Abstract
High dimensionality continues to be a challenge in computational systems biology. The kinetic models of many phenomena of interest are high-dimensional and complex, resulting in large computational effort in the simulation. Model order reduction (MOR) is a mathematical technique that is used to reduce the computational complexity of high-dimensional systems by approximation with lower dimensional systems, while retaining the important information and properties of the full order system. Proper orthogonal decomposition (POD) is a method based on Galerkin projection that can be used for reducing the model order. POD is considered an optimal linear approach since it obtains the minimum squared distance between the original model and its reduced representation. However, POD may represent a restriction for nonlinear systems. By applying the POD method for nonlinear systems, the complexity to solve the nonlinear term still remains that of the full order model. To overcome the complexity for nonlinear terms in the dynamical system, an approach called the discrete empirical interpolation method (DEIM) can be used. In this paper, we discuss model reduction by POD and DEIM to reduce the order of kinetic models of biological systems and illustrate the approaches on some examples. Additional computational costs for setting up the reduced order system pay off for large-scale systems. In general, a reduced model should not be expected to yield good approximations if different initial conditions are used from that used to produce the reduced order model. We used the POD method of a kinetic model with different initial conditions to compute the reduced model. This reduced order model is able to predict the full order model for a variety of different initial conditions.
Highlights
In biological systems, kinetic models of biochemical networks are necessary for predicting and optimizing the behavior of cells in culture
We discuss model reduction by proper orthogonal decomposition (POD) and discrete empirical interpolation method (DEIM) to reduce the order of kinetic models of biological systems and illustrate the approaches on some examples
Model order reduction is a mathematical theory for reducing the computational complexity of large-scale dynamical systems via finding a low-dimensional approximation while preserving the most important information of the full order system
Summary
Kinetic models of biochemical networks are necessary for predicting and optimizing the behavior of cells in culture. We discuss the model order reduction techniques by POD and DEIM for kinetic models of biological systems. From a practical point of view, the POD and DEIM methods are more advantageous for large-scale dynamical systems than time scale separation techniques, since we do not have to take care of satisfying the conditions required, e.g., for Tikhonov’s theorem. We apply the approaches to different models of biological systems from the BioModels database (http://identifiers.org/biomodels.db), and we compare the time costs of the simulation for the original and the reduced order model in different cases. We use the POD approach to compute a reduced order model of a kinetic model for different initial conditions of the dynamical system.
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