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Release of Streptomyces albus propagules from contaminated surfaces

G¨®rny, R. L., Mainelis, G., Grinshpun, S. A., Willeke, K., Dutkiewicz, J. and Reponen, T.
2003
Environmental Research, 91(1), 45-53

G¨®rny, R. L., Mainelis, G., Grinshpun, S. A., Willeke, K., Dutkiewicz, J. and Reponen, T., (2003), "Release of Streptomyces albus propagules from contaminated surfaces", Environmental Research, 91(1), 45-53.
Abstract:
The release of Streptomyces albus propagules from contaminated agar and ceiling tile surfaces was studied under controlled environmental conditions in a newly developed aerosolization chamber. The experiments revealed that both spores and cell fragments can be simultaneously released from the colonized surface by relatively gentle air currents of 0.3 m s-1. A 100¡Á increase of the air velocity can result in a 50-fold increase in the number of released propagules. The aerosolization rate depends strongly on the type and roughness of the contaminated surface. Up to 90% of available actinomycete propagules can become airborne during the first 10 min of the release process. Application of vibration to the surface did not reveal any influence on the aerosolization process of S. albus propagules under the tested conditions. This study has shown that propagules in the fine particle size range can be released in large amounts from contaminated surfaces. Measurement of the number of S. albus fragments in the vicinity of a contaminated area, as an alternative to conventional air or surface sampling, appears to be a promising approach for quantitative exposure assessment.

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Author Information and Other Publications Notes
G¨®rny, R. L.
     
Mainelis, G.
  1. Bioaerosol collection by a new electrostatic precipitator
  2. Collection of airborne microorganisms by a new electrostatic precipitator
  3. Collection of airborne spores by circular single-stage impactors with small jet-to-plate distance  
Grinshpun, S. A.
  1. Aerodynamic versus physical size of spores: measurement and implication for respiratory deposition
  2. Aerosol characteristics of airborne actinomycetes and fungi
  3. Bioaerosol collection by a new electrostatic precipitator
  4. Characteristics of airborne actinomycete spores
  5. Collection of airborne microorganisms by a new electrostatic precipitator
  6. Collection of airborne spores by circular single-stage impactors with small jet-to-plate distance
  7. Collection of bioaerosol particles by impaction: effect of fungal spore agglomeration and bounce
  8. Collection of fungal spores on air filters and spore reentrainment from filters into air
  9. Development and evaluation of aerosol generators for biological materials
  10. Effect of impact stress on microbial recovery on an agar surface
  11. Effect of relative humidity on the aerodynamic diameter and respiratory deposition of fungal spores
  12. Evaluation of a new personal sampler for enumerating airborne spores
  13. Field Testing of New Aerosol Sampling Method With a Porous Curved Surface as Inlet
  14. Fungal fragments as indoor air biocontaminants
  15. Fungal spore source strength tester: laboratory evaluation of a new concept
  16. Improved aerosol collection by combined impaction and centrifugal motion
  17. Inlet sampling efficiency of bioaerosol samplers
  18. Long-term sampling of airbome bacteria and fungi into a non-evaporating liquid
  19. Performance characteristics of the button personal inhalable aerosol sampler
  20. Performance of Air-O-Cell, Burkard, and Button samplers for total enumeration of airborne spores
  21. Release of lead-containing particles from a wall enclosure
  22. Techniques for dispersion of microorganisms into air  
Willeke, K.
  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 bioaerosol particles by impaction: effect of fungal spore agglomeration and bounce
  6. Collection of fungal spores on air filters and spore reentrainment from filters into air
  7. Development and evaluation of aerosol generators for biological materials
  8. Effect of impact stress on microbial recovery on an agar surface
  9. Effect of relative humidity on the aerodynamic diameter and respiratory deposition of fungal spores
  10. Evaluation of a new personal sampler for enumerating airborne spores
  11. Fungal fragments as indoor air biocontaminants
  12. Improved aerosol collection by combined impaction and centrifugal motion
  13. Inlet sampling efficiency of bioaerosol samplers
  14. Long-term sampling of airbome bacteria and fungi into a non-evaporating liquid
  15. Performance characteristics of the button personal inhalable aerosol sampler
  16. Performance of Air-O-Cell, Burkard, and Button samplers for total enumeration of airborne spores
  17. Performance of bioaerosol samplers: collection characteristics and sampler design considerations
  18. Release of lead-containing particles from a wall enclosure
  19. Source strength of fungal spore aerosolization from moldy building material
  20. Techniques for dispersion of microorganisms into air  
Dutkiewicz, J.
  1. Size distribution of bacterial and fungal bioaerosols in indoor air  
Reponen, T.
  1. Aerodynamic diameters and respiratory deposition estimates of viable fungal particles in mold problem dwellings
  2. Aerodynamic versus physical size of spores: measurement and implication for respiratory deposition
  3. Aerosol characteristics of airborne actinomycetes and fungi
  4. Bioaerosol collection by a new electrostatic precipitator
  5. Characteristics of airborne actinomycete spores
  6. Collection of airborne microorganisms by a new electrostatic precipitator
  7. Collection of airborne spores by circular single-stage impactors with small jet-to-plate distance
  8. Collection of bioaerosol particles by impaction: effect of fungal spore agglomeration and bounce
  9. Collection of fungal spores on air filters and spore reentrainment from filters into air
  10. Comparison of concentrations and size distributions of fungal spores in buildings with and without mould problems
  11. Control of exposure to airborne viable microorganisms during remediation of moldy buildings; report of three case studies
  12. Development and evaluation of aerosol generators for biological materials
  13. Effect of building frame and moisture damage on microbiological indoor air quality in school buildings
  14. Effect of indoor sources on fungal spore concentrations and size distributions
  15. Effect of relative humidity on the aerodynamic diameter and respiratory deposition of fungal spores
  16. Evaluation of a new personal sampler for enumerating airborne spores
  17. Everyday activities and variation of fungal spore concentrations in indoor air
  18. Field Testing of New Aerosol Sampling Method With a Porous Curved Surface as Inlet
  19. Fungal fragments as indoor air biocontaminants
  20. Fungal spore source strength tester: laboratory evaluation of a new concept
  21. Long-term sampling of airbome bacteria and fungi into a non-evaporating liquid
  22. Performance of Air-O-Cell, Burkard, and Button samplers for total enumeration of airborne spores
  23. Personal exposures and microenvironmental concentrations of particles and bioaerosols
  24. Size distributions of airborne microbes in moisture-damaged and reference school buildings of two construction types
  25. Techniques for dispersion of microorganisms into air
  26. Total and culturable airborne bacteria and fungi in arid region flood-damaged residences
  27. Viable fungal spores as indoor aerosols  


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