Abstract
The airborne transmission of infection relies on the ability of pathogens to survive aerosol transport as they transit between hosts. Understanding the parameters that determine the survival of airborne microorganisms is critical to mitigating the impact of disease outbreaks. Conventional techniques for investigating bioaerosol longevity in vitro have systemic limitations that prevent the accurate representation of conditions that these particles would experience in the natural environment. Here, we report a new approach that enables the robust study of bioaerosol survival as a function of relevant environmental conditions. The methodology uses droplet-on-demand technology for the generation of bioaerosol droplets (1 to greater than 100 per trial) with tailored chemical and biological composition. These arrays of droplets are captured in an electrodynamic trap and levitated within a controlled environmental chamber. Droplets are then deposited on a substrate after a desired levitation period (less than 5 s to greater than 24 h). The response of bacteria to aerosolization can subsequently be determined by counting colony forming units, 24 h after deposition. In a first study, droplets formed from a suspension of Escherichia coli MRE162 cells (108 ml-1) with initial radii of 27.8 ± 0.08 µm were created and levitated for extended periods of time at 30% relative humidity. The time-dependence of the survival rate was measured over a time period extending to 1 h. We demonstrate that this approach can enable direct studies at the interface between aerobiology, atmospheric chemistry and aerosol physics to identify the factors that may affect the survival of airborne pathogens with the aim of developing infection control strategies for public health and biodefence applications.
Highlights
Bioaerosols are a suspension of atmospheric particles of biological origin containing living and/or dead organisms and their derivatives
Such a capability makes it possible to explore the role microbial concentration in bioaerosol droplets plays in the airborne transmission of infection
We have presented a new methodology for measuring biological decay (BD) rates in bioaerosol particles as a function of different atmospheric conditions and particle compositions
Summary
Bioaerosols are a suspension of atmospheric particles of biological origin containing living and/or dead organisms (e.g. bacteria, viruses, pollen, etc.) and their derivatives (e.g. allergens, endotoxins, etc.). Their study requires an interdisciplinary approach encompassing atmospheric chemistry, microbiology, aerosol microphysics, climate and medical sciences, and an understanding of diverse physical processes including human inhalation, ice nucleation, cloud formation and aerial dispersal. Bioaerosol sources can be natural (e.g. human sneeze, pollen) or anthropogenic (e.g. through agricultural practices, waste management sites) with the source influencing the bioaerosol particle size, composition and concentration in the atmosphere [1]. Interest in bioaerosol has increased in recent decades due in part to a high number of airborne disease outbreaks and concern about the potential roles that airborne microorganisms play in atmospheric processes [2,3].
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
