Climate change, extreme weather events, air pollution and respiratory health in Europe

Introduction

The continuous increase in anthropogenic emissions of carbon dioxide and other greenhouse gases following the industrial revolution is dramatically changing climate, both overall and at regional level. As in other parts of the world, Europe has experienced a progressive warming (+0.90°C for 1901–2005) and an increase in mean precipitation, except in some regions (i.e. the Mediterranean region) that are becoming arid [1, 2]. Climate scenarios for the next century predict that the warming will be associated with more frequent, more intense and longer lasting heatwaves, especially in Southern and Eastern Europe, and also in areas not currently susceptible to such events [2, 3]. This will be paralleled by an increase in the intensity of short duration precipitation events (1–2 days) in regions such as the Mediterranean, where a decrease in mean precipitation is also expected [2]. The higher intensity of rainfall events will increase the likelihood of floods, especially flash floods, throughout Europe, while the occurrence of heatwaves and droughts will increase the risk of wildfires and desertification, notably around the Mediterranean basin [2].

In urban areas, climate change is likely to influence outdoor air pollution levels because the generation and dispersion of air pollutants, such as ozone and particulate matter, depend in part on local patterns of temperature, wind, solar radiation and precipitation [4]. In some regions, air quality is projected to further worsen due to the increased frequency of wildfires that cause the release of gaseous and particulate pollutants into the atmosphere. In addition, changes in wind patterns and desertification will modify the long-range transport of pollutants emitted by human activities and biomass burning [4].

Changing patterns of disease are occurring in response to changing environmental conditions. It is widely recognised that air pollution has a significant impact on human health, with a great burden on respiratory diseases, particularly asthma, rhinosinusitis, chronic obstructive pulmonary disease (COPD) and respiratory tract infections [5]. Changes in climate are expected to further aggravate the effect of air pollution on these diseases. Prompted by these scenarios, the American Thoracic Society and the European Respiratory Society have recently expressed their concern about the threat posed by air pollution and climate change on respiratory disease [6, 7]. Current and future impacts on respiratory mortality and morbidity deriving from changes in climate as well as from trends in air pollutants are, therefore, a priority for the researchers, respiratory clinicians and policy-makers agenda.

This review summarises the scientific evidence on the effects of climate-related hazards on respiratory health from epidemiological studies. Specifically, we considered those climate events which may be influenced most by climate change and for which climate conditions are interlinked with air quality: temperature extremes, wildfires and dust storms. The conceptual framework for these interactions is summarised in figure 1. Pathogenetic mechanisms, vulnerable population subgroups and policy implications are discussed and research needs are identified.

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Figure 1–

Climate change: its influence on extreme weather events, air pollution and aeroallergens, and effects on respiratory health. PM: particulate matter; COPD: chronic obstructive pulmonary disease.

Climate change and air quality

Climate change and air pollution are intrinsically connected since greenhouse gases and air pollutants originate from the same source, fossil fuel combustion [8–10]. In fact, combustion processes emit both greenhouse gases, like carbon dioxide (CO₂), methane (CH₄) and nitrous oxide (N₂O), and air pollutants, like particulate matter (PM), sulfur dioxide (SO₂), nitrogen dioxide (NO₂) and carbon monoxide (CO).

At both a global and a regional level, now and in the future, climate change and air pollution trends counterbalance in determining air quality: on the one hand, a reduction in anthropogenic emissions, resulting from the implementation of the emission control legislation adopted in each country and energetic sector improvements; on the other hand, climate change effects, in most cases leading to an increase in pollution levels [10].

The correlation between climate and air quality is noteworthy for ozone. Ozone levels are directly driven by weather since ozone-generating photochemical reactions of air pollutants (nitrogen oxides; methane; volatile organic compounds, VOCs) need high temperatures and bright sunshine, conditions typical of summer months [11]. High temperatures are often associated with dry weather conditions, which significantly contribute to high ozone levels during heatwaves through a drought stress on vegetation that inhibits stomatal uptake of ozone [8, 12]. Anthropogenic emissions of ozone precursors will decline in industrialised countries but not in the emerging economies. Hemispheric background ozone concentrations will increase due to a higher frequency of forest fires [11]. Considering climate change scenarios, a large climate change-related ozone increase is expected in Southern European regions that will overcome the beneficial reduction in ozone precursor anthropogenic emissions in these countries [11].

Climatic factors affect particulate matter concentrations to different extents depending on the PM chemical components [8]. On the one hand, high temperature results in an increase in sulfate aerosols due to faster SO₂ oxidation, and on the other, it brings about a reduction in nitrate PM concentrations due to increased gas phase transition [8]. However, under climate change the nitrate burden is predicted to increase along with all other aerosol species, except sulfates [13]. Over Europe, the predicted increase in overall aerosol concentrations will be by 20–40 μg·m⁻³ relative to the present-day values [13]. Changes will be driven by precipitation changes since wet deposition represents the primary PM sink, but also by increments in water vapour that increase oxidation of SO₂ and sulfate concentrations. Air stagnation conditions represent another important factor that will increase PM concentrations in polluted regions [4, 8]. Climate change-related increase in wildfires will also influence particulate levels [14, 15]; an increased fire risk in Mediterranean countries is expected, especially in areas with high forest cover [4, 16]. The 2003 heatwave in Europe is emblematic since it was associated with both record wildfires and high PM levels [8]. During wildfires the main concern is fine particles (particles with a diameter <2.5 μm, PM_2.5) since they have a longer lifetime (of the order of days) and may be carried long distances from their source regions [17]. Future PM concentrations are also driven by the long-range transport of dust aerosols. The long-range transport of pollutants emitted by human activities, burning biomass and dust will also be influenced by future climate changes, due to changes in wind patterns and desertification [4].

Another important link between climate and air quality is that primary products of combustion processes (i.e. carbon monoxide, non-methane VOCs, nitrogen oxides, sulfur dioxide, black carbon and organic carbon aerosols) and some secondary pollutants (i.e. ozone) have the potential to increase global warming directly or indirectly [18]. Carbon monoxide, non-methane VOCs and nitrogen oxides cause a reduction in the oxidant power of the atmosphere increasing the lifetime of methane, one of the most important warming agents and a precursor to ozone [18]. Nitrate particles, as well as organic carbon aerosols, instead have a cooling effect on the climate. Sulfur dioxide partly converts to sulfate particles, which also have cooling potential, and partly reacts with black carbon, which has a strong warming effect [18]. Wildfires may directly contribute to global warming since they emit large quantities of greenhouse gases (i.e. carbon monoxide, carbon dioxide and methane) [19].

Respiratory health effects

Since the 1990s, an extensive European collaboration has been set up through the European Union (EU) funded research programmes in the field of air pollution (APHEA, APHEIS, AIRNET, APHEKOM) and climate change (cCASHh, PHEWE, EuroHEAT, CIRCE) [20]. These studies have substantially contributed to current epidemiological knowledge on the short-term health effects of air pollution and high temperatures or heatwaves in Europe, and to the formulation of the World Health Organization guidelines [21] and EU air pollution standards. Several of these projects also specifically investigated the synergy between air pollution, high temperature exposure and heatwave events (PHEWE, EuroHEAT, CIRCE) [22]. The ongoing EU project PHASE (Public Health Adaptation Strategies to Extreme weather events) will provide further insights into the synergy between air pollution and extreme weather events (e.g. heatwaves and cold spells) and an innovative aspect will be investigation of their environmental consequences (floods, wildfires) that are projected to increase with predicted climate change [23].

Synergy (effect modification) of air pollution and temperature effects

Several European time-series and case-crossover studies have provided indirect evidence (i.e. that effects are stronger in the warm season or in warmer cities) suggestive of interactions between air pollution and heat, although other explanations are consistent with these results [53–56]. The multicentre APHEA study found ozone effects on respiratory mortality only during summer [34], while single-city studies provided contrasting results, with a significant effect on respiratory deaths all year round [57], and a positive association with physician consultations for asthma and with paediatric asthma hospital admissions only in the summer months [58, 59]. A study in Cyprus showed an ozone effect on respiratory admissions that was stronger in the warm season [60].

The APHEA project also provided evidence of seasonal differences in the effect of pollutants other than ozone, i.e. black smoke and sulfur dioxide, whose effects on respiratory mortality were also found to be higher in summer [53]. Other studies found similar [55, 61], or contrasting findings [57, 59, 62]. The APHEA study provided evidence of effect modification not only by season but also according to typical temperatures for the area; the greatest PM₁₀ effects were in the warmest cities but no result for respiratory causes was available [63]. On the other side of the relationship, a study from Greece found a greater effect of heatwaves in Athens where pollution levels were higher than in all other urban areas [64].

Several studies provided consistent evidence of a synergy between the two exposures [65–77], with only one study showing no evidence of interaction [78]. In all these studies the potential interaction between air pollution health effects and high or low temperature was tested through interaction terms or by means of a stratified analysis in time-series and case-crossover analyses. Among studies carried out in a European country (table 2), three studies [55, 76, 79] analysed the synergistic effect on mortality for respiratory causes. In the UK study, the ozone effect on respiratory mortality during hot days corresponded to a rate ratio of 1.009, while the pollutant had no effect on ordinary days (rate ratio = 1.000), but the ozone–heat interaction was significant only in London and ozone–heat interactions were greatest in those aged <75 years [76]. In Italy, an effect of PM₁₀ on respiratory mortality was found only for temperatures above the 50th percentile compared to no effect on days with a temperature below the 50th percentile [55]. The study of Carder et al. [79], carried out in Scotland, instead found a positive interaction between cold temperatures and black smoke concentrations on respiratory mortality. Other European studies analysed total mortality; they were focused on specific heatwave episodes [64, 66–69] or on both warm and cold periods [70] and provided evidence of a significant interaction between high temperature and pollutants, mainly ozone. Two multicentre studies suggested that the synergistic effect may vary among cities according to local climate characteristics, activity patterns and physical adaptation [69, 76].

The synergy between temperature and air pollution has been also evaluated in multicentre European studies analysing the other side of effect modification: air pollution levels modifying the health effect of temperature or heatwaves (table 3) [22]. For ozone, there is consistent evidence of interaction with heat or heatwave effects on mortality from natural causes in the elderly, but no evidence of interaction on respiratory mortality [22]. Concerning PM₁₀, the study carried out before the year 2000 did not find any interaction with temperature, while the more recent time-series studies showed a significant effect modification. In particular, PM₁₀ significantly modified the heatwave effect on mortality for respiratory causes in Mediterranean cities (65–74 years) [22] and there is a suggestion of interaction with effect of high temperature on this group of diseases. For PM₁₀ there is also evidence of effect modification of temperature effect during the cold season, with a lower cold effect on respiratory mortality on high pollution days [22].

Overall, results from studies of temperature–air pollution interactions suggest that this topic cannot be disregarded when studying temperature or air pollution effects regarding respiratory causes, since the true magnitude of the associations may be underestimated. Results differ by pollutant considered and study area, suggesting that the underlying mechanisms are driven by local conditions. Moreover, the evaluation of effect modification presents specific methodological challenges. In many studies stratification can provide quantitative estimates, but results are dependent on the selection of cut-offs for strata. In contrast, the use of more flexible models, i.e. joint pollutant-temperature response surface on health outcomes, has the disadvantage of not providing parametric estimates [29, 74].

Other weather conditions, such as humidity, have been suggested to interact with air pollutant effects. Low absolute humidity may increase the effect of total suspended particles on hospitalisations for COPD [80]. However, it should be noted that absolute humidity is very strongly correlated with temperature, so in essence this finding may be reflecting temperature effects. Humidity was also found to be a significant effect modifier of the effect of air pollutants on mortality, as found in the 29 EU cities included in the APHEA2 project [63]; the observed effect of PM₁₀ increased as humidity levels decreased. Another remarkable type of interaction is that from air masses and air pollutants. In a study in Birmingham, UK, two winter air masses that were associated with increased admission rates for respiratory causes (continental anticyclonic gloom and continental anticyclonic fine and cold) were also favourably associated with high PM₁₀ levels [47].

Mechanisms and vulnerable subgroups

The respiratory system is the main target of gases, aerosols and particles present in air pollution. A wide range of effects on the respiratory system are triggered by environmental toxicants, from reversible local responses to long-term chronic effects: local irritation, direct cellular damage to the epithelium of respiratory airways, allergic responses (i.e. asthma) and cancer. The underlying mechanisms are different for the different pollutants. Ozone provokes oxidative damage to the respiratory epithelium, resulting in lung inflammation, decrements in lung function, worsening of respiratory tract symptoms and increased airway reactivity [105]. Particulate matter, via enhanced oxidative stress, may disrupt lung endothelial cell barrier integrity, thereby inducing lung dysfunction and adverse cardiopulmonary outcomes [106].

Not only air pollution but also high and low temperatures have a strong effect on respiratory health as discussed above. Underlying mechanisms are better understood for cold than for heat. Cold temperature may affect respiratory health in different ways and seems to affect not only susceptible but also healthy subjects. Breathing cold air causes the cooling of nasal and bronchial mucosa, seriously impairing ciliary motility and consequently reducing the immune system's resistance to respiratory infections [107, 108]. Exposure to cold air may also increase the number of granulocytes and macrophages in the lower airways in healthy subjects [109] and induce bronchoconstriction [110, 111], suggesting that cold exposure could be involved in the pathogenesis of the asthma-like condition. Part of the increase in respiratory outcomes during cold periods may also be attributed to cross-infections from increased indoor crowding during winter [112].

In contrast to observed cold-related effects, the health consequences deriving from exposure to heat seem to be greater in patients affected by chronic respiratory diseases. In these patients, it may be hypothesised that thermoregulatory responses to heat stress, particularly those involving the respiratory system, may be ineffective at dissipating excess heat, thus increasing their risk of developing heat stress conditions such as dehydration and heatstroke. However, this hypothesis is still not supported by experimental studies [113]. A different pathway linking heat exposure to respiratory health outcomes involves the clinical course of heat-related illnesses such as heatstroke. In patients with heatstroke, acute lung inflammation and damage might occur [114] and heat may trigger a series of physiological changes in the lung leading to a severe respiratory distress syndrome [41, 115]. Recent experimental evidence suggests that exposure to chronic heat stress could increase the susceptibility of animals to highly pathogenic respiratory viruses by reducing local immunity in the respiratory tract, i.e. the number of pulmonary alveolar macrophages [116]. Other weather conditions, particularly humidity, may adversely affect respiratory health but their role is still unclear. Some studies showed that in both healthy and asthmatic subjects humidity may decrease lung capacity and increase airways resistance [117, 118], while in others humidity did not influence non-specific airway hyperresponsiveness [119]. Humidity may also indirectly affect respiratory allergic diseases by influencing atmospheric levels of aeroallergens, with low humidity favouring release, dispersion and transport of pollen [120, 121]. Extreme weather events, such as thunderstorms, may trigger asthma epidemics by inducing pollen grain rupture by osmotic shock, which releases respirable allergens into the atmosphere [120, 121].

The evidence of a synergistic effect between air pollution and temperature can have different explanations. Since the respiratory surfaces are the primary route by which air pollutants enter the body, the activation of thermoregulatory responses at pulmonary level during prolonged heat exposure may augment the total intake of airborne pollutants due to the increase in ventilation rate and lung volumes [122, 123]. It has also been suggested that variations in the sources of air pollution and meteorological factors can result in changes in characteristics of the air pollution mixture across seasons [70, 124, 125]. However, in an experimental study modifications in PM components were not able to explain the seasonal difference in PM effects, which could instead be related to the highest prevalence of allergens in spring and summer influencing the onset and severity of allergic diseases [126]. The higher effects of pollutants observed in summer than in winter might also be due to the lower exposure measurement error during summer, as a consequence of more time spent outdoors or, especially for particles, due to a more similar composition between indoor and outdoor pollutants [55, 70, 124, 127, 128]. Another hypothesis is that the lower winter mortality for infectious diseases resulting in a lower mortality among the elderly, i.e. among those most susceptible, has the consequence of a larger pool of susceptible people at risk of air pollution effects the following summer [70, 124, 127]. To explain the interaction between pollutant and low temperature [79], a hypothesised mechanism is that the cold-related impairment of respiratory mucociliary function may inhibit the clearance of pollutants [107, 108].

Meteorological factors such as temperature may also influence the interaction between allergens and air pollution in producing adverse respiratory effects since air pollution-related damage to the respiratory epithelium increases airway permeability stimulating allergen-induced responses and absorption of pollutants to the surface of pollen grains may modify their allergenic potential [120, 121]. Also humidity may modify air pollution effects on respiratory health. Airways of individuals suffering from respiratory diseases seem to be protected against the effect of particles by high humidity, probably due to the reduced number of particles [80].

Mechanisms explaining the respiratory effects of wildfires and dust storms are mainly linked to the air pollution associated with these events. Particulate matter is the predominant air pollutant in fire smoke, which also contains gases including carbon monoxide, nitrous oxides, polycyclic aromatic hydrocarbons, VOCs, ozone and nitrogen dioxide [81–83]. Wood smoke particles have been shown to activate systemic and pulmonary inflammation in healthy human subjects [91, 93]. There is still insufficient evidence to establish whether wildfire PM may have a greater effect than urban background PM [17, 81–83].

However, smoke particulate is probably different in composition with respect to urban PM, having a greater concentration of PM that can accumulate in the lungs. An in vivo experiment found that responses to wood smoke consist of higher inflammatory and cytotoxic responses than those triggered by urban particulate matter [129]. Apportionment techniques are expected to provide important insights into whether fire components are less or more toxic than the same constituents from fossil fuel burning and to clarify the underlying mechanisms.

In the case of dust storms, not only the chemical composition of particles but also its biological content is the probable causative agent of respiratory health effects [91–93]. In particular, coarse particles may have greater allergenic and inflammatory properties, absorbing to their surface pollens and microorganisms such as bacteria and fungi, as well as endotoxins, which are components of the bacterial wall that can cause respiratory and systemic inflammatory responses, and exacerbate lung disease [91–93]. This hypothesis is coherent with recent evidence of an increase in infectious diseases (i.e. meningitis) on dust days [93]. Moreover, in their long-range travel dust particles may absorb metals, pesticides and industrial products mixing with the anthropogenic emissions of industrial regions (e.g. North African). Inhaling these compounds can cause lung irritation, reducing lung capacity through activation of oxidative stress pathways [91, 93]. As in the case of wildfires, chemical speciation and toxicity studies may clarify whether dust particles are more or less toxic than urban PM, considering that dust may also contribute to PM concentrations other than interacting with airborne particulate pollution from local sources.

Research needs in the context of respiratory health

Considering climate change scenarios, quantifying the effect estimates on respiratory health and identifying vulnerable population subgroups are crucial research areas to carry out health impact assessments to understand future impacts and to support decision-makers and the healthcare community in the fight against this global environmental threat [6].

table 5 summarises for each climate hazard the main respiratory outcomes and the population subgroups for which there is evidence of association from epidemiological studies; research gaps and future expected impacts under climate change are also highlighted. Overall, every climate hazard appears to have a significant impact on the respiratory system, although evidence on specific respiratory diseases and specific age groups is still limited. At European level, there is scarce epidemiological evidence on the effects of extreme cold and wildfires. Multicentre studies are lacking in the analysis of rare and local-extent episodes, such as dust storms and wildfires. The ongoing PHASE [23] and MEDPARTICLES [140] multicentre projects will provide further insights on both these hazardous exposures. Pre-existing respiratory diseases are important vulnerability factors to both temperature and air pollution effects. Since vulnerability factors are specific for each climate hazard and may vary across populations and over time, more research is needed, in particular on younger age groups and children, but also on other population segments, such as low socioeconomic groups.

Considering future impacts on respiratory diseases, population ageing, increased prevalence of chronic diseases and the socioeconomic transitions which are currently ongoing in several countries will probably increase the portion of the population at risk [141, 142]. Almost all climate hazards will worsen under climate change, as will the related disease burden. The only beneficial effect will be the reduction in cold-related effect (i.e. respiratory infections) due to warmer winters [142]. However, due to the complexity of the above mentioned climate–air quality interactions, a great deal of uncertainty remains regarding future trends of climate and pollutants. Research is needed to increase the modelling capability to better understand the interplay between human activities, air pollution and regulatory requirements, climate policy, economic factors, and to predict future trends of air pollutants, accounting for uncertainty and variability in projections of global change. Advances in modelling capability can derive from disease surveillance integrated with air pollution, weather and climate data and from combining ecological approaches (time-series studies) with spatial methods to produce a more complete evaluation of health effects, taking into account both geographical and temporal variations. From a public health point of view, since health professionals have joined the climate change debate late [143], they are urged to develop modelling skills in relation to climate change, particularly by combining climate models with ecological and health outcome models for projecting disease dynamics under various climate scenarios.

Policy implications

Due to the close climate and air pollution interlinkages, climate change policies need to be integrated with air quality policies to be effective. Moreover, mutual benefits can be achieved: actions to mitigate climate change by reducing greenhouse gas emissions may help reduce air pollution since they involve mainly changes in the transport and energy sectors which are also driving pollutant sinks and, at the same time, clean air measures can reduce anthropogenic emissions that are important contributors to global warming. Benefits of climate policies on air pollution have been evaluated for Europe [144]. Although there were limitations in data availability, especially in relation to the scenario datasets and modelling uncertainties, benefits resulted for all investigated emission scenarios, with the scenarios based on energy efficiency strategies leading to larger benefits [144].

At the European level, although stringent emission targets have been made (i.e. to reduce domestic greenhouse gas emissions by 80% by 2050 compared to 1990 levels), the greatest reductions in greenhouse gas emissions have been achieved only as an indirect effect of the current economic crisis [145]. To accomplish greenhouse gas reduction targets, countries need to reach the convergence between resource productivity and efficiency. However, energy efficiency improvements, i.e. switching to fuel with a low-carbon content but higher price, leads to increases in environmental inequality posing major risks to disadvantaged groups, for example due to inadequate housing and heating systems. To cope with economic and climate changes, European countries need to develop a more comprehensive policy framework that integrates climate policy, industrial policy, employment and social policy [145].

Conclusions

Climate and climate change are modifying air pollution effects on respiratory health in several ways: climate variations are predicted to influence the start, duration and intensity of the pollen season, to increase the frequency and intensity of heatwaves, heavy precipitation events (i.e. thunderstorms) and wildfires, and to raise long-range transport of air pollutants and allergens [4].

To face both the current and future climate and pollution challenges, adequate policy and public health actions are needed, taking into account the interrelationships between the two hazardous exposures. Since climate change is a global problem, with the worst consequences occurring not in developed but in developing countries, global actions are needed. Policies to reduce greenhouse gas emissions need to be established, especially in countries which hold the greatest emission burden. In parallel, developing countries are increasingly affected by urban air pollution due to rapid economic and population growth [146, 147]. The way forward to face both these challenges needs the multisectorial collaboration of epidemiologists, climatologists, respiratory and allergy specialists, policy makers and public health professionals to share the heavy responsibility of guiding the world through the climate crisis and making the environment sustainable for future generations.