Evaluation of Negative Air Ions in Bioaerosol Removal: Indoor Concentration of Airborne Bacterial and Fungal in Residential Building in Qom City, Iran
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Evaluation of Negative Air Ions in Bioaerosol Removal: Indoor Concentration of Airborne Bacterial and Fungal in Residential Building in Qom City, Iran

Authors: Z. Asadgol, A. Nadali, H. Arfaeinia, M. Khalifeh Gholi, R. Fateh, M. Fahiminia

Abstract:

The present investigation was conducted to detect the type and concentrations of bacterial and fungal bioaerosols in one room (bedroom) of each selected residential building located in different regions of Qom during February 2015 (n=9) to July 2016 (n=11). Moreover, we evaluated the efficiency of negative air ions (NAIs) in bioaerosol reduction in indoor air in residential buildings. In the first step, the mean concentrations of bacterial and fungal in nine sampling sites evaluated in winter were 744 and 579 colony forming units (CFU)/m3, while these values were 1628.6 and 231 CFU/m3 in the 11 sampling sites evaluated in summer, respectively. The most predominant genera between bacterial and fungal in all sampling sites were detected as Micrococcus spp. and Staphylococcus spp. and also, Aspergillus spp. and Penicillium spp., respectively. The 95% and 45% of sampling sites have bacterial and fungal concentrations over the recommended levels, respectively. In the removal step, we achieved a reduction with a range of 38% to 93% for bacterial genera and 25% to 100% for fungal genera by using NAIs. The results suggested that NAI is a highly effective, simple and efficient technique in reducing the bacterial and fungal concentration in the indoor air of residential buildings.

Keywords: Bacterial, fungal, negative air ions, indoor air, Iran.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1316177

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References:


[1] Crawford JA, Rosenbaum PF, Anagnost SE, Hunt A, Abraham JL. Indicators of airborne fungal concentrations in urban homes: understanding the conditions that affect indoor fungal exposures. Science of the total environment. 2015;517:113-24.
[2] Sarkhosh M, Mahvi AH, Zare MR, Fakhri Y, Shamsolahi HR. Indoor contaminants from hardcopy devices: characteristics of VOCs in photocopy centers. Atmospheric environment. 2012;63:307-12.
[3] Nasir ZA, Colbeck I, Sultan S, Ahmed S. Bioaerosols in residential micro-environments in low income countries: a case study from Pakistan. Environmental pollution. 2012;168:15-22.
[4] Srikanth P, Sudharsanam S, Steinberg R. Bio-aerosols in indoor environment: composition, health effects and analysis. Indian journal of medical microbiology. 2008;26(4):302.
[5] Gilbert Y, Duchaine C. Bioaerosols in industrial environments: a review. Journal of Environmental Engineering and Science. 2014;9(1):4-19.
[6] Després VR, Huffman JA, Burrows SM, Hoose C, Safatov AS, Buryak G, et al. Primary biological aerosol particles in the atmosphere: a review. Tellus B. 2012;64.
[7] Van Leuken J, Swart A, Havelaar A, Van Pul A, Van der Hoek W, Heederik D. Atmospheric dispersion modelling of bioaerosols that are pathogenic to humans and livestock–A review to inform risk assessment studies. Microbial Risk Analysis. 2015.
[8] Wéry N. Bioaerosols from composting facilities—a review. Frontiers in cellular and infection microbiology. 2014;4.
[9] Aydogdu H, Asan A, Otkun MT. Indoor and outdoor airborne bacteria in child day-care centers in Edirne City (Turkey), seasonal distribution and influence of meteorological factors. Environmental monitoring and assessment. 2010;164(1-4):53-66.
[10] Bornehag C, Blomquist G, Gyntelberg F, Järvholm B, Malmberg P, Nordvall L, et al. Nordic interdisciplinary review of the scientific evidence on associations between exposure to’Dampness’ in buildings and health effects. Indoor Air. 2001;13:72-86.
[11] Mendell MJ, Mirer AG, Cheung K, Tong M, Douwes J. Respiratory and allergic health effects of dampness, mold, and dampness-related agents: a review of the epidemiologic evidence. Environ Health Perspect. 2011;119(6):748-56.
[12] Burge H, Feeley J, Kreiss K, Milton D, Morey P, Otten J, et al., editors. Guidelines for the Assessment of Bioaerosols in the Indoor Environment. American Conference of Governmental Industrial Hygienists, Cincinnati, OH; 1989.
[13] Kowalski W. Aerobiological engineering handbook: airborne disease and control technologies: McGraw Hill Professional; 2005.
[14] Mentese S, Rad AY, Arısoy M, Güllü G. Seasonal and spatial variations of bioaerosols in indoor urban environments, Ankara, Turkey. Indoor and Built Environment. 2012;21(6):797-810.
[15] Ayoko GA, Morawska L, Kokot S, Gilbert D. Application of multicriteria decision making methods to air quality in the microenvironments of residential houses in Brisbane, Australia. Environmental science & technology. 2004;38(9):2609-16.
[16] Barnes CS, Dowling P, Van Osdol T, Portnoy J. Comparison of indoor fungal spore levels before and after professional home remediation. Annals of Allergy, Asthma & Immunology. 2007;98(3):262-8.
[17] Yun SJ, Seo Y. Removal of bacteria and odor gas by an alumina support catalyst and negative air ions. Journal of Aerosol Science. 2013;58:33-40.
[18] Oren I, Haddad N, Finkelstein R, Rowe JM. Invasive pulmonary aspergillosis in neutropenic patients during hospital construction: before and after chemoprophylaxis and institution of HEPA filters. American journal of hematology. 2001;66(4):257-62.
[19] Cho MS, Ko HJ, Kim D, Kim KY. On-site application of air cleaner emitting plasma ion to reduce airborne contaminants in pig building. Atmospheric environment. 2012;63:276-81.
[20] Levetin E, Shaughnessy R, Rogers CA, Scheir R. Effectiveness of germicidal UV radiation for reducing fungal contamination within air-handling units. Applied and environmental microbiology. 2001;67(8):3712-5.
[21] Tyagi A, Malik A. Antimicrobial action of essential oil vapours and negative air ions against Pseudomonas fluorescens. International journal of food microbiology. 2010;143(3):205-10.
[22] Arnold L, Boothe D, Mitchell B. Use of negative air ionization for reducing bacterial pathogens and spores on stainless steel surfaces. The Journal of Applied Poultry Research. 2004;13(2):200-6.
[23] Climate-Data.Org. Available from: https://en.climate-data.org/location/956725/.
[24] Niazi S, Hassanvand MS, Mahvi AH, Nabizadeh R, Alimohammadi M, Nabavi S, et al. Assessment of bioaerosol contamination (bacteria and fungi) in the largest urban wastewater treatment plant in the Middle East. Environmental Science and Pollution Research. 2015;22(20):16014-21.
[25] Hassanvand MS, Naddafi K, Faridi S, Arhami M, Nabizadeh R, Sowlat MH, et al. Indoor/outdoor relationships of PM 10, PM 2.5, and PM 1 mass concentrations and their water-soluble ions in a retirement home and a school dormitory. Atmospheric Environment. 2014;82:375-82.
[26] Lee J-H, Jo W-K. Characteristics of indoor and outdoor bioaerosols at Korean high-rise apartment buildings. Environmental research. 2006;101(1):11-7.
[27] Hoseini M, Jabbari H, Naddafi K, Nabizadeh R, Rahbar M, Yunesian M, et al. Concentration and distribution characteristics of airborne fungi in indoor and outdoor air of Tehran subway stations. Aerobiologia. 2013;29(3):355-63.
[28] Naddafi K, Jabbari H, Hoseini M, Nabizadeh R, Rahbar M, Yunesian M. Investigation Of Indoor And Outdoor Air Bacterial Density In Tehran Subway System. Iranian Journal of Environmental Health Science & Engineering (IJEHSE). 2011;8(4).
[29] Andersen AA. New sampler for the collection, sizing, and enumeration of viable airborne particles. Journal of Bacteriology. 1958;76(5):471.
[30] Faridi S, Hassanvand MS, Naddafi K, Yunesian M, Nabizadeh R, Sowlat MH, et al. Indoor/outdoor relationships of bioaerosol concentrations in a retirement home and a school dormitory. Environmental Science and Pollution Research. 2015;22(11):8190-200.
[31] Gaunt L, Higgins S, Hughes J. Interaction of air ions and bactericidal vapours to control micro‐organisms. Journal of applied microbiology. 2005;99(6):1324-9.
[32] Standard A. Ventilation for acceptable indoor air quality. Atlanta. 1989;62:1989.
[33] Burge H, Chew G, Muilenberg M, Gold D, editors. Role of fungi in-house dust ecosystems. Journal of Allergy and Clinical Immunology; 1995: Mosby-Year Book INC 11830 Westline Industrial DR, ST Louis, MO 63146-3318.
[34] Bonetta S, Bonetta S, Mosso S, Sampò S, Carraro E. Assessment of microbiological indoor air quality in an Italian office building equipped with an HVAC system. Environmental monitoring and assessment. 2010;161(1):473-83.
[35] Hussin NHM, Sann LM, Shamsudin MN, Hashim Z. Characterization of bacteria and fungi bioaerosol in the indoor air of selected primary schools in Malaysia. Indoor and Built Environment. 2011;20(6):607-17.
[36] Parat S, Perdrix A, Mann S, Baconnier P. Contribution of particle counting in assessment of exposure to airborne microorganisms. Atmospheric Environment. 1999;33(6):951-9.
[37] Hsu Y-C, Kung P-Y, Wu T-N, Shen Y-H. Characterization of indoor-air bioaerosols in Southern Taiwan. Aerosol Air Qual Res. 2012;12:651-61.
[38] Fang Z, Gong C, Ouyang Z, Liu P, Sun L, Wang X. Characteristic and concentration distribution of culturable airborne bacteria in residential environments in Beijing, China. Aerosol Air Qual Res. 2014;14(3):943-53.
[39] Pastuszka JS, Paw UKT, Lis DO, Wlazło A, Ulfig K. Bacterial and fungal aerosol in indoor environment in Upper Silesia, Poland. Atmospheric Environment. 2000;34(22):3833-42.
[40] Mandal J, Brandl H. Bioaerosols in indoor environment-a review with special reference to residential and occupational locations. The Open Environmental & Biological Monitoring Journal. 2011;4(1).
[41] Shargawi J, Theaker E, Drucker D, MacFarlane T, Duxbury A. Sensitivity of Candida albicans to negative air ion streams. Journal of applied microbiology. 1999;87(6):889-97.
[42] Pratt R, Barnard RW. Some effects of ionized air on Penicillium notatum. Journal of Pharmaceutical Sciences. 1960;49(10):643-6.
[43] Tyagi AK, Malik A. Bactericidal action of lemon grass oil vapors and negative air ions. Innovative Food Science & Emerging Technologies. 2012;13:169-77.
[44] Cai K, Liu X, Xu Y, Ren C, Chen H, Xu J, et al. Damage effects induced by electrically generated negative air ions in Caenorhabditis elegans. Science of the total environment. 2008;401(1):176-83.
[45] Yu K-P, Lee GW-M, Lin S-Y, Huang CP. Removal of bioaerosols by the combination of a photocatalytic filter and negative air ions. Journal of Aerosol Science. 2008;39(5):377-92.
[46] Fletcher LA, Gaunt LF, Beggs CB, Shepherd SJ, Sleigh PA, Noakes CJ, et al. Bactericidal action of positive and negative ions in air. BMC microbiology. 2007;7(1):32.
[47] Fan L, Song J, Hildebrand P, Forney C. Interaction of ozone and negative air ions to control micro‐organisms. Journal of applied microbiology. 2002;93(1):144-8.