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. 2020 Aug:141:105794.
doi: 10.1016/j.envint.2020.105794. Epub 2020 May 11.

Estimation of airborne viral emission: Quanta emission rate of SARS-CoV-2 for infection risk assessment

G Buonanno  1 L Stabile  2 L Morawska  3
Affiliations

Estimation of airborne viral emission: Quanta emission rate of SARS-CoV-2 for infection risk assessment

G Buonanno et al. Environ Int. 2020 Aug.

Abstract

Airborne transmission is a pathway of contagion that is still not sufficiently investigated despite the evidence in the scientific literature of the role it can play in the context of an epidemic. While the medical research area dedicates efforts to find cures and remedies to counteract the effects of a virus, the engineering area is involved in providing risk assessments in indoor environments by simulating the airborne transmission of the virus during an epidemic. To this end, virus air emission data are needed. Unfortunately, this information is usually available only after the outbreak, based on specific reverse engineering cases. In this work, a novel approach to estimate the viral load emitted by a contagious subject on the basis of the viral load in the mouth, the type of respiratory activity (e.g. breathing, speaking, whispering), respiratory physiological parameters (e.g. inhalation rate), and activity level (e.g. resting, standing, light exercise) is proposed. The results showed that high quanta emission rates (>100 quanta h-1) can be reached by an asymptomatic infectious SARS-CoV-2 subject performing vocalization during light activities (i.e. walking slowly) whereas a symptomatic SARS-CoV-2 subject in resting conditions mostly has a low quanta emission rate (<1 quantum h-1). The findings in terms of quanta emission rates were then adopted in infection risk models to demonstrate its application by evaluating the number of people infected by an asymptomatic SARS-CoV-2 subject in Italian indoor microenvironments before and after the introduction of virus containment measures. The results obtained from the simulations clearly highlight that a key role is played by proper ventilation in containment of the virus in indoor environments.

Keywords: Coronavirus; Indoor; SARS-CoV-2 (CoVID19); Ventilation; Viral load; Virus airborne transmission.

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Conflict of interest statement

Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Figures

Fig. 1
Fig. 1
ERq (quanta h−1) trends as a function of the viral load in sputum (cv, RNA copies mL−1) and quanta-RNA copies correction factor (ci) for different respiratory activities (voiced counting, whispered counting, unmodulated vocalization, breathing) and different activity levels (resting, standing, light exercise, moderate exercise, and heavy exercise). Zones representative of low (<1 quantum h−1) and high (>100 quanta h−1) quanta emission are indicated as blue and red shaded areas, respectively.
Fig. 2
Fig. 2
Details of application of the proposed approach in the calculation of quanta concentrations, n(t), and infection risks, R, in the pharmacy environment for the exposure scenarios before lockdown (B) in natural (NV) and mechanical ventilation (MV) conditions. The graph shows the entry of the infected individual (first 10 min) and the risk for a customer entering the microenvironment at min 26 and remaining inside for 10 min. The trends are shown for up to 100 min to highlight the peaks of the n(t) and R values.
Fig. 3
Fig. 3
R0 calculated for all the exposure scenarios (natural ventilation, mechanical ventilation; before lockdown, after lockdown) and microenvironments (pharmacy, supermarket, restaurant, post office, bank) under investigation considering an asymptomatic SARS-CoV-2 infected subject (cv = 1 × 109 copies mL−1) while performing light exercise activities (ERq = 142 quanta h−1) and exposed population standing and/or performing light exercise (IR = 0.96 m3 h−1).
See this image and copyright information in PMC

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