Combined effect of hydrodynamic and interfacial flow parameters on lysozyme deactivation in a stirred tank bioreactor

Ghadge, Rajaram S. ; Patwardhan, Ashwin W. ; Joshi, Jyeshtharaj B. (2006) Combined effect of hydrodynamic and interfacial flow parameters on lysozyme deactivation in a stirred tank bioreactor Biotechnology Progress, 22 (3). pp. 660-672. ISSN 8756-7938

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Official URL: http://onlinelibrary.wiley.com/doi/10.1021/bp05026...

Related URL: http://dx.doi.org/10.1021/bp050269s

Abstract

The dynamic environment within a bioreactor and in the purification equipment is known to affect the activity and yield of enzyme production. The present research focuses on the effect of hydrodynamic flow parameters (average energy dissipation rate, maximum energy dissipation rate, average shear rate, and average normal stress) and the interfacial flow parameters (specific interfacial area and mass transfer coefficient) on the activity of lysozyme. Flow parameters were estimated using CFD simulation based on the k-ε approch. Enzyme deactivation was investigated in 0.1, 0.3, 0.57, and 1 m i.d. vessels. Enzyme solution was subjected to hydrodynamic stress using various types of impellers and impeller combinations over a wide range of power consumption (0.03 < PG/V < 7, kW/m3). The effects of tank diameter, impeller diameter, blade width, blade angle, and the number of blades on the extent of deactivation were investigated. At equal value of PG/V, εmax, and γavg, the extent of deactivation was dramatically different for different impeller types. The extent of deactivation was found to correlate well with the average turbulent normal stress and the mass transfer coefficient.

Item Type:Article
Source:Copyright of this article belongs to John Wiley and Sons.
ID Code:61154
Deposited On:13 Sep 2011 11:09
Last Modified:13 Sep 2011 11:09

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