Abstract
The bottleneck in creating dynamic models of biological networks and processes often lies in estimating unknown kinetic model parameters from experimental data. In this regard, experimental conditions have a strong influence on parameter identifiability and should therefore be optimized to give the maximum information for parameter estimation. Existing model-based design of experiment (MBDOE) methods commonly rely on the Fisher information matrix (FIM) for defining a metric of data informativeness. When the model behavior is highly nonlinear, FIM-based criteria may lead to suboptimal designs, as the FIM only accounts for the linear variation in the model outputs with respect to the parameters. In this work, we developed a multi-objective optimization (MOO) MBDOE, for which the model nonlinearity was taken into consideration through the use of curvature. The proposed MOO MBDOE involved maximizing data informativeness using a FIM-based metric and at the same time minimizing the model curvature. We demonstrated the advantages of the MOO MBDOE over existing FIM-based and other curvature-based MBDOEs in an application to the kinetic modeling of fed-batch fermentation of baker’s yeast.
Highlights
Dynamic models of biological networks and processes are often created to gain a better understanding of the system behavior
We proposed a multi-objective optimization (MOO) model-based design of experiment (MBDOE) method using a combination of a Fisher information matrix (FIM) criterion and model curvature
We evaluated the performance of the proposed MBDOE in an application to a kinetic model of a fed-batch fermentation of baker’s yeast [30,31]
Summary
Dynamic models of biological networks and processes are often created to gain a better understanding of the system behavior. The creation of dynamic biological models requires the values of kinetic parameters, many of which are system-specific and typically not known a priori. These parameters are commonly estimated by calibrating model simulations to the available experimental data. Such parameter fitting is known to be challenging, as there often exist multiple parameter combinations that fit the available data well; that is, the model parameters are not identifiable [1,2,3,4,5]. Biological experiments and data collection are often costly and time-consuming, further motivating the need for well-planned experiments that would give the maximum information given finite resources
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