Red blood cells tracking and cell-free layer formation in a microchannel with hyperbolic contraction: a CFD model validation
| Autor(a) principal: | |
|---|---|
| Data de Publicação: | 2022 |
| Outros Autores: | , , , , |
| Tipo de documento: | Artigo |
| Idioma: | eng |
| Título da fonte: | Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos) |
| Texto Completo: | https://hdl.handle.net/1822/81472 |
Resumo: | Background and Objective: In recent years, progress in microfabrication technologies has attracted the attention of researchers across disciplines. Microfluidic devices have the potential to be developed into powerful tools that can elucidate the biophysical behavior of blood flow in microvessels. Such devices can also be used to separate the suspended physiological fluid from whole in vitro blood, which includes cells. Therefore, it is essential to acquire a detailed description of the complex interaction between erythrocytes (red blood cells; RBCs) and plasma. RBCs tend to undergo axial migration caused by occurrence of the Fåhræus-Lindqvist effect. These dynamics result in a cell-free layer (CFL), or a low volume fraction of cells, near the vessel wall. The aim of the paper is to develop a numerical model capable of reproducing the behavior of multiphase flow in a microchannel obtained under laboratory conditions and to compare two multiphase modelling techniques Euler-Euler and Euler-Lagrange. Methods: In this work, we employed a numerical Computational Fluid Dynamics (CFD) model of the blood flow within microchannels with two hyperbolic contraction shapes. The simulation was used to reproduce the blood flow behavior in a microchannel under laboratory conditions, where the CFL formation is visible downstream of the hyperbolic contraction. The multiphase numerical model was developed using Euler-Euler and hybrid Euler-Lagrange approaches. The hybrid CFD simulation of the RBC transport model was performed using a Discrete Phase Model. Blood was assumed to be a nonhomogeneous mixture of two components: dextran, whose properties are consistent with plasma, and RBCs, at a hematocrit of 5% (percent by volume of RBCs). Results: The results show a 5 μm thick CFL in a microchannel with a broader contraction and a 35 μm thick CFL in a microchannel with a narrower contraction. The RBC volume fraction in the CFL is less than 2%, compared to 7–8% in the core flow. The results are consistent for both multiphase simulation techniques used. The simulation results were then validated against the experimentally-measured CFL in each of the studied microchannel geometries. Conclusions: Reasonable agreement between experiments and simulations was achieved. A validated model such as the one tested in this study can expedite the microchannel design process by minimizing the need to prefabricate prototypes and test them under laboratory conditions. |
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Red blood cells tracking and cell-free layer formation in a microchannel with hyperbolic contraction: a CFD model validationHemodynamicsComputer SimulationMicrovesselsHydrodynamicsErythrocytesBiofluid mechanicsRed blood cellsCFDMicrochannelsHyperbolic contractionMultiphaseModel Euler-EulerModel Euler-LagrangeScience & TechnologyBackground and Objective: In recent years, progress in microfabrication technologies has attracted the attention of researchers across disciplines. Microfluidic devices have the potential to be developed into powerful tools that can elucidate the biophysical behavior of blood flow in microvessels. Such devices can also be used to separate the suspended physiological fluid from whole in vitro blood, which includes cells. Therefore, it is essential to acquire a detailed description of the complex interaction between erythrocytes (red blood cells; RBCs) and plasma. RBCs tend to undergo axial migration caused by occurrence of the Fåhræus-Lindqvist effect. These dynamics result in a cell-free layer (CFL), or a low volume fraction of cells, near the vessel wall. The aim of the paper is to develop a numerical model capable of reproducing the behavior of multiphase flow in a microchannel obtained under laboratory conditions and to compare two multiphase modelling techniques Euler-Euler and Euler-Lagrange. Methods: In this work, we employed a numerical Computational Fluid Dynamics (CFD) model of the blood flow within microchannels with two hyperbolic contraction shapes. The simulation was used to reproduce the blood flow behavior in a microchannel under laboratory conditions, where the CFL formation is visible downstream of the hyperbolic contraction. The multiphase numerical model was developed using Euler-Euler and hybrid Euler-Lagrange approaches. The hybrid CFD simulation of the RBC transport model was performed using a Discrete Phase Model. Blood was assumed to be a nonhomogeneous mixture of two components: dextran, whose properties are consistent with plasma, and RBCs, at a hematocrit of 5% (percent by volume of RBCs). Results: The results show a 5 μm thick CFL in a microchannel with a broader contraction and a 35 μm thick CFL in a microchannel with a narrower contraction. The RBC volume fraction in the CFL is less than 2%, compared to 7–8% in the core flow. The results are consistent for both multiphase simulation techniques used. The simulation results were then validated against the experimentally-measured CFL in each of the studied microchannel geometries. Conclusions: Reasonable agreement between experiments and simulations was achieved. A validated model such as the one tested in this study can expedite the microchannel design process by minimizing the need to prefabricate prototypes and test them under laboratory conditions.The work was partially supported by the Faculty of Energy and Environmental Engineering, Silesian University of Technology (SUT) within Ministry of Education and Science (Poland) statutory research funding scheme (MG, ZO) and by the Silesian University of Technology rector’s pro-quality grants No. 02/040/RGJ21/1011 (SS) and 08/060/RGJ21/1017 (ZO) and National Center of Science (Poland) No. 2017/27/B/ST8/01046 (BM). Rui Lima and João M. Miranda were partially funded by Portuguese national funds of FCT/MCTES (PIDDAC) through the base funding from the following research units: UIDB/00532/2020 (Transport Phenomena Research Center CEFT) and UIDB/04077/2020 (MEtRICs).ElsevierUniversidade do MinhoGracka, MariaLima, Rui Alberto Madeira MacedoMiranda, João M.Student, SebastianMelka, BartłomiejOstrowski, Ziemowit2022-112022-11-01T00:00:00Zinfo:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/articleapplication/pdfhttps://hdl.handle.net/1822/81472eng0169-26071872-756510.1016/j.cmpb.2022.10711736122496107117https://www.sciencedirect.com/science/article/pii/S0169260722004989?via%3Dihubinfo:eu-repo/semantics/openAccessreponame:Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos)instname:Agência para a Sociedade do Conhecimento (UMIC) - FCT - Sociedade da Informaçãoinstacron:RCAAP2023-07-21T12:51:44Zoai:repositorium.sdum.uminho.pt:1822/81472Portal AgregadorONGhttps://www.rcaap.pt/oai/openaireopendoar:71602024-03-19T19:50:42.845371Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos) - Agência para a Sociedade do Conhecimento (UMIC) - FCT - Sociedade da Informaçãofalse |
| dc.title.none.fl_str_mv |
Red blood cells tracking and cell-free layer formation in a microchannel with hyperbolic contraction: a CFD model validation |
| title |
Red blood cells tracking and cell-free layer formation in a microchannel with hyperbolic contraction: a CFD model validation |
| spellingShingle |
Red blood cells tracking and cell-free layer formation in a microchannel with hyperbolic contraction: a CFD model validation Gracka, Maria Hemodynamics Computer Simulation Microvessels Hydrodynamics Erythrocytes Biofluid mechanics Red blood cells CFD Microchannels Hyperbolic contraction Multiphase Model Euler-Euler Model Euler-Lagrange Science & Technology |
| title_short |
Red blood cells tracking and cell-free layer formation in a microchannel with hyperbolic contraction: a CFD model validation |
| title_full |
Red blood cells tracking and cell-free layer formation in a microchannel with hyperbolic contraction: a CFD model validation |
| title_fullStr |
Red blood cells tracking and cell-free layer formation in a microchannel with hyperbolic contraction: a CFD model validation |
| title_full_unstemmed |
Red blood cells tracking and cell-free layer formation in a microchannel with hyperbolic contraction: a CFD model validation |
| title_sort |
Red blood cells tracking and cell-free layer formation in a microchannel with hyperbolic contraction: a CFD model validation |
| author |
Gracka, Maria |
| author_facet |
Gracka, Maria Lima, Rui Alberto Madeira Macedo Miranda, João M. Student, Sebastian Melka, Bartłomiej Ostrowski, Ziemowit |
| author_role |
author |
| author2 |
Lima, Rui Alberto Madeira Macedo Miranda, João M. Student, Sebastian Melka, Bartłomiej Ostrowski, Ziemowit |
| author2_role |
author author author author author |
| dc.contributor.none.fl_str_mv |
Universidade do Minho |
| dc.contributor.author.fl_str_mv |
Gracka, Maria Lima, Rui Alberto Madeira Macedo Miranda, João M. Student, Sebastian Melka, Bartłomiej Ostrowski, Ziemowit |
| dc.subject.por.fl_str_mv |
Hemodynamics Computer Simulation Microvessels Hydrodynamics Erythrocytes Biofluid mechanics Red blood cells CFD Microchannels Hyperbolic contraction Multiphase Model Euler-Euler Model Euler-Lagrange Science & Technology |
| topic |
Hemodynamics Computer Simulation Microvessels Hydrodynamics Erythrocytes Biofluid mechanics Red blood cells CFD Microchannels Hyperbolic contraction Multiphase Model Euler-Euler Model Euler-Lagrange Science & Technology |
| description |
Background and Objective: In recent years, progress in microfabrication technologies has attracted the attention of researchers across disciplines. Microfluidic devices have the potential to be developed into powerful tools that can elucidate the biophysical behavior of blood flow in microvessels. Such devices can also be used to separate the suspended physiological fluid from whole in vitro blood, which includes cells. Therefore, it is essential to acquire a detailed description of the complex interaction between erythrocytes (red blood cells; RBCs) and plasma. RBCs tend to undergo axial migration caused by occurrence of the Fåhræus-Lindqvist effect. These dynamics result in a cell-free layer (CFL), or a low volume fraction of cells, near the vessel wall. The aim of the paper is to develop a numerical model capable of reproducing the behavior of multiphase flow in a microchannel obtained under laboratory conditions and to compare two multiphase modelling techniques Euler-Euler and Euler-Lagrange. Methods: In this work, we employed a numerical Computational Fluid Dynamics (CFD) model of the blood flow within microchannels with two hyperbolic contraction shapes. The simulation was used to reproduce the blood flow behavior in a microchannel under laboratory conditions, where the CFL formation is visible downstream of the hyperbolic contraction. The multiphase numerical model was developed using Euler-Euler and hybrid Euler-Lagrange approaches. The hybrid CFD simulation of the RBC transport model was performed using a Discrete Phase Model. Blood was assumed to be a nonhomogeneous mixture of two components: dextran, whose properties are consistent with plasma, and RBCs, at a hematocrit of 5% (percent by volume of RBCs). Results: The results show a 5 μm thick CFL in a microchannel with a broader contraction and a 35 μm thick CFL in a microchannel with a narrower contraction. The RBC volume fraction in the CFL is less than 2%, compared to 7–8% in the core flow. The results are consistent for both multiphase simulation techniques used. The simulation results were then validated against the experimentally-measured CFL in each of the studied microchannel geometries. Conclusions: Reasonable agreement between experiments and simulations was achieved. A validated model such as the one tested in this study can expedite the microchannel design process by minimizing the need to prefabricate prototypes and test them under laboratory conditions. |
| publishDate |
2022 |
| dc.date.none.fl_str_mv |
2022-11 2022-11-01T00:00:00Z |
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info:eu-repo/semantics/publishedVersion |
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info:eu-repo/semantics/article |
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article |
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publishedVersion |
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https://hdl.handle.net/1822/81472 |
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https://hdl.handle.net/1822/81472 |
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eng |
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eng |
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0169-2607 1872-7565 10.1016/j.cmpb.2022.107117 36122496 107117 https://www.sciencedirect.com/science/article/pii/S0169260722004989?via%3Dihub |
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openAccess |
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Elsevier |
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Elsevier |
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