Since the 1980s, various techniques have been used in the field of medicine for the post-processing of medical imaging data from computed tomography (CT) and magnetic resonance (MR). They include multiplanar reformations (MPR), maximum intensity projection (MIP) and Volume Rendering (VR). This paper presents the prototype of a new means of post-processing radiological examinations such as CT and MR, a technique that, for the first time, provides photorealistic visualizations of the human body. This new procedure was inspired by the quality of images achieved by animation software such as programs used in the entertainment industry, particularly to produce animated films. Thus, the name: Cinematic Rendering. It is already foreseeable that this new method of depiction will quickly be incorporated into the set of instruments employed in socalled virtual anatomy (teaching anatomy through the use of radiological depictions of the human body via X-ray, CT and MR in addition to the use of computer animation programs designed especially for human anatomy). Its potential for medical applications will have to be evaluated by future scientific investigations.
References
[1]
Wallis, J.W., Miller, T.R., Lerner, C.A. and Kleerup, E.C. (1989) Three-Dimensional Display in Nuclear Medicine. IEEE Transactions on Medical Imaging, 8, 297-303. http://dx.doi.org/10.1109/42.41482
[2]
Calhoun, P.S., Kuszyk, B.S., Heath, D.G., Carley, J.C. and Fishman, E.K. (1999) Three-Dimensional Volume Rendering of Spiral CT Data: Theory and Method. Radiographics, 19, 745-764. http://dx.doi.org/10.1148/radiographics.19.3.g99ma14745
[3]
Levoy, M. (1988) Display of Surfaces from Volume Data. IEEE Computer Graphics and Applications, 8, 29-37. http://dx.doi.org/10.1109/38.511
[4]
Drebin, R.A., Carpenter, L. and Hanrahan, P. (1988) Volume Rendering. Computers & Graphics, 22, 65-74. http://dx.doi.org/10.1145/378456.378484
[5]
Fishman, E.K., Drebin, B., Magid, D., Scott Jr., W.W., Ney, D.R., Brooker Jr., A.F., Riley Jr., L.H., St Ville, J.A., Zerhouni, E.A. and Siegelman, S.S. (1987) Volumetric Rendering Techniques: Applications for Three-Dimensional Imaging of the Hip. Radiology, 163, 733-738. http://dx.doi.org/10.1148/radiology.163.3.3575725
[6]
Catmull, E., Fishman, E.K., Horton, K.M. and Raman, S.P. (2015) From Toy Story to CT Scans: Lessons from Pixar for Radiology. Journal of the American College of Radiology, 12, 978-979. http://dx.doi.org/10.1016/j.jacr.2014.08.010
[7]
Levoy, M. (1990) Efficient Ray Tracing of Volume Data. ACM Transactions on Graphics, 9, 245-261. http://dx.doi.org/10.1145/78964.78965
[8]
Westermann, R. and Ertl, T. (1998) Efficiently Using Graphics Hardware in Volume Rendering Applications. SIGGRAPH 98 Proceedings of the 25th Annual Conference on Computer Graphics and Interactive Techniques, 169-177. http://dx.doi.org/10.1145/280814.280860
[9]
Roettger, S., Guthe, S., Weiskopf, D. and Ertl, T. (2003) Smart Hard-ware-Accelerated Volume Rendering. Proceedings of EG/IEEEE TCVG Symposium on Visualization VisSym’03, 231-238
[10]
Csébfalvi, B. and Szirmay-Kalos, S. (2003) Monte Carlo Volume Rendering. VIS’03 Proceedings of the 14th IEEE Visualization, 59. http://dx.doi.org/10.1109/visual.2003.1250406
[11]
Ropinski, T., Doring, C. and Rezk-Salama, C. (2010) Interactive Volumetric Lighting Simulating Scattering and Shadowing. Proceedings of IEEE Pacific Visualization, 169-176.
[12]
Kroes, T., Post, F.H. and Botha, C.P. (2012) Exposure Render: An Interactive Photo-Realistic Volume Rendering Framework. PLoS ONE, 7, e38586. http://dx.doi.org/10.1371/journal.pone.0038586
