Model-based optimization of scaffold geometry and operating conditions of radial flow packed-bed bioreactors for therapeutic applications

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Abstract

Radial flow perfusion of cell-seeded hollow cylindrical porous scaffolds may overcome the transport limitations of pure diffusion and direct axial perfusion in the realization of bioengineered substitutes of failing or missing tissues. Little has been reported on the optimization criteria of such bioreactors. A steady-state model was developed, combining convective and dispersive transport of dissolved oxygen with Michaelis-Menten cellular consumption kinetics. Dimensional analysis was used to combine more effectively geometric and operational variables in the dimensionless groups determining bioreactor performance. The effectiveness of cell oxygenation was expressed in terms of non-hypoxic fractional construct volume. The model permits the optimization of the geometry of hollow cylindrical constructs, and direction and magnitude of perfusion flow, to ensure cell oxygenation and culture at controlled oxygen concentration profiles. This may help engineer tissues suitable for therapeutic and drug screening purposes.

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Donato, D., De Napoli, I. E., & Catapano, G. (2014). Model-based optimization of scaffold geometry and operating conditions of radial flow packed-bed bioreactors for therapeutic applications. Processes, 2(1), 34–57. https://doi.org/10.3390/pr2010034

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