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DOI: 10.1055/s-0039-1683964
Three-dimensional Cat Virtual Anatomy: Development of an Interactive Virtual Anatomical Software
Publication History
02 August 2018
11 February 2019
Publication Date:
23 May 2019 (online)
Abstract
Background Three-dimensional (3D) virtual models are novel tools to teach veterinary anatomy.
Objective The aim of the present study was to create a 3D cat image software and a library of cross-sectional images.
Methods Modeling of the 3D cat organs and structures was done with Autodesk Maya, version 2017 (Autodesk Inc., San Rafael, California, USA) and ZBrush, version 4R7 (Pixologic, Los Angeles, CA, USA) software. In order to obtain the images for the library, three cadavers of adult cats were used, with the following techniques: 1) scanning by magnetic resonance imaging (MRI) at 3-mm intervals, 2) scanning by computed tomography (CT) at 2-mm intervals, and 3) photographing of 178 transverse cuts at 2.5-mm intervals from the frozen cadavers. Out of all the images, thirty images of each technique were selected. An interactive software was developed with the modeled 3D cat and the selected images using Unity, version 5.4 (Unity Technologies, San Francisco, CA, USA).
Results A virtual 3D cat model was obtained with 418 labeled structures of the skeletal, muscular, circulatory, nervous, respiratory, digestive, urinary, and integumentary systems. The virtual interface enables the manipulation of the 3D cat in all views and the visualization of the selected images in a chosen localization along the body of the cat. The library of images allows comparison among CT, MRI and photographs of transverse cuts.
Conclusions The software interface facilitates the access to the content for the user. Sectional images of the cat and of its body structures can be easily understood. This new 3D software of cat anatomy is another tool that can be used in teaching veterinary anatomy.
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References
- 1 Lewis TL, Burnett B, Tunstall RG, Abrahams PH. Complementing anatomy education using three-dimensional anatomy mobile software applications on tablet computers. Clin Anat 2014; 27 (03) 313-320
- 2 Nicholson DT, Chalk C, Funnell WRJ, Daniel SJ. Can virtual reality improve anatomy education? A randomised controlled study of a computer-generated three-dimensional anatomical ear model. Med Educ 2006; 40 (11) 1081-1087
- 3 Jang HG, Chung MS, Shin DS. , et al. Segmentation and surface reconstruction of the detailed ear structures, identified in sectioned images. Anat Rec (Hoboken) 2011; 294 (04) 559-564
- 4 Allen LK, Bhattacharyya S, Wilson TD. Development of an interactive anatomical three-dimensional eye model. Anat Sci Educ 2015; 8 (03) 275-282
- 5 Nowinski WL, Thirunavuukarasuu A, Volkau I. , et al. A new presentation and exploration of human cerebral vasculature correlated with surface and sectional neuroanatomy. Anat Sci Educ 2009; 2 (01) 24-33
- 6 Geyer LL, Schoepf UJ, Meinel FG. , et al. State of the art: iterative CT reconstruction techniques. Radiology 2015; 276 (02) 339-357
- 7 Henn JS, Lemole Jr GM, Ferreira MA. , et al. Interactive stereoscopic virtual reality: a new tool for neurosurgical education. Technical note. J Neurosurg 2002; 96 (01) 144-149
- 8 Martinsen S, Jukes N. Towards a humane veterinary education. J Vet Med Educ 2005; 32 (04) 454-460
- 9 Preece D, Williams SB, Lam R, Weller R. “Let's get physical”: advantages of a physical model over 3D computer models and textbooks in learning imaging anatomy. Anat Sci Educ 2013; 6 (04) 216-224
- 10 Leung KK, Lu KS, Huang TS, Hsieh BS. Anatomy instruction in medical schools: connecting the past and the future. Adv Health Sci Educ Theory Pract 2006; 11 (02) 209-215
- 11 Shin DS, Chung MS, Park JS. , et al. Three-dimensional surface models of detailed lumbosacral structures reconstructed from the Visible Korean. Ann Anat 2011; 193 (01) 64-70
- 12 Park JS, Chung MS, Hwang SB, Lee YS, Har DH. Technical report on semiautomatic segmentation using the Adobe Photoshop. J Digit Imaging 2005; 18 (04) 333-343
- 13 Segars WP, Mahesh M, Beck TJ, Frey EC, Tsui BM. Realistic CT simulation using the 4D XCAT phantom. Med Phys 2008; 35 (08) 3800-3808
- 14 Segars WP, Tsui BM, Frey EC, Johnson GA, Berr SS. Development of a 4-D digital mouse phantom for molecular imaging research. Mol Imaging Biol 2004; 6 (03) 149-159
- 15 Lauridsen H, Hansen K, Wang T. , et al. Inside out: modern imaging techniques to reveal animal anatomy. PLoS One 2011; 6 (03) e17879
- 16 Spitzer V, Ackerman MJ, Scherzinger AL, Whitlock D. The visible human male: a technical report. J Am Med Inform Assoc 1996; 3 (02) 118-130
- 17 Schiemann T, Freudenberg J, Pflesser B. , et al. Exploring the Visible Human using the VOXEL-MAN framework. Comput Med Imaging Graph 2000; 24 (03) 127-132
- 18 Zhang SX, Heng PA, Liu ZJ. Chinese visible human project. Clin Anat 2006; 19 (03) 204-215
- 19 Park JS, Chung MS, Hwang SB, Shin BS, Park HS. Visible Korean Human: its techniques and applications. Clin Anat 2006; 19 (03) 216-224
- 20 Paul Segars W, Tsui BM. MCAT to XCAT: The Evolution of 4-D Computerized Phantoms for Imaging Research: Computer models that take account of body movements promise to provide evaluation and improvement of medical imaging devices and technology. Proc IEEE Inst Electr Electron Eng 2009; 97 (12) 1954-1968
- 21 Dogdas B, Stout D, Chatziioannou AF, Leahy RM. Digimouse: a 3D whole body mouse atlas from CT and cryosection data. Phys Med Biol 2007; 52 (03) 577-587
- 22 Böttcher P, Maierl J. Macroscopic cryosectioning: a simple new method for producing digital, three-dimensional databases in veterinary anatomy. Anat Histol Embryol 1999; 28 (02) 97-102
- 23 Park HS, Shin DS, Cho DH, Jung YW, Park JS. Improved sectioned images and surface models of the whole dog body. Ann Anat 2014; 196 (05) 352-359