Brachyrhizodus wichitaensis

Romer, 1942


Classification: Euchondrocephali incert. sedis incert. fam.

Reference of the original description
Romer, A.S. (1942)
Notes on certain American Paleozoic fishes. American Journal of Science, 240, 216–228

Synonyms / new combinations and misspellings
Brachyrhizodus cf. wichitaensis

Types
Brachyrhizodus wichitaensis



Description:


Citation: Brachyrhizodus wichitaensis Romer, 1942: In: Database of fossil elasmobranch teeth www.shark-references.com, World Wide Web electronic publication, Version 12/2024

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Remarks
shark-references Species-ID=613;
valid after Hoganson et al. (2019) p. 42 [27441]; Case et al. (2019) p. 78 [27568];


References
Schnetz, L. & Dunne, E.M. & Feichtinger, I. & Butler, R.J. & Coates, M.I. & Sansom, I.J. (2024)
Rise and diversification of chondrichthyans in the Paleozoic. Paleobiology, in press
DOI: 10.1017/pab.2024.1
Ebersole, J.A. & Cicimurri, D.J. & Stringer, G.L. & Jacquemin, S.J. & Ciampaglio, C.N. (2024)
Cretaceous Fishes of Alabama, Brachyrhizodus version 1. In J.A. Ebersole (ed.), Fossil Fishes of Alabama. McWane Science Center, Birmingham, Alabama 3(38), 1–6
DOI: 10.69737/MJQX9394
Guinot, G. & Condamine, F.L. (2023)
Global impact and selectivity of the Cretaceous-Paleogene mass extinction among sharks, skates, and rays. Science, 379, 802–806
DOI: 10.1126/science.abn2080
Timmerman, J. & Chandler, R.E. (2019)
Cretaceous and Paleogene Fossils of North Carolina, A Field Guide. North Carolina Fossil Club, Durham, 70 p. 2019 Edition
Case, G.R. & Cook, T.D. & Kightlinger, T. & Borodin, P.D. (2019)
Middle Campanian Euselachian Diversity of the Southern Region of the Atlantic Coastal Plain of North America. Vertebrate Anatomy Morphology Palaeontology, 7, 69–82
DOI: 10.18435/vamp29345
Schubert, J.A. & Wick, S.L. & Lehman, T.M. (2017)
An Upper Cretaceous (middle Campanian) marine chondrichthyan and osteichthyan fauna from the Rattlesnake Mountain sandstone member of the Aguja Formation in West Texas. Cretaceous Research, 69, 6–33
DOI: 10.1016/j.cretres.2016.08.008
Callahan, W.R. & Mehling, C.M. & Denton, R.K. & Parris, D.C. (2014)
Vertebrate Paleontology and Stratigraphy of the Late Cretaceous Holmdel Park Site, Monmouth County, New Jersey. Dakoterra, 6: 163–169
Ikejiri, T. & Ebersole, J.A. & Blewitt, H.L. & Ebersole, S.M. (2013)
An overview of Late Cretaceous vertebrates from Alabama. Bulletin of the Alabama Museum of Natural History, 31(1), 46–66
Enault, S. & Cappetta, H. & Adnet, S. (2013)
Simplification of the enameloid microstructure of large stingrays (Chondrichthyes: Myliobatiformes): a functional approach. Zoological Journal of the Linnean Society, 169(1), 144–155
DOI: 10.1111/zoj.12059
Ciampaglio, C.N. & Cicimurri, D.J. (2012)
Elasmobranch and osteichthyan diversity from two late cretaceous (late campanian) transgressive lag deposits along the Neuse River, Lenoir County, North Carolina [Abstract]. Journal of Vertebrate Paleontology, 32(Suppl. 1), 79
DOI: 10.1080/02724634.2012.10635175
Ginter, M. & Hampe, O. & Duffin, C.J. (2010)
Handbook of Paleoichthyology, Vol. 3D: Chondrichthyes Paleozoic Elasmobranchii: Teeth Verlag Dr. Friedrich Pfeil, pp. 168, 154 fig., 4 Tab.
Claeson, K.M. & O'Leary, M.A. & Roberts, E.M. & Sissoko, F. & Bouaré, M. & Tapanila, L. & Goodwin, D. & Gottfried, M.D. (2010)
First Mesozoic Record of the Stingray Myliobatis wurnoensis from Mali and a Phylogenetic Analysis of Myliobatidae Incorporating Dental Characters. Acta Palaeontologica Polonica, 55(4), 655–674
DOI: 10.4202/app.2009.1117
Timmerman, J. & Chandler, R.E. (2008)
Cretaceous and Paleogene Fossils of North Carolina, A Field Guide. North Carolina Fossil Club, Durham, 70 p.
Becker, M.A. & Earley, R.J. & Chamberlain, J.A. (2002)
A Survey of Non-tooth Chondrichthian Hard-parts from the Lower Navesink formation (Maastrichtian) in Monmouth County, New Jersey. Northeastern Geology and Environmental Science, 24(4), 282–292
Antunes, M.T. & Cappetta, H. (2002)
Sélaciens du Crétacé (Albien-Maastrichtien) d'Angola. Palaeontographica, Abt. A, 264(5–6), 85–146
Becker, M.A. & Chamberlain, J.A. & Stoffer, P.W. (2000)
Pathologic tooth deformities in modern and fossil chondrichthians: a consequence of feeding-related injury. Lethaia, 33(2), 103–118
DOI: 10.1080/00241160050150249
Becker, M.A. & Slattery, W. & Chamberlain, J.A. (1998)
Mixing of Santonian and Campanian chondrichthyan and ammonite macrofossils along a transgressive lag deposit, Greene County, western Alabama. Southeastern Geology, 37(4), 205–216
Case, G.R. (1995)
Fossil shark remains from the early and middle Maastrichtian of the Upper Cretaceous of Monmouth County, New Jersey. In J. Baker(ed.), Contributions to the Paleontology of New Jersey. Geological Association of New Jersey 12: 72–80
Welton, B.J. & Farish, R.F. (1993)
The collector's guide to fossil sharks and rays from the Cretaceous of Texas. Before Time, Lewisville, 1993
Manning, E.M. & Dockery, D.T. (1992)
A guide to the Frankstown vertebrate fossil locality (Upper Cretaceous), Prentiss County, Mississippi. Mississippi Department of Environmental Quality, Office of Geology, Circular 4: 43pp
Robb, A.J. (1989)
The Upper Cretaceous (Campanian, Black Creek Formation) fossil fish fauna of Pheobus Landing, Bladen County, North Carolina. Mosasaur, 4, 75–92
Case, G.R. & Schwimmer, D.R. (1988)
Late Cretaceous fish from the Blufftown Formation (Campanian) in western Georgia. Journal of Paleontology, 62(2), 290–301
Lauginiger, E.M. & Hartstein, E.F. (1983)
A guide to fossil sharks, skates, and rays from the Chesapeake and Delaware Canal area, Delaware. Open File Report, 21, 6–95
Case, G.R. (1979)
Collecting fossil shark's teeth at Big Brook, Monmouth County, New Jersey. Bulletin of the Bergen County Mineral and Paleontological Society, 13(5), 12–14
Cappetta, H. & Case, G.R. (1975)
Contribution à l'étude des Sélaciens du groupe Monmouth (Campanien-Maestrichtien) du New Jersey. Palaeontographica, Abt. A, 151(1–3), 1–46
Romer, A.S. (1942)
Notes on certain American Paleozoic fishes. American Journal of Science, 240, 216–228