Associations between Air Quality and Covid-19 Infection
Yuye Chen
a
Department of Chemistry, University College London, London WC1E 6BT, U.K.
Keywords: COVID-19, Air Pollution, Particulate Matter, ACE2.
Abstract: Air pollution has been an urgent trouble for many regions. The clear relationship between various types of air
pollution and COVID-19 cases has not been well understood. The particulate matter (PM), as an air pollutant,
was found to act as a potential carrier of the SARS-CoV-2 virus. It might also cause higher angiotensin-
converting enzyme 2 (ACE2) activation when inducing airway inflammation, and eventually increase the risk
of COVID-19 infection. By concluding some of the existing studies, the statistical correlations between air
pollutants and COVID-19 infection can be visualised, such as positive correlations found between PM
2.5
,
PM
10
, NO
2
, etc. and COVID-19 infection, while negative correlations with SO
2
, as well as some controversial
findings on O
3
, etc. Further research is required to address possible mechanisms of how PM might facilitate
the spreading of COVID-19. Monitoring air pollution levels and applying comprehensive models for analys-
ing associations between COVID-19 infection and air pollution appear to be useful for further studies.
1 INTRODUCTION
COVID-19 has caused a worldwide pandemic. Over
200 countries have suffered from the SARS-CoV-2
virus. As of 10th September 2021, over 200 million
infection cases and 4 million deaths have been re-
ported to World Health Organization (Geneva: World
Health Organization, 2020). COVID-19 patients usu-
ally undergo fever, cough; and fatigue, with conges-
tion, sore throat, etc. also could be seen in some cases
(Fu et al. 2020). Coronaviruses (CoVs) are enveloped
viruses with a positive single-stranded RNA genome
inside each virus. COVID-19 is caused by the SARS-
CoV-2, a very pathogenic form of virion (Borisova
and Komisarenko 2021) that enters the host
cell via binding through the angiotensin-converting
enzyme 2 (ACE2) receptor (Naqvi et al. 2020), which
is a membrane enzyme found in the lungs, arteries,
heart, kidney, and intestines’ cells (Lin et al., 2018).
Research has found that countries such as China
(Zhu et al. 2020, Hou et al. 2021, Yao et al. 2021) and
Italy (Bontempi 2020, Fattorini and Regoli 2020) that
reported a high incidence of COVID-19 together with
high levels of air pollution. For example, a study of
China with an average daily COVID-19 confirmed
cases of 12.94 calculated during the observation pe-
riod found that average daily concentrations of PM
2.5
,
a
https://orcid.org/0000-0003-3813-2466
PM
10
, CO, NO
2
, and O
3
(46.43 μg/m
3
, 62.97 μg/m
3
,
0.85 mg/m
3
, 19.28 μg/m
3
and 78.22 μg/m
3
, respec-
tively) were significantly positively related to
COVID-19 confirmed cases (Zhu et al. 2020). More-
over, among these air pollutant particles, the mecha-
nism of how PM (particulate matter) might facilitate
the infection of COVID-19 was recently investigated
(Comunian et al. 2020). Previous studies found that
PM
10
may cause airway inflammation (Choi et al.
2020) and PM
2.5
collected in China largely enhanced
the levels of expression of the inflammatory genes
(Bekki et al. 2016). In the case of inflammation
caused by PM, ACE2 as an anti-inflammatory peptide
generator is overactivated, leading to an increased
likelihood of COVID-19 entering the cells (Hayashi
et al. 2010).
This review introduces the possible mechanism of
COVID-19 infection facilitated by PM, as well as
summarizes and discusses the correlation between the
number of COVID-19 infection cases and air pollu-
tion. The different models chosen for the various
studies are also mentioned, which would give refer-
ences to the model constructions in further studies.
Chen, Y.
Associations between Air Quality and Covid-19 Infection.
DOI: 10.5220/0011255200003438
In Proceedings of the 1st International Conference on Health Big Data and Intelligent Healthcare (ICHIH 2022), pages 245-253
ISBN: 978-989-758-596-8
Copyright
c
2022 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
245
2 GENERAL MECHANISMS
2.1 Interaction between PM Particles
and COVID-19 Virus
PM as the global environmental issue is known to
cause irregular inflammatory and coagulation re-
sponses through the whole body (Choi et al. 2020).
There are many sources of PM classified by their di-
ameters. For example, PM
10
and PM
2.5
stand for par-
ticulate matter with diameters no more than 10 mi-
crometers and 2.5 micrometers respectively
(Comunian et al. 2020). Certain types of PM were
found to be able to interact with the plasma membrane
of nerve cells (Borisova and Komisarenko 2021).
COVID-19 virus has an envelope that can contain li-
pid components of host neuron cells as well as mem-
brane fragments of infected cells (Borisova and
Komisarenko 2021). Evidence has shown that some
fine/ultrafine PM was be able to interact with the
plasma membrane of nerve terminals in brains
(Borisova and Komisarenko 2021). Therefore, these
water-suspended PM particles in turn forms com-
plexes with the COVID-19 virus that contains mem-
brane segments of brain nerve cells. The complexes,
when dried, then serves as carriers of the COVID-19
virus in the transmission (Borisova and Komisarenko
2021). The viruses are immobilized to the surfaces of
these particles, leading to possible changes in the
characteristics of the original virus. For example, the
virus becomes more stable when grouping with these
PM. Moreover, these SARS-CoV-2-PM complex
possibly may enter the cells without binding to the
ACE2 receptor (Borisova and Komisarenko 2021).
2.2 PM Activating ACE2 Causing
COVID-19 Infection
ACE2 is a receptor on the cell membrane that binds
to the spike-like proteins on the surface of the
COVID-19 virus. It can regulate blood pressure by
catalyzing the breaking of vasoconstrictor peptide,
angiotensin 2 and turn them into angiotensin 1-7
(Comunian et al. 2020). ACE1 and ACE2 cooperating
in the renin-angiotensin system could lead to the pro-
tection of organs and blood vessels by anticoagulant,
anti-inflammatory, anti-oxidative stress activity, etc.
(Gemmati et al. 2020). As SARS-CoV-2 depends on
ACE2 to enter the host cell, various pathological con-
ditions that could further activate ACE2 have been
listed as possible hazards for COVID-19 (Wang et al.
2021). One of the possible mechanisms could be in-
flammation. Due to the anti-inflammatory function of
angiotensin 1-7 peptide, ACE2 can make lung impair-
ment from hyperoxia less severe by inhibiting the in-
flammatory response. Therefore, when there is in-
flammation, the activity of ACE2 would increase
(Comunian et al. 2020). Chronic PM
2.5
exposure was
found to increase the risk of systemic inflammation
and oxidative stress in the lung epithelial cells (Pun et
al. 2017). Also, research showed that exposure to PM
particles can cause an inflammatory response, which
might activate ACE2 and thus facilitate the infection
of COVID-19 (Comunian et al. 2020). Therefore, PM
may increase the risk of COVID-19 infection via
ACE2 expression, as shown in Fig.1. In addition, the
increased inflammation may also aggravate lung in-
jury (Tung et al. 2021).
Figure 1: PM facilitating SARS-CoV-2 binding to ACE2 receptors to enter the host cell.
ACE2 receptors
SARS-CoV-2
TMPRSS2
PM induced oxidative
stress and inflammatory
response
Activated ACE2; upregulated
ACE2 expression
Increased risk of COVID-19
infection
Viral
Attachment
Host cell
Virus Entry
ICHIH 2022 - International Conference on Health Big Data and Intelligent Healthcare
246
2.3 Nose-to-brain Entering Pathways
of PM Particulates and
CoronaVirus and Their Influence
on Brain Nerve Terminals
PM, the inhalable corpuscles, can lead to various
health problems because of their small size
(Comunian et al. 2020). For example, the water-sus-
pended smoke PM was found to affect exocytosis in
nerve terminals (Borisova and Komisarenko 2021).
The air pollution PM influenced exocytosis in nerve
terminals, which in turn changed the transfer activity
of CoVs between neurons. Air pollution PM and
CoVs can be inhaled through the same nasal cavity
path, pass through the axon of olfactory nerves, and
eventually reach the brain (Borisova and
Komisarenko 2021). They can then act separately
and/or as a SARS-CoV-2-PM complex. Their neuro-
logical effects can meddle and intensify each other,
being additive or even synergetic. When acting as a
complex, the SARS-CoV-2-PM may disturb synaptic
vesicle recycling in the process of exo-/endocytosis
due to their larger size (Borisova and Komisarenko
2021).
3 AIR QUALITY CHANGES
DURING COVID-19
LOCKDOWN
Results for a study in China showed that the signifi-
cant decreases in NO
x
and other air pollution emis-
sions in the lockdown period due to COVID-19 con-
tributed to considerable increases in O
3
, which in-
duced elevated atmospheric oxidizing ability and
boosted the forming of secondary PM in eastern
China (Huang et al. 2021). Another study of America
found that the CO concentration fell more rapidly
than NO
2
and PM
2.5
concentrations during the
COVID-19 situation, while NO
2
emissions dropped
over places of main power plants and rose over
densely populated residential regions, especially
those functioning as transportation centres at the junc-
tions of national highways (Liu et al. 2021). A study
in Korea found that from January 2020 to April 2020,
monthly mean concentrations of PM
2.5
, PM
10
, NO
2
,
and CO were significantly lower than those in the
three previous years (Ju et al. 2021). Another study of
the Bangkok Metropolitan Region found that NO and
the AQI declined during the COVID-19 lockdown.
By comparison, CO, NO
2
, SO
2
, O
3
, and PM
2.5
in-
creased considerably during the lockdown period
compared to the corresponding period of last year
(Sangkham et al. 2021). Another study in China also
witnessed a sharp reduction in the concentrations of
air pollutants during the COVID-19 outbreak. In con-
trast to the same period in 2019 (from December 2018
to April 2019), the concentration of ambient air pol-
lutants decreased 9.31%, 14.49%, 11.54%, and
13.89% for PM
2.5
, SO
2
, NO
2
, and CO respectively.
However, PM
10
and O
3
concentrations increased
0.57% and 6.90% (Zhang et al. 2021).
4 STATISTICAL CORRELATION
BETWEEN COVID-19 CASES
AND AIR QUALITY
MEASUREMENTS IN
DIFFERENT REGIONS
Many studies have been investigating the long-term
(over one year) and short-term (less than one year)
relationships between the number of COVID-19 in-
fection cases and air quality with several models. For
example, a study of Italy summarized their data using
the number of confirmed cases against the detection
date and the correspondent PM
10
concentration values
(Bontempi 2020), and another study in China focused
on the percentage change of daily COVID-19 infec-
tors with a unit rise (10 μg/m
3
rise in PM
2.5
, PM
10
,
SO
2
, NO
2
, O
3
and 1 mg/m
3
in CO) in pollutant con-
centration among six different pollutants (Zhu et al.
2020). Though different conclusions were also drawn
from these studies. Hence, this review is to compare
these differences and analyse the possible reasons for
proposing a new possible model for further studies.
4.1 Short Term Studies
An Italian study (from 10th February 2020 to 27th
March 2020) focused on the PM
10
concentration in
Lombardy cities, as well as some Piedmont cities,
though no overall relationship was found (Bontempi,
2020). This study compared the pattern of PM
10
con-
centration changes with the increase in COVID-19
confirmed cases about 20 days later. In some Lom-
bardy cities like Bergamo and Brescia, the high PM
10
concentration (over 50 μg/m
3
/day) from 22nd to 26th
of February, was corresponding to the increase in
COVID-19 cases on the 11th and 12th of March.
However, there were other cities, such as Pavia and
Cremona, that also experienced high concentrations
of PM
10
, but reported a limited number of infection
cases throughout the whole period. In some adjoining
piedmont cities that also experienced high levels of
pollution, no close relationship was found between
Associations between Air Quality and Covid-19 Infection
247
PM
10
and COVID-19 cases. The lack of a direct con-
tribution owing to PM
10
acting as carriers for COVID-
19 spreading was suggested in this study. One possi-
ble reason was that COVID-19 cases remained unde-
tected for the investigated period, resulting in delayed
countermeasures (Bontempi 2020).
A short-term study in China witnessed a clear cor-
relation between the daily increase in COVID-19
cases from 23rd January 2020 to 29th February 2020,
and the concentration of six pollutants: PM
2.5
, PM
10
,
SO
2
, NO
2
, CO, and O
3
. Except for SO
2
, the other five
pollutants all showed significant positive correlations
with reported COVID-19 infectors (Zhu et al. 2020).
A brief California study using the dataset from 4th
March 2020 to 24th April 2020 found that ambient air
pollutants were remarkably related to COVID-19
cases and mortality. PM
10
, PM
2.5
, SO
2
, CO, and NO
2
had significant associations with the total number of
cases and deaths for both Spearman and Kendall
models, with higher magnitudes resulted for PM
10
,
PM
2.5
, SO
2
, and NO
2
using the Spearman model
(Bashir et al. 2020). The limitations of this study in-
clude not accounting for socio-economic indicators,
social distancing, and personal hygiene.
In another study for Saudi Arabia, the degrees of
air pollution for the three pollutants (PM
10
, NO
2
, and
O
3
) investigated from 9th March 2020 to 19th No-
vember 2020 were all positively related to the number
of daily COVID-19 infectors. Other meteorological
parameters like temperature and wind speed were also
investigated in the study, revealing a significant asso-
ciation with the daily number of COVID-19 infec-
tions (Ben Maatoug et al. 2021).
4.2 Long Term Studies
A study of Italy that analysed the average concentra-
tions of O
3
, NO
2
, PM
2.5
, and PM
10
for a long period
from 2016 to 2019 suggested a significant correlation
between a long-term, chronic exposure to air pollu-
tants and the enhanced spreading of the COVID-19
virus (Fattorini and Regoli 2020). However, this
study did not consider other crucial factors of
COVID-19 incidence and mortality, for example, age
structure, lifestyle factor, and the duration of the con-
finement.
A significant positive relationship between
COVID‐19 infections and the number of people ex-
posed to SO
2
, NO
2
, and PM
10
showed that pollution-
related morbidity induced the COVID‐19 infection
across Mumbai (Chattopadhyay and Shaw 2021).
This research suggested that Mumbai as a subtropical
city having high temperature and humidity probably
had not undergone the ill effect of PM
10
during the
COVID-19 situation. They also revealed a low-low
association between air pollution and COVID-19 in
the southern areas, which could be owing to a smaller
quantity of industries, the predominance of corporate
offices, defence areas, etc., and partially for its loca-
tion of facing the open sea in both west and east parts
where the wind could flow freely (Chattopadhyay and
Shaw 2021).
The long-term association between exposures to
common air pollutants and the COVID-19 case fatal-
ity rate (CFR) in China was investigated (Hou et al.
2021). The relationships between CFR and air quality
indicators (air quality score, AQI, and PM
2.5
concen-
tration) in the past 1,3, and 5 years were examined,
and the results showed that the CFR of COVID‐19
infectors rose for higher levels of long‐term AQI,
PM
2.5
, and PM
10
. However, there was no statistically
significant association between the CFR and the lev-
els of SO
2
, NO
2
, and O
3
found (Hou et al. 2021). Lim-
itations of this study include those specific patient
comorbidities, ethnic characteristics, and social fac-
tors, such as access to care and pollution density, as
well as the relatively small sample size which may
affect the CFR for this population‐level study.
A study in the Netherlands focused on the period
2015-19 (Cole et al. 2020) found that PM
2.5
concen-
trations had a statistically significant positive correla-
tion with COVID-19 cases, hospital admissions, and
deaths. For NO
2
, a statistically significant positive as-
sociation was found between the number of COVID-
19 cases and deaths but was not associated with hos-
pital admissions. For SO
2
a trend of positive relation-
ship was also found with COVID-19, but not statisti-
cally significant. A further application of the Fisher
combination test suggested that both PM
2.5
and NO
2
significantly affect the overall COVID-19 outcomes,
but SO
2
did not. The results indicated that, with other
conditions under control, a district with 1 μg/m
3
extra
PM
2.5
concentrations than another would on average
report 9.4 and 15.1 more COVID-19 infections, var-
ying from the model used. It would also result in from
2.9 to 4.4 more COVID-19 hospital admissions and
from 2.2 to 2.8 more COVID-19 deaths. In this study,
it was also found that average household income was
inversely related to COVID-19 infection, while the
average household size and the share of small housing
were both positively correlated with COVID-19
spreading.
ICHIH 2022 - International Conference on Health Big Data and Intelligent Healthcare
248
4.3 Combination of Both Short-term
and Long-term Models in One
Study
Both single-year and five-year average models at sub-
regional and individual levels were discussed in an
England study; the two models (subregional and indi-
vidual) have significantly different patterns
(Travaglio et al. 2021). In the individual model, PM
2.5
and PM
10
were the most significant contributors to the
higher incidence of COVID-19, with similar statistics
in both long-term and short-term studies. Nitrogen
oxides and dioxides were also positively related,
while ozone showed a lack of relevance with COVID-
19 infection. However, in the subregional study, only
nitrogen oxides and nitrogen dioxides had infectivity
rate ratios over 1 for both the single-year and multi-
year models. PM
2.5
, PM
10
, and O
3
were negatively re-
lated to the infectivity of COVID-19. It was proposed
that the inverse correlations between O
3
levels and the
number of COVID-19 cases and deaths may be be-
cause less nitrogen oxide converted to ozone in met-
ropolitan regions, a phenomenon that had been de-
clared in regions with heavy traffic. In addition, due
to the high reactivity of ozone, the negative associa-
tion between O
3
levels and COVID-19 cases is com-
patible with extended nitric oxide scavenging nearly
reaching levels of emissions.
Another study in China (Yao et al. 2021) focused
mainly on the correlation between NO
2
concentration
and spreading capability (basic reproductive number,
R0) of COVID-19 in 63 cities in China. R0 was pos-
itively related to the average NO
2
level from 2016 to
2019 with adjusted temperature and relative humid-
ity. Moreover, no significant relationships were found
between the other examined air pollutants (SO
2
, CO,
O
3
, PM
2.5
, and PM
10
) and R0. The study also investi-
gated the daily R0 values for 11 cities in Hubei (ex-
cept Wuhan) and normalized the data based on daily
R0 value in Wuhan to exterminate the influences by
other covariates. 11 Hubei cities (except Xianning
City) reported significantly positive association for
NO
2
with R0, indicating a positive correlation be-
tween daily NO
2
concentration and COVID-19 diffu-
sion on the transient scale.
Table 1: Correlation between air pollutant particles and COVID-19 cases.
Coun-
try/Re-
gion
Short-
term/long-term
study
Pollutant(s) Type(s) of the model
used
Association with
COVID-19 infection
Refer-
ence
Italy
(Lom-
bardy and
Piedmont)
Short term
(from 10th Feb-
ruary 2020 to
27th March
2020)
PM
10
Confirmed infection
cases against the detec-
tion day and corre-
sponding PM
10
concen-
tration values
No clear association (Bonte
mpi
2020)
China
(120 cit-
ies)
Short term
(from 23rd Jan-
uary 2020 to
29th February
2020)
PM
2.5
, PM
10
,
SO
2
, NO
2
, CO,
and O
3
Generalized additive
model, including both
single-pollutant model
and two-pollutant
model
Significant positive asso-
ciations with PM
2.5
,
PM
10
, CO, NO
2
, and O
3
;
negative association with
SO
2
(Zhu et
al.
2020)
California Short term
(from 4th
March 2020 to
24th April
2020)
VOC, Pb, PM
10
,
PM
2.5
, SO
2
, CO,
and NO
2
Spearman and Kendall
correlation tests
Significant associations
with PM
10
, PM
2.5
, SO
2
,
CO, and NO
2
(Bashir
et al.
2020)
Saudi
Arabia
Short term
(from 9th
March 2020 to
19th November
2020)
PM
10
, NO
2
, and
O
3
Poisson and binomial
negative models
Positive associations with
PM
10
, NO
2
, and O
3
(Ben
Maatou
g et al.
2021)
Italy Long term
(from 2016 to
2019)
O
3
, NO
2
, PM
2.5
,
and PM
10
Average concentrations
of NO
2
, PM
2.5
, and
PM
10
and number of
days exceeding the con-
trolled limits (averages
of the last 3 years) for
Significant associations
with O
3
, NO
2
, PM
2.5
, and
PM
10
(Fattori
ni and
Regoli
2020)
Associations between Air Quality and Covid-19 Infection
249
O
3
and PM
10
versus the
number of COVID-19
confirmed cases
Mumbai Long term
(from 2017 to
2019)
SO
2
, NO
2
, and
PM
10
Ordinary Least Square
model, spatial lag
model, spatial error
model, and spatially ad-
justed regression model
Significant positives as-
sociation with SO
2
, NO
2
,
and PM
10
(Chatto
padhyay
and
Shaw
2021)
China Long term
(from 2015 to
2020)
PM
2.5
, PM
10
,
SO
2
, NO
2
, and
O
3
Shapiro–Wilk test,
Pearson correlation, and
Spearman test
Positive associations with
PM
2.5
and PM
10
; no sig-
nificant associations with
SO
2
, NO
2
, and O
3
(Hou et
al.
2021)
Nether-
lands (355
munici-
palities)
Long term
(from 2015 to
2019)
PM
2.5
, NO
2
, and
SO
2
Fisher combination test,
negative binomial count
model, Operational Pri-
ority Substances disper-
sion model, spatial
econometric models
Significant positive asso-
ciations with PM
2.5
and
NO
2
; not significant posi-
tive association with SO
2
(Cole et
al.
2020)
England Both short term
(2018) and long
term (from
2014 to 2018)
PM
2.5
, PM
10
,
NO, NO
2
, and
O
3
Negative binomial re-
gression model, bino-
mial regression model,
including both subre-
gional and individual
models
Individual model: posi-
tive associations with
PM
2.5
, PM
10
, NO, and
NO
2
; lack of association
with O
3
Subregional model: posi-
tive associations with NO
and NO
2
; negative associ-
ations with PM
2.5
, PM
10
,
and O
3
(Travagl
io et al.
2021)
China Both short term
(from 1st Janu-
ary 2020 to 8th
February 2020)
and long term
(from 2016 to
2019)
NO
2
, PM
2.5
,
PM
10
, SO
2
, CO,
and O
3
Linear regression
model
Significant positive asso-
ciation with NO
2
; no sig-
nificant associations with
PM
2.5
, PM
10
, SO
2
, CO,
and O
3
(Yao et
al.
2021)
4.4 General Trends in the 10 Selected
Studies
Table 1 represents the correlation between air pollu-
tant particles and COVID-19 infectivity. From the 10
studies, PM
2.5
, PM
10
, and NO
2
showed a significant
positive correlation with COVID-19 cases in both
long and short terms. It was, therefore suggested that
concentrations of pollutants like NO
2
should be mon-
itored, especially in urban areas (Bashir et al. 2020).
Moreover, colder regions of the world should adopt
stricter measures (Iqbal et al. 2021). Similarly, the
significance of PM
2.5
and PM
10
suggested that reduc-
ing air pollutants could be a useful way to control
COVID-19 infection (Zhu et al. 2020), and the adop-
tion of green environmental policies should be further
promoted (Bashir et al. 2020). In addition, the burning
of fossil fuels is the main source of NO
2
emissions.
Therefore, variations in NO
2
levels can be applied to
show alternations in human activity and population
movement due to the COVID-19 lockdown (Yao et
al. 2021). SO
2
was under debate. For the association
discussed in 6 of the studies, three of them indicated
a lack of significance with COVID-19 infection (Hou
et al. 2021, Yao et al. 2021, Cole et al. 2020), two of
them found significant association (Bashir et al. 2020,
Chattopadhyay and Shaw 2021), while one study
showed a negative association with COVID-19 cases
(Zhu et al. 2020). Similar trends can be found with
O
3
, which showed significant association (Zhu et al.,
2020, Ben Maatoug et al. 2021), no significant rele-
vance (Hou et al. 2021, Yao et al. 2021, Travaglio et
al. 2021), or negative association, which may be due
to less nitrogen oxide converting to ozone in urban
areas (Travaglio et al. 2021). Hence, more laboratory
ICHIH 2022 - International Conference on Health Big Data and Intelligent Healthcare
250
research needs to be carried out to clarify the under-
lying mechanism (Zhu et al. 2020). CO has not been
frequently discussed in these studies and the potential
associations remain unclear.
5 CURRENT EFFORTS IN
CONTROLLING COVID-19
AND FUTURE EXPECTATIONS
Along with the research about the possible ways of
COVID-19 spreading and infection, efforts have been
done for the prevention and treatment of COVID-19.
Preventions involve the use of personal protective
equipment including masks, gloves, and googles (Qu
et al. 2021). Vaccines have also been applied widely.
As of 5th September 2021, a total of 5,352,927,296
vaccine doses have been administered as reported to
WHO (Geneva: World Health Organization 2020).
Studies are working on developing antiviral therapeu-
tics. A recent study focusing on the nsp14 MTase ac-
tivity suggested that development in this field would
be viable for the COVID-19 pandemic treatment
(Devkota et al. 2021). Another research targeting the
SARS-CoV-2 Nsp13 Helicase also drew the same
conclusion that potential inhibitor compounds could
be identified and applied (White et al. 2020). On the
other hand, it was proposed that the COVID-19 epi-
demic could not only be resolved through medicinal
analysis and experiment, but also be promoted
through environment-related sustainable research
(Iqbal et al. 2021). Future research could involve a
more in-depth study of characterization of SARS-
CoV-2 virion’s sorption onto atmospheric particulate
matter (Duval et al. 2021) and thus find methods to
alleviate the spreading of COVID-19 virus through
air pollution.
6 CONCLUSIONS
An increasing amount of data are available to illus-
trate the correlation between COVID-19 infectivity
and exposure to air pollutants. This review summa-
rized the results of multiple studies, including infor-
mation about country/region, length of data collected,
pollutants, type(s) of the model used, and associations
between the pollutants and COVID-19 infection, as
shown in Table 1. In the selected research, PM
2.5
,
PM
10
, and NO
2
were found to have the most signifi-
cant positive association with COVID-19 confirmed
cases. Different perspectives were oriented for SO
2
and O
3
among different studies, while CO was not fre-
quently discussed in these studies. COVID-19 lock-
down also showed significant association with the air
quality changes in the same period. These statistics
also suggested a possible mechanism of PM facilitat-
ing the spreading of SARS-CoV-2. Studies have
found that PM would lead to COVID-19 infection by
introducing inflammation and thus increasing the ac-
tivity of the ACE2 receptor, the binding site of SARS-
CoV-2. PM in water surrounding can also bind with
the coronavirus, forming the SARS-CoV-2-PM com-
plex, which could serve as carriers of the COVID-19
virus or disturb synaptic vesicle recycling if entering
the brain. Further research in this area may involve
more complex models and focus on the multifaceted
conditions including weather, age groups, income
level, population density, etc.
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