Digital reconstruction of the skull of Sarmientosaurus musacchioi
3D models of Peratherium musivum and Pt. maximum (early Eocene, France)
3D models of amphisbaenians from the Paleogene of North Africa
3D GM dataset of bird skeletal variation
Skeletal embryonic development in the catshark
Bony connexions of the petrosal bone of extant hippos
bony labyrinth (11) , inner ear (10) , Eocene (8) , South America (8) , Paleobiogeography (7) , skull (7) , phylogeny (6)
Maëva Judith Orliac (21) , Lionel Hautier (21) , Laurent Marivaux (14) , Bastien Mennecart (12) , Pierre-Olivier Antoine (11) , Renaud Lebrun (10) , Rodolphe Tabuce (10)
MorphoMuseuM Volume 10, issue 02
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3D dataset3D models related to the publication: Comparative anatomy of the vocal apparatus in bats and implication for the diversity of laryngeal echolocation.Nicolas L. M. Brualla
Published online: 28/06/2024 |
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M3#1305Laryngeal cartilages and muscles of the cave nectar bat Type: "3D_surfaces"doi: 10.18563/m3.sf.1305 state:published |
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Macroglossus sobrinus VN15-017 View specimen
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M3#1306Laryngeal anatomy of Macroglossus sobrinus Type: "3D_surfaces"doi: 10.18563/m3.sf.1306 state:published |
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Aselliscus dongbacana VTTu15-013 View specimen
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M3#1307Laryngeal anatomy of Aselliscus dongbacana Type: "3D_surfaces"doi: 10.18563/m3.sf.1307 state:published |
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Coelops frithii VN19-196 View specimen
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M3#1308Laryngeal anatomy of Coelops frithii Type: "3D_surfaces"doi: 10.18563/m3.sf.1308 state:published |
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Hipposideros larvatus VN18-209 View specimen
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M3#1309Laryngeal anatomy of Hipposideros larvatus Type: "3D_surfaces"doi: 10.18563/m3.sf.1309 state:published |
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Rhinolophus cornutus JP21-025 View specimen
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M3#14763D surfaces of Rhinolophus cornutus Type: "3D_surfaces"doi: 10.18563/m3.sf.1476 state:published |
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Rhinolophus macrotis VN11-089 View specimen
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M3#1477Laryngeal cartilages and muscles of Rhinolophus macrotis Type: "3D_surfaces"doi: 10.18563/m3.sf.1477 state:published |
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Lyroderma lyra VN17-535 View specimen
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M3#1312Laryngeal anatomy of Lyroderma lyra Type: "3D_surfaces"doi: 10.18563/m3.sf.1312 state:published |
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Saccolaimus mixtus A3257 View specimen
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M3#1478Laryngeal components of Saccolaimus mixtus Type: "3D_surfaces"doi: 10.18563/m3.sf.1478 state:published |
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Taphozous melanopogon VN17-0252 View specimen
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M3#1479Laryngeal cartilages and muscles of Taphozous melanopogon Type: "3D_surfaces"doi: 10.18563/m3.sf.1479 state:published |
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Artibeus jamaicensis AJ001 View specimen
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M3#1316Laryngeal anatomy of Artibeus jamaicensis Type: "3D_surfaces"doi: 10.18563/m3.sf.1316 state:published |
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Kerivoula hardwickii VN11-0043 View specimen
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M3#1317Laryngeal anatomy of Kerivoula hardwickii Type: "3D_surfaces"doi: 10.18563/m3.sf.1317 state:published |
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Myotis ater VN19-016 View specimen
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M3#1318Laryngeal anatomy of Myotis ater Type: "3D_surfaces"doi: 10.18563/m3.sf.1318 state:published |
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Myotis siligorensis VTTu14-018 View specimen
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M3#1319Laryngeal anatomy of Myotis siligorensis Type: "3D_surfaces"doi: 10.18563/m3.sf.1319 state:published |
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Suncus murinus KATS_835A View specimen
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M3#1395Laryngeal anatomy of Suncus murinus Type: "3D_surfaces"doi: 10.18563/m3.sf.1395 state:published |
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Boonman A, Bumrungsri S, Yovel Y, 2014. Nonecholocating fruit bats produce biosonar clicks with their wings. Current Biology: CB 24: 2962–7. https://doi.org/10.1016/j.cub.2014.10.077
Brualla NLM, Wilson LA, Doube M, Carter RT, McElligott ME, Koyabu D, 2023. The vocal apparatus: an understudied tool to reconstruct the evolutionary history of echolocation in bats? Journal of Mammalian Evolution 30: 79–94. https://doi.org/10.1093/zoolinnean/zlad180
Brualla NLM, Wilson LA, Tu VT, Nojiri T, Carter RT, Ngamprasertwong T, Wannaprasert T, Doube M, Fukui D, Koyabu D, 2024: Comparative anatomy of the vocal apparatus in bats and implication for the diversity of laryngeal echolocation. Zoological Journal of the Linnean Society, vol. zlad180. https://doi.org/10.1093/zoolinnean/zlad180.
Chaverri G, Ancillotto L, Russo D, 2018. Social communication in bats. Biological Reviews of the Cambridge Philosophical Society 93: 1938–54. https://doi.org/10.1111/brv.12427
Davies KTJ, Maryanto I, Rossiter SJ, 2013. Evolutionary origins of ultrasonic hearing and laryngeal echolocation in bats inferred from morphological analyses of the inner ear. Frontiers in Zoology 10: 2. https://doi.org/10.1186/1742-9994-10-2
Griffin DR, 1944. Echolocation by blind men, bats and radar. Science 100:589–90. https://doi.org/10.1126/science.100.2609.589
Harrison DFN, 1995. The Anatomy and Physiology of the Mammalian Larynx, 1st edn. Cambridge, UK: Cambridge University Press.
Metzner W, Müller R, 2016. Ultrasound production, emission, and reception. In: Fenton MB, Grinnell AD, Popper AN, Fay RR (eds), Bat Bioacoustics. New York, NY, USA: Springer, 55–91.
Metzner W, Schuller G, 2010. Vocal control in echolocating bats. In: Brudzynski SM (ed.), Handbook of Behavioral Neuroscience. London, UK: Elsevier, 403–15.
Nojiri T, Wilson LAB, López-Aguirre C, Tu VT, Kuratani S, Ito K, Higashiyama H, Son NT, Fukui D, Sadier A, Sears KE, 2021. Embryonic evidence uncovers convergent origins of laryngeal echolocation in bats. Current Biology 31: 1353–1365.e3. https://doi.org/10.1016/j.cub.2020.12.043
Rayner JMV, 1988. The evolution of vertebrate flight. Biological Journal of the Linnean Society 34:269–87. https://doi.org/10.1111/j.1095-8312.1988.tb01963.x
Saigusa H, 2011. Comparative anatomy of the larynx and related structures. Japan Medical Association Journal 54: 241–7.
Simmons NB, Cirranello AL, 2020. Bats of the world: a taxonomic and geographic database. American Museum of Natural History
Suthers RA, 2004. Vocal mechanisms in birds and bats: a comparative view. Anais da Academia Brasileira de Ciencias 76: 247–52. https://doi.org/10.1590/s0001-37652004000200009
Teeling EC. Bats (Chiroptera). 2009. In: Hedges SB, Kumar S (eds), The Timetree of Life. Oxford, UK: Oxford University Press 499–503
Veselka N, McErlain DD, Holdsworth DW, Eger JL, Chhem RK, Mason MJ, Brain KL, Faure PA, Fenton MB, 2010. A bony connection signals laryngeal echolocation in bats. Nature 463: 939–42. https://doi.org/10.1038/nature08737
Wang Z, Zhu T, Xue H, Fang N, Zhang J, Zhang L, Pang J, Teeling EC, Zhang S, 2017. Prenatal development supports a single origin of laryngeal echolocation in bats. Nature Ecology & Evolution 1: 1–5. https://doi.org/10.1038/s41559-016-0021
Yovel Y, Geva-Sagiv M, Ulanovsky N, 2011. Click-based echolocation in bats: not so primitive after all. Journal of Comparative Physiology. A, Neuroethology, Sensory, Neural, and Behavioral Physiology 197: 515–30. https://doi.org/10.1007/s00359-011-0639-4
