Lattice Boltzmann numerical simulation and experimental research of dynamic flow in an expansion-contraction microchannel

Jiang, Di; Sun, Defeng; Xiang, Nan; Chen, Ke; Hong, Yuling; Zhang, Ni

doi:10.1063/1.4812456

Cited by 13 publications

(4 citation statements)

References 31 publications

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“…[30] The specific principle could be seen in these previous works. [31][32][33] In the numerical simulation of cell deformation, the water phase with a density of 1000 kg m −3 and the dynamic viscosity of 0.001 pa s was used to simulate the sample suspension, and the incompressible neo-Hookean hyperelastic solid was used to simulate the cells. The fluid-solid interaction model was discretized and solved by the COMSOL multiphysics 5.6.…”

Section: Numerical Simulationmentioning

confidence: 99%

Inertial Multi‐Force Deformability Cytometry for High‐Throughput, High‐Accuracy, and High‐Applicability Tumor Cell Mechanotyping

Chen,

Ni,

Jiang

et al. 2023

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Previous on‐chip technologies for characterizing the cellular mechanical properties often suffer from a low throughput and limited sensitivity. Herein, an inertial multi‐force deformability cytometry (IMFDC) is developed for high‐throughput, high‐accuracy, and high‐applicability tumor cell mechanotyping. Three different deformations, including shear deformations and stretch deformations under different forces, are integrated with the IMFDC. The 3D inertial focusing of cells enables the cells to deform by an identical fluid flow, and 10 parameters, such as cell area, perimeter, deformability, roundness, and rectangle deformability, are obtained in three deformations. The IMFDC is able to evaluate the deformability of different cells that are sensitive to different forces on a single chip, demonstrating the high applicability of the IMFDC in analyzing different cell lines. In identifying cell types, the three deformations exhibit different mechanical responses to cells with different sizes and deformability. A discrimination accuracy of ≈93% for both MDA‐MB‐231 and MCF‐10A cells and a throughput of ≈500 cells s−1 can be achieved using the multiple‐parameters‐based machine learning model. Finally, the mechanical properties of metastatic tumor cells in pleural and peritoneal effusions are characterized, enabling the practical application of the IMFDC in clinical cancer diagnosis.

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Section: Numerical Simulationmentioning

confidence: 99%

Inertial Multi‐Force Deformability Cytometry for High‐Throughput, High‐Accuracy, and High‐Applicability Tumor Cell Mechanotyping

Chen,

Ni,

Jiang

et al. 2023

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“…35 Furthermore, size-based particle/cell separation in a multiorifice microchannel is also driven by a secondary flow. 34,36,37 As a consequence of a series of alternating narrow (contracting) and wide (expanding) channel geometries, a unique vortex will arise under low Re c at the corners of the expansion channels. Interestingly, the presence of vortexes in an orifice channel is slightly different from that in the straight channel generated by high Re c , 38 and vastly different from that of the Dean vortex created in a curved channel at low Re c (ref.…”

Section: Theory and Mechanismmentioning

confidence: 99%

High-throughput rare cell separation from blood samples using steric hindrance and inertial microfluidics

Shen

Zhao

et al. 2014

Lab Chip

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The presence and quantity of rare cells in the bloodstream of cancer patients provide a potentially accessible source for the early detection of invasive cancer and for monitoring the treatment of advanced diseases. The separation of rare cells from peripheral blood, as a "virtual and real-time liquid biopsy", is expected to replace conventional tissue biopsies of metastatic tumors for therapy guidance. However, technical obstacles, similar to looking for a needle in a haystack, have hindered the broad clinical utility of this method. In this study, we developed a multistage microfluidic device for continuous label-free separation and enrichment of rare cells from blood samples based on cell size and deformability. We successfully separated tumor cells (MCF-7 and HeLa cells) and leukemic (K562) cells spiked in diluted whole blood using a unique complementary combination of inertial microfluidics and steric hindrance in a microfluidic system. The processing parameters of the inertial focusing and steric hindrance regions were optimized to achieve high-throughput and high-efficiency separation, significant advantages compared with existing rare cell isolation technologies. The results from experiments with rare cells spiked in 1% hematocrit blood indicated >90% cell recovery at a throughput of 2.24 × 10(7) cells min(-1). The enrichment of rare cells was >2.02 × 10(5)-fold. Thus, this microfluidic system driven by purely hydrodynamic forces has practical potential to be applied either alone or as a sample preparation platform for fundamental studies and clinical applications.

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“…The microvortex generated in sudden expansion is of great importance for particle manipulation. Researchers have gained some beneficial research results [9][10][11] in the theoretical analysis and experimental investigations on the formation of vortices in different microchannel configurations. Jiang et al [9] numerically investigated the flow field under various inlet flow rates and cavity structures and then systematically studied the flow features of the vortex and Dean flow in this channel by LBM.…”

Section: Introductionmentioning

confidence: 99%

“…Researchers have gained some beneficial research results [9][10][11] in the theoretical analysis and experimental investigations on the formation of vortices in different microchannel configurations. Jiang et al [9] numerically investigated the flow field under various inlet flow rates and cavity structures and then systematically studied the flow features of the vortex and Dean flow in this channel by LBM. Bȃlan et al [10] investigated the dynamics of the vortices generated in the vicinity of Yand T-microbifurcations with one occluded branch.…”

Section: Introductionmentioning

confidence: 99%

Hydrodynamic Trapping of Particles in an Expansion-Contraction Microfluidic Device

Wang¹

2013

Abstract and Applied Analysis

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Manipulation and sorting of particles utilizing microfluidic phenomena have been a hot spot in recent years. Here, we present numerical investigations on particle trapping techniques by using intrinsic hydrodynamic effects in an expansion-contraction microfluidic device. One emphasis is on the underlying fluid dynamical mechanisms causing cross-streamlines migration of the particles in shear and vortical flows. The results show us that the expansion-contraction geometric structure is beneficial to particle trapping according to its size. Particle Reynolds number and aspect ratio of the channel will influence the trapping efficiency greatly because the force balance between inertial lift and vortex drag forces is the intrinsic reason. Especially, obvious inline particles contribution presented when the particle Reynolds number being unit. In addition, we selected three particle sizes (2, 7, and 15 μm) to examine the trapping efficiency.

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Lattice Boltzmann numerical simulation and experimental research of dynamic flow in an expansion-contraction microchannel

Cited by 13 publications

References 31 publications

Inertial Multi‐Force Deformability Cytometry for High‐Throughput, High‐Accuracy, and High‐Applicability Tumor Cell Mechanotyping

Inertial Multi‐Force Deformability Cytometry for High‐Throughput, High‐Accuracy, and High‐Applicability Tumor Cell Mechanotyping

High-throughput rare cell separation from blood samples using steric hindrance and inertial microfluidics

Hydrodynamic Trapping of Particles in an Expansion-Contraction Microfluidic Device

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