Disarticulation and Preservation of Fossil Echinoderms: Recognition of Ecological-Time Information in the Echinoderm Fossil Record

William I. Ausich

doi:10.1017/9781108893374

Series: Elements of Paleontology

Disarticulation and Preservation of Fossil Echinoderms: Recognition of Ecological-Time Information in the Echinoderm Fossil Record

Published online by Cambridge University Press: 09 February 2021

William I. Ausich

Show author details

William I. Ausich: Affiliation:
Ohio State University

Summary

The history of life on earth is largely reconstructed from time-averaged accumulations of fossils. A glimpse at ecologic-time attributes and processes is relatively rare. However, the time-sensitive and predictability of echinoderm disarticulation makes them model organisms to determine post-mortem transportation and allows recognition of ecological-time data within paleocommunity accumulations. Unlike many other fossil groups, this has allowed research on many aspects of echinoderms and their paleocommunities, such as the distribution of soft tissues, assessment of the amount of fossil transportation prior to burial, determination of intraspecific variation, paleocommunity composition, estimation of relative abundance of taxa in paleocommunities, determination of attributes of niche differentiation, etc. Crinoids and echinoids have received the most amount of taphonomic research, and the patterns present in these two groups can be used to develop a more thorough understanding of all echinoderm clades.

Element contents

Summary
References

Get access

Keywords

Echinodermata taphonomy preservation paleoecology crinoid echinoid asteroid ophiuroid

Type: Element
Information: Series: Elements of Paleontology

DOI: https://doi.org/10.1017/9781108893374 [Opens in a new window]

Online ISBN: 9781108893374

Publisher: Cambridge University Press

Print publication: 11 February 2021

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Adkins, W. S. (1928). Handbook of Texas Cretaceous fossils. University of Texas Bulletin, 2838Google Scholar

Aigner, T. (1985). Storm depositional systems: Dynamic stratigraphy in modern and ancient shallow-marine sequences. Lecture Notes in the Earth Sciences, 3, New York, Springer-Verlag.Google Scholar

Allison, P. A. (1990). Variation in rates of decay and disarticulation of Echinodermata: Implications for the application of actualistic data. PALAIOS, 5, 432–440.CrossRef Google Scholar

Aronson, R. B. (1987). Predation on fossil and Recent ophiuroids. Paleobiology, 13, 187–192.CrossRef Google Scholar

Aronson, R. B., & Blake, D. B. (1997). Evolutionary paleoecology of dense ophiuroids populations. In Waters, J. A. & Maples, C. G., eds., Geobiology of Echinoderm. Paleontological Society Papers, 3, pp. 107–119.CrossRef Google Scholar

Aslin, C. J. (1968). Echinoid preservation in Upper Estuarine Limestone of Blisworth Northamptonshire. Geological Magazine, 105, 506–518.Google Scholar

Ausich, W. I. (1977). The functional morphology and evolution of Pisocrinus (Crinoidea: Silurian). Journal of Paleontology, 51, 672–686.Google Scholar

Ausich, W. I. (1980). A model for niche differentiation in Lower Mississippian crinoid communities. Journal of Paleontology, 54, 273–288.Google Scholar

Ausich, W. I. (1983). Functional morphology and feeding dynamics of the Early Mississippian crinoid Barycrinus asteriscus. Journal of Paleontology, 57, 31–41.Google Scholar

Ausich, W. I. (1997). Regional encrinites: A vanished lithofacies. In Brett, C. E. and Baird, G. C., eds., Paleontological Events: Stratigraphic, Ecologic and Evolutionary Implications. New York: Columbia University Press, pp. 509–519.Google Scholar

Ausich, W. I. (2001). Echinoderm taphonomy. In Lawrence, J. and Jangoux, M., eds., Echinoderm Studies, Vol. 6. Rotterdam: A. A. Balkema Press, pp. 171–227.Google Scholar

Ausich, W. I. (2016). Fossil species as data: A perspective from echinoderms. In Allmon, W. D. & Yacobucci, M. M., eds., Species and Speciation in the Fossil Record. Chicago, IL: University of Chicago Press, pp. 301–311.Google Scholar

Ausich, W. I. , & Baumiller, T. K. (1993a). Taphonomic method for determining muscular articulations in fossil crinoids. PALAIOS, 8, 477–484.CrossRef Google Scholar

Ausich, W. I., & Baumiller, T. K. (1993b). Column regeneration in an Ordovician crinoid (Echinodermata): Paleobiologic implications. Journal of Paleontology, 67, 1068–1070.CrossRef Google Scholar

Ausich, W. I. , & Baumiller, T. K. (1998). Disarticulation patterns in Ordovician crinoids: Implications for the evolutionary history of connective tissue in the Crinoidea. Lethaia, 31: 113–123.Google Scholar

Ausich, W. I. , & Bottjer, D. J. (1982). Tiering in suspension-feeding communities on soft substrata throughout the Phanerozoic. Science, 216, 173–174.CrossRef Google Scholar PubMed

Ausich, W. I. , & Lane, N. G. (1980). Platform communities and rocks of the Borden Siltstone Delta (Mississippian) along the south shore of Monroe Reservoir, Monroe County, Indiana. In Shaver, R. H., ed., Field Trips 1980 from the Indiana University Campus, Bloomington: Indiana University, pp. 36–67.Google Scholar

Ausich, W. I. , & Meyer, D. L. (1990). Origin and composition of carbonate buildups and associated facies in the Fort Payne Formation (Lower Mississippian, south-central Kentucky): An integrated sedimentologic and paleoecologic analysis. Geological Society of America Bulletin, 102, 129–146.Google Scholar

Ausich, W. I. , & Sevastopulo, G. D. (1994). Taphonomy of Lower Carboniferous crinoids from the Hook Head Formation, Ireland. Lethaia, 27, 245–256.Google Scholar

Balaústegui, Z, Muñiz, F., Nebelsick, J. H., Domènech, R., & Martinell, J. (2012). Echinoderm ichnology: Bioturbation, bioerosion and related processes. Journal of Paleontology, 91, 643–661.Google Scholar

Bantz, H. –U. (1969). Echinoidea uns Plattenkalken der Altmühlabhre Biostratyinomie. Erlanger Geologische Abhandlunge, 78, 1–35.Google Scholar

Bathurst, R. G. C. (1976). Carbonate Sediments and Their Diagensis, 2nd ed. Amsterdam: Elsevier.Google Scholar

Baumiller, T. K. (2003). Experimental and biostratinomic disarticulation of crinoids: Taphonomic implications In Echinoderm Research 2001. In Féral, J.-P. & David, B., eds., Paleontological Events: Stratigraphic, Ecologic, and Evolutionary Implications. Lisse: Swets and Zietlinger, pp. 243–248.Google Scholar

Baumiller, T. K. (2008). Crinoid ecological morphology. Annual Reviews in the Earth Sciences, 36, 221–249.CrossRef Google Scholar

Baumiller, T. K., & Ausich, W. I. (1992). The “broken stick” model as a null hypothesis for crinoid stalk taphonomy and as a guide to the distribution of connective tissues in fossils. Paleobiology, 18, 288–298.Google Scholar

Baumiller, T. K. , & Hagdorn, H. (1995). Taphonomy as a guide to functional morphology of Holocrinus, the first post-Paleozoic crinoid. Lethaia, 28, 221–228.Google Scholar

Baumiller, T. K., Gahn, F. J., Hess, H. , & Messing, C. G. (2008). Taphonomy as an indicator of behavior among fossil crinoid. In Ausich, W. I. & Webster, G. D., eds., Echinoderm Paleobiology, Bloomington: Indiana University Press, pp. 7–20.Google Scholar

Baumiller, T. K., Llewellyn, G., Messing, C. G., & Ausich, W. I. (1995). Taphonomy and autotomy of isocrinid stalks: Influence of decay and autotomy. Palaios, 10, 87–95.Google Scholar

Bell, B. M. (1976). A study of North American Edrioasteroidea. New York State Museum Memoir, 21, 447 p.Google Scholar

Bernardi, M., Boschele, S., Ferretti, P., & Avanzini, M. (2010). Echinoid burrow Bichordites monastiriensis from the Oligocene of NE Italy. Acta Palaeontologica Polonica, 55, 479–486.Google Scholar

Birkenmajer, K. (1977). Jurassic and Cretaceous lithostratigraphic unites of the Leinny Klippen Belt, Carpathians, Poland. Studia Geologica Polonica, 45, 1–158.Google Scholar

Blake, D. B. (1967). Pre-burial abrasion of articulated asteroid skeletons. Paleobios, 2, 4 p.Google Scholar

Blake, D. B. (1975). A new west American Miocene species of the modern Australian ophiuroids. Ophiocrassota. Journal of Paleontology, 49, 501–506.Google Scholar

Blake, D. B., & Zinsmeister, W. J. (1979). Two early Cenozoic sea stars (Class Asteroidea) from Seymour Island, Antarctica Peninsula. Journal of Paleontology, 53, 1145–1154.Google Scholar

Blake, D. B., Guensburg, T. E., Sprinkle, J. , & Sumrall, C. D. (2007). A new phylogenetically significant Early Ordovician asteroid (Echinodermata). Journal of Paleontology, 81, 1100–1101.Google Scholar

Blumer, M. (1951). Fossile Kohlenwassertoffe und Farbstoffe in Kalketeinen. Mikrochemie, 36/37, 1048–1055CrossRef Google Scholar

Blumer, M. (1960). Pigments of a fossil echinoderm. Nature, 188, 1100–1101.Google Scholar

Blumer, M. (1962a). The organic chemistry of a fossil – I: The structure of fringelite-pigments. Geochimica et Cosmochimica Acta, 26, 225–227.CrossRef Google Scholar

Blumer, M. (1962b). The organic chemistry of a fossil – II: Some rare polynuclear hydrocarbons. Geochimica et Cosmochimica Acta, 26, 228–230.Google Scholar

Blumer, M. (1965). Organic pigments: Their long-term fate. Science, 149, 722–726.Google Scholar

Blyth Cain, J. D. (1968). Aspects of the depositional environment and paleoecology of crinoidal limestones. Scottish Journal of Geology, 4, 191–208.Google Scholar

Bottjer, D. J. , & Ausich, W. I.. (1987). Phanerozoic development of tiering in soft substrata suspension-feeding communities. Paleobiology 12, 400–420.Google Scholar

Breton, G. (1997). Deux étoiles de mer du Bajocien du nord-est du basin de Paris (France): leur allies actuels sond des fossils vivants. Bulletin trimestriel de la Société Géologique de Normandie et des Amis du Museum du Havre, 84, 23–34.Google Scholar

Brett, C. E. (1985). Pelmatozoan echinoderms on Silurian bioherms in western New York and Ontario. Journal of Paleontology, 59, 820–838.Google Scholar

Brett, C. E. (1995). Sequence stratigraphy, biostratigraphy, and taphonomy in shallow marine environments. PALAIOS, 10, 597–616.Google Scholar

Brett, C. E., & Baird, G. (1986). Comparative taphonomy: A key to paleoenvironmental interpretation based on fossil preservation. PALAIOS, 1, 207–227.Google Scholar

Brett, C. E., & Baird, G. (1997). Epiboles, outages, and ecological evolutionary bioevents: Taphonomy, ecological, and biogeographic factors. In Brett, C. E. & Baird, G., eds., Paleontological Events: Stratigraphic, Ecologic, and Evolutionary Implications. New York: Columbia University Press, pp. 249–284.Google Scholar

Brett, C. E., & Liddell, W. D. (1978). Preservation and paleoecology of a Middle Ordovician hardground community. Paleobiology, 4, 329–348.Google Scholar

Brett, C. E., & Seilacher, A. (1991). Fossil-Lagerstätten: a taphonomic consequence of event sedimentation. In Einsele, G., Ricken, W. & Seilacher, A., eds., Cycles and Events in Stratigraphy. New York, Berlin: Springer Verlag, pp. 283–297.Google Scholar

Brett, C. E., & Taylor, W. L. (1997). The Homocrinus beds: Silurian Lagerstätten of western New York and southern Ontario. In Brett, C. E. & Baird, G., eds., Paleontological Events: Stratigraphic, Ecologic, and Evolutionary Implications. New York: Columbia University Press, pp. 181–499.Google Scholar

Brett, C. E., Deline, B. L., & McLaughlin, P. I. (2008). Attachment, facies distribution, and life history strategies in crinoids from the Upper Ordovician of Kentucky. In Ausich, W. I. & Webster, G. D., eds., Echinoderm Paleobiology. Bloomington: Indiana University Press, pp. 23–52.Google Scholar

Brett, C. E., Dick, V. E., & Baird, G. C. (1991). Comparative taphonomy and paleoecology of Middle Devonian dark gray and black shale facies from Western New York. In E. Landing & C. E. Brett, eds., Dynamic Stratigraphy and Depositional Environments of the Hamilton Group (Middle Devonian) in New York State, Part II. New York State Museum Bulletin, 469, pp. 5–36.Google Scholar

Brett, C. E., Moffat, H. A., & Taylor, W. L. (1997). Echinoderm taphonomy, taphofacies, and Lagerstätten. In J. A. Waters & C. G. Maples, eds., Geobiology of Echinoderms. Paleontological Society Papers, 3, p147–190.CrossRef Google Scholar

Bridges, P. H., Gutteridge, P., & Pickard, N. A. H. (1995). The environmental setting of Early Carboniferous mud-mounds. In Monty, C. L. V., Bosence, D. W. J., Bridges, P. H. & Pratt, B. R., eds., Carbonate Mud-mounds Their Origin and Evolution. Oxford: Blackwell Science, pp. 171–190.CrossRef Google Scholar

Bromley, R. G., & Ekdale, A. A. (1986). Composite ichnofabrics and tiering of burrows. Geological Magazine, 123, 59–65.Google Scholar

Brower, J. C. (1974). Crinoids from the Girardeau Limestone (Ordovician). Palaeontographica Americana, 7, 259–499.Google Scholar

Brower, J. C., & Veinus, J. (1978). Middle Ordovician crinoids from the Twin Cities area of Minnesota. Bulletins of American Paleontology, 74, 369–506.Google Scholar

Carozzi, A. V., & Soderman, J. G. (1962). Petrography of Mississippian (Borden) crinoidal limestones at Stobo, Indiana. Journal of Sedimentary Petrology, 32, 397–414.Google Scholar

Cassa, M. R., & Kissling, D. L. (1982). Carbonate facies of the Onondaga and Boise Blanc Formations Niagara Peninsula, Ontario. In Buehler, E. J. & Calkin, P. E., eds., Guidebook for Field Trips in Western New York, Northern Pennsylvania, and Adjacent Southern Ontario. New York State Geological Association 54th Annual Meeting, 55–97. Rocky Mountain Paleogeography Symposium I, Paleozoic Paleogeography of the West-Central United States, pp. 111–128.Google Scholar

Cole, S. R. (2017). Phylogeny and morphologic evolution of the Ordovician Camerata (Class Crinoidea, Phylum Echinodermata). Journal of Paleontology, 91, 815–828.Google Scholar

Cole, S. R. (2018). Phylogeny and evolutionary history of diplobathrid crinoids (Echinodermata). Palaeontology, 62, 357–373.Google Scholar

Cole, S. R. (2019). Hierarchical controls on extinction selectivity across the diplobathrid crinoid phylogeny. Paleobiology, doi: https://doi.org/10.1017/pab.2019.37.Google Scholar

Cole, S. R., Wright, D. W., & Ausich, W. I. (2019). Phylogenetic community paleoecology of one of the earliest complex crinoid faunas (Brechin Lagerstätte, Ordovician). Palaeogeography, Palaeoclimatology, Palaeoecology, 521, 82–98.CrossRef Google Scholar

Cornell, S. R., Brett, C. E., & Sumrall, C. D. (2003). Paleoecology and taphonomy of an edrioasteroid-dominated hardground association from tentaculitid limestones in the Early Devonian of New York: A Paleozoic rocky peritidal community. PALAIOS, 18, 212–224.2.0.CO;2>CrossRef Google Scholar

Desrocher, A. (2006). Rocky shoreline deposits in the Lower Silurian (upper Llandovery, Telychian) Chicotte Formation, Anticosti Island, Quebec. Canadian Journal of Earth Sciences, 43, 1205–1214.Google Scholar

Dickson, J. A. D. (1995). Paleozoic Mg calcite preserved: Implications for the Carboniferous ocean. Geology, 23, 535–538.Google Scholar

Dickson, J. A. D. (2001a). Diagenesis and crystal caskets: Echinoderm Mg calcite transformation. Dry Canyon, New Mexico, U.S.A. Journal of Sedimentary Research, 71, 764–777.Google Scholar

Dickson, J. A. D. (2001b). Transformation of echinoid Mg calcite skeletons by heating. Geochimica, Geocosmochimica, Acta, 65, 443–454.CrossRef Google Scholar

Dickson, J. A. D. (2002). Fossil echinoderms as monitor of the Mg/Ca ratio of Phanerozoic oceans. Science, 298, 1222–1224.Google Scholar

Dickson, J. A. D. (2004). Echinoderm skeletal preservation: Calcite-aragonite seas and the Mg/Ca ratio of Phanerozoic oceans. Journal of Sedimentary Research, 74, 355–365.Google Scholar

Dickson, J. A. D. (2009). Mississippian paleocean chemistry from biotic and abiotic carbonate, Muleshoe Mound, Lake Valley Formation, New Mexico, U.S.A. – discussion. Journal of Sedimentary Research, 79, 40–41.Google Scholar

Donovan, S. K. (1991). Taphonomy of echinoderms: Calcareous multi-element skeletons in the marine environment. In Donovan, S. K., ed., The Process of Fossilization. London: Belhaven, pp. 241–269.Google Scholar

Donovan, S. K., & Pawson, D. L. (1997). Proximal growth of the column in bathycrinid crinoids (Echinodermata) following decapitation. Bulletin of Marine Science, 61, 571–579.Google Scholar

Donovan, S. K., & Schmidt, D. A. (2001). Survival of crinoid stems following decapitation: Evidence from the Ordovician and palaeobiological implications. Lethaia, 34, 263–370.CrossRef Google Scholar

Durham, J. W. (1978). Polymorphism in the Pliocene sand dollar Merriamaster (Echinodermata). Journal of Paleontology, 52, 275–286.Google Scholar

Durham, J. W. (1993). Observations on the Early Cambrian helicoplacoid echinoderms. Journal of Paleontology, 67, 590–604.CrossRef Google Scholar

Emson, R. H., & Wilkie, I. C. (1980). Fission and autotomy in echinoderms. Oceanography and Marine Biology, 18, 155–250.Google Scholar

Franzén, C. (1982). A Silurian crinoid thanatotope from Gotland. Geologiska Föreningens i Stockholm Förhandlingar, 103, 469–490.Google Scholar

Ginsburg, R. N. (2005). Disobedient sediments can feedback on their transportation, deposition, and geomorphology. Sedimentary Geology, 175, 9–18.Google Scholar

Gahn, F. J., & Baumiller, T. K. (2004). A bootstrap analysis for comparative taphonomy as applied to Early Mississippian (Kinderhookian) crinoids from the Wassonville cycle of Iowa. PALAIOS, 19, 17–38.2.0.CO;2>CrossRef Google Scholar

Gale, A. S. (1986). Goniasteridae (Asteroidea, Echinodermata) from the Late Cretaceous of north-west Europe. I. Introduction. The genera Metopaster and Recurvaster. Mesozoic Research, 1, 1–69.Google Scholar

Glass, A. (2005). Two isorophid edrioasteroids (Echinodermata) encrusting conularids from the Hunsrück Slate (Lower Devonian, Emsian; Rheinisches Schiefergebirge) of Germany. Senckenbergiana lethaea, 85, 31–37.Google Scholar

Glynn, P. W. (1984). An amphionid worm predator of the crown-of-thorns sea star and general predation on asteroids in eastern and western Pacific coral reefs. Bulletin of Marine Science, 35, 54–71.Google Scholar

Goldring, R., & Laggenstrassen, F. (1979). Open shelf and near-shore clastic facies in the Devonian. Special Papers in Palaeontology, 23, 81–97.Google Scholar

Goldring, B., & Stephenson, D. G. (1972). The depositional environment of three starfish beds. Neues Jahrbuch für Geologie und Paläontologie – Abhandlungen, 10, 611–624.Google Scholar

Gorzelak, P. (2018). Microstructural evidence for stalk autotomy in Holocrinus: The oldest stem-group isocrinid. Palaeogeography, Palaeoclimatology, Palaeoecology, 506, 202–207. DOI: doi.org/10.1016/j.palaeo.2018.06.036.Google Scholar

Gorzelak, P., Głuchowski, E., & Salamon, M. (2014). Reassessing the improbability of a muscular crinoid stem. Scientific Reports, 4. DOI: 10:1038/srep06049.CrossRef Google Scholar PubMed

Gorzelak, P., Krzykawski, T., & Stolarski, J. (2016). Diagenesis of echinoderm skeletons: Constraints on paleoseawater Mg/Ca reconstructions. Global and Planetary Change, 144, 142–157.Google Scholar

Gorzelak, P., Stolarski, J., Mazur, M., & Meibom, A. (2012). Micro- to nanostructure and geochemistry of extant crinoidal echinoderm skeletons. Geobiology. DOI: 10:1111/gbi.12012.Google Scholar

Greb, S. F., Potter, P. E., Meyer, D. L., & Ausich, W. I. (2009). Mud Mounds, Paleoslumps, Crinoids, and More; The Geology of the Fort Payne Formation at Lake Cumberland, South-central Kentucky. Kentucky Geological Survey Guidebook. www.professionalgeologist.org/guidebook.thtm; last accessed March 27, 2019.Google Scholar

Greenstein, B. J. (1989). Mass mortality of the West-Indian echinoid Diadema antillarum (Echinodermata: Echinoidea): A natural experiment in taphonomy. PALAIOS, 4, 487–492.Google Scholar

Greenstein, B. J. (1990). Taphonomic biasing of subfossil echinoid populations adjacent to St. Croix, U.S.V.I. In D. K. Larve, ed., Transactions of the 12^th International Caribbean Congress, Miami Geological Society, pp. 290–300.Google Scholar

Greenstein, B. J. (1991). An integrated study of echinoid taphonomy: Predictions for the fossil record of four echinoid families. PALAIOS, 6, 519–540.Google Scholar

Greenstein, B. J. (1992). Taphonomic bias and the evolutionary history of the family Cidaridae (Echinodermata: Echinoidea). Paleobiology, 18, 50–79.CrossRef Google Scholar

Grun, T. B., Mancosu, A., Bealaústegui, Z., & Nebelsick, J. H. (2018). The taphonomy of Clypeaster: A paleontological tool to identify stable structures in natural shell systems. Neues Jahrbuch für Geologie und Paläontologie – Abhandlungen, 289, 189–202. DOI:10.1127/njgpa/2018/0737.Google Scholar

Guensburg, T. E. (1988). Systematics, functional morphology, and life modes of late Ordovician edrioasteroids, Orchard Creek Shale, southern Illinois. Journal of Paleontology, 62, 110–126.Google Scholar

Guensburg, T. E., & Sprinkle, J. (1994). Revised phylogeny and functional interpretation of the Edrioasteroidea based on new taxa from the Early Ordovician of eastern Utah. Fieldiana (Geology), 29, 43 p.Google Scholar

Guensburg, T. E., & Sprinkle, J. (1995). Origin of echinoderms in the Paleozoic evolutionary fauna: The role of substrates. PALAIOS, 10, 437–453.Google Scholar

Gutschick, R. C., Sandberg, C. A., & Sando, W. J. (1980). Mississippian shelf margin and carbonate platform from Montana to Nevada. In T. D. Fouch & E. R. Magathan, eds., Rocky Mountain Paleogeography Symposium I, Paleozoic Paleogeography of the West-Central United States, pp. 111–128.Google Scholar

Hagdorn, H., & Schulz, M. (1996). Echinodermen-Konservatlagerstätten im Unteren Muschelkalk Osthessens, 1. Die Bimbacher Seelilienbank von Grossenlüder-Bimbach. Geologisches Jahrbuch Hessen, 124, 97–122.Google Scholar

Hagdorn, H., Berra, F., & Tintori, A. (2018). Encrinus aculeatus von Meyer, 1849 (Crinoidea, Echinodermata) from the Middle Triassic of Bal Brembana (Alpi Orobie, Bergamo, Italy). Swiss Journal of Paleontology, 137, 211–224. DOI: doi.org/10.1007/s13358-018-1270-0.CrossRef Google Scholar

Hess, H. (1972a). Chariocrinus n. gen. für Isocrinus andraea Desor aus dem unteren Hauptrogenstein (Bajocien) des Basler Juras. Eclogae Geologicae Helvetiae, 65, 197–210.Google Scholar

Hess, H. (1972b). The fringilites of the Jurassic Sea. CIBA-GEIGY Journal, 2, 14–17.Google Scholar

Hess, H. (1985). Schlangensterne und Seelilien aus dem unteren Lias von Hallau (Kanton Schaffhausen). Sonderdruck aus den Mitteilungen der Naturforschenden Gesellschoft Schaffhausen, 33, 1–15.Google Scholar

Jackson, W. D., & De Keyser, T. (1984). Microfacies analysis of Muleshoe Mound (Early Mississippian), Sacramento Mountains, New Mexico: A point-source depositional model Part II. West Texas Geological Society Bulletin, 23 (6), 6–10.Google Scholar

Jaekel, O. (1894). Über die Morphogenie und Phylogenic der Crinoiden. Sitzungsberichten der Gesellschaft Naturforschender Freunde, Jargang 1894, 4, 101–121.Google Scholar

Jagt, J. W. M., Thuy, B., Donovan, S. K., et al. (2014). A starfish bed in the middle Miocene Grand Bay Formation of Carriacou, The Grenadines (West Indies). Geological Magazine, 151, 381–393.Google Scholar

James, N. P., Desrochers, A., & Kyser, T. K. (2015). Polygenetic (polyphase) karsted hardground omission surfaces in lower Silurian neritic limestones: Anticosti Island, eastern Canada. Journal of Sedimentary Research, 85, 1138–1154.CrossRef Google Scholar

Kammer, T. W., Tissue, E. C., & Wilson, M. A. (1987). Neoisorophusella, a new edrioasteroid genus from the Upper Mississippian of the Eastern United States. Journal of Paleontology, 61, 1033–1042.Google Scholar

Kent, W. N., & Rawson, R. R. (1980). Depositional environments of the Mississippian Redwall Limestone in northeastern Arizona. In T. D. Fouch & E. R. Magathan, eds., Rocky Mountain Paleogeography Symposium I, Paleozoic Paleogeography of the West-Central United States, pp. 101–109.Google Scholar

Kesling, R. V. (1969). A new brittle-star from the Middle Devonian Arkona Shale of Ontario. University of Michigan Museum of Paleontology Contributions, 23, 37–51.Google Scholar

Kesling, R. V., & Le Vasseur, D. (1971). Strataster ohioensis, a new Early Mississippian brittle-star, and the paleoecology of its community. Contributions to the Museum of Paleontology, University of Michigan, 23, 305–341.Google Scholar

Kidwell, S. M., & Baumiller, T. K. (1990). Experimental disintegration of regular echinoids: Roles of temperature, oxygen, and decay thresholds. Paleobiology, 16, 247–271.Google Scholar

Kidwell, S. M., & Jablonski, D. (1983). Taphonomic feedback: Ecological consequences of shell accumulation. In Tevesz, M. J. S. & McCall, P. L., eds., Biotic Interactions in Recent and Fossil Communities. New York: Plenum Press, pp. 195–248.Google Scholar

Kidwell, S. M., Fürsich, & T. Aigner, . (1986). Conceptual framework for the analysis and classification of fossil concentrations. PALAIOS, 1, 228–238.Google Scholar

Kier, P. M. (1968). Triassic echinoids from the North America. Journal of Paleontology, 42, 1000–1006Google Scholar

Kier, P. M. (1977). The poor fossil record of the regular echinoid. Paleobiology, 3, 168–174.Google Scholar

Koch, D. L., & Strimple, H. L. (1968). A new upper Devonian cystoid attached to a discontinuity surface. Iowa Geological Survey Report of Investigations, 5, 49 p.Google Scholar

Kotake, N. (1993). Tiering of trace fossil assemblages in Plio-Pleistocene bathyal deposits of Boso Peninsula, Japan. PALAIOS, 8, 544–553.CrossRef Google Scholar

Krivicich, E. B., Ausich, W. I., & Meyer, D. L. (2014). Crinoid assemblages from the Fort Payne Formation (late Osagean, early Viséan, Mississippian) from Kentucky, Tennessee, and Alabama. Journal of Paleontology, 88, 1154–1162.CrossRef Google Scholar

Kroh, A., & Nebelsick, J. H. (2003). Echinoid assemblages as a tool for palaeoenvironmental reconstruction – An example from the early Miocene of Egypt. Palaeogeography, Palaeoclimatology, Palaeoecology, 201, 157–177.CrossRef Google Scholar

Kühl, G., Bartels, C., Briggs, D. E. G., & Rust, J. (2012). Visions of a Vanished World. New Haven: Yale University Press, 128 p.Google Scholar

Lane, H. R. (1978). The Burlington Shelf (Mississippian, north-central North America). Geologica et Paleontologica, 12, 165–176.Google Scholar

Lane, H. R., & DeKeyser, T. L. (1980). Paleogeography of the late Early Mississippian (Tournaisian 3) in the central and southwestern United States. In T. D. Fouch and Magathan, E., eds., Paleozoic paleogeography of west-central United States: West-central United States. West-Central United States Paleogeographic Symposium, 1, pp. 149–162.Google Scholar

Lane, N. G. (1963). The Berkeley crinoid collection from Crawsfordsville, Indiana. Journal of Paleontology, 3, 1001–1008.Google Scholar

Lane, N. G. (1971). Crinoids and reefs. Proceedings of the First North American Paleontological convention, 1, 1430–1443.Google Scholar

Lane, N. G. (1973). Paleontology and paleoecology of the Crawfordsville fossil site (Upper Osagian. Indiana). California University Publications in the Geological Sciences, 99, 141 p.Google Scholar

Lane, N. G., & Ausich, W. I. (1995). Interreef crinoid faunas from the Mississinewa Shale Member of the Wabash Formation (northern Indiana: Silurian; Echinodermata). Journal of Paleontology, 69, 1090–1106.Google Scholar

Lane, N. G., & Macurda, D. B., Jr. (1975). New evidence for muscular articulations in Paleozoic crinoids. Paleobiology, 1, 59–62.Google Scholar

Lapham, K. E., Ausich, W. I., & Lane, N. G. (1976). A technique for developing the stereom of fossil crinoid ossicles. Journal of Paleontology, 50, 245–248.Google Scholar

Latch, R., Trzęsoik, D., & Szopa., P. (2014). Life and death: an intriguing history of a Jurassic crinoid. Paleontological Journal, 18, 40–44.Google Scholar

Laudon, L. R., & Beane, B. H. (1937). The crinoid fauna of the Hampton Formation at LeGrand, Iowa. University of Iowa Studies, 17, 227–272.Google Scholar

Le Clare, E. E. (1993). Effects of anatomy and environment on the relative preservation of asteroids: a biomechanical observation. PALAIOS, 8, 233–243.Google Scholar

Lees, A., & Miller, J. (1995). Waulsortian banks. In Monty, C. L. V., Bosence, D. W. J., Bridges, P. H., & Pratt, B. R., eds. Carbonate Mudmounds Their Origin and Evolution Oxford: Blackwell Science, pp. 191–271.Google Scholar

Lewis, R. (1980). Taphonomy. In Broadhead, T. W. and Waters, J. A., eds., Echinoderms: Notes for a Short Course. Knoxville: University of Tennessee Department of Geological Sciences Studies in Geology, pp. 40–58.Google Scholar

Lewis, R. (1986). Relative rates of skeletal disarticulation in modern ophiuroids and Paleozoic crinoids. Geological Society of America Abstracts with Programs, 18, 672.Google Scholar

Liddell, W. D. (1975). Recent crinoid biostratinomy. Geological Society of America, Abstracts with Programs, 7, 1169.Google Scholar

Lin, J.-P., Ausich, W. I., & Zhao, Y.-L. (2008). Settling strategy of stalked echinoderms from the Kaili Biota (middle Cambrian), Guizhou Province, China. Palaeogeography, Palaeoclimatology, Palaeoecology, 258, 213–221.CrossRef Google Scholar

Lin, J.-P., Ausich, W. I., Zhao, Y.-L., & Peng, J. (2007). Taphonomy, palaeocological implications, and colouration of Cambrian gogiid echinoderms from Guizhou Province, China. Geological Magazine, 145, 17–36. doi:10.1017/S0016756807003901 (published on paper in 2008 volume)Google Scholar

Lin, J.-P., Ausich, W. I., Zhao, Y.-L., Peng, J., & Tai, T. S. (2015). Crypto-helical body plan in partially disarticulated gogiids from the Cambrian of South China. Palaeoworld, 24, 393–399.Google Scholar

Lowenstam, H. A. (1957). Niagaran reefs in the Great Lakes region. Geological Society of America Memoir, 67, 215–248.Google Scholar

MacQueen, R. W., Ghent, E. D., & Davies, G. R. (1974). Magnesium distribution in living and fossil specimens of the echinoid Peronella lesueuia Agassiz, Shark Bay, Western Australia. Journal of Sedimentary Petrology, 44, 60–69.Google Scholar

Macurda, D. B., Jr., & Meyer, D. L. (1975). The microstructure of the crinoid endoskeleton. University of Kansas Paleontological Institute Paper, 74, 22 p.Google Scholar

Macurda, D. B., Jr., Meyer, D. L., & Roux, M. (1978). The crinoid stereom. In Moore, R. C. & Teichert, C, eds., Treatise on Invertebrate Paleontology, Part T., Echinodermata 2, 1. Lawrence, KS, and Boulder, CO: University of Kansas Press and Geological Society of America, pp. 217–232.Google Scholar

Mancousa, A., & Nebelsick, J. H. (2013). Multiple routes to mass accumulations of clypeasteroid echinoids: a comparative analysis of Miocene echinoids beds of Sardinia. Palaeogeography, Palaeoclimatology, Palaeoecology, 374, 173–186.CrossRef Google Scholar

Mancousa, A., & Nebelsick, J. H. (2015). The origin and paleoecology of clypeasteroid assemblages from different shelf settings of the Miocene of Sardinia, Italy. PALAIOS, 30, 273–287.Google Scholar

Mancousa, A., & Nebelsick, J. H. (2017). Ecomorphological and taphonomic gradients in clypeasteroid-dominated echinoderm assemblages along a mixed siliciclastic-carbonate shelf from the early Miocene of northern Sardinia, Italy. Acta Palaeontologica Polonica, 62, 627–646.Google Scholar

Maples, C. G., & Archer, A. W. (1989). Paleoecological and sedimentological significance of bioturbated crinoid calyces. PALAIOS, 4, 379–383.Google Scholar

Meyer, D. L. (1971). Post-mortem disarticulation of Recent crinoids and ophiuroids under natural conditions. Geological Society of America, Abstracts with Programs, 3, 645.Google Scholar

Meyer, D. L. (1990). Population paleoecology and comparative taphonomy of two edrioasteroid (Echinodermata) pavements: Upper Ordovician of Kentucky and Ohio. Historical Biology, 4, 155–178.Google Scholar

Meyer, D. L., & Ausich, W. I. (2019). Ecological and taphonomic fidelity in fossil crinoid accumulations. PALAIOS, 34, 575–583. DOI: http://dx.doi.org/10.2110/palo.2019.032.Google Scholar

Meyer, D. L., & Meyer, K. B. (1986). Biostratinomy of Recent crinoids (Echinodermata) at Lizard Island, Great Barrier Reef, Australia. PALAIOS, 1, 294–301.Google Scholar

Meyer, D. L., & Weaver, T. R. (1980). Biostratinomy of crinoid-dominated communities in the lower Bull Fork Formation (Upper Ordovician) of southwestern Ohio. Geological Society of America Abstracts with Programs, 12, 251.Google Scholar

Meyer, D. L., Ausich, W. I., Bohl, D. T., Norris, W. A., & Potter, P. E. (1995). Carbonate mud-mounds in the Fort Payne Formation (lower Carboniferous) Cumberland Saddle region, Kentucky and Tennessee USA. In Monty, C. L. V., Bosence, D. W. J., Bridges, P. H., & Pratt, B. R., eds., Carbonate Mudmounds Their Origin and Evolution Oxford: Blackwell Science, pp. 273–287.Google Scholar

Meyer, D. L., Ausich, W. I., & Terry, R. E. (1990). Comparative taphonomy of echinoderms in carbonate facies: Fort Payne Formation (Lower Mississippian) of Kentucky and Tennessee. PALAIOS, 4, 533–552. (this 1989 issue not published until 1990).Google Scholar

Meyer, D. L., Tobin, R. C., Pryor, W. A., et al. (eds.) (1981). Stratigraphy, sedimentology, and paleoecology of the Cincinnatian Series (Upper Ordovician) in the vicinity of Cincinnati, Ohio. In Roberts, T. G., (ed.), Geological Society of America Cincinnati 1981, Field Trip Guidebooks, Falls Church, VA: American Geological Institute pp. 31–72.Google Scholar

Milam, M. J., Meyer, D. L., Dattilo, B. J., & Hunda, B. R. (2017). Taphonomy of an Ordovician crinoid Lagerstätte from Kentucky. Palaios, 32: 166–180, figs. 1–15.Google Scholar

Miller, J. S. (1821). A natural history of the Crinoidea, or lily-shaped animals; with observations on the genera, Asteria, Euryale, Comatula and Marsupites. Bristol, UK: Bryan and Co.Google Scholar

Moore, R. C., & Laudon, L. R. (1943). Evolution and classification of Paleozoic crinoids. Geological Society of America Special Paper, 46, 151 p.Google Scholar

Moran, P. J. (1992). Preliminary observations of the decomposition of crown-of-thorns starfish, Acanthaster planci (L.). Coral Reefs, 11, 115–118.Google Scholar

Müller, A. H. (1963). Lehrbuch der Paläozoologie I. Allgemeine Grudlagen, Second Edition. Jena: G. Fisher.Google Scholar

Nagle, J. S. (1967). Wave and current orientation of shells. Journal of Sedimentary Petrology, 37, 1124–1138.Google Scholar

Nebelsick, J. H. (1992). The northern bay of Safaga (Red Sea, Egypt): An actuopaläontological approach, III distribution of echinoids. Beiträge zut Paläontologie von Österreich, 17, 5–79Google Scholar

Nebelsick, J. H. (1995a). Actuopalaeontological investigations of echinoids: The potential for taphonomic interpretations. In Emson, R., Smith, A. & Campbell, A., eds., Echinoderm Research, 1995, Rotterdam: Balkema Press, pp. 209–214.Google Scholar

Nebelsick, J. H. (1995b). Uses and limitations of actuopalaeontological investigations on echinoids. Geobios, 18, 329–336.Google Scholar

Nebelsick, J. H. (1995c). Comparative taphonomy of Clypeasteroids. Ecologae Geologicue Helvetiae 88, 685–693.Google Scholar

Nebelsick, J. H. (1996). Biodiversity of shallow-water Red Sea echinoids: implications for the fossil record. Journal of the Marine Biological Association. U.K. 76, 185–194.Google Scholar

Nebelsick, J. H. (2008). Taphonomy of the irregular echinoid Clypeaster humilis from the Red Sea: Implications for taxonomic resolution along taphonomic gradients. In Ausich, W. I. & Webster, G. D., eds., Echinoderm Paleobiology. Bloomington: Indiana University Press, pp. 115–128.Google Scholar

Nebelsick, J. H., Dynowski, J. F., Grossmann, J. N., & Tötzke, C. (2015). Echinoderms: Hierarchically organized light weight skeletons. In Hamm, C., ed., Evolution of Lightweight Structures: Analyses and Technical Applications, Biologically-Inspired Systems, Vol. 6, London: Springer-Verlag, 141–156. DOI 10.1007/978–017-9398–8_8. ISBN-10: 9401793972.Google Scholar

Nebelsick, J. H., & Kampfer, S. (1994). Taphonomy of Cypeaster humilis and Echinodiscus auritus (Echinoidea, Clypeateroide) from the Red Sea. In David, B., Guille, A., Feral, J.-P., and Roux, M., eds., Echinoderms Through Time, Rotterdam: Balkema, pp. 803–808.Google Scholar

Nebelsick, J. H., & Kroh, A. (1999). Palaeoecology and taphonomy of Parascutella bed from the lower Miocene of the Eastern Desert, Egypt. In Candia Carnevali, M. D. & Bonasoro, F, eds., Echinoderm Research 1998. Rotterdam: A.A. Balkema Press, p.353.Google Scholar

Nebelsick, J. H., & Mancosu, A. (2021). The taphonomy of echinoids: skeletal morphologies, environmental factors, and preservational pathways. Element in preparation.Google Scholar

Newell, N. D., Imbie, J., Purdy, E. G., & Thurber, D. L. (1959). Organism communities and bottom facies, Great Bahamas Bank. Bulletin of the American Museum of Natural History, 117, 177–228.Google Scholar

Oji, T., & Amemiya, S. (1998). Survival of crinoid stalk fragments and its taphonomic implications. Paleontological Research, 2, 67–70.Google Scholar

Okulitch, V. J., & Tovell, W. M. (1941). A crinoidal marking in the Dundas Formation at Toronto. Journal of Paleontology, 15, 89.Google Scholar

O’Malley, C. E., Ausich, W. I., & Chin., Y-P. (2008). Crinoid biomarkers (Borden Group, Mississippian): Implications for phylogeny. In Ausich, W. I. and Webster, G. D., eds., Echinoderm Paleobiology, Bloomington: Indiana University Press, pp. 290–306.Google Scholar

O’Malley, C. E., Ausich, W. I., & Chin., Y-P. (2013). Isolation and characterization of the earliest taxon-specific organic molecules (Mississippian, Crinoidea). Geology, 41, 347–350. (doi:10.1130/G33792.1)Google Scholar

O’Malley, C. E., Ausich, W. I., & Chin., Y-P. (2016). Deep echinoderm phylogeny preserved in organic molecules from Paleozoic fossils. Geology, 4, 379–382. [doi:10.1130/G37761.1]Google Scholar

Parsley, R. (2009). Morphology, ontogeny, and heterochrony in Lower and Middle Cambrian gogiids (Eocrinoidea, Echinodermata) from Guizhou Province, China. Palaeontological Journal, 43, 1406–1414.Google Scholar

Parsley, R. L., & Zhou, Y. (2006). Long stalked eocrinoids in the basal Middle Cambrian Kaili Biota, Taijiang County, Guizhou Province, China. Journal of Paleontology, 80, 1058–1071.Google Scholar

Pawson, D. L. (1980). Holothurians. In Broadhead, T. W. & Waters, J. A., eds., Echinoderm Notes for a Short Course. Knoxville: University of Tennessee Studies in Geology, 3, 175–189.Google Scholar

Purdy, E. G. (1963). Recent calcium carbonate facies on the Great Bahamas Bank, 2, sedimentary facies. Journal of Geology, 71, 472–497.Google Scholar

Régis, M. B. (1977). Organisation microstructurale du stéréome de l’Echinoïde Paracentrotus lifidus Lamarck et ses éventuelles incidences physiologiques. Comptes Rendus de l’Académie des Sciences Paris, Séries D, 285, 189–192.Google Scholar

Reid, M., Bordy, E. M., & Taylor, W. (2015). Taphonomy and sedimentology of an echinoderm obrution bed in the Lower Devonian Voorstehoek Formation (Bokkeveld Group, Cape Supergroup) of South Africa. Journal of African Earth Sciences, 110, 135–149.Google Scholar

Rhenberg, E. C., Ausich, W. I., & Meyer, D. L. (2016). Actinocrinitidae from the Lower Mississippian Fort Payne Formation of Kentucky and Alabama. Journal of Paleontology, 90,1148–1159. dx.doi.org/10.1017/jpa.2016.85 CrossRef Google Scholar

Riddle, S. W., Wulff, J. I. & Ausich, W. I. (1988). Biomechanics and stereomic microstructure of the Gilbertsocrinus tuberosus column. In Burke, R. D., Mladenov, P. V., Lambert, P., and Parsley, R. L., eds., Echinoderm Biology. Rotterdam: A.A. Balkema, pp. 641–648.Google Scholar

Rosenkranz, D. (1971). Zur sedimentology und Okölogie von Echinoderm-Lagerstätten. Neues Jahrbuch für Geologie und Paläontologie, Abhandlungen, 138, 221–258.Google Scholar

Rousseau, J., Gale, A. S., & Thuy, B. (2018). New articulated asteroids (Echinodermata, Asteroidea) and ophiuroids (Echinodermata, Ophiuroidea) from the Late Jurassic (Volgian/Tithian) of central Spitsbergen. European Journal of Taxonomy, 411, 1–6.Google Scholar

Roux, M. (1970). Introduction à l’etude des microstructures des tiges de crinöids. Geobios, 3, 79–98.Google Scholar

Roux, M. (1974a). Les principaux modes d’articulation des ossicules du squelete des Crinöides pédonculés actuels, Observations microstructurales et consequences pour l’interprétation des fossils. Compte Rendu de l’Academie des Sciences, Paris, 278, 2015–2018.Google Scholar

Roux, M. (1974b). Observations au microscope électronique à bakayage de quelques articulations entre les ossicules de sequelette des Crinöides pédonculés actuels (Bathycrinidae et Isocrinina). Travaux du Labroratoire de Paléontologie, Orsay, 10 p.Google Scholar

Roux, M. (1975). Microstructural analysis of the crinoid stem. University of Kansas Paleontological Contributions, Paper, 75, 1–7.Google Scholar

Sadler, M., & Lewis, R. D. (1996). Actualistic studies of taphonomy and ichnology the of irregular echinoid Meoma verntricosa at San Salvador, Bahamas. Geological Society of America Abstracts with Programs, 28, 293–294.Google Scholar

Savarese, M., Dodd, J. R., & Lane, N. G. (1997). Taphonomic and sedimentologic implications of crinoid intraskeletal porosity. Lethaia, 29, 141–156.Google Scholar

Schäfer, W. (1972). Ecology and Paleoecology of Marine Environments. Chicago: University of Chicago Press.Google Scholar

Schneider, C. L., Sprinkle, J., & Ryder, D. (2005). Pennsylvanian (Late Carboniferous) echinoids from the Winchell Formation, North-Central Texas, USA. Journal of Paleontology, 79, 745–762.Google Scholar

Schumacher, G. A. (1986). Storm processes and crinoid preservation. Abstracts, Fourth North American Paleontological Convention, Boulder, 12–15 August, p. A41.Google Scholar

Schwarzacher, W. (1961). Petrology and structure of some Loer Carboniferous reefs in northwestern Ireland. Journal of Sedimentary Petrology, 45, 481–503.Google Scholar

Schwarzacher, W. (1963). Orientation of crinoid by current action. Journal of Sedimentary Geology, 33, 580–586.Google Scholar

Seilacher, A. (1960). Strömumgsanzeichen in Hunsrückshiefer Notizblatt des Hessischen. Landesant für Bodenforschung zu Wiesbaden, 88, 88–106.Google Scholar

Seilacher, A. (1968). Origin and diagenesis of the Oriskany Sandstone (Lower Devonian, Appalachians) as reflected in the fossil shells. In Müller, B. & Friedman, G. M., eds., Recent Developments in Sedimentary Geology in Central Europe, New York: Springer-Verlag, pp. 175–185.Google Scholar

Seilacher, A. (1979). Constructional morphology of sand dollars. Paleobiology, 5, 1–20.Google Scholar

Sevastopulo, G. D., & Keegan, J. B. (1980). A technique for revealing the stereom structure of fossil crinoids. Palaeontology, 23, 749–756.Google Scholar

Shroat-Lewis, R. A., McKinney, M. L., Brett, C. E., Meyer, D. L., & Sumrall, C. D. (2011). Paleoecological assessment of an edrioasteroid (Echinodermata)-encrusted hardground from the Upper Ordovician (Maysvillian) Bellevue Member, Maysville, Kentucky. PALAIOS, 26, 470–483.Google Scholar

Shroat-Lewis, R. A., Sumrall, C. D., McKinney, M. L., & Meyer, D. L. (2014). A paleoecological comparison of two edrioasteroid (Echinodermata) encrusted pavements from the Upper Ordovician Correyville Formation of Florence, Kentucky and the Miamitown Shale of Sharonville, Ohio, U.S.A. PALAIOS, 29, 154–169.Google Scholar

Shroat-Lewis, R. A., Greenwood, E. N., & Sumrall, C. D. (2019). Paleoecological analysis of edrioasteroid (Echinodermata) encrusted slabs from the Chesterian (Upper Mississippian) Kinkaid Limestone of southern Illinois. PALAIOS, 34, 146–158.Google Scholar

Smith, A. B. (1980). Stereom microstructure of echinoid tests. Special Papers in Palaeontology, 25, 1–81.Google Scholar

Smith, A. B. (1984). Echinoid Paleobiology. London:George Allen and Unwin.Google Scholar

Smith, A. B., & Gallemí, J. (1991). Middle Triassic holothurians from northern Spain. Palaeontology, 34, 49–76.Google Scholar

Smith, A. B., & Paul, C. R. C. (1982). Revision of the class Cyclocystoidea (Echinodermata). Philosophical Transactions of the Royal Society of London, B, Biological Series, 296, 577–684.Google Scholar

Smith, A. B., & Rader, W. L. (2009). Echinoid diversity, preservation potential and sequence stratigraphic cycles in the Glen Rose Formation (early Albian, Early Cretaceous), Texas, USA. Palaeobiodiversity and Palaeoenvironments, 89, 7–52.Google Scholar

Smith, A. B., Reich, M., & Zamora, A. (2009). Morphology and ecological setting of the basal echinoid genus Rhenechinus from the early Devonian of Spain. Acta Palaeontologica Polonica, 58, 751–762.Google Scholar

Smosma, R. (1988). Paleogeographic reconstruction of the Lower Devonian Helderberg Group in the Appalachian Basin. In N. J. McMillan, A. F. Embry & D. J. Glass, eds., Devonian of the World, Proceedings of the Second International Symposium on the Devonian of the World, Calgary, Canada, 1, 265–275. Canadian Society of Petroleum Geologists.Google Scholar

Spencer, W. K., & Wright, C. W. (1966). Asterozoans. In Moore, R. C., ed., Treatise on Invertebrate Paleontology, Part V, Echinodermata 3. Lawrence, KS, Boulder, CO: University of Kansas Paleontological Institute and Geological Society of America, pp. U4–U107.)Google Scholar

Sprinkle, J. (1973). Morphology and evolution of blastozoan echinoderms. Harvard Museum of Comparative Zoology Special Publication, 283 p.Google Scholar

Sprinkle, J. (1982). Echinoderm zones and faunas of the Bromide Formation (Middle Ordovician) of Oklahoma. University of Kansas Paleontological Contributions Monograph, 1, 46–56.Google Scholar

Sprinkle, J., and Guensburg, T. E. (1995). Origin of echinoderms in the Paleozoic Evolutionary Fauna: The role of substrates. PALAIOS, 10, 437–453.Google Scholar

Sprinkle, J., & Gutschick, R. C. (1967). Costaloblastus, a channel fill blastoids from the Sappington Formation of Montana. Journal of Paleontology, 41, 385–402.Google Scholar

Sroka, S. D. (1988). Preliminary studies on a complete fossil holothurian from the Middle Pennsylvanian Francis Shale of Illinois. In Burke, R. D., Mladenov, P. V., Lambert, P., and Parsley, R. L., eds., Echinoderm Biology, Proceedings of the Sixth International Echinoderm Conference, Victoria, British Columbia. 23–28 August, 1987. Rotterdam: Balkema Press, pp. 159–160.Google Scholar

Sroka, S. D., & Blake, D. B. (1997). Echinodermata. In Shabica, C. W., and Hay, A. A., eds., Richardson’s Guide to the Fossil Fauna of Mazon Creek. Chicago, IL: Northeastern University Press, pp. 223–225.Google Scholar

Stevenson, A., Gahn, F. J., Baumiller, T. K., & Sevastopulo, G. D. (2017). Predation on feather stars by regular echinoids as evidenced by laboratory and field observations and its paleobiological implications. Paleobiology, 43, 274–285.Google Scholar

Stolarski, J., Gorzelak, P., Mazur, M., Marrocchi, Y., & Meibon, A. (2009). Nanostructural and geochemical features of the Jurassic isocrinids columnal ossicles. Acta Palaeontological Polonica, 54, 69–75.Google Scholar

Strimple, H. L., & Moore, R. C. (1971). Crinoids from the LaSalle Limestone (Pennsylvanian) Illinois. University of Kansas Paleontological Institute, Echinodermata Article 11, 48 p.Google Scholar

Sumrall, C. D. (2000). The biologic implications of an edrioasteroid attached to a pleurocystitid rhombiferan. Journal of Paleontology, 84, 356–359.Google Scholar

Sumrall, C. D. (2001). Paleoecology and taphonomy of two new edrioasteroids from a Mississippian hardground in Kentucky. Journal of Paleontology, 75, 136–146Google Scholar

Sumrall, C. D. (2010). The systematics of a new upper Ordovician edrioasteroid pavement from northern Kentucky. Journal of Paleontology, 84, 783–794.Google Scholar

Sumrall, C. D., Brett, C. E., Work, P. T., & Meyer, D. L. (2001). Taphonomy and paleoecology of an edrioasteroid encrusted hardground in the Bellevue Formation at Maysville, Kentucky. In T. J. Algeo & C. E. Brett, eds., Sequence, Cycle, and Event Stratigraphy of Upper Ordovician and Silurian Strata of the Cincinnati Arch Region. Kentucky Geological Survey, Kentucky Guidebook Series 12, 1, 123–131.Google Scholar

Sumrall, C. D., Sprinkle, J., & Bonem, R. M. (2006). An edrioasteroid-dominated echinoderm assemblage from a Lower Pennsylvanian marine conglomerate in Oklahoma. Journal of Paleontology, 80, 229–244.Google Scholar

Taylor, W. L., & Brett, C. E. (1996). Taphonomy and paleoecology of echinoderm Lagerstätten from the Silurian (Wenlockian) Rochester Shale. PALAIOS, 11, 118–140.Google Scholar

Telford, M. (1985a). Domes, arches and urchins: the skeletal architecture of echinoids (Echinodermata). Zoomorphology, 105, 114–124.Google Scholar

Telford, M. (1985b). Structural analysis of the test of Echinocyamus pusillus (O. F. Müller). In Keegan, B. F. and O’Conner, B. D. S., eds., Proceedings of the Fifth International Echinoderm Conference. Rotterdam: Balkema, pp. 353–360.Google Scholar

Thompka, J. R., Lewis, R.D., Mosher, D., Pabian, R. K., & Holterhoff, P. F. (2011). Genus-level taphonomic variation within cladid crinoids from the Upper Pennsylvanian Barnsdall Formation, northeastern Oklahoma. PALAIOS, 26, 377–389.Google Scholar

Tetreault, D. K. (1995). An unusual Silurian arthropod/echinoderm dominated soft-bodied fauna from the Eramosa Member (Ludlow) of the Guelph Formation, southern Bruce Peninsula, Ontario, Canada. Geological Society of America Abstracts with Programs, 27, A–114.Google Scholar

Ubaghs, G. (1963). Rhopalocystis detombsei n. gen., n. sp. Eocrinoïde de l’Ordovicien inférieur (Trémadocien supériur de Sud marocain. Notes du Service Géologique du Marocain, 23, 25–45.Google Scholar

Veitch, M. A., Messing, C. G., & Baumiller, T. K. (2015). Contractile connective tissue (CCT) in the stalk of the bourgueticrinid crinoid, Democrinus: functional, ecological, and evolutionary implications. Geological Society of America Abstracts with Programs, 47(7), 855.Google Scholar

Wachsmuth, C., & Springer, F. (1880–1886). Revision of the Palaeocrinoidea. Proceedings of the Academy of Natural Sciences of Philadelphia Pt. I. The families Ichthyocrinidae and Cyathocrinidae (1880), pp. 226–378, (separate repaged pp. 1–153). Pt. II. Family Sphaeroidocrinidae, with the sub-families Platycrinidae, Rhodocrinidae, and Actinocrinidae (1881), pp. 177–411, (separate repaged, pp. 1–237). Pt. III, Sec. 1. Discussion of the classification and relations of the brachiate crinoids, and conclusion of the generic descriptions (1885), pp. 225–364 (separate repaged, pp. 1–138). Pt. III, Sec. 2. Discussion of the classification and relations of the brachiate crinoids, and conclusion of the generic descriptions (1886), pp. 64–226 (separate repaged to continue with section 1, pp. 139–302).Google Scholar

Waddington, J. B. (1980). A soft substrata community with edrioasteroids from the Verulum Formation (Middle Ordovician) at Gambridge, Ontario. Canadian Journal of Earth Sciences, 17, 674–749.Google Scholar

Weber, J. N. (1969). The incorporation of magnesium into the skeletal calcite of echinoderms. American Journal of Science, 267, 537–566.Google Scholar

Welch, J. R. (1984). The asteroid Lepidasterella montanaensis n. sp., from the upper Mississippian Bear Gulch Formation of Montana. Journal of Paleontology, 58, 843–851.Google Scholar

Wilson, J. L. (1975). Carbonate Facies in Geologic History. New York: Springer-Verlag, 471 p.Google Scholar

Witzke, B. J., Tassier-Surine, S. A., Anderson, R. R., Bunker, B. J., & Artz, J. A. (2002). Pleistocene, Mississippian, and Devonian Stratigraphy of the Burlington, Iowa, area. Iowa Geological Survey Guidebook, 23, 23–51 p.Google Scholar

Wolkenstein, K., Głuchowski, E., Gross, J. H., & Marynowski, L. (2008). Hypericrinoid pigments in millericrinids from the lower Kimmeridgian of the Holy Cross Mountains (Poland). PALAIOS, 23, 773–777.Google Scholar

Wolkenstein, K., Gross, J. H., Heinz, F., & Schöler, H. F. (2006). Preservation of hypericine and related polycyclic quinone pigments in fossil crinoids. Proceedings of the Royal Society, B–Biological Sciences, 273, 451–456, doi:10.1098/rspb.2005.3358Google Scholar

Wright, D. F. (2017a). Bayesian estimation of fossil phylogenies and the evolution of early to middle Paleozoic crinoids (Echinodermata). Journal of Paleontology, 91, 799–814. doi: 10.1017/jpa.2016.141.Google Scholar

Wright, D. F. (2017b). Phenotypic innovation and adaptive constraints in the evolutionary radiation of Palaeozoic crinoids. Scientific Reports, 7: 13745 | DOI:10.1038/s41598-017-13979-9.Google Scholar

Wright, D. F., Ausich, W. I., Cole, S. R., Peter, M. E., & Rhenberg, E. C., (2017). Phylogenetic taxonomy and classification of the Crinoidea (Echinodermata): Journal of Paleontology, 91, 829–846. doi 10.1917/jpa.2016.142; published online 02–22-17.Google Scholar

Zhao, Y., Parsley, R. L., & Peng, J. (2008). Basal middle Cambrian short-stalked eocrinoids from the Kaili Biota: Guizhou Province, China. Journal of Paleontology, 82, 415–422.Google Scholar

Zamora, S., Gozalo, R. & Linñán, E. (2009). Middle Cambrian gogiid echinoderms from Northeastern Spain: Taxonomy, palaeoecology, and palaeogeographic implications. Acta Palaeontologica Polonica, 54, 253–265.Google Scholar

Zittel, K. A. von. (1895). Grundzüge der Palaeontologie (Palaeozoologie), 1st edit. München: R. Oldenbourg.Google Scholar

Element contents

Disarticulation and Preservation of Fossil Echinoderms: Recognition of Ecological-Time Information in the Echinoderm Fossil Record

Summary

Keywords

Access options

References

Save element to Kindle

Save element to Dropbox

Save element to Google Drive