Bounding the stationary distributions of the chemical master equation via mathematical programming

Kuntz, Juan; Thomas, Philipp; Stan, Guy-Bart; Barahona, Mauricio

doi:10.1063/1.5100670

Cited by 35 publications

(53 citation statements)

References 80 publications

(188 reference statements)

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“…The PDE approximation can be obtained assuming Taylor expansion of CME (Schnoerr et al, 2017). The error bounds for numerically computed stationary distributions of CME are obtained in (Kuntz et al, 2017). CME for hierarchical BRNs consisting of dependent and independent sub-networks is solved analytically in (Reis et al, 2018).…”

Section: Modeling Brns By Differential Equationsmentioning

confidence: 99%

Comprehensive Review of Models and Methods for Inferences in Bio-Chemical Reaction Networks

2019

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The key processes in biological and chemical systems are described by networks of chemical reactions. From molecular biology to biotechnology applications, computational models of reaction networks are used extensively to elucidate their non-linear dynamics. The model dynamics are crucially dependent on the parameter values which are often estimated from observations. Over the past decade, the interest in parameter and state estimation in models of (bio-) chemical reaction networks (BRNs) grew considerably. The related inference problems are also encountered in many other tasks including model calibration, discrimination, identifiability, and checking, and optimum experiment design, sensitivity analysis, and bifurcation analysis. The aim of this review paper is to examine the developments in literature to understand what BRN models are commonly used, and for what inference tasks and inference methods. The initial collection of about 700 documents concerning estimation problems in BRNs excluding books and textbooks in computational biology and chemistry were screened to select over 270 research papers and 20 graduate research theses. The paper selection was facilitated by text mining scripts to automate the search for relevant keywords and terms. The outcomes are presented in tables revealing the levels of interest in different inference tasks and methods for given models in the literature as well as the research trends are uncovered. Our findings indicate that many combinations of models, tasks and methods are still relatively unexplored, and there are many new research opportunities to explore combinations that have not been considered—perhaps for good reasons. The most common models of BRNs in literature involve differential equations, Markov processes, mass action kinetics, and state space representations whereas the most common tasks are the parameter inference and model identification. The most common methods in literature are Bayesian analysis, Monte Carlo sampling strategies, and model fitting to data using evolutionary algorithms. The new research problems which cannot be directly deduced from the text mining data are also discussed.

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Section: Modeling Brns By Differential Equationsmentioning

confidence: 99%

Comprehensive Review of Models and Methods for Inferences in Bio-Chemical Reaction Networks

2019

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“…For the equilibrium distribution, for example, the time-derivative of all moments is equal to zero. This directly yields constraints that have been used for parameter estimation at steady-state [5] and bounding moments of the equilibrium distribution using semi-definite programming [14,15,21]. The latter technique of bounding moments has been successfully adapted in the context of transient analysis [12,29,30].…”

Section: Related Workmentioning

confidence: 99%

“…Here, such approximations are not necessary, since we will apply the moment dynamics in the context of stochastic sampling instead of trying to integrate (6). Apart from integration strategies, setting (6) to zero has been used as a constraint for parameter estimation at steady-state [5] and bounding moments at steady-state [11,15,21]. The extension of the latter has recently lead to the adaption of these constraints to a transient setting [12,30].…”

Section: Moment Constraintsmentioning

confidence: 99%

Control Variates for Stochastic Simulation of Chemical Reaction Networks

Backenköhler

Bortolussi

Wolf

2019

Computational Methods in Systems Biology

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Stochastic simulation is a widely used method for estimating quantities in models of chemical reaction networks where uncertainty plays a crucial role. However, reducing the statistical uncertainty of the corresponding estimators requires the generation of a large number of simulation runs, which is computationally expensive. To reduce the number of necessary runs, we propose a variance reduction technique based on control variates. We exploit constraints on the statistical moments of the stochastic process to reduce the estimators' variances. We develop an algorithm that selects appropriate control variates in an on-line fashion and demonstrate the efficiency of our approach on several case studies.

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“…In current synthetic biology, the majority of studies uses Monte Carlo based stimulations of single cell trajectories to approximately evaluate these statistics of population distributions [20]. To complement the time-consuming nature of the Monte Carlo approach, other computational tools are available to directly quantify population distributions [21,22] and raw moments [23,24,25,26] without running simulations. However, these methods are not designed to directly compute descriptive statistics of biocircuits, which makes it difficult to further develop systematic design tools that can handle statistical biocircuit specifications.…”

Section: Introductionmentioning

confidence: 99%

“…1). Building upon a moment computation approach [26,27,28], we formulate the biocircuit design problems in the form of convex optimization programs [29], which enable efficient evaluation of the statistics and its sensitivity without running time-consuming simulations of single-cell trajectories. Our optimization based synthesis approach is capable of characterizing feasible design space that satisfies multiple and possibly incompatible performance specifications with mathematical rigor.…”

Section: Introductionmentioning

confidence: 99%

Optimization-based synthesis of stochastic biocircuits with statistical specifications

Sakurai

Hori

2017

Preprint

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Model-guided design has become a standard approach to engineering biomolecular circuits in current synthetic biology. However, the stochastic nature of biomolecular reactions is often overlooked in the design process. As a result, cell-cell heterogeneity causes unexpected deviation of biocircuit behaviors from model predictions and requires additional iterations of design-build-test cycles. To enhance the design process of stochastic biocircuits, this paper presents a computational framework to systematically specify the level of intrinsic noise using well-defined metrics of statistics and design highly heterogeneous biocircuits based on the specifications. Specifically, we use descriptive statistics of population distributions as an intuitive specification language of stochastic biocircuits and develop an optimization based computational tool that explores parameter configurations satisfying design requirements. Sensitivity analysis methods are also developed to ensure the robustness of a biocircuit design. These design tools are formulated using convex optimization programs to enable efficient and rigorous quantification of the statistics without approximation, and thus, they are amenable to the synthesis of stochastic biocircuits that require high reliability. We demonstrate these features by designing a stochastic negative feedback biocircuit that satisfies multiple statistical constraints. In particular, we use a rigorously quantified parameter map of feasible design space to perform in-depth study of noise propagation and regulation in negative feedback pathways.The authors contributed equally to this work.

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Bounding the stationary distributions of the chemical master equation via mathematical programming

Cited by 35 publications

References 80 publications

Comprehensive Review of Models and Methods for Inferences in Bio-Chemical Reaction Networks

Comprehensive Review of Models and Methods for Inferences in Bio-Chemical Reaction Networks

Control Variates for Stochastic Simulation of Chemical Reaction Networks

Optimization-based synthesis of stochastic biocircuits with statistical specifications

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