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Indoor air quality assessment with respect to culturable airborne bacteria, total volatile organic compounds, formaldehyde, PM10, CO2, NO2, and O3 in underground subway stations and parking lots

  • Sung Ho Hwang
  • Wha Me ParkEmail author
Article

Abstract

We measured the concentrations of indoor pollutants (fine particulate matter (PM10)), culturable airborne bacteria (CAB), total volatile organic compounds (TVOCs), formaldehyde (HCHO), CO2, NO2, and O3 in subway stations and public parking lots at a national scale in South Korea in order to determine their possible relationships with other underground environmental factors and facility characteristics. Indoor pollutants were sampled at 59 underground facilities with a total of 187 samples in subway stations and parking lots. Kruskal–Wallis and Mann–Whitney analyses were used to examine the relationships between atmospheric pollutants at underground facilities and indoor/outdoor differences in PM10 and O3 concentrations. Underground PM10 concentrations were higher than outdoor concentrations at all underground facilities (p < 0.001), while underground O3 concentrations were lower than outdoor O3 concentrations at all underground facilities (p < 0.001).

Keywords

PM10 Culturable airborne bacteria Carbon dioxide Nitrogen dioxide Ozone 

Notes

Funding information

This research was supported by the Korea Ministry of Environment (MOE) as the Environmental Health Action Program and the Basic Science Research Program through the National Research Foundation of Korean (NRF) funded by the Ministry of Science, ICT and Future Planning (2018R1C1A1A02037363), and by the Korea government (MSIP) (NRF-2016R1C1B2016366).

References

  1. Alves CA, Calvo AI, Castro A, Fraile R, Evtyugina M, Bate-Epey E (2013) Indoor air quality in two university sports facilities. Aerosol Air Qual Res 13:1723–1730CrossRefGoogle Scholar
  2. Assimakopoulos VD, Saraga D, Helmis CG, Stathopoulou OI, Halios CH (2008) An experimental study of the indoor air quality in areas of different use. Glob Nest J 10:192–200Google Scholar
  3. Bateson TF, Schwartz J (2008) Children’s response to air pollutants. J Toxicol Environ Health A 71:238–243CrossRefGoogle Scholar
  4. Bozkurt Z et al (2015) Determination of the personal, indoor and outdoor exposure levels of inorganic gaseous pollutants in different microenvironments in an industrial city. Environ Monit Assess 187(590):1–17Google Scholar
  5. Branco PTBS, Nunes RAO, Alvim-Ferraz MCM, Martins FG, Souse SIV (2015) Children’s exposure to indoor air in urban nurseries – part II: gaseous pollutants’ assessment. Environ Res 142:662–670CrossRefGoogle Scholar
  6. Chen YY, Sung FC, Chen ML, Mao IF, Lu CY (2016) Indoor air quality in the metro system in North Taiwan. Int J Environ Res Public Health 13:1200CrossRefGoogle Scholar
  7. Chithra VS, Shiva Nagendra SM (2014) Seasonal trends of indoor particulate matter concentrations in a naturally ventilated school building. WIT Trans Ecol Environ 183:341–351CrossRefGoogle Scholar
  8. Douwes J, Thome P, Pearce N, Heederik D (2003) Bioaerosol health effect and exposure assessment: progress and prospects. Ann Occup Hyg 47(3):187–200Google Scholar
  9. Du Z, Mo J, Zhang Y (2014) Risk assessment of population inhalation exposure to volatile organic compounds and carbonyls in urban China. Environ Int 73:33–45CrossRefGoogle Scholar
  10. Elbayoumi M, Ramli NA, Yusof NFFM, Madhoun WA (2013) Spatial and seasonal variation of particulate matter (PM10 and PM2.5) in Middle Eastern classrooms. Atmos Environ 80:389–397CrossRefGoogle Scholar
  11. Fahrudin AE, Endarko E, Nasrulloh AV, Sari N (2017) Development of ozone sterilization system based microcontroller for E. Coli bacteria sterilization. J Phys Conf Ser 853:012007CrossRefGoogle Scholar
  12. Frankel M, Beko G, Timm M, Gustavsen S, Hansen EW, Madsen AM (2012) Seasonal variations of indoor microbial exposures and their relation to temperature, relative humidity, and air exchange rate. Appl Environ Microbiol 78(23):8289–8297CrossRefGoogle Scholar
  13. Gold DR, Allen G, Damokosh A, Serrano P, Hayes C, Castillejos M (1996) Comparison of outdoor and classroom ozone exposures for school children in Mexico city. J Air Waste Manage Assoc 46:335–342Google Scholar
  14. Hromadaka J, Korposh S, Partridge MC, James SW, Davis F, Crump D, Tatam RP (2017) Multi-parameter measurements using optical fibre long period gratings for indoor air quality monitoring. Sensor Actuators B Chem 244:217–225CrossRefGoogle Scholar
  15. Hwang SH, Kim IS, Park WM (2017) Concentrations of PM10 and airborne bacteria in daycare centers in Seoul relative to indoor environmental factors and daycare center characteristics. Air Qual Atmos Health 10(2):139–145CrossRefGoogle Scholar
  16. Hwang SH, Roh J, Park WM (2018) Evaluation of PM10, CO2, airborne bacteria, TVOCs, and formaldehyde in facilities for susceptible populations in South Korea. Environ Pollut 242:700–708CrossRefGoogle Scholar
  17. Kabrein H, Yusof MZM, Leman AM, Afandi A (2017) Improving indoor air quality and thermal comfort in office buildings by using combination filters. IOP Conf Ser: Mater Sci Eng 243:012052CrossRefGoogle Scholar
  18. Kim KY, Jeong YI, Kim CN (2007) Distribution of airborne microorganism in the foodstuff manufacture factory. JKSOEH 17(4):335–342Google Scholar
  19. Kim KY, Kim YS, Roh YM, Lee CM, Kim CY (2008) Spatial distribution of particulate matter (PM10 and PM2.5) in Seoul metropolitan subway stations. J Hazard Mater 154(1–3):440–444CrossRefGoogle Scholar
  20. Madureira J, Paciencia I, Rufo J, Severo M, Ramos E, Barros H, Fernandes EO (2016) Source apportionment of CO2, PM10 and VOCs levels and health risk assessment in naturally ventilated primary school in Porto, Portugal. Build Environ 96:198–205CrossRefGoogle Scholar
  21. Martins V, Moreno T, Minguillon MC, Amato FA, Miguel Ed, Capdevila M, Querol X (2015) Exposure to airborne particulate matter in the subway system. Sci Total Environ 511:711–722CrossRefGoogle Scholar
  22. Masih A, Lall AS, Taneja A, Singhvi R (2017) Exposure profiles, seasonal variation and health risk assessment of BTEX in indoor air of homes at different microenvironments of a terai province of northern India. Chemosphere.  https://doi.org/10.1016/j.chemosphere.2017.02.105
  23. Mendell MJ, Heath GA (2005) Do indoor pollutants and thermal conditions inschools influence student performance? A critical review of the literature. Indoor Air 15:27–52CrossRefGoogle Scholar
  24. Mendes A, Bonassi S, Aguiar L, Pereira C, Neves P, Silva S, Mendes D, Guimaraes L, Moroni R, Teixeira JP (2014) Indoor air quality and thermal comfort in elderly care centers. Urban Climate 14:486–501CrossRefGoogle Scholar
  25. Ministry of Environment of Korea (2015) Indoor air quality management in public facilities Indoor Air Quality Management Act AmendmentGoogle Scholar
  26. Moschandreas D, Pagilla KR, Storino LV (2003) Time and space uniformity of indoor bacteria concentrations in Chicago area residences. Aerosol Sci Technol 37:899–906CrossRefGoogle Scholar
  27. Pekárek S (2003) Non-thermal plasma ozone generation. Acta Polytech 43(6)Google Scholar
  28. Rogers WJ (2012) Sterilisation techniques for polymers. Sterilisation of Biomaterials and Medical Devices, pp 151–211Google Scholar
  29. Tham KW (2016) Indoor air quality and its effects on humans-a review of challenges and developments in the last 30 years. Energ Buildings 130:637–650CrossRefGoogle Scholar
  30. Tsai DH, Lin JS, Chan CC (2012) Office workers' sick building syndrome and indoor carbon dioxide concentrations. J Occup Environ Hyg 9:345–351Google Scholar
  31. WHO (World Health Organization) (2000) Air quality guidelines for Europe 2000, vol 91, 2nd edn. WHO Regional Publications, European Series, Copenhagen, p 288Google Scholar
  32. WHO (World Health Organization) (2013) Health effects of particulate matter: policy implications for Countries in Eastern Europe, Caucasus and Central Asia Regional Office for Europe, UN City, Marmorvej 51, DK–2100 CopenhagenGoogle Scholar
  33. Womack AM, Bohannan BJM, Green JL (2010) Biodiversity and biogeography of the atmosphere. Philos Trans R Soc B 365:3645–3653CrossRefGoogle Scholar
  34. Yang J, Nam I, Yun H, Kim J, Oh HJ, Lee D, Jeon SM, Yoo SH, Sohn JR (2015) Characteristics of indoor air quality at urban elementary schools in Seoul, Korea: assessment of effect of surrounding environments. Atmos Pollut Res 6:1113–1112CrossRefGoogle Scholar

Copyright information

© Springer Media B.V., onderdeel van Springer Nature 2019

Authors and Affiliations

  1. 1.National Cancer Control Institute, National Cancer CenterGoyang-siSouth Korea
  2. 2.The Institute for Occupational HealthYonsei University College of MedicineSeoulSouth Korea
  3. 3.Graduate School of Public HealthYonsei UniversitySeoulSouth Korea

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