Characterization of size-segregated PM down to UFP (PM0.1) and its trace and major elemental composition in blacksmith factories, Indonesia

Rinda Andhita Regia; Katharina Oginawati; Suharyanto; Dewi Sumaryani Soemarko; Muhammad Amin; Muhayatun Santoso

doi:10.20517/jeea.2025.37

Journal of Environmental Exposure Assessment ›› 2025, Vol. 4 ›› Issue (4) :38 DOI: 10.20517/jeea.2025.37

Research Article

Characterization of size-segregated PM down to UFP (PM_0.1) and its trace and major elemental composition in blacksmith factories, Indonesia

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Abstract

This study examines the size-segregated particulate matter (PM) concentrations in blacksmith workshops (WSs) in West Java, Indonesia, using the Ambient Nano Sampler (ANS). PM was categorized into six size fractions: > 10 µm, 10-2.5 µm, 2.5-1 µm, 1-0.5 µm, 0.5-0.1 µm, and < 0.1 µm (ultrafine particles, UFPs). The results showed that WSs with intensive welding activities had the highest ultrafine PM concentrations. WS-A recorded the highest total suspended particle (TSP) concentration (3,504.58 µg/m³), with UFPs contributing 998.27 µg/m³ (37% of PM_2.5), while WS-B had the lowest TSP concentration (1,978.16 µg/m³). The ratio of PM < 0.1 to PM_2.5 ranged from 0.26 to 0.42, demonstrating the dominance of UFPs in fine PM fractions. Outdoor UFP levels (4.64 µg/m³) were significantly lower than indoor concentrations, confirming that blacksmithing activities are a major emission source. Heavy metal analysis revealed iron (Fe) as the dominant element (up to 284.775 µg/m³ in UFPs), with Cr, Pb, and Mn also detected, highlighting occupational exposure risks. These findings indicate that blacksmith WSs generate significantly higher UFP and metal emissions than ambient environments, posing potential health hazards for workers. This study underscores the need for effective air quality management in small-scale metal industries.

Keywords

PM_0.1 / size-segregated PMs / blacksmith factories / indoor air quality / heavy metals / Indonesia

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Rinda Andhita Regia, Katharina Oginawati, Suharyanto, Dewi Sumaryani Soemarko, Muhammad Amin, Muhayatun Santoso. Characterization of size-segregated PM down to UFP (PM_0.1) and its trace and major elemental composition in blacksmith factories, Indonesia. Journal of Environmental Exposure Assessment, 2025, 4(4): 38 DOI:10.20517/jeea.2025.37

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Fujii H.Economic development and multiple air pollutant emissions from the industrial sector.Environ Sci Pollut Res Int2016;23:2802-12

[2]	Kelly FJ.Air pollution and public health: emerging hazards and improved understanding of risk.Environ Geochem Health2015;37:631-49 PMCID:PMC4516868

[3]	Manisalidis I,Stavropoulos A.Environmental and health impacts of air pollution: a review.Front Public Health2020;8:14 PMCID:PMC7044178

[4]	Holme JA,Machala M.Lung cancer associated with combustion particles and fine particulate matter (PM_2.5) - the roles of polycyclic aromatic hydrocarbons (PAHs) and the aryl hydrocarbon receptor (AhR).Biochem Pharmacol2023;216:115801 PMCID:PMC10543654

[5]	Molina L.Biochemical and metabolic plant responses toward polycyclic aromatic hydrocarbons and heavy metals present in atmospheric pollution.Plants (Basel)2021;10:2305 PMCID:PMC8622723

[6]	Morakinyo OM,Mukhola MS.Health outcomes of exposure to biological and chemical components of inhalable and respirable particulate matter.Int J Environ Res Public Health2016;13:592 PMCID:PMC4924049

[7]	Valavanidis A,Vlachogianni T.Airborne particulate matter and human health: toxicological assessment and importance of size and composition of particles for oxidative damage and carcinogenic mechanisms.J Environ Sci Health C Environ Carcinog Ecotoxicol Rev2008;26:339-62

[8]	Bauleo L,Antonucci C.Long-term exposure to air pollutants from multiple sources and mortality in an industrial area: a cohort study.Occup Environ Med2019;76:48-57 PMCID:PMC6327870

[9]	Fang SC,Christiani DC.A systematic review of occupational exposure to particulate matter and cardiovascular disease.Int J Environ Res Public Health2010;7:1773-806 PMCID:PMC2872342

[10]	Waidyatillake NT,Vicendese D,Curto A.Particulate matter and premature mortality: a Bayesian meta-analysis.Int J Environ Res Public Health2021;18:7655 PMCID:PMC8303514

[11]	Environment Agency (EEA). Air quality in Europe - 2020 report.EEA Report2020;

[12]	Apte JS,Cohen AJ,Pope CA.Ambient PM_2.5 reduces global and regional life expectancy.Environ Sci Technol Lett2018;5:546-51

[13]	Kumar S.Interrelationship of indoor particulate matter and respiratory dust depositions of women in the residence of Dhanbad City, India.Environ Sci Pollut Res Int2022;29:4668-89

[14]	World Health Organization (WHO). WHO Global Air Quality Guidelines: Particulate Matter (PM2.5 and PM10), ozone, nitrogen dioxide, sulfur dioxide, and carbon monoxide. 2021. Available from: https://www.who.int/publications/i/item/9789240034228/ (accessed on 2025-9-15)

[15]	Silveira Fleck A, Sadoine ML, Buteau S, Suarthana E, Debia M, Smargiassi A. Environmental and occupational short-term exposure to airborne particles and FEV(1) and FVC in healthy adults: a systematic review and meta-analysis.Int J Environ Res Public Health2021;18:10571 PMCID:PMC8536058

[16]	Sekhavati E.Particulate matter exposure in construction sites is associated with health effects in workers.Front Public Health2023;11:1130620 PMCID:PMC10028260

[17]	Jean-Jacques S,Ferdinand S.Oxidative potential of particles in different occupational environments: a pilot study.Ann Occup Hyg2015;59:882-94

[18]	Shezi B,Cele N,Street RA.Occupational exposure to fine particulate matter (PM₄ and PM_2.5) during hand-made cookware operation: personal, indoor and outdoor levels.Int J Environ Res Public Health2020;17:7522 PMCID:PMC7602743

[19]	Ali MU,Yousaf B.Pollution characteristics, mechanism of toxicity and health effects of the ultrafine particles in the indoor environment: current status and future perspectives.Crit Rev Environ Sci Technol2022;52:436-73

[20]	Moreno-Rangel A,McGill G.Indoor air quality in passivhaus dwellings: a literature review.Int J Environ Res Public Health2020;17:4749 PMCID:PMC7369996

[21]	Zhang M,Huang H.Seasonal variation of water-soluble inorganic ions and carbonaceous components of PM2.5 and PM1 in industrial and residential areas of Suizhou, China.Atmos Pollut Res2024;15:102276

[22]	Abdillah SFI.Ambient ultrafine particle (PM_0.1): sources, characteristics, measurements and exposure implications on human health.Environ Res2023;218:115061

[23]	Casquero-Vera JA,Titos G.Quantifying traffic, biomass burning and secondary source contributions to atmospheric particle number concentrations at urban and suburban sites.Sci Total Environ2021;768:145282

[24]	Li C,Wei X,Wu C.Health Risk Assessment of inhalable dust exposure during the welding and grinding process of subway aluminum alloy components.Buildings2023;13:2469

[25]	Rahman MM,Clifford S.Estimate of main local sources to ambient ultrafine particle number concentrations in an urban area.Atmospheric Research2017;194:178-89

[26]	Hong G.Special issue on ultrafine particles: where are they from and how do they affect us?.Exp Mol Med2020;52:309-10 PMCID:PMC7156368

[27]	Kwon HS,Carlsten C.Ultrafine particles: unique physicochemical properties relevant to health and disease.Exp Mol Med2020;52:318-28 PMCID:PMC7156720

[28]	Lai CH,Liao CC,Peng YP.Effects of heavy metals on health risk and characteristic in surrounding atmosphere of tire manufacturing plant, Taiwan.RSC Adv2018;8:3041-50 PMCID:PMC9077559

[29]	Crépeaux G,David MO.Non-linear dose-response of aluminium hydroxide adjuvant particles: selective low dose neurotoxicity.Toxicology2017;375:48-57

[30]	Gaidajis G,Gazea E.Ambient air quality at the wider area of an industrial mining facility at Stratoni, Chalkidiki, Greece.J Environ Sci Health A Tox Hazard Subst Environ Eng2012;47:1869-77

[31]	Higashikubo I,Kawamoto T.Worker's personal exposure to PM_0.1 and PM₄ titanium dioxide nanomaterials during packaging.Aerosol Air Qual Res2021;21:200606

[32]	Mutua AM,Abubakar A.Effects of iron intake on neurobehavioural outcomes in African children: a systematic review and meta-analysis of randomised controlled trials.Wellcome Open Res2021;6:181 PMCID:PMC8777511

[33]	Salih Z.Heavy metal accumulation in dust and workers’ scalp hair as a bioindicator for air pollution from a steel factory.Pol J Environ Stud2020;29:1805-13

[34]	Kong N,Wang H.Blood leukocyte count as a systemic inflammatory biomarker associated with a more rapid spirometric decline in a large cohort of iron and steel industry workers.Respir Res2021;22:254 PMCID:PMC8467242

[35]	Kornberg TG,Antonini JA.Potential toxicity and underlying mechanisms associated with pulmonary exposure to iron oxide nanoparticles: conflicting literature and unclear risk.Nanomaterials (Basel)2017;7:307 PMCID:PMC5666472

[36]	Langevin SM,Michaud DS,Nelson HH.Occupational dust exposure and head and neck squamous cell carcinoma risk in a population-based case-control study conducted in the greater Boston area.Cancer Med2013;2:978-86 PMCID:PMC3892403

[37]	Nakadate T,Adachi C.A cross sectional study of the respiratory health of workers handling printing toner dust.Occup Environ Med2006;63:244-9 PMCID:PMC2078083

[38]	Susihono W.Assessment of inhaled dust by workers and suspended dust for pollution control change and ergonomic intervention in metal casting industry: A cross-sectional study.Heliyon2020;6:e04067 PMCID:PMC7264714

[39]	Szűcs-Somlyó É,Májlinger K,Jerzsele Á.Immune response to zinc oxide inhalation in metal fume fever, and the possible role of IL-17f.Sci Rep2023;13:22239 PMCID:PMC10721908

[40]	Vella F,Matera S.Risk of pneumoconiosis in workers exposed to crystalline silica from lava rock dust from Mount Etna.J Clin Med2025;14:3781 PMCID:PMC12155804

[41]	Otani Y,Furuuchi M,Tekasakul P.Inertial classification of nanoparticles with fibrous filters.Aerosol Air Qual Res2007;7:343-52

[42]	Furuuchi M,Hata M.Development of a personal sampler for evaluating exposure to ultrafine particles.Aerosol Air Qual Res2010;10:30-7

[43]	Amin M,Handika RA.Size-segregated particulate matter down to PM0.1 and carbon content during the rainy and dry seasons in Sumatra Island, Indonesia.Atmosphere2021;12:1441

[44]	Putri RM,Suciari TF.Site-specific variation in mass concentration and chemical components in ambient nanoparticles (PM0.1) in North Sumatra Province-Indonesia.Atmos Pollut Res2021;12:101062

[45]	Chang LP,Chang KL.Water-soluble inorganic ions in airborne particulates from the nano to coarse mode: a case study of aerosol episodes in southern region of Taiwan.Environ Geochem Health2008;30:291-303

[46]	Chang C,Shafer M.Physicochemical and toxicological characteristics of welding fume derived particles generated from real time welding processes.Environ Sci Process Impacts2013;15:214-24

[47]	Abdullahi IL.Welding fumes composition and their effects on blood heavy metals in albino rats.Toxicol Rep2020;7:1495-501 PMCID:PMC7653205

[48]	Liu H,Yuan W,Liu J.Essential role of element Si in corrosion resistance of a bridge steel in chloride atmosphere.Corros Sci2020;173:108758

[49]	Cunat, P. J. Alloying elements in stainless steel and other chromium-containing alloys. Available from: chrome-extension://efaidnbmnnnibpcajpcglclefindmkaj/https://worldstainless.org/wp-content/uploads/2025/02/alloying-elements.pdf (accessed on 2025-9-15)

[50]	Ghosh B,Niyogi S,Hecker M.A comparative study of heavy metal pollution in ambient air and the health risks assessment in industrial, urban and semi-urban areas of West Bengal, India: an evaluation of carcinogenic, non-carcinogenic, and additional lifetime cancer cases.Environments2023;10:190

[51]	Sadheesh S,Arundhathi ,Swetha R.Monitoring and analyzing the effect of heavy metals in air based on ecological and health risks in Coimbatore.IOP Conf Ser: Earth Environ Sci2022;1125:012002

[52]	Amari A,Rostami R.A systematic review on concentration of heavy metal in the ambient air of different industries and the health risk assessment.ACT2023;8

[53]	Zhang X,Aikawa M.Characteristics of PM_2.5-bound metals in Japan over six years: spatial distribution, health risk, and source analysis.J Environ Manage2023;344:118750

[54]	Gonzalez-Villalva A,Nelly LV.Lead systemic toxicity: a persistent problem for health.Toxicology2025;515:154163

[55]	Maria H,Gabriella E,Yudiarso A.Impact of Lead (Pb) on Health.JGRPH2025;10:1-14

[56]	Lucchini R.Manganese-induced parkinsonism: evidence from epidemiological and experimental studies.Biomolecules2023;13:1190 PMCID:PMC10452806

[57]	Hong H,Yang T.Manganese exposure induces parkinsonism-like symptoms by Serpina3n-TFEB-v/p-ATPase signaling mediated lysosomal dysfunction.Cell Biol Toxicol2025;41:34 PMCID:PMC11759460