The impact of outdoor air pollution on COVID-19: a review of evidence from in vitro, animal, and human studies

Air pollution and viral respiratory infections

A century after the Spanish Influenza Pandemic, a study reported that cities that used more coal had tens of thousands of excess flu deaths compared to cities that used less coal, taking into account confounders such as socio-economic and baseline health status [9]. Long-term exposure to air pollution has been associated with increased influenza mortality in the USA [10]. In 2003, a Chinese study on SARS-CoV-1 showed that people living in the most polluted areas had a two-fold increased risk of dying from SARS compared to people living in less polluted areas [11]. In 2015, analysis conducted in 195 countries concluded that air pollution is a significant contributor to the burden of lower respiratory tract infections [12]. As demonstrated for influenza, exposure to air pollution increases the severity of viral respiratory infections [13]. In addition, several studies have demonstrated that increases in air pollutant concentrations were associated with an increased occurrence of respiratory viral diseases among children and adults, in particular when the viral infection was concomitant to a short-term increase in exposure to air pollution. Increases in PM_2.5 concentrations have been associated with increased rates of viral infection, namely influenza, respiratory syncytial virus (RSV) and measles. In these studies, concentrations of PM_2.5 were correlated with the number of new cases of respiratory viral infections with a lag time of a few days [14, 15].

Air pollution and COVID-19

Various studies have also reported a link between air pollution exposure and COVID-19 morbidity and mortality in humans (table 1). However, from an epidemiological point of view, several concerns arose from non-randomised studies that have investigated this relationship. First, the values for the number of confirmed COVID-19 cases, including the number of deaths, have been determined without standardised methodologies and tools, and without reliable testing in many cases during the first months of the COVID-19 pandemic, which may have led to an underestimation in the total number of COVID-19 outcomes. Secondly, the studies suffer from air pollution exposure misclassification. Available assessments come from either satellites or local monitoring stations without any detail on individual exposures. Aside from the study by Travaglio et al. [32] with individual level data from the UK Biobank, all epidemiological studies are ecological with aggregated assessments at the population levels (countries, counties and cities); thus, more longitudinal studies with individual level data are needed [36]. Ambient outdoor pollution concentrations can be a general indicator of air quality, but they are not a reliable substitute for the exposure experienced by a given individual. In this context, using exceedance levels established by public authorities is also limiting, although it can be considered as a proxy of chronic exposure to elevated levels of air pollution. Another weakness encountered arises from the fact that both air pollution and infections are autocorrelated both spatially and temporally, which has not been taken into account so far by the existing investigations. Studies lacking a control for spatio-temporal autocorrelations have been shown to bias the estimation of the results. In this context it has to be underlined that COVID-19 cases mainly arise from clusters, i.e. at work, that are not taken into account in epidemiological studies [36]. Furthermore, most analyses have not taken into account important confounders, i.e. factors related to both air pollution and COVID-19, such as population density [36].Viral spread may vary considerably across different areas depending on population density, the time of the virus introduction, and the time of infection control measures, such as physical distancing, mask requirements, test policies or stay-at-home directives. All these factors influence the dynamics of the disease that can be estimated through the daily number of new cases or through the calculation of the basic reproductive number (R0) and effective reproductive number, both depending on transmissibility, contact rates and duration of contagiousness, as well as on virus mutation time. As air pollution may also influence both transmissibility and duration of infectiousness, the analysis of the impact of air pollution on the dynamic of COVID-19 has to take into account confounders such as population density, the time of the virus introduction and the time of introduction of infection control measures [37].

Among the studies addressing short-term effects of air pollution, Setti et al. [16] were the first to observe an association between the number of Italian provinces with daily averaged PM₁₀ concentrations exceeding the European limit values of 50 µg·m⁻³ and the subsequent number of COVID-19. Significant associations were found between mean concentrations of PM_2.5 during the month of February 2020 and the total number of Italian COVID-19 cases on 31 March 2020 [20]. However, a similar study focusing on the Lombardy and Piedmont regions in Northern Italy from 10 February to 27 March 2020 reported a null association between the number of COVID-19 cases and PM₁₀ concentrations measured several days before the COVID emergency explosion [17]. This study is less robust than the others as it is based only on a visual approach without any statistical tests. A study exploring COVID-19 cases in Italy, France, Germany and Spain reported a positive association between PM_2.5 and PM₁₀ concentrations between February and April 2020 and the number of SARS-CoV-2 infected cases, while a negative association was found for O₃ [33].

In China, city-specific effects of PM₁₀ and PM_2.5 on daily confirmed COVID-19 cases were examined in more than 70 cities. Short-term lagged (7 and 14 days) increases in PM_2.5 were associated with daily COVID-19 confirmed cases, and the magnitude of effect was greater for PM_2.5 compared to PM₁₀ [26]. Another study in China looked at short-term levels of six different pollutants (PM_2.5, PM₁₀, SO₂, CO, NO₂ and O₃) in 120 cities to determine their association with daily COVID-19 confirmed cases. The study reported an approximate 2% increase in daily COVID-19 cases for every 2-week lagged 10 μg·m⁻³ increase in PM_2.5 and PM₁₀ [27]. A pre-print study also reported a positive association between NO₂ levels measured with a 12-day time-lag and the spread of COVID-19 (estimated with the basic reproduction number R₀) in 63 Chinese cities, after adjustment of temperature and humidity [25].

Regarding the role of long-term exposure to air pollution, an Italian study reported that mean levels of NO₂, O₃, PM_2.5 and PM₁₀ during the past 4 years, as well as the number of days exceeding the limit values established by the European Commission during the past 3 years, were both correlated with the number of COVID-19 cases in Italy [29]. A UK study using individual data from the UK Biobank of 1450 participants, including 669 COVID-19 confirmed cases, that adjusted the models for confounding variables, reported significant positive associations of PM_2.5 and PM₁₀ with SARS-CoV-2 infectivity [32].

In addition, to explore the link between air pollution and the spread of COVID-19, several studies have analysed the effect of air pollution on the prognosis of COVID-19. Although these studies answer a different question and may also have their own weaknesses, exploring the prognosis of COVID-19 is less influenced by the dynamics of infection and thus leads to less internal validity threats such as unmeasured confounding. In terms of COVID-19 mortality, NO₂ was found to be related to COVID-19 in a study covering Italy, Spain, Germany and France that revealed 83% of COVID-19 fatalities occurred in the regions with the highest NO₂ levels [33]. In an Italian study, COVID-19 mortality on 31 March 2020 was twice as high in the regions with the highest levels of PM_2.5 compared to that in the regions with the lowest levels of PM_2.5 [20].

Interpretations of these short- and long-term effects should be made in the context of their respective epidemiologic designs. Since all of the previously mentioned studies were ecological and cross-sectional, individual-level inferential statements cannot be derived. The currently available ecological studies have an inherent internal validity threat, unmeasured confounding bias. Potential confounders such as population density, socioeconomic composition, access to healthcare and social distancing measures could also explain the findings. However, a US study examined the link between long-term ambient fine particulate concentrations and COVID-19 mortality taking these into account. This study, adjusted for multiple county-level confounders, covered more than 3000 US counties and examined whether the COVID-19-related mortality per capita varied by estimated county level PM_2.5 concentrations across the 2000–2016 period. After adjusting for population density, average body mass index, levels of poverty, smoking rates, average temperature, humidity, and the number of tests performed in each state, the study concluded that a 1 µg·m³ increase in long-term PM_2.5 concentration was associated with an 8% increase in COVID-19 mortality, which is a factor of 10 higher than all-cause mortality rates in the same counties reported in a previous analysis [30]. By taking into account the time of virus introduction in each county, this study also took into account the dynamic of the disease. Although this study adjusted for potential confounders, it is based on the assumption that previous PM_2.5 concentrations were still representative of those during 2016–2020. Another limitation comes from the fact that many of the county-level adjustment factors resulted from the Behavioral Risk Factor Survey that excluded institutionalised residents, whereas they represent a large part of COVID-19 deaths [36].

Recently, another large study conducted at the county level in the USA showed a significant relationship between long-term exposure to NO₂ and COVID-19 mortality [31]. This study used both single and multi-pollutant models and controlled for spatial trends and a comprehensive set of potential confounders including state-level test positive rates, county-level healthcare capacity, phase-of-epidemic, population mobility, socio-demographics, socioeconomic status, behaviour risk factors, and meteorological factors. Furthermore, the previously mentioned UK study, adjusted for population density, found that the levels of SO₂ and NO₂ recorded between 2018 and 2019, were positively linked to COVID-19 cases and COVID-19 mortality, while O₃ was negatively correlated [32]. Although population density is important because it can promote both viral spread and air pollution, it fails to explain why some highly populated regions have larger numbers of COVID-19 cases and fatalities, pointing to socioeconomic and racial inequalities, including disparities related to environmental exposure. Recent data from the USA indicate that the number of COVID-19 cases and fatalities experienced by Black citizens were higher (up to 75%) than in the rest of the population, although they constitute only a small proportion (32% at maximum) of the overall population [38]. Outside conventional epidemiology, comprehensive econometric methods were applied to study the effect of PM_2.5 and COVID-19 cases, hospitalisations and deaths in all 355 municipalities in the Netherlands [34]. The authors attempted a number of sensitivity analyses to account for unmeasured confounding (or omitted variable bias as commonly known in econometrics), measurement error in the exposure and the outcome and spatial spill-over. They found that a 1 µg·m⁻³ increase in long-term PM_2.5 is associated with nine additional cases, three additional hospital admissions, and two additional deaths. Interestingly, this study found that the relationships between air pollution and COVID- 19 are also observed in rural zones, which suggests that air pollution plays a direct role in impacting COVID-19, independent of an urban setting with all its characteristics, such as density or crowding. In those rural zones, PM_2.5 mainly arises from agricultural sources and especially from intensive livestock farming that leads to NH₃ release. By interacting with other gaseous pollutants such as NO_x, atmospheric NH₃ leads to PM_2.5 formation. In Europe, agriculture is one of the main sources of PM_2.5 [39].

Additional limitations of these observational studies include the fact that most environmental health studies estimate conditional associations between non-randomised environmental exposures and health outcomes by directly regressing observed data without conceptual and design stages [40], an approach that is well documented to not guarantee valid causal inferences in general, especially in air pollution studies in which environmental exposures can be correlated with each other and effects are small [41, 42]. Disentangling independent air pollutant effects has been a challenge for observational studies, but can be achieved if the latter is embedded into a hypothetical multi-pollutant randomised experiment [42]. Moreover, to assess the robustness of epidemiological conclusions, air pollution studies should systematically consider sensitivity analyses that either: 1) vary the magnitude of the relationships between the unmeasured background covariates and both the exposure assignment mechanism and the outcome; or 2) study deviations from the assumed exposure assignment mechanism. Further investigations taking into account these limitations are needed to better understand the relationship of air pollution exposure to COVID-19.

How does air pollution affect COVID-19 comorbidities?

Air pollution and COVID-19 impact the same organs (figure 1). The course of COVID-19 indicates the very important role of the existence of comorbidities, which significantly increase a patient's risk profile. These include many chronic diseases such as cardiopulmonary and metabolic diseases, which air pollution adversely contributes to through both long- and short-term/acute air pollution exposure. This may explain why exposure to air pollution could indirectly predispose people to severe and more lethal forms of COVID-19, as suggested by epidemiological studies. In addition, air pollution may facilitate viral entry into the body via several processes. Herein, we review the main physiological systems affected by both air pollutants and SARS-CoV-2 and discuss the underlying mechanisms.

• Download figure
• Open in new tab
• Download powerpoint

FIGURE 1

Target organs and the main diseases that coronavirus disease 2019 (blue) and air pollution (green) share. ARDS: acute respiratory distress syndrome.

Human studies

A study involving 222 children reported that those living close to an electronic waste area with high PM_2.5 concentrations had significantly decreased levels of salivary agglutinin (one of the primary antimicrobial proteins and peptides) compared to children living in a less polluted area [65]. In a randomised double-blind study in which volunteers were exposed to either ambient air or air with high levels of NO_2, in an environmental chamber, analysis of bronchoalveolar lavage has demonstrated that macrophages were less efficient in inactivating the influenza virus when individuals were previously exposed to NO₂ compared to ambient air [66]. In another randomised double-blind study, nonsmoking volunteers were exposed to wood smoke particles or filtered air before nasal inoculation with a vaccine dose of live attenuated influenza virus. When exposed to smoke particles, nasal lavage revealed reduced levels of interferon-γ-induced protein-10, which may lead to a decrease in immune response to viral infection, as interferon-γ-induced protein-10 is involved in the recruitment of cytotoxic lymphocytes [67]. In another double-blind randomised study including both healthy volunteers and volunteers with allergic rhinitis, nasal inoculation of live attenuated influenza virus was performed after 2 h of exposition to diesel exhaust or clean air and concluded that diesel exposure led to eosinophil activation and increased viral replication in the allergic group, highlighting the fact that diesel exhaust promotes infllamation and reduces virus clearance in allergic patients [68].

In vitro studies

As suggested by human studies, in vitro studies have also reported that air pollution may reduce antimicrobial activity through the downregulation of antimicrobial proteins and peptides (e.g. salivary agglutinin and surfactant protein D) in respiratory mucosal fluid [69]. In the epithelial lining fluid of the human respiratory tract, air pollutants, in particular O₃ and PM, induce oxidative stress and the formation of reactive oxygen species that lead to antioxidant and surfactant depletion [70]. A similar experimental study demonstrated that when RSV is associated with ultrafine particles from combustion sources (e.g. those found in diesel exhaust) and then incubated with an epithelial cell culture, the inflammatory response was elevated compared to that from RSV alone [13, 71]. Another in vitro study examining human lung epithelial cells infected by the H1N1 virus also showed that in vitro exposure to secondary organic aerosols, which are part of combustion-derived particles (e.g. traffic or heating), led to cell apoptosis and increased viral replication [72].

Studies using environmental chambers have investigated the interactions between fine particles and different types of bacteriophage viruses, which were mixed with each other and brought into contact with host bacteria. When the air and virus mixture was previously filtered through a high-efficiency particulate absorbing filter, which removes a large fraction of fine particles, the activity of the viruses on the host bacteria was significantly modified: for some viruses, the presence of fine particles had a potentiating effect on viral infection, whereas for other viruses, fine particles significantly reduced viral replication [73]. This study illustrates the fact that the chemical and electrical characteristics of both particles and viruses play an important role in virus–particulate matter interactions. Regarding NO₂ and O₃ and concomitant exposure to rhinovirus, a major increase in the production of IL-8 in human nasal and bronchial epithelial cells was seen, as well as a decrease in macrophage activity [13]. In human nasal epithelial cells exposed to influenza A, pre-exposure to O₃ increases viral replication due to an increase in cellular protease activity resulting from oxidative stress [74]. Proteases play an essential role in driving the cleavage of the viral membrane protein hemagglutinin and of the spike protein, necessary for viral entry into the host cells [75, 76]. This proteolysis plays an important role in the spread of several respiratory viruses, including both SARS-CoV-1 and SARS-CoV-2 [48, 49].

Animal studies

When mice are exposed to RSV after being exposed to ultrafine particles from combustion sources, studies found a significant decrease in immune response, specifically, a decrease in tumour necrosis factor-α, lymphocytes and interferons in bronchoalveolar lavage fluid, which was followed over the next 7 days, by an exacerbation of inflammation and infection [13]. In another study, authors observed a significant reduction in the phagocytosis capacity of macrophages when they were previously exposed to ultrafine particles from combustion sources [13]. Similar results were observed when mice were previously exposed to high concentrations of NO₂ for 2 days and then exposed to murine cytomegalovirus [13]. The amount of virus needed in order to become infected was 100 times lower than that for mice exposed to ambient air. O₃ exposure in mice led to different results depending on time and duration of exposure. In particular, when exposure to O₃ occurred at the same time as viral infection, O₃ may have had an antiviral activity [13, 77, 78]. This paradoxical protective effect of O₃ may be explained by its oxidising behaviour, degrading viral macromolecules such as lipids, proteins and nucleic acids. As an example, O₃ has an antimicrobial effect in high concentrations and is used to disinfect waterborne pathogens, e.g. ozonated water used in dental medicine and O₃ treatment for sewage water [79, 80]. However, for O₃ to decrease viral suspension in the air, the O₃ must be present in high concentrations, which are not seen by current ambient levels. Thus, we do not expect the overall effect of O₃ to decrease the viral load within humans or animals, but rather to impair immune response.

In rats, exposure to PM, especially ultrafine particles, induces the expression of the renin-angiotensin-aldosterone system (RAAS) and increases the expression of AT1R, a receptor of angiotensin 2, which is involved in lung and heart injuries [81, 82]. RAAS is involved in several diseases: while angiotensin 2 (through AT1 receptors) leads to vasoconstriction and inflammation, ACE2 receptor converts angiotensin 2 into protective angiotensin 1–7 with anti-inflammatory and vasodilating properties [83]. Severe forms of COVID-19, such as ARDS, have been associated with ACE2/AT1R imbalances [83, 84]. Although the exact role of RAAS on the severity of COVID-19 is still unclear, we know that SARS-CoV-2 uses the ACE2 receptor to enter the cells, which may lead to an increase in bioavailability and toxicity of angiotensin 2 through AT1R. In addition to the possible increase of AT1R expression due to PM, previous studies on rats have also reported that NO₂ exposure induces the expression of ACE (angiotensin-converting enzyme that converts angiotensin 1 into angiotensin 2) and increases the liaison of angiotensin 2 to AT1R [85]; however, further studies are needed to explore the exact role of RAAS on the severity of COVID-19 and the possible role of air pollution.

Droplets and aerosols

The physical size of SARS-CoV-2 is approximately 70–130 nm and its transmission mainly arises through the emission of macro droplets of 50–100 µm, e.g. through coughing and sneezing. Macro droplets consist of the virus in the centre, surrounded by water molecules and also mucus or cellular debris. These macro droplets are heavy and fall rapidly to the ground, which is why a safety distance of 2 m has been established by the health authorities in order to limit viral transmission. Macro droplets can also be deposited on solid surfaces where viral RNA is still quantifiable several hours later [86]. As has been demonstrated for influenza and measles, and suspected for SARS-CoV-1, recent studies are also considering SARS-CoV-2 transmission by aerosols formed by micro- and nano-droplets, also called droplet nuclei and defined as a suspended system of solid or liquid particles <5 µm in the air [87–90]. Depending on the particle mass, aerosols are able to remain suspended in the air for several hours and studies have found that SARS-CoV-2 RNA is still detected in the air 3 h after being emitted [86]. The role of airborne transmission of SARS-CoV-2 in COVID-19 is getting more recognition now. Some doubt remains about the pathogenicity of SARS-CoV-2 in suspensions because aerosols are smaller than macro droplets, and may contain fewer viable viruses but, in a recent study, increases in viral SARS-CoV-2 RNA during cell culture of the virus from recovered aerosol emitted by patients through breathing or speaking demonstrated the presence of infectious, replicating virions in <1 µm aerosol samples at a significant level (p<0.05) [91]. Western blot and transmission electron microscopy) analysis of these samples also showed evidence of viral proteins and intact virions. The infectious nature of aerosols collected in this study suggests that airborne transmission of COVID-19 is possible, and that aerosol prevention measures are necessary to effectively stem the spread of SARS-CoV-2. Other studies are needed to support it.

Airborne SARS-CoV-2 and PM and related mechanisms

Regardless of infectivity, SARS-CoV-2 emitted in aerosol form, for example from breathing, should behave like ultrafine particles arising from other sources, such as road traffic and heating. Viruses may mix with other suspended ultrafine particles, and thus may agglomerate to form particles of various sizes through aggregation condensation of ultrafine particles and nucleation of gaseous precursors [92, 93]. It is also well known that particles may serve as vectors for various substances such as pollen and microorganisms, including bacteria, fungi and viruses [94, 95]. It has previously been demonstrated that viruses are carried by fine particles. For example, a study has shown that the avian influenza virus was transmitted by dust particles between separated chicken groups [96]. SARS-CoV-2 RNA has recently been detected on PM in the Bergamo Province, Northern Italy, collected over a continuous 3 week period by two independent air samplers [97]. However, the presence of viral RNA does not necessarily mean viral infectivity, which depends on viral structural integrity, such as surface glycoproteins and sufficient viral concentration [98].