key: cord-1017019-tw59b0fm authors: Meo, Sultan Ayoub; Abukhalaf, Abdulelah Adnan; Alomar, Ali Abdullah; Alessa, Omar Mohammed; sami, Waqas; Klonoff, David C. title: Effect of Environmental Pollutants PM-2.5, Carbon Monoxide, and Ozone on the Incidence and Mortality of SARS-COV-2 Infection in Wildfire Affected Ten Counties in California date: 2020-11-25 journal: Sci Total Environ DOI: 10.1016/j.scitotenv.2020.143948 sha: d761bb0885d34c7ec7f33b00057c3ac44370b53e doc_id: 1017019 cord_uid: tw59b0fm Various regions of California have experienced a large number of wildfires this year, at the same time the state has been experiencing a large number of cases of and deaths from Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2). The present study aimed to investigate the relationship of wildfire allied pollutants, including particulate matter (PM-2.5μm), carbon monoxide (CO), and Ozone (O3) with the dynamics of new daily cases and deaths due to SARS-COV 2 infection in 10 counties, which were affected by wildfire in California. The data on COVID-19 pertaining to daily new cases and deaths was recorded from Worldometer Web. The daily PM-2.5μm, CO, and O3 concentrations were recorded from three metrological websites: BAAQMD- Air Quality Data; California Air Quality Index-AQI; and Environmental Protection Agency- EPA. The data recorded from the date of the appearance of first case of (SARS-CoV-2) in California region to the onset of wildfire, and from the onset of wildfire to September 22, 2020. After the wildfire, the PM2.5 concentration increased by 220.71%; O3 by 19.56%; and the CO concentration increased by 151.05%. After the wildfire, the numbers of cases and deaths due to COVID-19 both increased respectively by 56.9% and 148.2%. The California wildfire caused an increase in ambient concentrations of toxic pollutants which were temporally associated with an increase in the incidence and mortality of COVID-19. compounds (Balmes, 2018) . Wildfire smoke and pollutants can travel far from the actual site of the wildfire, and poses various human health hazards and economical challenges. Smoke and particulate matter (PM2.5) exposures are associated with various respiratory and cardiovascular illnesses as well as mortality. The most susceptible populations from exposure of wildfire smoke includes middle-aged and older adults with acute or chronic respiratory and cardiovascular diseases, and pregnant women (Cascio, 2020) . The same groups of people are also susceptible to SARS-COV-2 infections (Madjid et al., 2020; Meo and Alhowikan et al., 2020) . Presently, the United States of America is facing two major health care challenges: environmental pollution due to the wildfires, and an increasing number of SARS-COV-2 cases and deaths. Wildfires have burned nearly 7.7 million acres this year in the various states of USA, which has affected human lives and damaged economies (Hoover and Hanson,2020). As of October 30, 2020, the total number of documented SARS-COV-2 cases in USA was 9,217,960 out of a worldwide total number of cases of SARS-COV-2 of 45,496,299. The total number of SARS-COV-2 cases in California at this time was 92,5055, which is 10.03% of the total number of cases in the USA. (Worldometer, 2020) . Weather conditions and environmental pollution can have an impact on the pattern of health and disease . Environmental pollution can promote the transportation of microbes and SARS COV-2 infection (Bo wang et al., 2020; Bilal et al., 2020) . Environmental pollution, including wildfire allied pollutants enter into the lungs, blood circulation, deposit in various organs of the human body and cause severe illness and death. This study aimed to investigate the relationship of wildfire allied pollutants, including particulate matter (PM-2.5μm), CO, and O 3 with the dynamics of new daily cases and deaths due to SARS-COV 2 infection in 10 counties, which were affected by wildfire in California, USA. J o u r n a l P r e -p r o o f Journal Pre-proof In this study, we selected 10 different counties from the state of California (USA), which were affected by wildfire. The wildfires and the affected counties included (1) SCU In recent months, these ten counties in California were affected by wildfire and its associated pollution, smoke, dust, and particulate matters (both fine and ultrafine). Daily information on meteorological conditions, wildfire pollutants, particulate matter (PM-2.5), CO levels, and O 3 levels was obtained from three metrological Websites: (BAAQMD-Air Quality Data); (California Air Pollution: Air Quality Index-AQI); and (Environmental Protection Agency -EPA, USA). The data were divided into two groups, before (Group A) and during the wildfire (Group B) in the ten counties in California. The daily levels of particulate matter (PM-2.5μm), CO, and O 3 and the daily new cases and daily deaths were recorded from the date of the appearance of first case of SARS-CoV-2 in 10 different counties in California region from March 19, 2020 to August 15, 2020 (Group A); and from the occurrence of wildfire from August 15, 2020 to Sept 22, 2020 (Group B). The data on daily cases and daily deaths due to the COVID-19 pandemic, were collected from the Web (Worldometer, 2020). The data was analyzed using R Core Team (2020). R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. High-low-close charts were prepared to depict the collated information of four characteristics (cases, deaths, pollutant parameters and groups). Mean±SEM has been reported for quantitative variables. Normality of data for Normal and Poisson distributions was checked through one-sample Kolmogorov-Smirnov test. Welch t-test was applied to compare the mean differences between two groups with the number of cases, deaths and pollutant parameters. Binary Logistic Regression analysis was also performed to observe the log-odds in groups when compared with the number of cases, deaths and pollutant parameters. Spearman Rho correlation was applied to assess the relationship between various meteorological factors at 1% level of significance, whereas, Poisson Regression analysis was performed to predict the number of cases and deaths from PM2.5, O3 and CO after fulfilling the assumptions. Goodness of Fit tests and Model tests for all regression analysis were significant. An α=0.05 and 0.01 were considered as statistically significant. The environmental pollutants mean values for PM2.5, CO and O 3 each significantly increased during the wildfire compared to before the wildfire. The increase for the PM2.5 level was 220.71%, for the O 3 level was 19.56%, and for the CO level was 151.05% (p<0.001 for each). The average number of SARS-COV-2 cases and deaths significantly increased during the wildfire as compared to before the onset of wildfire. The percentage increase in the number of cases was 56.9%, and for deaths was 148.21% (p<0.001 for each) (See Table 1 ). The PM-2.5μm, CO, and O3 levels and daily new cases and daily deaths were further analyzed based by combining county data into total pollution levels and cases/deaths for all counties affected in each of five different fire zones ( The mean number of new cases of COVID-19 in each of the five fire zones was compared for the periods of before (Group A) and after (Group B) the onset of wildfire. The number of new cases of COVID-19 was significantly higher in Group B compared to Group A for all five fire zones. However, in Group B, the number of deaths significantly raised in SCU Lightning and Creek zones as compared to Group A (Table 3 , 4). The rho-coefficient relation showed a significantly increased number of new cases and deaths with increasing levels of PM2.5 and CO, however, for increasing levels of O 3 there was a significant relationship with new cases but an insignificant relationship with deaths (See Table 5 ). When area-wise correlations were studied before and after the onset of wildfire, in SCU Lightening, with increasing levels of PM2.5, CO, and O 3 the number of new cases significantly increased, whereas deaths were positively correlated with increasing levels of PM2.5 and CO but not O 3 . An increasing trend was observed in the Creek area where the number of cases and deaths had a positive relationship with PM2.5, O 3 and CO. In LNU Complex a significant rise morbidity from respiratory infections. Kan et al., (2005) demonstrated that each 10 micrograms per cubic meter increase in respirable particulate matter PM-2.5 and MP-10, is associated with a 6% increased relative risk of mortality during a coronavirus outbreak. Similarly, (Paital and Agrawal, 2020) identified a relationship between PM2.5 levels, ambient NO 2 concentrations, and ACE-2 expression all with severity of COVID-19 infections. A few previous studies have also established an association between high concentration of ambient fine particles, particulate matter PM-2.5, and respiratory infections (Cannon et al., 2018; Gandini et al., 2018; Croft et al., 2020) . The literature shows that environmental and climate conditions possibly affect the transmissibility and incidence of SARS-COV-2 infection . Bianconi et al., (2020) demonstrated that exposure to PM2.5 and PM-10 was linked to COVID-19 cases and deaths. The authors concluded that air pollution played a role in the outbreak of COVID-19 cases in Italy. Similarly, Zhu et al (2020) found a positive relationship between air pollutants, PM2.5, PM10, CO, O 3 with COVID-19 infections in China. In another study, Frontera et al., (2020) reported that increased air pollutants PM-2.5 and NO2 work independently and synergistically to induce a high incidence of mortality because of SARS-CoV-2 infections. Furthermore, Bilal et al., (2020) performed a study on the environmental pollutants, climate indicators and the COVID-19 cases, recoveries, and deaths in Germany. The authors reported that PM2.5, O 3 , and NO 2 each have a significant relationship with the outbreak of COVID-19. Low temperature and low humidity are significant climate indicators which have correlated with the spread of COVID-19 (Ma et al., 2020) . In another study appraised the correlation between environmental pollutants and COVID-19 outbreak in California. Their study findings demonstrated that environmental pollutants including PM10, PM2.5, SO 2 , NO 2 , and CO J o u r n a l P r e -p r o o f Journal Pre-proof have a significant correlation with the COVID-19 epidemic in California. Moreover, (Chakrabarty et al., 2002) reported that long-term exposure to air pollution, PM2.5 renders a population more susceptible to COVID-19 in USA. Similarly, (Paital, 2020) demonstrated that air pollution increases the risk of COVID-19 infection. In a recently published study found that PM-2.5 and CO were reported to have a positive association with an increased number of SARS-COV-2 daily cases, cumulative cases, and cumulative deaths in San Francisco. Similarly, the present study findings show an COVID-19 cases and deaths were associated with wildfire allied environmental pollutants PM 2.5, CO and O3 in 10 different counties in California, USA. One of the reasons for the rising incidence of SARS-COV-2 cases in California may be its low air quality and high environmental pollution, which could make California more susceptible to respiratory-mediated infectious diseases such as COVID-19 . There is a debate in the science community, whether there is a link between PM pollution and the COVID-19 pandemic (Conticini et al., 2020) . This hypothesized linkage is supported by evidence that exposure to PM pollution has been found to be particularly high in wildfire regions where high numbers of COVID-19 cases and deaths have been reported. The literature has established some pathophysiological and epidemiological links between PM exposure and viral infections (Bo wang et al., 2020) . There is an association between airborne pollution and the incidence of COVID-19 (Bianconi et al., 2020) . Environmental pollution, especially particulate matters, acts as a carrier of the virus, impairs immunity, and causes people to be more susceptible to pathogens (Zhou et al., 2020). Moreover, fine particulate matter PM-2.5, CO, and O 3 all can induce a series of adverse health effects including inflammation, oxidative damage, and DNA damage to the lungs, which can trigger pulmonary and cardiovascular diseases through J o u r n a l P r e -p r o o f cytotoxicity mechanisms. Thus, a variety of lines of evidence support the hypothesis that exposure to air pollutants could play a significant role in the spread of COID-19 (Seposo et al., 2020; Zoran et al., 2020) . We have found evidence that strengthens the hypothesized casual linkage between particulate matter PM-2.5, CO and O 3 generated by wildfire and the epidemiological dynamics of COVID 19 cases with mortality. The present study's findings are consistent with evidence that particulate matter PM2.5 is an efficient carrier or transport vector for SARS-COV-2 virus, and also promotes entry by viruses into the respiratory tract and where they can cause infections (Setti et al., 2020). Moreover, PM2.5 and carbon monoxide are highly toxic, exposure to which can result in damage to the lungs. These mechanisms of lung injury due to wildfire-generated pollutants support the hypothesis that wildfire pollutants particulate matter (PM-2.5), carbon monoxide, and ozone resulted in a recent increase in new SARS-COV-2 cases and deaths in ten counties in California. This is the first study in literature, to our knowledge, that has investigated the effect of wildfireallied major pollutants, including PM-2.5, CO, and O 3 on the incidence and mortality trends of SARS-COV-2 infection in 10 different counties in California. We selected the main pollutants, PM-2.5, CO and Ozone, because these pollutants penetrate deeply into the lungs. Moreover, we selected 10 different countries which were affected by wildfire. The daily new cases, daily deaths, and concentrations of PM-2.5 μm, CO, and O 3 were recorded during two time periods. The first time period spanned the date of the appearance of first case of (SARS-CoV-2) in California (which was March 19, 2020) through a recent outbreak of wildfire (which was August 15, 2020,). The second time period spanned the onset of wildfire (which was August 15, 2020) J o u r n a l P r e -p r o o f to Sept 22, 2020 (which was a period of almost 7 weeks, that was sufficient for the wildfire to affect the incidence of COVID-19.) A limitation of this study is that we were unable to collect data for other pollutants, such as PM10 and carbon dioxide, both of which may also affect the dynamics of the COVID-19 epidemic. Another limitation is that new COVID-19 cases and deaths can fluctuate in frequency for other reasons besides pollution. These reasons could include temperature, humidity, changes in societal patterns of social distancing and mass gatherings or adherence to wearing masks. This study demonstrated that daily mean particulate matter PM-2.5, CO, and O 3 concentrations significantly increased after wildfire in ten counties in California. These pollutants were temporally associated with daily cases and daily deaths due to SARS-COV-2. Further study can elucidate the relative contribution to this association of wildfire, as well as potential contributions of demographic, social, therapeutic, and other environmental factors. J o u r n a l P r e -p r o o f J o u r n a l P r e -p r o o f BAAQMD-Air Quality Data. 2020. 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