COVID-19: Aerosolized particles carrying virus stay in the air longer than previously thought

The model revealed the aerosol-cloud containing COVID-19 spreads outside the immediate vicinity of the coughing person and dilutes in the process, but the dilution occurs over several minutes.

Summary: New model reveals the aerosolized particles carrying the coronavirus can remain in the air longer than was previously suggested. Researchers modeled a scenario where an infected person coughs in a supermarket aisle and takes into consideration in-store ventilation systems. The model revealed the aerosol-cloud containing COVID-19 spreads outside the immediate vicinity of the coughing person and dilutes in the process, but the dilution occurs over several minutes.

Source: Aalto University

A joint project carried out by four Finnish research organizations has studied the transport and spread of coronavirus through the air. Preliminary results indicate that aerosol particles carrying the virus can remain in the air longer than was originally thought, so it is important to avoid busy public indoor spaces. This also reduces the risk of droplet infection, which remains the main path of transmission for coronavirus.

Aalto University, Finnish Meteorological Institute, VTT Technical Research Centre of Finland and University of Helsinki have studied how extremely small airborne aerosol particles emitted from the respiratory tract when coughing, sneezing or even talking are transported in the air. Such particles can carry pathogens such as coronaviruses.

The researchers modeled a scenario where a person coughs in an aisle between shelves, like those found in grocery stores; and taking into consideration the ventilation. Aalto University, VTT Technical Research Centre of Finland and Finnish Meteorological Institute each carried out the modeling independently, using the same starting conditions.

The researchers obtained the same preliminary result: in the situation under investigation, the aerosol cloud spreads outside the immediate vicinity of the coughing person and dilutes in the process. However, this can take up to several minutes. ‘Someone infected by the coronavirus, can cough and walk away, but then leave behind extremely small aerosol particles carrying the coronavirus. These particles could then end up in the respiratory tract of others in the vicinity’, explains Aalto University Assistant Professor Ville Vuorinen.

‘The preliminary results obtained by the consortium highlight the importance of our recommendations. The Finnish Institute for Health and Welfare recommends that you stay at home if you are unwell and that you maintain physical distance with everyone. The instructions also include coughing into your sleeve or a tissue and taking care of good hand hygiene’, says Jussi Sane, Chief Specialist at the Finnish Institute for Health and Welfare.

‘Based on the modeling of the consortium, it is not yet possible to directly issue new recommendations. However, these results are an important part of the whole, and they should be compared with the data from real-life epidemic studies,’ Sane adds.

The spread of diseases through social networks has been studied extensively. From these infection models, it is known that the spread of a virus may slow down or even be suppressed altogether as mobility decreases at ‘nodal points’ – places where lots of people gather, such as shops, restaurants and public transport. Avoiding busy indoor areas reduces the risk of droplet infection while in close proximity to others, which, according to current information, is the main cause of coronavirus infection.


Credit: Aalto University / Finnish Meteorological Institute / VTT / University of Helsinki: Animation: Mikko Auvinen and Antti Hellsten.

The researchers of the consortium modeled the airborne movement of aerosol particles smaller than 20 micrometers. For a dry cough, which is a typical symptom of the current coronavirus, the particle size is typically less than 15 micrometers. Extremely small particles of this size do not sink on the floor, but instead, move along in the air currents or remain floating in the same place. Studies of influenza A have confirmed that the influenza A virus can be found in the smallest particles, which measure less than 5 micrometers.

Supercomputer used for modeling

The project involves around 30 researchers, whose specializations include fluid dynamics, aerosol physics, social networks, ventilation, virology, and biomedical engineering. The research is being carried out in conjunction with Essote (the joint municipal authority for social and health services in South Savo), which proposed the research project, as well as infectious diseases specialists from the Finnish Institute for Health and Welfare.

This shows the aerosol cloud model
The researchers modeled a situation in which a person coughs down a shelf-restricted corridor typical of grocery stores. The image is credited to Petteri Peltonen / Aalto University.

The airborne transport and preservation of droplets leaving the respiratory tract were simulated using a supercomputer, and 3D visualization of the results was then carried out. CSC – Finnish IT Center for Science Ltd. made its supercomputer available to researchers at very short notice. Thanks to the high computing capacity and close, multidisciplinary cooperation, the first results were produced in around a week.

The physics of the phenomena now being modeled are very familiar from previous research. The consortium aims to use visualization to create a better understanding of the behavior of aerosol particles. Researchers will continue to work on the modeling and further refine it. Experts in infectious diseases and virology will examine the results and their importance in relation to the information being gathered on coronavirus and coronavirus infections. The involvement of two Swedish universities has further strengthened the consortium.

About this COVID-19 research article

Source:
Aalto University
Media Contacts:
Ville Vuorinen – Aalto University
Image Source:
The image is credited to Petteri Peltonen / Aalto University.

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