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Issue
Korean Journal of Chemical Engineering,
Vol.34, No.4, 1109-1121, 2017
Medium optimization for high yield production of extracellular human interferon-γ from Pichia pastoris: A statistical optimization and neural network-based approach
Prabhu AA, Mandal B, Dasu VV
Medium development for high level expression of human interferon gamma (hIFN-γ) from Pichia pastoris (GS115) was performed with the aid of statistical and nonlinear modeling techniques. In the initial screening, gluconate and glycine were found to be key carbon and nitrogen sources, showing significant effect on production of hIFN-γ. Plackett-Burman screening revealed that medium components., gluconate, glycine, KH2PO4 and histidine, have a considerable impact on hIFN-γ production. Optimization was further proceeded with Box-Behnken design followed by artificial neural network linked genetic algorithm (ANN-GA). The maximum production of hIFN-γ was found to be 28.48mg/L using Box-Behnken optimization (R2=0.98), whereas the ANN-GA based optimization had displayed a better production rate of 30.99mg/L (R2=0.98), with optimal concentration of gluconate=50 g/L, glycine=10.185 g/L, KH2PO4=35.912 g/L and histidine 0.264 g/L. The validation was carried out in batch bioreactor and unstructured kinetic models were adapted. The Luedeking-Piret (L-P) model showed production of hIFN-γ was mixed growth associated with the maximum production rate of 40mg/L of hIFN-γ production.
Keywords: Pichia pastoris; Human Interferon Gamma; Plackett-Burman; Box-Behnken; Artificial Neural Network-Genetic Algorithm (ANN-GA)
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[Cited By]
  1. Joshi C, Singhal RS, Korean Journal of Chemical Engineering, 35(1), 195, 2018
  2. Emami MRS, Amiri MK, Zaferani SPG, Korean Journal of Chemical Engineering, 38(2), 316, 2021
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