OVert: Open Exploration of Vertebrate Diversity in 3D: Difference between revisions

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=== Publications ===
=== Publications ===


Bardua, C., Fabre, A.C., Bon, M., Das, K., Stanley, E.L., Blackburn, D.C., & Goswami, A. (2020). Evolutionary integration of the frog cranium. Evolution, https://doi.org/10.1111/evo.13984.<br>
Bardua, C., Fabre, A.C., Bon, M., Das, K., Stanley, E.L., Blackburn, D.C., & Goswami, A. (2020). Evolutionary integration of the frog cranium. Evolution, 74, 1200–1215.<br>
 
Blackburn, D.C., R.M. Keeffe, M.C. Vallejo-Pareja, and J. Vélez-Juarbe. (2020). The earliest record of Caribbean frogs: a fossil coquí from Puerto Rico. Biology Letters, 16, 20190947.<br>


Bock, A., Doraiswamy, H., Summers, A., & Silva, C. (2018). Topoangler: Interactive topology-based extraction of fishes. IEEE transactions on visualization and computer graphics, 24(1), 812-821.<br>
Bock, A., Doraiswamy, H., Summers, A., & Silva, C. (2018). Topoangler: Interactive topology-based extraction of fishes. IEEE transactions on visualization and computer graphics, 24(1), 812-821.<br>
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Boyer, D.M., Yapuncich, G.S., Dunham, N.T., McNamara, A., Shapiro, L.J., Hieronymus, T.L., & Young, J.W. (2019). My branch is your branch: Talar morphology correlates with relative substrate size in platyrrhines at Tiputini Biodiversity Station, Ecuador. Journal of Human Evolution, 133, 23-31.<br>
Boyer, D.M., Yapuncich, G.S., Dunham, N.T., McNamara, A., Shapiro, L.J., Hieronymus, T.L., & Young, J.W. (2019). My branch is your branch: Talar morphology correlates with relative substrate size in platyrrhines at Tiputini Biodiversity Station, Ecuador. Journal of Human Evolution, 133, 23-31.<br>


Buser, T.J., Finnegan, D.L., Summers, A.P., & Kolmann, M.A. (2019). Have niche, will travel. New means of linking diet and ecomorphology reveals niche conservatism in freshwater cottoid fishes. Integrative Organismal Biology, 1(1), obz023.<br>
Buser, T.J., Finnegan, D.L., Summers, A.P., & Kolmann, M.A. (2019). Have niche, will travel. New means of linking diet and ecomorphology reveals niche conservatism in freshwater cottoid fishes. Integrative Organismal Biology, 1, obz023.<br>


Conway, K.W., Mateos, M., & Vrijenhoek, R.C. (2019). A new species of the live-bearing fish genus Poeciliopsis from northern Mexico (Cyprinodontiformes, Poeciliidae). ZooKeys, 883, 91.<br>
Conway, K.W, King, C. D. Summers A.P. Kim, D. Hastings, P.A. Moore, G.I. Iglésias, S.P Erdmann, M.V., Short, G. Fujiwara, K. Trnski, T. Voelker, G. and Rüber L.  (2020). Molecular phylogenetics of the clingfishes (Teleostei: Gobiesocidae) – Implications for Classification.  Copeia, in press.<br>
 
Conway, K.W., Mateos, M., & Vrijenhoek, R.C. (2019). A new species of the live-bearing fish genus ''Poeciliopsis'' from northern Mexico (Cyprinodontiformes, Poeciliidae). ZooKeys, 883, 91.<br>


Conway, K.W., Moore, G.I., & Summers, A.P. (2019). A new genus and two new species of miniature clingfishes from temperate southern Australia (Teleostei, Gobiesocidae). ZooKeys, 864, 35.<br>
Conway, K.W., Moore, G.I., & Summers, A.P. (2019). A new genus and two new species of miniature clingfishes from temperate southern Australia (Teleostei, Gobiesocidae). ZooKeys, 864, 35.<br>


Conway, K.W., Stewart, A.L., & Summers, A.P. (2018). A new species of sea urchin associating clingfish of the genus ''Delllichthys'' from New Zealand (Teleostei, Gobeisocidae). ZooKeys, 740, 77-95.<br>
Conway, K.W., Stewart, A.L., & Summers, A.P. (2018). A new species of sea urchin associating clingfish of the genus ''Delllichthys'' from New Zealand (Teleostei, Gobeisocidae). ZooKeys, 740, 77–95.<br>


Conway, K.W., Stewart, A.L., & Summers, A.P. (2018). A new genus and species of clingfish from the Kermadec Islands of New Zealand (Teleostei: Gobiesocidae). ZooKeys, 786, 75-104.<br>
Conway, K.W., Stewart, A.L., & Summers, A.P. (2018). A new genus and species of clingfish from the Kermadec Islands of New Zealand (Teleostei: Gobiesocidae). ZooKeys, 786, 75–104.<br>


Corn, K.A., Farina, S.C., Summers, A.P., & Gibb, A.C. (2018). Effects of organism and substrate size on burial mechanics of English sole, Parophrys vetulus. Journal of Experimental Biology, 221(18), jeb176131.<br>
Corn, K.A., Farina, S.C., Summers, A.P., & Gibb, A.C. (2018). Effects of organism and substrate size on burial mechanics of English sole, Parophrys vetulus. Journal of Experimental Biology, 221, jeb176131.<br>


Early, C.M., Ridgely, R.C., & Witmer, L.M. (2020). Beyond endocasts: using predicted brain-structure volumes of extinct birds to assess neuroanatomical and behavioral inferences. Diversity, 12(1), 34.<br>
Fabre, A.-C., Bardua, C., Bon, M., Clavel, J., Felice, R.N., Streicher, J.W., Bonnel, J., Stanley, E.L., Blackburn, D.C., & Goswami, A. (2020). Metamorphosis shapes cranial diversity and rate of evolution in salamanders. Nature Ecology & Evolution, https://doi.org/10.1038/s41559-020-1225-3.<br>


Fabre, A.-C., Bardua, C., Bon, M., Clavel, J., Felice, R.N., Streicher, J.W., Bonnel, J., Stanley, E.L., Blackburn, D.C., & Goswami, A. (2020). Metamorphosis shapes cranial diversity and rate of evolution in salamanders. Nature Ecology & Evolution, https://doi.org/10.1038/s41559-020-1225-3.<br>
Farina, S.C.,Knope, M.L., Corn, K.A., Summers, A.P., & Bemis, W.B. (2019). Functional coupling in the evolution of suction feeding and gill ventilation of sculpins (Perciformes: Cottoidei), Integrative and Comparative Biology, icz022.<br>


Farina, S.C.,Knope, M.L., Corn, K.A., Summers, A.P., & Bemis, W.B.(2019). Functional coupling in the evolution of suction feeding and gill ventilation of sculpins (Perciformes: Cottoidei), Integrative and Comparative Biology, icz022. <br>
Ferry, L.A., E.W. Paig-Tran, A.P. Summers, and K.F. Liem. (2019). Extreme premaxillary protrusion in the king-of-the-salmon, ''Trachipterus altivelis''. Journal of Morphology, 280, 1865–1870.  


Fried, P., Woodward, J., Brown, D., Harvell, D., & Hanken, J. (2020). 3D scanning of antique glass by combining photography and computed tomography. Digital Applications in Archaeology and Cultural Heritage, 18, e00147.<br>
Fried, P., Woodward, J., Brown, D., Harvell, D., & Hanken, J. (2020). 3D scanning of antique glass by combining photography and computed tomography. Digital Applications in Archaeology and Cultural Heritage, 18, e00147.<br>


Griffing, A.H., Sanger, T.J., Daza, J.D., Nielsen, S.V., Pinto, B.J., Stanley, E.L., & Gamble, T. (2019). Embryonic development of a parthenogenetic vertebrate, the mourning gecko (Lepidodactylus lugubris). Developmental Dynamics.<br>
Griffing, A.H., Sanger, T.J., Daza, J.D., Nielsen, S.V., Pinto, B.J., Stanley, E.L., & Gamble, T. (2019). Embryonic development of a parthenogenetic vertebrate, the mourning gecko (''Lepidodactylus lugubris''). Developmental Dynamics, 248, 1070–1090.<br>
 
Hall, K.C., Hundt, P.J., Swenson, J.D., Summers, A.P., & Crow, K.D. (2018). The evolution of underwater flight: The redistribution of pectoral fin rays, in manta rays and their relatives (Myliobatidae). Journal of Morphology, 279,1155–1170.<br>
 
Harrington, A.R., Kuzawa, C.W., & Boyer, D.M. (2019). Carotid foramen size in the human skull tracks developmental changes in cerebral blood flow and brain metabolism. American Journal of Physical Anthropology, 169, 161–169.<br>


Hall, K.C., Hundt, P.J., Swenson, J.D., Summers, A.P., & Crow, K.D. (2018) The evolution of underwater flight: The redistribution of pectoral fin rays, in manta rays and their relatives (Myliobatidae). Journal of Morphology, https://doi.org/10.1002/jmor.20837. <br>
Hastings, P. A., Eytan, R. and Summers, A.P. (2020). A new species of ''Acanthemblemaria'' from the Caribbean coast of South America with notes on ''Acanthemblemaria johnsoni'' (Teleostei:  Chaenopsidae). Zootaxa, 4816, 209–216.<br>


Harrington, A.R., Kuzawa, C.W., & Boyer, D.M. (2019). Carotid foramen size in the human skull tracks developmental changes in cerebral blood flow and brain metabolism. American Journal of Physical Anthropology.<br>
Hedrick, B.P., Heberling, J.M., Meineke, E.K., Turner, K.G., Grassa, C.J., Park, D.S., Kennedy, J., Clarke, J.A., Cook, J.A., Blackburn, D.C. & Edwards, S.V. (2020). Digitization and the future of natural history collections. BioScience, 70, 243–251.<br>


Hedrick, B.P., Heberling, J.M., Meineke, E.K., Turner, K.G., Grassa, C.J., Park, D.S., Kennedy, J., Clarke, J.A., Cook, J.A., Blackburn, D.C. & Edwards, S.V. (2020). Digitization and the future of natural history collections. BioScience, 70(3), 243-251.<br>
Hilton, E.J., G.J. Watkins-Colwell, & S.K. Huber. (2020). The expanding role of natural history collections. Copeia, in press.<br>


Hoke, K.L., Adkins-Regan, E., Bass, A.H., McCune, A.R., & Wolfner, M.F. (2019). Co-opting evo-devo concepts for new insights into mechanisms of behavioural diversity. Journal of Experimental Biology, 222(8), jeb190058.<br>
Hoke, K.L., Adkins-Regan, E., Bass, A.H., McCune, A.R., & Wolfner, M.F. (2019). Co-opting evo-devo concepts for new insights into mechanisms of behavioural diversity. Journal of Experimental Biology, 222, jeb190058.<br>


Hongjamrassilp, W., Summers, A.P., & Hastings, P.A. (2018). Heterochrony in fringeheads (''Neoclinus'') and amplification of an extraordinary aggressive display in the Sarcastic Fringehead (Teleostei: Blenniiformes). Journal of Morphology.<br>
Hongjamrassilp, W., Summers, A.P., & Hastings, P.A. (2018). Heterochrony in fringeheads (''Neoclinus'') and amplification of an extraordinary aggressive display in the Sarcastic Fringehead (Teleostei: Blenniiformes). Journal of Morphology, 279, 626–635.<br>


Huie, J.M., Summers, A.P., & Kolmann, M.A. (2019). Body shape separates guilds of rheophilic herbivores (Myleinae: Serrasalmidae) better than feeding morphology. Proceedings of the Academy of Natural Sciences of Philadelphia, 166(1), 1-15.<br>
Huie, J.M., Summers, A.P., & Kolmann, M.A. (2019). Body shape separates guilds of rheophilic herbivores (Myleinae: Serrasalmidae) better than feeding morphology. Proceedings of the Academy of Natural Sciences of Philadelphia, 166, 1-15.<br>


Huie, J.M., Thacker, C., & Tornabene, L. (2019). Co‐evolution of cleaning and feeding morphology in the western Atlantic and eastern Pacific gobies. Evolution, https://doi.org/10.1111/evo.13904.<br>
Huie, J.M., Thacker, C., & Tornabene, L. (2019). Co‐evolution of cleaning and feeding morphology in the western Atlantic and eastern Pacific gobies. Evolution, 74, 419–433.<br>


Kolmann, M.A., Huie, J.M., Evans, K., & Summers, A.P. (2018). Specialized specialists and the narrow niche fallacy: a tale of scale-feeding fishes. Royal Society Open Science, 5(1), 171581.<br>
Keeffe, R., and D.C. Blackburn. (2020). Comparative morphology of the humerus in forward-burrowing frogs. Biological Journal of the Linnean Society, in press.<br>


Kruppert, S., Chu, F., Stewart, M.C., Schmitz, L., & Summers, A.P. (2020) Ontogeny and potential function of poacher armor (Actinopterygii: Agonidae). Journal of Morphology, DOI: 10.1002/jmor.21223.<br>
Kolmann, M.A. K.E. Cohen, K. Bemis, A.P. Summers, Adam, F. Irish, and L.P. Hernandez (2019). Tooth and consequences: heterodonty and dental replacement in piranhas and pacus (Serrasalmidae). Evolution and Development, 21, 247-262.<br>


Leão, M.D.V., Carvalho, T.P., Reis, R.E., & Wosiacki, W.B. (2019). A new species of Pseudobunocephalus Friel, 2008 (Siluriformes: Aspredinidae) from the lower Tocantins and Mearim river drainages, North and Northeast of Brazil. Zootaxa, 4586(1), 109-126.<br>
Kolmann, M.A., Huie, J.M., Evans, K., & Summers, A.P. (2018). Specialized specialists and the narrow niche fallacy: a tale of scale-feeding fishes. Royal Society Open Science, 5, 171581.<br>


Lewis, Z.R., Dorantes, J.A., & Hanken, J. (2018). Expression of a novel surfactant protein gene is associated with sites of extrapulmonary respiration in a lungless salamander. Proceedings of the Royal Society B, 285(1888), 20181589.<br>
Kruppert, S., Chu, F., Stewart, M.C., Schmitz, L., & Summers, A.P. (2020) Ontogeny and potential function of poacher armor (Actinopterygii: Agonidae). Journal of Morphology, in press. DOI: 10.1002/jmor.21223.<br>


Lundberg, J.G., Hendrickson, D.A., Luckenbill, K.R. & Arce, M. (2017). Satan's skeleton revealed: a tomographic and comparative osteology of ''Satan eurystomus'', the subterranean Widemouth Blindcat (Siluriformes, Ictaluridae). Proceedings of the Academy of Natural Sciences of Philadelphia, 165(1), 117-173.<br>
Leão, M.D.V., Carvalho, T.P., Reis, R.E., & Wosiacki, W.B. (2019). A new species of ''Pseudobunocephalus'' Friel, 2008 (Siluriformes: Aspredinidae) from the lower Tocantins and Mearim river drainages, North and Northeast of Brazil. Zootaxa, 4586, 109–126.<br>


Marramà, G., & Carnevale, G. (2017). The relationships of "Gasteroclupea branisai" Signeux, 1964, a freshwater double-armored herring (Clupeomorpha, Ellimmicthyiformes) from the Late Cretaceous-Paleocene of South America. Historical Biology, 29(7), 904-917.<br>
Lewis, Z.R., Dorantes, J.A., & Hanken, J. (2018). Expression of a novel surfactant protein gene is associated with sites of extrapulmonary respiration in a lungless salamander. Proceedings of the Royal Society B, 285, 20181589.<br>
 
Lundberg, J.G., Hendrickson, D.A., Luckenbill, K.R. & Arce, M. (2017). Satan's skeleton revealed: a tomographic and comparative osteology of ''Satan eurystomus'', the subterranean Widemouth Blindcat (Siluriformes, Ictaluridae). Proceedings of the Academy of Natural Sciences of Philadelphia, 165, 117-173.<br>
 
Luparell. J.L., A.P. Summers, and T.J Buser. (2019). Digitizing North America’s fishes. American Currents, 44,14-16.<br>
 
Marramà, G., & Carnevale, G. (2017). The relationships of "Gasteroclupea branisai" Signeux, 1964, a freshwater double-armored herring (Clupeomorpha, Ellimmicthyiformes) from the Late Cretaceous-Paleocene of South America. Historical Biology, 29, 904-917.<br>


Matthews, T., Keeffe, R., & Blackburn, D.C. (2019) An identification guide to fossil frog assemblages of southern Africa based on ilia of extant taxa. Zoologischer Anzeiger, 283, 46–57.<br>
Matthews, T., Keeffe, R., & Blackburn, D.C. (2019) An identification guide to fossil frog assemblages of southern Africa based on ilia of extant taxa. Zoologischer Anzeiger, 283, 46–57.<br>


Nelson, G., & Ellis, S. (2019). The history and impact of digitization and digital data on biodiversity research. Philosophical Transactions of the Royal Society B, 374(1763), 20170391.<br>
Page, L.M., Ray, B.C., Tongnunui, S., Boyd, D.A., & Randall, Z.S. (2019). ''Garra surinbinnani'', a new species of labeonine from the Mae Khlong basin of Thailand (Teleostei: Cyprinidae). Ichthyological Exploration of Freshwaters, 1–15. http://doi.org/10.23788/IEF-1117.<br>


Page, L.M., Ray, B.C., Tongnunui, S., Boyd, D.A., & Randall, Z.S. (2019). Garra surinbinnani, a new species of labeonine from the Mae Khlong basin of Thailand (Teleostei: Cyprinidae). Ichthyological Exploration of Freshwaters, http://doi.org/10.23788/IEF-1117.<br>
Paluh, D.J., Stanley, E.L., & Blackburn, D.C. (2020). Evolution of hyperossification expands skull diversity in frogs. Proceedings of the National Academy of Sciences USA, 117, 8554-8562.<br>


Paluh, D.J., Stanley, E.L., & Blackburn, D.C. (2020). Evolution of hyperossification expands skull diversity in frogs. Proceedings of the National Academy of Sciences, 117(15), 8554-8562.<br>
Parra Olea, G., M.G. Garcia-Castillo, S.M. Rovito, J. Maisano, J. Hanken, & D.B. Wake. (2020). Descriptions of five new species of the salamander genus ''Chiropterotriton'' (Caudata: Plethodontidae) from eastern Mexico and the status of three currently recognized taxa. PeerJ, 8, e8800. <br>


Prestridge, H.L., & Conway, K.L. (2019). TCWC – The Collection of Fishes at the Biodiversity Research and Teaching Collections, Texas A&M University. Boletim Sociedade Brasileira de Ictiologia, 129, 121-124.<br>
Prestridge, H.L., & Conway, K.L. (2019). TCWC – The Collection of Fishes at the Biodiversity Research and Teaching Collections, Texas A&M University. Boletim Sociedade Brasileira de Ictiologia, 129, 121-124.<br>
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Stocker, M.R., Nesbitt, S.J., Kligman, B.T., Paluh, D.J., Marsh, A.D., Blackburn, D.C., & Parker, W.G. (2019). The earliest equatorial record of frogs from the Late Triassic of Arizona. Biology Letters, 15(2), 20180922.<br>
Stocker, M.R., Nesbitt, S.J., Kligman, B.T., Paluh, D.J., Marsh, A.D., Blackburn, D.C., & Parker, W.G. (2019). The earliest equatorial record of frogs from the Late Triassic of Arizona. Biology Letters, 15(2), 20180922.<br>


Vijayakumar, S.P., Pyron, R.A., Dinesh, K.P., Torsekar, V.R., Srikanthan, A.N., Swamy, P., ... & Shanker, K. (2019). A new ancient lineage of frog (Anura: Nyctibatrachidae: Astrobatrachinae subfam. nov.) endemic to the Western Ghats of Peninsular India. PeerJ, 7.<br>
Štrus, J., M. Tušek-Žnidarič, U. Repnik, A. Blejec, and A.P. Summers (2019) Microscopy of crustacean cuticle: formation of a flexible extracellular matrix in moulting sea slaters ''Ligia pallasii''. Journal of the Marine Biological Association of the United Kingdom, 99, 857-865. <br>
 
Vijayakumar, S.P., Pyron, R.A., Dinesh, K.P., Torsekar, V.R., Srikanthan, A.N., Swamy, P., Stanley, E.L., Blackburn, D.C., & Shanker, K. (2019). A new ancient lineage of frog (Anura: Nyctibatrachidae: Astrobatrachinae subfam. nov.) endemic to the Western Ghats of Peninsular India. PeerJ, 7.<br>


Watkins-Colwell, G.J., Love, K., Randall, Z., Boyer, D.M., Winchester, J.M., Stanley, E.L., & Blackburn, D.C. (2018) The Walking Dead: status report, data workflow and best practices of the oVert Thematic Collections Network. Biodiversity Information Science and Standards 2: e26078.<br>
Watkins-Colwell, G.J., Love, K., Randall, Z., Boyer, D.M., Winchester, J.M., Stanley, E.L., & Blackburn, D.C. (2018). The Walking Dead: status report, data workflow and best practices of the oVert Thematic Collections Network. Biodiversity Information Science and Standards, 2, e26078.<br>


Weinell, J.L., Paluh, D.J., Singh, A.L., Blackburn, D.C., & Brown, R.M. (2019) Myersophis alpestris (Myers' Mountain Snake. Reproduction. Herpetological Review, 50(1): 164-165.<br>
Weinell, J.L., Paluh, D.J., Singh, A.L., Blackburn, D.C., & Brown, R.M. (2019). ''Myersophis alpestris'' (Myers' Mountain Snake. Reproduction. Herpetological Review, 50, 164-165.<br>


Westeen, E.P., Durso, A.M., Grundler, M.C., Rabosky, D.L., & Rabosky, A.R. (2020) What makes a fang? Phylogenetic and ecological controls on tooth evolution in rear-fanged snakes. BMC Evolutionary Biology, 20: 80.<br>
Westeen, E.P., Durso, A.M., Grundler, M.C., Rabosky, D.L., & Rabosky, A.R. (2020). What makes a fang? Phylogenetic and ecological controls on tooth evolution in rear-fanged snakes. BMC Evolutionary Biology, 20, 80.<br>


Yapuncich, G.S., Feng, H.J., Dunn, R.H., Seiffert, E.R., & Boyer, D.M. (2019). Vertical support use and primate origins. Scientific reports, 9(1), 1-10.<br>
Yapuncich, G.S., Feng, H.J., Dunn, R.H., Seiffert, E.R., & Boyer, D.M. (2019). Vertical support use and primate origins. Scientific reports, 9, 1-10.<br>


Yopak, K.E., Carrier, J.C., & Summers, A.P. (2018). Imaging technologies in the field and laboratory. In Shark Research: Emerging Technologies and Applications for the Field and Laboratory. J.C. Carrier & M.R. Heithaus, eds.<br>
Yopak, K.E., Carrier, J.C., & Summers, A.P. (2018). Imaging technologies in the field and laboratory. In Shark Research: Emerging Technologies and Applications for the Field and Laboratory. J.C. Carrier & M.R. Heithaus, eds.<br>
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