Co-occurrence of airborne biological and anthropogenic pollutants in the central European urban ecosystem

The interactions between organic and inorganic air pollutants, enhanced by the impact of weather parameters, may worsen the respiratory allergy symptoms in allergy sufferers. Pollen grains and fungal spores belong to some of the most crucial aeroallergens. Other allergenic bioparticles in the atmospheric microbiome can include microalgae, fern spores and mites. In this study, we evaluated if and to what extent air pollutants and weather parameters drive the daily variation in airborne concentrations of broad spectrum of bioparticles (pollen grains, fungal spores, microalgae, fern spores and invertebrates) in the air of Bratislava over 3 years, 2019-2021. Air samples were collected using a Hirst-type volumetric sampler. Based on the results of Spearman's correlation analysis, air temperature seems to be the most influential meteorological factor, positively associated with the concentration of all types of bioparticles at assemblage level, even though the association with microalgae was negative. Wind speed, known to have a diluting effect on most airborne particles, appears to be the most influential for microalgae, as their concentration in the air increases along with rising wind speed. Considering air pollutants, correlation analysis revealed that as the daily concentrations of ozone, PM10, CO and/or NO2 increased, so did the levels of most types of analysed bioaerosols at the assemblage level. Regarding that bioparticles may act as carriers for inorganic particles and amplify their allergenic impact, a concomitant increment in the airborne concentration of both organic and inorganic pollutants poses a threat to allergy sufferers in the study area. The concentration of microalgae, on the other hand, decreases with rising levels of CO, NO2 and PM10; thereby, their synergistic effect on allergy sufferers is negligible. Based on our findings, we suggest that the response of pollen and fungal spore concentration to environmental conditions should be investigated at the taxon, not the assemblage level, as each pollen/spore taxon has a different pattern in response to meteorological parameters and air pollutants.

Automated summary

The interactions between organic and inorganic air pollutants, enhanced by weather parameters, can worsen respiratory allergy symptoms. This study investigated the daily variation in airborne concentrations of various bioparticles (pollen grains, fungal spores, microalgae, fern spores, and invertebrates) over a three-year period in Bratislava. It was found that air temperature had the most significant influence on bioparticle concentrations, positively correlating with all types except microalgae. Wind speed had a diluting effect on most particles but positively correlated with microalgae concentrations. Additionally, higher levels of ozone, PM10, CO, and/or NO2 were associated with increased levels of bioaerosols. The coexistence of organic and inorganic pollutants poses a threat to allergy sufferers, while microalgae concentrations decrease with increasing levels of CO, NO2, and PM10.