New dose-response model and SARS-CoV-2 quanta emission rates for calculating the long-range airborne infection risk
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https://hdl.handle.net/10037/28283Date
2022-12-14Type
Journal articleTidsskriftartikkel
Peer reviewed
Abstract
Predictive models for airborne infection risk have been extensively used during the pandemic, but there is yet
still no consensus on a common approach, which may create misinterpretation of results among public health
experts and engineers designing building ventilation. In this study we applied the latest data on viral load,
aerosol droplet sizes and removal mechanisms to improve the Wells Riley model by introducing the following
novelties i) a new model to calculate the total volume of respiratory fluid exhaled per unit time ii) developing a
novel viral dose-based generation rate model for dehydrated droplets after expiration iii) deriving a novel
quanta-RNA relationship for various strains of SARS-CoV-2 iv) proposing a method to account for the incomplete
mixing conditions. These new approaches considerably changed previous estimates and allowed to determine
more accurate average quanta emission rates including omicron variant. These quanta values for the original
strain of 0.13 and 3.8 quanta/h for breathing and speaking and the virus variant multipliers may be used for
simple hand calculations of probability of infection or with developed model operating with six size ranges of
aerosol droplets to calculate the effect of ventilation and other removal mechanisms. The model developed is
made available as an open-source tool.
Publisher
ElsevierCitation
Aganovic A, Cao, Wargocki, Kurnitski. New dose-response model and SARS-CoV-2 quanta emission rates for calculating the long-range airborne infection risk. Building and Environment. 2022;228Metadata
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