Risk assessment for airborne disease transmission by poly-pathogen aerosols

Bodenschatz, Eberhard; Bagheri, Gholamhossein

doi:10.1101/2020.11.30.20241083

Cited by 8 publications

(24 citation statements)

References 44 publications

(137 reference statements)

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“…In particular, small particles, e.g. <10 µm, shrink by evaporation in a fraction of a second under typical ambient conditions and remain in the air for a long time [e.g., see [12][13][14]29]. In addition, the situation-specific particle size and concentration determine the protective properties of filtering face masks [see e.g.…”

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confidence: 99%

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Exhaled particles from nanometre to millimetre and their origin in the human respiratory tract

Bagheri

Schlenczek

Turco

et al. 2021

Preprint

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Detailed knowledge of the properties of exhaled particles from the human respiratory tract for all genders and ages is essential to determine the modes of transmission of airborne diseases. This applies not only to the current COVID-19 pandemic, but also to many others, be it measles, seasonal influenza or tuberculosis. To date, there are no data on the individual-specific concentrations and sizes of exhaled particles over the entire size range from nanometre to millimetre. Here we present a comprehensive data set, measured by particle size spectrometry and in-line holography covering the entire size range from 132 healthy volunteers aged 5 to 80 years for a defined set of breathing and vocalisation activities. We find age to have a large effect on small particle concentrations (<5 microns), doubling in children during adolescence and in adults over a 30-year period. In contrast, gender, body mass index, smoking or exercise habits have no discernible influence. Particles >20 microns show on average no measurable dependence on the type of vocalisation with the exception of shouting. We show evidence that particles <5 microns mainly originate in the lower respiratory tract, 5-15 microns in the larynx/pharynx, and >15 microns in the oral cavity.

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confidence: 99%

“…, 14]. The shrinkage of these particles, defined as the particle diameter in the respiratory tract compared to the equilibrium size they reach at ambient relative humidity (RH), determines their deposition rates on surfaces and residence times in the air [13,14,[22][23][24][25][26][27][28]. In particular, small particles, e.g.…”

mentioning

confidence: 99%

Exhaled particles from nanometre to millimetre and their origin in the human respiratory tract

Bagheri

Schlenczek

Turco

et al. 2021

Preprint

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“…Ventilation rates and deposition in the respiratory tract of the susceptible individual are calculated based on the ICRP lung deposition model [52], where the inhaled aerosols undergo time-dependent hygroscopic growth and under best estimates are only composed of water and NaCl. The risk of infection is calculated under the assumption of an exponential model and monopathogenic aerosols [5]. Note that for the parameters studied here, the polypathogen model yields a lower infection risk [5] and therefore the monopathogen model is best for estimating the upper bound.…”

Section: Methodsmentioning

confidence: 99%

“…The risk of infection is calculated under the assumption of an exponential model and monopathogenic aerosols [5]. Note that for the parameters studied here, the polypathogen model yields a lower infection risk [5] and therefore the monopathogen model is best for estimating the upper bound. We also assumed that the initial absorbed dose to the susceptible individual was zero.…”

Section: Methodsmentioning

confidence: 99%

“…While moist exhaled aerosols larger than 50 µm settle by gravitational deposition on room surfaces before drying, smaller droplets dry rapidly, thereby shrink, and due to their small mass remain airborne for extended periods of time [3]. Such aerosols may contain single or multiple copies of pathogens when exhaled by an infectious, and when inhaled by a susceptible, there is a risk of infection given by the absorbed dose of pathogens [5]. In order to control and minimize airborne transmission risk by infectious aerosols, it is essential to further our understanding of aerosol dynamics and dispersion across their large spectrum of size distributions.…”

Section: Introductionmentioning

confidence: 99%

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Aerosol transport measurements and assessment of risk from infectious aerosols: a case study of two German cash-and-carry hardware/DIY stores

Hejazi¹,

Schlenczek²,

Thiede³

et al. 2021

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We report experimental results on aerosol dispersion in two large German cash-and-carry hardware/DIY stores to better understand the factors contributing to disease transmission by infectious human aerosols in large indoor environments. We examined the transport of aerosols similar in size to human respiratory aerosols (0.3μm-10μm) in representative locations, such as high-traffic areas and restrooms. In restrooms, the observed decay of aerosol concentrations was consistent with well-mixed air exchange. In all other locations, fast decay times were measured, which were found to be independent of aerosol size (typically a few minutes). From this, we conclude that in the main retail areas, including at checkouts, rapid turbulent mixing and advection is the dominant feature in aerosol dynamics. With this, the upper bound of risk for airborne disease transmission to a susceptible is determined by direct exposure to the exhalation cloud of an infectious. For the example of the SARS-CoV-2 virus, we find when speaking without a face mask and aerosol sizes up to an exhalation (wet) diameter of 50μm, a distance of 1.5me to be unsafe. However, at the smallest distance between an infectious and a susceptible, while wearing typical surgical masks and for all sizes of exhaled aerosol, the upper bound of infection risk is only ∼ 5% and decreases further by a factor of 100 (∼ 0.05%) for typical FFP2 masks for a duration of 20 min. This upper bound is very conservative and we expect the actual risk for typical encounters to be much lower. The risks found here are comparable to what might be expected in calm outdoor weather.

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Impact of the Euro 2020 championship on the spread of COVID-19

et al. 2023

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Large-scale events like the UEFA Euro 2020 football (soccer) championship offer a unique opportunity to quantify the impact of gatherings on the spread of COVID-19, as the number and dates of matches played by participating countries resembles a randomized study. Using Bayesian modeling and the gender imbalance in COVID-19 data, we attribute 840,000 (95% CI: [0.39M, 1.26M]) COVID-19 cases across 12 countries to the championship. The impact depends non-linearly on the initial incidence, the reproduction number R, and the number of matches played. The strongest effects are seen in Scotland and England, where as much as 10,000 primary cases per million inhabitants occur from championship-related gatherings. The average match-induced increase in R was 0.46 [0.18, 0.75] on match days, but important matches caused an increase as large as +3. Altogether, our results provide quantitative insights that help judge and mitigate the impact of large-scale events on pandemic spread.

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Risk assessment for airborne disease transmission by poly-pathogen aerosols

Cited by 8 publications

References 44 publications

Exhaled particles from nanometre to millimetre and their origin in the human respiratory tract

Exhaled particles from nanometre to millimetre and their origin in the human respiratory tract

Aerosol transport measurements and assessment of risk from infectious aerosols: a case study of two German cash-and-carry hardware/DIY stores

Impact of the Euro 2020 championship on the spread of COVID-19

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