Authors: G. Aloisio, L. T. De Paolis, A. De Mauro, A. Mongelli

Abstract:

One of the essential requirements of a realistic surgical simulator is to reproduce haptic sensations due to the interactions in the virtual environment. However, the interaction need to be performed in real-time, since a delay between the user action and the system reaction reduces the immersion sensation. In this paper, a prototype of a coronary stent implant simulator is present; this system allows real-time interactions with an artery by means of a specific haptic device. To improve the realism of the simulation, the building of the virtual environment is based on real patients- images and a Web Portal is used to search in the geographically remote medical centres a virtual environment with specific features in terms of pathology or anatomy. The functional architecture of the system defines several Medical Centres in which virtual environments built from the real patients- images and related metadata with specific features in terms of pathology or anatomy are stored. The searched data are downloaded from the Medical Centre to the Training Centre provided with a specific haptic device and with the software necessary both to manage the interaction in the virtual environment. After the integration of the virtual environment in the simulation system it is possible to perform training on the specific surgical procedure.

Keywords: Medical Simulation, Web Portal, Virtual Reality.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1061350

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1751

References:

[1] S.L. Dawson, S. Cotin, D. Meglan, D.W. Shaffer, M.A. Ferrell, "Designing a Computer-Based Simulator for Interventional Cardiology Training, Catheterization and Cardiovascular Interventions", Wiley Press, Vol.51, 2000, pp. 522-527.
[2] E. Gobbetti, P. Pili, A. Zorcolo, M. Tuveri, "Interactive Virtual Angiography", IEEE Computer Society Press, 1998, pp. 435-438.
[3] M. Urbino, J. Tasto, B. Nguyen, R. Cunningham, G. Merrill, "CathSim: an Intravascular Catheterization Simulator on a PC", Proc. Medicine Meets Virtual Reality, IOS Press, Amsterdam, 1999, pp. 360-366.
[4] Immersion Medical, Inc., http://www.immersion.com/medical/
[5] Mentice Corporation, Sweden, http://www.mentice.com
[6] M.F. Beg, C. Ceritoglu, A.E. Kolasny, C.E. Priebe, J.T. Rathahather, P. Yu, R. Yashinski, L. Younes, J. Jovicich, R.L. Buckner, S. Pieper, B. Fischl, M.I. Miller, "Biomedical Informatics Research Network: Multisite Processing pipeline for shape analysis of brain structures", Proc. Human Brain Mapping, Budapest, Hungary, 2004.
[7] J. Pytlinski, L. Skorwider, P. Bala, M. Nazaruk, K Wawruch, "BioGRID - Uniform Platform for Biomolecular Applications", Lecture Notes in Computer Science, Springer-Verlag , pp. 881-884, 2002.
[8] S. Martin, D. Pike, "Using Web services in the European Grid of Solar Observation (EGSO)", Proc. First European Workshop on Object Orientation and Web Services - ECOOP 2003, Darmstadt, Germany, 2003.
[9] C.T. Liu, A.G. Long, Y.C. Li, K.C. Tsai, Kuo, H.S., "Sharing Patient Care Records over the World Wide Web", International Journal of Medical Informatics, 61, pp. 189-205, 2001.
[10] Aloisio G., Bergamasco M. et al., "Computer-Based Simulator for Catheter Insertion Training", Medicine Meets Virtual Reality 12 , J.D. Westwood et al. (Eds.), IOS Press, Vol.98, pp. 4-6, 2004.
[11] Aloisio G., De Paolis L.T., Provenzano L., "An Integrated System for the Angioplasty Intervention Simulation", Proc. of Medicon & Health Telematics 2004, Vol. 6, Ischia, Italy, 2004.
[12] Aloisio G., De Paolis L.T., Mongelli A., Provenzano L., "Artery Soft- Tissue Modelling for Stent Implant Training System", Journal of Systemics, Cybernetics and Informatics, 2(4), 2004.
[13] Van den Bergen G., "Collision Detection in Interactive 3D Environments", Elsevier Morgan Kaufmann Publishers, San Francisco, 2004.
[14] Cotin S., Delingette H., Ayache N., "Real-time Elastic Deformations of Soft Tissues for Surgery Simulation", IEEE Transactions on Visualization and Computer Graphics, Vol.5, pp. 62-73, 1999.
[15] Gottschalk K., Graham S., Kreger H., Snell J., "Introduction to Web Services Architecture", IBM Systems Journal, Vol.41, pp. 170-177, 2002.
[16] Pierce M., Youn C., Balsoy O., Fox G., Mock S., Mueller, K., "Interoperable Web Services for Computational Portals", Proc. of 2002 ACM/IEEE Conf. on Supercomputing, Baltimore, Maryland, USA, pp. 1- 12, 2002.
[17] Pierce M., Youn C., Fox G., "Application Web Services", Internal Comm. Grid Lab Report.
[18] Kneoaurek K., Ivanovic M., Machac J., Weber D.A., "Medical Image Registration", Europhysics News, 31(4), pp. 5-8, 2000.
[19] Van Den Elsen P.A., Viergever M.A., Pol E.J., "Medical Image Matching - a Review with Classification", Proc. of IEEE Engineering in Medicine and Biology, 12, pp. 26-39, 1993.
[20] Lorensen W., Cline H., "Marching Cubes: a High Resolution 3D Surface Construction Algorithm", Proc. of SIGGRAPH '87, pp. 163-169, 1987.