Toward Understanding the Risk of Secondary Airborne Infection: Emission of Respirable Pathogens

Nicas, Mark; Nazaroff, William W.; Hubbard, Alan

doi:10.1080/15459620590918466

Cited by 735 publications

(895 citation statements)

References 28 publications

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“…[36][37][38] The concentration of airborne bacteria has been shown to vary from as low as 4 to 1000s of CFU m -3 depending on the species. 33,[39][40][41] Airborne viruses have been detected at WWTPs as well. Adenovirus and norovirus concentrations as high as 2.27 × 10 6 genome copies m -3 and 1.42± 1.14 × 10 3 genome copies m -3 , respectively, have been reported.…”

Section: Potential For Aerosol Transmission Via Wastewatermentioning

confidence: 99%

Aerosolization of Ebola Virus Surrogates in Wastewater Systems

Lin

Marr

2017

Environ. Sci. Technol.

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Academic AbstractRecent studies have shown that Ebola virus can persist in wastewater, and the potential for the virus to be aerosolized and pose a risk of inhalation exposure has not been evaluated.We considered this risk for three wastewater systems: toilets, a lab-scale model of an aeration basin, and a lab-scale model of converging sewer pipes. We measured the aeroso l size distribution generated by each system, spiked Ebola virus surrogates into each system, and determined the emission rate of viruses into the air. While the number of aerosols released ranged from 10 5 to 10 7 per flush from the toilets or per minute from the lab-scale models, the total volume of aerosols generated by these systems was ~10 -8 to 10 -7 mL per flush or per minute in all cases. The Ebola virus surrogates MS2 and Phi6, spiked into toilets at an initial concentration of 10 7 PFU mL -1 , were not detected in air after flushing.Airborne concentrations of MS2 and Phi6 were ~20 PFU L -1 and ~0.1 PFU L -1 , respectively, associated with the aeration basin and sewer models. This corresponds to emission rates of 547 PFU min -1 and 3.8 PFU min -1 of MS2 and Phi6, respectively, for the aeration basin and 79 PFU min -1 and 0.3 PFU min -1 for the sewer model. Since informa tio n on the aerosolization of Ebola virus is quite limited, these emission rates can greatly help inform risk assessment of inhalation exposure to Ebola virus.iii

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Section: Potential For Aerosol Transmission Via Wastewatermentioning

confidence: 99%

Aerosolization of Ebola Virus Surrogates in Wastewater Systems

Lin

Marr

2017

Environ. Sci. Technol.

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“…The initial droplet size distribution of the injection was adopted from the coughing size distribution reported in literatures. As reviewed by Nicas et al (2005), there are three major studies about the size distribution of expiratory droplets available in the literature. Papineni and Rosenthal (1997) employed optical particle counters (OPCs) and transmission electron microscope analysis, which covered the size range of only 0.3-8 μm.…”

Section: Boundary Conditionsmentioning

confidence: 99%

“…Duguid (1946) and Louden and Roberts (1967) employed a stain-mark-counting approach, which covered a droplet size range (from 1 to over 1000 μm) much wider than that reported by Papineni and Rosenthal (1997). The data reported by Papineni and Rosenthal (1997) may also suffer from sampling and transmission losses in the OPCs, as indicated by Nicas et al (2005). Comparing with a bioaerosols study, Nicas et al (2005) judged that the size distributions of Duguid (1946) and Loudon and Roberts (1967) were consistent with the study findings but inconsistent with Papineni and Rosenthal (1997).…”

Section: Boundary Conditionsmentioning

confidence: 99%

Dispersion of Expiratory Droplets in a General Hospital Ward with Ceiling Mixing Type Mechanical Ventilation System

Wan

Chao

et al. 2007

Aerosol Science and Technology

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This study investigated the dispersion characteristics of polydispersed droplets in a general hospital ward equipped with ceilingmixing type ventilation system. Injections of water test droplets containing non-volatile content were produced. The injections simulate human coughs with a similar droplet size distribution (peak size at 12 μm) and airflow rate (0.4 L/s). The dispersion of test droplets was measured in-situ by interferometric Mie imaging (IMI) method combined with an aerosol spectrometer. A multiphase numerical model was employed to simulate the droplet dispersion tracks to provide additional transient position tracking data. Results show that the small size group of droplets or droplet nuclei (initial size ≤45 μm) behaved airborne transmittable as some nuclei stayed airborne for more than 360 s. The dispersions were strongly affected by the ventilation airflow pattern. The expiratory droplets exhibited a two-stage lateral dispersion behavior, in which rapid dispersion was found in the early "initial dispersion" stage and then the dispersion became much slower in the subsequent "stable" stage. The exhaust air vents significantly enhanced lateral dispersions towards their direction. Droplets in the large size group (initial size = 87.5 μm and 137.5 μm) were subjected to heavy gravitational effect and stayed airborne for less than 30 s. Results indicate that the location of exhaust air vents has significant impact on the dispersion pattern of expiratory droplets. It should be carefully considered in designing ventilation systems for health-care settings.

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“…Humans produce more aerosol particles when they cough vs. when they exhale 27, 28. Most of the aerosol particles produced during normal breathing are thought to originate deep in the respiratory tract, while coughing may produce aerosol both from the lower airways and also from the upper airways 29, 30, 31.…”

Section: Introductionmentioning

confidence: 99%

Viable influenza A virus in airborne particles expelled during coughs versus exhalations

Lindsley

Blachère

Beezhold

et al. 2016

Influenza Resp Viruses

132

117

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BackgroundTo prepare for a possible influenza pandemic, a better understanding of the potential for the airborne transmission of influenza from person to person is needed.ObjectivesThe objective of this study was to directly compare the generation of aerosol particles containing viable influenza virus during coughs and exhalations.MethodsSixty‐one adult volunteer outpatients with influenza‐like symptoms were asked to cough and exhale three times into a spirometer. Aerosol particles produced during coughing and exhalation were collected into liquid media using aerosol samplers. The samples were tested for the presence of viable influenza virus using a viral replication assay (VRA).ResultsFifty‐three test subjects tested positive for influenza A virus. Of these, 28 (53%) produced aerosol particles containing viable influenza A virus during coughing, and 22 (42%) produced aerosols with viable virus during exhalation. Thirteen subjects had both cough aerosol and exhalation aerosol samples that contained viable virus, 15 had positive cough aerosol samples but negative exhalation samples, and 9 had positive exhalation samples but negative cough samples.ConclusionsViable influenza A virus was detected more often in cough aerosol particles than in exhalation aerosol particles, but the difference was not large. Because individuals breathe much more often than they cough, these results suggest that breathing may generate more airborne infectious material than coughing over time. However, both respiratory activities could be important in airborne influenza transmission. Our results are also consistent with the theory that much of the aerosol containing viable influenza originates deep in the lungs.

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Toward Understanding the Risk of Secondary Airborne Infection: Emission of Respirable Pathogens

Cited by 735 publications

References 28 publications

Aerosolization of Ebola Virus Surrogates in Wastewater Systems

Aerosolization of Ebola Virus Surrogates in Wastewater Systems

Dispersion of Expiratory Droplets in a General Hospital Ward with Ceiling Mixing Type Mechanical Ventilation System

Viable influenza A virus in airborne particles expelled during coughs versus exhalations

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