Indoor dust composition of university laboratories and potential health risks in Pahang, Malaysia

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Fazrul Razman Sulaiman
Tuan Nur Haziqah Tuan Roslin
Noorzamzarina Sulaiman
Ismaniza Ismail

Abstract

Dust pollution poses a significant risk to human health and natural systems, and has a substantial impact on the overall quality of both outdoor and indoor air. Dust also plays a crucial role in transporting metal elements in an indoor environment. This study examines the levels of specific metals (Al, Fe, Cu, Pb, Zn) present in dust samples collected from two laboratories in UiTM Cawangan Pahang, Malaysia. The analysis focuses on assessing pollution levels and potential impacts on human health. The concentrations of metal were significantly higher in Lab 2. Moderate enrichment of Zn was found in the indoor dust samples. Both laboratories showed that the major route of exposure to metals posing health risks was ingestion, followed by skin contact and inhalation, for individuals of all age groups, including adults and children. Zn and Pb exhibited higher potential non-cancer risk than Fe and Cu. The hazard index (HI) and lifetime cancer risk (LCR) were within acceptable thresholds (HI < 1 and 10–6 < LCR < 10–4) in both laboratories.

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Ajayi OO, Aborode AT, Orege JI, Oyewumi TO, Othmani A, Adegbola MA, Orege OB. 2023. Bio-accessibility and health risk assessment of some selected heavy metals in indoor dust from higher institutions in Ondo State, Nigeria. Environmental Science and Pollution Research, 30, 25256–25264

Asvad SR, Esmaili-Saria A, Bahramifara N, Behroozb RD, Paschalidouc AK, Kaskaouti DG. 2023. Heavy metals contamination status and health risk assessment of indoor and outdoor dust in Ahvaz and Zabol cities, Iran. Atmospheric Pollution Research, 14, 101727

ATSDR (Agency for Toxic Substances and Disease Registry). 2005. https://www.atsdr.cdc.gov/toxprofiledocs/index.html

Branis M, Rezacova P, Domasova M. 2005. The effect of outdoor air and indoor human activity on mass concentrations of PM10, PM2.5, and PM1 in a classroom. Environmental Research, 99, 143–149.

Cao S, Chen X, Zhang L, Xing X, Wen D, Wang B, Qin N, Wei F, Duan X. 2020. Quantificational exposure, sources, and health risks posed by heavy metals in indoor and outdoor household dust in a typical smelting area in China. Indoor Air, 30, 872–884.

Chabukdhara M, Nema AK. 2013. Heavy metals assessment in urban soil around industrial clusters in Ghaziabad, India: probabilistic health risk approach. Ecotoxicology and Environmental Safety, 87, 57-64.

Clarke CE, Mohammed FK, Hamid A, Bent G-A. 2022. Quantification and health risk assessment of heavy metals in residual floor dust at an indoor firing range: a case study in Trinidad, WI. International Journal of Environmental Health Research, 32, 652–664.

Fan X, Lu X, Yu B, Zuo L, Fan P, Yang Y, Zhuang S, Liu H, Qin Q. 2021. Risk and sources of heavy metals and metalloids in dust from university campuses: A case study of Xi’an, China. Environmental Research, 202, 111703

Guney M, Zagury GJ, Dogan N, Onay TT. 2010. Exposure assessment and risk characterization from trace elements following soil ingestion by children exposed to playgrounds, parks and picnic areas. Journal of Hazardous Materials, 182 (1–3), 656–664

Guo G, Wu F, Xie F, Zhang R. 2012. Spatial distribution and pollution assessment of heavy metals in urban soils from southwest China. Journal of Environmental Science, 24(3), 410–418.

Han S, Bian H, Feng Y, Liu A, Li X, Zeng F, Zhang X. 2011. Analysis of the relationship between O3, NO and NO2 in Tianjin, China. Aerosol and Air Quality Research, 11(2), 128–139.

Harb MK, Ebqa’ai M, Al-Rashidi A, Alaziqi BH, Alrashidi MS, Ibrahim B. 2015. Investigation of selected heavy metals in street and house dust from Al- Qunfudah, Kingdom of Saudi Arabia. Environmental Earth Sciences, 74, 1755–1763.

Hassan SKM. 2012. Metal concentrations and distribution in the household, stairs and entryway dust of some Egyptian homes. Atmospheric Environment, 54, 207–215.

Hu X, Zhang Y, Ding Z, Wang T, Lian H, Sun Y, Wu J. 2012. Bioaccessibility and health risk of arsenic and heavy metals (Cd, Co, Cr, Cu, Ni, Pb, Zn and Mn) in TSP and PM2.5 in Nanjing, China. Atmospheric Environment, 57, 146–152.

Kelepertzis E, Chrastný V, Botsouc F, Sigala E, Kypritidoua Z, Komárek M, Skordas K, Argyraki A. 2021. Tracing the sources of bioaccessible metal(loid)s in urban environments: A multidisciplinary approach. Science of the Total Environment, 771, 144827

Latif MT, Othman MR, Kim CL, Murayadi SA, Sahaimi KNA. 2009. Composition of household dust in semi-urban areas in Malaysia. Indoor and Built Environment, 18, 155–161.

Latif MT, Baharudin NH, Velayutham P, Awang N, Hamdan H, Mohamad R, Mokhtar M. 2011. Composition of heavy metals and airborne fibers in the indoor environment of a building during renovation. Environmental Monitoring and Assessment, 181, 479–489.

Latif MT, Saw MY, Saad A, Mohamad N, Baharudin NF, Mokhtar M, Mohd-Tahir N. 2014. Composition of heavy metals in indoor dust and their possible exposure: A case study of preschool children in Malaysia. Air Quality, Atmosphere and Health, 7, 181–193.

Lopez-Aparicio S, Smolk J, Maskova L, Souckova M, Grøntoft T, Ondrackova L, Stankiewicz J. 2011. Relationship of indoor and outdoor air pollutants in a naturally ventilated historical building envelope. Building and Environment, 4, 1460–1468.

Massey D, Kulshrestha A, Masih J, Taneja A. 2012. Seasonal trends of PM10, PM5.0, PM2.5 & PM1.0 in indoor and outdoor environments of residential homes located in North- Central India. Building and Environment, 47, 223–231.

Massey D, Kulshrestha A, Taneja A. 2013. Particulate matter concentrations and their related metal toxicity in rural residential environment of semi-arid region of India. Atmospheric Environment, 67, 278–286.

Matson U. 2005. Indoor and outdoor concentrations of ultrafine particles in some Scandinavian rural and urban areas. Science of the Total Environment, 343, 169–176.

McAlister JJ, Smith BJ, Torok A. 2008. Transition metals and water-soluble ions in deposits on a building and their potential catalysis of stone decay. Atmospheric Environment, 42, 7657–7668.

Mohamad N, Latif MT, Khan MF. 2016. Source apportionment and health risk assessment of PM10 in a naturally ventilated school in a tropical environment. Ecotoxicology and Environmental Safety, 124, 351–362.

Nazir R, Shaheen N, Shah MH. 2011. Indoor/outdoor relationship of trace metal in the atmosphere particulate matter of an industrial area. Atmospheric Research, 101(3), 765–772.

Raysoni AU, Stock TH, Sarnat JA, Sosa TM, Sarnat SE, Holguin F, Greenwald R, Johnson B, Li WW. 2013. Characterization of traffic-related air pollutant metrics at four schools in El Paso, Texas, USA: Implications for exposure assessment and siting schools in urban areas. Atmospheric Environment, 80,140–151.

Sloan CD, Andrew AS, Gruber JF, Mwenda KM, Moore JH, Onega T, Karagas MR, Shi X, Duell EJ. 2012. Indoor and outdoor air pollution and lung cancer in New Hampshire and Vermont. Toxicological and Environmental Chemistry, 94, 605–615

Srithawirat T, Latif MT, Sulaiman FR. 2016. Indoor PM10 and its heavy metal composition at a roadside residential environment, Phitsanulok, Thailand. Atmósfera, 29 (4), 311-322

Sulaiman FR, Bakri NIF, Nazmi N, Latif MT. 2017. Assessment of heavy metal in indoor dust of a university in tropical environment. Environmental Forensics, 18 (1), 74-82

Sulaiman FR, Suratmin MA. 2020. Composition of metal in indoor dust from university laboratories. Malaysian Journal of Medicine and Health Science, 16 (Supp 11), 28-32

USDOE (United States Department of Energy). 2011. The Risk Assessment Information System (RAIS), U.S. Department of Energy, Washington. DE-AC05-96OR22464.

USEPA (United States Environmental Protection Agency). 2011. Integrated Risk Information System (IRIS). Washington, DC: U.S. Environmental Protection Agency.

USEPA (United States Environmental Protection Agency). 2002. Supplemental guidance for developing soil screening levels for superfund sites. Office of Emergency and Remedial Response, Washington. https://rais.ornl.gov/documents/SSG_nonrad_ supplemental.pdf.

Wang H, Cai L, Wang S, Hu G, Chen L. 2021. A comprehensive exploration on pollution characteristics and health risks of potentially toxic elements in indoor dust from a large Cu smelting area, Central China. Environmental Science and Pollution Research, 28, 57569–57581.

Yang Razali NY, Latif MT, Dominick D, Mohamad N, Sulaiman FR, Srithawirat T. 2015. Concentration of particulate matter, CO and CO2 in selected schools in Malaysia. Building and Environment, 87, 108–116.

Zhao X, Li Z, Wang D, Tao Y, Qiao F, Lei L, Huang J, Ting Z. 2021. Characteristics, source apportionment and health risk assessment of heavy metals exposure via household dust from six cities in China. Science of the Total Environment, 762.

Zhong JNM, Latif MT, Mohamad N, Abd-Wahid NB, Dominick D, Juahir H. 2014. Source apportionment of particulate matter (PM10) and indoor dust in a university building. Environmental Forensics, 15(1), 8–16.