Abstract
Due to the complicated metabolism of mammalian cells, the corresponding dynamic mathematical models usually consist of large sets of differential and algebraic equations with a large number of parameters to be estimated. On the other hand, the measured data for estimating the model parameters are limited. Consequently, the parameter estimates may converge to a local minimum far from the optimal ones, especially when the initial guesses of the parameter values are poor. The methodology presented in this paper provides a systematic way for estimating parameters sequentially that generates better initial guesses for parameter estimation and improves the accuracy of the obtained metabolic model. The model parameters are first classified into four subsets of decreasing importance, based on the sensitivity of the model’s predictions on the parameters’ assumed values. The parameters in the most sensitive subset, typically a small fraction of the total, are estimated first. When estimating the remaining parameters with next most sensitive subset, the subsets of parameters with higher sensitivities are estimated again using their previously obtained optimal values as the initial guesses. The power of this sequential estimation approach is illustrated through a case study on the estimation of parameters in a dynamic model of CHO cell metabolism in fed-batch culture. We show that the sequential parameter estimation approach improves model accuracy and that using limited data to estimate low-sensitivity parameters can worsen model performance.
Highlights
The use of biologics, including antibiotics and antibodies, has increased across different therapeutic areas, and is poised to fuel pharmaceutical revenues and stimulate growth in the biopharmaceutical market
More than half of the therapeutic recombinant proteins are produced in immortalized mammalian cell lines, including Chinese hamster ovary (CHO), baby hamster kidney (BHK), and mouse myeloma cells (NS0)
We demonstrate the power of the proposed method by successfully identifying the important parameters in a well-received model of CHO cell metabolism [4] using experimental data
Summary
The use of biologics, including antibiotics and antibodies, has increased across different therapeutic areas, and is poised to fuel pharmaceutical revenues and stimulate growth in the biopharmaceutical market. Sensitivity analysis methodologies, including local and global sensitivity analysis, are widely applied to select the subset of parameters with the largest impact on the outputs of a metabolic model to be estimated with available data [8]. As the sensitivity coefficients are calculated based on the impacts by individual parameters, the LSA approaches do not account for the interaction impact of multiple parameters, which may significantly affect the output variables of nonlinear and complicated models. We propose a systematic approach to discriminate the parameters into four categories based on the sensitivity of the model outputs This allows the modeler to prioritize the estimation of the model parameters by initially focusing on those with the highest importance or largest sensitivity indices. We show that our sequential parameter estimation method results in a more accurate model compared to when all of the parameters are estimated simultaneously
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
