《1. Introduction》

1. Introduction

The global outbreak of coronavirus disease 2019 (COVID-19) caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is the biggest crisis facing humanity since World War II. The number of cases has been increasing in many countries with over 75 million confirmed cases and over 1.6 million deaths around the world by December 21, 2020, at which time the number of cases is increasing exponentially in North America and Europe [1]. Surveillance of SARS-CoV-2 is expected to continue until 2024 in an attempt to predict the possible resurgence of COVID-19, even if the virus may be well controlled in the future [2]. The pandemic is challenging the current public health emergency response systems (PHERSs) of many countries. Although environmental research on viruses is an essential part of midand long-term priorities to control COVID-19, as proposed by ‘‘A Coordinated Global Research Roadmap” issued by the World Health Organization (WHO) (Fig. 1) [3,4], little attention has been given to the roles of environmental factors in PHERSs. Medical and public health researchers mainly focus on the pathogenesis of viruses, clinical management, prevention and control of infection, and development of therapeutics and vaccines, whereas environmental engineers and scientists are mainly concerned with understanding and predicting the transmission of viruses and their secondary environmental risks [5–7]. Hence, there is currently no proper integration of public health and environmental science in PHERSs.

《Fig. 1》

Fig. 1. An illustration of the roles of environmental factors in future PHERSs. Before a pandemic outbreak, environmental and wildlife protection should be strengthened, detailed viral surveillance should be conducted in animals and hotspots, and early-warning systems should be improved to minimize the outbreak of a pandemic. During a pandemic, the impacts of environmental factors on viral behaviors should be studied; also, control measures to minimize secondary environmental risks and timely assessments of viral risks and secondary environmental effects should be undertaken in order to reduce the impacts of the pandemic on human health and ecosystems. After a pandemic, surveillance for viruses and prevention of viral spread should be strengthened, control measures for minimizing secondary environmental risks should be maintained, and scientific prediction capability should be developed in order to respond to the next unexpected resurgence in a timely manner. Meanwhile, the normal life and production of the public should be sustainably restored (sources of illustrations: ↑ reproduced from Ref. [3] with permission of WHO; the 17 goals are from Ref. [4]). T: temperature; RH: relative humidity; UV: ultra violet; RT-PCR: reverse transcription-polymerase chain reaction.

Outbreaks of infectious diseases can be related to destruction of the environment, deterioration of ecosystems, extreme weather, and changes in other environmental factors [8]. Environmental factors such as temperature, humidity, and ultraviolet (UV) radiation are important for the continuous spread of SARS-CoV-2 around the world [9–11]. Furthermore, the environment is closely related to public health. For example, PM2.5 (particulate matter with an aerodynamic diameter no greater than 2.5 μm) pollution impairs the cilia of the upper airways and weakens the human immune response, potentially leading to increased lethality of COVID-19 [12]. Thus, neglect of environmental factors will affect the prevention and control of viral pandemic diseases. To improve current PHERSs and proactively respond to public health emergencies, it is important to integrate various environmental factors in the prevention of and response to public health emergencies.

China’s PHERS, established after the outbreak of severe acute respiratory syndrome (SARS) in 2003, involves systems for institutions, emergency management, medical treatment, control, and support, but ignores the influences and functions of environmental factors. The US PHERS emphasizes cross-departmental collaboration, among which the Department of Health and Human Services bears the primary responsibility for public health management, and the Environmental Protection Agency regulates the safety of air, water, and ecosystems [13]. However, the International Health Regulations that came into force in 2007 barely consider the influences of environmental factors [14]. Nonetheless, the Sendai Framework for Disaster Risk Reduction 2015–2030, which was adopted by the United Nations’ member nations in 2015, requires a more balanced approach in which countries consider social, environmental, political, and institutional factors in the responses to emerging infectious diseases [15]. For COVID-19, ‘‘A Coordinated Global Research Roadmap,” which was published in March 2020, emphasizes that additional studies of the sources, transmission, and stability of viruses in various environments will facilitate the prevention and control of pandemics in various regions [3]. Nevertheless, the integration of environmental factors into PHERSs remains an urgent problem.

Unlike organic and inorganic pollutants, viruses are alive and can be transmitted via human respiratory droplets, direct contact, and aerosols [16], facilitating rapid outbreaks of pandemics. To prevent and control outbreaks of viral pandemics and improve national capabilities to respond to public health emergencies, environmental factors should be integrated into PHERSs based on the ‘‘One Health” concept and on harmonious coexistence between humankind and the natural environment [17]. More specifically, the significance of environmental factors should be fully developed before, during, and after the response to public health emergencies (Fig. 1). Elaborated measures are described below.

《2. How can pandemic outbreaks be prevented?》

2. How can pandemic outbreaks be prevented?

Frequent contact between humans and animals can increase the possibility of pandemic outbreaks (Fig. 2) [18]. To minimize the outbreak of a pandemic (i.e., prior to an outbreak), it is a prerequisite to enhance environmental and wildlife protection, such as the protection of natural habitats and minimization of wildlife poaching and trading (Fig. 1). Surveillance of viruses in the environment and in hotspots will provide useful information to develop more reliable early-warning systems (Fig. 1).

《Fig. 2》

Fig. 2. Possible virus transmission routes in the environment.

《2.1. Protection of the environment and wildlife》

2.1. Protection of the environment and wildlife

2.1.1. Protection of wildlife habitats

Destruction of wildlife habitats forces wildlife and humans into closer and closer proximity, and hence increases the possibility of cross-species viral transmission [18,19]. Humans move into undeveloped areas through logging, hunting, roadbuilding, mining, agriculture, and animal farming—activities that fragment wildlife habitats and increase the contact between humans and wildlife [19]. Nowadays, the frequency of viruses ‘‘hopping” from animals to humans is two to three times greater than it was in the 1980s [18].

To reduce the cross-species transmission of viruses, it is recommended to protect forest resources [8]. To be specific, disorganized activities such as deforestation and mining should be restricted, and reforestation; the protection of natural forests, returning farmlands to forest, and the application of wood substitutes should be encouraged in order to increase forest coverage and protect biodiversity as a means of minimizing virus outbreaks. Although such measures might slow economic growth, they will promote sustainability and may have a high return in the long run.

2.1.2. Wildlife protection

Due to the huge demand for wildlife, wild animals such as bats, pangolins, and boars have been hunted, transported, and traded globally [20]. In addition, wildlife farming is industrialized in some countries. For example, wildlife farming industries in China involve about 15 million people and facilitate the spread of zoonotic diseases [21]. Wildlife markets bring various species into close proximity, and live and dead animals are maintained and sold with poor regulations and health screening [22], posing a serious threat to public health.

On 24 February 2020, China’s National People’s Congress adopted legislation to prohibit the illegal trade of wildlife and the consumption of field-harvested and captive-bred wildlife [23]. This policy was supported by scientists and by a number of international organizations (e.g., the Humane Society International and the WHO) [24,25]. However, banning the trade and consumption of wildlife as food for humans is not enough to protect people from zoonotic diseases. If wildlife markets were forced to close, the wildlife trade would go underground, which could increase the difficulty of managing it [26]. To manage wildlife markets and reduce the potential for virus transmission, the following measures are recommended:

(1) Facilitating the transformation and suppression of the wildlife farming industry by providing financial subsidies [27];

(2) Improving disease surveillance and implementing a system to manage animal farming industries by promoting handwashing, wearing personal protective equipment, enhancing disease surveillance, preventing the mixture of different animal species, limiting animal densities in captivity, and adopting veterinary care with high standards [26];

(3) Advancing the hygiene and regulatory standards of animal markets using similar measures as described in part (2) [22];

(4) Limiting the global consumption of meat and shifting consumption toward plant-based foods [26];

(5) Stringently managing livestock and seafood from abroad by tracing their sources and strengthening health screening at points of import [19].

《2.2. Surveillance of viruses in the environment》

2.2. Surveillance of viruses in the environment

2.2.1. Surveillance of viruses in animals

To prevent pandemics, knowledge of viruses in the environment is essential (Fig. 2). Some programs have tried to discover viruses in wildlife and high-risk humans. For example, between 2011 and 2015, surveillance of viruses in bats from a cave in Southwest China found 11 kinds of novel coronaviruses [28]; furthermore, from 2009 to 2019, the PREDICT project, supported by the US Agency for International Development, found 949 emergent viruses in 164 000 humans and animals [29]. However, knowledge of novel viruses is still limited in comparison with the millions of yet-to-be-discovered viruses on the planet. The distribution of reference laboratories is also extremely unequal, with 62% of reference laboratories having been established in North America and Europe. In contrast, less studied regions such as Africa, Central and South America, and Southeast Asia are at high risk for viral transmission [30].

To better understand pathogens in wildlife and predict the next pandemic, governments should provide more funding to support research to screen viruses in high-risk animals and humans. More specifically, a surveillance system with lower cost and wider viral monitoring should be developed as soon as possible, and more laboratories should be established in high-risk regions [30]. Local scientists and workers in wildlife and healthcare could be trained to use accessible molecular equipment and conduct basic experiments with biosafety standards in order to screen viruses in wildlife and prevent the spillover of pathogens into humans. Compared with wildlife, the biosecurity of livestock and poultry can be controlled more easily. Livestock and poultry are intermediate hosts of pathogens, making viral surveillance necessary (Fig. 2). Although the surveillance of viruses in animals is onerous and expensive, this cost is small compared to the economic losses of a global pandemic [18].

2.2.2. Surveillance of viruses in hotspots

There are various transmission routes of viruses in the environment. As shown in Fig. 2, viruses are very likely to be transmitted via contaminated water, aerosols, soil, food packaging, and so forth, which are closely related to human wellbeing [31–33]. Animal surveillance combined with human testing programs can help identify infectious pathogens [34]. There are many zoonotic hotspots with a high risk of viral transmission, which gather a considerable number of viruses and promote the survival of viruses with dark, wet, and cold conditions. For example, wastewater is a source and pool of viruses, and threatens the health of sewage workers through direct contact or indirect bioaerosols [35]. In low-income areas, exposure to untreated wastewater and fecal wastes can increase the likelihood of viral transmission [34]. In rural areas of China, human feces and urine are often used to produce biogas and organic fertilizer, which can greatly elevate the risk of fecal– oral transmission of viruses in the community. Gathering places of live or dead livestock, poultry, seafood, and meats, such as farms, slaughter-houses, and wet markets, are hotspots for the crossspecies transmission of viruses [19,22]. Due to the cold, wet, and dark conditions, the global cold-food supply chain has become a pathway for the transmission of viruses [36]. For example, it has been suggested that the recurrence of COVID-19 in Beijing, Tianjin, and Qingdao, China, might be the result of frozen seafood from abroad, which could have been contaminated during processing, transportation, or packaging [33,37].

To reduce the risk of viral transmission, it is recommended that routine environmental surveys should concentrate on the surveillance of viruses in zoonotic hotspots, such as the influents and effluents of wastewater treatment plants (WWTPs), village sewage discharge, sanitation infrastructures, farms, slaughter-houses, wet markets, and cold-food supply chains in order to provide sufficient evidence for early warning of public health emergencies. Nevertheless, standards for viral surveillance in hotspots are scarce. Commonly used indicators of pathogens in water quality monitoring are mainly fecal indicator bacteria and several enteroviruses [38], whereas the indicators for enveloped viruses are blank for routine monitoring purposes. Also, there are great differences between enteroviruses and enveloped viruses in terms of viral structures, stability, survivability, and pathogenicity. Appropriate indicators of viruses that react similarly to target infectious viruses should be selected by means of meta-viromics to determine the biosecurity of hotspots [38]. Detailed protocols for viral surveillance in hotspots should be established and adopted in routine monitoring in the near future.

《2.3. Establishment of a shared platform and improvement of earlywarning systems》

2.3. Establishment of a shared platform and improvement of earlywarning systems

Surveillance of viruses in the environment is difficult and requires collaboration among countries. Accordingly, the sharing of resources and information will be necessary. It is recommended to establish a shared biobank containing all viral information from animals and hotspots for better preparation for the next pandemic. The biobank could be managed by an organization following principles of transparency, ethics, equitable access, and respect for international laws [39], and partner countries could share data from the biobank at an affordable cost according to their contributions to the biobank establishment. Based on the knowledge of viruses in the biobank, scientists could assess the zoonotic risk of individual viruses using statistical and machinelearning approaches and could predict the most likely zones of viral outbreaks so as to improve the early-warning capabilities of PHERSs.

《3. How can the impacts of pandemics be reduced?》

3. How can the impacts of pandemics be reduced?

To better control pandemic outbreaks (i.e., during the occurrence of a pandemic), increased attention should be given to the impacts of environmental factors on the behaviors of viruses (Fig. 1). Secondary environmental risks produced during a pandemic response should be controlled to minimize the impacts of the pandemic on ecosystems and human health (Fig. 1). Risks of viruses and control measures for the pandemic, such as disinfection and waste disposal, should be assessed in a timely manner for human health and ecosystems (Fig. 1) [3,4].

《3.1. Impacts of environmental factors on virus behaviors》

3.1. Impacts of environmental factors on virus behaviors

The lifespan, diffusion, migration, and variation of infectious viruses in the environment are associated with various environmental factors. Studies on the impacts of environmental factors on virus behaviors are beneficial to the scientific prevention and control of pandemics. For example, viruses can be transferred by human respiratory droplets and aerosols, and the distance droplets and aerosols will transfer in the air is associated with the size, gravity, inertia, and evaporation of droplets [40]. Under indoor conditions, aerosols containing SARS-CoV-2 can be transferred further than 6 ft (1.8 m), whereas viral concentrations can be diluted more rapidly in outdoor environments by breezes and winds [41]. Furthermore, the attachment of viruses to dust and particulates can modify their aerodynamic characteristics and increase their dispersion. SARS-CoV-2 is sensitive to heat; its viral lifetime decreases from greater than 14 d to 5 min as the incubation temperature increases from 4 to 70 °C [11]. SARS-CoV-2 is also less stable on rough surfaces than on smooth surfaces, while it survives well at a relative humidity of less than 33% or of 100% [10]. However, the impacts of environmental factors on the behavior of the new variant of SARS-CoV-2 are unknown, although the variant is spreading at ‘‘an alarming rate” [42] in the United Kingdom and may be up to 70% more transmissible than SARS-CoV-2. Current studies on virus behaviors should be further strengthened to provide more scientifically relevant information for establishing effective control measures.

《3.2. Minimization of secondary environmental risks》

3.2. Minimization of secondary environmental risks

3.2.1. Scientific disinfection

During the pandemic, chemical agents have been widely used for the disinfection of municipal wastewater, village sewage discharge, streets, public areas, households, and communities, as this is the most convenient, widely used, and low-cost method. However, sprinkled disinfectants end up in the ambient environment either directly or indirectly, thereby contaminating the environment, destroying ecosystems, and threatening the health of organisms including humans [7,43]. It has been pointed out that most disinfectants, such as sodium hypochlorite, are corrosive and irritate the mucous membranes of the respiratory and digestive tracts of mammals and birds [43]. In water, chlorinated disinfectants can result in disinfection byproducts, such as halomethanes, haloacetic acid, haloacetonitriles, inorganic halooxate, halonitromethane, cyanogen halides, and haloacetaldehyde, which are carcinogenic, teratogenic, and mutagenic [44]. Therefore, it is urgent to develop scientific and environmentally friendly means of disinfection and thus reduce the long-term risks for humans and ecosystems.

Proper disinfection methods should be developed and used. It has been demonstrated that SARS-CoV-2 is highly susceptible to far-ultraviolet radiation C (far-UVC) (222 nm) (Table 1) [45], which is safe for human skin and eyes. Thus, for indoor environments with poor ventilation, low-dose-rate far-UVC light could be used to safely reduce airborne coronaviral levels. Peracetic acid, 75% ethanol, and chlorinated disinfectants can inactivate SARS-CoV-2 effectively [46], while co-occurrence substances, such as organic matter, can decrease the sensitivity of viruses to disinfectants. Therefore, the mechanism of disinfection needs to be studied further in order to disinfect efficiently. Apart from the adoption of disinfection technology, shrinking the scope of human activity during a pandemic could efficiently reduce the usage of disinfection.

《Table 1》

Table 1 Inactivation of SARS-CoV-2 by far-UVC light (222 nm) (0.1 mW·cm–2 ) [45].

a TCID50: 50% tissue culture infectious dose (the data were means ± standard deviation)

b Log removal: differences between lgTCID50 values recovered from plates after 222 nm far-UVC irradiation and those from nonirradiated samples.

3.2.2. Disposal of hazardous wastes

The COVID-19 pandemic has led to a massive increase in hazardous wastes, especially infectious medical wastes, which threaten human health and the functions of ecosystems. For example, medical wastes in Wuhan, China, increased from 40 t·d–1 in normal days to about 247 t·d–1 in the early days of the COVID-19 pandemic (March, 2020) [47]. Medical wastes in Kuala Lumpur, Manila, Bangkok, and Hanoi have increased to 154–280 t·d–1 more than the amount prior to COVID-19 [48]. The operation loads of disposal facilities for medical wastes in Hubei Province, China, were as high as 85%–96% in 2019 [49], and there was clearly a much greater need for medical wastes disposal during the subsequent pandemic. During the pandemic in China, massive amounts of hazardous wastes were incinerated by transporting them to nearby incinerators. In addition, more mobile emergency incineration facilities were built, and old incineration facilities for household wastes were rebuilt to facilitate the treatment of an increased amount of hazardous wastes [49]. However, incineration is not a sustainable method, as it has a high cost and may release harmful substances due to improper operation.

To reduce the socioeconomic and environmental impacts of waste disposal, sustainable methods that consider waste generation, collection, transport, treatment, recycling, and the disposal of the remaining waste residues are recommended [50]. Sustainable mobile treatment systems are also encouraged. Considering the instability of disposal facilities, the specificity of wastes produced during pandemics, and the lack of criteria for sampling and monitoring discharge, governments should rapidly establish standards for the exhaust from such emergency treatment facilities, and assess its environmental risks in order to minimize any negative impacts to the environment and human health.

Hazardous wastes do not only come from hospitals; they are also produced in households and public places. For example, masks can reduce airborne viral concentrations to protect uninfected individuals from SARS-CoV-2 aerosols and droplets [41]. Scientists and governments in many countries have encouraged people to wear masks in public places, and a large number of masks are being used and discarded over relatively short periods of time. Some of these masks are likely to have been contaminated by asymptomatic individuals and thus contain infectious viruses [41]. To avoid the further spread of infectious viruses during the pandemic, masks discarded in places other than hospitals should be treated separately from other forms of waste. Discarded masks should be collected in separate rubbish bins with clear labels. These masks, bins, and transporters should be disinfected in a timely manner, and the masks should be disposed of by qualified departments to decrease the risk of further dissemination of infectious viruses due to improper disposal measures. Meanwhile, workers dealing with the hazardous wastes should be equipped with protective masks, gloves, and clothing, as well as hand sanitizer, detergent, and other necessary protective equipment to ensure their safety.

《3.3. Management of wastewater and minimization of further viral dissemination》

3.3. Management of wastewater and minimization of further viral dissemination

3.3.1. Surveillance of viruses in wastewater

During a pandemic, the surveillance of viruses in wastewater must be enhanced in order to understand the disease burdens, changing trends, and resurgence likelihood of the pandemic [35]. This noninvasive method can be used to assess and manage the risks of viral dissemination, alert the authorities of a resurgence of the pandemic, guide officials to strengthen or withdraw lockdowns, and decrease the damage to health and the economy.

3.3.2. Treatment of viruses in wastewater

In general, conventional WWTP processes cannot remove viruses completely, and high influent viral loads during a pandemic may result in an insufficient reduction of viruses before discharge, for viruses such as rotavirus, sapovirus, astrovirus, and SARS-CoV-2 [51–53]. It has been shown that SARS-CoV-2 RNA was detected in a secondary-treated wastewater (2.4 × 103 copies·L–1 ) in Japan [54], although another study showed that it was completely removed in the treated effluent of WWTPs with secondary biological processes [55]. These contrasting results indicate that there is a chance that virus occurrence in treated effluent and could carry the risk of triggering secondary transmissions. To ensure the inactivation of SARS-CoV-2, membrane filtration and disinfection by chlorinated disinfectants, UVC irradiation, and ozonation for treated effluents are necessary. For example, microfiltration and ultrafiltration are perfect barriers for SARS-CoV-2 when the pore size distributions on the membrane filters are less than the hydrated diameter of SARS-CoV-2 [56,57]; SARS-CoVs tend to be more susceptible to chlorinated disinfectants than enteroviruses [58]; and UVC irradiation at 254 and 222 nm can inactivate SARS-CoV-2 efficiently [9,45]. Co-occurrence matrices can affect the efficiency of virus removal, however [59]. More effective and low-cost methods should be rapidly developed to remove viruses effectively. In addition, discharge standards for WWTPs should include the monitoring of enveloped viruses based on appropriate indicators.

3.3.3. Management of wastewater from rural areas

During pandemics, wastewater in low-income areas—especially the feces and urine of humans and animals—must be given more attention, due to the general lack of sanitation infrastructure and WWTPs in these areas. According to the United Nations, about 9% of global residents defecate in the open, while another 8% use a facility that is shared with another household [60]. Even worse, the reuse of fecal and other organic wastes is encouraged in the rural areas of China, which greatly increases the risk of virus transmission.

To avoid further virus dissemination, the reuse of wastewater and excreta should be stopped immediately, and wastes should be disinfected by every household [59]. It is essential to strengthen the design, establishment, and management of sanitation infrastructures and WWTPs in low-income areas. Furthermore, governments should review and re-examine the regulations and standards for the safe disposal and reuse of fecal wastes, domestic sewage, and household wastes in rural areas.

《3.4. Risk assessment》

3.4. Risk assessment

Infective virions in effluent and reused wastewater not only directly threaten human health, but also produce bioaerosols containing viruses [61]. It has been reported that the rates of emission of virions by aerosolization in the aeration basin of WWTPs are greater than those in toilets and lab-scale models, and the existence of solids does not mitigate the aerosolization of viruses [62]. Moreover, sprinkler irrigation using wastewater and fertilization using wastewater solids might also generate aerosols [59]. SARS-CoV-2 is infectious in aerosols for up to 16 h [31]. Accordingly, infectious aerosols threaten the health of relevant workers and nearby residents.

To avoid adverse effects on human health, the risks caused by viruses in wastewater and aerosols need to be quantified. The process of quantitative microbial risk assessment (QMRA), a tool for combining quantitative scientific data related to environmentally relevant disease pathways to support environmental safety management, contains four steps (Fig. 3): hazard identification, exposure assessment, dose–response assessment, and risk characterization. QMRA has been used to assess the risks of some pathogens in water, aerosol, or food, such as legionella, mycobacteria tuberculosis complex, and influenza virus in aerosol; cryptosporidium, campylobacter, and rotavirus in drinking water; and adenovirus, enterovirus, hepatitis A virus, and norovirus in wastewater [61,63,64]. Recently, Zaneti et al. [65] investigated the potential health risks of SARS-CoV-2 in sewage for WWTP workers, and found that the estimated risks for the aggressive and extreme scenarios were likely to be above the derived tolerable infection risk for SARS-CoV-2. However, few assessments have been done on the risks of coronavirus using QMRA, so more studies are warranted.

《Fig. 3》

Fig. 3. QMRA: a tool for combining quantitative scientific data related to environmentally relevant disease pathways to support environmental safety management.

The secondary environmental risks produced during pandemic control should also be assessed in order to minimize the impacts to ecosystems and human health. For example, the main disinfection byproducts in regions where vast quantities of disinfectants are used and the harmful exhaust from treatment facilities for emergency medical wastes treatment should be assessed in a timely manner.

《4. How can the probability of pandemic resurgence be reduced and normal activities be restored?》

4. How can the probability of pandemic resurgence be reduced and normal activities be restored?

To avoid the resurgence of COVID-19 (after pandemic control), surveillance of SARS-CoV-2 in hotspots should be strengthened in comparison with that from before the COVID-19 pandemic. Residual secondary environmental risks should be assessed and controlled continuously to minimize the impacts of pandemics. Predicting the resurgence of COVID-19, considering the environmental and anthropogenic factors, is significant to enable timely responses to the next resurgence. To restore normal life and production among humanity, protection of the environment and wildlife should be maintained in order to minimize outbreaks of virus infections in the future and realize sustainable development (Fig. 1) [3,4].

《4.1. Strengthened viral surveillance in the environment》

4.1. Strengthened viral surveillance in the environment

During the post-pandemic period, the presence of the infectious virus that induced the past pandemic in the environment, such as in hotspots, should be surveyed more frequently and comprehensively than usual in order to prevent further dissemination of viruses and resurgence of the pandemic. For example, viruses in wet markets, including on or in chopping boards, knives, refrigerators, mops, wastewater, and meat and seafood products, as well as the workers related to booths selling frozen and chilled meats and seafood, should be monitored frequently. As mentioned above, it is recommended that virus surveillance be strengthened in other hotspots, such as cold-food supply chains, sanitation infrastructures, farms, slaughter-houses, WWTPs, and sewage pipes in communities. Governments should review and revise the regulations on viral surveillance and management frameworks in these hotspots.

《4.2. Prediction of a pandemic resurgence considering environmental factors》

4.2. Prediction of a pandemic resurgence considering environmental factors

To predict the resurgence of SARS-CoV-2 from near-term climate forecasts, more attention should be given to relationships among climatic variations, interventions, and the COVID-19 pandemic. Some simulations of the COVID-19 pandemic have been conducted, which found that summer weather would not limit COVID-19 growth substantially, strong outbreaks were likely to occur in more humid climates, and COVID-19 would become more dangerous again in the winter [66,67]. Nevertheless, longer term studies are warranted on the dynamics of SARS-CoV-2 that consider the influence of various environmental factors on a global scale. Scenario planning is useful to determine which prior actions are beneficial to building resilience and reducing disastrous effects for the next unexpected pandemic. It is important to predict unexpected situations—instead of assuming that the next crisis will be ‘‘just like this one”—in order to prevent unfortunate surprises [68].

《4.3. Maintained protection of the environment to restore normal activities sustainably》

4.3. Maintained protection of the environment to restore normal activities sustainably

As of 15 May 2020, the global economic losses have been estimated to be between 5.8 × 1012 and 8.8 × 1012 USD, which is equivalent to 6.4% to 9.7% of the global gross domestic product [69]. This figure does not begin to measure the suffering of and psychological impacts on the global public, which are catastrophic. Losses in education and social interactions that can never be replaced are mounting daily. These costs are so great that such a pandemic should be avoided at all cost in the future. However, in order to recover their economies, many countries have relaxed their protection of the environment. For example, India has cut the funding allocated to environmental protection and relaxed the requirements for industrial and infrastructural discharge [70], and the United States has canceled certain environmental guidelines and appears to plan to recover its economy through the use of nonrenewable resources [71]. It is unwise to relax environmental protection because doing so will increase the likelihood of future pandemic outbreaks. Following the pandemic, the premise of ‘‘One Health” and sustainability should be at the core of economic recovery. Decarbonization is specifically recommended as compatible with economic recovery, as it produces co-benefits for environmental protection, human health, and economic growth [72]. Furthermore, regulations for environmental protection should not be set aside, and collaboration across multiple departments is necessary [72].

Finally, the end of this COVID-19 pandemic is not the end of viral pandemics. Three coronaviral pandemics have already broken out, and another viral pandemic may break out in the near future [35]. Further studies on the integration of environmental factors into PHERSs are essential to respond to the next unexpected pandemic.

《5. Conclusions》

5. Conclusions

In recent decades, pandemic outbreaks of pathogenic viruses are becoming more frequent, challenging current PHERSs. Given the ‘‘One Health” concept and the connectivity of viruses in the biosphere, the environment plays an important role in regulating viral transmission and thereby influencing PHERSs. However, little attention has been given in PHERSs to the role of environmental factors as an intersection between environment and health. This study proposed that the significance of the environment needs to be considered before, during, and after responses to a pandemic by strengthening environmental protection, surveying viruses in the environment, improving early-warning systems, avoiding secondary environmental risks, minimizing the further dissemination of viruses, and predicting and preventing subsequent outbreaks. Overall, environmental factors should be integrated into future PHERSs by establishing systems and institutions of technical support, environmental response, and risk prevention, in order to improve national capabilities to respond to serious public health emergencies. Furthermore, relevant regulations and standards should be updated and improved to provide timely political support. The recommendations of this study are essential for improving national capabilities to respond to public health emergencies around the globe. The significant roles of environmental factors before, during, and after responses to public health emergencies must receive more attention in the near future.

《Acknowledgment》

Acknowledgment

This work was financially supported by the National Science Foundation of China (41925031, 41991315, and 41521003).

《Compliance with ethics guidelines》

Compliance with ethics guidelines

Xiaolei Wang, Fengchang Wu, Xiaoli Zhao, Xiao Zhang, Junyu Wang, Lin Niu, Weigang Liang, Kenneth Mei Yee Leung, and John P. Giesy declare that they have no conflict of interest or financial conflicts to disclose.