Abstract
A smart virtual university hospital representing a real-life one, can prepare students for direct patient contact and provide possibilities for clinical practice. Such a virtual hospital will support student learning by providing adaptive and flexible solutions for practicing a variety of clinical situations at the students’ own pace. This paper builds on a previous research on the Smart Virtual University concept and explores the possibilities for medical procedural training with Virtual Reality. A scenario focusing on pre-operative neurosurgical procedural training was developed and tested. The procedural training has been enhanced with real world medical data (MRI and ultrasound). The feedbacks from the tests have been generally positive, both in terms of general user experience and expected learning outcomes. The paper presents the implementation procedure, evaluation results and outlines the directions for future work.
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References
Prasolova-Førland, E., Steinsbekk, A., Fominykh, M., Lindseth, F.: Practicing interprofessional team communication and collaboration in a smart virtual university hospital. In: Uskov, V., Bakken, J., Howlett, R., Jain, L. (eds.) Smart Universities, Smart Innovation, Systems and Technologies, vol. 70, pp. 191–224. Springer (2018)
Wiecha, J., Heyden, R., Sternthal, E., Merialdi, M.: Learning in a virtual world: experience with using second life for medical education. J. Med. Internet Res. 12(1) (2010). https://www.jmir.org/2010/1/e1/
Lowes, S., Hamilton, G., Hochstetler, V., Paek, S.: Teaching communication skills to medical students in a virtual world. J. Interact. Technol. Pedagogy 3, e1 (2013)
Jang, S., Black, J.B., Jyung, R.W.: Embodied cognition and virtual reality in learning to visualize anatomy. In: Ohlsson, S., Catrambone, R. (eds.) 32nd Annual Conference of the Cognitive Science Society, Portland, OR, 12–14 August, pp. 2326–2331. Cognitive Science Society, Austin (2010)
Huang, H.M., Liaw, S.S., Lai, C.M.: Exploring learner acceptance of the use of virtual reality in medical education: a case study of desktop and projection-based display systems. Interact. Learn. Environ. 24(1), 3–19 (2016)
Khanal, P., Gupta, A., Smith, M.: Virtual worlds in healthcare. In: Gupta, A., Patel, L.V., Greenes, A.R. (eds.) Advances in Healthcare Informatics and Analytics, pp. 233–248. Springer International Publishing, Cham (2016)
Stefanidis, D., Sevdalis, N., Paige, J., Zevin, B., Aggarwal, R., Grantcharov, T., Jones, D.B., Association for Surgical Education Simulation Committee & Association for Surgical Education Simulation Committee: Simulation in surgery: what’s needed next? Ann. Surg. 261(5), 846–853 (2015)
Lewis, T.M., Aggarwal, R., Rajaretnam, N., Grantcharov, T.P., Darzi, A.: Training in surgical oncology–the role of VR simulation. Surg. Oncol. 20(3), 134–139 (2011)
Kühnapfel, U., Cakmak, H.K., Maaß, H.: Endoscopic surgery training using virtual reality and deformable tissue simulation. Comput. Graph. 24(5), 671–682 (2000)
Pelargos, P.E., Nagasawa, D.T., Lagman, C., Tenn, S., Demos, J.V., Lee, S.J., Bui, T.T., Barnette, N.E., Bhatt, N.S., Ung, N., Bari, A.: Utilizing virtual and augmented reality for educational and clinical enhancements in neurosurgery. J. Clin. Neurosci. 35, 1–4 (2017)
CAE Healthcare: Neurotouch (2017). https://caehealthcare.com/surgical-simulation/neurovr
Mathur, A.S.: Low cost virtual reality for medical training. In: 2015 IEEE Virtual Reality (VR), pp. 345–346. IEEE (2015)
Razer: Razer hydra. https://www2.razerzone.com/au-en/gaming-controllers/razer-hydra-portal-2-bundle
Shi, J., Xia, J., Wei, Y., Wang, S., Wu, J., Chen, F., Huang, G., Chen, J.: Three-dimensional virtual reality simulation of periarticular tumors using Dextroscope reconstruction and simulated surgery: a preliminary 10-case study. Med. Sci. Monit. Int. Med. J. Exp. Clin. Res. 20, 1043 (2014)
Egger, J., Gall, M., Wallner, J., Boechat, P., Hann, A., Li, X., Chen, X., Schmalstieg, D.: HTC Vive MeVisLab integration via OpenVR for medical applications. PLoS One 12(3), e0173972 (2017)
Snarby, H., Gåsbakk, T., Lindseth, F., Prasolova-Førland, E., Steinsbekk, A.: Medical Procedural Training in Virtual Reality (2017)
Uskov, V.L., Bakken, J.P., Pandey, A., Singh, U., Yalamanchili, M., Penumatsa A.: Smart university taxonomy: features, components, systems. In: Uskov, L.V., Howlett, J.R., Jain, C.L. (eds.) Smart Education and e-Learning 2016. pp. 3–14. Springer International Publishing (2016)
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Snarby, H., Gåsbakk, T., Prasolova-Førland, E., Steinsbekk, A., Lindseth, F. (2019). Procedural Medical Training in VR in a Smart Virtual University Hospital. In: Uskov, V., Howlett, R., Jain, L., Vlacic, L. (eds) Smart Education and e-Learning 2018. KES SEEL-18 2018. Smart Innovation, Systems and Technologies, vol 99. Springer, Cham. https://doi.org/10.1007/978-3-319-92363-5_12
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DOI: https://doi.org/10.1007/978-3-319-92363-5_12
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