Numerical simulation of red blood cells deformation in microchannel under zero-net-mass-flux jet

Ai, Jinfang; Xie, Jixing; Hu, Guohui

doi:10.7498/aps.69.20200971

Cited by 4 publications

(2 citation statements)

References 61 publications

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“…It is worth mentioning that various models have been applied to describe hyperelastic materials, such as the Neo-Hookean [3,37,38,48], Ogden [14,36], Mooney-Rivlin [1,15,25,44], Yeoh [43], Gent [35], and Arruda-Boyce [28] models. The Gent model is adopted in the present study considering the ultimate stretching of the particle-doped DE membrane.…”

Section: Problem Formulation and Motion Equationsmentioning

confidence: 99%

Dynamical behavior of a particle-doped multi-segment dielectric elastomer minimal energy structure

Gong,

Han,

et al. 2023

Smart Mater. Struct.

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The dynamic behavior of dielectric elastomers (DEs) has significant influence on their performance. The present study investigates the nonlinear dynamics of particle-doped multi-segmented DE minimum energy structures (DEMESs). To simulate the multi-segment DEMES, we consider each segment as a combination of hyperelastic film and elastic beam and obtain the ordinary differential equations governing the system dynamics based on the Euler–Lagrange equations. Due to the difficulty in measuring various physical parameters of DEs in practice, we utilize experimental data from a single-segment DE and employ a physics-informed neural network to predict the unknown parameters of the DE and the framework, such as stiffness K bb and doping volume fraction ϕ. Based on these predictions, nonlinear analysis is performed for the multi-segment system. Stability analyses of the motion equations reveal that the system exhibits a supercritical pitchfork bifurcation with hyperelastic thin film pre-stretching as the bifurcation parameter. For the three-segment DEMES, there are eight stable modes, but only four are illustrated in the bifurcation diagram due to the identical parameter settings for each segment. The amplitude-frequency curves under different AC voltage loads indicate the presence of harmonic, superharmonic, and subharmonic resonances in the system, with varying frequencies and magnitudes depending on the applied load. The Poincaré maps of the time response demonstrate that the system response is predominantly quasiperiodic. Under low voltage loads, the system exhibits periodic oscillations, while under certain high voltage loads, chaotic behavior emerges, characterized by strong nonlinearity in the time-dependent curves and non-periodicity in the Poincaré maps. This study provides insights into the present mathematical model in the motion control of DEMES.

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Section: Problem Formulation and Motion Equationsmentioning

confidence: 99%

Dynamical behavior of a particle-doped multi-segment dielectric elastomer minimal energy structure

Gong,

Han,

et al. 2023

Smart Mater. Struct.

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“…The conformation and self-assembly of polymer molecules in confinement are key theoretical issues in various biomedical technologies, such as gene delivery, drug synthesis, and transport. 10–17 Numerical simulations have found that the hydrophobic nanoconfinement conditions seemingly have dramatic influences on the properties of drug molecules or organic particles. 18–20 The effects of confinement on polymers have been extensively studied by theoretical predictions, 21,22 numerical simulations, 8,21–33 and experimental investigations.…”

Section: Introductionmentioning

confidence: 99%

Modulation of DNA conformation in electrolytic nanodroplets

2022

Phys. Chem. Chem. Phys.

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Numerical study of opposed zero-net-mass-flow jet-induced erythrocyte mechanoporation

Xie

2022

Appl. Math. Mech.-Engl. Ed.

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With the advantages of biosafety and efficiency, increasing attention has been paid to the devices for gene and macromolecular drug delivery based on mechanoporation. The transient pore formation on the cell membrane allows cargo transportation when the membrane areal strain is beyond the critical pore value and below the lysis tension threshold. Based on this principle, we propose a method to apply the proper fluid stress on cells moving in a microchannel under the action of zero-net-mass-flux (ZNMF) jets. In this study, an immersed finite element method (IFEM) is adopted to simulate the interaction between the cells and the fluid fields so as to investigate the cell movement and deformation in this mechanoporation system. To evaluate the efficiency of the cargo delivery, a pore integral is defined as the mean pore rate when the cell passes through the jet region. By analyzing the effects of the parameters, including the pressure gradient along the microchannel, the jet amplitude, and the jet frequency, on the pore integrals, a group of optimized parameters for cargo delivery efficiency are obtained. Additionally, the stability and safety of this system are analyzed in detail. These results are helpful in designing the mechanoporation devices and improving their efficiency of drug delivery.

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Numerical simulation of red blood cells deformation in microchannel under zero-net-mass-flux jet

Cited by 4 publications

References 61 publications

Dynamical behavior of a particle-doped multi-segment dielectric elastomer minimal energy structure

Dynamical behavior of a particle-doped multi-segment dielectric elastomer minimal energy structure

Modulation of DNA conformation in electrolytic nanodroplets

Numerical study of opposed zero-net-mass-flow jet-induced erythrocyte mechanoporation

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