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Sampling methodologies and dosage assessment techniques for submicrometre and ultrafine virus aerosol particles
Author(s) -
Hogan C.J.,
Kettleson E.M.,
Lee M.H.,
Ramaswami B.,
Angenent L.T.,
Biswas P.
Publication year - 2005
Publication title -
journal of applied microbiology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.889
H-Index - 156
eISSN - 1365-2672
pISSN - 1364-5072
DOI - 10.1111/j.1365-2672.2005.02720.x
Subject(s) - aerosol , aerosolization , particle size , ultrafine particle , particle (ecology) , virus , particle size distribution , materials science , virus quantification , environmental science , chromatography , chemistry , virology , nanotechnology , biology , ecology , organic chemistry , anatomy , inhalation
Abstract Aims: The aerosolization and collection of submicrometre and ultrafine virus particles were studied with the objective of developing robust and accurate methodologies to study airborne viruses. Methods and Results: The collection efficiencies of three sampling devices used to sample airborne biological particles – the All Glass Impinger 30, the SKC BioSampler® and a frit bubbler – were evaluated for submicrometre and ultrafine virus particles. Test virus aerosol particles were produced by atomizing suspensions of single‐stranded RNA and double‐stranded DNA bacteriophages. Size distribution results show that the fraction of viruses present in typical aqueous virus suspensions is extremely low such that the presence of viruses has little effect on the particle size distribution of atomized suspensions. It has been found that none of the tested samplers are adequate in collecting submicrometre and ultrafine virus particles, with collection efficiencies for all samplers below 10% in the 30–100 nm size range. Plaque assays and particle counting measurements showed that all tested samplers have time‐varying virus particle collection efficiencies. A method to determine the size distribution function of viable virus containing particles utilizing differential mobility selection was also developed. Conclusions: A combination of differential mobility analysis and traditional plaque assay techniques can be used to fully characterize airborne viruses. Significance and Impact of the Study: The data and methods presented here provide a fundamental basis for future studies of submicrometre and ultrafine airborne virus particles.