Computational fluid modeling and performance analysis of a bidirectional rotating perfusion culture system

Kang, Chang Wei; Wang, Yan; Tania, Marshella; Zhou, Huancheng; Gao, Yi; Ba, Te; Tan, Guo-Dong Sean; Kim, Sangho; Leo, Hwa Liang

doi:10.1002/btpr.1736

Cited by 5 publications

(4 citation statements)

References 31 publications

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“…Many of the bioreactor systems are flow-based culture systems, and computational fluid dynamics (CFD) modeling is well suited to optimize bioreactor design as it provides a tool to describe fluid dynamics in the engineered culture devices (Kang et al, 2013 ; Hsu et al, 2014 ). CFD modeling allows parameter values to be varied and the effects on the system to be characterized rapidly.…”

Section: Introductionmentioning

confidence: 99%

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Fluid Dynamic Modeling to Support the Development of Flow-Based Hepatocyte Culture Systems for Metabolism Studies

Pedersen

Shim

Hans

et al. 2016

Front. Bioeng. Biotechnol.

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Accurate prediction of metabolism is a significant outstanding challenge in toxicology. The best predictions are based on experimental data from in vitro systems using primary hepatocytes. The predictivity of the primary hepatocyte-based culture systems, however, is still limited due to well-known phenotypic instability and rapid decline of metabolic competence within a few hours. Dynamic flow bioreactors for three-dimensional cell cultures are thought to be better at recapitulating tissue microenvironments and show potential to improve in vivo extrapolations of chemical or drug toxicity based on in vitro test results. These more physiologically relevant culture systems hold potential for extending metabolic competence of primary hepatocyte cultures as well. In this investigation, we used computational fluid dynamics to determine the optimal design of a flow-based hepatocyte culture system for evaluating chemical metabolism in vitro. The main design goals were (1) minimization of shear stress experienced by the cells to maximize viability, (2) rapid establishment of a uniform distribution of test compound in the chamber, and (3) delivery of sufficient oxygen to cells to support aerobic respiration. Two commercially available flow devices – RealBio® and QuasiVivo® (QV) – and a custom developed fluidized bed bioreactor were simulated, and turbulence, flow characteristics, test compound distribution, oxygen distribution, and cellular oxygen consumption were analyzed. Experimental results from the bioreactors were used to validate the simulation results. Our results indicate that maintaining adequate oxygen supply is the most important factor to the long-term viability of liver bioreactor cultures. Cell density and system flow patterns were the major determinants of local oxygen concentrations. The experimental results closely corresponded to the in silico predictions. Of the three bioreactors examined in this study, we were able to optimize the experimental conditions for long-term hepatocyte cell culture using the QV bioreactor. This system facilitated the use of low system volumes coupled with higher flow rates. This design supports cellular respiration by increasing oxygen concentrations in the vicinity of the cells and facilitates long-term kinetic studies of low clearance test compounds. These two goals were achieved while simultaneously keeping the shear stress experienced by the cells within acceptable limits.

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Section: Introductionmentioning

confidence: 99%

“…It can also be used to describe spatiotemporal distributions of a test compound or oxygen within the system. CFD and other computational methods have previously been applied to enhance our understanding of system parameters fundamental for cell responses within complex 3D culture environments (Kang et al, 2013 ; Hsu et al, 2014 ).…”

Section: Introductionmentioning

confidence: 99%

Fluid Dynamic Modeling to Support the Development of Flow-Based Hepatocyte Culture Systems for Metabolism Studies

Pedersen

Shim

Hans

et al. 2016

Front. Bioeng. Biotechnol.

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“…Other authors have shown on their works the benefits of simulations for the design and optimization of bioreactors and other kind of equipment. (Haringa et al, 2018;Kang et al, 2013;Trejo et al, 2012;Moilanen et al, 2006) In this study, the kinetic model developed by Biswas et al (2006) was applied to a tubular reactor using an intermittent feeding method. Additionally, a modification to the original model was proposed to include inhibition of methane production caused by high concentrations of acids in the reactor.…”

Section: Introductionmentioning

confidence: 99%

Modelling of Continuous Production of Biogas in a Tubular Reactor

Romero-Flores¹,

Sillas‐Moreno²,

Trejo³

et al. 2018

Rev.Mex.Ing.Quim.

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“…Thus, pressure drop predictions as a function of the scaffold permeability have been demonstrated for scaffolds with a variety of mechanical properties (elastic modulus and Poisson's ratio) to optimize the bioreactor design (Podichetty et al, ). Moreover, advection‐diffusion equations have been coupled with the hydrodynamics and mass transfer equations to increase model complexity and study the dynamic effect of cell colonization on the fluid‐induced stress distribution (Kang et al, ; Pearson et al, ; Spencer et al, ) within a tissue scaffold. Specifically, these reported studies aim to optimize the flow properties and bioreactor geometry to preclude any scaffold deformation or non‐uniform fluid‐induced shear stress distributions due to poroelasic phenomena that yield non‐uniform cell colonization.…”

Section: Introductionmentioning

confidence: 99%

Numerical investigation of dynamic microorgan devices as drug screening platforms. Part II: Microscale modeling approach and validation

Tourlomousis

Chang

2015

Biotech & Bioengineering

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The authors have previously reported a rigorous macroscale modeling approach for an in vitro 3D dynamic microorgan device (DMD). This paper represents the second of a two-part model-based investigation where the effect of microscale (single liver cell-level) shear-mediated mechanotransduction on drug biotransformation is deconstructed. Herein, each cell is explicitly incorporated into the geometric model as single compartmentalized metabolic structures. Each cell's metabolic activity is coupled with the microscale hydrodynamic Wall Shear Stress (WSS) simulated around the cell boundary through a semi-empirical polynomial function as an additional reaction term in the mass transfer equations. Guided by the macroscale model-based hydrodynamics, only 9 cells in 3 representative DMD domains are explicitly modeled. Dynamic and reaction similarity rules based on non-dimensionalization are invoked to correlate the numerical and empirical models, accounting for the substrate time scales. The proposed modeling approach addresses the key challenge of computational cost towards modeling complex large-scale DMD-type system with prohibitively high cell densities. Transient simulations are implemented to extract the drug metabolite profile with the microscale modeling approach validated with an experimental drug flow study. The results from the author's study demonstrate the preferred implementation of the microscale modeling approach over that of its macroscale counterpart.

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Computational fluid modeling and performance analysis of a bidirectional rotating perfusion culture system

Cited by 5 publications

References 31 publications

Fluid Dynamic Modeling to Support the Development of Flow-Based Hepatocyte Culture Systems for Metabolism Studies

Fluid Dynamic Modeling to Support the Development of Flow-Based Hepatocyte Culture Systems for Metabolism Studies

Modelling of Continuous Production of Biogas in a Tubular Reactor

Numerical investigation of dynamic microorgan devices as drug screening platforms. Part II: Microscale modeling approach and validation

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