A review on rheological models and mathematical problem formulations for blood flows
Abstract
A review on constitutive equations proposed for mathematical modeling of laminar and turbulent flows of blood as a concentrated suspension of soft particles is given. The rheological models of blood as a uniform Newtonian fluid, non-Newtonian
shear-thinning, viscoplastic, viscoelastic, tixotropic and micromorphic fluids are discussed. According to the experimental data presented, the adequate rheological model must describe shear-thinning tixotropic behavior with concentration-dependent viscoelastic properties which are proper to healthy human blood. Those properties can be studied on the corresponding mathematical problem formulations for the blood flows through the tudes or ducts. The corresponding systems of equations and boundary conditions for each of the proposed rheological models are discussed. Exact solutions for steady laminar flows between the parallel plates and through the circular tubes have been obtained and analyzed for the Ostwald, Hershel-Bulkley, and Bingham shear-thinning fluids. The influence of the model parameters on the velocity profiles has been studied for each model. It is shown, certain sets of fluid parameters lead to flattening of the velocity profile while others produce its sharpening around the axis of the channel.
It is shown, the second-order terms in the viscoelastic models give the partial derivative differential equations with high orders in time and mixed space-time derivatives. The corresponding problem formulations for the generalized rhelogical laws are derived. Their analytical solutions in the form of a normal mode are obtained. It is shown, the dispersion equations produce an additional set for the speed of sound (so called second sound) in the fluid. It is concluded, the most general rheological model must include shear-thinning, concentration and second sound phenomena
Downloads
References
Carson, R. Van Loon, P. Nithiarasu. Mathematical Techniques for Circulatory Systems, Encyclopedia of Biomedical Engineering, Elsevier. -- 2019. -- P. 79-94. DOI: https://doi.org/10.1016/B978-0-12-801238-3.99982-3
S.K. Zhou, D. Rueckert, G. Fichtinger. Handbook of Medical Image Computing and Computer Assisted Intervention, Elsevier. -- 2020. DOI: https://doi.org/10.1016/C2017-0-04608-6
W.W. Nichols, M.F. O'Rourke, Ch. Vlachopoulos. McDonald's Blood Flow in Arteries: Theoretical, Experimental and Clinical Principles. CRC Press. - 2011. DOI: https://doi.org/10.1201/b13568
D. Rubenstein, W. Yin, M. Frame. Biofluid Mechanics. An Introduction to Fluid Mechanics, Macrocirculation, and Microcirculation. Academic Press 2021. DOI: https://doi.org/10.1016/C2018-0-02144-1
J.R. Womersley. Method for the calculation of velocity, rate of flow and viscous drag in arteries when the pressure gradient is known, J. Physiol. -- 1955. Vol. 127, No 3. -- P. 553563. DOI: https://doi.org/10.1113/jphysiol.1955.sp005276
Y.C. Fung. Biomechanics Motion, flow, stress and growth. Springer-Verlag. -- 1990. DOI: https://doi.org/10.1007/978-1-4757-2257-4
F.M. White. Fluid Mechanics. 9-th edition. McGraw Hill. -- 2021. DOI: https://www.mheducation.com/highered/product/fluid-mechanics-white/M9781260258318.html
P. Giri, K. Chandran, K. Muralidhar, I.S. Dalal. Effects of coupling of mass transport and blood viscosity models for microchannel flows, J. Non-Newtonian Fluid Mech. -- 2022. Vol. 302. -- P. 104754. DOI: https://doi.org/10.1016/j.jnnfm.2022.104754
N. Kizilova, V. Cherevko. Mathematical modeling of particle aggregation and sedimentation in concentrated suspensions, Mechanika w Medycynie. Rzeszow Univ.Press. -- 2014. Vol. 12. -- P.43--52.
L.V. Batyuk, N.N. Kizilova. Modeling of laminar flows of the erythrocyte suspensions as Bingham fluids, Bull. T. Shevchenko Kyiv National University. Ser. Physical and Mathematical Sciences. -- 2017. No 4. -- P.23--28.
V. Cherevko, N. Kizilova. Complex flows of immiscible microfluids and nanofluids with velocity slip boundary conditions, Nanophysics, Nanomaterials, Interface Studies, and Applications, Springer Proceedings in Physics. -- 2017. Vol. 183. P. 207-230. DOI: https://doi.org/10.1007/978-3-319-56422-7-15
H. Liu, L. Lan, J. Abrigo, et al. Comparison of Newtonian and Non-newtonian Fluid Models in Blood Flow Simulation in Patients With Intracranial Arterial Stenosis, Front. Physiol., Sec. Computational Physiology and Medicine. -- 2021. Vol. 12. DOI: https://doi.org/10.3389/fphys.2021.718540
N. Elie, S. Sarah, R. Marc, et al. Blood Rheology: Key Parameters, Impact on Blood Flow, Role in Sickle Cell Disease and Effects of Exercise Frontiers in Physiology. -- 2019. Vol. 10. DOI: https://doi.org/10.3389/fphys.2019.01329
G. Barshtein, A. Gural, O. Zelig, et al. Unit-to-unit variability in the deformability of red blood cells, Transfusion and Apheresis Sci. -- 2020. Vol. 59, No 5. -- P.102876. DOI: https://doi.org/10.1016/j.transci.2020.102876
Kizilova N.M., Solovjova O.M. Analysis of discrete rheological models of bioactive soft and liquid materials, Visnyk of V.N. Karazin Kharkin National University. Ser. Mathematical modeling. Information Technology. Automated control systems. -- 2017. Vol. 35. -- P.21--30.
N. Kizilova. Electromagnetic Properties of Blood and Its Interaction with Electromagnetic Fields, Advances in Medicine and Biology. -- 2019. Vol. 137. -- P.1--74.
V.L. Sigal. The Copley-Scott Blair phenomenon. Will it be explained by the effect of an electric double layer? Biorheology. -- 1984. Vol. 21, No 3. -- P. 297--302. DOI: https://doi.org/10.3233/bir-1984-21301
S. Oka. Copley-Scott Blair phenomenon and electric double layer, Biorheology. -- 1984. Vol. 21, No 3. -- P. 417--421. DOI: https://doi.org/10.3233/bir-1984-21311
A. Yazdani, Y. Deng, H. Li, et al. Integrating blood cell mechanics, platelet adhesive dynamics and coagulation cascade for modelling thrombus formation in normal and diabetic blood, J. Royal Soc. Interface. -- 2021. Vol. 18, No 175. -- P. 33530862. DOI: https://doi.org/10.1098/rsif.2020.0834
D.J. Acheson. Elementary Fluid Mechanics. Oxford Applied Mathematics and Computing Science Series. -- 1990. DOI: https://doi.org/10.1002/aic.690380518
N.S. Wahid, N.M. Arifin, M. Turkyilmazoglu, et al. Effect of magnetohydrodynamic Casson fluid flow and heat transfer past a stretching surface in porous medium with slip condition, J. Physics: Conference Series. -- 2019. Vol. 1366. -- P. 012028. DOI: https://doi.org/10.1088/1742-6596/1366/1/012028
A.K.T. Radhakrishnan, C. Poelma, J. van Lier, F. Clemens. Laminar-turbulent transition of a non-Newtonian fluid flow, J. Hydraulic Res. -- 2021. Vol. 59, No. 2. -- P. 235-249. DOI: https://doi.org/10.1080/00221686.2020.1770876
N.A. Konan, E. Rosenbaum, M. Massoudi. On the response of a Herschel?Bulkley fluid due to a moving plate, Polymers. -- 2022. Vol. 14. -- P.3890. DOI: https://doi.org/10.3390/polym14183890
Z. Abbas, M.S. Shabbir. Analysis of rheological properties of Herschel-Bulkley fluid for pulsating flow of blood in ù-shaped stenosed artery, AIP Advances. -- 2017. Vol. 7, No 10. -P.05123. DOI: https://doi.org/10.1063/1.5004759
M. Asgir, A.A. Zafar, A.M. Alsharif, et al. Special function form exact solutions for Jeffery fluid: an application of power law kernel, Adv. Differ. Equ. -- 2021. Vol. 384. -- P.2021. DOI: https://doi.org/10.1186/s13662-021-03539-x}
N.M. Kizilova, I.V. Mayko. Generalization of the Lighthill's problem for the case of tubes with complicated wall rheology filled with a viscous liquid, Bull. T.Shevchenko Kyiv National University. Ser. Physical and Mathematical Sciences. -- 2020. No 1-2. -- P.67--70.
N.M. Kizilova, O.M. Solovjova. Analysis of discrete rheological models of bioactive soft and liquid materials. Visnyk of V.N. Karazin Kharkin National University. Ser. Mathematical modeling. Information Technology. Automated control systems. -- 2017. Vol. 35. -- P.21--30.
Ya.I. Braude, N.M. Kizilova Study on periodic axisymmetric flow of viscoelastic fluid through a cylindrical tube. Bull. T.Shevchenko Kyiv National University. Ser. Physical and Mathematical Sciences. -- 2020. No 1-2. -- P.49--52.
Copyright (c) 2023 N. M. Kizilova, L. V. Batyuk, S.O. Poslavski
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
The copyright holder is the author.
Authors who publish with this journal agree to the following terms:
1. Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal. (Attribution-Noncommercial-No Derivative Works licence).
2. Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.
3. Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work (see The Effect of Open Access).