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Reduction of mathematical models of signal transduction networks: simulation-based approach applied to EGF receptor signalling

Reduction of mathematical models of signal transduction networks: simulation-based approach applied to EGF receptor signalling

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Biological systems and, in particular, cellular signal transduction pathways are characterised by their high complexity. Mathematical models describing these processes might be of great help to gain qualitative and, most importantly, quantitative knowledge about such complex systems. However, a detailed mathematical description of these systems leads to nearly unmanageably large models, especially when combining models of different signalling pathways to study cross-talk phenomena. Therefore, simplification of models becomes very important. Different methods are available for model reduction of biological models. Importantly, most of the common model reduction methods cannot be applied to cellular signal transduction pathways. Using as an example the epidermal growth factor (EGF) signalling pathway, we discuss how quantitative methods like system analysis and simulation studies can help to suitably reduce models and additionally give new insights into the signal transmission and processing of the cell.

Inspec keywords: cellular biophysics; reduced order systems; biocontrol; large-scale systems; crosstalk; physiological models

Other keywords: epidermal growth factor receptor signalling; system analysis; cell processing; cross-talk phenomena; complex biological systems; mathematical model reduction; signal transmission; cellular signal transduction networks

Subjects: General, theoretical, and mathematical biophysics; Signal processing theory; Cellular biophysics; Systems theory applications in biology and medicine; Control system analysis and synthesis methods

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