Factors determining the diffusion of COVID-19 and suggested strategy to prevent future accelerated viral infectivity similar to COVID

Coccia, Mario

doi:10.1016/j.scitotenv.2020.138474

Cited by 577 publications

(635 citation statements)

References 138 publications

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“…There had been a series of researches suggested that the association between infectious diseases and air pollution particularly by NO 2 . These studies investigated that the increased level of NO 2 up to 70 µg/m3 caused the incidence of croup due to influenza virus (Chauhan and Johnston, 2003;Coccia, 2020;Hao et al, 2019;Xu et al, 2013). However, as per the proposed study, SO 2 had a negative correlation with COVID-19 infected cases, which may be the possible reason of low wind frequency along WSW-NW Winds (Cuesta-mosquera et al, 2020;Cuhadaroglu and Demirci, 1997;Mallik et al, 2019;Sangeetha and Sivakumar, 2019).…”

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confidence: 86%

Significance between Air pollutants, Meteorological Factors and COVID-19 Infections: Probable Evidences in India

Sahoo

2020

Preprint

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SARS-CoV-2 (Coronavirus) disease represents the causative agent with a potentially fatal risk which is having great global human health concern. Earlier studies suggested that air pollutants and meteorological factors were considered as the risk factors for acute respiratory infection, which carries harmful pathogens and affects the immunity. The study intended to explore the correlation between air pollutants, meteorological factors and the daily reported infection cases caused by novel coronavirus in India. The daily positive infected cases, air pollution and meteorological factors in 288 districts were collected from January 30, 2020 to April 23, 2020 in India. Speraman’s correlation and generalised additive model were applied to investigate the correlations of four air pollutants (PM2.5, PM10, NO2 and SO2) and eight meteorological factors (Temp, DTR, RH, AH, AP, RF, WS and WD) with COVID-19 infected cases. The study indicated that a 10 µg/m3 increase during (Lag0-14) in PM2.5, PM10 and NO2 was resulted in 2.21% (95%CI: 1.13 to 3.29), 2.67% (95% CI: 0.33 to 5.01) and 4.56 (95% CI: 2.22 to 6.90) increase in daily counts of COVID 19 infected cases respectively. However, only 1 unit increase in meteorological factor levels in case of daily mean temperature and DTR during (Lag0-14) associated with 3.78% (95%CI: 1.81 to 5.75) and 1.82% (95% CI: -1.74 to 5.38) rise of COVID-19 infected cases respectively. In addition, SO2 and relative humidity were negatively associated with COVID-19 infected cases at Lag0-14 with decrease of 7.23% (95% CI: -10.99 to -3.47) and 1.11% (95% CI: -3.45 to 1.23) for SO2 and for relative humidity respectively. The study recommended that there is significant relationship between air pollutants and meteorological factors with COVID-19 infected cases, which substantially explain the effect of national lockdown and suggested positive implications for control and prevention of the spread of SARS-CoV-2 disease.

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confidence: 86%

Significance between Air pollutants, Meteorological Factors and COVID-19 Infections: Probable Evidences in India

Sahoo

2020

Preprint

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“…In this context of emergence of COVID-19, the main goal of this study is to explain the relation between air pollution and the diffusion of COVID-19 to suggest environmental policies to cope with future epidemics and infections in society. This study revels new findings of how geo-environmental factors may have accelerated the spread of COVID-19 in Italy, one of the countries in the World to experience a rapid increase in confirmed cases of infection and deaths (Coccia, 2020). In particular, this study explains how COVID-19 transmitted so rapidly in northern Italy, analyzing the underlying relationships between infected people and environmental, demographic, and geographical factors that influenced its spread.…”

Section: Introductionmentioning

confidence: 60%

“…(1) This percentage is calculated considering infected individuals and total deaths weighted with population of these group of regions Table 8 shows that about 74.50% of infected individuals and about 81% of total death in Italy because of COVID-19 are in regions with high air pollution. In fact, studies argue that accumulated airborne pollutants induce that microorganisms might be attached to particulate matter, so in environments with heavy air pollution, highly toxic pollutants in PM2.5 and PM10 may inhibit microbial growth (Coccia, 2020;Frontera et al, 2020).…”

Section: Resultsmentioning

confidence: 99%

Effects of Air Pollution on COVID-19 and Public Health

Coccia¹

2020

Preprint

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The pandemic of coronavirus disease 2019 (COVID-19), generate by a novel virus SARS-CoV-2, is rapidly spreading all over the world, generating a high number of deaths. One of the current questions in the field of environmental science is to explain the relationships determining the diffusion of COVID-19 in specific regions of countries. The research here focuses on case study of Italy, one of the countries in the World to experience a rapid increase in confirmed cases and deaths. Results suggest that diffusion of COVID-19 is very high in cities with high air pollution generating severe negative effects on public health o. In particular, results reveal that, among Italian provincial capitals, the number of infected people was higher in cities with more than 100 days per year exceeding limits set for PM10 or ozone, cities located in hinterland zones (i.e. away from the coast), cities having a low average intensity of wind speed and cities with a lower temperature. In hinterland cities (mostly those bordering large urban conurbations) with a high number of days exceeding PM10 and ozone limits, coupled with low wind speed (atmospheric stability), the average number of infected people in April 2020 more than tripled those that had less than 100 days of excessive air pollution. In fact, results show that more than 75% of infected individuals and about 81% of deaths in Italy of COVID-19 are in regions with high air pollution. This study must conclude that a long-run strategy to constrain future epidemics similar to the COVID-19, reducing the negative impact on public health has also to be designed in terms of environmental and sustainability policies and not only in terms of efficient approaches in medicine.

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“…The model proposed in this paper allows us to answer questions like: 'How many days are necessary to stop the epidemic? ', 19 . In China, it lasted 57 days until the point of adp, in Italy, 93 days.…”

Section: Discussionmentioning

confidence: 99%

Estimating the critical points of an epidemic: An application of non-epidemiological logistic growth model for COVID-19

Allaman

Jelihovschi

2020

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Epidemiological models have become a very important tool in understanding an epidemic development, mainly because they help researchers in finding good and new strategies in their fight against its spread. Several models have been proposed up to now, some are mathematical others apply models from other areas. The SIR and SEIR among others, mainly focus on the variable response and on epidemiological parameters as the basic reproduction number (R0) and infection rate per unit of time, nevertheless they do not focus on the variable ‘time’. We propose the use of the variable time using the logistic model as it is generally used to describe the growth of animals. This model is important because it allows the estimation of the points of acceleration and deceleration, the point of maximum growth and the asymptotic point of the epidemic. This is only possible when the epidemic curve is stable and has an ‘S’ shape. In this work we use the variable ‘accumulated cases’ of China and Italy and point out the main socioeconomic facts that occurred in each period of the estimated critical points from the logistic growth model.

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Factors determining the diffusion of COVID-19 and suggested strategy to prevent future accelerated viral infectivity similar to COVID

Cited by 577 publications

References 138 publications

Significance between Air pollutants, Meteorological Factors and COVID-19 Infections: Probable Evidences in India

Significance between Air pollutants, Meteorological Factors and COVID-19 Infections: Probable Evidences in India

Effects of Air Pollution on COVID-19 and Public Health

Estimating the critical points of an epidemic: An application of non-epidemiological logistic growth model for COVID-19

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