MorphoMuseuM Volume 01, Issue 03:November 2015
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3D model related to the publication: A pangolin (Manidae, Pholidota, Mammalia) from the French Quercy phosphorites (Pech du Fraysse, Saint-Projet, Tarn-et-Garonne, late Oligocene, MP 28)Jean-Yves Crochet, Lionel Hautier and Thomas LehmannPublished online: 2015-09-16Keywords: Oligocene; Pangolin; Pech du Fraysse; Quercy Phosphorites doi: 10.18563/m3.1.3.e1 Abstract This contribution contains the 3D model described and figured in the following publication: Crochet, J.-Y., Hautier, L., Lehmann, T., 2015. A pangolin (Manidae, Pholidota, Mammalia) from the French Quercy phosphorites (Pech du Fraysse, Saint-Projet, Tarn-et-Garonne, late Oligocene, MP 28). Palaeovertebrata 39(2)-e4. doi: 10.18563/pv.39.2.e4 Necromanis franconica UM PFY 4051 View specimen
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3D cranium models of fossils of large canids (Canis lupus) from Goyet, Trou des Nutons and Trou Balleux, BelgiumAllowen Evin, Emmanuel Gilissen and Mietje GermonpréPublished online: 2015-11-06Keywords: Archaeozoology; Dog; Domestication; Pleistocene; Wolf doi: 10.18563/m3.1.3.e2 Abstract Archaeozoological studies are increasingly using new methods and approaches to explore questions about domestication. Here, we provide 3D models of three archaeological Canis lupus skulls from Belgium originating from the sites of Goyet (31,680±250BP; 31,890+240/-220BP), Trou des Nutons (21,810±90BP) and Trou Balleux (postglacial). Since their identification as either wolves or early dogs is still debated, we present these models as additional tools for further investigating their evolutionary history and the history of dog domestication. Canis lupus Goyet 2860 View specimen
Canis lupus Trou Balleux no-nr View specimen
Canis lupus Trou des Nutons 2559-1 View specimen
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3D models related to the publication: Morphology of the human embryonic brain and ventriclesNaoki Shiraishi, Airi Katayama, Takashi Nakashima, Naoto Shiraki, Shigehito Yamada, Chigako Uwabe, Katsumi Kose and Tetsuya TakakuwaPublished online: 2015-07-27Keywords: human brain; human embryo; magnetic resonance imaging; three-dimensional reconstruction doi: 10.18563/m3.1.3.e3 Abstract This contribution contains the 3D models described and figured in the following publication: Shiraishi N et al. Morphology and morphometry of the human embryonic brain: A three-dimensional analysis NeuroImage 115, 2015, 96-103, DOI: 10.1016/j.neuroimage.2015.04.044. Homo sapiens KC-CS13BRN50455 View specimen
Homo sapiens KC-CS14BRN18834 View specimen
Homo sapiens KC-CS15BRN19975 View specimen
Homo sapiens KC-CS16BRN7870 View specimen
Homo sapiens KC-CS17BRN26702 View specimen
Homo sapiens KC-CS18BRN25914 View specimen
Homo sapiens KC-CS19BRN16508 View specimen
Homo sapiens KC-CS20BRN26581 View specimen
Homo sapiens KC-CS21BRN33434 View specimen
Homo sapiens KC-CS22BRN27960 View specimen
Homo sapiens KC-CS23BRN28189 View specimen
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The endocranial cast of Microchoerus erinaceus (Euprimates, Tarsiiformes).Maëva OrliacPublished online: 2015-09-24Keywords: endocast; Late Eocene; Omomyiformes; Primate doi: 10.18563/m3.1.3.e4 Abstract This contribution contains the 3D model described and figured in the following publication: Ramdarshan A., Orliac M.J., 2015. Endocranial morphology of Microchoerus erinaceus (Euprimates, Tarsiiformes) and early evolution of the Euprimates brain. American Journal of Physical Anthropology. doi: 10.1002/ajpa.22868 Microchoerus erinaceus UM-PRR1771 View specimen
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3D models related to the publication: Morphological and functional changes in the vertebral column with increasing aquatic adaptation in crocodylomorphsJulia Molnar, Stephanie Pierce, Bhart-Anjan Bhullar, Alan Turner and John HutchinsonPublished online: 2015-11-06Keywords: archosaur; axial skeleton; Vertebrae doi: 10.18563/m3.1.3.e5 Abstract This contribution contains the 3D models described and figured in the following publication: Molnar, JL, Pierce, SE, Bhullar, B-A, Turner, AH, Hutchinson, JR (accepted). Morphological and functional changes in the crocodylomorph vertebral column with increasing aquatic adaptation. Royal Society Open Science. Protosuchus richardsoni AMNH-VP 3024 View specimen
Terrestrisuchus gracilis NHM-PV R 7562 View specimen
Pelagosaurus typus NHM-PV OR 32598 View specimen
Metriorhynchus superciliosus NHM-PV R 2054 View specimen
Crocodylus niloticus FNC0 View specimen
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3D models related to the publication: Morphogenesis of the inner ear at different stages of normal human developmentSaki Toyoda, Naoto Shiraki, Shigehito Yamada, Chigako Uwabe, Hirohiko Imai, Tetsuya Matsuda, Akio Yoneyama, Tohoru Takeda and Tetsuya TakakuwaPublished online: 2015-10-22Keywords: human embryo; human inner ear; magnetic resonance imaging; phase-contrast X-ray CT; three-dimensional reconstruction doi: 10.18563/m3.1.3.e6 Abstract The present 3D Dataset contains the 3D models analyzed in: Toyoda S et al., 2015, Morphogenesis of the inner ear at different stages of normal human development. The Anatomical Record. doi : 10.1002/ar.23268 Homo sapiens KC-CS17IER29248 View specimen
Homo sapiens KC-CS18IER17746 View specimen
Homo sapiens KC-CS19IER16127 View specimen
Homo sapiens KC-CS20IER20268 View specimen
Homo sapiens KC-CS21IER28066 View specimen
Homo sapiens KC-CS22IER35233 View specimen
Homo sapiens KC-CS23IER15919 View specimen
Homo sapiens KC-FIER52730 View specimen
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