Sequential Experimental Design for Optimal Structural Intervention in Gene Regulatory Networks Based on the Mean Objective Cost of Uncertainty

Imani, Mahdi; Dehghannasiri, Roozbeh; Braga-Neto, Ulisses; Dougherty, Edward R.

doi:10.1177/1176935118790247

Cited by 17 publications

(5 citation statements)

References 33 publications

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“…This paper employs a Boolean network with perturbation (BNp) model for capturing the dynamics of GRNs ( Shmulevich and Dougherty, 2010 ; Imani et al, 2018 ; Hajiramezanali et al, 2019 ). Previously, several works have successfully employed the BNp model for different purposes such as inference ( Dougherty and Qian, 2013 ; Marshall et al, 2007 ) and classification ( Karbalayghareh et al, 2018 ).…”

Section: Preliminariesmentioning

confidence: 99%

Inference of regulatory networks through temporally sparse data

Alali

Imani²

2022

Front. Control Eng.

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A major goal in genomics is to properly capture the complex dynamical behaviors of gene regulatory networks (GRNs). This includes inferring the complex interactions between genes, which can be used for a wide range of genomics analyses, including diagnosis or prognosis of diseases and finding effective treatments for chronic diseases such as cancer. Boolean networks have emerged as a successful class of models for capturing the behavior of GRNs. In most practical settings, inference of GRNs should be achieved through limited and temporally sparse genomics data. A large number of genes in GRNs leads to a large possible topology candidate space, which often cannot be exhaustively searched due to the limitation in computational resources. This paper develops a scalable and efficient topology inference for GRNs using Bayesian optimization and kernel-based methods. Rather than an exhaustive search over possible topologies, the proposed method constructs a Gaussian Process (GP) with a topology-inspired kernel function to account for correlation in the likelihood function. Then, using the posterior distribution of the GP model, the Bayesian optimization efficiently searches for the topology with the highest likelihood value by optimally balancing between exploration and exploitation. The performance of the proposed method is demonstrated through comprehensive numerical experiments using a well-known mammalian cell-cycle network.

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Section: Preliminariesmentioning

confidence: 99%

Inference of regulatory networks through temporally sparse data

Alali

Imani²

2022

Front. Control Eng.

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“…MOCU tracks how a system loses its performance because of the presence of uncertainty and the next experiment is chosen to reduce MOCU, i.e., that which reduces the variance in the posterior distribution the most. [71] For a cost function f (x), let us define x robust as the point with the expected value of f (x) over the unknown parameters, θ . That is, x robust = arg max x E θ f (x) is the best or 'average' result we can obtain given that θ is unknown.…”

Section: Mean Objective Cost Of Uncertaintymentioning

confidence: 99%

Efficient sampling for decision making in materials discovery*

Tian¹,

Lookman²,

Xue³

2021

Chinese Phys. B

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Accelerating materials discovery crucially relies on strategies that efficiently sample the search space to label a pool of unlabeled data. This is important if the available labeled data sets are relatively small compared to the unlabeled data pool. Active learning with efficient sampling methods provides the means to guide the decision making to minimize the number of experiments or iterations required to find targeted properties. We review here different sampling strategies and show how they are utilized within an active learning loop in materials science.

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“…For each possible experiment, compute MOCU for every possible outcome of the experiment, average these MOCU values, and then take the minimum of these averages over all possible experiments. This can be done sequentially, either greedily by repeating the procedure after the preceding experiment has determined a regulation, and continuing until some stopping criterion has been reached [9], or via dynamic programming [10]. In either case, the result is objective-based optimal experimental design.…”

Section: Optimal Experimental Designmentioning

confidence: 99%

A Nonmathematical Review of Optimal Operator and Experimental Design for Uncertain Scientific Models with Application to Genomics

Dougherty

2019

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Introduction: The most basic aspect of modern engineering is the design of operators to act on physical systems in an optimal manner relative to a desired objective – for instance, designing a control policy to autonomously direct a system or designing a classifier to make decisions regarding the system. These kinds of problems appear in biomedical science, where physical models are created with the intention of using them to design tools for diagnosis, prognosis, and therapy. Methods: In the classical paradigm, our knowledge regarding the model is certain; however, in practice, especially with complex systems, our knowledge is uncertain and operators must be designed while taking this uncertainty into account. The related concepts of intrinsically Bayesian robust operators and optimal Bayesian operators treat operator design under uncertainty. An objective-based experimental design procedure is naturally related to operator design: We would like to perform an experiment that maximally reduces our uncertainty as it pertains to our objective. Results & Discussion: This paper provides a nonmathematical review of optimal Bayesian operators directed at biomedical scientists. It considers two applications important to genomics, structural intervention in gene regulatory networks and classification. Conclusion: The salient point regarding intrinsically Bayesian operators is that uncertainty is quantified relative to the scientific model, and the prior distribution is on the parameters of this model. Optimization has direct physical (biological) meaning. This is opposed to the common method of placing prior distributions on the parameters of the operator, in which case there is a scientific gap between operator design and the phenomena.

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Sequential Experimental Design for Optimal Structural Intervention in Gene Regulatory Networks Based on the Mean Objective Cost of Uncertainty

Cited by 17 publications

References 33 publications

Inference of regulatory networks through temporally sparse data

Inference of regulatory networks through temporally sparse data

Efficient sampling for decision making in materials discovery*

A Nonmathematical Review of Optimal Operator and Experimental Design for Uncertain Scientific Models with Application to Genomics

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