Simulation and optimization of dynamic flux balance analysis models using an interior point method reformulation

Scott, Felipe; Wilson, Pamela E.; Conejeros, Raúl; Vassiliadis, Vassilios S.

doi:10.1016/j.compchemeng.2018.08.041

Cited by 23 publications

(18 citation statements)

References 37 publications

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“…This method assumes that bacterial metabolism reaches an internal steady state almost immediately after a change in the extracellular environment. This allows the update of the extracellular concentrations based on the exchanges predicted by the model, which in turn update the uptake rates of the substrates needed for growth ( 49 , 50 ). In this experiment, we considered a minimal medium where glucose is the only source of carbon (initial concentration, 222.2 mmol/liter), the initial concentration of inorganic phosphate is relatively low (4.6 mmol/liter), and the initial biomass concentration is 0.5 gDW/liter where gDW stands for grams in dry weight.…”

Section: Resultsmentioning

confidence: 99%

Multi-omics Study of Planobispora rosea, Producer of the Thiopeptide Antibiotic GE2270A

Carratore

Iorio²,

Pérez-Bonilla

et al. 2021

mSystems

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Section: Resultsmentioning

confidence: 99%

Multi-omics Study of Planobispora rosea, Producer of the Thiopeptide Antibiotic GE2270A

Carratore

Iorio²,

Pérez-Bonilla

et al. 2021

mSystems

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“…No ethanol production is observed under aerobic conditions (i.e., this phase is mainly used to increase the biomass), such that the concentration of ethanol can be omitted from the dynamics. This case study is commonly used as a benchmark for comparing DFBA solvers (see, e.g., [16, 27, 31]), as it exhibits stiff dynamics and multiple singularities.…”

Section: Resultsmentioning

confidence: 99%

“…However, the most commonly used UQ methods are intractable for expensive-to-evaluate computational models [15], which has severely limited their application to DFBA models. An overview of the various challenges in DFBA simulations can be found in [16].…”

Section: Introductionmentioning

confidence: 99%

Fast uncertainty quantification for dynamic flux balance analysis using non-smooth polynomial chaos expansions

2019

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We present a novel surrogate modeling method that can be used to accelerate the solution of uncertainty quantification (UQ) problems arising in nonlinear and non-smooth models of biological systems. In particular, we focus on dynamic flux balance analysis (DFBA) models that couple intracellular fluxes, found from the solution of a constrained metabolic network model of the cellular metabolism, to the time-varying nature of the extracellular substrate and product concentrations. DFBA models are generally computationally expensive and present unique challenges to UQ, as they entail dynamic simulations with discrete events that correspond to switches in the active set of the solution of the constrained intracellular model. The proposed non-smooth polynomial chaos expansion (nsPCE) method is an extension of traditional PCE that can effectively capture singularities in the DFBA model response due to the occurrence of these discrete events. The key idea in nsPCE is to use a model of the singularity time to partition the parameter space into two elements on which the model response behaves smoothly. Separate PCE models are then fit in both elements using a basis-adaptive sparse regression approach that is known to scale well with respect to the number of uncertain parameters. We demonstrate the effectiveness of nsPCE on a DFBA model of an E. coli monoculture that consists of 1075 reactions and 761 metabolites. We first illustrate how traditional PCE is unable to handle problems of this level of complexity. We demonstrate that over 800-fold savings in computational cost of uncertainty propagation and Bayesian estimation of parameters in the substrate uptake kinetics can be achieved by using the nsPCE surrogates in place of the full DFBA model simulations. We then investigate the scalability of the nsPCE method by utilizing it for global sensitivity analysis and maximum a posteriori estimation in a synthetic metabolic network problem with a larger number of parameters related to both intracellular and extracellular quantities.

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“…This method is also less computationally demanding compared to the DOA approach as the optimisation is done locally. However, new approaches are still presented to include more constraints such as nonlinear objective function [45] or linear kinetic constraints [46] or to improve the computation of the simulations [47,48].…”

Section: Direct Approach (Da)mentioning

confidence: 99%

Combining Kinetic and Constraint-Based Modelling to Better Understand Metabolism Dynamics

2021

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To understand the phenotypic capabilities of organisms, it is useful to characterise cellular metabolism through the analysis of its pathways. Dynamic mathematical modelling of metabolic networks is of high interest as it provides the time evolution of the metabolic components. However, it also has limitations, such as the necessary mechanistic details and kinetic parameters are not always available. On the other hand, large metabolic networks exhibit a complex topological structure which can be studied rather efficiently in their stationary regime by constraint-based methods. These methods produce useful predictions on pathway operations. In this review, we present both modelling techniques and we show how they bring complementary views of metabolism. In particular, we show on a simple example how both approaches can be used in conjunction to shed some light on the dynamics of metabolic networks.

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Simulation and optimization of dynamic flux balance analysis models using an interior point method reformulation

Cited by 23 publications

References 37 publications

Multi-omics Study of Planobispora rosea, Producer of the Thiopeptide Antibiotic GE2270A

Multi-omics Study of Planobispora rosea, Producer of the Thiopeptide Antibiotic GE2270A

Fast uncertainty quantification for dynamic flux balance analysis using non-smooth polynomial chaos expansions

Combining Kinetic and Constraint-Based Modelling to Better Understand Metabolism Dynamics

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