Particle Dynamics Methods of Blood FlowSimulations

A. Tosenberger; V. Salnikov; N. Bessonov; E. Babushkina; V. Volpert

doi:10.1051/mmnp/20116512

Abstract

Various particle methods are widely used to model dynamics of complex media. In this workmolecular dynamics and dissipative particles dynamics are applied to model blood flowscomposed of plasma and erythrocytes. The properties of the homogeneous particle fluid arestudied. Capillary flows with erythrocytes are investigated.

References

Bui, C., Lleras, V., Pantz, O., Dynamics of red blood cells in 2D, ESAIM Proceedings, 28 (2009), 182–194. CrossRef Google Scholar

Dupin, M. M., Halliday, I., Care, C. M., Alboul, L., Munn, L. L., Modeling the flow of dense suspensions of deformable particles in three dimensions, Physical Review E, 75 (2007), 066707. CrossRef Google Scholar PubMed

Espanol, P., Warren, P., Statistical mechanics of dissipative particle dynamics. Europhys. Lett., 30 (1995) (4), 191–196. CrossRef Google Scholar

Fedosov, D. A., Pivkin, I. V., Karniadakis, G. E., Velocity limit in DPD simulations of wall-bounded flows, Journal of Computational Physics, 227 (2008), 2540-2559. CrossRef Google Scholar

Fedosov, D. A., Caswell, B., Karniadakis, G. E., A multiscale red blood cell model with accurate mechanics, rheology, and dynamics, Biophysical Journal, 98 (2010), 2215-2225. CrossRef Google Scholar PubMed

D. A. Fedosov, Multiscale Modeling of Blood Flow and Soft Matter, PhD dissertation at Brown University, (2010).

A.L. Fogelson, em Cell-based models of blood clotting, In: A.R.A Anderson, A.A.J. Chaplain, K.A. Rejniak (Eds). Single-cell-based models in biology and medicine. Birkauser, Basel, 2007, pp. 243–270.

G.P. Galdi, R. Rannacher, A.M. Robertson, S. Turek, Hemodynamics flow. Modeling, analysis, and simulations, Birkhäuser, Basel, 2008.

Groot, R. D., Warren, P. B., Dissipative particle dynamics: Bridging the gap between atomistic and mesoscopic simulation, J. Chem. Phys., 107 (1997) (11), 4423–4435. CrossRef Google Scholar

Hosseini, S. M., Feng, J. J., A particle-based model for the transport of erythrocytes in capillaries, Chem. Eng. Sci., 64 (2009), 4488–4497. CrossRef Google Scholar

M. Karttunen, I. Vattulainen, A. Lukkarinen, A novel methods in soft matter simulations, Springer, Berlin, 2004.

K. Tsubota, S. Wada, H. Kamada, Y. Kitagawa, R. Lima, T. Yamaguchi, A particle method for blood flow simulation, application to flowing red blood cells and platelets, Journal of the Earth Simulator, Volume 5, March 2006, 2–7.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Tosenberger, A. Ataullakhanov, F. Bessonov, N. Panteleev, M. Tokarev, A. and Volpert, V. 2013. Modelling of thrombus growth in flow with a DPD-PDE method. Journal of Theoretical Biology, Vol. 337, Issue. , p. 30.

Panteleev, M.A. Sveshnikova, A.N. Belyaev, A.V. Nechipurenko, D.Y. Gudich, I. Obydenny, S.I. Dovlatova, N. Fox, S.C. Holmuhamedov, E.L. Sequeira, A. and Volpert, V. 2014. Systems Biology and Systems Pharmacology of Thrombosis. Mathematical Modelling of Natural Phenomena, Vol. 9, Issue. 6, p. 4.

Bessonov, N. Babushkina, E. Golovashchenko, S. F. Tosenberger, A. Ataullakhanov, F. Panteleev, M. Tokarev, A. Volpert, V. Sequeira, A. and Volpert, V. 2014. Numerical Modelling of Cell Distribution in Blood Flow. Mathematical Modelling of Natural Phenomena, Vol. 9, Issue. 6, p. 69.

Bodnár, Tomáš Fasano, Antonio and Sequeira, Adélia 2014. Fluid-Structure Interaction and Biomedical Applications. p. 483.

Gambaruto, Alberto M. 2015. Computational haemodynamics of small vessels using the Moving Particle Semi-implicit (MPS) method. Journal of Computational Physics, Vol. 302, Issue. , p. 68.

Bessonov, N. Sequeira, A. Simakov, S. Vassilevskii, Yu. Volpert, V. and Volpert, V. 2016. Methods of Blood Flow Modelling. Mathematical Modelling of Natural Phenomena, Vol. 11, Issue. 1, p. 1.

Tosenberger, A. Ataullakhanov, F. Bessonov, N. Panteleev, M. Tokarev, A. and Volpert, V. 2016. Modelling of platelet–fibrin clot formation in flow with a DPD–PDE method. Journal of Mathematical Biology, Vol. 72, Issue. 3, p. 649.

Molinari, Marco Brukhno, Andrey V. Parker, Stephen C. and Spagnoli, Dino 2016. Molecular Modeling of Geochemical Reactions. p. 33.

Tosenberger, Alen Gonze, Didier Bessonnard, Sylvain Cohen-Tannoudji, Michel Chazaud, Claire and Dupont, Geneviève 2017. A multiscale model of early cell lineage specification including cell division. npj Systems Biology and Applications, Vol. 3, Issue. 1,

Jafari, Somaye Zakeri, Ramin and Darbandi, Masoud 2018. DPD simulation of non-Newtonian electroosmotic fluid flow in nanochannel. Molecular Simulation, Vol. 44, Issue. 17, p. 1444.

Azhar, Mueed Shakil, Suleman Greiner, Andreas Kauzlarić, David and Korvink, Jan G. 2018. DPD enables mesoscopic MRI simulation of slow flow. Microfluidics and Nanofluidics, Vol. 22, Issue. 5,

Zhang, L. W. Ademiloye, A. S. and Liew, K. M. 2019. Meshfree and Particle Methods in Biomechanics: Prospects and Challenges. Archives of Computational Methods in Engineering, Vol. 26, Issue. 5, p. 1547.

Bouchnita, Anass Terekhov, Kirill Nony, Patrice Vassilevski, Yuri Volpert, Vitaly and Tian, Fang-Bao 2020. A mathematical model to quantify the effects of platelet count, shear rate, and injury size on the initiation of blood coagulation under venous flow conditions. PLOS ONE, Vol. 15, Issue. 7, p. e0235392.

Alexeev, Dmitry Amoudruz, Lucas Litvinov, Sergey and Koumoutsakos, Petros 2020. Mirheo: High-performance mesoscale simulations for microfluidics. Computer Physics Communications, Vol. 254, Issue. , p. 107298.

Schenkel, Torsten and Halliday, Ian 2021. Continuum Scale Non Newtonian Particle Transport Model for Hæmorheology. Mathematics, Vol. 9, Issue. 17, p. 2100.

Tian, Ben Zhang, Bing Deng, Junkai Wang, Dong Gong, Houjun Li, Yang Guo, Kerong Yang, Sen and Ke, Xiaoqin 2022. Morphological evolution during liquid-liquid phase separation governed by composition change pathways. Journal of Applied Physics, Vol. 132, Issue. 6,

Sun, Zebang Liu, Shaogang Zhao, Dan Dong, Liqiang Cao, Zilu and Qi, Jinming 2023. Study on the influence of composition parameters of magnetorheological fluid on its vibration transmission characteristics. Smart Materials and Structures, Vol. 32, Issue. 6, p. 065020.

Wu, Guorong Li, Yanggui Wang, Heping and Li, Shengshan 2023. Research on the Mesoscopic Characteristics of Kelvin–Helmholtz Instability in Polymer Fluids with Dissipative Particle Dynamics. Processes, Vol. 11, Issue. 6, p. 1755.

Vorozhtsov, Evgenii V. and Kiselev, Sergey P. 2024. An efficient method of finding new symplectic schemes for Hamiltonian mechanics problems with the aid of parametric Gröbner bases. Journal of Computational Physics, Vol. 496, Issue. , p. 112601.

Vorozhtsov, Evgenii V. 2024. Computer Algebra in Scientific Computing. Vol. 14938, Issue. , p. 349.

Article contents

Particle Dynamics Methods of Blood FlowSimulations

Abstract

Keywords

Access options

References

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Particle Dynamics Methods of Blood FlowSimulations

Abstract

Keywords

Access options

References

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests