Iterative community-driven development of a SARS-CoV-2 tissue simulator

Getz, Michael; Wang, Yafei; An, Gary; Asthana, Maansi; Becker, Andrew; Cockrell, Chase; Collier, Nicholson; Craig, Morgan; Davis, Courtney L.; Faeder, James R.; Versypt, Ashlee N. Ford; Mapder, Tarunendu; Gianlupi, Juliano Ferrari; Glazier, James A.; Hamis, Sara; Heiland, Randy; Hillen, Thomas; Hou, Dennis; Islam, Mohammad Aminul; Jenner, Adrianne L.; Kurtoglu, Furkan; Larkin, Caroline I; Liu, Bing; Macfarlane, Fiona; Maygrundter, Pablo; Morel, Penelope A.; Narayanan, Aarthi; Ozik, Jonathan; Pienaar, Elsje; Rangamani, Padmini; Saglam, Ali S.; Shoemaker, Jason E.; Smith, Amber M.; Weaver, Jordan J. A.; Macklin, Paul

doi:10.1101/2020.04.02.019075

Cited by 52 publications

(115 citation statements)

References 209 publications

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“…While there are many mathematical models developed at epidemiological level for COVID-19 to discuss the transmission of SARS-CoV-2 and de-confinement strategies ( Anderson, Heesterbeek, Klinkenberg, Hollingsworth, 2020 , Ferretti, Wymant, Kendall, Zhao, Nurtay, Abeler-Dörner, Parker, Bonsall, Fraser, 2020 , Lopez, Rodo, 2020 , Mejia-Hernandez, Hernandez-Vargas, 2020 , Peng, Yang, Zhang, Zhuge, & Hong , Ricardo-Azanza, Vargas-Hernandez, 2020 ), there are too few models at within-host level to understand SARS-CoV-2 replication cycle, interactions with the immune system, and drug effects ( Du, Yuan, 2020 , Ejima, Kim, Ito, Iwanami, Ohashi, Koizumi, Watashi, Bento, Aihara, Iwami, 2020 , Gonçalves, Bertrand, Ke, Comets, de Lamballerie, Malvy, Pizzorno, Terrier, Calatrava, Mentré, Smith, Perelson, Guedj, 2020 , Goyal, Cardozo-Ojeda, Schiffer, 2020 , Su, Ejima, Ito, Iwanami, Ohashi, 2020 , Wang, Heiland, Craig, Davis, Ford Versypt, Jenner, Ozik, Collier, Cockrell, Becker, An, Glazier, Narayanan, Smith, Macklin, 2020 ). Among different model structures to represent viral dynamics, the target cell limited model has served to represent several diseases such as HIV Hernandez-Vargas and Middleton (2013) ; Perelson and Ribeiro (2013) ; Pinkevych et al.…”

Section: Introductionmentioning

confidence: 99%

In-host Mathematical Modelling of COVID-19 in Humans

Hernandez‐Vargas

Hernández

2020

Annual Reviews in Control

183

196

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COVID-19 pandemic has underlined the impact of emergent pathogens as a major threat for human health. The development of quantitative approaches to advance comprehension of the current outbreak is urgently needed to tackle this severe disease. Considering different starting times of infection, mathematical models are proposed to represent SARS-CoV-2 dynamics in infected patients. Based on the target cell limited model, the within-host reproductive number for SARS-CoV-2 is consistent with the broad values of human influenza infection. The best model to fit the data was including immune cell response, which suggests a slow immune response peaking between 5 to 10 days post-onset of symptoms. The model with the eclipse phase, time in a latent phase before becoming productively infected cells, was not supported. Interestingly, all models predict that SARS-CoV-2 may replicate very slowly in the first days after infection, and viral load could be below detection levels during the first 4 days post infection. A quantitative comprehension of SARS-CoV-2 dynamics and the estimation of standard parameters of viral infections is the key contribution of this pioneering work. These models can serve for future evaluation of control theoretical approaches to tailor new potential drugs against COVID-19.

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Section: Introductionmentioning

confidence: 99%

In-host Mathematical Modelling of COVID-19 in Humans

Hernandez‐Vargas

Hernández

2020

Annual Reviews in Control

183

196

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“…The modelling and simulation of such complex scenarios require a dedicated multiscale computational architecture, where multiple models run in parallel and communicate among them to capture cellular behaviour and intercellular communications. Multiscale agent-based models simulate processes taking place at different time scales, e.g., diffusion, cell mechanics, cell cycle, or signal transduction [294], proposed also for COVID-19 [295]. PhysiBoSS [296] allows such simulation of intracellular processes by combining the computational framework of PhysiCell [297] with MaBoSS [298] tool for stochastic simulation of logical models to study of transient effects and perturbations [299].…”

Section: Multiscale and Stochastic Computational Modellingmentioning

confidence: 99%

COVID-19 Disease Map, a computational knowledge repository of SARS-CoV-2 virus-host interaction mechanisms

Ostaszewski

Niarakis

Mazein

et al. 2020

Preprint

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We hereby describe a large-scale community effort to build an open-access, interoperable, and computable repository of COVID-19 molecular mechanisms - the COVID-19 Disease Map. We discuss the tools, platforms, and guidelines necessary for the distributed development of its contents by a multi-faceted community of biocurators, domain experts, bioinformaticians, and computational biologists. We highlight the role of relevant databases and text mining approaches in enrichment and validation of the curated mechanisms. We describe the contents of the map and their relevance to the molecular pathophysiology of COVID-19 and the analytical and computational modelling approaches that can be applied to the contents of the COVID-19 Disease Map for mechanistic data interpretation and predictions. We conclude by demonstrating concrete applications of our work through several use cases.

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“…Mathematical modeling methods integrate the available host- and pathogen-level data on disease dynamics that are required to understand the complex biology of infection and immune response to optimize therapeutic interventions [3–5]. Mathematical models and computer simulations built on spatial and ODE frameworks have been extensively used to study in-host progression of viral infection [6], with a recent acceleration in the development of spatial COVID-19 viral infection models in response to the global pandemic [7, 8].…”

Section: Introductionmentioning

confidence: 99%

“…We approximate the discrete process of a cell’s internalization of a virus particle by a stochastic virus internalization event ( E1 ) determined by time elapsed, the local concentration of the virus field, and the number of available cell-surface receptors on the cell. We simplify the complexity of viral replication into four steps: unpacking, viral genome replication, protein synthesis and packaging/assembly ( E2 , Fig 2B) [7,52–54]. The subcellular kinetics of viral replication determine the rate of release of new virus particles into the extracellular environment ( E3 ).…”

Section: Introductionmentioning

confidence: 99%

A modular framework for multiscale, multicellular, spatiotemporal modeling of acute primary viral infection and immune response in epithelial tissues and its application to drug therapy timing and effectiveness

Sego

Aponte-Serrano

Ferrari-Gianlupi

et al. 2020

Preprint

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The COVID-19 crisis has shown that classic sequential models for scientific research are too slow and do not easily encourage multidisciplinary scientific collaboration. The need to rapidly understand the causes of differing infection outcomes and vulnerabilities, to provide mechanistic frameworks for the interpretation of experimental and clinical data and to suggest drug and therapeutic targets and to design optimized personalized interventions all require the development of detailed predictive quantitative models of all aspects of COVID-19. Many of these models will require the use of common submodels describing specific aspects of infection ( e.g. , viral replication) but combine them in novel configurations. As a contribution to this development and as a proof-of-concept for some components of these models, we present a multi-layered 2D multiscale, multi-cell model and associated computer simulations of the infection of epithelial tissue by a virus, the proliferation and spread of the virus, the cellular immune response and tissue damage. Our initial, proof-of-concept model is built of modular components to allow it to be easily extended and adapted to describe specific viral infections, tissue types and immune responses. Immediately after a cell becomes infected, the virus replicates inside the cell. After an eclipse period, the infected cells start shedding diffusing infectious virus, infecting nearby cells, and secretes a short-diffusing cytokine signal. Neighboring cells can take up the diffusing extracellular virus and become infected. The cytokine signal calls for immune cells from a simple model of the systemic immune response. These immune cells chemotax and activate within the tissue in response to the cytokine profile. Activated immune cells can kill underlying epithelial cells directly or by secreting a short-diffusible toxic chemical. Infected cells can also die by apoptosis due to the stress of viral replication. We do not include direct cytokine mediated protective factors in the tissue or distinguish the complexity of the immune response in this simple model. Despite unrealistically fast viral production and immune response, the current base model allows us to define three parameter regimes, where the immune system rapidly controls the virus, where it controls the virus after extensive tissue damage, and where the virus escapes control and infects and kills all / cells. We can simulate a number of drug therapy concepts, like delayed rate of production of viral RNAs, reduced viral entry, and higher and lower levels of immune response, which we demonstrate with simulation results of parameter sweeps of select model parameters. From results of these sweeps, we found that successful containment of infection in simulation directly relates to inhibited viral internalization and rapid immune cell recruitment, while spread of infection occurs in simulations with fast viral internalization and slower immune response. In contrast to other simulations of viral infection, our simulated tissue demonstrates...

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Iterative community-driven development of a SARS-CoV-2 tissue simulator

Cited by 52 publications

References 209 publications

In-host Mathematical Modelling of COVID-19 in Humans

In-host Mathematical Modelling of COVID-19 in Humans

COVID-19 Disease Map, a computational knowledge repository of SARS-CoV-2 virus-host interaction mechanisms

A modular framework for multiscale, multicellular, spatiotemporal modeling of acute primary viral infection and immune response in epithelial tissues and its application to drug therapy timing and effectiveness

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