In Silico Modeling of Virus Particle Propagation and Infectivity along the Respiratory Tract: A Case Study for SARS-COV-2

Vimalajeewa, Dixon; Balasubramaniam, Sasitharan; Berry, D.P.; Barry, Gerald

doi:10.1101/2020.08.20.259242

Cited by 3 publications

(11 citation statements)

References 25 publications

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“…This demonstrated the conjecture that the nasopharynx served as the seeding region for the contamination of the lower airway via aspiration of SARS-CoV-2-laden boluses of nasopharyngeal fluids (Basu and Chakravarty, 2020). It is noted that a few previous studies associating virus infection with in silico models have been reported and summarized (Daun and Clermont, 2007;Vaziri and Gopinath, 2008;Ciupe and Heffernan, 2017;Vimalajeewa et al, 2020). It is not hard to see that there is still a long way to go to unravel the mysteries of biomechanics in virus infection by in silico models.…”

Section: Organ-on-a-chipmentioning

confidence: 89%

How Physical Factors Coordinate Virus Infection: A Perspective From Mechanobiology

Liu

Tang

et al. 2021

Front. Bioeng. Biotechnol.

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Pandemics caused by viruses have threatened lives of thousands of people. Understanding the complicated process of viral infection provides significantly directive implication to epidemic prevention and control. Viral infection is a complex and diverse process, and substantial studies have been complemented in exploring the biochemical and molecular interactions between viruses and hosts. However, the physical microenvironment where infections implement is often less considered, and the role of mechanobiology in viral infection remains elusive. Mechanobiology focuses on sensation, transduction, and response to intracellular and extracellular physical factors by tissues, cells, and extracellular matrix. The intracellular cytoskeleton and mechanosensors have been proven to be extensively involved in the virus life cycle. Furthermore, innovative methods based on micro- and nanofabrication techniques are being utilized to control and modulate the physical and chemical cell microenvironment, and to explore how extracellular factors including stiffness, forces, and topography regulate viral infection. Our current review covers how physical factors in the microenvironment coordinate viral infection. Moreover, we will discuss how this knowledge can be harnessed in future research on cross-fields of mechanobiology and virology.

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Section: Organ-on-a-chipmentioning

confidence: 89%

How Physical Factors Coordinate Virus Infection: A Perspective From Mechanobiology

Liu

Tang

et al. 2021

Front. Bioeng. Biotechnol.

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“…Many approaches do consider k c in the steadystate, but we like to draw attention by the community that it can have non-linear relationships with the infected humans, so it should also be associated with different disease stages over time that is bounded by transition probabilities of stage changes (severe stage to mild, and vice versa). Moreover, as shown in both (20) and (21), that non-linearities do exist, for example, the relationship V r (t) P v (t) is added to the model but is currently non-existing in the literature. The initial virus concentration V 0 can be directly obtained from values in Table I.…”

Section: B Extra-body Molecular Communications Modelsmentioning

confidence: 99%

“…There are three main blocks in the model: the droplets entrance rate, the mouth-lung propagation, and the virus replication and deposition rates. The general model of virus propagation is based on a governing equation based on the Fick's second law for advection-diffusion investigated in [20]. This model accounts for the concentration of the virus in a particular branch of the respiratory tract G i , and can be represented as…”

Section: B Extra-body Molecular Communications Modelsmentioning

confidence: 99%

“…Secondly, there is the infection process of internal progression. The model for the viral entry can be found in [20] , which accounts for virus dispersion along the respiratory tract impacted by factors such as the respiratory rate, viral exposure levels (i.e., the quantity of virus that is inhaled), and the virus particle size. The authors developed a computational model to account for the changes in the virus propagation as it enters and propagates in the respiratory tract.…”

Section: Molecular Communications For Viral Infectionsmentioning

confidence: 99%

“…Even though there are models for molecular communications for bacterial infection [15] , [16] , there have not been any surveys proposed for molecular communications models of viral infections. To date, molecular communications models for viral infection includes multi-hop transfer of genetic content through diffusion over extracellular channels [17] , viral propagation in the air [18] , [19] , propagation within the respiratory tract [20] , as well as interactions with host cells [21] . Even though these models are very interesting and provide a formidable representation of biology through the glasses of a molecular communications researcher, the issue of virus propagation and the infection itself are much more complex.…”

Section: Introductionmentioning

confidence: 99%

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Molecular Communications in Viral Infections Research: Modeling, Experimental Data, and Future Directions

Barros

Veletić

Kanada

et al. 2021

IEEE Trans. Mol. Biol. Multi-Scale Commun.

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Hundreds of millions of people worldwide are affected by viral infections each year, and yet, several of them neither have vaccines nor effective treatment during and postinfection. This challenge has been highlighted by the COVID-19 pandemic, showing how viruses can quickly spread and impact society as a whole. Novel interdisciplinary techniques must emerge to provide forward-looking strategies to combat viral infections, as well as possible future pandemics. In the past decade, an interdisciplinary area involving bioengineering, nanotechnology and information and communication technology (ICT) has been developed, known as Molecular Communications. This new emerging area uses elements of classical communication systems to molecular signalling and communication found inside and outside biological systems, characterizing the signalling processes between cells and viruses. In this paper, we provide an extensive and detailed discussion on how molecular communications can be integrated into the viral infectious diseases research, and how possible treatment and vaccines can be developed considering molecules as information carriers. We provide a literature review on molecular communications models for viral infection (intra-body and extra-body), a deep analysis on their effects on immune response, how experimental can be used by the molecular communications community, as well as open issues and future directions.

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A prevalence study of COVID-19 among healthcare workers in a pandemic hospital in the Samsun province of Turkey

2022

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Among populations globally, many healthcare workers have been disproportionally impacted by the COVID-19 pandemic because of their above average exposure to people infected with SARS-CoV-2. Exposure to asymptomatic or pre-symptomatic individuals is particularly challenging, if those individuals continue to work, not knowing that they are potentially infectious. This study aimed to measure the level of asymptomatic infection in a cohort of workers in a healthcare setting in Turkey during the second major wave of infection in late 2020. Blood samples were collected and tested by electrochemiluminescence immunoassay for SARS-CoV-2 IgM and IgG antibodies. Nasal and throat swabs were performed in a subset of this cohort and RT-qPCR was used to search for the presence of SARS-CoV-2 RNA. The results showed that approximately 23% of the cohort were positive for anti-SARS-CoV-2 IgM antibodies and approximately 22% were positive for anti-SARS-CoV-2 IgG antibodies despite no reported history of COVID-19 symptoms. Just less than 30% of a subset of the group were positive for the presence of SARS-CoV-2 RNA indicating the likelihood of a current or recent infection, again despite a lack of typical COVID-19 associated symptoms. This study indicates a high rate of asymptomatic infection and highlights the need for regular testing of groups such as healthcare workers when community prevalence of disease is high and there is a desire to limit entry of virus into settings where vulnerable people may be present, because symptoms cannot be relied on as indicators of infection or infectiousness.

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In Silico Modeling of Virus Particle Propagation and Infectivity along the Respiratory Tract: A Case Study for SARS-COV-2

Cited by 3 publications

References 25 publications

How Physical Factors Coordinate Virus Infection: A Perspective From Mechanobiology

How Physical Factors Coordinate Virus Infection: A Perspective From Mechanobiology

Molecular Communications in Viral Infections Research: Modeling, Experimental Data, and Future Directions

A prevalence study of COVID-19 among healthcare workers in a pandemic hospital in the Samsun province of Turkey

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