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Near-optimal experimental design for model selection in systems biology.


ABSTRACT:

Motivation

Biological systems are understood through iterations of modeling and experimentation. Not all experiments, however, are equally valuable for predictive modeling. This study introduces an efficient method for experimental design aimed at selecting dynamical models from data. Motivated by biological applications, the method enables the design of crucial experiments: it determines a highly informative selection of measurement readouts and time points.

Results

We demonstrate formal guarantees of design efficiency on the basis of previous results. By reducing our task to the setting of graphical models, we prove that the method finds a near-optimal design selection with a polynomial number of evaluations. Moreover, the method exhibits the best polynomial-complexity constant approximation factor, unless P = NP. We measure the performance of the method in comparison with established alternatives, such as ensemble non-centrality, on example models of different complexity. Efficient design accelerates the loop between modeling and experimentation: it enables the inference of complex mechanisms, such as those controlling central metabolic operation.

Availability

Toolbox 'NearOED' available with source code under GPL on the Machine Learning Open Source Software Web site (mloss.org).

SUBMITTER: Busetto AG 

PROVIDER: S-EPMC3789540 | biostudies-literature | 2013 Oct

REPOSITORIES: biostudies-literature

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Publications

Near-optimal experimental design for model selection in systems biology.

Busetto Alberto Giovanni AG   Hauser Alain A   Krummenacher Gabriel G   Sunnåker Mikael M   Dimopoulos Sotiris S   Ong Cheng Soon CS   Stelling Jörg J   Buhmann Joachim M JM  

Bioinformatics (Oxford, England) 20130729 20


<h4>Motivation</h4>Biological systems are understood through iterations of modeling and experimentation. Not all experiments, however, are equally valuable for predictive modeling. This study introduces an efficient method for experimental design aimed at selecting dynamical models from data. Motivated by biological applications, the method enables the design of crucial experiments: it determines a highly informative selection of measurement readouts and time points.<h4>Results</h4>We demonstrat  ...[more]

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