2017 en paleontología

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Overview of the events of 2017 in paleontology

La paleontología o paleontología es el estudio de las formas de vida prehistóricas en la Tierra a través del examen de fósiles de plantas y animales . ^[1] Esto incluye el estudio de fósiles corporales, huellas ( icnitas ), madrigueras , partes desechadas, heces fosilizadas ( coprolitos ), palinomorfos y residuos químicos . Debido a que los humanos han encontrado fósiles durante milenios, la paleontología tiene una larga historia tanto antes como después de formalizarse como ciencia . Este artículo registra descubrimientos y eventos significativos relacionados con la paleontología que ocurrieron o fueron publicados en el año 2017.

Flora

Cnidarios

Investigación

Ou et al. (2017) consideran que las especies del Cámbrico temprano Galeaplumosus abilus y Chengjiangopenna wangii son sinónimos menores de Xianguangia sinica , interpretan los fósiles atribuidos a miembros de estas especies como partes del mismo organismo y consideran que X. sinica es probablemente un cnidario madre . ^[2]
Pseudooides prima es interpretado como un cnidario y sinónimo principal de Hexaconularia sichuanensis por Duan et al. (2017). ^[3]
Sappenfield, Tarhan y Droser (2017) describen medusas cnidarias fosilizadas de la cuarcita Zabriskie del Cámbrico ( California , Estados Unidos ), lo que representa la evidencia macrofósil más antigua de medusas cnidarias del Fanerozoico reportada hasta ahora. ^[4]
Dzik, Baliński y Sun (2017) publicaron un estudio sobre la morfología de los tubos fosfáticos de Sphenothallus de la Formación Fenxiang del Ordovícico Inferior ( China ), así como del Silúrico y Devónico Inferior de Podolia ( Ucrania ), y sus implicaciones para la evolución de la simetría en el plan corporal de los cnidarios . ^[5]
Wang et al. (2017) publicaron un estudio sobre la sucesión de conjuntos de corales a lo largo de la transición del Ordovícico al Silúrico en el sur de China . ^[6]
Tornabene et al. (2017) publicaron un estudio sobre los corales pétreos actuales y fósiles , cuyo objetivo era determinar si los corales fósiles vivían en simbiosis con dinoflagelados fotosintetizadores . ^[7]

Nuevos taxones

Nombre	Novedad	Estado	Autores	Edad	Unidad	Ubicación	Notas
Acantofilo filiforme ^[8]	noviembre esp.	Válido	Coen-Aubert	Devónico ( Givetiano )		Mauritania	Un coral rugoso perteneciente a la familia Ptenophyllidae.
Acanthophyllum sougyi ^[8]	noviembre esp.	Válido	Coen-Aubert	Devónico ( Givetiano )		Mauritania	Un coral rugoso perteneciente a la familia Ptenophyllidae.
Agetolites angullongensis ^[9]	noviembre esp.	Válido	Zhen, Wang y Percival	Ordovícico tardío	Formación Angullong	Australia	Un coral tabulado .
Auholia carbonica ^[10]	noviembre esp.	Válido	Niko y Fujikawa	Carbonífero ( Viséano )	Grupo de piedra caliza de Akiyoshi	Japón	Un coral tabulado .
Bothrophyllum gorbachevensis ^[11]	noviembre esp.	Válido	Fedorowski	Carbonífero ( Bashkirio )		Ucrania	Un coral rugoso perteneciente a la familia Bothrophyllidae.
Bothrophyllum kalmyussi ^[11]	noviembre esp.	Válido	Fedorowski	Carbonífero ( Bashkirio )		Ucrania	Un coral rugoso perteneciente a la familia Bothrophyllidae.
Cambroctoconus koori ^[12]	noviembre esp.	Válido	Cáscara	Estadio cámbrico 4 o estadio 5	Formación Henson Gletscher	Tierra Verde	Un posible miembro de Octocorallia .
Charactophyllum mauritanicum ^[8]	noviembre esp.	Válido	Coen-Aubert	Devónico ( Givetiano )		Mauritania	Un coral rugoso perteneciente a la familia Disphyllidae.
Charactophyllum soraufi ^[8]	noviembre esp.	Válido	Coen-Aubert	Devónico ( Givetiano )		Mauritania	Un coral rugoso perteneciente a la familia Disphyllidae.
Dianqianophyllum ^[13]	Gen. y sp. nov.	Válido	Liao y Ma	Devónico ( Givetiano )		Porcelana	Coral rugoso . El género incluye la nueva especie D. bianqingense .
Dibunophylloides columnatus ^[14]	noviembre esp.	Válido	Fedorowski	Carbonífero ( Bashkirio )		Ucrania	Un coral rugoso perteneciente a la familia Aulophyllidae.
Dibunophylloides paulus ^[14]	noviembre esp.	Válido	Fedorowski	Carbonífero ( Bashkirio )		Ucrania	Un coral rugoso perteneciente a la familia Aulophyllidae.
Dibunophylloides similis ^[14]	noviembre esp.	Válido	Fedorowski	Carbonífero ( Bashkirio )		Ucrania	Un coral rugoso perteneciente a la familia Aulophyllidae.
Dibunophyllum medio ^[14]	noviembre esp.	Válido	Fedorowski	Carbonífero ( Bashkirio )		Ucrania	Un coral rugoso perteneciente a la familia Aulophyllidae.
Enniskillenia multiseptada ^[15]	noviembre esp.	Válido	Bamber & Rodríguez en Bamber et al.	Carbonífero ( Misisipiense )		Canadá	Un coral rugoso.
Fungiaphyllia ^[16]	Gen. y sp. nov.	Válido	Melnikova y Roniewicz	Jurásico temprano ( Hettangiense / Sinemuriano – Pliensbachiano )		Afganistán	Coral pétreo perteneciente a la familia Latomeandridae. La especie tipo es Fungiaphyllia communis .
Gillismilia ^[17]	Nombre. noviembre	Válido	Lathuilière, Charbonnier y Pacaud	Jurásico temprano ( Pliensbachiano )		Francia	Un coral ; un nombre de reemplazo para Palaeocyathus Alloiteau (1956).
Guembelastraea dronovi ^[16]	noviembre esp.	Válido	Melnikova y Roniewicz	Jurásico temprano ( Hettangiense / Sinemuriano )		Afganistán	Un coral pétreo perteneciente a la familia Tropiastraeidae, una especie de Guembelastraea .
Lithostrotion termieri^[18]	noviembre esp.	Válido	Rodríguez & Somerville en Rodríguez, Somerville & Said	Carbonífero ( Viséano )	Cuenca de Azrou-Khenifra	Marruecos	Un coral rugoso perteneciente a la familia Lithostrotionidae.
Macgea tourneuri ^[8]	noviembre esp.	Válido	Coen-Aubert	Devónico ( Givetiano )		Mauritania	Un coral rugoso perteneciente a la familia Phillipsastreidae.
Nina ^[11]	Gen. y 3 sp. y comb. nov.	Homónimo junior	Fedorowski	Carbonífero ( Serpujoviense y Bashkiriense )		Ucrania	Coral rugoso perteneciente a la familia Bothrophyllidae. La especie tipo es N. donetsiana ; el género también incluye las especies nuevas N. dibimitaria y N. magna , así como "Bothrophyllum" berestovensis Vassilyuk (1960). El nombre del género es obra de Nina Horsfield (1829).
Oppelismilia spectabilis ^[16]	noviembre esp.	Válido	Melnikova y Roniewicz	Jurásico temprano ( Hettangiense / Sinemuriano )		Afganistán	Un coral pétreo perteneciente a la familia Oppelismiliidae, una especie de Oppelismilia .
Parepismilia dolicostoma ^[16]	noviembre esp.	Válido	Melnikova y Roniewicz	Jurásico temprano ( Hettangiense – Sinemuriano temprano )		Afganistán	Un coral pétreo perteneciente a la familia Parepismiliidae, una especie de Parepismilia .
Parepismilia dronovi ^[16]	noviembre esp.	Válido	Melnikova y Roniewicz	Jurásico temprano ( Hettangiense / Sinemuriano )		Afganistán	Un coral pétreo perteneciente a la familia Parepismiliidae, una especie de Parepismilia .
Periplacotroco ^[19]	Gen. y comb. y sp. nov.	Válido	Cairns	Eoceno tardío a Mioceno medio		Australia	Un coral flabélido . El género incluye P. deltoideus (Duncan, 1864), P. corniculatus (Dennant, 1899), P. elongatus (Duncan, 1864), P. pueblensis (Dennant, 1903), P. inflectus (Dennant, 1903) y P. magnus. (Dennant, 1904), así como la nueva especie P. cudmorei .
Petrophyllia niimiensis ^[20]	noviembre esp.	Válido	Niko, Suzuki y Taguchi	mioceno	Grupo Bihoku	Japón	Un coral pétreo .
Protomichelinia funafusensis ^[21]	noviembre esp.	Válido	Nico	Pérmico temprano	Caliza Funafuseyama	Japón	Un coral tabulado perteneciente al orden Favositida y a la familia Micheliniidae.
Qinscifo ^[22]	Gen. y sp. nov.	Válido	Liu y otros.	Cámbrico ( Fortuniense )	Formación Kuanchuanpu	Porcelana	Posible medusa corona perteneciente a la familia Olivooidae. La especie tipo es Q. necopinus .
Rozkowskia lenta ^[14]	noviembre esp.	Válido	Fedorowski	Carbonífero ( Bashkirio )		Ucrania	Un coral rugoso perteneciente a la familia Aulophyllidae.
Scoliopora hosakai ^[23]	noviembre esp.	Válido	Niko, Ibaraki y Tazawa	Devónico medio		Japón	Un coral tabulado perteneciente al orden Favositida y a la familia Alveolitidae.
Sinaster ^[24]	Gen. y sp. nov.	Válido	Wang y otros.	Cámbrico temprano	Formación Kuanchuanpu	Porcelana	Miembro de Medusozoa perteneciente a la familia Olivooidae. La especie tipo es S. petalon .
Stephanophyllia plattenwaldensis ^[25]	noviembre esp.	Válido	Barón-Szabo	Cretácico temprano (finales del Aptiense al Albiano )	Formación Garschella	Austria	Un coral pétreo perteneciente a la familia Micrabaciidae .
Esterictopatías ^[26]	Gen. y sp. nov.	Válido	Balneario y sol	Ordovícico (principios del Floiano )	Formación Fenxiang Formación Honghuayuan	Porcelana	Un coral negro emparentado con Sinopathes reptans . La especie tipo es S. radicatus .
Voragoaxum ^[14]	Gen. y sp. nov.	Válido	Fedorowski	Carbonífero ( Bashkirio )		Ucrania	Coral rugoso perteneciente a la familia Aulophyllidae. La especie tipo es V. cavum .
Zaphrentites etheringtonensis ^[15]	noviembre esp.	Válido	Bamber & Rodríguez en Bamber et al.	Carbonífero (Misisipiense)		Canadá	Un coral rugoso.
Zaphrentites lerandi ^[15]	noviembre esp.	Válido	Bamber & Rodríguez en Bamber et al.	Carbonífero (Misisipiense)		Canadá	Un coral rugoso.

Artrópodos

Briozoos

Investigación

Key et al. (2017) informan sobre briozoos epizoicos en cangrejos fósiles de la Formación Mishan del Mioceno ( Irán ). ^[27]

Nuevos taxones

Nombre	Novedad	Estado	Autores	Edad	Unidad	Ubicación	Notas
Acupipora mexicana ^[28]	noviembre esp.	Válido	Ernst & Vachard	Carbonífero ( Pensilvaniano medio )		México
Adeonellopsis sandbergi ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Adeonidae .
'Akatopora' en peligro de extinción ^[30]	noviembre esp.	Válido	Martha, Niebuhr y Scholz	Cretácico tardío (mediados-finales del Turoniano )	Formación Strehlen	Alemania	Un briozoo queilostoma .
Atactotoechus vaulxensis ^[31]	noviembre esp.	Válido	Ernst y otros.	Carbonífero ( Misisipiense )		Bélgica	Un briozoo .
Bashkirella arnaoense ^[32]	noviembre esp.	Válido	Suárez Andrés & Wyse Jackson	Devónico ( Eifeliense )	Formación Moniello	España	Un miembro de Fenestrata perteneciente a la familia Chasmatoporidae.
Bigeyina cantabrica ^[32]	noviembre esp.	Válido	Suárez Andrés & Wyse Jackson	Devónico ( Emsiense – principios del Eifeliano )	Formación Moniello	España	Un miembro de Fenestrata perteneciente a la familia Semicosciniidae.
Bigeyina spinosa ^[32]	noviembre esp.	Válido	Suárez Andrés & Wyse Jackson	Devónico ( Emsiense – principios del Eifeliano )	Formación Moniello	España	Un miembro de Fenestrata perteneciente a la familia Semicosciniidae.
Bragella ^[33]	Gen. y sp. nov.	Válido	Di Martino y otros.	Transición Eoceno – Oligoceno		Tanzania	Briozoo queilostomado . El género incluye la nueva especie B. pseudofedora .
Buskia waiinuensis ^[34]	noviembre esp.	Válido	Di Martino y otros.	pleistoceno	Caliza Nukumaru	Nueva Zelanda	Un miembro de Ctenostomatida perteneciente a la superfamilia Vesicularioidea y a la familia Buskiidae .
Cheiloporina clarksvillensis ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Cheiloporinidae .
Solenoide de cigclisula ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Colatooeciidae .
Coeloclemis zefrehensis ^[35]	noviembre esp.	Válido	Ernst y otros.	Devónico ( Frasniano )	Formación Bahram	Irán	Un briozoo trepostoma .
Acetato de diplosol ^[36]	noviembre esp.	Válido	Viskova y Pakhnevich	Jurásico medio ( Calloviano )		Rusia	Un briozoo perteneciente a la clase Stenolaemata y al orden Tubuliporida.
Ditaxipora lakriensis ^[37]	noviembre esp.	Válido	Sonar y Pawar	Mioceno ( Burdigaliense )	Formación Chhasra	India	Un miembro de la familia Catenicellidae .
Eridopora moravica ^[38]	noviembre esp.	Válido	Tolokonnikova, Kalvoda y Kumpan	Carbonífero ( Tournaisiano )		República Checa
Escharoides joannae ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Romancheinidae .
Euthyrhombopora tenuis ^[35]	noviembre esp.	Válido	Ernst y otros.	Devónico ( Frasniano )	Formación Bahram	Irán	Un briozoo criptóstomo rabdomesino .
Exechonella minutiperforata ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Exechonellidae .
Exidmonea baghi ^[39]	noviembre esp.	Válido	Zágoršek, Yazdi y Bahrami	mioceno	Formación Qom	Irán	Un briozoo ciclóstomo .
Fabifenestella almazani ^[28]	noviembre esp.	Válido	Ernst & Vachard	Carbonífero ( Pensilvaniano medio )		México
Fenestrapora elegans^[32]	noviembre esp.	Válido	Suárez Andrés & Wyse Jackson	Devónico ( Emsiano tardío – Eifeliense temprano )	Formación Moniello	España	Un miembro de Fenestrata perteneciente a la familia Semicosciniidae.
Filites robustus ^[32]	noviembre esp.	Válido	Suárez Andrés & Wyse Jackson	Devónico ( Emsiense – principios del Eifeliano )	Formación Moniello	España	Un miembro de Fenestrata perteneciente a la familia Acanthocladiidae.
Floridina subantiqua ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Onychocellidae .
Foratella cervisia ^[40]	noviembre esp.	Válido	Taylor y Martha	Cretácico tardío ( Cenomaniano )	Formación de piedra caliza Beer Head	Reino Unido	Un briozoo queilostoma .
Hagiosynodos simplex ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Cheiloporinidae .
Heteractis tanzaniensis ^[33]	noviembre esp.	Válido	Di Martino y otros.	Transición Eoceno – Oligoceno		Tanzania	Un briozoo queilostoma .
Hillmeropora ^[30]	Gen. y sp. nov.	Válido	Martha, Niebuhr y Scholz	Cretácico tardío (mediados-finales del Turoniano )	Formación Strehlen	Alemania	Género de briozoos queilostomados perteneciente a la familia Calloporidae . Especie tipo H. pavonina ; el género también incluye Membranipora procurrens Brydone, 1929.
Jablonskipora ^[41]	Gen. y sp. nov.	Válido	Martha y Taylor	Cretácico temprano ( Albiano )	Arena verde superior	Reino Unido	Briozoo queilostomado . La especie tipo es J. kidwellae .
Kalvariella antiqua ^[32]	noviembre esp.	Válido	Suárez Andrés & Wyse Jackson	Devónico ( Emsiense – principios del Eifeliano )	Formación Moniello	España	Un miembro de Fenestrata perteneciente a la familia Acanthocladiidae.
Lacrimula crassa ^[33]	noviembre esp.	Válido	Di Martino y otros.	Transición Eoceno – Oligoceno		Tanzania	Un briozoo queilostoma .
Lacrimula kilwaensis ^[33]	noviembre esp.	Válido	Di Martino y otros.	Transición Eoceno – Oligoceno		Tanzania	Un briozoo queilostoma .
Margaretta pentaceratops ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Margarettidae .
Metrarabdotos aquaeguttum ^[42]	noviembre esp.	Válido	Ramalho, Távora y Zagorsek	Mioceno temprano	Formación Pirabas	Brasil	Un miembro de Lepralielloidea perteneciente a la familia Metrarabdotosidae .
Metrarabdotos capanemensis ^[42]	noviembre esp.	Válido	Ramalho, Távora y Zagorsek	Mioceno temprano	Formación Pirabas	Brasil	Un miembro de Lepralielloidea perteneciente a la familia Metrarabdotosidae .
Metrarabdotos elongatum ^[42]	noviembre esp.	Válido	Ramalho, Távora y Zagorsek	Mioceno temprano	Formación Pirabas	Brasil	Un miembro de Lepralielloidea perteneciente a la familia Metrarabdotosidae .
Microeciella kolomnensis ^[36]	noviembre esp.	Válido	Viskova y Pakhnevich	Jurásico medio ( Calloviano )		Rusia	Un briozoo perteneciente al suborden Tubuliporina y a la familia Oncousoeciidae .
Microporella rusti ^[34]	noviembre esp.	Válido	Di Martino y otros.	pleistoceno	Caliza Nukumaru	Nueva Zelanda	Un miembro de la familia Microporellidae .
Nellia winstonae ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Quadricellariidae .
Nevianipora isfahani^[39]	noviembre esp.	Válido	Zágoršek, Yazdi y Bahrami	mioceno	Formación Qom	Irán	Un briozoo ciclóstomo .
'Onychocella' barbata ^[30]	noviembre esp.	Válido	Martha, Niebuhr y Scholz	Cretácico tardío ( Cenomaniano tardío )	Formación Dölzschen	Alemania	Un briozoo queilostoma . Taylor, Martha y Gordon (2018) transfirieron esta especie al género Kamilocella . ^[43]
Onychocella saxoniae ^[30]	noviembre esp.	Válido	Martha, Niebuhr y Scholz	Cretácico tardío ( Cenomaniano tardío )	Formación Dölzschen	Alemania	Un briozoo queilostoma .
Paralicornia interdigitata ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Candidae .
Paraseptopora geométrica ^[32]	noviembre esp.	Válido	Suárez Andrés & Wyse Jackson	Devónico ( Emsiano tardío – Eifeliense temprano )	Formación Moniello	España	Un miembro de Fenestrata perteneciente a la familia Septoporidae.
Paraseptopora irregular ^[32]	noviembre esp.	Válido	Suárez Andrés & Wyse Jackson	Devónico ( Emsiense – principios del Eifeliano )	Formación Moniello	España	Un miembro de Fenestrata perteneciente a la familia Septoporidae.
Faraón^[44]	Gen. y sp. nov.	Válido	Wyse Jackson, Ernst & Suárez Andrés	Carbonífero ( Tournaisiano )	Formación de la cabeza en forma de gancho	Irlanda	Miembro de Cryptostomata perteneciente a la familia Rhabdomesidae. La especie tipo es P. regularis .
Pleuromucrum epifanioi ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Phidoloporidae .
Pleuromucrum liowae ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Phidoloporidae .
Polyascosoecia iránica ^[39]	noviembre esp.	Válido	Zágoršek, Yazdi y Bahrami	mioceno	Formación Qom	Irán	Un briozoo ciclóstomo .
Puellina quadrispinosa ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Cribrilinidae .
Revalotrypa inopinata^[45]	noviembre esp.	Válido	Fedorov, Koromyslova y Martha	Ordovícico ( Floiano )		Rusia	Un briozoo estonioporado perteneciente a la familia Revalotrypidae.
Revalotrypa yugaensis^[45]	noviembre esp.	Válido	Fedorov, Koromyslova y Martha	Ordovícico ( Floiano )		Rusia	Un briozoo estonioporado perteneciente a la familia Revalotrypidae.
Esquizolepraliella ^[29]	Gen. y sp. nov.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma similar a Schizoporella de ubicación filogenética incierta. La especie tipo es S. nancyae .
Selenaria lyrulata ^[46]	noviembre esp.	Válido	López-Gappa, Pérez & Griffin	Mioceno temprano	Formación Monte León	Argentina	Un briozoo perteneciente a la familia Selenariidae .
Spiniflabellum jacksoni ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Cribrilinidae .
Tiara de Steginoporella ^[47]	noviembre esp.	Válido	Gordon, Voje y Taylor	Pleistoceno temprano		Nueva Zelanda	Un miembro de Cheilostomata perteneciente a la familia Steginoporellidae .
Stylopoma farleyensis ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Schizoporellidae .
Estilopoma de Leverhulme ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Schizoporellidae .
Thalamoporella bitorquata ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Thalamoporellidae .
Thalamoporella hastigera ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Thalamoporellidae .
Thalamoporella ogivalis ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Thalamoporellidae .
Thalamoporella papalis ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Thalamoporellidae .
Thalamoporella poligonalis ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Thalamoporellidae .
Trypostega vokesi ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Trypostegidae .
Turbicellepora giardinai ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Celleporidae .
Utropora parva ^[32]	noviembre esp.	Válido	Suárez Andrés & Wyse Jackson	Devónico ( Emsiense – principios del Eifeliano )	Formación Moniello	España	Un miembro de Fenestrata perteneciente a la familia Semicosciniidae.
Vix scolaroi ^[29]	noviembre esp.	Válido	Di Martino, Taylor & Portell	Mioceno temprano	Formación Chipola	Estados Unidos ( Florida )	Un briozoo queilostoma perteneciente a la familia Vicidae .
Wilbertopora manubriformis ^[40]	noviembre esp.	Válido	Taylor y Martha	Cretácico tardío ( Cenomaniano )	Formación de piedra caliza Beer Head	Reino Unido	Un briozoo queilostoma .
Wilbertopora ostiolatoides ^[30]	noviembre esp.	Válido	Martha, Niebuhr y Scholz	Cretácico tardío (mediados-finales del Turoniano )	Formación Strehlen	Alemania	Un briozoo queilostoma .

Braquiópodos

Investigación

Finnegan, Rasmussen y Harper (2017) publicaron un estudio sobre la selectividad de las extinciones de braquiópodos durante los eventos de extinción del Ordovícico-Silúrico . ^[48]
Garbelli, Angiolini y Shen (2017) publicaron un estudio sobre los patrones de biomineralización de las conchas de braquiópodos del Pérmico tardío y sus implicaciones para inferir las perturbaciones ambientales asociadas con el evento de extinción del Pérmico-Triásico . ^[49]

Nuevos taxones

Nombre	Novedad	Estado	Autores	Edad	Unidad	Ubicación	Notas
Acrothyra bonnia^[50]	noviembre esp.	Válido	Skovsted y otros.	Estadio cámbrico 4	Formación Forteau	Canadá ( Terranova y Labrador )	Un miembro de Acrotretida perteneciente a la familia Acrotretidae .
Anarhynchia smithi ^[51]	noviembre esp.	Válido	Pálfy y otros.	Jurásico temprano ( Pliensbachiano )	Formación Inklin	Canadá ( Columbia Británica )
Atelelasma longisulcum ^[52]	noviembre esp.	Válido	Liljeroth y otros.	Ordovícico	Formación de piedra caliza Dunabrattin Formación de piedra caliza Tramore	Irlanda	Un miembro de Strophomenata perteneciente al orden Billingsellida y a la familia Clitambonitidae.
Aticorinquia ^[53]	Gen. y sp. nov.	Válido	Baeza-Carratalá, Reolid & García Joral	Jurásico temprano (finales del Pliensbachiano – principios del Toarciense )	Formación Zegrí	España	Miembro de Rhynchonellida perteneciente a la familia Norellidae. La especie tipo es A. falsiorigo .
Avdeevella ^[54]	Gen. y sp. nov.	Válido	Baránov	Ordovícico		Rusia	La especie tipo es A. mica .
Bilobia alichovae ^[55]	noviembre esp.	Válido	Madison	Ordovícico ( Sandia )		Rusia ( Óblast de Leningrado )	Un miembro de Strophomenida .
Bitnerithyris ^[56]	Gen. nov	Válido	Popov y Zakharov	Triásico temprano ( Olenekiense )		Rusia ( Krai de Primorie )	Un miembro de Terebratulida .
Bronnothyris danaperensis ^[57]	noviembre esp.	Válido	Bitner y Müller	Eoceno ( Priaboniano )		Ucrania	Un miembro de Terebratulida perteneciente a la familia Megathyrididae .
Burrirhynchia albiensis ^[58]	noviembre esp.	Válido	Gaspar	Cretácico temprano ( Albiano )		Francia	Un miembro de Rhynchonellida perteneciente a la familia Tetrarhynchiidae.
Colaptomena auduni ^[52]	noviembre esp.	Válido	Liljeroth y otros.	Ordovícico	Formación de piedra caliza Tramore	Irlanda	Un miembro de Strophomenida perteneciente a la familia Rafinesquinidae.
Cyrtinaella?holi ^[59]	noviembre esp.	Válido	Lü y Ma	Devónico ( Frasniano tardío )		Porcelana	Un miembro de Spiriferinida.
Cyrtospirifer ainosawensis^[60]	noviembre esp.	Válido	Tazawa, Inose y Kaneko	Devónico tardío	Formación Ainosawa	Japón	Un miembro de Spiriferida perteneciente a la familia Cyrtospiriferidae .
Cyrtospirifer choanjiensis^[61]	noviembre esp.	Válido	Tazawa	Devónico tardío		Japón	Un miembro de Spiriferida perteneciente a la familia Cyrtospiriferidae .
Dactylogonia costellata ^[52]	noviembre esp.	Válido	Liljeroth y otros.	Ordovícico	Formación de piedra caliza Dunabrattin Formación de piedra caliza Tramore	Irlanda	Un miembro de Strophomenida perteneciente a la familia Strophomenidae.
Dirafinesquina antigua ^[62]	noviembre esp.	Válido	Popov y gallos	Ordovícico ( Dapingiano )		Irán	Un braquiópodo estrofomenoide .
Discinisca suborbicular^[63]	noviembre esp.	Válido	Smirnova y otros.	Jurásico tardío		Rusia
Discinisca sin datos ^[64]	noviembre esp.	Válido	Smirnova en Smirnova et al.	Jurásico tardío		Rusia	Un braquiópodo perteneciente a la familia Discinidae , una especie de Discinisca .
Elcanatiris ^[65]	Gen. y sp. nov.	Válido	Cobre y Jin	Silúrico ( Aeroniano )		Canadá ( Quebec )	Braquiópodo atírido. La especie tipo es E. pallula .
Eoporambonitas raziabadensis ^[62]	noviembre esp.	Válido	Popov y gallos	Ordovícico ( Dapingiano )		Irán	Un braquiópodo porambonitoideo .
Foveola ivari ^[66]	noviembre esp.	Válido ^[67]	Holmer y otros.	Ordovícico ( Sandia )		Estonia	Un miembro de Obolidae .
Gypidula xui ^[59]	noviembre esp.	Válido	Lü y Ma	Devónico ( Frasniano tardío )		Porcelana	Un miembro de Pentamerida .
Hesperorthis leinsterensis ^[52]	noviembre esp.	Válido	Liljeroth y otros.	Ordovícico	Formación de piedra caliza Dunabrattin Formación de piedra caliza Tramore	Irlanda	Un miembro de Orthida perteneciente a la familia Hesperorthidae.
Hexigtenichonetes ^[68]	Gen. y comb. nov.	Válido	Shen en Shen et al.	Pérmico ( Guadalupiano )	Formación Miaoling	Porcelana	Miembro de Productida perteneciente a la familia Rugosochonetidae . La especie tipo es "Hemichonetes" hemipleura Li & Su en Li et al. (1980); el género también incluye "Hemichonetes guangxingensis Li & Su en Li et al. (1980), "Hemichonetes subquadrata Li & Su en Li et al. (1980) y "Hemichonetes yanjiensis Li & Su en Li et al. (1980).
Hibernobonitas ^[52]	Gen. y comb. nov.	Válido	Liljeroth y otros.	Ordovícico	Formación de piedra caliza Dunabrattin Formación de piedra caliza Tramore Formación de piedra caliza Tourmakeady?	Irlanda	Miembro de Pentamerida perteneciente a la familia Porambonitidae. La especie tipo es " Atrypa " filosa M'Coy (1846); el género también podría incluir "Porambonites" dubius Williams & Curry (1985).
Howellites hibernicus ^[52]	noviembre esp.	Válido	Liljeroth y otros.	Ordovícico	Formación de piedra caliza Dunabrattin Formación de piedra caliza Tramore	Irlanda	Un miembro de Orthida perteneciente a la familia Dalmanellidae.
Isophragma paralelo ^[52]	noviembre esp.	Válido	Liljeroth y otros.	Ordovícico	Formación de piedra caliza Dunabrattin Formación de piedra caliza Tramore	Irlanda	Un miembro de Strophomenida perteneciente a la familia Plectambonitidae.
Joania ucraniana^[57]	noviembre esp.	Válido	Bitner y Müller	Eoceno ( Priaboniano )		Ucrania	Un miembro de Terebratulida perteneciente a la familia Megathyrididae .
Karadagithyris bollierae ^[69]	noviembre esp.	Válido	Halamski y Cherif	Jurásico tardío ( Oxfordiano )	Formación Argiles de Saïda	Argelia	Un miembro de Terebratulida perteneciente a la familia Muirwoodellidae.
Carlosso ^[70]	Gen. y comb. nov.	Válido	Jin y Holmer	Silúrico ( Wenlock )		Suecia	Un nuevo género para " Pentamerus " gothlandicus Lebedev (1892).
Koninckodonta sumuntanensis ^[53]	noviembre esp.	Válido	Baeza-Carratalá, Reolid & García Joral	Jurásico temprano (finales del Pliensbachiano – principios del Toarciense )	Formación Zegrí	España	Un miembro de Athyridida perteneciente a la familia Koninckinidae.
Kurtothyris ^[68]	Nombre. noviembre	Válido	Shen en Shen et al.	Pérmico ( Cisuraliano tardío )	Formación Chihsia	Porcelana	Miembro de Spiriferida perteneciente a la familia Skelidorygmidae; nombre que sustituye a Litothyris Chang (1987). La especie tipo es "Litothyris" anhuiensis Chang (1987).
Kyrshabaktella diabola ^[50]	noviembre esp.	Válido	Skovsted y otros.	Estadio cámbrico 4	Formación Forteau	Canadá ( Terranova y Labrador )	Miembro de Linguloidea perteneciente a la familia Kyrshabaktellidae.
Lagunas de Ivantsovi ^[66]	noviembre esp.	Válido ^[67]	Holmer y otros.	Ordovícico (principios del Darriwiliense )		Rusia	Un braquiópodo paterínido.
Lamellaerhynchia carronensis ^[58]	noviembre esp.	Válido	Gaspar	Cretácico temprano ( Albiano )		Francia	Un miembro de Rhynchonellida perteneciente a la familia Cyclothyrididae.
Leptagonia franca ^[71]	noviembre esp.	Válido	Mottequin y Simón	Carbonífero ( Tournaisiano )	Formación Tournai	Bélgica	Un miembro de Strophomenoidea perteneciente a la familia Rafinesquinidae.
Levipugnax?liui ^[59]	noviembre esp.	Válido	Lü y Ma	Devónico ( Frasniano tardío )		Porcelana	Un miembro de Rhynchonellida .
Liaotarimella ^[68]	Nombre. noviembre	Válido	Shen en Shen et al.	Pérmico ( Artinskiano )	Formación Wutankule	Porcelana	Miembro de Productida perteneciente a la familia Productellidae. Nombre que reemplaza a Tarimella Chen (2004). La especie tipo es "Tarimella" tarimensis Chen (2004).
Lichuanorelloides ^[72]	Gen. y sp. nov.	Válido	Wang y otros.	Triásico temprano		Porcelana	El género incluye la nueva especie L. lichuanensis .
Meristella aksuensis^[73]	noviembre esp.	Válido	Modzalevskaya y otros.	Devónico ( Lochkoviano )		Tayikistán
Nisusia guizhouensis^[74]	noviembre esp.	Válido	Mao y otros.	cambriano	Formación Kaili Formación Qingxudong	Porcelana	Un braquiópodo perteneciente al subfilo Rhynchonelliformea , orden Kutorginida y familia Nisusiidae.
Nucleospira hannoniae ^[71]	Nombre. noviembre	Válido	Mottequin y Simón	Carbonífero ( Tournaisiano )	Formación Tournai	Bélgica	Un miembro de Athyridida perteneciente a la familia Nucleospiridae; un nombre de reemplazo para Athyris globulina de Koninck (1887).
Onniella variabilis ^[75]	noviembre esp.	Válido	Harper, Parkes y Zhan	Ordovícico ( Katian )	Formación Raheen	Irlanda	Un braquiópodo dalmanelloide perteneciente a la familia Dalmanellidae.
Ouraniorrinco ^[73]	Gen. y sp. nov.	Válido	Modzalevskaya y otros.	Devónico ( Lochkoviano )		Tayikistán	Un braquiópodo . El género incluye la nueva especie O. dronovi .
Permocriptospirifera ^[68]	Gen. y comb. nov.	Válido	Shen y Grunt en Shen et al.	Pérmico ( Cisuraliano tardío y Guadalupiano )	Formación Chihsia Formación Maokou Formación Shazipo	Porcelana	Miembro de Athyridida perteneciente a la familia Athyrididae. La especie tipo es "Cryptospirifer" omeishanensis Huang (1933); el género también incluye "Cryptospirifer" minor Yang (1984) y "Cryptospirifer" shawanensis Jin et al. (1974).
Piarorhynchella tazawai ^[56]	noviembre esp.	Válido	Popov y Zakharov	Triásico temprano ( Olenekiense )		Rusia ( Krai de Primorie )	Un miembro de Rhynchonellida .
Platystrophia tramorensis^[52]	noviembre esp.	Válido	Liljeroth y otros.	Ordovícico	Formación de piedra caliza Tramore	Irlanda	Un miembro de Orthida perteneciente a la familia Platystrophiidae.
Pustulobolo ^[50]	Gen. y sp. nov.	Válido	Skovsted y otros.	Etapa cámbrica 3-4	Formación Forteau	Canadá ( Terranova y Labrador )	Miembro de Linguloidea perteneciente a la familia Eoobolidae. La especie tipo es P. triangulus .
Qidongia ^[59]	Gen. y sp. nov.	Válido	Lü y Ma	Devónico ( Frasniano tardío )		Porcelana	Miembro de Terebratulida . La especie tipo es Q. tani .
Rhipidomella discreta^[76]	noviembre esp.	Válido	Cisterna y col.	Carbonífero ( Serpujoviense tardío – Bashkiriense )	Formación El Paso	Argentina	Un braquiópodo perteneciente al grupo Orthida y a la familia Rhipidomellidae.
Rioultina zalasensis ^[77]	noviembre esp.	Válido	Radwanska	Jurásico tardío ( Oxfordiano )		Polonia	Un miembro de Thecideida perteneciente a la familia Thecidellinidae .
Sericoidea hibernica ^[75]	noviembre esp.	Válido	Harper, Parkes y Zhan	Ordovícico ( Katian )	Formación Raheen	Irlanda	Un braquiópodo plecambonitoideo perteneciente a la familia Sowerbyellidae.
Serratocrista scaldisensis ^[71]	noviembre esp.	Válido	Mottequin y Simón	Carbonífero ( Tournaisiano )	Formación Tournai	Bélgica	Un miembro de Orthotetida perteneciente a la familia Schuchertellidae.
Simehortis ^[78]	Gen. y sp. nov.	Válido	Kebria-Ee Zadeh, Popov y Ghobadi Pour	Ordovícico ( Darriwiliano )	Formación Lashkarak	Irán	Miembro de Orthida perteneciente a la familia Hesperorthidae. El género incluye la nueva especie S. fascicostellata .
Somalithyris lakhaparensis ^[79]	noviembre esp.	Válido	Mukherjee y Shome	Jurásico tardío ( Titoniano )		India
Starnikoviela ^[54]	Gen. y sp. nov.	Válido	Baránov	Ordovícico		Rusia	La especie tipo es S. settedabanica .
Tectogonotoechia rivasi ^[80]	noviembre esp.	Válido	García-Alcalde & Herrera	Devónico ( Pragiano )	Formación Nogueras	España	Un miembro de Rhynchonellida perteneciente a la superfamilia Ancistrorhynchoidea y a la familia Iberirhynchiidae.
Thomasaria?baii ^[59]	noviembre esp.	Válido	Lü y Ma	Devónico ( Frasniano tardío )		Porcelana	Un miembro de Spiriferida .
Thomasaria?liangi ^[59]	noviembre esp.	Válido	Lü y Ma	Devónico ( Frasniano tardío )		Porcelana	Un miembro de Spiriferida .
Tunethyris blodgetti ^[81]	noviembre esp.	Válido	Feldman	Triásico medio	Formación Saharonim	Israel	Un miembro de Terebratulida perteneciente a la familia Dielasmatidae.
Westonia mardini ^[82]	noviembre esp.	Válido	Mergl y otros.	Cámbrico ( Furongiano )	Formación Sosink	Pavo
Xiangia ^[59]	Gen. y sp. nov.	Homónimo junior	Lü y Ma	Devónico ( Frasniano tardío )		Porcelana	Miembro de Spiriferida . La especie tipo es X. liaoi . El nombre genérico es obra de Xiangia Peng (1987).
Zhanorthis ^[62]	Gen. y sp. nov.	Válido	Popov y gallos	Ordovícico ( Dapingiano )		Irán	Braquiópodo ortoideo . El género incluye la nueva especie Z. gerdkuhensis .
Ziyunospirifera ^[83]	Nombre. noviembre	Válido	Shen en Shen et al.	Carbonífero temprano	Formación Zhaojiashan	Porcelana	Miembro de Spiriferida perteneciente a la familia Choristitidae; nombre de reemplazo de Quizhouspirifer Xian (1982). La especie tipo es "Quizhouspirifer" ziyunensis Xian (1982).

Moluscos

Equinodermos

Investigación

Sheffield y Sumrall (2017) publican una revisión sistemática de los miembros norteamericanos de la familia diploporita Holocystitidae. ^[84]
Thuy, Hagdorn y Gale (2017) informan sobre miembros triásicos de los grupos paleozoicos de erizos de mar (familia Proterocidaridae), estrellas frágiles (familia Eospondylidae) y estrellas de mar . ^[85]^[86]^[87^{] [88]}^[89]^[90]^[91]
Análisis filogenético y revisión sistemática de crinoideos no camerados del Paleozoico temprano a medio publicados por Wright (2017). ^[92]
Revisión sistemática de los crinoideos camerados del Ordovícico publicada por Cole (2017). ^[93]
Revisión importante de la clasificación de Crinoidea fósiles y actuales por Wright et al. (2017), incluida la presentación de nuevas clasificaciones basadas en la filogenia y en rangos. ^[94]
Wright (2017) publicó un estudio sobre patrones a gran escala de evolución morfológica en la radiación paleozoica de crinoideos eucladidos. ^[95]
Clark et al. (2017) publican un estudio sobre la morfología interna del sistema vascular acuático en un espécimen de la especie de tallo - ofiuroide Protasterina flexuosa de la Formación Kope del Ordovícico ( Katian ) ( Kentucky , Estados Unidos ). ^[96]
Kato, Oji y Shirai (2017) publican un estudio sobre la paleoecología de las especies de equinodermos conocidas del Pierre Shale del Campaniano superior (incluido el crinoideo Lakotacrinus brezinai ), especialmente sobre sus adaptaciones al entorno de filtración fría . ^[97]^[98]^[99]

Nuevos taxones

Nombre	Novedad	Estado	Autores	Edad	Unidad	Ubicación	Notas
Amblypygus matruhensis ^[100]	noviembre esp.	Válido	Alí	Mioceno medio		Egipto	Un erizo de mar .
Amboacrino ^[101]	Gen. y sp. nov.	Válido	Cole y otros.	Ordovícico ( Katian )	Formación Fombuena	España	Un crinoideo camerato diplobatrido . El género incluye la nueva especie A. decorus .
Andymetra toarcensis ^[102]	noviembre esp.	Válido	Hess y Thuy	Jurásico temprano		Francia	Un crinoideo comatúlido .
Antroosasterias ^[103]	Gen. y sp. nov.	Válido	Blake	Carbonífero	Formación de la ciudad de Gilmore	Estados Unidos ( Iowa )	Estrella de mar perteneciente a la familia Urasterellidae. El género incluye la nueva especie A. mikrotero .
Antillaster farisi ^[104]	noviembre esp.	Válido	Alí	Eoceno medio		Egipto	Un erizo de mar .
Aspidophiura?seren ^[105]	noviembre esp.	Válido	Ewin y Thuy	jurásico	Formación de arcilla Oxford	Reino Unido	Una estrella frágil .
Ateleocistitis?lansae ^[106]	noviembre esp.	Válido	McDermott y Paul	Ordovícico ( Katian )	Camas Slade y Redhill	Reino Unido	Un mitrato perteneciente a la familia Anomalocystitidae, posiblemente una especie de Ateleocystites .
Brissus mihalyi ^[107]	Noviembre esp.	Válido	Polonkai y otros.	Mioceno medio	Formación de piedra caliza de Leitha	Hungría	Un erizo de corazón perteneciente a la familia Brissidae .
Crepidosoma doylei ^[108]	noviembre esp.	Válido	Blake, Donovan y Harper	Silúrico ( Telychian )	Formación Kilbride	Irlanda	Una estrella frágil perteneciente al grupo Oegophiurida y a la familia Encrinasteridae .
Dalicrino ^[101]	Gen. y sp. nov.	Válido	Cole y otros.	Ordovícico ( Katian )	Formación Fombuena	España	Crinoideo camerado diplobatrídeo . El género incluye la nueva especie D. hammanni .
Diplodetus brisenoi ^[109]	noviembre esp.	Válido	Silva-Martínez et al.	Cretácico tardío ( Campaniano temprano )	Formación Austin	México	Un erizo de corazón perteneciente a la familia Brissidae .
Echinocyamus belali^[104]	noviembre esp.	Válido	Alí	Eoceno medio		Egipto	Un erizo de mar .
Enakomusium whymanae ^[105]	noviembre esp.	Válido	Ewin y Thuy	jurásico	Formación de arcilla Oxford	Reino Unido	Una estrella frágil .
Eopatelliocrinus hispaniensis ^[101]	noviembre esp.	Válido	Cole y otros.	Ordovícico ( Katian )	Formación Fombuena	España	Un crinoideo camerado monobatrido .
Eotiaris guadalupensis ^[110]	noviembre esp.	Válido	Thompson en Thompson, Petsios y Bottjer	Pérmico ( Capitaniano )	Formación del cañón Bell	Estados Unidos ( Texas )	Un erizo de mar . El nombre apareció por primera vez en la publicación de Thompson et al. (2015); ^[111] sin embargo, se publicó en una revista solo en línea Scientific Reports y no se registró en ZooBank , lo que lo hizo inválido hasta que fue validado por Thompson, Petsios y Bottjer (2017). ^[110]
Cistáceas de Felbabka ^[112]	Gen. y sp. nov.	Válido	Nardin y otros.	Cámbrico ( Drumiano )	Formación Jince	República Checa	Forma de transición entre los blastozoos con cáliz y los blastozoos con teca . El género incluye la nueva especie F. luckae .
Fombuenacrino ^[101]	Gen. y sp. nov.	Válido	Cole y otros.	Ordovícico ( Katian )	Formación Fombuena	España	Crinoideo camerado diplobathrid . El género incluye la nueva especie F. nodulus .
Forcipicrino ^[102]	Gen. y sp. nov.	Válido	Hess y Thuy	Jurásico temprano		Francia	Crinoideo isocrínido . El género incluye la nueva especie F. normannicus .
Globator roselli ^[113]	noviembre esp.	Válido	Carrasco	Eoceno		España	Un erizo de mar relacionado con los miembros del género Conulus .
Goniopygus emmae ^[114]	noviembre esp.	Válido	Forner i Valls	Cretácico tardío ( Campaniano )		Marruecos	Un erizo de mar perteneciente al grupo Arbacioida y a la familia Acropeltidae.
Grigopirgus ^[115]	Gen. y comb. nov.	Válido	Müller & Hahn	Devónico temprano		Alemania	Miembro de Edrioasteroidea perteneciente a la familia Agelacrinitidae ; un nuevo género para "Agelacrinites" curvatus Grigo (1995).
Goyacrino ^[101]	Gen. y sp. nov.	Válido	Cole y otros.	Ordovícico ( Katian )	Formación Fombuena	España	Crinoideo camerado diplobatrido . El género incluye la nueva especie G. gutierrezi .
Heropirgo ^[116]	Gen. y sp. nov.	Válido	Briggs y otros.	siluriano	Establos de Herefordshire	Reino Unido	Un edrioasteroide renopirgido . La especie tipo es H. disterminus .
Holocystites salmoensis ^[117]	noviembre esp.	Válido	Sheffield, Ausich y Sumrall	Ordovícico ( Hirnantiense )	Formación de la bahía Ellis	Canadá ( Quebec )	Un miembro de Diploporita perteneciente al grupo Sphaeronitida y a la familia Holocystitidae.
Metalia lindaae^[104]	noviembre esp.	Válido	Alí	Eoceno medio		Egipto	Un erizo de mar .
Monostychia alanrixi ^[118]	noviembre esp.	Válido	Sadler, Martin y Gallagher	mioceno	Arenisca de Colville	Australia	Un erizo de mar .
Monostychia macnamarai ^[118]	noviembre esp.	Válido	Sadler, Martin y Gallagher	mioceno	Arenisca de Colville	Australia	Un erizo de mar .
Monostychia robertirwini ^[118]	noviembre esp.	Válido	Sadler, Martin y Gallagher	mioceno	Arenisca de Colville	Australia	Un erizo de mar .
Disco de Marruecos ^[119]	Gen. y sp. nov.	Válido	Reich y otros.	Ordovícico ( Darriwiliano )	Formación Taddrist	Marruecos	Un equinodermo ciclocistoideo. El género incluye la nueva especie M. smithi .
Oehlerticrinus peachi ^[120]	noviembre esp.	Válido	Donovan y Fearnhead	Devónico temprano	Cuenca de Looe	Reino Unido	Un crinoideo perteneciente al grupo Monobathrida y a la familia Hexacrinitidae.
Ophiotitanos smithi ^[105]	noviembre esp.	Válido	Ewin y Thuy	jurásico	Formación de arcilla Oxford	Reino Unido	Una estrella frágil .
Huevos rancios ^[121]	noviembre esp.	Válido	Zachos	Paleoceno ( Thanetiense )	Formación Vincentown	Estados Unidos ( Nueva Jersey )	Un erizo de mar .
Paerticrino ^[122]	Gen. y sp. nov.	Válido	Wright y Toom	Silúrico ( Rhuddaniano )		Estonia	Un crinoideo . El género incluye la nueva especie P. arvosus .
Estructura del paleocomaster ^[102]	noviembre esp.	Válido	Hess y Thuy	Jurásico temprano		Francia	Un crinoideo comatúlido .
Persiacarpos ^[123]	Gen. y sp. nov.	Válido	Rozhnov y Perejil	cambriano	Formación Mila	Irán	Miembro de Cornuta . El género incluye la nueva especie P. jefferiesi .
Petalobrissus ossoi ^[114]	noviembre esp.	Válido	Forner i Valls	Cretácico tardío ( Campaniano )		Marruecos	Un erizo de mar perteneciente al grupo Cassiduloida y a la familia Faujasidae.
Petalocrinus stenopetalus ^[124]	noviembre esp.	Válido	Mao y otros.	Silúrico (Aeroniano)		Porcelana	Un crinoideo perteneciente a la familia Petalocrinidae .
Picassocrino ^[101]	Gen. y sp. nov.	Válido	Cole y otros.	Ordovícico ( Katian )	Formación Fombuena	España	Crinoideo cladido . El género incluye la nueva especie P. villasi .
Ronsocrino ^[125]	Gen. y sp. nov.	Válido	Cordie y Witzke	Devónico ( Givetiano )		Estados Unidos ( Iowa )	Crinoideo camerado perteneciente a la familia Melocrinitidae. El género incluye la nueva especie R. rabia .
Salenia palmyra ^[121]	noviembre esp.	Válido	Zachos	Paleoceno ( Daniano )	Formación Clayton	Estados Unidos ( Alabama Georgia (estado de EE. UU.) )	Un erizo de mar .
Sanducystis ^[126]	Gen. y sp. nov.	Válido	Zamora y col.	Cámbrico ( Furongiano )	Formación Sandu	Porcelana	Un equinodermo con tallo. La especie tipo es S. sinensis .
Singillatimetra truncata ^[102]	noviembre esp.	Válido	Hess y Thuy	Jurásico temprano		Francia	Un crinoideo isocrínido .
Solanocrinites sagti ^[102]	noviembre esp.	Válido	Hess y Thuy	Jurásico temprano		Francia	Un crinoideo comatúlido .
Spinimetros ^[102]	Gen. y sp. nov.	Válido	Hess y Thuy	Jurásico temprano		Francia	Un crinoideo comatúlido . El género incluye la nueva especie S. chesnieri .
Spirocrinus circularis ^[124]	noviembre esp.	Válido	Mao y otros.	Silúrico (Aeroniano)		Porcelana	Un crinoideo perteneciente a la familia Petalocrinidae .
Spirocrinus dextrosus ^[124]	noviembre esp.	Válido	Mao y otros.	Silúrico (Aeroniano)		Porcelana	Un crinoideo perteneciente a la familia Petalocrinidae .
Staurasterias ^[103]	Gen. y sp. nov.	Válido	Blake	Carbonífero	Formación Keokuk	Estados Unidos ( Indiana )	Estrella de mar perteneciente a la familia Urasterellidae. El género incluye la nueva especie S. elegans .
Resumen ^[127]	Gen. y sp. nov.	Válido	Müller & Hahn	Devónico temprano	Formación Seifen	Alemania	Miembro de Edrioasteroidea . El género incluye la nueva especie S. rseiberti .
Supersteaster ^[128]	Gen. y sp. nov.	Válido	Villier y otros.	Triásico temprano		Estados Unidos ( Utah )	Una estrella de mar . El género incluye la nueva especie S. promissor .
Teleósastro ^[129]	Gen. y sp. nov.	Válido	Cazador y McNamara	Pérmico ( Kunguriense )	Formación Cundlego	Australia	Estrella frágil . El género incluye la nueva especie T. creasyi .
Tintinnabulicrino ^[122]	Gen. y sp. nov.	Válido	Wright y Toom	Ordovícico ( Katian )		Estonia	Un crinoideo . El género incluye la nueva especie T. estoniensis .
Ulphaceaster ^[130]	Gen. y sp. nov.	Válido	Néraudeau y otros.	Cretácico tardío ( Cenomaniano )		Francia	Erizo de mar perteneciente a la familia Archiaciidae. El género incluye la nueva especie U. sarthacensis .
Piedras rodantes de Vologesia ^[131]	noviembre esp.	Válido	Schlüter & Wiese	Cretácico tardío ( Campaniano temprano )		España	Un erizo de mar perteneciente a la familia Echinolampadidae .

Conodontos

Investigación

Jarochowska et al. (2017) publican un estudio sobre el conjunto de conodontes de la Formación Rootsiküla del Silúrico ( Homérico ) ( Estonia ), que se interpreta que se encuentra en los estratos que contienen evaporita , y sobre la diversidad de conodontes en varios entornos. ^[132]
Zhang et al. (2017) describen restos esqueléticos articulados de Hindeodus parvus , que proporcionan evidencia directa de la cantidad y disposición de elementos en el aparato, del Triásico Inferior de China . ^[133]^[134]^[135]

Nuevos taxones

Nombre	Novedad	Estado	Autores	Edad	Unidad	Ubicación	Notas
Ácaro zeballus^[136]	noviembre esp.	Válido	Voldman y Albanesi en Voldman et al.	Ordovícico temprano		Argentina
Aldridgeognathus ^[137]	Gen. y sp. nov.	Válido	Miller y otros.	Ordovícico ( Darriwiliano )	Formación Amdeh	Omán	Miembro de Balognathidae . El género incluye la nueva especie A. manniki .
Bispathodus ultimus corradinii ^[138]	Subsp. nov	Válido	Söte, Hartenfels & Becker	Devónico ( Fameniano )		Alemania
Coelocerodontus hunanensis ^[139]	noviembre esp.	Válido	Dong y Zhang	Cámbrico ( Furongiano )	Formación Panjiazui	Porcelana	Un euconodonte .
Ctenopolygnathus parallelus ^[140]	noviembre esp.	Válido	Ovnatanova y otros.	Devónico tardío	Formación Kedzyrschor	Rusia
Fahraeusodus jachalensis ^[141]	noviembre esp.	Válido	Feltes y Albanesi en Serra et al.	Ordovícico ( Darriwiliano )	Formación Gualcamayo Formación Las Aguaditas Formación Las Chacritas Formación San Juan	Argentina
Furnishina wangcunensis^[139]	noviembre esp.	Válido	Dong y Zhang	Cámbrico ( Furongiano )	Formación Bitiao	Porcelana	Un miembro de Paraconodontida .
Gothodus vetus ^[136]	noviembre esp.	Válido	Voldman y Albanesi en Voldman et al.	Ordovícico temprano		Argentina
Guexispathodus ^[142]	Gen. y comb. nov.	Válido	Plasencia et al.	Triásico medio	Formación Mukheiris Formación Saharonim	Israel Jordania	Miembro de la familia Gondolellidae . La especie tipo es " Neospathodus " shagami Benjamini & Chepstow-Lusty (1986); El género también incluye "Pseudofurnishius" siyalaensis Sadeddin & Kozur (1992).
Gullodus tieqiaoensis ^[143]	noviembre esp.	Válido	Sol y otros.	Pérmico		Porcelana
Icriodus ballbergensis^[144]	noviembre esp.	Válido	Lüddecke, Hartenfels y Becker	Devónico ( Fameniano )		Alemania
Icriodus marieae^[145]	noviembre esp.	Válido	Suttner, Kido y Suttner	Devónico medio	Formación Valentin	Austria Francia Alemania
Idiognathodus boardmani^[146]	noviembre esp.	Válido	Hogancamp y Barrick	Carbonífero ( Gzheliano )	Esquisto de Heebner	Estados Unidos
Idiognathodus itaitubensis^[147]	noviembre esp.	Válido	Cardoso, Sanz-López & Blanco-Ferrera	Carbonífero ( Pensilvaniano )	Grupo Tapajós	Brasil
Idiognathoides luokunensis^[148]	noviembre esp.	Válido	Hu y Qi en Hu et al.	Carbonífero ( Bashkirio )		Porcelana
Iowagnathus ^[149]	Gen. y sp. nov.	Válido	Liu y otros.	Ordovícico ( etapa de Whiterock )	Winneshiek Konservat-Lagerstätte	Estados Unidos ( Iowa )	El género incluye la nueva especie I. grandis .
Kirilella ^[142]	Gen. y comb. nov.	Válido	Plasencia et al.	Triásico medio		Austria Canadá China Egipto Hungría Israel Italia Japón Jordania Rusia España Estados Unidos	Miembro de la familia Gondolellidae . La especie tipo es " Polygnathus " mungoensis Diebel (1956); El género también incluye "Tardogondolella" diebeli Kozur & Mostler (1971), " Epigondolella " mostleri Kozur en Kozur & Mock (1972) y " Metapolygnathus " longobardicus Kovács (1983).
Laiwugnathus hunanensis ^[139]	noviembre esp.	Válido	Dong y Zhang	Cámbrico ( Drumiano )	Formación Huaqiao	Porcelana	Un miembro de Paraconodontida .
Laiwugnathus transitans ^[139]	noviembre esp.	Válido	Dong y Zhang	Cámbrico ( guzhangiano y paibiano )	Formación Chefu	Porcelana	Un miembro de Paraconodontida .
Lenathodus ^[150]	Gen. y sp. nov.	Válido	Izokh en Izokh y Yazikov	Carbonífero temprano		Rusia	El género incluye la nueva especie L. bakharevi .
Lugnato ^[139]	Gen. y sp. nov.	Válido	Dong y Zhang	Estadio Cámbrico 10 y Ordovícico temprano ( Tremadociano )	Formación Panjiazui	Porcelana	Miembro de Paraconodontida . El género incluye la nueva especie L. hunanensis .
Marquezella ^[142]	Gen. y comb. nov.	Válido	Plasencia et al.	Triásico medio		Austria Bulgaria China Francia Grecia Hungría India Italia Japón Rusia Eslovaquia Eslovenia España	Miembro de la familia Gondolellidae . La especie tipo es "Gladigondolella" truempyi Hirsch (1971); el género también incluye " Polygnathus " japonicus Hayashi (1968).
Mayrodio ^[151]	Gen. y sp. nov.	Válido	Zhang, Jowett y Barnes	Silúrico ( Sheinwoodiano )	Formación de Cabo Phillips	Canadá ( Nunavut )	Un conodonto de ubicación filogenética incierta. La especie tipo es M. melchini .
Miaognato ^[139]	Gen. y sp. nov.	Válido	Dong y Zhang	Estadio cámbrico 10	Formación Shenjiawan	Porcelana	Miembro de Paraconodontida . El género incluye la nueva especie M. multicostatus .
Millerodontus ^[139]	Gen. y sp. nov.	Válido	Dong y Zhang	Cámbrico ( Furongiano )	Formación Shenjiawan	Porcelana	Un euconodonte . El género incluye la nueva especie M. intermedius .
Mosherella praebudaensis ^[152]	noviembre esp.	Válido	Chen y Lukeneder	Triásico Tardío ( Carniano )	Formación Kasimlar	Pavo
Neopolygnathus communis yazikovi ^[150]	Subsp. nov	Válido	Izokh en Izokh y Yazikov	Carbonífero temprano		Rusia
Neopolygnathus crucesignatis ^[153]	noviembre esp.	Válido	Plotitsyn y Zhuravlev	Carbonífero ( Tournaisiano )		Rusia
Norigondolella carlae ^[154]	noviembre esp.	En prensa	Rigo y otros.	Triásico Tardío ( Carniano )	Formación de Scillato	Austria Italia Turquía	Un miembro de Ozarkodinida .
Omanognato ^[137]	Gen. y sp. nov.	Válido	Miller y otros.	Ordovícico ( Darriwiliano )	Formación Amdeh	Omán	Miembro de Balognathidae . El género incluye la nueva especie O. daiqaensis .
Palmatolepis chernovi^[155]	noviembre esp.	Válido	Soboleva	Devónico ( Frasniano )		Rusia
Palmatolepis spallettae^[156]	Nombre. noviembre	Válido	Klapper y otros.	Devónico ( Frasniano )		Canadá ( Ontario )	Un nombre de reemplazo para Palmatolepis nodosa Klapper et al. (2004).
Palmatolepis zhuravlevi^[155]	noviembre esp.	Válido	Soboleva	Devónico ( Frasniano )		Rusia
Arco de polignathus^[153]	noviembre esp.	Válido	Plotitsyn y Zhuravlev	Carbonífero ( Tournaisiano )		Rusia
Polygnathus mawsonae^[140]	noviembre esp.	Homónimo junior	Ovnatanova y otros.	Devónico ( Fameniano )	Formación Sortomael	Australia Rusia	Ovnatanova et al. (2019) acuñaron un nombre de reemplazo, Polygnathus sharyuensis . ^[157]
Polygnathus postvogesi^[158]	noviembre esp.	Válido	Plotitsyn y Zhuravlev	Carbonífero ( Tournaisiano )		Rusia
Prosagittodontus compressus ^[139]	noviembre esp.	Válido	Dong y Zhang	Cámbrico ( guzhangiano y paibiano )	Formación Chefu	Porcelana	Un miembro de Paraconodontida .
Pseudohindeodus elliptica ^[143]	noviembre esp.	Válido	Sol y otros.	Pérmico		Porcelana
Quadralella wanlanensis ^[159]	noviembre esp.	Válido	Zhang y otros.	Triásico		Porcelana
Quadralella yongyueensis ^[159]	noviembre esp.	Válido	Zhang y otros.	Triásico		Porcelana
Siphonodella carinata^[160]	noviembre esp.	Válido	Zhuravlev	Carbonífero ( Tournaisiano )	Formación Idzhid	Rusia ( República de Komi )
Siphonodella kalvodai^[161]	noviembre esp.	Válido	Kaiser, Kumpan y Cígler	Carbonífero ( Tournaisiano )	Formación Líšeň	República Checa Tayikistán	Un miembro de Ozarkodinida perteneciente a la familia Elictognathidae .
Sweetognathus asimétrica^[143]	noviembre esp.	Válido	Sol y otros.	Pérmico		Porcelana
Tujiagnathus ^[139]	Gen. y sp. nov.	Válido	Dong y Zhang	Cámbrico ( Furongiano )	Formación Bitiao	Porcelana	Un euconodonte . El género incluye la nueva especie T. gracilis .
Vjalovognathus carinatus^[162]	noviembre esp.	Válido	Wang y otros.	Pérmico ( Changhsingiano )		China India
Wangcunella ^[139]	Gen. y sp. nov.	Válido	Dong y Zhang	Cámbrico ( Furongiano )	Formación Bitiao	Porcelana	Un euconodonte . El género incluye la nueva especie W. conicus .
Wangcunognathus ^[139]	Gen. y sp. nov.	Válido	Dong y Zhang	Cámbrico ( Paibiano )	Formación Bitiao	Porcelana	Miembro de Paraconodontida . El género incluye la nueva especie W. elegans .
Westergaardodina dimorpha^[139]	noviembre esp.	Válido	Dong y Zhang	Cámbrico ( Paibiano )	Formación Bitiao	Porcelana	Un miembro de Paraconodontida .
Westergaardodina gigantea^[139]	noviembre esp.	Válido	Dong y Zhang	Cámbrico ( Guzhangiano )	Formación Chefu	Porcelana	Un miembro de Paraconodontida .
Westergaardodina sola^[139]	noviembre esp.	Válido	Dong y Zhang	Cámbrico ( Guzhangiano )	Formación Chefu	Porcelana	Un miembro de Paraconodontida .
Zentagnato ^[136]	Gen. y comb. nov.	Válido	Voldman y Albanesi en Voldman et al.	Ordovícico temprano		Argentina	Un nuevo género para "Trapezognathus" primitivus Voldman, Albanesi & Zeballo en Voldman et al. (2013); El género también incluye "Trapezognathus" argentinensis Rao et al. (1994)

Peces

Anfibios

Investigación

MacIver et al. (2017) publican un estudio sobre la evolución del tamaño de los ojos en los primeros tetrápodos y en los peces pertenecientes al linaje que dio origen a los tetrápodos, así como sobre el impacto del tamaño de los ojos en el rendimiento ocular al ver objetos a través del agua y del aire . ^[163 ]
Molnar et al. (2017) publican en línea un estudio sobre la evolución de la musculatura de las extremidades anteriores desde los peces de aletas lobuladas hasta los primeros tetrápodos. ^[164]
Tietje y Rödel (2017) publicaron un estudio sobre la influencia de las características del hábitat en la duración de la persistencia de especies de anfibios fósiles y vivas. ^[165]
Danto et al. (2017) publicaron un estudio sobre el desarrollo del intercentro vertebral y el pleurocentro en anfibios fósiles. ^[166]
Witzmann y Werneburg (2017) publicaron un estudio sobre la probable función de las vacuidades interpterigoideas (agujeros en el paladar ) en los temnospóndilos como sitio de inserción muscular. ^[167]
Werneburg (2017) publica un estudio sobre el desarrollo larvario más temprano en temnospóndilos, según lo indican los especímenes de los sedimentos del lago Pérmico ( Sakmariano ) cerca de Obermoschel ( Cuenca Saar-Nahe , Alemania ). ^[168]
Gee, Haridy y Reisz (2017) publican un estudio sobre la histología de las pequeñas placas palatinas y sus dentículos en un temnospóndilo dissorofoideo pérmico de la cantera de piedra caliza Dolese Brothers cerca de Richards Spur ( Oklahoma , Estados Unidos ). ^[169]
Una revisión taxonómica de todos los rinesúquidos descritos y un estudio sobre las relaciones filogenéticas de los miembros de Rhinesuchidae es publicada por Marsicano et al. (2017), quienes transfieren la especie " Rhinesuchus " capensis Haughton (1925) al género Rhinesuchoides . ^[170]
Azevedo, Vega y Soares (2017) describen un nuevo ejemplar del rinesúquido Australerpeton cosgriffi (un cráneo y una mandíbula ) de la Formación Pérmica Rio do Rasto ( Brasil ). ^[171]
Arbez, Dahoumane y Steyer (2017) publican una descripción de la anatomía de la caja craneana y las regiones del oído medio de un cráneo excepcionalmente bien conservado de Stanocephalosaurus amenasensis del Triásico de Argelia . ^[172]
Fortuny, Marcé-Nogué & Konietzko-Meier (2017) publican un estudio sobre la anatomía de los cráneos de las especies de metoposáuridos Metoposaurus krasiejowensis y Apachesaurus gregorii , así como sus implicaciones para establecer si los metoposáuridos eran depredadores activos o emboscados. ^[173]
Gee, Parker y Marsh (2017) publican un análisis de la microanatomía e histología de las vértebras de metoposáuridos del Parque Nacional del Bosque Petrificado , e interpretan que Apachesaurus gregorii probablemente sea una etapa ontogenética temprana de un metoposáurido grande, como Koskinonodon perfectus , en lugar de una especie distinta. ^[174]
Gee y Parker (2017) describen un ejemplar juvenil de Koskinonodon perfectus del Miembro del Bosque Petrificado de Norian de la Formación Chinle del Triásico Tardío ( Arizona , Estados Unidos ). ^[175]
Witzmann y Brainerd (2017) publicaron un estudio sobre la fisiología (especialmente tasa metabólica, temperatura corporal, respiración, alimentación, digestión, osmorregulación y excreción ) de Archegosaurus decheni . ^[176]
Skutschas y Boitsova (2017) publicaron un estudio sobre la histología de los huesos del techo del cráneo dérmico en Kokartus honorarius . ^[177]
Tissier, Rage y Laurin (2017) describen tejidos blandos fosilizados conservados con el espécimen tipo de salamandra Phosphotriton sigei . ^[178]
Lappin et al. (2017) publican un estudio sobre la fuerza de mordida en la rana cornuda de Cranwell ( Ceratophrys cranwelli ) actual y sus implicaciones para estimar la fuerza de mordida en la especie del Cretácico tardío Beelzebufo ampinga . ^[179]
Delfino (2017) describe fósiles de ranas, incluidos los primeros fósiles conocidos de ranas nariz de pala , del Plioceno temprano de Kanapoi ( Kenia ). ^[180]
Pardo et al. (2017) publican un estudio sobre la morfología del cráneo de Lethiscus stocki y sobre las relaciones filogenéticas de los primeros tetrápodos, recuperando a los lepospóndilos como un grupo polifilético . ^[181]

Nuevos taxones

Temnospondilos

Nombre	Novedad	Estado	Autores	Edad	Unidad	Ubicación	Notas	Imágenes
Aphaneramma gavialimimus^[182]	noviembre esp.	Válido	Fortuny y otros.	Triásico temprano ( Olenekiense )		Madagascar		Afaneramma
Chinlestegophis^[183]	Gen. y sp. nov.	Válido	Pardo, Pequeño y Huttenlocker	Triásico Tardío	Formación Chinle	Estados Unidos ( Colorado )	Miembro de Stereospondyli, posiblemente una cecilia primitiva . La especie tipo es C. jenkinsi .
Ciclotosaurus naraserluki^[184]	noviembre esp.	Válido	Marzola y col.	Triásico Tardío	Formación del fiordo Fleming	Tierra Verde		Ciclotosaurio
Tomea ^[185]	Gen. y sp. nov.	Válido	Eltink, Stock Da-Rosa y Dias-da-Silva	Triásico temprano	Formación Sanga do Cabral	Brasil	Un capitosaurio .

Lisanfibios

Nombre	Novedad	Estado	Autores	Edad	Unidad	Ubicación	Notas
Chachaiphrynus ^[186]	Gen. y sp. nov.	Válido	Nicoli	Oligoceno		Argentina	Miembro de Odontophrynidae . La especie tipo es C. lynchi .
Genibatraco ^[187]	Gen. y sp. nov.	Válido	Gao y Chen	Cretácico temprano	Formación Guanghua (parte superior de Longjiang)	Porcelana	Una rana del grupo corona . La especie tipo es G. baoshanensis .
Sanshuibatrachus ^[188]	Gen. y sp. nov.	Válido	Wang, Roček y Dong	Eoceno temprano		Porcelana	Una rana pelobatoidea de ubicación filogenética incierta. El género incluye la nueva especie S. sinensis .

Otros anfibios

Nombre	Novedad	Estado	Autores	Edad	Unidad	Ubicación	Notas	Imágenes
Espaticéfalo marsdeni^[189]	noviembre esp.	Válido	Smithson y otros.	Carbonífero ( Viséano )	Formación Anstruther	Reino Unido	Un miembro de la superfamilia Baphetoidea .
Yumenerpetón^[190]	Gen. y sp. nov.	Válido	Jiang, Ji y Mo	Pérmico medio	Formación Xidagou	Porcelana	Un croniosuquio bystrowiano . La especie tipo es Y. yangi .

Reptiles

Sinápsidos

Sinápsidos no mamíferos

Investigación

Brocklehurst y Fröbisch (2017) sostienen que Phreatophasma aenigmaticum es un miembro de Caseidae . ^[191]
Romano et al. (2017) describen nuevo material fósil del caseido Alierasaurus ronchii de los depósitos pérmicos de la Formación Cala del Vino ( Cerdeña , Italia ). ^[192]
Shelton & Sander (2017) publican un estudio sobre la histología de los húmeros de Ophiacodon^{, que revela la existencia de hueso fibrolamelar en los huesos postcraneales de este taxón. [193]}
Brocklehurst y Brink (2017) publicaron un estudio sobre la evolución del tamaño corporal de los edafosáuridos y los esfenacodóntidos . ^[194]
Rey et al. (2017) publicaron un estudio sobre la evolución de la endotermia en terápsidos no mamíferos, según lo indica la composición de isótopos de oxígeno del fosfato de los huesos y los dientes en terápsidos del Pérmico y el Triásico . ^[195]
Benoit et al. (2017) publican un estudio sobre la morfología cerebral de terápsidos no mamíferoformes basado en endomoldes craneales de Moschops capensis y varios biarmosuquios (incluidos Herpetoskylax hopsoni y miembros de los géneros Hipposaurus y Lemurosaurus^{). [196]}
Benoit et al. (2017) publican un estudio sobre la morfología del laberinto óseo de cinco especímenes de biarmosuquios . ^[197]
Benoit et al. (2017) publican un estudio sobre la anatomía del cráneo de Moschops capensis que revela adaptaciones del sistema nervioso central relacionadas con el combate cuerpo a cuerpo. ^[198]
Olivier et al. (2017) publicaron un estudio sobre la tasa metabólica en reposo en Moghreberia nmachouensis ^{[199] .}
Laaß, Schillinger y Kaestner (2017) publicaron un estudio sobre el contenido de la depresión conocida como "zona no osificada" en la cavidad cerebral de Diictodon feliceps . ^[200]
Angielczyk y Kammerer (2017) publican una reevaluación de la morfología del cráneo y la posición filogenética de Compsodon helmoedi . ^[201]
Botha-Brink (2017) describe un esqueleto de Lystrosaurus curvatus en una madriguera fosilizada, preservado con evidencia tafonómica que indica que este individuo fue el constructor de la madriguera, del Triásico Inferior de la cuenca del Karoo sudafricano . ^[202]
Laaß y Kaestner (2017) informan de una estructura análoga al neocórtex de los mamíferos en Kawingasaurus fossilis . ^[203]
Whitney, Mose y Sidor (2017) informaron sobre un dentario de gorgonopsia afectado por una afección muy similar a un odontoma compuesto en el Pérmico superior de Tanzania . ^[204]
Araújo et al. (2017) publican una descripción detallada de la caja craneana de dos especímenes de gorgonopsianos (un probable espécimen de Aelurosaurus wilmanae de Sudáfrica y un posible espécimen de Arctognathus ? nasuta de Tanzania ). ^[205]
Kammerer (2017) publica una redescripción y revisión del género gorgonopsiano Arctops^{. [206]}
Kammerer (2017) describe un holotipo redescubierto de la especie de gorgonopsiana Clelandina major y considera que esta especie es un sinónimo menor de Clelandina rubidgei . ^[207]
Benoit et al. (2017) publicaron un estudio sobre la anatomía de los dientes y el maxilar de Euchambersia mirabilis y sus implicaciones para la hipótesis de que la glándula venenosa estaba presente en esta especie. ^[208]
Maisch (2017) publica una redescripción y un estudio sobre las relaciones filogenéticas de Silphoictidoides ruhuhuensis y considera que la especie es un miembro basal de Baurioidea . ^[209]
Benoit et al. (2017) publican un estudio sobre la morfología interna de la región interorbital del cráneo de los cinodontos basales , incluidos elementos orbitoesfenoides raramente fosilizados . ^[210]
Crompton et al. (2017) publican un estudio sobre la anatomía de las regiones nasales de los cinodontos no mamíferos Massetognathus , Probainognathus y Elliotherium , comparándolas con las regiones nasales de los mamíferos fósiles y los mamíferos actuales. ^[211]
Jasinoski y Abdala (2017) publican un estudio de las agregaciones de especímenes de Galesaurus planiceps y Thrinaxodon liorhinus , con énfasis en si las agregaciones consisten en individuos de edad similar o representan una mezcla de diferentes clases de edad. ^[212]
Jasinoski y Abdala (2017) publican un estudio sobre los cambios ontogenéticos en el cráneo y la mandíbula de Galesaurus planiceps . ^[213]
Liu, Schneider y Olsen (2017) publican una descripción del esqueleto postcraneal de Boreogomphodon de la Formación Pekin del Triásico ( Carolina del Norte , Estados Unidos ) y una revisión de la variación postcraneal entre los miembros de la familia Traversodontidae . ^[214]
Kubo, Yamada y Kubo (2017) publicaron un estudio sobre el movimiento de la mandíbula de Exaeretodon argentinus según lo indica su microdesgaste dental. ^[215]
Un estudio sobre la morfología de los dientes del cinodonte Candelariodon barberenai , así como sobre las relaciones filogenéticas de la especie, es publicado por Martinelli et al. (2017). ^[216]
Gaetano, Abdala y Govender (2017) publican una descripción de la anatomía del esqueleto postcraneal de Tritylodon longaevus . ^[217]
Panciroli et al. (2017) publican una reevaluación de la anatomía de los dientes postcaninos de Stereognathus , basada en todo el material disponible del Reino Unido , y consideran que la especie S. hebridicus es un sinónimo menor de la especie S. ooliticus . ^[218]
Bordy et al. (2017) describen un molde de una madriguera que probablemente fue hecha por un cinodonte triteledóntido de la Formación Elliot superior del Jurásico Temprano ( Sudáfrica ). ^[219]
Lautenschlager et al. (2017) publicaron un estudio sobre la evolución de los músculos de la mandíbula durante la transición de cinodonte a mamífero . ^[220]

Nuevos taxones

Nombre	Novedad	Estado	Autores	Edad	Unidad	Ubicación	Notas
Alemoatherium^[221]	Gen. y sp. nov.	Válido	Martinelli y otros.	Triásico tardío ( Carniense tardío )	Formación Santa María	Brasil	Cinodonte perteneciente al grupo Prozostrodontia . La especie tipo es A. huebneri .
Aleodon cromptoni^[222]	noviembre esp.	Válido	Martinelli y otros.	Triásico ( Ladiniense - Carniense temprano )		Brasil Namibia ?	Un cinodonte perteneciente a la familia Chiniquodontidae .
Bulbasauro^[223]	Gen. y sp. nov.	Válido	Cámara y Smith	Pérmico tardío	Formación Teekloof	Sudáfrica	Dicinodonte de la familia Geikiidae . La especie tipo es B. phylloxyron .
Dalongkoua^[224]	Gen. y sp. nov.	Válido	Liu y Abdala	Pérmico tardío	Formación Guodikeng	Porcelana	Un terocéfalo . La especie tipo es D. fuae .
Microwhaisias ^[225]	Gen. y sp. nov.	Válido	Huttenlocker y Smith	Pérmico ( Wuchiapingiano )	Formación Teekloof	Sudáfrica	Un terocéfalo whaitsiid . La especie tipo es M. mendrezi .
Nuerterio^[226]	Gen. y sp. nov.	Válido	Velazco, Buczek y Novacek	Jurásico tardío	Secuencia de Ulan Malgait	Mongolia	Un cinodonte tritilodóntido . La especie tipo es N. baruunensis .
Ofidostoma ^[225]	Gen. y sp. nov.	Válido	Huttenlocker y Smith	Pérmico ( Wuchiapingiano )	Formación Teekloof	Sudáfrica	Un terocéfalo whaitsioideo de ubicación filogenética incierta. La especie tipo es O. tatarinovi .
Parasuminia^[227]	Gen. y sp. nov.	Válido	Kurkin	Pérmico (Severodviniano)	Formación Poldarsa	Rusia	Un anomodonte emparentado con Suminia . El género incluye la nueva especie P. ivakhnenkoi .
Scalenodon ribeiroae^[228]	noviembre esp.	Válido	Melo, Martinelli y Soares	Triásico	Supersecuencia de Santa María	Brasil	Un cinodonte traversodóntido .
Shartegodon^[226]	Gen. y sp. nov.	Válido	Velazco, Buczek y Novacek	Jurásico tardío	Secuencia de Ulan Malgait	Mongolia	Un cinodonte tritilodonto . La especie tipo es S. altai .
Shiguaignato^[229]	Gen. y sp. nov.	Válido	Liu y Abdala	Pérmico tardío	Formación Naobaogou	Porcelana	Un terocéfalo akidnognátido . La especie tipo es S. wangi .

Mamíferos

Otros animales

Investigación

Zhu et al. (2017) publican un estudio sobre una sucesión de conjuntos fósiles del Ediacárico al Cámbrico de la Plataforma Siberiana Oriental ( Rusia ) , quienes sostienen que las biotas esqueléticas denominadas del Ediacárico y del Cámbrico temprano se superponen sin un recambio biótico notable. ^[230]
Paterson et al. (2017) publican un estudio sobre el taxón ediacárico Parvancorina minchami , que indica que este animal era capaz de realizar reotaxis . ^[231]
Darroch et al. (2017) publican un estudio sobre el flujo de agua alrededor del cuerpo del taxón ediacárico Parvancorina^{y sus implicaciones para el modo de alimentación y la movilidad de este animal. [232]}
Warren et al. (2017) informan de fósiles de miembros del género Namacalathus (co-ocurrente con Cloudina y Corumbella ) de la Formación Ediacárica Tagatiya Guazú (Grupo Itapucumi, Paraguay ) , ampliando el rango geográfico conocido del taxón. ^[233]
Evans, Droser y Gehling (2017) publicaron un estudio sobre la morfología , el crecimiento y el desarrollo de Dickinsonia costata . ^[234]
Hoekzema et al. (2017) publican un estudio sobre el crecimiento y desarrollo de Dickinsonia , quienes interpretan este taxón como un animal. ^[235]
Zakrevskaya e Ivantsov (2017) publicaron un estudio sobre la anatomía de Dickinsonia costata y D. tenuis , e interpretaron que D. costata probablemente desciende de D. tenuis por neotenia . ^[236]
Lieberman et al. (2017) publican la descripción de fósiles de cuerpo blando y forma de disco recientemente descubiertos en la Formación Carrara del Cámbrico temprano ( California , Estados Unidos ), asignados tentativamente al género Discophyllum (un animal de ubicación filogenética incierta, podría ser un condróforo o un eldónido ) . ^[237]
Becker-Kerber et al. (2017) informan sobre especímenes de Cloudina asociados con texturas de tapetes microbianos de la Formación Tamengo Ediacárica ( Brasil ). ^[238]
Parry et al. (2017) describen un conjunto de fósiles traza de limolitas del período Ediacárico - Cámbrico en Brasil , probablemente producidos por un organismo similar a un nematoide . ^[239]
Botting et al. (2017) describen una fauna diversa dominada por esponjas que vivió inmediatamente después de la extinción del Hirnantian en China . ^[240]
Brayard et al. (2017) informan de un conjunto marino diverso del Triásico Temprano ( Olenekiano ) ( biota de París ), que incluye esponjas protomonaxónidas leptomítidas (un grupo conocido solo del Cámbrico y Ordovícico ), nuevas formas del orden crinoideo Holocrinida que muestran caracteres avanzados, un probable ofiodermátido basal y coleoides portadores de gladius (previamente desconocidos en los estratos del Triásico Temprano) de París ( Idaho , Estados Unidos ) . ^[241]
Young y Vinther (2017) publicaron un estudio sobre la anatomía muscular de Pambdelurion whittingtoni . ^[242]
La especie del Cámbrico Zhenghecaris shankouensis , originalmente clasificada como artrópodo bivalvo , es reinterpretada como miembro de Radiodonta por Zeng et al. (2017). ^[243]
El espécimen holotipo de una especie putativa de lobopodio, Aysheaia prolata, es reinterpretado como un apéndice frontal aislado de un radiodontano perteneciente al género Stanleycaris por Pates, Daley y Ortega-Hernández (2017). ^[244]
Pates y Daley (2017) publican una revisión del género radiodóntico Caryosyntrips , quienes interpretan el espécimen holotipo de una supuesta especie lobopodia Mureropodia apae como un apéndice aislado parcial de un miembro del género Caryosyntrips . ^[245]
La descripción de la morfología de Amplectobelua symbrachiata , con un enfoque en su región de la cabeza, fue publicada por Cong et al. (2017). ^[246]
Moysiuk, Smith y Caron (2017) publicaron un estudio sobre la anatomía del hiolito cámbrico Haplophrentis , así como sobre las relaciones filogenéticas de los hiolitos. ^[247]
Sallan et al. (2017) publican un estudio sobre las relaciones filogenéticas de Tullimonstrum gregarium , que cuestiona su interpretación como vertebrado. ^[248]
Li, Liu y Ou (2017) describen nuevos fósiles excepcionalmente conservados de Vetulicola longbaoshanensis de la Formación Wulongqing del Cámbrico Inferior ( China ). ^[249]
Poinar et al. (2017) describen metacercarias de trematodos putativos preservadas en la base de los fémures de un lagarto ágamido a partir del ámbar birmano del Cretácico ( Myanmar ). ^[250]

Nuevos taxones

Nombre	Novedad	Estado	Autores	Edad	Unidad	Ubicación	Notas
Acoelia discontinua ^[251]	noviembre esp.	Válido	Wu	Pérmico ( Changhsingiano )		Porcelana	Esponja calcárea perteneciente al orden Inozoa y a la familia Acoeliidae.
Aerorretiolitos ^[252]	Gen. y sp. nov.	Válido	Melchin, Lenz y Kozlowska	siluriano		Canadá	Un graptolito . El género incluye la nueva especie A. cancellatus .
Aladraco ^[253]	Nombre y apellido nov.	Válido	Geyer	cambriano	Formación Jbel Wawrmast Formación Tannenknock	Alemania Marruecos	Miembro de Hyolitha ; nombre que reemplaza a Oxyprymna Kiderlen (1933). El género incluye A. schloppensis (Wurm, 1925) y una nueva especie, A. ougnatensis .
Allonnia erjiensis^[254]	noviembre esp.	Válido	Yun, Zhang y Li	cambriano	Ciudad de almacenamiento de Chengjiang	Porcelana	Un canciller .
Andiprión ^[255]	Gen. y sp. nov.	Válido	Consejos et al.	Ordovícico ( Dapingiano )		Argentina	Poliqueto descrito a partir de escolecodontos . El género incluye la nueva especie A. paxtonae .
Angulosuspongia ^[256]^[257]	Gen. y sp. nov.	Válido	Yang y otros.	Estadio cámbrico 5	Formación Kaili	Porcelana	Esponja perteneciente al orden Verongida y a la familia Vauxiidae . El género incluye la nueva especie A. sinensis .
Ankalodous ^[258]	Gen. y sp. nov.	Válido	Shu y otros.	Serie cámbrica 3	Formación Qiongzhusi (Chiungchussu)	Porcelana	Gusano flecha . La especie tipo es A. sericus .
Arqueoquionelasmo ^[259]	Gen. y sp. nov.	Válido	Kočí y otros.	Cretácico tardío ( Cenomaniano )	Cuenca Cretácica de Bohemia	República Checa	Animal de ubicación filogenética incierta. Originalmente se lo interpretó como un percebe perteneciente al grupo Balanomorpha y a la superfamilia Chionelasmatoidea; Gale y Skelton (2018) lo consideraron un bivalvo rudista . ^[260] El género incluye la nueva especie A. nekvasilovae .
Biskolitas ^[261]	Gen. y sp. nov.	Válido	Valent, Fatka y Marek	Cámbrico ( Drumiano )	Formación Buchava	República Checa	Miembro de Hyolitha . El género incluye nuevas especies B. iactans .
Capinatador^[262]	Gen. y sp. nov.	Válido	Briggs y Caron	cambriano	Esquisto de Burgess	Canadá ( Columbia Británica )	Un gusano flecha . La especie tipo es C. praetermissus .
Caryosyntrips camurus^[245]	noviembre esp.	Válido	Patés y Daley	cambriano	Formación Burgess Shale Langston ¿Formación Valdemiedes?	Canadá ( Columbia Británica ) Estados Unidos ( Utah ) España ?	Un miembro de Radiodonta .
Caryosyntrips durus^[245]	noviembre esp.	Válido	Patés y Daley	cambriano	Esquisto Wheeler	Estados Unidos ( Utah )	Un miembro de Radiodonta .
Nube de ningqiangensis^[263]	noviembre esp.	Válido	Cai y otros.	Ediacárico tardío		Porcelana
Cloudina xuanjiangpingensis^[263]	noviembre esp.	Válido	Cai y otros.	Ediacárico tardío		Porcelana
Conchicolites rossicus^[264]	noviembre esp.	Válido	Vinn y Madison	Ordovícico ( Katian )		Rusia	Un miembro de Cornulitida perteneciente a la familia Cornulitidae.
Conciliospongia ^[265]	Gen. y sp. nov.		Botting, Zhang y Muir	Ordovícico tardío	Formación Wenchang	Porcelana	Una demosponja de tallo de ubicación filogenética incierta. La especie tipo es C. anjiensis .
Corallistes campanensis ^[266]	noviembre esp.	Válido	Świerczewska-Gladysz	Cretácico tardío ( Campaniano temprano )		Polonia	Una demosponja litistida perteneciente a la familia Corallistidae .
Cretacimermis aphidophilus^[267]	noviembre esp.	Válido	Poinar	Cretácico tardío ( Cenomaniano )	Ámbar birmano	Birmania	Un nematodo perteneciente a la familia Mermithidae .
Eolorica^[268]	Gen. y sp. nov.	Válido	Harvey y Butterfield	Cámbrico ( Furongiano )	Formación de madera muerta	Canadá ( Saskatchewan )	Miembro del grupo total de los loricíferos . La especie tipo es E. deadwoodensis .
Eorograptus spirifer ^[252]	noviembre esp.	Válido	Melchin, Lenz y Kozlowska	siluriano		Canadá	Un graptolito .
Feiyanella ^[269]	Gen. y sp. nov.	Válido	Han y otros.	Cámbrico más temprano	Formación Kuanchuanpu	Porcelana	Un microfósil tubular parecido a Cloudina . La especie tipo es F. manica .
Geoditesia jordaniensis^[270]	Sp. nov	Valid	Ungureanu, Ahmad & Farouk	Middle Jurassic (Callovian)		Jordan	A sponge.
Glomerula gemmellaroi^[271]	Sp. nov	Valid	Sanfilippo in Sanfilippo et al.	Permian	"Pietra di Salomone" Limestone	Italy	A polychaete belonging to the family Sabellidae, a species of Glomerula.
Guettardiscyphia zitti^[272]	Sp. nov	Valid	Vodrážka	Late Cretaceous (Turonian)	Bílá Hora Formation	Czech Republic	A hexactinellid sponge belonging to the family Cribrospongiidae.
Inquicus^[273]	Gen. et sp. nov	Valid	Cong et al.	Early Cambrian	Chengjiang Lagerstätte	China	A tiny worm infecting members of the genera Cricocosmia and Mafangscolex. Genus includes new species I. fellatus.
Keretsa^[274]	Gen. et sp. nov	Valid	Ivantsov	Late Precambrian	Zimnie Gory Formation	Russia ( Arkhangelsk Oblast)	An early eumetazoan, showing similarities to the arthropod species Naraoia longicaudata. The type species is K. brutoni.
Labechia yeongwolense^[275]	Sp. nov	Valid	Jeon et al.	Ordovician (Darriwilian)	Yeongheung Formation	South Korea	A stromatoporoid.
Lepidocoleus kuangguoduni^[276]	Sp. nov	Valid	Gügel et al.	Devonian (Eifelian)	Nandan Formation	China	A machaeridian.
'Linevitus' guizhouensis^[277]	Sp. nov	Valid	Sun et al.	Cambrian Stage 4	Balang Formation	China	A member of Hyolitha.
Microdictyon cuneum^[278]	Sp. nov	Valid	Wotte & Sundberg	Cambrian		United States ( Nevada)	A lobopodian.
Microdictyon montezumaensis^[278]	Sp. nov	Valid	Wotte & Sundberg	Cambrian		United States ( Nevada)	A lobopodian.
Mughanniyyum^[270]	Gen. et sp. nov	Valid	Ungureanu, Ahmad & Farouk	Middle Jurassic (Callovian)		Jordan	A sponge. Genus includes new species M. hanium.
Multiconotubus^[263]	Gen. et sp. nov	Valid	Cai et al.	Late Ediacaran		China	A Cloudina-like fossil. Genus includes new species M. chinensis.
Neophrissospongia kacperskii^[266]	Sp. nov	Valid	Świerczewska-Gładysz	Late Cretaceous (early Campanian)		Poland	A lithistid demosponge belonging to the family Corallistidae.
Orthrozanclus elongata^[279]	Sp. nov		Zhao & Smith in Zhao et al.	Cambrian Stage 3	Maotianshan Shales	China
Ovatiovermis^[280]	Gen. et sp. nov	Valid	Caron & Aria	Cambrian	Burgess Shale	Canada ( British Columbia)	A lobopodian belonging to the family Luolishaniidae. The type species is O. cribratus.
Pachinion canaliculatum^[266]	Sp. nov	Valid	Świerczewska-Gładysz	Late Cretaceous (early Campanian)		Poland	A lithistid demosponge belonging to the family Corallistidae.
Paratetragraptus cooperi^[281]	Sp. nov	Valid	VandenBerg	Ordovician (early Floian)		Australia	A graptolite belonging to the group Dichograptina and the family Phyllograptidae.
Paratetragraptus? henrywilliamsi^[281]	Sp. nov	Valid	VandenBerg	Ordovician (early Floian)		Australia	A graptolite belonging to the group Dichograptina and the family Phyllograptidae.
Paratetragraptus thomassmithi^[281]	Sp. nov	Valid	VandenBerg	Ordovician (early Floian)		Australia	A graptolite belonging to the group Dichograptina and the family Phyllograptidae.
Plumulites lamonti^[282]	Sp. nov	Valid	Candela & Crighton	Silurian (Telychian)	Wether Law Linn Formation	United Kingdom	A machaeridian.
Propomatoceros permianus^[271]	Sp. nov	Valid	Sanfilippo in Sanfilippo et al.	Permian	"Pietra di Salomone" Limestone	Italy	A polychaete belonging to the family Serpulidae, a species of Propomatoceros.
Pseudoretiolites hyrichus^[252]	Sp. nov	Valid	Melchin, Lenz & Kozłowska	Silurian		Canada	A graptolite.
Pyrgopolon (Septenaria) cenomanensis^[283]	Sp. nov	Valid	Kočí, Jäger & Morel	Late Cretaceous (Cenomanian)		France	A polychaete belonging to the family Serpulidae.
Pyrgopolon (Turbinia?) gaiae^[271]	Sp. nov	Valid	Sanfilippo in Sanfilippo et al.	Permian	"Pietra di Salomone" Limestone	Italy	A polychaete belonging to the family Serpulidae, a species of Pyrgopolon.
Radiofibrosclera^[251]	Gen. et sp. nov	Valid	Wu	Permian (Changhsingian)		China	A sclerosponge. The type species is R. laibinensis.
Ratcliffespongia arivechensis^[284]	Sp. nov	Valid	Beresi et al.	Cambrian Series 3		Mexico	A reticulosan sponge of uncertain phylogenetic placement.
Saccorhytus^[285]	Gen. et sp. nov	Valid	Han et al.	Earliest Cambrian		China	An animal of uncertain phylogenetic placement. Originally described as an early deuterostome related to vetulicolians and vetulocystids, but subsequently argued to be an ecdysozoan.^[286] The type species is S. coronarius.
"Serpula" distefanoi^[271]	Sp. nov	Valid	Sanfilippo in Sanfilippo et al.	Permian	"Pietra di Salomone" Limestone	Italy	A polychaete belonging to the family Serpulidae.
Serpula? pseudoserpentina^[283]	Sp. nov	Valid	Kočí, Jäger & Morel	Late Cretaceous (Cenomanian)		France	A polychaete belonging to the family Serpulidae.
Silicunculus saaqqutit^[287]	Sp. nov	Valid	Peel	Cambrian Series 3		Greenland	A sponge.
Singuuriqia^[288]	Gen. et sp. nov	Valid	Peel	Cambrian Stage 3	Sirius Passet Lagerstätte	Greenland	A member of Priapulida. Genus includes new species S. simoni.
Siphusauctum lloydguntheri^[289]	Sp. nov	Valid	Kimmig, Strotz & Lieberman	Cambrian Stage 5	Spence Shale	United States ( Utah)
Tauricornicaris^[243]	Gen. et 2 sp. nov	Valid^[290]	Zeng et al.	Early Cambrian	Chengjiang Lagerstätte	China	Originally considered as member of Radiodonta, possibly a member of Hurdiidae, but denied in 2018.^[291]^[292] Genus includes new species T. latizonae and T. oxygonae.
Thoracospongia lacrimiformis^[287]	Sp. nov	Valid	Peel	Cambrian Series 3		Greenland	A sponge.
Tianzhushanella tolli^[293]	Sp. nov	Valid	Kouchinsky et al.	Cambrian	Medvezhya Formation	Russia	A member of Tianzhushanellidae (a group of animals of uncertain phylogenetic placement, possibly stem-brachiopods).
Tshallograptus^[281]	Gen. et comb. et 3 sp. nov	Valid	VandenBerg	Ordovician (early Floian)		Australia Canada	A graptolite belonging to the group Dichograptina and the family Phyllograptidae. The type species is "Graptolithus" fruticosus Hall (1858); genus also includes new species T. tridens, T. cymulus and T. furcillatus.
Valospongia sonorensis^[284]	Sp. nov	Valid	Beresi et al.	Cambrian Series 3		Mexico	A reticulosan sponge of uncertain phylogenetic placement.
Vittatusivermis^[294]	Gen. et sp. nov		Zhang et al.	Cambrian (Fortunian)	Yuhucun Formation	China	A worm-like organism, possibly a member of Bilateria of uncertain phylogenetic placement. The type species is V. annularius.
Websteroprion^[295]	Gen. et sp. nov	Valid	Eriksson, Parry & Rudkin	Devonian (late Emsian-early Eifelian)	Kwataboahegan Formation	Canada ( Ontario)	A eunicidan polychaete of uncertain phylogenetic placement. The type species is W. armstrongi.

Other organisms

Research

Eoarchean (over 3,700 million years old) organic residues are reported from Isua, West Greenland by Hassenkam et al. (2017).^[296]
Putative fossilized microorganisms that are at least 3,770 million and possibly 4,280 million years old are described from the Nuvvuagittuq belt (Quebec, Canada) by Dodd et al. (2017).^[297]
Organic carbon contents are reported from the oldest metasedimentary rocks from northern Labrador (Canada) by Tashiro et al. (2017), who interpret the finding as the oldest evidence of organisms greater than 3.95 Ga;^[298] the study is subsequently criticized by Whitehouse et al. (2019).^[299]
Potential biosignatures, including stromatolites, are reported from the newly discovered rocks recovered from ca. 3.48 billion years old Dresser Formation (Pilbara Craton, Australia) by Djokic et al. (2017).^[300]
Lenticular structures known from the ~3.4 Ga Kromberg Formation (Kaapvaal Craton, South Africa) are interpreted as organic Archean microfossils by Oehler et al. (2017).^[301]
Fossils of early eukaryotes Tappania plana, Dictyosphaera macroreticulata and Valeria lophostriata are described from the early Mesoproterozoic Greyson Formation (Belt Supergroup, Montana, United States) by Adam et al. (2017).^[302]
2.4-billion-year-old filamentous fossils forming mycelium-like structures, considered to be either the oldest known fungi or members of an unknown branch of fungus-like mycelial organisms, are described from the Ongeluk Formation (South Africa) by Bengtson et al. (2017).^[303]
A study on the anatomy of the fossils of Chuaria circularis recovered from the Tonian Liulaobei Formation (China) is published by Tang et al. (2017), who interpret Chuaria as most likely a simple multicellular organism (a colonial organism without cell differentiation).^[304]
A study on the apatitic scale microfossils from the Fifteenmile Group (Yukon, Canada), indicating that the fossils document the existence of eukaryotic biomineralizing organisms approximately 810 million years ago, is published by Cohen et al. (2017).^[305]
A study on the structure, morphology, and development of the large intracellular structures preserved in embryo-like microfossils from the Ediacaran Weng'an Biota (China) is published by Yin et al. (2017), who interpret these structures as likely cell nuclei.^[306]
A study testing the suggested link between the appearance of large body size in rangeomorphs (organisms of uncertain phylogenetic placement, likely animals) in the Ediacaran and postulated regional increases in environmental nutrient levels is published by Hoyal Cuthill & Conway Morris (2017).^[307]
A study on the internal morphology of Rangea from the Nama Group (Namibia), based on data obtained using X-ray micro-computed tomography, is published by Sharp et al. (2017).^[308]
Smith et al. (2017) report the discovery of fossils of Gaojiashania from the Ediacaran strata of the Nama Group (Namibia) and a new fossil assemblage from the Ediacaran strata of the Wood Canyon Formation (Nevada, United States), including erniettomorphs and a variety of tubular body fossils.^[309]
A study on the well-preserved Devonian calcareous nanicellid foraminiferans from the Świętokrzyskie Mountains (Poland) and their implications for the biomineralization style and affinities of Paleozoic fusulinid foraminiferans is published by Dubicka & Gorzelak (2017).^[310]
Four forms of modern-looking gilled mushrooms, including two taxa belonging to the family Marasmiaceae, are described from the Cretaceous Burmese amber by Cai et al. (2017).^[311]

New taxa

Name	Novelty	Status	Authors	Age	Unit	Location	Notes
Acadialithus^[312]	Gen. et 2 sp. nov	Valid	Howe	Late Jurassic (Tithonian)		Bulgaria Offshore eastern Newfoundland, Canada Offshore in the eastern Gulf of Mexico Offshore of the northeast coast of the United States	A nannofossil. Genus includes new species A. dennei and A. valentinei.
Adendorfia^[313]	Gen. et sp. nov	Valid	Worobiec et al.	Miocene		Germany	A fungus, probably a member of Chaetomiaceae. Genus includes new species A. miocenica.
Algites philippoviensis^[314]	Sp. nov	Valid	Naugolnykh	Permian (Kungurian)	Philippovian Formation	Russia	A brown alga.
Algites shurtanensis^[314]	Sp. nov	Valid	Naugolnykh	Permian (Kungurian)	Shurtan Formation	Russia	A brown alga.
Alpinoschwagerina nagatoensis^[315]	Sp. nov	Valid	Kobayashi	Permian (Asselian)	Akiyoshi Limestone Group	Japan	A foraminifer belonging to the group Fusulinida.
Amsassia argentina^[316]	Sp. nov	Valid	Carrera, Astini & Gomez	Early Ordovician	La Silla Formation	Argentina	A coral-like organism of uncertain phylogenetic placement.
Asterina indodeightonii^[317]	Sp. nov	Valid	Vishnu et al.	Mid-Miocene to early Pleistocene		India	A fungus, a species of Asterina.
Asterina mioconsobrina^[317]	Sp. nov	Valid	Vishnu et al.	Mid-Miocene to early Pleistocene		India	A fungus, a species of Asterina.
Asterina miosphaerelloides^[317]	Sp. nov	Valid	Vishnu et al.	Mid-Miocene to early Pleistocene		India	A fungus, a species of Asterina.
Asterina neocombreticola^[317]	Sp. nov	Valid	Vishnu et al.	Mid-Miocene to early Pleistocene		India	A fungus, a species of Asterina.
Asterina neoelaeocarpi^[317]	Sp. nov	Valid	Vishnu et al.	Mid-Miocene to early Pleistocene		India	A fungus, a species of Asterina.
Asterina presaracae^[317]	Sp. nov	Valid	Vishnu et al.	Mid-Miocene to early Pleistocene		India	A fungus, a species of Asterina.
Baculogypsinella^[318]	Gen. et sp. nov	Valid	Matsumaru	Eocene		Philippines	A foraminifer. Genus includes new species B. eocenica.
Blastanosphaira^[319]	Gen. et sp. nov	Valid	Javaux & Knoll	Mesoproterozoic	Mainoru Formation	Australia	A possible eukaryotic microorganism of uncertain phylogenetic placement. The type species is B. kokkoda.
Bonniea makrokurtos^[320]	Sp. nov	Valid	Cohen, Irvine & Strauss	Tonian	Callison Lake Formation	Canada ( Yukon)	A vase-shaped microfossil.
Braarudosphaera pseudobatilliformis^[321]	Sp. nov	Valid	Alves, Lima & Shimabukuro	Early Cretaceous (Aptian)		Brazil	A haptophyte belonging to the family Braarudosphaeraceae.
Carbonoschwagerina nipponica^[315]	Sp. nov	Valid	Kobayashi	Carboniferous (Kasimovian and Gzhelian)	Akiyoshi Limestone Group	Japan	A foraminifer belonging to the group Fusulinida.
Cephalothecoidomyces^[313]	Gen. et sp. nov	Valid	Worobiec et al.	Neogene		Germany Poland	A fungus, probably a member of Cephalothecaceae. Genus includes new species C. neogenicus.
Chiphragmalithus muzylevii^[322]	Sp. nov	Valid	Musatov	Eocene (Ypresian)		Russia	A haptophyte.
Cobios^[323]	Gen. et sp. nov	Valid	Du et al.	Ediacaran	Doushantuo Formation	China	A red alga. The type species is Cobios rubo.
Curviacus^[324]	Gen. et sp. nov	Valid	Shen et al.	Ediacaran	Dengying Formation	China	A benthic modular organism consisting of serially arranged and crescent-shaped chambers. Genus includes new species C. ediacaranus.
Cyanonema grandis^[325]	Sp. nov	Valid	Shi & Feng in Shi et al.	Early Mesoproterozoic	Gaoyuzhuang Formation	China	A member of Cyanobacteria belonging to the group Nostocales.
Cycliocyrillium rootsi^[320]	Sp. nov	Valid	Cohen, Irvine & Strauss	Tonian	Callison Lake Formation Chuar Group (Kwagunt Formation)^[326]	Canada ( Yukon) United States^[326]	A vase-shaped microfossil. Originally described as a species of Cycliocyrillium, but subsequently transferred to the genus Obelix.^[326] Morais et al. (2019) corrected the suffix for the specific epithet to rootsii.^[326]
Dalongicaepa^[327]	Gen. et sp. et comb. nov	Valid	Xiao & Suzuki in Xiao, Suzuki & He	Late Permian	Upper Dalong Formation	China Thailand	A radiolarian belonging to the group Spumellaria and the family Spongotortilispinidae. The type species is D. bipolaris; genus also includes "Pseudospongoprunum" fontainei Sashida in Sashida et al. (2000).
Denaricion^[328]	Gen. et sp. nov	Valid	Bengtson in Bengtson et al.	~1.6 billion years ago		India	An organism of uncertain phylogenetic placement, might be an alga or prokaryote. Genus includes new species D. mendax.
Devisphaera^[329]	Gen. et sp. nov	Valid	Tang et al.	Late Mesoproterozoic – early Neoproterozoic	Madhubani Group	India	An organic-walled microfossil. Genus includes new species D. corallis.
Discusphyton^[330]	Gen. et sp. nov	Valid	Wang, Wang & Du	Ediacaran	Doushantuo Formation	China	A macroalga of uncertain phylogenetic placement. Genus includes new species D. whenghuiensis.
Fissumella^[331]	Gen. et sp. nov	Valid	Cruz-Abad et al.	Early Cretaceous (Albian)		Italy	A foraminifer. Genus includes new species F. motolae.
Flabelloperforata^[332]	Gen. et sp. nov	Valid	Schlagintweit & Rashidi	Late Cretaceous (Maastrichtian)	Tarbur Formation	Iran	A foraminifer belonging to the group Loftusiida, possibly a member of the family Biokovinidae. Genus includes new species F. tarburensis.
Gigadiacrodium^[333]	Gen. et comb. et sp. nov	Valid	Szczepanik, Servais & Żylińska	Cambrian (Furongian)	Alum Shale Formation Elliott's Cove Formation	Canada Iran Italy Poland Sweden	An acritarch. The type species is "Veryhachium" martinum Pittau (1985); genus also includes new species G. vidalii.
Gigantosphaeridium floccosum^[334]	Sp. nov	Valid	Agić, Moczydłowska & Yin	Early Mesoproterozoic	Ruyang Group	China	A microfossil.
Gondwanagaricites^[335]^[336]	Gen. et sp. nov	Valid	Heads, Miller & Crane	Early Cretaceous (Aptian)	Crato Formation	Brazil	A gilled mushroom. Genus includes new species G. magnificus.
Hagenococcus^[337]	Gen. et sp. nov	Valid	Krings et al.	Early Devonian	Rhynie chert	United Kingdom	A microorganism of uncertain phylogenetic placement, most likely an alga with affinities to the Chlorophyta or Streptophyta. Genus includes new species H. aggregatus.
Haplophragmoides arcticus^[338]	Sp. nov	Valid	Kaminski, Waskowska & Chan	Middle Pleistocene		Arctic Ocean (Lomonosov Ridge)	A foraminifer.
Jigulites titanicus^[315]	Sp. nov	Valid	Kobayashi	Carboniferous (Gzhelian) and Permian (Asselian)	Akiyoshi Limestone Group	Japan	A foraminifer belonging to the group Fusulinida.
Limeta^[339]	Gen. et sp. nov	Valid	Morais, Fairchild & Lahr in Morais et al.	Neoproterozoic	Urucum Formation	Brazil	A vase-shaped microfossil. Genus includes new species L. lageniformis.
Montiparus minensis^[315]	Sp. nov	Valid	Kobayashi	Carboniferous (Kasimovian)	Akiyoshi Limestone Group	Japan	A foraminifer belonging to the group Fusulinida.
Nannoconus troelsenii^[321]	Sp. nov	Valid	Alves, Lima & Shimabukuro	Early Cretaceous (Aptian)		Brazil	A haptophyte belonging to the family Nannoconaceae.
Oscillatoriopsis gigas^[325]	Sp. nov	Valid	Shi & Feng in Shi et al.	Early Mesoproterozoic	Gaoyuzhuang Formation	China	A member of Cyanobacteria belonging to the group Oscillatoriales.
Palaeoamphora^[339]	Gen. et sp. nov	Valid	Morais, Fairchild & Lahr in Morais et al.	Neoproterozoic	Urucum Formation	Brazil	A vase-shaped microfossil. Genus includes new species P. urucumense.
Palaeostromatus^[340]	Gen. et sp. nov	Valid	Dentzien-Dias, Poinar & Francischini	Permian (Guadalupian)	Rio do Rasto Formation	Brazil	An actinomycete. Genus includes new species P. diairetus.
Paleohaimatus^[341]	Gen. et sp. nov	Valid	Poinar	Eocene-Miocene	El Mamey Formation (Dominican amber)	Dominican Republic	A member of Apicomplexa belonging to the group Piroplasmida. Genus includes new species P. calabresi.
Parastaffelloides kanmerai^[315]	Sp. nov	Valid	Kobayashi	Carboniferous (Moscovian)	Akiyoshi Limestone Group	Japan	A foraminifer belonging to the group Fusulinida.
Pentadinium darmirae^[342]	Sp. nov	Valid	Slimani & Ţabără in Ţabără et al.	Paleocene (Danian)	Izvor Formation Runcu Formation	Romania	A dinoflagellate belonging to the group Gonyaulacales and the family Gonyaulacaceae.
Persiella^[332]	Gen. et sp. nov	Valid	Schlagintweit & Rashidi	Late Cretaceous (Maastrichtian)	Tarbur Formation	Iran	A foraminifer belonging to the group Loftusiida, possibly a member of the family Spirocyclinidae. Genus includes new species P. pseudolituus.
Pocillithus crucifer^[343]	Sp. nov	Valid	Lees, Bown & Young	Late Cretaceous (Turonian)		Tanzania	A haptophyte belonging to the family Papposphaeraceae.
Pocillithus macleodii^[343]	Sp. nov	Valid	Lees, Bown & Young	Late Cretaceous (Turonian)		Tanzania	A haptophyte belonging to the family Papposphaeraceae.
Quasifusulinoides grandis^[315]	Sp. nov	Valid	Kobayashi	Carboniferous (Kasimovian)	Akiyoshi Limestone Group	Japan	A foraminifer belonging to the group Fusulinida.
Rafatazmia^[328]	Gen. et sp. nov	Valid	Bengtson in Bengtson et al.	~1.6 billion years ago		India	An alga of uncertain phylogenetic placement. Genus includes new species R. chitrakootensis.
Ramathallus^[328]	Gen. et sp. nov	Valid	Sallstedt in Bengtson et al.	~1.6 billion years ago		India	A possible stem-florideophycean red algae. Genus includes new species R. lobatus.
Schwagerina wakatakeyamensis^[315]	Sp. nov	Valid	Kobayashi	Permian (Asselian)	Akiyoshi Limestone Group	Japan	A foraminifer belonging to the group Fusulinida.
Schwagerina watanabei^[315]	Sp. nov	Valid	Kobayashi	Permian (Asselian)	Akiyoshi Limestone Group	Japan	A foraminifer belonging to the group Fusulinida.
Spearlithus^[344]	Gen. et 12 sp. nov	Valid	Da Gama	Pleistocene		Dominican Republic	A calcareous nannofossil of uncertain phylogenetic placement.
Staffella subsphaerica^[315]	Sp. nov	Valid	Kobayashi	Carboniferous (Kasimovian and Gzhelian)	Akiyoshi Limestone Group	Japan	A foraminifer belonging to the group Fusulinida.
Stradnerlithus? haynesiae^[343]	Sp. nov	Valid	Lees, Bown & Young	Late Cretaceous (Turonian)		Tanzania	A haptophyte belonging to the order Stephanolithiales and the family Stephanolithiaceae.
Stradnerlithus wendleri^[343]	Sp. nov	Valid	Lees, Bown & Young	Late Cretaceous (Turonian)		Tanzania	A haptophyte belonging to the order Stephanolithiales and the family Stephanolithiaceae.
Suraqalatia^[345]	Gen. et sp. nov	Valid	Görmüş, Ameen Lawa & Al Nuaimy	Late Cretaceous (Maastrichtian)		Iraq	A foraminifer belonging to the family Dicyclinidae. Genus includes new species S. brasieri.
Synaptomitus^[346]	Gen. et sp. nov	Valid	Poinar	Eocene to Miocene	Dominican amber	Dominican Republic	Originally described as a fungus belonging to the group Basidiomycota,^[346] but this interpretation was challenged by Selosse et al. (2017).^[347] Genus includes new species S. orchiphilus.
Syracosphaera antiqua^[343]	Sp. nov	Valid	Bown, Lees & Young	Late Cretaceous (Turonian)		Tanzania	A haptophyte belonging to the order Syracosphaerales and the family Syracosphaeraceae.
Syracosphaera repagula^[343]	Sp. nov	Valid	Bown, Lees & Young	Late Cretaceous (Turonian)		Tanzania	A haptophyte belonging to the order Syracosphaerales and the family Syracosphaeraceae.
Tarburina^[348]	Gen. et sp. nov	Valid	Schlagintweit, Rashidi & Barani	Late Cretaceous (late Maastrichtian)	Tarbur Formation	Iran	A foraminifer. Genus includes new species T. zagrosiana.
Taruma^[339]	Gen. et sp. nov	Valid	Morais, Fairchild & Lahr in Morais et al.	Neoproterozoic	Urucum Formation	Brazil	A vase-shaped microfossil. Genus includes new species T. rata.
Tortolithus foramen^[343]	Sp. nov	Valid	Lees, Bown & Young	Late Cretaceous (Turonian)		Tanzania	A haptophyte of uncertain phylogenetic placement.
Veteronostocale grandis^[325]	Sp. nov	Valid	Shi & Feng in Shi et al.	Early Mesoproterozoic	Gaoyuzhuang Formation	China	A member of Cyanobacteria belonging to the group Nostocales.
Windipila^[349]	Gen. et sp. nov	Valid	Krings & Harper	Early Devonian	Windyfield chert	United Kingdom	A fungus described on the basis of a reproductive unit. Genus includes new species W. spinifera.
Xiaohongyuia^[350]	Gen. et sp. nov	Valid	Shi & Feng in Shi et al.	Late Paleoproterozoic	Dahongyu Formation	China	A probable eukaryotic microfossil. Genus includes new species X. sinica.

General paleontology

Research related to paleontology that either does not concern any of the groups of the organisms listed above, or concerns multiple groups.

A study on the links between changes in the composition of exposed continental crust and oxygenation of the atmosphere in the Precambrian is published by Smit & Mezger (2017).^[351]
A review of the progress in modeling the Snowball Earth atmosphere, cryosphere, hydrosphere and lithosphere, specifically as it pertains to Cryogenian geology and geobiology, is published by Hoffman et al. (2017).^[352]
A revised record of fossil eukaryotic steroids during the Neoproterozoic is presented by Brocks et al. (2017), who argue that bacteria were the only notable primary producers in the oceans before the Cryogenian, and that rapid rise of marine planktonic algae to domination occurred in the narrow time interval between the Sturtian and Marinoan glaciations, 659–645 million years ago, likely driving the subsequent radiation of animals in the Ediacaran period.^[353]
A study evaluating whether mass extinction events over the last 500 million year were caused by astronomical phenomena is published by Erlykin et al. (2017).^[354]
A study on the water column geochemistry of the Yangtze Sea during the Ediacaran-Cambrian transition and its implications for the relationship between ocean oxygenation and Early Cambrian animal diversification is published by Zhang et al. (2017).^[355]
A study on the links between the expansion of siliceous sponges and seawater oxygenation during the Ediacaran–Cambrian transition is published by Tatzel et al. (2017).^[356]
A study on the factors influencing marine invertebrate diversity dynamics through the Phanerozoic is published by Cermeño et al. (2017).^[357]
Edwards et al. (2017) identify a strong temporal link between the rising atmospheric oxygen levels and the Great Ordovician Biodiversification Event.^[358]
A study on the impact of the drawdown of atmospheric carbon dioxide (caused by burial of organic carbon leading to the formation of coal) on the climate around the Carboniferous/Permian boundary is published by Feulner (2017).^[359]
A comprehensive reconstruction of the Permian (Lopingian) Bletterbach Biota (Italy) and a review of other best-known Lopingian terrestrial associations containing both vertebrate and plant remains is published by Bernardi et al. (2017).^[360]
A study on the causal connection between the Siberian Traps large igneous province magmatism and Permian–Triassic extinction event, identifying the initial emplacement pulse as likely to have triggered mass extinction, is published by Burgess, Muirhead & Bowring (2017).^[361]
Viglietti, Rubidge & Smith (2017) review the tectonic setting of the Late Permian Karoo Basin (South Africa), provide an updated basin development model, and interpret their findings as indicating that the climatic changes associated with the Permian–Triassic extinction event were occurring much lower in the stratigraphy (and thus earlier) than previously documented.^[362]
A summary of knowledge of the impact of Permian-Triassic mass extinction on reef ecosystems, and on their recovery after this extinction, is presented by Martindale, Foster & Velledits (2017).^[363]
A study on benthic invertebrate communities from the Lower Triassic Werfen Formation (Italy), aiming to test whether carbon isotope perturbations during the Early Triassic were associated with biotic crises that impeded benthic recovery after the Permian–Triassic extinction event, is published by Foster et al. (2017).^[364]
A study on the impact of the magmatic activity associated with the Central Atlantic magmatic province on the Triassic–Jurassic extinction event is published by Davies et al. (2017).^[365]
A study on the volcanic activity at the end of the Triassic as indicated by mercury concentrations in sediments from around the world is published by Percival et al. (2017).^[366]
A study on the oxygen levels in Earth's oceans during and after the Triassic–Jurassic extinction event as indicated by uranium isotopes in shallow-marine limestones in the Lombardy Basin (northern Italy) is published by Jost et al. (2017).^[367]
A high-resolution stratigraphic chart for terrestrial Late Cretaceous units of North America and a study on the stratigraphic ranges of North American dinosaurs is published by Fowler (2017).^[368]
A study on the impact that large amounts of soot injected into the atmosphere during the Cretaceous–Paleogene extinction event (probably caused by global wildfires) had on the climate is published by Bardeen et al. (2017).^[369]
A study estimating the decrease of the air temperature and the duration of the climate cooling caused by Chicxulub impact at the end of the Cretaceous is published by Brugger, Feulner & Petri (2017).^[370]
A study on the volume of the climate-active gases released from sedimentary rocks as a result of the Chicxulub impact, as well as on their effect on the global climate, is published by Artemieva, Morgan & Expedition 364 Science Party (2017).^[371]
Kaiho & Oshima (2017) calculate the amounts of stratospheric soot and sulfate formed by a virtual asteroid impact at various global locations, and conclude that the Cretaceous–Paleogene extinction event was caused by the Chicxulub impact happening at the hydrocarbon-rich, sulfate-dominated area on the Earth's surface, and that an impact at a low–medium hydrocarbon area on Earth would be unlikely to cause mass extinction.^[372]
A study on the data sets of molluscan fossils from the Cretaceous–Paleogene of the Seymour Island (Antarctica) is published by Tobin (2017), who identifies possible evidence of two separate extinction events, one prior to the Cretaceous–Paleogene boundary, and one simultaneous with the bolide impact at the Cretaceous–Paleogene boundary.^[373]
A study on the behavioral and ecological diversification of animals that colonized land as indicated by trace fossils is published by Minter et al. (2017).^[374]
A study on the age of the Cowie Harbour Fish Bed (Scotland, United Kingdom), containing fish and arthropod fossils (including the millipede Pneumodesmus newmani), is published by Suarez et al. (2017).^[375]
A study on the preservation of skin and keratinous integumentary structures in tetrapod fossils through time is published by Eliason et al. (2017).^[376]
A study on the differences between the tetrapod faunas at different latitudes during the early and middle Permian, as well as their implications for establishing whether the Olson's Extinction was a genuine event, is published by Brocklehurst et al. (2017).^[377]
A study on the non-flying terrestrial tetrapod species richness through the Mesozoic and early Palaeogene is published by Close et al. (2017).^[378]
A study on the evolution of the shape of brain and skull roof during the transition from early reptiles through archosauromorphs, including nonavian dinosaurs, to birds is published by Fabbri et al. (2017).^[379]
A study on the structure and vulnerability of the food web in marine vertebrate assemblages prior to the Cretaceous–Paleogene extinction event as indicated by calcium isotope data from plesiosaurs and mosasaurs is published by Martin et al. (2017).^[380]
Qvarnström et al. (2017) reconstruct fossil inclusions in two coprolites (produced by an insectivorous animal and a large aquatic predator) from the Late Triassic locality of Krasiejów (Poland) using propagation phase-contrast synchrotron microtomography.^[381]
A study on the fossil inclusions in coprolite fragments (produced by medium to large-sized carnivores, possibly therocephalian therapsids or early archosauriforms) recovered from the Late Permian locality of Vyazniki (Russia) is published by Bajdek et al. (2017).^[382]
A new tetrapod assemblage from the lowermost levels of the Triassic Chañares Formation (Argentina), dominated by fossils of Tarjadia ruthae, dicynodonts and cynodonts, and also including fossils of other pseudosuchians and rhynchosaurs, is described by Ezcurra et al. (2017), who also reinterpret Tarjadia ruthae and Archeopelta arborensis as erpetosuchid archosaurs.^[383]
A study on the cosmopolitanism of terrestrial amniote faunas in the aftermath of the Permian–Triassic extinction event and Triassic–Jurassic extinction event is published by Button et al. (2017).^[384]
Frese et al. (2017) determine the mineral and elemental composition of a range of fossils from the Talbragar fossil site (Australia) and their rock matrices using ultraviolet light-induced fluorescence/photoluminescence, X-ray fluorescence and X-ray diffractometry, and use those techniques to reveal anatomical details of animals and plants fossils that weren't discernible otherwise.^[385]
A study on changes of the size of fossil marine shells and predatory drill holes in those shells during the Phanerozoic, as well as their implications for changes of predator-prey size ratio throughout the Phanerozoic, is published by Klompmaker et al. (2017).^[386]
A study evaluating the utility of oxygen-isotope compositions of fossilised foraminifera tests as proxies for surface- and deep-ocean paleotemperatures, and its implications for inferring Late Cretaceous and Paleogene deep-ocean and high-latitude surface-ocean temperatures, is published by Bernard et al. (2017).^[387]^[388]^[389]
A study on the glacial development and environmental changes in the Aurora Subglacial Basin (Antarctica) throughout the Cenozoic based on geophysical and geological evidence is published by Gulick et al. (2017).^[390]
A study on the onset duration of the Paleocene–Eocene Thermal Maximum is published by Kirtland Turner et al. (2017).^[391]
A study on the relationship between volcanic activity in the North Atlantic Igneous Province and the Paleocene–Eocene Thermal Maximum is published by Gutjahr et al. (2017).^[392]
A study on the environment in the area corresponding to the present-day Amazon basin in the Miocene as indicated by data from the shark and ray fossils from the Pirabas Formation (Brazil) is published by Aguilera et al. (2017).^[393]
A study on the impact of the Messinian salinity crisis on Mediterranean magmatism is published by Sternai et al. (2017).^[394]
A study on the changes of ice sheets volume and sea level during the late Pliocene is published by de Boer et al. (2017).^[395]
Pimiento et al. (2017) identify a previously unrecognized extinction event among marine megafauna at the end of the Pliocene.^[396]
A study on the aridity in eastern Africa over the past 4.4 million years as indicated by oxygen isotope ratios in fossil herbivore tooth enamel, and on its implications for inferring the role of climate in shaping early hominin environments, is published by Blumenthal et al. (2017).^[397]
Tierney, deMenocal & Zander (2017) reconstruct temperature and aridity in the Horn of Africa region spanning the past 200,000 years.^[398]
A vertebrate fauna from the Pleistocene and Holocene of Sumba (Indonesia) is described by Turvey et al. (2017).^[399]
A study on the modified mammalian bones from the Plio–Pleistocene of Ethiopia is published by Sahle, El Zaatari & White (2017), who interpret the marks on some of these bones as more likely to be produced by crocodiles than by hominids using stone tools.^[400]
Hagstrum et al. (2017) report impact-related microspherules and elevated platinum concentrations found in fine-grained sediments retained within Late Pleistocene bison and mammoth skull fragments from Alaska and Yukon, and interpret the findings as evidence of repeated airbursts and ground/ice impacts associated with multiple episodes of cosmic impact.^[401]
A study on changes in landscape moisture in the rangelands in Europe, Siberia and the Americas during the late Pleistocene as indicated by data from the bones of megaherbivores is published by Rabanus-Wallace et al. (2017).^[402]

References

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[74] Yong-Qin Mao; Yuan-Long Zhao; Cheng-Wen Wang; Timothy Topper (2017). "A fresh look at Nisusia Walcott, 1905 from the Cambrian Kaili Formation in Guizhou". Palaeoworld. 26 (1): 12–24. doi:10.1016/j.palwor.2016.03.001.

[IJESRaheen-75] David A.T. Harper; Matthew A. Parkes; Zhan Ren-Bin (2017). "Late Ordovician deep-water brachiopod fauna from Raheen, Waterford Harbour, Ireland" (PDF). Irish Journal of Earth Sciences. 35: 1–18. doi:10.3318/ijes.2017.35.1. S2CID 134598008.

[76] G.A. Cisterna; A.F. Sterren; O. López Gamundí; M.M. Vergel (2017). "Carboniferous postglacial faunas in the late Serpukhovian–Bashkirian interval of central-western Argentina". Alcheringa: An Australasian Journal of Palaeontology. 41 (3): 413–431. doi:10.1080/03115518.2017.1299795. hdl:11336/44723. S2CID 133077581.

[77] Urszula Radwańska (2017). "Selected Oxfordian brachiopods from Zalas (Cracow Upland, Poland)". Acta Geologica Polonica. 67 (3): 423–430. Bibcode:2017AcGeP..67..433R. doi:10.1515/agp-2017-0021.

[78] Mohammad-Reza Kebria-Ee Zadeh; Leonid E. Popov; Mansoureh Ghobadi Pour (2017). "A new orthide brachiopod genus from the Middle Ordovician of the Alborz Mountains, Iran". GFF. 139 (4): 327–332. doi:10.1080/11035897.2017.1347197. S2CID 135028500.

[79] Debahuti Mukherjee; Sabyasachi Shome (2017). "Tithonian brachiopods from the Kachchh and Jaisalmer basins, India". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 285 (2): 187–199. doi:10.1127/njgpa/2017/0676.

[80] Jenaro L. García-Alcalde; Zarela Herrera (2017). "Tectogonotoechia rivasi n. sp. A new lower Pragian Celtiberian (Spain) Ancystrorhynchoidea rhynchonellid brachiopod" (PDF). Spanish Journal of Palaeontology. 32 (1): 115–128.

[81] Howard R. Feldman (2017). "Tunethyris blodgetti sp. nov. (Brachiopoda, Terebratulida) from the Middle Triassic of the Makhtesh Ramon, southern Israel". Annales Societatis Geologorum Poloniae. 87 (1): 89–99. doi:10.14241/asgp.2017.004.

[82] M. Mergl; İ. Hoşgör; I. O. Yilmaz; S. Zamora; J. Colmenar (2017). "Divaricate patterns in Cambro-Ordovician obolid brachiopods from Gondwana". Historical Biology: An International Journal of Paleobiology. 30 (7): 1015–1029. doi:10.1080/08912963.2017.1327531. S2CID 134763114.

[83] Shuzhong Shen; Li Qiao; Yan Zhang; Yuanlin Sun; Yugan Jin (2017). "Carboniferous brachiopod genera on type species of China". In Jiayu Rong; Yugan Jin; Shuzhong Shen; Renbin Zhan (eds.). Phanerozoic brachiopod genera of China. Beijing: Science Press. pp. 559–649.

[84] Sarah L. Sheffield; Colin D. Sumrall (2017). "Generic revision of the Holocystitidae of North America (Diploporita, Echinodermata) based on universal elemental homology". Journal of Paleontology. 91 (4): 755–766. Bibcode:2017JPal...91..755S. doi:10.1017/jpa.2016.159. S2CID 133298313.

[85] Ben Thuy; Hans Hagdorn; Andy S. Gale (2017). "Paleozoic echinoderm hangovers: Waking up in the Triassic". Geology. 45 (6): 531–534. Bibcode:2017Geo....45..531T. doi:10.1130/G38909.1.

[86] Daniel B. Blake (2017). "Paleozoic echinoderm hangovers: Waking up in the Triassic: COMMENT". Geology. 45 (7): e417. Bibcode:2017Geo....45E.417B. doi:10.1130/G39163C.1.

[87] Ben Thuy; Hans Hagdorn; Andy S. Gale (2017). "Paleozoic echinoderm hangovers: Waking up in the Triassic: REPLY". Geology. 45 (7): e418. Bibcode:2017Geo....45E.418T. doi:10.1130/G39210Y.1.

[88] Mariusz A. Salamon; Przemysław Gorzelak (2017). "Paleozoic echinoderm hangovers: Waking up in the Triassic: COMMENT". Geology. 45 (7): e419. Bibcode:2017Geo....45E.419S. doi:10.1130/G39196C.1.

[89] Ben Thuy (2017). "Paleozoic echinoderm hangovers: Waking up in the Triassic: REPLY". Geology. 45 (7): e420. Bibcode:2017Geo....45E.420T. doi:10.1130/G39221Y.1.

[90] Aaron W. Hunter; Kenneth J. McNamara (2017). "Paleozoic echinoderm hangovers: Waking up in the Triassic: COMMENT". Geology. 45 (11): e431. Bibcode:2017Geo....45E.431H. doi:10.1130/G39575C.1.

[91] Ben Thuy; Hans H. Hagdorn; Andy S. Gale (2017). "Paleozoic echinoderm hangovers: Waking up in the Triassic: REPLY". Geology. 45 (11): e432. Bibcode:2017Geo....45E.432T. doi:10.1130/G39684Y.1.

[92] David F. Wright (2017). "Bayesian estimation of fossil phylogenies and the evolution of early to middle Paleozoic crinoids (Echinodermata)". Journal of Paleontology. 91 (4): 799–814. Bibcode:2017JPal...91..799W. doi:10.1017/jpa.2016.141. S2CID 5018503.

[93] Selina R. Cole (2017). "Phylogeny and morphologic evolution of the Ordovician Camerata (Class Crinoidea, Phylum Echinodermata)". Journal of Paleontology. 91 (4): 815–828. Bibcode:2017JPal...91..815C. doi:10.1017/jpa.2016.137. S2CID 90459044.

[94] David F. Wright; William I. Ausich; Selina R. Cole; Mark E. Peter; Elizabeth C. Rhenberg (2017). "Phylogenetic taxonomy and classification of the Crinoidea (Echinodermata)". Journal of Paleontology. 91 (4): 829–846. Bibcode:2017JPal...91..829W. doi:10.1017/jpa.2016.142. S2CID 13806992.

[95] David F. Wright (2017). "Phenotypic innovation and adaptive constraints in the evolutionary radiation of Palaeozoic crinoids". Scientific Reports. 7 (1): Article number 13745. Bibcode:2017NatSR...713745W. doi:10.1038/s41598-017-13979-9. PMC 5653864. PMID 29062117.

[96] Elizabeth G. Clark; Bhart-Anjan S. Bhullar; Simon A. F. Darroch; Derek E. G. Briggs (2017). "Water vascular system architecture in an Ordovician ophiuroid". Biology Letters. 13 (12): 20170635. doi:10.1098/rsbl.2017.0635. PMC 5746540. PMID 29212753.

[97] Moe Kato; Tatsuo Oji; Kotaro Shirai (2017). "Paleoecology of echinoderms in cold seep environments revealed by isotope analysis in the Late Cretaceous Western Interior Seaway". PALAIOS. 32 (4): 218–230. Bibcode:2017Palai..32..218K. doi:10.2110/palo.2016.079. S2CID 131975877.

[98] Aaron W. Hunter; Neal L. Larson; Jamie Brezina (2018). "Comment to Kato et al. (2017), "Paleoecology of echinoderms in cold seep environments revealed by isotope analysis in the Late Cretaceous Western Interior Seaway"". PALAIOS. 33 (6): 282–283. Bibcode:2018Palai..33..282H. doi:10.2110/palo.2017.071. S2CID 133937083.

[99] Moe Kato; Tatsuo Oji; Kotaro Shirai (2018). "Reply to comment on Kato et al. (2017) "Paleoecology of echinoderms in cold seep environments revealed by isotope analysis in the Late Cretaceous Western Interior Seaway"". PALAIOS. 33 (6): 284–285. Bibcode:2018Palai..33..284K. doi:10.2110/palo.2018.028. S2CID 134000894.

[100] Mohamed Said M. Ali (2017). "First Record of a New Species of Amblypygus (Echinoidea) from the Middle Miocene of Mersa Matruh, Western Desert, Egypt". Paleontological Research. 21 (1): 44–53. doi:10.2517/2016PR016. S2CID 132772107.

[Ambonacrinus-101] Selina R. Cole; William I. Ausich; Jorge Colmenar; Samuel Zamora (2017). "Filling the Gondwanan gap: paleobiogeographic implications of new crinoids from the Castillejo and Fombuena formations (Middle and Upper Ordovician, Iberian Chains, Spain)". Journal of Paleontology. 91 (4): 715–734. Bibcode:2017JPal...91..715C. doi:10.1017/jpa.2016.135. hdl:20.500.12468/565. S2CID 132280262.

[Spinimetra-102] Hans Hess; Ben Thuy (2017). "Extraordinary diversity of feather stars (Echinodermata: Crinoidea: Comatulida) from a Lower Jurassic (Pliensbachian–Toarcian) rock reef of Feuguerolles (Normandy, France)". Swiss Journal of Palaeontology. 136 (2): 301–321. doi:10.1007/s13358-016-0122-5. S2CID 132449128.

[Anthroosasterias-103] Daniel B. Blake (2017). "Two new Carboniferous Asteroidea (Echinodermata) of the family Urasterellidae". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 284 (1): 65–73. doi:10.1127/njgpa/2017/0652.

[JAESGebelQarara-104] Mohamed Said M. Ali (2017). "Middle Eocene echinoids from Gebel Qarara, Maghagh, Eastern Desert, Egypt". Journal of African Earth Sciences. 133: 46–73. Bibcode:2017JAfES.133...46A. doi:10.1016/j.jafrearsci.2017.04.031.

[JPBrittlestars-105] Timothy A.M. Ewin; Ben Thuy (2017). "Brittle stars from the British Oxford Clay: unexpected ophiuroid diversity on Jurassic sublittoral mud bottoms". Journal of Paleontology. 91 (4): 781–798. Bibcode:2017JPal...91..781E. doi:10.1017/jpa.2016.162. S2CID 132581349.

[106] Patrick D. McDermott; Christopher R. C. Paul (2017). "Ateleocystites? lansae sp. nov. (Mitrata, Anomalocystitidae) from the Upper Ordovician of South Wales". Geological Journal. 52 (1): 1–13. doi:10.1002/gj.2712. S2CID 140153267.

[107] Bálint Polonkai; Andreas Kroh; Ágnes Görög; Ildikó Selmeczi; Mihály Dunai; Emese Réka Bodor (2017). "First occurrence of echinoid genus Brissus in the Badenian (Middle Miocene) of Hungary and description of Brissus mihalyi n. sp". Földtani Közlöny. 147 (4): 383–398. doi:10.23928/foldt.kozl.2017.147.4.383.

[108] Daniel B. Blake; Stephen K. Donovan; David A.T. Harper (2017). "A new Silurian ophiuroid from the west of Ireland" (PDF). Irish Journal of Earth Sciences. 35: 57–66. doi:10.3318/ijes.2017.35.57. S2CID 134782375.

[109] Luis E. Silva-Martínez; Alberto Blanco-Piñón; Jesús A. de León-González; Hidalgo Rodríguez-Vela (2017). "New Echinoid (Spatangoida: Toxasterinidae) from the Campanian of Coahuila, Northeastern Mexico". Boletín de la Sociedad Geológica Mexicana. 69 (2): 371–384. doi:10.18268/BSGM2017v69n2a4.

[Eguadalupensis-110] Jeffrey R. Thompson; Elizabeth Petsios; David J. Bottjer (2017). "A diverse assemblage of Permian echinoids (Echinodermata, Echinoidea) and implications for character evolution in early crown group echinoids". Journal of Paleontology. 91 (4): 767–780. Bibcode:2017JPal...91..767T. doi:10.1017/jpa.2016.158. S2CID 29250459.

[111] Jeffrey R. Thompson; Elizabeth Petsios; Eric H. Davidson; Eric M. Erkenbrack; Feng Gao; David J. Bottjer (2015). "Reorganization of sea urchin gene regulatory networks at least 268 million years ago as revealed by oldest fossil cidaroid echinoid". Scientific Reports. 5: Article number 15541. Bibcode:2015NatSR...515541T. doi:10.1038/srep15541. PMC 4614444. PMID 26486232.

[112] Elise Nardin; Bertrand Lefebvre; Oldřich Fatka; Martina Nohejlová; Libor Kašička; Miroslav Šinágl; Michal Szabad (2017). "Evolutionary implications of a new transitional blastozoan echinoderm from the middle Cambrian of the Czech Republic". Journal of Paleontology. 91 (4): 672–684. Bibcode:2017JPal...91..672N. doi:10.1017/jpa.2016.157. S2CID 132699375.

[113] José Francisco Carrasco (2017). "Primera cita del género Globator (Echinoidea, Eoceno) en España. Nueva especie" (PDF). Batalleria. 25: 8–12.

[Nemus2017-114] Enric Forner i Valls (2017). "Equinoïdeus nous (Echinodermata: Echinoidea) del Campanià de Moyenne Moulouya, nord est del Marroc". Nemus: Revista de l'Ateneu de Natura. 7: 51–72.

[115] Peter Müller; Gerhard Hahn (2017). "Grigopyrgus n. gen., a new agelacrinitid edrioasteroid genus from the Lower Devonian of the Westerwald: (Echinodermata, Rhenish Slate Mountains, Germany)". Mainzer Geowissenschaftliche Mitteilungen. 45: 93–102.

[116] Derek E. G. Briggs; Derek J. Siveter; David J. Siveter; Mark D. Sutton; Imran A. Rahman (2017). "An edrioasteroid from the Silurian Herefordshire Lagerstätte of England reveals the nature of the water vascular system in an extinct echinoderm". Proceedings of the Royal Society B: Biological Sciences. 284 (1862): 20171189. doi:10.1098/rspb.2017.1189. hdl:10044/1/53015. PMC 5597833. PMID 28904139.

[117] Sarah L. Sheffield; William I. Ausich; Colin D. Sumrall (2017). "Late Ordovician (Hirnantian) diploporitan fauna of Anticosti Island, Quebec, Canada: implications for evolutionary and biogeographic patterns". Canadian Journal of Earth Sciences. 55 (1): 1–7. doi:10.1139/cjes-2017-0160. hdl:1807/80500.

[AlcheringaMonostychia-118] Tony Sadler; Sarah K. Martin; Stephen J. Gallagher (2017). "Three new species of the echinoid genus Monostychia Laube, 1869 from Western Australia". Alcheringa: An Australasian Journal of Palaeontology. 41 (4): 464–473. doi:10.1080/03115518.2017.1282979. S2CID 90600580.

[119] Mike Reich; James Sprinkle; Bertrand Lefebvre; Gertrud E. Rössner; Samuel Zamora (2017). "The first Ordovician cyclocystoid (Echinodermata) from Gondwana and its morphology, paleoecology, taphonomy, and paleogeography". Journal of Paleontology. 91 (4): 735–754. Bibcode:2017JPal...91..735R. doi:10.1017/jpa.2017.7. hdl:20.500.12468/709. S2CID 135376365.

[120] Stephen K. Donovan; Fiona E. Fearnhead (2017). "A Lower Devonian hexacrinitid crinoid (Camerata, Monobathrida) from south-west England". PalZ. 91 (2): 217–222. doi:10.1007/s12542-017-0344-x. S2CID 134913415.

[JPAZachos-121] Louis G. Zachos (2017). "Paleocene echinoid faunas of the eastern United States". Journal of Paleontology. 91 (5): 1001–1024. Bibcode:2017JPal...91.1001Z. doi:10.1017/jpa.2017.22. S2CID 134191333.

[Paerticrinus-122] David F. Wright; Ursula Toom (2017). "New crinoids from the Baltic region (Estonia): fossil tip-dating phylogenetics constrains the origin and Ordovician–Silurian diversification of the Flexibilia (Echinodermata)". Palaeontology. 60 (6): 893–910. doi:10.1111/pala.12324.

[123] S.V. Rozhnov; R.L. Parsley (2017). "A new cornute (Homalozoa: Echinodermata) from the Uppermost Middle Cambrian (Stage 3, Furongian) from northern Iran: its systematics and functional morphology". Paleontological Journal. 51 (5): 500–509. doi:10.1134/S0031030117050100. S2CID 133862520.

[JPPetalocrinidae-124] Yingyan Mao; William I. Ausich; Yue Li; Jih-Pai Lin; Caihua Lin (2017). "New taxa and phyletic evolution of the Aeronian (Llandovery, Silurian) Petalocrinidae (Echinodermata, Crinoidea) in Guizhou, South China Block". Journal of Paleontology. 91 (3): 477–492. Bibcode:2017JPal...91..477M. doi:10.1017/jpa.2016.156. S2CID 91044529.

[125] David R. Cordie; Brian J. Witzke (2017). "A New Crinoid Genus from the Middle Devonian of Iowa, USA (Camerata, Melocrinitidae)". Paleontological Research. 21 (1): 7–13. doi:10.2517/2016PR014. S2CID 132181687.

[126] Samuel Zamora; Colin D. Sumrall; Xue-Jian Zhu; Bertrand Lefebvre (2017). "A new stemmed echinoderm from the Furongian of China and the origin of Glyptocystitida (Blastozoa, Echinodermata)". Geological Magazine. 154 (3): 465–475. Bibcode:2017GeoM..154..465Z. doi:10.1017/S001675681600011X. hdl:20.500.12468/771. S2CID 131161649.

[127] Peter Müller; Gerhard Hahn (2017). "Edrioasteroidea from the Seifen Formation of the Westerwald, Rhenish Slate Mountains (Lower Devonian, Germany), part 2: Sumrallia rseiberti gen. et sp. nov". PalZ. 91 (4): 629–639. doi:10.1007/s12542-017-0356-6. S2CID 135233073.

[128] Loïc Villier; Arnaud Brayard; Kevin G. Bylund; James F. Jenks; Gilles Escarguel; Nicolas Olivier; Daniel A. Stephen; Emmanuelle Vennin; Emmanuel Fara (2017). "Superstesaster promissor gen. et sp. nov., a new starfish (Echinodermata, Asteroidea) from the Early Triassic of Utah, USA, filling a major gap in the phylogeny of asteroids" (PDF). Journal of Systematic Palaeontology. 16 (5): 395–415. doi:10.1080/14772019.2017.1308972. S2CID 89854727.

[129] Aaron W. Hunter; Kenneth J. McNamara (2017). "Prolonged co-existence of 'archaic' and 'modern' Palaeozoic ophiuroids – evidence from the early Permian, Southern Carnarvon Basin, Western Australia". Journal of Systematic Palaeontology. 16 (11): 891–907. doi:10.1080/14772019.2017.1353549. S2CID 135162886.

[130] Didier Néraudeau; Jean-Pierre Pineau; Jean-Christophe Dudicourt; Patrice Raboeuf (2017). "Ulphaceaster sarthacensis, nouveau genre et nouvelle espèce d'échinide Archiaciidae du Cénomanien (Sarthe, France)". Annales de Paléontologie. 103 (1): 87–91. Bibcode:2017AnPal.103...87N. doi:10.1016/j.annpal.2017.01.002.

[131] Nils Schlüter; Frank Wiese (2017). "Late Cretaceous species of Vologesia (Echinoidea, Cassiduloida) from northern Spain". Zootaxa. 4306 (2): 261–270. doi:10.11646/zootaxa.4306.2.6.

[132] Emilia Jarochowska; Viive Viira; Rein Einasto; Rafał Nawrot; Oskar Bremer; Peep Männik; Axel Munnecke (2017). "Conodonts in Silurian hypersaline environments: Specialized and unexpectedly diverse". Geology. 45 (1): 3–6. Bibcode:2017Geo....45....3J. doi:10.1130/G38492.1. S2CID 131974217.

[133] Muhui Zhang; Haishui Jiang; Mark A. Purnell; Xulong Lai (2017). "Testing hypotheses of element loss and instability in the apparatus composition of complex conodonts: articulated skeletons of Hindeodus". Palaeontology. 60 (4): 595–608. Bibcode:2017Palgy..60..595Z. doi:10.1111/pala.12305. hdl:2381/40480.

[134] Sachiko Agematsu; Martyn L. Golding; Michael J. Orchard (2018). "Comments on: Testing hypotheses of element loss and instability in the apparatus composition of complex conodonts (Zhang et al.)". Palaeontology. 61 (5): 785–792. Bibcode:2018Palgy..61..785A. doi:10.1111/pala.12372.

[135] Mark A. Purnell; Muhui Zhang; Haishui Jiang; Xulong Lai (2018). "Reconstruction, composition and homology of conodont skeletons: a response to Agematsu et al.". Palaeontology. 61 (5): 793–796. Bibcode:2018Palgy..61..793P. doi:10.1111/pala.12387. hdl:2381/42406.

[GJCordilleraconodonts-136] Gustavo G. Voldman; Guillermo L. Albanesi; Gladys Ortega; María Eugenia Giuliano; Carlos Ruben Monaldi (2017). "New conodont taxa and biozones from the Lower Ordovician of the Cordillera Oriental, NW Argentina". Geological Journal. 52 (3): 394–414. doi:10.1002/gj.2766. S2CID 131460368.

[Aldridgeognathus-137] C. Giles Miller; Alan P. Heward; Angelo Mossoni; Ivan J. Sansom (2017). "Two new early balognathid conodont genera from the Ordovician of Oman and comments on the early evolution of prioniodontid conodonts" (PDF). Journal of Systematic Palaeontology. 16 (7): 571–593. doi:10.1080/14772019.2017.1314985. S2CID 134576678.

[138] Till Söte; Sven Hartenfels; Ralph Thomas Becker (2017). "Uppermost Famennian stratigraphy and facies development of the Reigern Quarry near Hachen (northern Rhenish Massif, Germany)". Palaeobiodiversity and Palaeoenvironments. 97 (3): 633–654. doi:10.1007/s12549-017-0287-y. S2CID 134615450.

[Lugnathus-139] ^ a b c d e f g h i j k l m n Xi-ping Dong; Huaqiao Zhang (2017). "Middle Cambrian through lowermost Ordovician conodonts from Hunan, South China". Journal of Paleontology. 91 (S73): 1–89. Bibcode:2017JPal...91S...1D. doi:10.1017/jpa.2015.43.

[PJ5110-140] N. S. Ovnatanova; L. I. Kononova; L. S. Kolesnik; Yu. A. Gatovsky (2017). "Upper Devonian conodonts of northeastern European Russia". Paleontological Journal. 51 (10): 973–1165. doi:10.1134/S003103011710001X. S2CID 90202627.

[141] Fernanda Serra; Nicolás A. Feltes; Miles A. Henderson; Guillermo L. Albanesi (2017). "Darriwilian (Middle Ordovician) conodont biofacies from the Central Precordillera of Argentina". Marine Micropaleontology. 130: 15–28. Bibcode:2017MarMP.130...15S. doi:10.1016/j.marmicro.2016.12.002. hdl:11336/44643.

[Guexispathodus-142] Pablo Plasencia; Ali Murat Kiliç; Aymon Baud; Milan Sudar; Francis Hirsch (2017). "The evolutionary trend of platform-denticulation in Middle Triassic Acuminate Gondolellidae (Conodonta)". Turkish Journal of Zoology. 42 (2): 187–197. doi:10.3906/zoo-1708-20.

[PPPTieqiaosection-143] Y.D. Sun; X.T. Liu; J.X. Yan; B. Li; B. Chen; D.P.G. Bond; M.M. Joachimski; P.B. Wignall; X. Wang; X.L. Lai (2017). "Permian (Artinskian to Wuchapingian) conodont biostratigraphy in the Tieqiao section, Laibin area, South China" (PDF). Palaeogeography, Palaeoclimatology, Palaeoecology. 465, Part A: 42–63. Bibcode:2017PPP...465...42S. doi:10.1016/j.palaeo.2016.10.013.

[144] Felix Lüddecke; Sven Hartenfels; Ralph Thomas Becker (2017). "Conodont biofacies of a monotonous middle Famennian pelagic carbonate succession (Upper Ballberg Quarry, northern Rhenish Massif)". Palaeobiodiversity and Palaeoenvironments. 97 (3): 591–613. doi:10.1007/s12549-017-0288-x. S2CID 134191571.

[145] Thomas J. Suttner; Erika Kido; Andreas W. W. Suttner (2017). "Icriodus marieae, a new icriodontid conodont species from the Middle Devonian". PalZ. 91 (1): 137–144. doi:10.1007/s12542-017-0337-9. PMC 5445598. PMID 28615752.

[146] Nicholas J. Hogancamp; James E. Barrick (2017). "Ungrooved species of Idiognathodus from the lower Gzhelian (Pennsylvanian) Heebner Shale, Midcontinent North America, U.S.A." Micropaleontology. 62 (5): 385–53. Bibcode:2017MiPal..62..385H. doi:10.47894/mpal.62.5.04. S2CID 248382981.

[147] Cassiane Negreiros Cardoso; Javier Sanz-López; Silvia Blanco-Ferrera (2017). "Pennsylvanian conodonts from the Tapajós Group (Amazonas Basin, Brazil)". Geobios. 50 (2): 75–95. Bibcode:2017Geobi..50...75C. doi:10.1016/j.geobios.2017.02.004.

[148] Ke-Yi Hu; Yu-Ping Qi; Qiu-Lai Wang; Tamara I. Nemyrovska; Ji-Tao Chen (2017). "Early Pennsylvanian conodonts from the Luokun section of Luodian, Guizhou, South China". Palaeoworld. 26 (1): 64–82. doi:10.1016/j.palwor.2015.12.003.

[149] Huaibao P. Liu; Stig M. Bergström; Brian J. Witzke; Derek E. G. Briggs; Robert M. McKay; Annalisa Ferretti (2017). "Exceptionally preserved conodont apparatuses with giant elements from the Middle Ordovician Winneshiek Konservat-Lagerstätte, Iowa, USA". Journal of Paleontology. 91 (3): 493–511. Bibcode:2017JPal...91..493L. doi:10.1017/jpa.2016.155. hdl:11380/1114523. S2CID 132698401.

[Lenathodus-150] Nadezhda Izokh; Aleksandr Yazikov (2017). "Discovery of Early Carboniferous conodonts in Northern Kharaulakh Ranges (lower reaches of the Lena River, northeastern Siberia, Arctic Russia)". Revue de Micropaléontologie. 60 (2): 213–232. Bibcode:2017RvMic..60..213I. doi:10.1016/j.revmic.2017.03.001.

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