Study on Rheology of RBC by Coupled Model in Fluid-Solid-Electrics Multi-physical Fields

doi:10.12068/j.issn.1005-3026.2023.12.001

Journal of Northeastern University(Natural Science) ›› 2023, Vol. 44 ›› Issue (12): 1673-1679.DOI: 10.12068/j.issn.1005-3026.2023.12.001

Study on Rheology of RBC by Coupled Model in Fluid-Solid-Electrics Multi-physical Fields

HU Sheng^1,2， WANG Yang-cheng¹， LYU Xiao-yong^1,2

1. School of Control Engineering， Northeastern University at Qinhuangdao， Qinhuangdao 066004， China； 2. Hebei Key Laboratory of Micro-nano Precision Optical Sensing and Measurement Technology， Northeastern University at Qinhuangdao， Qinhuangdao 066004， China.

Online:2024-01-30 Published:2024-01-30
Contact: HU Sheng
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Abstract

Abstract: The study of the mechanical deformation of red blood cell (RBC) suffered from fluid stress becomes more mature， but is insufficient for multi-physical fields， which involve the combination of electrical， acoustic， optical and thermal fields. Using COMSOL finite element software， a coupled model including three physical fluid-solid-electrics fields is built to study the migration simulation of two different RBC shapes with respect to spherocyte and normocyte. Compared to coupled model only involved in fluid-solid fields， the von Mises stress of spherocyte suffered from is greater than that of the normocyte when the electroosmotic flow generated by the electric field drives the cell migration. The effect of electroosmotic flow at 180μm/s leads to the RBC shape evolving into a “C” gesture. The spherocyte and normocyte have a different direction of rotation when they come across a pin obstacle due to the different shape. Regarding the coupled model with multi-physical fields presented， the motion trajectories of two cells reveal the possibility of separating different shaped cell relying on electroosmosis.

Key words: red blood cell (RBC)； rheology； electro-osmosis； electrokinetics； microfluidics, COMSOL

CLC Number:

R331.3

HU Sheng, WANG Yang-cheng, LYU Xiao-yong. Study on Rheology of RBC by Coupled Model in Fluid-Solid-Electrics Multi-physical Fields[J]. Journal of Northeastern University(Natural Science), 2023, 44(12): 1673-1679.

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Study on Rheology of RBC by Coupled Model in Fluid-Solid-Electrics Multi-physical Fields

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