Summary
Aeriobiological studies are essential for understanding the distribution, ecology and deposition patterns of both phytopathogenic and nonpathogenic fungal spores which are carried away from their source. Many spores and conidia are devitalized during aerial transportation as a consequence of being exposed to atmospheric agents. Nonetheless, a sufficient number remain viable, causing infections of various kinds, some of which extremely serious and with an epidemic trend.
In order to predict the onset of fungi-induced diseases, it is necessary to be able to determine the inoculum source of the pathogenic agent. As air is the main vector transporting pathogenic fungal spores and conidia, periodical monitoring is required. Thus, having established the critical stages of plant infection, necessary precautionary measures can be undertaken in order to control diseases onset and development.
It is therefore necessary to gain a through understanding of spore takeoff and dispersal mechanisms so as to determine how the spores and conidia are transported by air currents onto the plants and how they cause infective impaction. Spores and conidia suspended in the atmosphere can be collected by means of appropriate traps filtering a predetermined amount of air at predetermined time intervals in order to be able to make predictions as to the possibility of plant infection. Volumetric air sampling allows not only to determine the concentration of spores and conidia in a given period of time but also to establish the hours of the day in which they are present in highest concentrations and in which therefore they are more liable to cause infection. This information may be used in estimating the incidence of disease symptoms, the duration of infection and the seriousness of the disease.
On the basis of this data, mathematical models for predicting epidemics can be worked out.
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Govi, G. Aerial diffusion of phytopathogenic fungi. Aerobiologia 8, 84–93 (1992). https://doi.org/10.1007/BF02291334
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DOI: https://doi.org/10.1007/BF02291334