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The Application of Computational Fluid Dynamics (CFD) Method and Several Rheological Models of Blood Flow: A Review

Yıl 2018, Cilt: 31 Sayı: 4, 1213 - 1227, 01.12.2018

Öz

Computational fluid dynamics (CFD) method
can be applied for gaining insights to
the most fluid processes and related phenomena. Applying CFD method in the investigation of
physiological flows especially blood is one of the interesting topics for many researchers. Because of its
significant effect on various human
cardiovascular diseases and arterial diseases, extended knowledge of blood flow
in physiological conditions is required. This review provided an overview of
recent studies on the application of CFD method of blood flow inside the
corkscrew artery, arterial stenoses, human patient-specific left ventricle and
arteries affected by multiple aneurysms. Also, several rheological models for
describing the blood rheology were discussed. Based on this review, it was
concluded that the application of CFD method can help the medical practitioners
in the patients’ treatment decision in the investigation of blood flow

 




Kaynakça

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Yıl 2018, Cilt: 31 Sayı: 4, 1213 - 1227, 01.12.2018

Öz

Kaynakça

  • [1] Da silva, J. L., & Rao, M. A., “Rheological behavior of food gels”, Rheology of Fluid and Semisolid Foods, Springer US, 5, 339-401, (2007).
  • [2] Kordani, N., & Vanini, A. S., “Optimizing the ethanol content of shear thickening fluid/fabric composites under impact loading”, Journal of Mechanical Science and Technology, 28(2), 663-667, (2014).
  • [3] Brown, S., “Computational Fluid Dynamic Modeling of Aortic Blood Flow”, Doctoral dissertation, McMaster University, Canada, (2014).
  • [4] Rabby, M. G., Shupti, S. P., & Molla, M. M., “Pulsatile non-Newtonian laminar blood flows through arterial double stenoses”, Journal of Fluids, 55, 122-134, (2014).
  • [5] Yilmaz, F., & Gundogdu, M. Y., “A critical review on blood flow in large arteries; relevance to blood rheology, viscosity models, and physiologic conditions”, Korea-Australia Rheology Journal, 20(4), 197-211, 2008.
  • [6] Nezamidoost, S., Sadeghy, K., & Askari, V., “Pulsatile flow of thixotropic fluids through a partially-constricted tube”, Nihon Reoroji Gakkaishi, 41(2), 45-52, (2013).
  • [7] Baskurt, O. K., & Meiselman, H. J., “Blood rheology and hemodynamics”, In Seminars in thrombosis and hemostasis, Thieme Medical Publishers, 29(5), 435-450, (2003).
  • [8] Doost, S. N., Zhong, L., Su, B., & Morsi, Y. S., “The numerical analysis of non-Newtonian blood flow in human patient-specific left ventricle”, Computer methods and programs in biomedicine, 127(3), 232-247, (2016).
  • [9] Vlachopoulos, C., O'Rourke, M., & Nichols, W. W., “McDonald's blood flow in arteries: theoretical, experimental and clinical principles”, CRC press, 15-32, (2011).
  • [10] Lantz, J., Gardhagen, R., & Karlsson, M., “Quantifying turbulent wall shear stress in a subject specific human aorta using large eddy simulation”, Medical Engineering and Physics, 34(8), 1139-1148, (2012).
  • [11] Chen, J., & Lu, X. Y., “Numerical investigation of the non-Newtonian pulsatile blood flow in a bifurcation model with a non-planar branch”, Journal of biomechanics, 39(5), 818-832, (2006).
  • [12] Siddiqui, S. U., Verma, N. K., Mishra, S., & Gupta, R. S., “Mathematical modelling of pulsatile flow of Casson’s fluid in arterial stenosis”, Applied Mathematics and Computation, 210(1), 1-10, (2009).
  • [13] Sultanov, R. A., & Guster, D., “Full dimensional computer simulations to study pulsatile blood flow in vessels, aortic arch and bifurcated veins: Investigation of blood viscosity and turbulent effects”, In Engineering in Medicine and Biology Society, Annual International Conference of the IEEE, 4704-4710, (2009).
  • [14] Ternik, P., & Marn, J., “Numerical study of blood flow in stenotic artery”, Applied Rheology, 19(1), 130-145, (2009).
  • [15] Pedrizzetti, G., and Perktold K., “Cardiovascular fluid mechanics”, New York-Springer, 45-63, (2003).
  • [16] Su, C. M., Lee, D., Tran-Son-Tay, R., & Shyy, W., “Fluid flow structure in arterial bypass anastomosis”, Journal of biomechanical engineering, 127(4), 611-618, (2005).
  • [17] Maurits, N. M., Loots, G. E., & Veldman, A. E. P., “The influence of vessel walls elasticity and peripheral resistance on the carotid artery flow wave form: a CFD model compared to in vivo ultrasound measurements”, Journal of biomechanics, 40(2), 427-436, (2007).
  • [18] De Santis, G., Mortier, P., De Beule, M., Segers, P., Verdonck, P., & Verhegghe, B., “Patient-specific computational fluid dynamics: structured mesh generation from coronary angiography”, Medical & biological engineering & computing, 48(4), 371-380, (2010).
  • [19] Leuprecht, A., Kozerke, S., Boesiger, P., & Perktold, K., “Blood flow in the human ascending aorta: a combined MRI and CFD study”, Journal of engineering mathematics, 47(3-4), 387-404, (2003).
  • [20] Kaazempur-Mofrad, M. R., Isasi, A. G., Younis, H. F., Chan, R. C., Hinton, D. P., Sukhova, G., Kamm, R. D., “Characterization of the atherosclerotic carotid bifurcation using MRI, finite element modeling, and histology”, Annals of biomedical engineering, 32(7), 932-946, (2004).
  • [21] Schumann, C., M. Neugebauer, R. Bade, B. Preim, and Peitgen, H., “Implicit vessel surface reconstruction for visualization and CFD simulation”, International Journal of Computer Assisted Radiology and Surgery, 2(5), 275-286, (2008).
  • [22] Sousa, L. C., C. F. Castro, and Antonio, C., “Blood flow simulation and applications”, Technologies for medical sciences, 3, 67-86, (2012).
  • [23] Chen, J., X. Y. Lu, and Wang W., “Non-Newtonian effects of blood flow on hemodynamics in distal vascular graft anastomoses”, Journal of Biomechanics, 39(11), 1983-1995, (2006).
  • [24] Molla, M. Mamun, and Paul M. C., “LES of non-Newtonian physiological blood flow in a model of arterial stenosis”, Medical engineering & physics, 34(8), 1079-1087, (2012).
  • [25] Fan, Y., W. Jiang, Y. Zou, J. Li, J. Chen, and Deng X., “Numerical simulation of pulsatile non-Newtonian flow in the carotid artery bifurcation”, Acta Mechanica Sinica, 25(2), 249-255, (2009).
  • [26] Johnston, B. M., P. R. Johnston, S. Corney, and Kilpatrick D., “Non-Newtonian blood flow in human right coronary arteries: transient simulations”, Journal of biomechanics, 39(6), 1116-1128, (2006).
  • [27] Kim, Y. H., P. J. VandeVord, and Lee, J. S., “Multiphase non‐Newtonian effects on pulsatile hemodynamics in a coronary artery”, International journal for numerical methods in fluids, 58(7), 803-825, (2008).
  • [28] Vajravelu, K., S. Sreenadh, P. Devaki, and Prasad, K., “Mathematical model for a Herschel-Bulkley fluid flow in an elastic tube”, Open Physics, 9(5), 1357-1365, (2011).
  • [29] Pontrelli, G., “Blood flow through a circular pipe with an impulsive pressure gradient”, Mathematical Models and Methods in Applied Sciences, 10(2), 187-202, (2000).
  • [30] Das, B., G. Enden, and Popel A. S., “Stratified multiphase model for blood flow in a venular bifurcation”, Annals of biomedical engineering, 25(1), 135-153, (1997).
  • [31] Hundertmark-Zaušková, A., and Lukáčová-Medvid’ová M., “Numerical study of shear-dependent non-Newtonian fluids in compliant vessels”, Computers & Mathematics with Applications, 60(3), 572-590, (2010).
  • [32] Lou, Z., and Yang W. J., “A computer simulation of the non-Newtonian blood flow at the aortic bifurcation”, Journal of biomechanics, 26(1), 37-49, (1993).
  • [33] Zueco, J., and Bég O. A., “Network numerical simulation applied to pulsatile non-Newtonian flow through a channel with couple stress and wall mass flux effects”, International Journal of Applied Mathematics and Mechanics, 5(2), 1-16, (2009).
  • [34] Marcinkowska-Gapińska, A., J. Gapinski, W. Elikowski, F. Jaroszyk, and Kubisz L., “Comparison of three rheological models of shear flow behavior studied on blood samples from post-infarction patients”, Medical & biological engineering & computing, 45(9), 837-844, (2007).
  • [35] Bodnár, T., A. Sequeira, and Prosi. M., “On the shear-thinning and viscoelastic effects of blood flow under various flow rates”, Applied Mathematics and Computation, 217(11), 5055-5067, (2011).
  • [36] Augier, F., O. Masbernat, and Guiraud, P., “Slip velocity and drag law in a liquid‐liquid homogeneous dispersed flow”, AIChE journal, 49(9), 2300-2316, (2003).
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Toplam 83 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Mühendislik
Bölüm Mechanical Engineering
Yazarlar

Esmaeel Fatahıan

Naser Kordanı Bu kişi benim

Hossein Fatahıan

Yayımlanma Tarihi 1 Aralık 2018
Yayımlandığı Sayı Yıl 2018 Cilt: 31 Sayı: 4

Kaynak Göster

APA Fatahıan, E., Kordanı, N., & Fatahıan, H. (2018). The Application of Computational Fluid Dynamics (CFD) Method and Several Rheological Models of Blood Flow: A Review. Gazi University Journal of Science, 31(4), 1213-1227.
AMA Fatahıan E, Kordanı N, Fatahıan H. The Application of Computational Fluid Dynamics (CFD) Method and Several Rheological Models of Blood Flow: A Review. Gazi University Journal of Science. Aralık 2018;31(4):1213-1227.
Chicago Fatahıan, Esmaeel, Naser Kordanı, ve Hossein Fatahıan. “The Application of Computational Fluid Dynamics (CFD) Method and Several Rheological Models of Blood Flow: A Review”. Gazi University Journal of Science 31, sy. 4 (Aralık 2018): 1213-27.
EndNote Fatahıan E, Kordanı N, Fatahıan H (01 Aralık 2018) The Application of Computational Fluid Dynamics (CFD) Method and Several Rheological Models of Blood Flow: A Review. Gazi University Journal of Science 31 4 1213–1227.
IEEE E. Fatahıan, N. Kordanı, ve H. Fatahıan, “The Application of Computational Fluid Dynamics (CFD) Method and Several Rheological Models of Blood Flow: A Review”, Gazi University Journal of Science, c. 31, sy. 4, ss. 1213–1227, 2018.
ISNAD Fatahıan, Esmaeel vd. “The Application of Computational Fluid Dynamics (CFD) Method and Several Rheological Models of Blood Flow: A Review”. Gazi University Journal of Science 31/4 (Aralık 2018), 1213-1227.
JAMA Fatahıan E, Kordanı N, Fatahıan H. The Application of Computational Fluid Dynamics (CFD) Method and Several Rheological Models of Blood Flow: A Review. Gazi University Journal of Science. 2018;31:1213–1227.
MLA Fatahıan, Esmaeel vd. “The Application of Computational Fluid Dynamics (CFD) Method and Several Rheological Models of Blood Flow: A Review”. Gazi University Journal of Science, c. 31, sy. 4, 2018, ss. 1213-27.
Vancouver Fatahıan E, Kordanı N, Fatahıan H. The Application of Computational Fluid Dynamics (CFD) Method and Several Rheological Models of Blood Flow: A Review. Gazi University Journal of Science. 2018;31(4):1213-27.