Lessons Learned from Quantitative Dynamical Modeling in Systems Biology
Contents
Lessons Learned from Quantitative Dynamical Modeling in Systems Biology
Paper Reference
Raue A, Schilling M, Bachmann J, Matteson A, Schelke M, et al. (2013) Lessons Learned from Quantitative Dynamical Modeling in Systems Biology PLOS ONE 8(9): e74335. https://doi.org/10.1371/journal.pone.0074335
Summary
This paper consideres modelling intracellular interaction networks with ordinary differential equation models (ODEs). Several aspects for robust and efficient estimation of model parameters were investigated.
Study outcomes
In this paper, the following approaches were compared:
Outcome O1
The performance benefit of parallel implementation in terms of computation times compared to computation on a single core is evaluated for fitting ODE models
Outcome O2
The bias of parameter estimation was smaller if error parameters are estimated simultaneously instead of estimating measurement errors as a preprocessing step by averaging over replicates.
Outcome O3
Stochastic optimization algorithms exhibited a weak performance compared to deterministic optimization methods
Outcome O4
Derivatives calculated by sensitivities was superior to finite differences
Outcome O5
Reparametrization of the model equations improved the performance for one model
Outcome O6
A hybrid optimization method combining deterministic and stochastic optimization exhibited intermediate performance (better than pure stochastic, worse than pure deterministic) but at the same time had required the largest number of function evaluations
Further outcomes
The paper discusses further aspects which are outside the benchmarking scope.
Study design and evidence level
General aspects
Three models are investigated:
- A toy model was used to obtain study outcome O2
- The so-called Becker model REF with 16 parameters and 85 experimental data points was used to derive study outcomes O3, O4 and O5.
- The so-called Bachmann model REF with 115 paraemters and 541 experimental data points was used to derive study outcomes O1, O3, O4 and O5.
Design for Outcome O1
- Four different parallelization levels (1 vs. 2 cores, 1 vs. 4, 1 vs. 8, and 1 vs. 16)
- The outcome was generated for a single model (Becker model)
- The outcome was generated for 1000 randomly drawn parameter settings
Design for Outcome O2
- A toy model woas used to obtain this outcome
- 200 parameter estimation runs for 100 different simulated data sets were evaluated
Design for Outcome O3
- Two application models (Becker and Bachmann) were used for this outcome
- Untuned, standard configuration parameters were used for stochastic optimization
- 100 optimization runs with different randomly drawn initial guesses were evaluated
- Computational speed has been evaluated in terms of number of function evaluations
Design for Outcome O4
- Two application models (Becker and Bachmann) were used for this outcome
- The observed performance benefit could be explained by illstrating non-smooth outcomes for finite differences if a parameter is varied and by showing a dependency on the finite difference step-size. Both issues did not occur for the solution of sensitivity equations.
- 100 optimization runs with different randomly drawn initial guesses were evaluated
- Computational speed has been evaluated in terms of number of function evaluations
Design for Outcome O5
- Two application models (Becker and Bachmann) were used for this outcome. A performance benefit was only visible for the Bachmann model.
- 100 optimization runs with different randomly drawn initial guesses were evaluated
- Computational speed has been evaluated in terms of number of function evaluations
Design for Outcome O6
- The hybrid algorithm was evaluated with default configuration parameters
- 100 optimization runs with different randomly drawn initial guesses were evaluated
- Computational speed has been evaluated in terms of number of function evaluations
Further References
V. Becker, M. Schilling, J. Bachmann, U. Baumann, A. Raue, T. Maiwald, J. Timmer, U. Klingmueller. Covering a broad dynamic range: Information processing at the erythropoietin receptor. Science 328, 2010, 1404-1408
J. Bachmann, A. Raue, M. Schilling, M. Boehm, A.C. Pfeifer, C. Kreutz, D. Kaschek, H. Busch, N. Gretz, W.D. Lehmann, J. Timmer, U. Klingmueller. Division of labor by dual feedback regulators controls JAK2/STAT5 signaling over broad ligand range. Mol. Sys. Bio. 7, 2011, 516