In: BMC Systems Biology, 6 (2012), Nr. 14. S. 1-16. ISSN 1752-0509
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Abstract
Background: Given the complex mechanisms underlying biochemical processes systems biology researchers tend to build ever increasing computational models. However, dealing with complex systems entails a variety of problems, e.g. difficult intuitive understanding, variety of time scales or non-identifiable parameters. Therefore, methods are needed that, at least semi-automatically, help to elucidate how the complexity of a model can be reduced such that important behavior is maintained and the predictive capacity of the model is increased. The results should be easily accessible and interpretable. In the best case such methods may also provide insight into fundamental biochemical mechanisms. Results: We have developed a strategy based on the Computational Singular Perturbation (CSP) method which can be used to perform a "biochemically-driven" model reduction of even large and complex kinetic ODE systems. We provide an implementation of the original CSP algorithm in COPASI (a COmplex PAthway SImulator) and applied the strategy to two example models of different degree of complexity - a simple one-enzyme system and a full-scale model of yeast glycolysis. Conclusion: The results show the usefulness of the method for model simplification purposes as well as for analyzing fundamental biochemical mechanisms. COPASI is freely available at http://www.copasi.org.
Dokumententyp: | Artikel |
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Titel der Zeitschrift: | BMC Systems Biology |
Band: | 6 |
Nummer: | 14 |
Verlag: | BioMed Central |
Ort der Veröffentlichung: | London |
Erstellungsdatum: | 17 Feb. 2016 09:47 |
Erscheinungsjahr: | 2012 |
ISSN: | 1752-0509 |
Seitenbereich: | S. 1-16 |
Institute/Einrichtungen: | Fakultät für Biowissenschaften > Dekanat der Fakultät für Biowissenschaften
Zentrale und Sonstige Einrichtungen > Interdisziplinäres Zentrum für Wissenschaftliches Rechnen (IWR) Zentrale und Sonstige Einrichtungen > Bioquant Zentrale und Sonstige Einrichtungen > CellNetworks Core Technology Platform Zentrale und Sonstige Einrichtungen > Centre for Organismal Studies Heidelberg (COS) Zentrale und Sonstige Einrichtungen > Zentrum für Modellierung und Simulation in der Biowiss. |
DDC-Sachgruppe: | 570 Biowissenschaften, Biologie |