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Aerodynamic versus physical size of spores: measurement and implication for respiratory deposition

Reponen, T., Grinshpun, S. A., Conwell, K. L., Wiest, J. and Anderson, M.
2001
Grana, 40(3), 119 - 125


Reponen, T., Grinshpun, S. A., Conwell, K. L., Wiest, J. and Anderson, M., (2001), "Aerodynamic versus physical size of spores: measurement and implication for respiratory deposition", Grana, 40(3), 119 - 125.
Abstract:
Different methods available for size measurements of fungal and actinomycete spores were compared for four fungal species (Penicillium brevicompactum, Penicillium melinii, Cladosporium cladosporioides, and Aspergillus versicolor) and two actinomycete species (Streptomyces albus and Thermoactinomyces vulgaris). The physical size of spores was measured with three microscopic methods: with an optical microscope from stained (wet) slides, with an optical microscope from unstained (dry) slides and with an environmental scanning electron microscope (SEM) directly from the microbial culture. The aerodynamic diameter, da, of airborne spores was measured with an aerodynamic particle sizer. The respiratory deposition of spores was calculated with a computer-based model. The environmental SEM measurements indicated larger size for fungal spores than the optical microscope, whereas for actinomycete spores, both microscopes gave comparable results. Optical microscopic measurements showed that the stained fungal spores were 1.1-1.2 times larger than the unstained ones, which was attributed to the different hydration status of spores. There was no clear trend in the relationship between the da and the physical diameter measured with any of three tested microscopic methods. For example, the physical diameter of Cladosporium cladosporioides spores was larger than the da by a factor ranging from 2.0 to 2.2, whereas the da of Streptomyces albus spores was larger than the physical diameter by a factor of 1.3-1.5. Thus, the aerodynamic diameter of microbial spores cannot be accurately estimated solely based on the physical diameter but needs information on the density of the spores that may vary considerably. The results on the spore size were utilized to calculate respiratory deposition of spores. The errors in the size measurement were found to result in overestimation of the respiratory deposition of C. cladosporioides spores by a factor of 1.2-1.8, and underestimation of the respiratory deposition of S. albus spores by a factor of 0.6-0.7. These errors in the size measurement cause bias in the exposure assessment and in the estimation of the efficiency of control devices. More research is needed to standardize the method for particle diameter estimates applicable for airborne spores.

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Author Information and Other Publications Notes
Reponen, T.
Dr.Tiina Reponen, Research Associate Professor Department of Environmental Health University of Cincinnati
     
Grinshpun, S. A.
  1. Aerosol characteristics of airborne actinomycetes and fungi
  2. Bioaerosol collection by a new electrostatic precipitator
  3. Characteristics of airborne actinomycete spores
  4. Collection of airborne microorganisms by a new electrostatic precipitator
  5. Collection of airborne spores by circular single-stage impactors with small jet-to-plate distance
  6. Collection of bioaerosol particles by impaction: effect of fungal spore agglomeration and bounce
  7. Collection of fungal spores on air filters and spore reentrainment from filters into air
  8. Development and evaluation of aerosol generators for biological materials
  9. Effect of impact stress on microbial recovery on an agar surface
  10. Effect of relative humidity on the aerodynamic diameter and respiratory deposition of fungal spores
  11. Evaluation of a new personal sampler for enumerating airborne spores
  12. Field Testing of New Aerosol Sampling Method With a Porous Curved Surface as Inlet
  13. Fungal fragments as indoor air biocontaminants
  14. Fungal spore source strength tester: laboratory evaluation of a new concept
  15. Improved aerosol collection by combined impaction and centrifugal motion
  16. Inlet sampling efficiency of bioaerosol samplers
  17. Long-term sampling of airbome bacteria and fungi into a non-evaporating liquid
  18. Performance characteristics of the button personal inhalable aerosol sampler
  19. Performance of Air-O-Cell, Burkard, and Button samplers for total enumeration of airborne spores
  20. Release of lead-containing particles from a wall enclosure
  21. Release of Streptomyces albus propagules from contaminated surfaces
  22. Techniques for dispersion of microorganisms into air  
Conwell, K. L.
     
Wiest, J.
     
Anderson, M.
  1. Prefab Prototypes: Site-Specific Design for Offsite Construction  



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