The ability of A. versicolor to grow and produce volatile metabolites, carbon dioxide, and microbial volatile organic compounds (MVOC) in house dust, was investigated. First, signs of metabolic activity were detected after 7 d at relative humidity (RH) of air of 84-86% and after 2 d at RH of 96-98%. Within four weeks, the concentration of A. versicolor spores increased almost 100 fold at the lower RH and over 600 fold at the higher RH. However, after the fast rising at the beginning of the incubation, CO2 concentration became steady probably because of the depletion of favourable carbon sources. MVOC were analyzed by gas chromatography with thermal desorption and mass selective detector and high pressure liquid chromatography. The results revealed that A. versicolor can utilize various hydrocarbons and fatty acids in house dust. Some MVOC were also formed as a result of the biosynthesis of amino acids. The main MVOC were 2-ethyl-1-hexanol, 1-octen-3-ol, 3-octanone, 2-heptanone, 2-pentanone, 2-hexanone, and 2-methylfuran. The last three compounds have not been presented earlier as volatile metabolites of this fungus.

• fungi: assessment, sampling and analysis
• fungi: components and products
• fungi: MVOC - microbial volatile organic compound

1. Can microbial volatile metabolites cause irritation at indoor air concentrations?
2. Effect of duct-cleaning detergents and disinfection substances on mould growth
3. Ergosterol content in various fungal species and biocontaminated building materials
4. Fungal growth on wood surfaces at different moisture conditions in crawl spaces
5. Fungal spore transport through a building structure
6. Microbial contamination of indoor air due to leakages from crawl space- a field study
7. Significance of air humidity and air velocity for fungal spore release into the air
8. Transport of fungal spores from crawl space to indoors
9. Volatile compounds originating from mixed microbial cultures on building materials under various humidity conditions
10. Volatile organic metabolites associated with some toxic fungi end their mycotoxins  

1. Critical aspects on the significance of microbial volatile metabolites as indoor air pollutants
2. Microbial growth and metabolism in house dust  

1. Microbial growth and metabolism in house dust
2. Occurrence and moisture requirements of microbial growth in building materials  

1. A review: fungal exposure assessment in indoor environments
2. Airborne mesophilici fungal spores in various residential environments
3. Can microbial volatile metabolites cause irritation at indoor air concentrations?
4. Critical aspects on the significance of microbial volatile metabolites as indoor air pollutants
5. Effect of duct-cleaning detergents and disinfection substances on mould growth
6. Ergosterol content in various fungal species and biocontaminated building materials
7. Evaluation of indoor fungal exposure
8. Fungal growth and survival in building materials under fluctuating moisture and temperature conditions
9. Fungal microcolonies on indoor surfaces an explanation for the base-level fungal spore counts in indoor air
10. Occurrence and moisture requirements of microbial growth in building materials
11. Sensory irritating potency of some microbial volatile organic compounds (MVOCs) and a mixture of five MVOCs
12. Sensory irritation of microbially produced volatile organic compounds in mice during repeated exposures
13. Significance of air humidity and air velocity for fungal spore release into the air
14. The relationship between measured moisture conditions and fungal concentrations in water-damaged building materials
15. Volatile metabolites of Serpula lacrymans, Coniophora puteana, Poria placenta, Stachybotrys chartarum and Chaetomium globosum
16. Volatile organic metabolites associated with some toxic fungi end their mycotoxins