Abstract
Airborne allergenic pollen impact the health of a great part of the global population. Under climate change conditions, the abundance of airborne pollen has been rising dramatically and so is the effect on sensitized individuals. The first line of allergy management is allergen avoidance, which, to date, is by rule achieved via forecasting of daily pollen concentrations. The aim of this study was to elaborate on 3-hourly predictive models, one of the very few to the best of our knowledge, attempting to forecast pollen concentration based on near-real-time automatic pollen measurements. The study was conducted in Augsburg, Germany, during four years (2016–2019) focusing on Betula and Poaceae pollen, the most abundant and allergenic in temperate climates. ARIMA and dynamic regression models were employed, as well as machine learning techniques, viz. artificial neural networks and neural network autoregression models. Air temperature, relative humidity, precipitation, air pressure, sunshine duration, diffuse radiation, and wind speed were additionally considered for the development of the models. It was found that air temperature and precipitation were the most significant variables for the prediction of airborne pollen concentrations. At such fine temporal resolution, our forecasting models performed well showing their ability to explain most of the variability of pollen concentrations for both taxa. However, predictive power of Betula forecasting model was higher achieving R2 up to 0.62, whereas Poaceae up to 0.55. Neural autoregression was superior in forecasting Betula pollen concentrations, whereas, for Poaceae, seasonal ARIMA performed best. The good performance of seasonal ARIMA in describing variability of pollen concentrations of both examined taxa suggests an important role of plants’ phenology in observed pollen abundance. The present study provides novel insight on per-hour forecasts to be used in real-time mobile apps by pollen allergic patients. Despite the huge need for real-time, short-term predictions for everyday clinical practice, extreme weather events, like in the year 2019 in our case, still comprise an obstacle toward highly performing forecasts at such fine timescales, highlighting that there is still a way to go to this direction.
Highlights
Airborne pollen dispersion is part of plant phenology, following yearly seasonal cycles with the aim of successful reproduction
Pollen information provided for example via pollen applications to the target population of allergic individuals might become an important aid in avoiding exposure to allergenic pollen, and in planning medication and outdoor activities (Kmenta et al 2014)
The main pollen season of Betula average started by the end of March, and lasted on average 38 days (SD = 10.2)
Summary
Airborne pollen dispersion is part of plant phenology, following yearly seasonal cycles with the aim of successful reproduction. The ongoing increase in air temperature and the overall effect of climate change have been increasing steadily the abundances of airborne pollen across the globe and, at the same time, have been shifting earlier the pollen seasons for several allergenic taxa (Ziska et al 2019). The World Allergy Organization has warned that, because of climate change, plants will be stressed to flower and pollinate earlier within the year and in higher amounts, increasing the natural pollen exposure of sensitized individuals and, increasing the severity of associated symptoms (Pawankar 2014). Pollen information provided for example via pollen applications to the target population of allergic individuals might become an important aid in avoiding exposure to allergenic pollen, and in planning medication and outdoor activities (Kmenta et al 2014). Automated pollen monitoring in real time might be a solution covering this urgent need
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