:10.1016/j.cretres.2024.106019.
  85. ^ Bienkowska-Wasiluk, M.; Granica, M.; Kovalchuk, O. (2024). "A new extinct shad from Poland in the light of clupeiform diversity and distribution within the Paratethys during the Oligocene". Acta Geologica Polonica. 74 (3). e23. doi:10.24425/agp.2024.151753.
  86. ^ Dirnberger, M.; Bauer, E.; Reichenbacher, B. (2024). "A new freshwater gobioid from the Lower Miocene of Turkey in a significantly amended total evidence phylogenetic framework". Journal of Systematic Palaeontology. 22 (1). 2340498. Bibcode:2024JSPal..2240498D. doi:10.1080/14772019.2024.2340498.
  87. ^ Barták, P.; Ivanov, M.; Tihlaříková, E.; Olbert, M.; Neděla, V. (2024). "New, large actinopterygian fishes from the upper Carboniferous of Nýřany, Czech Republic". Acta Palaeontologica Polonica. 69 (3): 501–522. doi:10.4202/app.01162.2024.
  88. ^ Přikryl, T.; Lin, C.-H.; Hsu, C.-H.; Lee, S.-W. (2024). "New acropomatiform fossils from the Upper Kueichulin Formation (Lower Pliocene), northern Taiwan". Rivista Italiana di Paleontologia e Stratigrafia. 130 (2): 211–229. doi:10.54103/2039-4942/22639.
  89. ^ Xu, G.-H.; Yuan, Z.-W.; Ren, Y.; Liao, J.-L.; Zhao, L.-J.; Song, H.-J. (2024). "Teffichthys wui sp. nov., a new perleidid fish from the Early Triassic of Jiangsu and Anhui, China". Vertebrata PalAsiatica. 62 (3): 165–185. doi:10.19615/j.cnki.2096-9899.240528.
  90. ^ Cooper, S. L. A.; López-Arbarello, A.; Maxwell, E. E. (2024). "First occurrence of a †coccolepidid fish (?Chondrostei: †Coccolepididae) from the Upper Lias (Toarcian, Early Jurassic) of southern Germany". Palaeontologia Electronica. 27 (1). 27.1.a23. doi:10.26879/1326.
  91. ^ Yabumoto, Y.; Nomura, R.; Nazarkin, M. V. (2024). "A New Miocene Deep-Sea Fish, Vinciguerria shinjiensis sp. nov. (Stomiiformes: Phosichthyidae) from Shinji, Matsue City, Shimane, Japan". Paleontological Research. 28 (4): 394–406. doi:10.2517/PR220030.
  92. ^ Arratia, G.; González-Rodríguez, K. A. (2024). "A New Intriguing Teleost from the Albian Muhi Quarry, Central Mexico, and Early Euteleostean Diversification". Diversity. 16 (7). 414. doi:10.3390/d16070414.
  93. ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae af ag ah ai aj ak al am an ao ap aq ar as at au av aw ax ay az ba bb bc bd be bf bg bh bi bj bk Schwarzhans, W. W.; Stringer, G. L.; Takeuchi, G. T. (2024). "The middle Eocene bony fish fauna of California, USA, reconstructed by means of otoliths". Rivista Italiana di Paleontologia e Stratigrafia. 130 (2): 373–473. doi:10.54103/2039-4942/22783.
  94. ^ a b c d e f Kocsis, L.; Lin, C.-H.; Bernard, E.; Johari, A. (2024). "Late Miocene teleost fish otoliths from Brunei Darussalam (Borneo) and their implications for palaeoecology and palaeoenvironmental conditions". Historical Biology: An International Journal of Paleobiology: 1–35. doi:10.1080/08912963.2023.2271489.
  95. ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae af ag ah ai aj ak al am an ao ap aq ar as at au av aw Schwarzhans, W. W.; Aguilera, O. A. (2024). "Otoliths of the Gobiidae from the Neogene of tropical America". Swiss Journal of Palaeontology. 143 (1). 13. Bibcode:2024SwJP..143...13S. doi:10.1186/s13358-023-00302-5.
  96. ^ a b c d e f g h i Lin, C.-H.; Steurbaut, E.; Nolf, D. (2024). "Early Eocene fish otoliths from the eastern and southern USA". European Journal of Taxonomy (935): 203–240. doi:10.5852/ejt.2024.935.2557.
  97. ^ a b c d e f g h i Schwarzhans, W.; Klots, O.; Kovalchuk, O.; Dubikovska, A.; Ryabokon, T.; Kovalenko, V. (2024). "Life on a Miocene barrier reef – fish communities and environments in the Medobory backreef". Palaeontologia Electronica. 27 (3). 27.3.a46. doi:10.26879/1429.
  98. ^ a b c d Schwarzhans, W. W.; Wakefield, M. I. (2024). "Otoliths from the Lealt Shale Formation, Great Estuarine Group, Middle Jurassic (Bathonian), Inner Hebrides, Scotland". Scottish Journal of Geology. 60 (2): 002. Bibcode:2024ScJG...60....2S. doi:10.1144/sjg2024-002.
  99. ^ a b c d e f g h i j k l m n o Schwarzhans, W. W.; Carnevale, G. (2024). "Fish otoliths from the upper Oligocene and Lower Miocene of the Monferrato and Turin Hill, northern Italy". Rivista Italiana di Paleontologia e Stratigrafia. 130 (3): 663–709. doi:10.54103/2039-4942/23455.
  100. ^ a b c Tsuchiya, Y.; Schwarzhans, W.; Ohe, F.; Ujihara, A. (2024). "Deep-sea fish otoliths from the Lower Miocene Oi and Katada formations, Ichishi Group, Mie Prefecture, central Japan". Historical Biology: An International Journal of Paleobiology: 1–24. doi:10.1080/08912963.2023.2301408.
  101. ^ Stringer, G. L.; Welton, B. J. (2024). "The enigmatic occurrence, size distribution, and significance of a new macrourid species, Nezumia armentrouti, based on otoliths from the Lincoln Creek Formation (upper Oligocene Section), Washington State, USA". Historical Biology: An International Journal of Paleobiology: 1–17. doi:10.1080/08912963.2024.2310199.
  102. ^ Near, T. J.; Thacker, C. E. (2024). "Phylogenetic Classification of Living and Fossil Ray-Finned Fishes (Actinopterygii)". Bulletin of the Peabody Museum of Natural History. 65 (1): 3–302. doi:10.3374/014.065.0101.
  103. ^ Dankina, D.; Šečkus, J.; Plax, D. P. (2024). "Middle Devonian actinopterygians from Lithuania and Belarus". Fossil Studies. 2 (3): 141–159. doi:10.3390/fossils2030007.
  104. ^ Figueroa, R. T.; Weinschütz, L. C.; Giles, S.; Friedman, M. (2024). "Soft-tissue fossilization illuminates the stepwise evolution of the ray-finned fish brain". Current Biology. 34 (13): 2831–2840.e2. Bibcode:2024CBio...34.2831F. doi:10.1016/j.cub.2024.05.027. PMID 38866006.
  105. ^ Štamberg, S. (2024). "Redescription of the actinopterygian fish Westollia crassa (Pohlig, 1892) (Aeduellidae) from the Permian sediments of Thuringia and its relationships to other Aeduellidae". PalZ. 98 (3): 491–508. Bibcode:2024PalZ...98..491S. doi:10.1007/s12542-024-00696-8.
  106. ^ Bakaev, A. S.; Bulanov, V. V.; Kogan, I.; Johanson, Z.; Minikh, A. V. (2024). "Early ray-finned herbivores: the dental system of Eurynotoidiidae (Actinopterygii; middle–late Permian, European Russia) and implications for palaeobiology and palaeoecology". Palaeontology. 67 (3). e12700. Bibcode:2024Palgy..6712700B. doi:10.1111/pala.12700.
  107. ^ Bakaev, A. S. (2024). "Actinopterygians from the continental Permian–Triassic boundary section at Babiy Kamen (Kuznetsk Basin, Siberia, Russia)". Palaeoworld. doi:10.1016/j.palwor.2024.05.007.
  108. ^ Kumar, P.; Patnaik, R.; Choudhary, D.; Kumar, R.; Wazir, W. A. (2024). "First report of Cylindracanthus (Osteichthyes) from the Eocene of India". Palæovertebrata. 47 (1). e2. doi:10.18563/pv.47.1.e2 (inactive 1 November 2024).{{cite journal}}: CS1 maint: DOI inactive as of November 2024 (link)
  109. ^ Cooper, S. L. A. (2024). "First occurrence of an acipenseriform (Chondrostei: Acipenseriformes) from the Upper Jurassic Kimmeridge Clay Formation of England". Journal of Vertebrate Paleontology. e2407171. doi:10.1080/02724634.2024.2407171.
  110. ^ Cavin, L.; Argyriou, T.; Romano, C.; Grădinaru, E. (2024). "Large durophagous fish from the Spathian (late Early Triassic) of Romania hints at earlier onset of the Triassic actinopterygian revolution". Papers in Palaeontology. 10 (2). e1553. Bibcode:2024PPal...10E1553C. doi:10.1002/spp2.1553.
  111. ^ Cawley, J. J.; Kriwet, J. (2024). "The Fossil Record and Diversity of Pycnodontiform Fishes in Non-Marine Environments". Diversity. 16 (4). 225. doi:10.3390/d16040225.
  112. ^ Capasso, L. (2024). "Growth and Aging in †Pycnodonts (Actinopterygii: †Pycnodontomorpha)". Paleontological Research. 28 (3): 1–23. doi:10.2517/PR230017.
  113. ^ Capasso, L.; Ebert, M.; Witzmann, F. (2024). "Dental paleopathologies in †Pycnodontiformes (Osteichthyes: Actinopterygii)". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 311 (3): 299–341. doi:10.1127/njgpa/2024/1193.
  114. ^ Capasso, L.; Ebert, M.; Witzmann, F. (2024). "Skeletal and integumental paleopathologies in †Pycnodontomorpha (Osteichthyes: Actinopterygii)". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. doi:10.1127/njgpa/2024/1218.
  115. ^ Capasso, L.; Witzmann, F. (2024). "Non-dental odontodes in the masticatory apparatus of †pycnodonts (Osteichthyes, Actinopterygii)". Historical Biology: An International Journal of Paleobiology: 1–6. doi:10.1080/08912963.2024.2405882.
  116. ^ Fang, G.-Y.; Wu, F.-X. (2024). "New insights into Tibetodus gyrodoides Young & Liu, 1954 (Actinopterygii, Pycnodontiformes) from the Qinghai-Xizang Plateau based on micro-CT data". Mesozoic. 1 (3): 389–395. doi:10.11646/mesozoic.1.3.18.
  117. ^ Vullo, R.; Frey, E. (2024). "Bat consumption by holostean fishes in the Eocene Lake Messel: insights into the trophic adaptability of extinct gars and bowfins". Biology Letters. 20 (9). 20240194. doi:10.1098/rsbl.2024.0194. PMC 11371436. PMID 39226920.
  118. ^ Gouiric-Cavalli, S.; Iglesias, A.; Cariglino, B.; Reguero, M. A. (2024). "A Late Jurassic deep-bodied actinopterygian fish from Antarctica". Acta Palaeontologica Polonica. 69 (3): 467–483. doi:10.4202/app.01158.2024.
  119. ^ Nikolov, V.; Andreev, P.; Voykov, G.; Dochev, D. (2024). "The first record of gars (Ginglymodi: Lepisosteidae) from the Upper Cretaceous of Bulgaria reveals a wider paleogeographic distribution of lepisosteids within the European Archipelago". Cretaceous Research. 165. 105985. doi:10.1016/j.cretres.2024.105985.
  120. ^ Weis, R.; Delsate, D.; Klug, C.; Argyriou, T.; Fuchs, D. (2024). "Pachycormid fish fed on octobrachian cephalopods: new evidence from the 'Schistes bitumineux' (early Toarcian) of southern Luxembourg". Swiss Journal of Palaeontology. 143 (1). 5. Bibcode:2024SwJP..143....5W. doi:10.1186/s13358-023-00295-1.
  121. ^ Cooper, S. L. A. (2024). "Cannibalism in the Early Jurassic bony fish Pachycormus macropterus (Teleosteomorpha: Pachycormiformes) and its paleoecological significance". Journal of Vertebrate Paleontology. 43 (3). e2294000. doi:10.1080/02724634.2023.2294000.
  122. ^ Cooper, S. L. A.; Maxwell, E. E.; Martill, D. M. (2024). "An unusually large 'suspension-feeding' fish from the Kimmeridge Clay Formation of Dorset: the first true record of Asthenocormus (Pachycormiformes: Asthenocorminae) in the UK". PalZ. 98 (3): 469–490. Bibcode:2024PalZ...98..469C. doi:10.1007/s12542-024-00700-1.
  123. ^ Bean, L. B. (2024). "A revision of the Late Jurassic fish Aphnelepis australis from the Talbragar Fossil Fish Bed of New South Wales, Australia". Alcheringa: An Australasian Journal of Palaeontology. 48 (1): 109–126. Bibcode:2024Alch...48..109B. doi:10.1080/03115518.2024.2311092.
  124. ^ Bennett, S. C. (2024). "Pathological caudal skeleton of an ichthyodectiform fish from the Upper Cretaceous Niobrara Formation of western Kansas, USA". PeerJ. 12. e17353. doi:10.7717/peerj.17353. PMC 11086299. PMID 38737736.
  125. ^ Cantalice, K. M.; Porras-Múzquiz, H.; de Mayrinck, D.; Alvarado-Ortega, J. (2024). "Bonefish (Elopomorpha, Albuliformes) remains from Late Cretaceous outcrops of San Carlos Quarry, Coahuila, Northern Mexico: evidence of a new giant teleost in the Western Interior Seaway". Paleontología Mexicana. 13 (1): 35–44. doi:10.22201/igl.05437652e.2024.13.1.371.
  126. ^ Capobianco, A.; Friedman, M. (2024). "Fossils indicate marine dispersal in osteoglossid fishes, a classic example of continental vicariance". Proceedings of the Royal Society B: Biological Sciences. 291 (2028). 20241293. doi:10.1098/rspb.2024.1293. PMC 11321865. PMID 39137888.
  127. ^ Kevrekidis, C.; Moritz, T.; Cerwenka, A. F.; Bauer, E.; Reichenbacher, B. (2024). "Uncovering the relationships among herring-like fossils (Clupei: Teleostei): a phylogenetic analysis". Zoological Journal of the Linnean Society. 202 (3). zlae115. doi:10.1093/zoolinnean/zlae115.
  128. ^ Liu, J.; Chang, M.; Zhang, J.; Chen, G.; Shi, C. (2024). "Taxonomic revision and type specimens' location of jianghanichthyids (Ostariophysii: Cypriniformes) from Buxin Formation, Sanshui Basin, China". Journal of Vertebrate Paleontology. 43 (6). e2342857. doi:10.1080/02724634.2024.2342857.
  129. ^ Claeson, K. M.; Sidlauskas, B. L.; Troll, R.; Prescott, Z. M.; David, E. B. (2024). "From sabers to spikes: A newfangled reconstruction of the ancient, giant, sexually dimorphic Pacific salmon, †Oncorhynchus rastrosus (SALMONINAE)". PLOS ONE. 19 (4). e0300252. doi:10.1371/journal.pone.0300252. PMC 11042722. PMID 38656950.
  130. ^ Torres-Parada, J. M.; Orihuela, J.; Patarroyo Camargo, G. D.; Alarcón Gómez, C. M.; Diaz Villamizar, J. S.; Gómez-Coronado, J. S.; Márquez Prada, J. J. (2024). "Upper Cretaceous Enchodontidae (Actinopterygii: Aulopiformes) in the La Luna formation, Eastern Cordillera, Colombia: A new report". Journal of South American Earth Sciences. 148. 105160. Bibcode:2024JSAES.14805160T. doi:10.1016/j.jsames.2024.105160.
  131. ^ Davesne, D.; Andrews, J. V.; Beckett, H. T.; Giles, S.; Friedman, M. (2024). "Three-dimensional anatomy of the early Eocene Whitephippus (Teleostei, Lampriformes) documents parallel conquests of the pelagic environment by multiple teleost lineages". Journal of Vertebrate Paleontology. 43 (3). e2284998. doi:10.1080/02724634.2023.2284998.
  132. ^ Laine, J.; Mak, S. S. T.; Martins, N. F. G.; Chen, X.; Gilbert, M. T. P.; Jones, F. C.; Pedersen, M. W.; Romundset, A.; Foote, A. D. (2024). "Late Pleistocene stickleback environmental genomes reveal the chronology of freshwater adaptation". Current Biology. 34 (5): 1142–1147.e6. Bibcode:2024CBio...34E1142L. doi:10.1016/j.cub.2024.01.056. hdl:11250/3143818. PMID 38350445.
  133. ^ Miyata, S.; Isaji, S.; Kashiwagi, K.; Asai, H. (2024). "The first record of Lower Cretaceous otoliths from the Kimigahama Formation (Barremian) of the Choshi Group, Chiba Prefecture, Japan". Palaeontologia Electronica. 27 (1). 27.1.a20. doi:10.26879/1318.
  134. ^ Schwarzhans, W. W.; Carnevale, G.; Stringer, G. L. (2024). "The diversity of teleost fishes during the terminal Cretaceous and the consequences of the K/Pg boundary extinction event". Netherlands Journal of Geosciences. 103. e5. Bibcode:2024NJGeo.103E...5S. doi:10.1017/njg.2024.1.
  135. ^ Wilson, J. D.; Huang, E. J.; Lyson, T. R.; Bever, G. S. (2024). "Freshwater fish and the Cretaceous/Palaeogene boundary: a critical assessment of survivorship patterns". Proceedings of the Royal Society B: Biological Sciences. 291 (2029). 20241025. doi:10.1098/rspb.2024.1025. PMC 11352605. PMID 39196282.
  136. ^ Challands, T. J.; Cavin, L.; Zondo, M.; Munyikwa, D.; Choiniere, J. N.; Barrett, P. M. (2024). "A new lungfish from the Upper Triassic of the Mid-Zambezi Basin, Zimbabwe". Journal of Vertebrate Paleontology. 43 (6). e2365391. doi:10.1080/02724634.2024.2365391.
  137. ^ Manuelli, L.; Mondéjar Fernández, J.; Dollman, K.; Jakata, K.; Cavin, L. (2024). "The most detailed anatomical reconstruction of a Mesozoic coelacanth". PLOS ONE. 19 (11). e0312026. Bibcode:2024PLoSO..1912026M. doi:10.1371/journal.pone.0312026. PMC 11540180. PMID 39504317.
  138. ^ Choo, B.; Holland, T.; Clement, A. M.; King, B.; Challands, T.; Young, G.; Long, J. A. (2024). "A new stem-tetrapod fish from the Middle–Late Devonian of central Australia". Journal of Vertebrate Paleontology. 43 (3). e2285000. doi:10.1080/02724634.2023.2285000.
  139. ^ Young, G. C. (2024). "Relative age of the Devonian tetrapod Metaxygnathus, based on the associated fossil fish assemblage at Jemalong, New South Wales". Alcheringa: An Australasian Journal of Palaeontology. 48 (2): 278–297. Bibcode:2024Alch...48..278Y. doi:10.1080/03115518.2024.2327039.
  140. ^ Clement, A. M.; Cloutier, R.; Lee, M. S. Y.; King, B.; Vanhaesebroucke, O.; Bradshaw, C. J. A.; Dutel, H.; Trinajstic, K.; Long, J. A. (2024). "A Late Devonian coelacanth reconfigures actinistian phylogeny, disparity, and evolutionary dynamics". Nature Communications. 15 (1). 7529. Bibcode:2024NatCo..15.7529C. doi:10.1038/s41467-024-51238-4. PMC 11392942. PMID 39266502.
  141. ^ Toriño, P.; Dutel, H.; Soto, M.; Norbis, W.; Ezquerra, V.; Perea, D. (2024). "Reconstructing an ancient fish: Three-dimensional skeletal restoration of the head of Mawsonia (Sarcopterygii, Actinistia) using CT scan, and an adjusted model for body size estimation in fossil coelacanths". Journal of Anatomy. 245 (3): 467–489. doi:10.1111/joa.14054. PMC 11306766. PMID 38749764.
  142. ^ Cupello, C.; Clément, G.; Herbin, M.; Meunier, F. J.; Brito, P. M. (2024). "Pulmonary arteries in coelacanths shed light on the vasculature evolution of air-breathing organs in vertebrates". Scientific Reports. 14 (1). 10624. Bibcode:2024NatSR..1410624C. doi:10.1038/s41598-024-61065-8. PMC 11082188. PMID 38724555.
  143. ^ Panzeri, K. M. (2024). "Revisiting the Cretaceous lungfish Atlantoceratodus iheringi (Ameghino, 1898) from the Mata Amarilla Formation (Argentina) with comments on tooth plates histology". Rivista Italiana di Paleontologia e Stratigrafia. 130 (2): 191–209. doi:10.54103/2039-4942/21646.
  144. ^ Panzeri, K. M.; Guzmán, F. A. (2024). "Unveiling the histology and anatomy of the lungfish Chaoceratodus portezuelensis (Sarcopterygii: Dipnoi) from the Portezuelo and Cerro Lisandro formations (Upper Cretaceous) of Argentine Patagonia". Palaeontologia Electronica. 27 (2). 27.2.a42. doi:10.26879/1408.
  145. ^ Stewart, T. A.; Lemberg, J. B.; Hillan, E. J.; Magallanes, I.; Daeschler, E. B.; Shubin, N. H. (2024). "The axial skeleton of Tiktaalik roseae". Proceedings of the National Academy of Sciences of the United States of America. 121 (15). e2316106121. Bibcode:2024PNAS..12116106S. doi:10.1073/pnas.2316106121. PMC 11009633. PMID 38564638.
  146. ^ Ivanov, A. O.; Seuss, B. (2024). "Late Pennsylvanian fishes from the Finis Shales of North-Central Texas (USA)". PalZ. 98 (2): 263–274. Bibcode:2024PalZ...98..263I. doi:10.1007/s12542-023-00679-1.
  147. ^ Rinehart, L. F.; Lucas, S. G. (2024). "A walking fish trace fossil from the early Permian Robledo Mountains Formation of South-Central New Mexico, USA". Historical Biology: An International Journal of Paleobiology: 1–9. doi:10.1080/08912963.2024.2371958.
  148. ^ Pindakiewicz, M.; Hryniewicz, K.; Janiszewska, K.; Kaim, A. (2024). "A microfossil evidence for the composition of fish communities in the Late Triassic of Tethys: examples from Cassian Formation, Italy". Lethaia. 57 (3): 1–15. doi:10.18261/let.57.3.7.
  149. ^ Blake, L.; Fursman, M.; Duffin, C. J.; Batchelor, T.; Hildebrandt, C.; Benton, M. J. (2024). "Microvertebrates from the Lower Greensand Group (Lower Cretaceous) of Clophill, Bedfordshire, UK, and Nutfield, Surrey, UK". Proceedings of the Geologists' Association. 135 (5): 493–517. Bibcode:2024PrGA..135..493B. doi:10.1016/j.pgeola.2024.07.002.
  150. ^ Boles, Z. M.; Ullmann, P. V.; Putnam, I.; Ford, M.; Deckhut, J. T. (2024). "New vertebrate microfossils expand the diversity of the chondrichthyan and actinopterygian fauna of the Maastrichtian–Danian Hornerstown Formation in New Jersey". Acta Palaeontologica Polonica. 69 (2): 173–198. doi:10.4202/app.01117.2023.
  151. ^ Goedert, J. L.; Kiel, S.; Thomas, E. J.; Kriwet, J. (2024). "An early Eocene fish assemblage associated with a barite deposit in the lower part of the Crescent Formation, Olympic Peninsula, Washington State, USA". PalZ. 98 (3): 443–467. Bibcode:2024PalZ...98..443G. doi:10.1007/s12542-024-00692-y. PMC 7616609. PMID 39359717.
  152. ^ Ebersole, J. A.; Cicimurri, D. J.; Stallworth, L. M.; Gentry, A. D. (2024). "Preliminary report on the fishes (Chondrichthyes & Teleostei) from the lower Oligocene (Rupelian) Red Bluff Clay at site AMo-9, Monroe County, Alabama, USA". Palæovertebrata. 47 (2). e2. doi:10.18563/pv.47.2.e2 (inactive 1 November 2024).{{cite journal}}: CS1 maint: DOI inactive as of November 2024 (link)