Alarie[8] developed an animal bioassay for the evaluation of the sensory irritating potency of airborne chemicals (including MVOCs). The method was then standardized,[9] and researchers suggested that it be used for the prediction of exposure limits for chemicals to prevent sensory irritation in humans.[10] The evaluation is based on determining the concentration of a chemical capable of producing a 50% decrease [(RD.sub.50)] in respiratory rate in mice when this decrease in respiratory rate is induced by a characteristic pause following inspiration resulting from stimulation of nasal trigeminal nerve endings. More relevant for the indoor air perspective, however, would be the determination of an airborne chemical concentration that would likely not cause any discomfort or sensory irritation---even in the most sensitive people (i.e., a recommended indoor air level [RILl). Investigators can estimate RIL from the high-exposure concentrations, which are used to determine [RD.sub.50] by applying a safety factor. For a very wide variety of chemicals, investigators have shown that their 0.03 x [RD.sub.50] correlates very well with occupational exposure level (OEL), such as threshold limit value (TLV), for 89 chemicals.[10] That level, however, might be too high, resulting from longer exposure time, for acceptable indoor air quality. The OELs are applied to 8 hr/d and 5 d/wk and are established in the interest of protecting the majority of normal adults; however, the indoor exposure time might be 4 times longer, and the major factor for consideration is that more sensitive individuals may exist. Thus, it was suggested that RILs be obtained by dividing the OEL of the chemical by a factor 40, which is the equivalent to dividing the [RD.sub.50] of the chemical by 1 333.[11,12] Moreover, investigators can evaluate the risk of irritation caused by MVOCs in moldy buildings by comparing the RILs with actual indoor air concentrations of MVOCs.[13]

In the present study, the sensory irritating potency of 3 individual MVOCs--l-octen-3-ol, 3-octanol, and 3-octanone--was evaluated in mice, and [RD.sub.50] values and RILs for these MVOCs were established. We selected these compounds because frequently they are released into indoor air during microbial growth in damp building materials,[2,14,15] and because their irritating potencies were a mystery. In addition, in an effort to reveal how MVOCs act together, we determined the [RD.sub.50] value experimentally for a mixture of 5 MVOCs that are among compounds released during microbial growth in building materials.[2] A possible role of these MVOCs as a causative agent of the irritative effects experienced by occupants in moldy houses is discussed, and we have taken into account their potency as sensory irritants and the range of exposure concentrations reported to exist...."

• fungi: health effects
• fungi: MVOC - microbial volatile organic compound : MVOC not as important

1. Can microbial volatile metabolites cause irritation at indoor air concentrations?
2. Fungal volatile metabolites and biological responses to fungal exposure
3. Sensory irritation of microbially produced volatile organic compounds in mice during repeated exposures
4. Volatile compounds originating from mixed microbial cultures on building materials under various humidity conditions
5. Volatile metabolites of Serpula lacrymans, Coniophora puteana, Poria placenta, Stachybotrys chartarum and Chaetomium globosum  

1. Inflammatory potential of the spores of Penicillium spinulosum isolated from indoor air of a moisture-damaged building in mouse lungs  

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. Growth and volatile metabolite production of Aspergillus versicolor in house dust
11. Occurrence and moisture requirements of microbial growth in building materials
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