Abstract
Assessment of cerebral aneurysm rupture risk is very crucial for clinicians, because it causes a number of deaths worldwide. Hemodynamics is commonly thought to play a significant role in the mechanisms of development, maturity, and rupture of aneurysm. It is reasonable to assume that rupture risk assessment can be improved by incorporating hemodynamic analysis on the parameters like wall shear stress, velocity, static pressure information, etc. So to compare the hemodynamic parameters on different cerebrovascular phantoms with and without aneurysm, carries a significant role in prediction of occurrence of aneurysm and subsequently rupture risk of the same. Computational fluid dynamics is one conventional approaches to determine the hemodynamic parameter.
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This project is supported by the DST PURSE-II, Government of India, project of Computer Science and Engineering Department of Jadavpur University.
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Rakshit, P., Das, N., Nasipuri, M., Basu, S. (2018). Hemodynamic Analysis on Human Cerebrovascular Phantoms with and Without Aneurysm. In: Mandal, J., Saha, G., Kandar, D., Maji, A. (eds) Proceedings of the International Conference on Computing and Communication Systems. Lecture Notes in Networks and Systems, vol 24. Springer, Singapore. https://doi.org/10.1007/978-981-10-6890-4_37
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