The Mycometer products are based on a well-documented technology. Independent, as well as scientists from Mycometer have published and are currently publishing papers on the technology in peer reviewed well reputed international journals and at scientific conferences. The technology has gone through the ETV (Environmental Technology Verification) program United States Environmental Agency (US-EPA´s). However, the best documentation is the fact that our customers keep coming back for more products and sales have been increasing every year since we started.


  • Airborne fungal cell fragments in homes in relation to total fungal biomass. Adhikan A, Reponen T. Rylander R. Indoor Air 2012; in print.
  • Nocturnal asthma and domestic exposure to fungi. Terčelj M, Salobir B, Narancsik Z, Kriznar K, Grzetic-Romcevic T, Matos T, Rylander R. Indoor + Built Env. 2012; in print.
  • Enzyme measurements for risk evaluations in sewage treatment plants. Rylander R, Calo A. Open J Publ Health, Jun 2012.
  • Beyond LEED, Pre and Post Occupancy Evaluations for New Buildings. P Buckmaster. Synergist, May 2011.
  • Assessment of the Bacterial Contamination and Remediation Efficacy after Flooding Using Fluorometric Detection. M. Reeslev, JC Nielsen, L Rogers. Accepted for publication ASTM Journal, 2011.
  • Aggressive Sampling, Improving the Predictive Value of Air Sampling for Fungal Aerosols. M. Reeslev, M. Miller, JC Nielsen, L Rogers. Proceedings of Indoor Air Conference, ISIAQC. June 2011, Austin Texas.
  • Airborne enzyme in homes of patients with sarcoidosis. Terčelj M, Salobir B, Rylander R. Env Health 2011; 10; 8-13.
  • Airborne enzyme measurements for the identification of mouldy buildings. Rylander R, Reeslev M, Hulander T. . . J Environ Monit, 2010; 12:2161-2164.
  • Fluorometric detection and estimation of fungal biomass on cultural heritage materials. Journal of Microbiological Methods 80 (2010) 178–182, R Mitchell, et al (Harvard) 2010.
  • Airborne enzyme measurements to detect indoor mould exposure. Journal of Environmental Monitoring, V.12, p.2161–2164. R. Rylander, et al. 2010.
  • Successful Mold Growth Remediation in HVAC Systems. P Buckmaster. Occupational Health and Safety, January 2008.
  • Quantifying Mold Biomass on Gypsum Board: Comparison of Ergosterol and Beta-N-Acetylhexosaminidase as Mold Biomass Parameters. Applied and Environmental Microbiology. Vol. 69, No.7, p. 3996-3998. M.Reeslev, M.Miller, KF Nielsen. 2003. 
  • Analytical Instrument Performance Criteria: Application of a Fluorometric Method for the Detection of Mold in Indoor Environments. Applied Occupational and Environmental Hygiene. Vol. 18, No.7, p. 499-503. D Krause, YY Hamad, L Ball. 2003.
  • Application of a Fluorometric Method for the Detection of Mold in Indoor Environments. (2003), D. Krause. Applied Occupational and Environmental Hygiene Volume 18(7): 1–5.
  • Nagase Activity in Airborne Biomass Dust and Relationship between Nagase Concentrations and Fungal Spores. Aerobiologia Vol. 19, 97 – 105. A.M., Madsen. 2003.
  • The Mycometer™-Test: A New Rapid Method for Detection and Quantification of Mold in Buildings. Proceedings of Healthy Buildings 2000, Vol. 1, p.589-590. M.Reeslev and M. Miller. 2000.
  • Fluorogenic Substrates to Measure Fungal Presence and Activity in Soil. Appl. Environ. Microbiol. 64:613-617. M. Miller, A. Palojärvi, A. Rangger, M. Reeslev, A. Kjøller. 1998.

Mycometer-surface Applications

  • Post remediation verification (PRV)
  • Documenting the efficacy of the cleaning of surfaces for mould growth
  • Documentation of mould growth
  • Documentation that discoloration is NOT mould growth
  • Delineation of mould growth where it is non-visible. How much should be cleaned?
  • Documenting the cleaning of HVAC systems