The investigation of form-function relationships requires a detailed understanding of anatomical systems. Here we document the 3-dimensional morphology of the cranial musculoskeletal anatomy in the Australian Laughing Kookaburra Dacelo novaeguineae, with a focus upon the geometry and attachments of the jaw muscles in this species. The head of a deceased specimen was CT scanned, and an accurate 3D representation of the skull and jaw muscles was generated through manual segmentation of the CT scan images, and augmented by dissection of the specimen. We identified 14 major jaw muscles: 6 in the temporal group (M. adductor mandibulae and M. pseudotemporalis), 7 in the pterygoid group (M. pterygoideus dorsalis and M. pterygoideus ventralis), and the single jaw abductor M. depressor mandibulae. Previous descriptions of avian jaw musculature are hindered by limited visual representation and inconsistency in the nomenclature. To address these issues, we: (1) present the 3D model produced from the segmentation process as a digital, fully interactive model in the form of an embedded 3D image, which can be viewed from any angle, and within which major components can be set as opaque, transparent, or hidden, allowing the anatomy to be visualised as required to provide a detailed understanding of the jaw anatomy; (2) provide a summary of the nomenclature used throughout the avian jaw muscle literature. The approach presented here provides considerable advantages for the documentation and communication of detailed anatomical structures in a wide range of taxa.
References
[1]
Baeumler N, Haszprunar G, Ruthensteiner B. 2008. 3D interactive microanatomy of Omalogyra atomus (Philippi, 1841)(Gastropoda) Zoosymposia 1:101-118
[2]
Barnes DG, Fluke CJ. 2008. Incorporating interactive three-dimensional graphics in astronomy research papers. New Astronomy 13:599-605
[3]
Barnes DG, Fluke CJ, Bourke PD, Parry OT. 2006. An advanced, three-dimensional plotting library for astronomy. Publications of the Astronomical Society of Australia 23:82-93
[4]
Barnes DG, Vidiassov M, Ruthensteiner B, Fluke CJ, Quayle MR, McHenry CR. 2013. Embedding and publishing interactive, 3-dimensional, scientific figures in portable document format (PDF) files. PLoS ONE 8:e69446
[5]
1993. Baumel JJ, King AS, Breazile JE, Evans HE, Vanden Berge JC, eds. Handbook of avian anatomy: Nomina Anatomica Avium (2nd edition). Cambridge, MA: Nuttall Ornithological Club.
[6]
Birr S, Monch J, Sommerfeld D, Preim U, Preim B. 2013. The LiverAnatomyExplorer: a WebGL-based surgical teaching tool. Computer Graphics and Applications, IEEE 33:48-58
[7]
Burton PJK. 1984. Anatomy and evolution of the feeding apparatus in the avian orders Coraciiformes and Piciformes. Bulletin of the British Museum (Natural History Zoology series) 47:331-443
[8]
de Bakker BS, de Jong KH, Hagoort J, Oostra R-J, Moorman AFM. 2012. Towards a 3-dimensional atlas of the developing human embryo: the Amsterdam experience. Reproductive Toxicology 34:225-236
[9]
Elzanowski A. 1987. Cranial and eyelid muscles and ligaments of the tinamous (Aves: Tinaformes) Zoologische Jahrbücher Abteilung für Anatomie und Ontogenie der Tiere 116:63-118
[10]
Ferrara T, Clausen P, Huber D, McHenry C, Peddemors V, Wroe S. 2011. Mechanics of biting in great white and sandtiger sharks. Journal of Biomechanics 44:430-435
[11]
Ghetie V, Chitescu S, Cotofan V, Hillebrand A. 1976. Atlas de Anatomie a Pasarilor Domestice. Romania: Editura Academiei Republicii Socialiste Romania.
[12]
Ginsburg D, Gerhard S, Calle JE, Pienaar R. 2011. Realtime visualization of the connectome in the browser using WebGL [Conference Abstract: 4th INCF Congress of Neuroinformatics]. Front. Neuroinform.
[13]
Herrel A, O’Reilly J, Richmond A. 2002. Evolution of bite performance in turtles. Journal of Evolutionary Biology 15:1083-1094
[14]
Herring SW, Rafferty KL, Liu ZJ, Marshall CD. 2001. Jaw muscles and the skull in mammals: the biomechanics of mastication. Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology 131:207-219
[15]
Holliday CM, Tsai HP, Skiljan RJ, George ID, Pathan S. 2013. A 3D interactive model and atlas of the jaw musculature of Alligator mississippiensis. PLoS ONE 8:e62806
[16]
Holliday CM, Witmer LM. 2007. Archosaur adductor chamber evolution: integration of musculoskeletal and topological criteria in jaw muscle homology. Journal of Morphology 268:457-484
[17]
Knoll F, Witmer LM, Ortega F, Ridgely RC, Schwarz-Wings D. 2012. The braincase of the basal sauropod dinosaur Spinophorosaurus and 3D reconstructions of the cranial endocast and inner ear. PLoS ONE 7:e30060
[18]
Kumar P, Vahedi-Faridi A, Saenger W, Merino E, de Castro JAL, Uchanska-Ziegler B, Ziegler A. 2009. Structural basis for T cell alloreactivity among three HLA-B14 and HLA-B27 antigens. Journal of Biological Chemistry 284:29784-29797
[19]
Lauder GV, Huey RB, Monson RK, Jensen RJ. 1995. Systematics and the study of organismal form and function. BioScience 45:696-704
[20]
Lautenschlager S. 2013. Palaeontology in the third dimension: a comprehensive guide for the integration of three-dimensional content in publications. Palontologische Zeitschrift 88:111-121
[21]
Lautenschlager S, Bright JA, Rayfield EJ. 2013. Digital dissection–using contrast-enhanced computed tomography scanning to elucidate hard- and soft-tissue anatomy in the Common Buzzard Buteo buteo. Journal of Anatomy 224:412-431
[22]
Neusser TP, He M, Schrdl M. 2009. Tiny but complex-interactive 3D visualization of the interstitial acochlidian gastropod Pseudunela cornuta (Challis, 1970) Frontiers in Zoology 6:20
[23]
Pettit J, Marioni J. 2013. BioWeb3D: an online webGL 3D data visualisation tool. BMC Bioinformatics 14:185
[24]
Quayle MR. 2011. A morphological study of the kingfisher skull. Environmental science and management honours thesis, University of Newcastle
[25]
Richards LP, Bock WJ. 1973. Functional anatomy and adaptive evolution of the feeding apparatus in the Hawaiian honeycreeper genus Loxops (Drepanididae) Ornithological Monographs 86:489-491
[26]
Russell E. 1916. Form and function. A contribution to the history of animal morphology. London: J. Murray. (Reprint Chicago University Press 1982)
[27]
Ruthensteiner B, He M. 2008. Embedding 3D models of biological specimens in PDF publications. Microscopy Research and Technique 71:778-786
[28]
Selvam L, Vasilyev V, Wang F. 2009. Methylation of zebularine: a quantum mechanical study incorporating interactive 3D pdf graphs. The Journal of Physical Chemistry B 113:11496-11504
[29]
Thompson DAW. 1917. On growth and form. Cambridge: Cambridge University Press.
[30]
Wroe S, McHenry C, Thomason J. 2005. Bite club: comparative bite force in big biting mammals and the prediction of predatory behaviour in fossil taxa. Proceedings of the Royal Society B: Biological Sciences 272:619-625
[31]
Ziegler A, Faber C, Mueller S, Bartolomaeus T. 2008. Systematic comparison and reconstruction of sea urchin (Echinoidea) internal anatomy: a novel approach using magnetic resonance imaging. BMC Biology 6:33
[32]
Zusi RL, Storer RW. 1969. Osteology and myology of the head and neck of the pied-billed grebes (Podilymbus) University of Michigan Miscellaneous Publications of the Museum of Zoology 139:1-49
[33]
Zweers GA. 1974. Structure, movement, and myography of the feeding apparatus of the mallard (Anas platyrhynchos L.) A study in functional anatomy. Netherlands Journal of Zoology 24:323-467