Abstract
Insights gained from multilevel computational models of biological systems can be translated into real-life applications only if the model correctness has been verified first. One of the most frequently employed in silico techniques for computational model verification is model checking. Traditional model checking approaches only consider the evolution of numeric values, such as concentrations, over time and are appropriate for computational models of small scale systems (e.g. intracellular networks). However for gaining a systems level understanding of how biological organisms function it is essential to consider more complex large scale biological systems (e.g. organs). Verifying computational models of such systems requires capturing both how numeric values and properties of (emergent) spatial structures (e.g. area of multicellular population) change over time and across multiple levels of organization, which are not considered by existing model checking approaches. To address this limitation we have developed a novel approximate probabilistic multiscale spatio-temporal meta model checking methodology for verifying multilevel computational models relative to specifications describing the desired/expected system behaviour. The methodology is generic and supports computational models encoded using various high-level modelling formalisms because it is defined relative to time series data and not the models used to generate it. In addition, the methodology can be automatically adapted to case study specific types of spatial structures and properties using the spatio-temporal meta model checking concept. To automate the computational model verification process we have implemented the model checking approach in the software tool Mule (http://mule.modelchecking.org). Its applicability is illustrated against four systems biology computational models previously published in the literature encoding the rat cardiovascular system dynamics, the uterine contractions of labour, the Xenopus laevis cell cycle and the acute inflammation of the gut and lung. Our methodology and software will enable computational biologists to efficiently develop reliable multilevel computational models of biological systems.
Highlights
Multilevel computational models of complex biological systems are abstract representations of living systems that span multiple levels of organization
Using the novel model checking approach introduced in this paper multilevel computational models of biological systems can be verified relative to formal specifications as described by the workflow depicted in Fig 1, which comprises four steps: 1. Model construction: Using biological observations and/or relevant references from the literature to construct the computational model
To the best of our knowledge the only formal language for reasoning about numeric and spatial properties corresponding to computational models of biological systems is called Bounded Linear Spatial Temporal Logic (BLSTL), which we have previously introduced in [57]
Summary
Multilevel computational models of complex biological systems are abstract representations of living systems that span multiple levels of organization. In systems medicine it is argued [4] that multilevel computational models could potentially facilitate delivering personalized treatments by providing a patient specific understanding of how diseases and their treatment reflect across multiple levels of organization [5]. Computational models of biological systems can be validated either in the in vitro environment by checking if the model simulation results can be reproduced experimentally, or in the in silico environment by verifying if the model simulation results conform to a formal specification describing the desired/expected system behaviour. Stochastic nature of biological systems only approximate probabilistic model checking approaches are considered throughout this paper
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