Inner ear morphology in wild vs laboratory mice
Holotype of Hamadasuchus rebouli
3D models related to the publication: Shape diversity in conodont elements, a quantitative study using 3D topography
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) , South America (8) , Eocene (8) , skull (7) , brain (6) , Oligocene (6)
Maëva Judith Orliac (17) , Lionel Hautier (17) , Bastien Mennecart (12) , Laurent Marivaux (11) , Pierre-Olivier Antoine (11) , Leonardo Kerber (10) , Renaud Lebrun (9)
3D model of the brain endocast
Data citation: Ane E. B. Pavanatto , Leonardo Kerber and Sérgio Dias-da-Silva , 2019. M3#426. doi: 10.18563/m3.sf.426
Model solid/transparent
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3D models related to the publication: Virtual reconstruction of cranial endocasts of traversodontid cynodonts (Eucynodontia: Gomphodontia) from the upper Triassic of Southern Brazil.Ane E. B. Pavanatto, Leonardo Kerber and Sérgio Dias-da-SilvaPublished online: 10/09/2019Keywords: CT-scan; Cynognathia; endocranial morphology; Exaeretodon; Siriusgnathus https://doi.org/10.18563/journal.m3.97 Abstract The present 3D Dataset contains the 3D models of brain endocast of traversodontid cynodonts studied in: Pavanatto et al. 2019. Virtual reconstruction of cranial endocasts of traversodontid cynodonts (Eucynodontia: Gomphodontia) from the upper Triassic of Southern Brazil. Journal of Morphology. https://doi.org/10.1002/jmor.21029 See original publication M3 article infos Published in Volume 05, issue 04 (2019) |
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