key: cord-1041132-gliqwcki
authors: Leonardi, Anthony Joseph; Mishra, Asit Kumar
title: A Sanitation Argument for Clean Indoor Air: Meeting a Requisite for Safe Public Spaces
date: 2022-02-09
journal: Front Public Health
DOI: 10.3389/fpubh.2022.805780
sha: 5d5128540d125392aa02b1df65db7bc767cec6e0
doc_id: 1041132
cord_uid: gliqwcki

nan

In public health terms, "sanitation" refers to a public health implementation of hygienic standards and practices meant to address transmissible diseases like Malaria and Cholera in industrial and public settings like factories, schools, and resorts (1) . We propose the management of air given the current pandemic with an airborne pathogen (2) . Sanitation has had a stable history as a primary focus in the field of public health engineering, responsible for potable water, waste management, and control of mosquito breeding-grounds (1, 3) . Since addressed by a sanitation approach, the effective handling of vector media has made outbreaks and epidemics like the cholera outbreak of 1,911 in New York City unrepeated in the USA (1) . However, rarely have pathogens been met with mitigations and public health sanitation measures considering airborne transmission, save for sanitariums and open-air schools for Tuberculosis and the "Fresh Air" movement during the 1918 Influenza Pandemic, which were both caused by pathogens spreading by aerosols (4) (5) (6) . In such a rare, but notable example in 1918, an open-air hospital in Boston was retrospectively found to benefit the staff by reducing Influenza infection (7) . Given our current pandemic, we believe such ventilation measures should be readopted and the air should be sanitized.

As new evidence shows airborne pathogens such as SARS-Cov-2 spread via aerosols, we should refine what is a nebulous attribution of responsibility in mitigating the spread of airborne pathogens indoors and assign it under the purview of public health sanitation and engineering in order to effectively manage indoor air (2) . A building's ventilation system is critical to maintaining a healthy work environment (8) . Humans breathe in many times more air than our food or water intake-around 6 liters/minute (7) . Therefore, we argue for the sanitation of air under the domain of public health environmental engineering, and echo the calls for a necessary paradigm shift via measures such as ventilation and filtration (8) .

Many viruses including SARS-CoV-2 have ample evidence of primarily airborne transmission (8) .

Generation of respiratory aerosols is not limited to aerosols generating medical procedures and is observed for many day-to-day activities like breathing, talking, shouting, coughing and sneezing, and singing (9) (10) (11) (12) . Emissions increase with airflow velocity and speech volume (13, 14) . The expelled aerosols have a multimodal size distribution: 0.1, 0.2-0.8, 1.5-1.8, and 3.5-5.0 microns, while coughing and talking also have modes at 123 microns and 145 microns, respectively, though the large particles during both talking and coughing are still under 5 microns in size (2) . Smaller sized aerosols are generated deeper in the respiratory tract (2) .

Most exhaled aerosols are under 5 microns (15, 16) . Normal breathing produces hundreds to thousands of such particles per liter of exhaled air (16) (17) (18) . Due to such small size, these particles can be respired (19) . For every particle over 100 microns produced during speech, 100 to 1,000 particles under 100 microns in size (10) . Blustery expulsions, like a sneeze or a cough, can produce numerous aerosols in a short period, but talking and breathing are continuous action and a cause for greater concern (20), especially when an infectious person does not display symptoms. A minute of loud conversation can produce thousands of droplets every second, of which, about a thousand particles could contain virus and these can remain afloat for 8 mins or more (21) .

While a historical 5 micron boundary has cropped up to distinguish between aerosols and droplets, a 100 micron boundary is supported by evidence (2, 22, 23) . Stokes law for small particles subject to laminar flow can provide a simple approximation of their terminal velocity, thus providing an idea of how long they may stay afloat:

where "g" is the acceleration due to gravity, "η" is the dynamic viscosity of air, "ρ p " is the density of the particle, "d p " is the diameter of the particle, and C is the Cunnigham slip correction factor (to account for slippage, leading to reduced air resistance, relevant when particle size becomes of the order of the mean free path of air molecules) (24). In still air, a 100 micron particle released at a 1.5 m height can stay in the air for ∼5 s, while traversing ∼2 m. Similarly, a 10 micron particle can stay suspended for ∼17 min, a 5 micron particle for ∼33 min and a 1 micron particle for over 12 h (2, 17, 25) . A one micron respiratory aerosols is about a thousand times larger than a single virion. It can contain enough of the virus and stay afloat for hours. Studies have found smaller aerosols to be enriched with infectious pathogens (15, 19, 26, 27) . Since room air is rarely still, these particles can get further, especially while aided by violent exhalation events like sneezing or coughing (28) . Modeling shows that large droplets over 100 micron are only likely to be the dominant mode of infection within 0.2 m (talking) or 0.5 m (coughing) of an infectious person (29) . This makes sense when you consider that the concentration of exhaled aerosols is highest closest to the source, in this case, the infectious person. Risks of infection from aerosols will be quite high close to the source (2), highest when the infected and the exposed individuals are positioned so close that breathing flows can approach each other's faces, with complex flow interactions, difficult to predict (20) .

Greenhalgh et al. (30) , succinctly summarized the evidence that strongly indicates COVID-19 is airborne. The following are some key points from their work.

• Long-range transmission of the disease and overdispersion of the basic reproduction number (R0). These are consistent with airborne transmission but cannot be adequately explained depending on droplets and fomites (31) .

• Transmission between people who were never in each other's physical presence, as evidenced from outbreaks in quarantine hotels (32) .

• Asymptomatic or presymptomatic transmission, where the infectious person is not sneezing or coughing, accounts for 33 to 59% of transmissions worldwide, indicating mostly airborne transmission and not droplets (33) .

• The disease transmits much more easily indoors than outdoors (34) , and transmission can be mitigated by good indoor ventilation (35) (36) (37) (38) .

• Despite strict contract and droplet precautions and use of relevant personal protective equipment (PPE) (against droplets only), nosocomial infections have unfortunately occurred (39) .

• Viable SARS-CoV-2 has been detected in the air in laboratory studies (40, 41) as well as in spaces with infected occupants, without any so-called aerosol generating medical procedures being undertaken (42, 43) . Exhalation of infectious aerosols have now been documented in both animal models (44) and in humans (26).

• SARS-CoV-2 has been traced to locations in buildings that could only be reached via aerosols, like air filters in air handling units of hospitals and the air conditioning vents/ducting (45) • Animal models where transmission of SARS-CoV-2 occurred between animals whose cages were connected by a ducting network that can only be negotiated by aerosols and not droplets (46) . It has also been shown in animal models that placing surgical masks around cages of infectious individuals reduced transmission (47) . Animal models also show the aerosol exposure more likely leading to more severe disease and efficient transmission (48, 49) .

Several in-depth post-hoc analysis of outbreaks have shown that transmission was most likely through aerosols, as opposed to droplets or fomites, like, a department store in China (50), a party traveling in buses (51), the Skagit Valley Chorale (52) , and the outbreak on the Diamond Princess cruise ship (53) .

Relative humidity of indoor air impacts the equilibrium size of exhaled aerosols particles (and thus how long they are suspended in air and the distance they can traverse), the viability of viruses in the particles, and our immune defenses (mucociliary clearance) (2) . A relative humidity of 40-60% indoors could reduce possibilities of transmission (54, 55) .

Both the volume of ventilation and air flow patterns in an occupied space have an impact on airborne transmission of viruses (2, 20) . Good ventilation can improve indoor air quality and benefit health, comfort, and office work performance, while also reducing occurrences of allergic and asthmatic incidents (56, 57) . It is important to assure that, like food or waterborne diseases, we can reduce risks of airborne diseases through appropriate engineering measures (8) .

Standards recommend minimum ventilation rates for buildings based on either needs for maintaining acceptable indoor air quality (58) or needs for infection prevention (59) . The ventilation in a specific building depends on the intended use of the space, like a school, vs. office buildings, vs. residences, vs. hospital wards, due to differences in occupancy density, layouts, hours of occupancy, and infection prevention needs. Type of ventilation system also affects the chances of infection transmission. In an ideal world, when we can be sure of who is infectious, personalized extraction ventilation for infectious persons can dramatically reduce infection transmission risks (20) . However, when a virus can be transmitted by persons exhibiting no symptoms, we would have to provide personalized ventilation and personalized extraction to every occupant, which can quickly become prohibitively costly. An increase in ventilation volume need not always correspond with a reduction in risks (60) , implying ventilation volume alone should not be used as an indicator for ventilation performance in actual buildings (20) . Improved ventilation has also been related to reduction in SBS (sick building syndrome) symptoms and relative risks of respiratory illness (61), particularly for the elderly (62), improved comfort and lowering sick absence (schools and offices) (63), and improved productivity (even offsetting any additional energy costs) (64, 65) . Models of infectious disease transmission show that improved ventilation can mitigate outbreaks of influenza (66) , seasonal variations in ventilation (less ventilation during winter) can increase risks of airborne disease transmission in classrooms (67), improved air quality reduces transmission risks of several airborne pathogens in clinics (68) , and can also reduce disease transmission risks at a city level (69) . A disease that is airborne and has epidemic proportions around the world, is tuberculosis and there are several studies linking improvement in ventilation with reduction in risks of tuberculosis infection (70, 71) .

Measuring room carbon dioxide levels, while not a proxy for infection risks, is a cost-effective tool for identifying poorly ventilated spaces and spaces that have frequent overcrowding, thus indicating places where transmission is likely to occur (58, 72, 73) . Poor indoor air quality, measured with carbon dioxide (CO 2 ) as a proxy, has been shown to increase lower respiratory tract infections in children (74) , more frequent incidences of common cold (75) , and even a pneumococcal outbreak in a correctional facility (76) .

While introducing outdoor air and increasing ventilation is a preferred option, it also carries energy and hence economic implications. In such a situation, assuming the existing heating ventilation and air conditioning (HVAC) system can handle better grade filters, choosing high-efficiency filters can mitigate risks of infection while requiring less operational costs than increasing the outdoor air ventilation levels (77) . The added cost due to improved filtration can far outweigh the cost of infections.

But changing mechanical ventilation in a building can be expensive and time taking. For such situations and also for buildings without mechanical ventilation, use of portable air cleaners (PACs) can be a quick and affordable option. PACs were already in the market since late 70s, early 80s and their use in homes has been increasing, due to a concern with outdoor air quality (78) (79) (80) . They are part of design recommendations for setting up temporary, negative pressure isolation units (81, 82) and also a part of the WHO Roadmap for ventilation in face of the COVID-19 pandemic (57) . Multiple studies during the past months have focused on PACs, due to the ongoing pandemic, and have used approaches CFD modeling (83) , experiments in actual spaces (84) (85) (86) (87) (88) , and study involving actual COVID-19 patients (89) to validate that PACs are an effective mitigation measure. The studies using PACs, to date, have mostly focused on particulate matter pollution (80) . Recent studies, cited above, looking at infection mitigation potential have certain limitations in terms of use of different kinds of equipment in different sized spaces, introduction of PACs as part of several other mitigation measures, and few studies that can offer clinical evidence (85, 86, 88, 89) . This is an aspect that is gradually starting to gain attention with better designed studies and controlled trials in clinical settings. In the coming years, the noted shortcomings regarding effectiveness of PACs are likely to be comprehensively addressed. The schema in Figure 1 summarizes the mitigation strategies we discuss, centred around improving indoor air quality, through dilution, ventilation, and filtration.

All authors listed have made a substantial, direct, and intellectual contribution to the work and approved it for publication.

Sanitation and public health: a heritage to remember and continue

Mosquito larval source management for controlling malaria

Open-air schools

Tuberculosis then and now: a personal perspective on the last 50 years

The Great Influenza: The Epic Story of the Deadliest Plague in History

The open-air treatment of pandemic influenza

An update on sick building syndrome

Respiratory minute volume and tidal volume in normal boys

Modality of human expired aerosol size distributions

The size and the duration of air-carriage of respiratory droplets and droplet-nuclei

Breathing is enough: for the spread of influenza virus and SARS-CoV-2 by breathing only

The experimental aerosol transmission of influenza virus

Aerosol emission and superemission during human speech increase with voice loudness

Airborne transmission of respiratory viruses

Cough aerosol in healthy participants: fundamental knowledge to optimize droplet-spread infectious respiratory disease management

Origin of exhaled breath particles from healthy and human rhinovirus-infected subjects

Aerosol transmission of SARS-CoV-2? evidence, prevention and control

Risk assessment of airborne transmission of COVID-19 by asymptomatic individuals under different practical settings

Particle sizes of infectious aerosols: implications for infection control

Airborne spread of expiratory droplet nuclei between the occupants of indoor environments: A review

The airborne lifetime of small speech droplets and their potential importance in SARS-CoV-2 transmission

Airborne transmission of SARS-CoV-2

On air-borne infection. Study II. Droplets and droplet nuclei

Terminal fall velocity: the legacy of Stokes from the perspective of fluvial hydraulics

SARS-CoV-2 in Exhaled Aerosols and Efficacy of Masks During Early Mild Infection

Viral load of severe acute respiratory syndrome coronavirus 2 (SARS-COV-2) in respiratory aerosols emitted by patients with coronavirus disease (COVID-19) while breathing, talking, and singing

Dismantling myths on the airborne transmission of severe acute respiratory syndrome coronavirus (SARS-CoV-2)

Short-range airborne route dominates exposure of respiratory infection during close contact

Ten scientific reasons in support of airborne transmission of SARS-CoV-2. The Lancet

Superspreading drives the COVID pandemic-and could help to tame it

Transmission of severe acute respiratory syndrome coronavirus 2 during border quarantine and air travel

SARS-CoV-2 transmission from people without COVID-19 symptoms

Outdoor transmission of SARS-CoV-2 and other respiratory viruses: a systematic review

It is time to address airborne transmission of coronavirus disease. (COVID-19)

Available online at

CDC. Ventilation in Buildings

Review and comparison of HVAC operation guidelines in different countries during the COVID-19 pandemic

Transmission of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) from asymptomatic and presymptomatic individuals in healthcare settings despite medical masks and eye protection

Aerosol and surface stability of SARS-CoV-2 as compared with SARS-CoV-1

Airborne SARS-CoV-2 Is Rapidly inactivated by simulated sunlight

Viable SARS-CoV-2 in the air of a hospital room with COVID-19 patients

Isolation of SARS-CoV-2 from the air in a car driven by a COVID patient with mild illness

Infectious SARS-CoV-2 Is Emitted in Aerosols

Long-distance airborne dispersal of SARS-CoV-2 in COVID-19 wards

SARS-CoV and SARS-CoV-2 are transmitted through the air between ferrets over more than one meter distance

Surgical mask partition reduces the risk of noncontact transmission in a golden syrian hamster model for coronavirus disease (2019). (COVID-19)

Aerosol exposure of cynomolgus macaques to SARS-CoV-2 results in more severe pathology than existing models

SARS-CoV-2 disease severity and transmission efficiency is increased for airborne compared to fomite exposure in Syrian hamsters

Aerosol transmission, an indispensable route of COVID-19 spread: case study of a department-store cluster

Community outbreak investigation of SARS-CoV-2 transmission among bus riders in Eastern China

Transmission of SARS-CoV-2 by inhalation of respiratory aerosol in the Skagit Valley Chorale superspreading event

Mechanistic transmission modeling of COVID-19 on the Diamond Princess cruise ship demonstrates the importance of aerosol transmission

Indoor transmission of SARS-CoV-2. Indoor Air

The influence of temperature, humidity, and simulated sunlight on the infectivity of SARS-CoV-2 in aerosols

What we know and should know about ventilation

Roadmap to Improve and Ensure Good Indoor Ventilation in the Context of COVID-19. Roadmap to Improve and Ensure Good Indoor Ventilation in the Context of COVID-19

Challenges in developing ventilation and indoor air quality standards: The story of ASHRAE Standard 62

Guidelines for environmental infection control in health-care facilities. recommendations of CDC and the Healthcare Infection Control Practices Advisory Committee (HICPAC)

Adequacy of air change rate as the sole indicator of an air distribution system's effectiveness to mitigate airborne infectious disease transmission caused by a cough release in the room with overhead mixing ventilation: a case study

Association of ventilation rates and CO 2 concentrations with health andother responses in commercial and institutional buildings

Indoor air quality, ventilation and respiratory health in elderly residents living in nursing homes in Europe

Ten questions concerning well-being in the built environment

Ten questions concerning thermal and indoor air quality effects on the performance of office work and schoolwork

Optimizing ventilation: theoretical study on increasing rates in offices to maximize occupant productivity with constrained additional energy use

Assessing the dynamics and control of droplet-and aerosol-transmitted influenza using an indoor positioning system

Seasonal variation in airborne infection risk in schools due to changes in ventilation inferred from monitored carbon dioxide

Modeling of the transmission of coronaviruses, measles virus, influenza virus, mycobacterium tuberculosis, and legionella pneumophila in dental clinics

Building ventilation as an effective disease intervention strategy in a dense indoor contact network in an ideal city

Effect of ventilation improvement during a tuberculosis outbreak in underventilated university buildings

Natural ventilation as a means of airborne tuberculosis infection control in minibus taxis

Available online at

Indoor carbon dioxide concentrations in ventilation and indoor air quality standards

Indoor air quality and the risk of lower respiratory tract infections in young Canadian Inuit children

In China, students in crowded dormitories with a low ventilation rate have more common colds: evidence for airborne transmission

An epidemic of pneumococcal disease in an overcrowded, inadequately ventilated jail

HVAC filtration for controlling infectious airborne disease transmission in indoor environments: predicting risk reductions and operational costs

What is an effective portable air cleaning device? a review

Effectiveness of a portable air cleaner in removing aerosol particles in homes close to highways

Personal-Level protective actions against particulate matter air pollution exposure: a scientific statement from the american heart association

Airborne Infectious Disease Management: Methods for Temporary Negative Pressure Isolation. Minnoesta, MN: Office of Emergency Preparedness Minnesota Department of Health

An evaluation of portable high-efficiency particulate air filtration for expedient patient isolation in epidemic and emergency response

Airborne transmission of COVID-19 and mitigation using box fan air cleaners in a poorly ventilated classroom

Testing mobile air purifiers in a school classroom: Reducing the airborne transmission risk for SARS-CoV-2

Use of portable air cleaners to reduce aerosol transmission on a hospital coronavirus disease. (COVID-19) ward

Effectiveness of portable air filtration on reducing indoor aerosol counts: preclinical observational trials. medRxiv

Efficacy of portable air cleaners and masking for reducing indoor exposure to simulated exhaled SARS-CoV-2 aerosols-United States 2021

The removal of airborne SARS-CoV-2 and other microbial bioaerosols by air filtration on COVID-19 Surge Units

Quantifying human and environmental viral load relationships amidst mitigation strategies in a controlled chamber with participants having COVID-19

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.Publisher's Note: All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.Copyright © 2022 Leonardi and Mishra. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.