Abstract
Bioaerosol characterization represents a major challenge for the risk assessment and management of exposed people. One of the most important bioaerosol sources is the organic waste collection and treatment. This work analyzed and discussed the literature with the purpose of investigating the main techniques used nowadays for bioaerosol monitoring during organic waste treatment. The discussion includes an overview on the most efficient sampling, DNA extraction, and analysis methods, including both the cultural and the bio-molecular approach. Generally, an exhaustive biological risk assessment is not applied due to the organic waste heterogeneity, treatment complexity, and unknown aerosolized emission rate. However, the application of bio-molecular methods allows a better bioaerosol characterization, and it is desirable to be associated with standardized cultural methods. Risk assessment for organic waste workers generally includes the evaluation of the potential exposition to pathogens and opportunistic pathogens or to other microorganisms as biomarkers. In most cases, Saccharopolyspora rectivirgula, Legionella spp., Aspergillus spp., and Mycobacterium spp. are included. Future perspectives are focused on identifying common composting biomarkers, on investigating the causality process between chronic bioaerosol exposure and disease onset, and finally, on defining common exposure limits.
Highlights
The rapid growth of the world population has led to an impressive increase of waste destined for landfill and to a resulting increase in greenhouse gas emissions
Bioaerosol characterization in organic waste treatment facilities is still a controversial topic, since the determination of the biological composition is strongly influenced by environmental factors, such as temperature, humidity, season, and prevalent source contamination, as well as technical factors like sampling and analysis methods
It is not yet possible to define a standardized method for bioaerosol characterization, some identified procedures can lead to a more homogeneous research and could allow a more exhaustive bioaerosol description
Summary
The rapid growth of the world population has led to an impressive increase of waste destined for landfill and to a resulting increase in greenhouse gas emissions. The European Union committed to reducing the total quantity of waste destined for landfill [1,2]. Organic waste (OW) can be treated through biological transformations, by aerobic process alone, which produces an improver used as soil fertilizer, or by an anaerobic process that produces energy. According to ISPRA (Istituto Superiore per la Protezione e la Ricerca Ambientale) in 2018, the organic waste treatment plants (OWTPs), that integrate anaerobic digestion to the aerobic phase, are more than the sites that use only the biomethanization (35 plants against 23, respectively) [5].
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
