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1دورية أكاديمية
المؤلفون: Lain, Santiago, Caballero Gaviria, Andrés David
مصطلحات موضوعية: Simulación por computadores, Computer simulation, Esfuerzos cortantes parietales, Aorta torácica, Hemodinámica, Thoracic aorta, Dinámica de fluidos computacional, Flujo sanguíneo, Wall shear stress, Hemodynamics, Computational fluid dynamics, Blood flow
الوقت: Universidad Autónoma de Occidente. Calle 25 115-85. Km 2 vía Cali-Jamundí
وصف الملف: application/pdf; 10 páginas
العلاقة: 101; 92; 37; Laín, S., y Caballero, A. D. (2017). Simulation of unsteady blood flow dynamics in the thoracic aorta. Ingeniería e Investigación, 37(3), 92-101; Ingeniería e Investigación; Caballero, AD., Laín, S. (2013). A Review on Computational Fluid Dynamics Modelling in Human Thoracic Aorta. Cardiovascular Engineering and Technology, 4, 103-130.; Caballero, AD., Laín, S. (2015). Numerical Simulation of non-Newtonian Blood Flow Dynamics in Human Thoracic Aorta. Computer Methods in Biomechanics and Biomedical Engineering, 18, 1200-1216.; Cecchi, E., Giglioli, C., Valente, S., Lazzeri, C., Gensini, G.F., Abbate, R., Mannini, L. (2011). Role of hemodynamic shear stress in cardiovascular disease. Atherosclerosis., 214, 249-256.; Chandran, K.B. (1993). Flow Dynamics in the Human Aorta. J Biomech Eng., 115, 611–616.; Dabagh, M., Vasava, P., & Jalali, P. (2015). Effects of severity and location of stenosis on the hemodynamics in human aorta and its branches. 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2دورية أكاديمية
المؤلفون: Lain, Santiago, Caballero Gaviria, Andrés David
مصطلحات موضوعية: Aorta, Thoracic, Flujo sanguíneo, Hemodinámica, Blood flow, Hemodynamics, Computational fluid dynamics, Human thoracic aorta
الوقت: Universidad Autónoma de Occidente. Calle 25 115-85. Km 2 vía Cali-Jamundí
وصف الملف: application/pdf; 44 páginas
العلاقة: Cardiovascular Engineering and Technology. páginas 1-32; 130; 103; Cardiovascular Engineering and Technology; Mori D, Yamaguchi T. 2002a. Computational fluid dynamics modelling and analysis of the effect of 3-D distortion of the human aortic arch. Comput Methods Biomech Biomed Engin. 5:249–260.; Mori D, Hayasaka T, Yamaguchi T. 2002b. Modelling of the human aortic arch with its major branches for computational fluid dynamics simulation of the blood flow. JSME. C-45(4):997-1002.; Shahcheraghi N, Dwyer HA, Cheer AY, Barakat AI, Rutanganira T. 2002. Unsteady and three-dimensional simulation of blood flow in the human aortic arch. J Biomech Eng. 124(4):378-87.; Jin S, Oshinski J, Giddens DP. 2003. Effect of wall motion and compliance on flow patterns in the ascending aorta. J. Biomech. Eng. 125:347–354.; Leuprecht A, Kozerke S, Boesiger P, Perktold K. 2003. Blood flow in the human ascending aorta: a combined MRI and CFD study. Journal of Engineering Mathematics. 47:387–404.; Kim T, Cheer AY, Dwyer HA. 2004. A simulated dye method for flow visualization with a computational model for blood flow. J Biomech. 27:1125–1136.; Morris L, Delassus P, Callanan A, Walsh M, Wallis F, Grace P, McGloughlin T. 2005. 3-D numerical simulation of blood flow through models of the human aorta. J Biomech Eng. 127:767-775.; Gao F, Watanabe M, Matsuzawa T. 2006. Stress analysis in a layered aortic arch model under pulsatile blood flow. Biomed. Eng Online. 5:25.; Gao F, Matsuzawa T. 2006. FSI within aortic arch model over cardiac cycle and Influence of wall stiffness on wall stress in layered wall. Engineering Letters. 13:167-172.; Gao F, Guo Z, Sakamoto M, Matsuzawa T. 2006. Fluid structure interaction within a layered aortic arch model. Journal of Biological Physics. 32(5):435–454.; Gardhagen R, Renner J, Lanne T, Karlsson M. 2006. Subject specific wall shear stress in the human thoracic aorta. WSEAS Transaction on Biology and Biomedicine. 3(10):609-614.; Park YJ, Park CY, Hwang CM, Sun K, Min BG. 2007. Pseudo-organ boundary conditions applied to a computational fluid dynamics model of the human aorta. Comput. Biol. Med. 37(8):1063-1072.; Gao F, Ohta O, Matsuzawa T. 2008. Fluid-structure interaction in layered aortic arch aneurysm model: assessing the combined influence of arch aneurysm and wall stiffness. Australas Phys Eng Sci Med. 3(1):32-41.; Lam SK, Fung GSK, Cheng SWK, Chow WK. 2008. A computational study on the biomechanical factors related to stent-graft models in the thoracic aorta. Med Biol Eng Comput. 46:1129–1138.; Soulis JV, Giannoglou GD, Dimitrakopoulou M, Logothetides S, Mikhailidis D. 2009. Influence of oscillating flow on LDL transport and wall shear stress in the normal aortic arch. Open Cardiovasc Med J. 17:128-142.; Renner J, Gardhagen R, Heiberg E, Ebbers T, Loyd D, Länne T, Karlsson M. 2009. A method for subject specific estimation of aortic wall shear stress. WSEAS Transaction on Biology and Biomedicine. 6(3):49-57.; Renner J, Loyd D, Lanne T, Karlsson M. 2009. Is a flat inlet profile sufficient for WSS estimation in the aortic arch? WSEAS Transactions on Fluid Mechanics. 4(4):148-160.; Kim HJ, Vignon-Clementel IE, Figueroa CA, LaDisa JF Jr, Jansen KE, Feinstein JA, Taylor CA. 2009. On coupling a lumped parameter heart model and a three-dimensional finite element aorta model. Ann Biomed Eng. 37(11):2153–2169.; Liu X, Pu F, Fan Y. 2009. A numerical study on the flow of blood and the transport of LDL in the human aorta: the physiological significance of the helical flow in the aortic arch. Am J Physiol Heart Circ Physiol. 297: H163-H170.; Tan FPP, Torii R, Borghi A, Mohiaddin RH, Wood NB, Thom S, Xu XY. 2009. Analysis of flow patterns in a patient-specific thoracic aortic aneurysm model. Computers and Structures. 87:680-690.; Wen CY, Yang AS, Tseng LY, Chai JW. 2010. 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الإتاحة: https://doi.org/10.1007/s13239-013-0146-6Test
https://doi.org/10.1155/2012/861837Test
https://doi.org/10.1016/j.medengphy.2012.08.009Test
https://doi.org/10.1007/s10237-012-0383-xTest
https://doi.org/10.1016/j.jtcvs.2012.03.051Test
https://doi.org/10.1016/j.medengphy.2012.07.015Test
http://red.uao.edu.co//handle/10614/11806Test
