A computational model for predicting changes in infection dynamics due to leakage through N95 respirators

Hariharan, Prasanna; Sharma, Neha; Guha, Sudipto; Banerjee, Rupak; D’Souza, Gavin A.; Myers, Matthew R.

doi:10.1038/s41598-021-89604-7

Cited by 15 publications

(15 citation statements)

References 30 publications

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“…Particularly when talking, the number of particles captured by the mask increased at a rate of about 5% per L/min [ 45 ], suggesting that less aerosol was leaked. Similar conclusions were drawn by Hariharan et al, who investigated the particle leakage with different respirators, measuring a reduction from 17–22% to 4% when the flow rate was increased from 10 L/min to 70 L/min [ 46 ]. Tang et al studied the turbulent jet caused by coughing and suggested that, according to the typology of the mask worn, it is possible to thwart the trajectory of the jet, directing airflow towards the boundaries of masks with poor fit [ 47 ].…”

Section: Discussionsupporting

confidence: 83%

A Simple Method to Quantify Outward Leakage of Medical Face Masks and Barrier Face Coverings: Implication for the Overall Filtration Efficiency

Chiera

Cristoforetti

Benedetti

et al. 2022

IJERPH

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Face masking proved essential to reduce transmission of COVID-19 and other respiratory infections in indoor environments, but standards and literature do not provide simple quantitative methods for quantifying air leakage at the face seal. This study reports an original method to quantify outward leakage and how wearing style impacts on leaks and filtration efficiency. The amount of air leakage was evaluated on four medical masks and four barrier face coverings, exploiting a theoretical model and an instrumented dummy head in a range of airflows between 30 and 160 L/min. The fraction of air leaking at the face seal of the medical masks and barrier face coverings ranged from 43% to 95% of exhaled air at 30 L/min and reduced to 10–85% at 160 L/min. Filter breathability was the main driver affecting both leak fraction and total filtration efficiency that varied from 5% to 53% and from 15% to 84% at 30 and 160 L/min, respectively. Minor changes were related to wearing style, supporting indications on the correct mask use. The fraction of air leaking from medical masks and barrier face coverings during exhalation is relevant and varies according to design and wearing style. The use of highly breathable filter materials reduces air leaks and improve total filtration efficiency.

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Section: Discussionsupporting

confidence: 83%

A Simple Method to Quantify Outward Leakage of Medical Face Masks and Barrier Face Coverings: Implication for the Overall Filtration Efficiency

Chiera

Cristoforetti

Benedetti

et al. 2022

IJERPH

View full text Add to dashboard Cite

show abstract

“…Similar observations were reported for breathing, coughing and sneezing by using human subjects [ 24 , 33 , 50 ], manikin model [ 22 , 23 , 39 , 53 ] or CFD models [ 26 ]. Furthermore, leakages were also found for KN95 or N95 masks [ 25 , 42 , 55 , 56 ]. Especially in closed rooms without effective ventilation, exhaled aerosol particles can accumulate and develop a critical concentration if single persons are infected.…”

Section: Discussionmentioning

confidence: 99%

Effects of surgical masks on aerosol dispersion in professional singing

Kniesburges

Schlegel

Peters

et al. 2021

J Expo Sci Environ Epidemiol

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Background In the CoVID-19 pandemic, singing came into focus as a high-risk activity for the infection with airborne viruses and was therefore forbidden by many governmental administrations. Objective The aim of this study is to investigate the effectiveness of surgical masks regarding the spatial and temporal dispersion of aerosol and droplets during professional singing. Methods Ten professional singers performed a passage of the Ludwig van Beethoven’s “Ode of Joy” in two experimental setups—each with and without surgical masks. First, they sang with previously inhaled vapor of e-cigarettes. The emitted cloud was recorded by three cameras to measure its dispersion dynamics. Secondly, the naturally expelled larger droplets were illuminated by a laser light sheet and recorded by a high-speed camera. Results The exhaled vapor aerosols were decelerated and deflected by the mask and stayed in the singer’s near-field around and above their heads. In contrast, without mask, the aerosols spread widely reaching distances up to 1.3 m. The larger droplets were reduced by up to 86% with a surgical mask worn. Significance The study shows that surgical masks display an effective tool to reduce the range of aerosol dispersion during singing. In combination with an appropriate aeration strategy for aerosol removal, choir singers could be positioned in a more compact assembly without contaminating neighboring singers all singers.

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“…These values are subsequently summed to calculate the leakage gap surface area. 8,13 The following measures are used to assess the fit for various frame designs (1) contact gap profile between the face mask and the headform and (2) surface area of the leakage gap created due to imperfect fit.…”

Section: Methodsmentioning

confidence: 99%

In Silico Fit Evaluation of Additively Manufactured Face Coverings

Carr

D’Souza

et al. 2022

Ann Biomed Eng

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In response to the respiratory protection device shortage during the COVID-19 pandemic, the additive manufacturing (AM) community designed and disseminated numerous AM face masks. Questions regarding the effectiveness of AM masks arose because these masks were often designed with limited (if any) functional performance evaluation. In this study, we present a fit evaluation methodology in which AM face masks are virtually donned on a standard digital headform using finite element-based numerical simulations. We then extract contour plots to visualize the contact patches and gaps and quantify the leakage surface area for each mask frame. We also use the methodology to evaluate the effects of adding a foam gasket and variable face mask sizing, and finally propose a series of best practices. Herein, the methodology is focused only on characterizing the fit of AM mask frames and does not considering filter material or overall performance. We found that AM face masks may provide a sufficiently good fit if the sizing is appropriate and if a sealing gasket material is present to fill the gaps between the mask and face. Without these precautions, the rigid nature of AM materials combined with the wide variation in facial morphology likely results in large gaps and insufficient adaptability to varying user conditions which may render the AM face masks ineffective.

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A computational model for predicting changes in infection dynamics due to leakage through N95 respirators

Cited by 15 publications

References 30 publications

A Simple Method to Quantify Outward Leakage of Medical Face Masks and Barrier Face Coverings: Implication for the Overall Filtration Efficiency

A Simple Method to Quantify Outward Leakage of Medical Face Masks and Barrier Face Coverings: Implication for the Overall Filtration Efficiency

Effects of surgical masks on aerosol dispersion in professional singing

In Silico Fit Evaluation of Additively Manufactured Face Coverings

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