Reliable calibration and validation of phenomenological and hybrid models of high-cell-density fed-batch cultures subject to metabolic overflow
link https://doi.org/10.1016/j.compchemeng.2024.108706account_box Ibáñez Espinel, Franciscoaccount_box Puentes Cantor, Hernán Felipeaccount_box Barzaga Martell, Lisbelaccount_box Saa Higuera, Pedroaccount_box Agosin Trumper, Eduardoaccount_box Perez Correa, José Ricardo
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Fed-batch cultures are the preferred operation mode for industrial bioprocesses requiring high cellular densities. Avoids accumulation of major fermentation by-products due to metabolic overflow, increasing process productivity. Reproducible operation at high cell densities is challenging (> 100 gDCW/L), which has precluded rigorous model evaluation. Here, we evaluated three phenomenological models and proposed a novel hybrid model including a neural network. For this task, we generated highly reproducible fedbatch datasets of a recombinant yeast growing under oxidative, oxygen-limited, and respiro-fermentative metabolic regimes. The models were reliably calibrated using a systematic workflow based on pre-and post-regression diagnostics. Compared to the best-performing phenomenological model, the hybrid model substantially improved performance by 3.6- and 1.7-fold in the training and test data, respectively. This study illustrates how hybrid modeling approaches can advance our description of complex bioprocesses that could support more efficient operation strategies
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| Autor | Ibáñez Espinel, Francisco Puentes Cantor, Hernán Felipe Barzaga Martell, Lisbel Saa Higuera, Pedro Agosin Trumper, Eduardo Perez Correa, José Ricardo |
| Título | Reliable calibration and validation of phenomenological and hybrid models of high-cell-density fed-batch cultures subject to metabolic overflow |
| Revista | Computers and Chemical Engineering |
| Página inicio | 1 |
| Página final | 16 |
| Fecha de publicación | 2024 |
| Resumen | Fed-batch cultures are the preferred operation mode for industrial bioprocesses requiring high cellular densities. Avoids accumulation of major fermentation by-products due to metabolic overflow, increasing process productivity. Reproducible operation at high cell densities is challenging (> 100 gDCW/L), which has precluded rigorous model evaluation. Here, we evaluated three phenomenological models and proposed a novel hybrid model including a neural network. For this task, we generated highly reproducible fedbatch datasets of a recombinant yeast growing under oxidative, oxygen-limited, and respiro-fermentative metabolic regimes. The models were reliably calibrated using a systematic workflow based on pre-and post-regression diagnostics. Compared to the best-performing phenomenological model, the hybrid model substantially improved performance by 3.6- and 1.7-fold in the training and test data, respectively. This study illustrates how hybrid modeling approaches can advance our description of complex bioprocesses that could support more efficient operation strategies |
| Derechos | acceso restringido |
| DOI | 10.1016/j.compchemeng.2024.108706 |
| Enlace | |
| Id de publicación en WoS | WOS:001238497500001 |
| Paginación | 16 páginas |
| Palabra clave | Hybrid models Dynamic optimization High-density cultures Overflow metabolism Fed-batch fermentation Physics-informed neural networks |
| Tema ODS | 03 Good health and well-being |
| Tema ODS español | 03 Salud y bienestar |
| Temática | Matemática física y química |
| Tipo de documento | artículo |