Formal reasoning about systems biology using theorem proving

Rashid, Adnan; Hasan, Osman; Siddique, Umair; Tahar, Sofiène

doi:10.1371/journal.pone.0180179

Cited by 9 publications

(10 citation statements)

References 59 publications

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“…Hence, there is a growing interest for acquiring evidence-based knowledge via integrated and multiplatform Omics-studies on Cannabis. In this regard, systems biology [1,2] is well-equipped to integrate findings and define the genetic variability and functional metabolites [3] in a model plant system. Model plant research, such as that of well-known Arabidopsis thaliana [4][5][6][7] and the extensively-studied medicinal plant, Papaver somniferum [8][9][10][11][12], highlight the significance of gathering information about regulation of plant fitness and homeostatic mechanisms of metabolites [13] orchestrated by the host genome and its affiliated microbial metagenome [14].…”

Section: Introductionmentioning

confidence: 99%

Scientific Prospects for Cannabis-Microbiome Research to Ensure Quality and Safety of Products

et al. 2020

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Cannabis legalization has occurred in several countries worldwide. Along with steadily growing research in Cannabis healthcare science, there is an increasing interest for scientific-based knowledge in plant microbiology and food science, with work connecting the plant microbiome and plant health to product quality across the value chain of cannabis. This review paper provides an overview of the state of knowledge and challenges in Cannabis science, and thereby identifies critical risk management and safety issues in order to capitalize on innovations while ensuring product quality control. It highlights scientific gap areas to steer future research, with an emphasis on plant-microbiome sciences committed to using cutting-edge technologies for more efficient Cannabis production and high-quality products intended for recreational, pharmaceutical, and medicinal use.

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Section: Introductionmentioning

confidence: 99%

Scientific Prospects for Cannabis-Microbiome Research to Ensure Quality and Safety of Products

et al. 2020

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“…Furthermore, the inherent correctness of the theorem proving method confirms that all the needed assumptions are explicitly existing with the respective theorem. Also, because of the expressiveness feature of the higher-order logic, our methodology permits us to model the biological circuits dynamics involving differential and derivative ((13), (15), (17), (19), (21)) in their true form, while, in their corresponding model checking-based analysis [20], they are discretised and demonstrated using a state-transition system, which compromises the accuracy, correctness and completeness of the corresponding analysis.…”

Section: Discussionmentioning

confidence: 99%

“…Formal methods [14] are computer-based mathematical methods that are being extensively used for the accurate modelling, specification and verification of many complex real-world systems [15][16][17]. They are classified into two categories, i.e.…”

Section: Introductionmentioning

confidence: 99%

Formal reasoning about synthetic biology using higher‐order‐logic theorem proving

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Rashid

Hasan

2020

IET Systems Biology

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Synthetic biology is an interdisciplinary field that uses well-established engineering principles for performing the analysis of the biological systems, such as biological circuits, pathways, controllers and enzymes. Conventionally, the analysis of these biological systems is performed using paper-and-pencil proofs and computer simulation methods. However, these methods cannot ensure accurate results due to their inherent limitations. Higher-order-logic (HOL) theorem proving is proposed and used as a complementary approach for analysing linear biological systems, which is based on developing a mathematical model of the genetic circuits and the bio-controllers used in synthetic biology based on HOL and analysing it using deductive reasoning in an interactive theorem prover. The involvement of the logic, mathematics and the deductive reasoning in this method ensures the accuracy of the analysis. It is proposed to model the continuous dynamics of the genetic circuits and their associated controllers using differential equations and perform their transfer function-based analysis using the Laplace transform in a theorem prover. For illustration, the genetic circuits of activated and repressed expressions and autoactivation of protein, and phase lag and lead controllers, which are widely used in cancer-cell identifiers and multi-input receptors for precise disease detection, are formally analyzed.

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“…The uniqueness of the first integral can be directly handled by Lerch's theorem, whereas, for the case of (−∞, 0], the integral can be first reflected and then the formally verified Lerch's theorem can be used to verify its uniqueness as well. Another future direction is to use this formalization in our project on system biology [30], for finding the analytical solutions of the differential equation based reaction kinetic models of the biological systems.…”

Section: Discussionmentioning

confidence: 99%

Formalization of Transform Methods Using HOL Light

Rashid

Hasan

2017

Lecture Notes in Computer Science

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Abstract. Transform methods, like Laplace and Fourier, are frequently used for analyzing the dynamical behaviour of engineering and physical systems, based on their transfer function, and frequency response or the solutions of their corresponding differential equations. In this paper, we present an ongoing project, which focuses on the higher-order logic formalization of transform methods using HOL Light theorem prover. In particular, we present the motivation of the formalization, which is followed by the related work. Next, we present the task completed so far while highlighting some of the challenges faced during the formalization. Finally, we present a roadmap to achieve our objectives, the current status and the future goals for this project.

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Formal reasoning about systems biology using theorem proving

Cited by 9 publications

References 59 publications

Scientific Prospects for Cannabis-Microbiome Research to Ensure Quality and Safety of Products

Scientific Prospects for Cannabis-Microbiome Research to Ensure Quality and Safety of Products

Formal reasoning about synthetic biology using higher‐order‐logic theorem proving

Formalization of Transform Methods Using HOL Light

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