The rise of respiratory allergic diseases has become a growing public health concern in Europe. Strongly linked to environmental transformations, that include air pollution, global warming and extreme weather events that are altering pollen production. Allergy is described as an exaggerated response from the body’s immune system to otherwise inert substances present in the environment. Hypersensitivity refers to an inappropriate immune response to common, typically harmless antigens, manifesting along a continuum from minor conditions such as atopic dermatitis and rhinitis to more severe outcomes like asthma and anaphylaxis [1]. These immune-mediated diseases are increasingly influenced by external environmental factors. Recent research has shown that climate change can modify pollen production and allergenicity, extend pollen seasons, and alter the distribution of allergenic plants, leading to new sensitization and longer exposure windows. Allergic responses can be intensified and triggered by the interaction between pollen, air pollutants, and meteorological variables. Conditions that pose particular risk to vulnerable populations. Despite recognition of the link between climate change and allergic disease, dedicated health strategies remain underdeveloped. It is important to keep in mind that while climate change alters pollen production and seasons, air pollution directly enhances pollen allergenicity and worsens respiratory symptoms [2].

The mini review aims to put together the latest evidence on how climate change and environmental pollution affect respiratory allergies and asthma across Europe.

Climate change, air pollution, and extreme weather conditions are some of the causes of the increasing prevalence and severity of respiratory allergies. For example, thunderstorms fragment the pollen grains into smaller and highly allergenic particles. Due to their size and number, they penetrate deeper into the lung and can trigger severe asthma attacks even in people with mild or undiagnosed pollen allergies. Also, greenhouse gas (GHG) resulting from human activities (burning fossil fuels, deforestation, and overall industrial processes) leads to climate change that can affect ecosystems and the geographic distribution of allergens. There is an urgent need for governmental actions to address climate resilience, which have to include the implementation of dedicated health plans on allergies and other health consequences related to climate change. We have conducted a pragmatic literature search of the current state of knowledge related to the impact of climate change on populations suffering from respiratory allergy.

Climate change has a significant impact on pollen production, allergenicity, and seasonal pollen dynamics, leading to increased risks of respiratory disorders for specific populations. The rise of carbon dioxide (CO₂) levels and temperature enhances annual pollen production and prolongs pollen seasons, increasing human exposure to allergens. Season pollen integral data suggests that climate change affects annual pollen production more directly than atmospheric transport, suggesting that forecasting models could predict future pollen burden and health related impacts [3].

The natural geographic distribution of allergenic plants is impacted and could be leading to longer flowering seasons [4]. Habitats and species density are shifting northward in the Northern Hemisphere, raising the risk of specific and new pollen sensitization in new areas. This increased allergen exposure can lead to respiratory symptom manifestations and sensitization appearing from the age of 4 years [5].

Climate change directly impacts meteorological conditions and events, as it exacerbates extreme temperatures and increases the frequency and strength of events as thunderstorms, wildfires, and dust storms that contribute to increased pollen health-related risks [6].

Longer and more acute pollen seasons alongside rising allergic sensitization have direct consequences, such as enhancing the allergen content of pollen (e.g., birch pollen with higher allergenicity under warmer conditions) [3].

Thunderstorm asthma is a phenomenon in which thunderstorms fragment pollen grains into smaller and highly allergenic particles that penetrate deeper into the lungs, triggering severe asthma attacks. Thunderstorm asthma events are a rising public health concern, affecting both sensitized and non-sensitized individuals. One such event was observed in 2004 in Naples. In 2016 in Australia, a thunderstorm asthma event led to 10 deaths and sent about 9,000 hospitalizations for severe asthma [7]. The first one was characterized in 1983, in the United Kingdom (UK). Since then, over 20 other events were reported. In the UK, another thunderstorm was recorded in June 2023 with a dramatic increase in European Union (EU) attendances due to asthma all over England [8].

Air pollutants are also responsible and enhance allergic diseases (Figure 1). They modify the shape, size, and allergenicity of pollen grains, enhancing their inflammatory potential. Studies show that diesel pollutants and resulting fine particles have pro-inflammatory effects, which combined with an increasing allergen concentration worsen allergic manifestations.

Finally, ozone (O₃) increases pollen allergenicity and impairs airway defenses. In Mediterranean regions, sunny days (ultraviolet light converts nitrogen dioxide into O₃) create “summer smog” that worsens asthma and allergic inflammation. Up to 60% of the inhaled O₃ is absorbed by the nasal airways, with the remainder reaching the lower airways [6]. O₃ is a prototypic oxidant pollutant that can generate reactive oxygen species in the airways when inhaled, that can lead to oxidative stress [10]. In recent studies, it has been shown that O₃ concentration enhances the potential of birch pollen. Higher O₃, correlates with increased levels of Bet v 1, and heightened immune response in sensitized individuals. These studies suggest that O₃, acts as a key environmental factor enhancing birch pollen allergenicity, which can potentially exacerbate allergic symptoms [11]. Bet v 1, is one of the most allergenic pollen produced by trees, with over 100 million people allergic to its pollen [12].

According to the World Health Organisation (WHO), by 2050, 50% of the population will suffer from allergy disorders resulting from the acceleration of air pollution associated with toxic gas emissions and climate change [13].

Climate change and pollution act as significant plant stressors, modifying pollen allergenicity via reactive oxygen specifies and proteomic plasticity in plants. Stress increases allergenic proteins in ragweed, a potent aeroallergen in Europe, especially in Eastern Europe, Italy, and France. In many European countries, the prevalence of ragweed sensitization is above 2.5% (up to a maximum of 20% in Denmark and 50% in Hungary) [14].

Vulnerable populations, including children, the elderly, and low-income communities, due to overlapping risk factors (social determinants, reduced access to medical care), are the populations experiencing the most climate change-related respiratory health issues (Figure 2). For example, urban environments have been associated with a higher prevalence of allergic disease, suggesting that early-life exposure to pollutants impacts allergic sensitization and disease development [15, 16].

As the most impactful manifestation of allergies, allergic asthma is a major public health concern. To reduce allergy and asthma related risk, public prevention campaigns and education are crucial. The Global Initiative for Asthma (GINA) report on the burden of this disease has estimated that 400 million people in the world suffer from allergic rhinitis and 300 million from asthma [17]. The total cost of asthma for the European Union is estimated at €3 billion, while the annual economic cost of premature deaths from air pollution across Europe was estimated by WHO at US$1.431 trillion, with an overall cost that includes health impacts and mortality from air pollution of US$1.575 trillion [13].

Climate change impacts both pollen distribution and production, directly increasing prevalence, frequency and severity of allergy manifestations and its most debilitating consequence, allergic asthma, a major public health concern.

In addition, pollution generated by human activity worsens CO₂, O₃, and small particle levels, exacerbating allergic reactions, affecting lung airways and causing inflammation. These combined factors lead to a significant worsening of allergic manifestations.

There is an urgent need for the implementation of impactful public actions, such as limiting the proliferation of highly allergenic species (e.g., ragweed, birch), particularly in urban areas and reducing pollution due to human activities. The adverse effects of human activities and climate change on allergic conditions could be reduced through the implementation of effective and targeted interventions (Figure 3). In addition, proactive, systematic and large communication campaigns on pollutants and pollen levels crossed with weather forecasts could anticipate and prevent significant health damage for allergic populations. In response, the European Union has established the Ambient Air Quality Directive to regulate and monitor air pollutants that pose a risk to public health.

Finally, the increasing prevalence and severity of allergic manifestations will need to be managed. As of today, the number of allergologists is decreasing whilst prevalence and allergy diseases and their severity increase. This creates bottlenecks and strong access barriers for patients who cannot be managed by specialists in due time and receive appropriate diagnosis and treatments. Optimizing the allergic patients’ pathway will allow appropriate disease management by specialists and other healthcare providers, as well as access to an appropriate therapeutic arsenal, including both symptomatic rescue medication and targeted disease modifying treatments such as allergen immunotherapy. Allergen immunotherapy is, due to its mode of action, the only therapy that can change the course of the allergic disease and reduce the severity of allergic manifestations due to climate change.

Minimize climate change and pollution effects: Act urgently to limit the proliferation of highly allergenic plants (e.g., ragweed, birch), particularly in urban settings, and reduce pollution caused by human activities to mitigate the worsening impact of global warming on allergies and asthma.