Workers involved in paint production or application are extensively exposed to various hazardous substances like organic solvents, lead-based pigments, adhesives, and residual plastic monomers. Therefore, workers in the paint industry are at high risk of suffering adverse health effects. Studies of the lymphocytes of paint workers have demonstrated that industrial paint induces DNA damage and cellular changes. The aim of the present study was to assess DNA damage in 54 paint workers from paint production and application areas and 54 age-gender matched control subjects using a non-invasive buccal micronucleus (MN) assay. Buccal MN frequencies were significantly increased in workers compared to controls. MN frequencies significantly increased among workers from paint production areas compared with workers from paint application areas. MN frequencies in long-term workers (>10 years) were found to be significantly higher than those of short-term workers (≤10 years), which indicates that the duration of exposure to paints causes cytogenetic damage. MN frequencies increased with increasing age, while smoking status and the use of protective masks had no additional effect on MN frequencies within groups. In conclusion, it appears that long-term exposure to complex chemical mixtures during paint production may increase DNA damage in the workers. Understanding the possible causes of occupational exposure-induced genotoxicity in paint industry workers is of great importance for the protection of public health. Monitoring variables related to genotoxic damage in the paint workers using non-invasive methods will facilitate and improve risk assessment in the paint production sector.
AkramZMahjabeenIBatoolM, et al. (2023) Expression deregulation of genes related to DNA repair and lead toxicity in occupationally exposed industrial workers. International Archives of Occupational and Environmental Health96(10): 1333–1347.
2.
AnetorJI (2010) Industrialization and the increasing risk of genome instability in developing countries: nutrigenomics as a promising antidote. African Journal of Medicine & Medical Sciences39(Suppl): 7–20.
3.
AwodeleOPopoolaTDOgbuduBS, et al. (2014) Occupational hazards and safety measures amongst the paint factory workers in Lagos, Nigeria. Safety and Health at Work5(2): 106–111.
4.
BaeGNJungHCParkJH (2010) Xposure assessment of organic solvents used in the paint industry. Safety and Health at Work1(1): 42–52.
5.
BecitMŞuleÇBaşaranMM, et al. (2021) Changes in genotoxicity, inflammatory and oxidative stress parameters of workers in marble processing plants. Environmental Research197: 111209. doi: 10.1016/j.envres.2021.111209.
6.
BergamaschiEBellisarioVMacrìM, et al. (2022) A biomonitoring pilot study in workers from a paints production plant exposed to pigment-grade titanium dioxide (TiO2). Toxics10(4): 171.
7.
BolognesiCKnasmuellerSNersesyanA, et al. (2013) The HUMNxl scoring criteria for different cell types and nuclear anomalies in the buccal micronucleus cytome assay - an update and expanded photogallery. Mutation Research753(2): 100–113.
8.
BonassiSBiasottiBKirsch-VoldersM, et al. (2009) State of the art survey of the buccal micronucleus assay--a first stage in the HUMN(XL) project initiative. Mutagenesis24(4): 295–302.
9.
BonettaSMacrìMAcitoM, et al. (2024) DNA damage in workers exposed to pigment grade titanium dioxide (TiO2) and association with biomarkers of oxidative stress and inflammation. Environmental Toxicology and Pharmacology105: 104328.
10.
BrownC (2010) Human-animal medicine: clinical approaches to zoonoses, toxicants and other shared health risks. Emerging Infectious Diseases16(6): 1050.
11.
BrumEDSda SilvaLMTeixeiraTP, et al. (2021) DNA damage and inflammatory response in workers exposed to fuels and paints. Archives of Environmental & Occupational Health76(3): 152–162.
12.
CaoJLiuYSunH, et al. (2002) Chromosomal aberrations, DNA strand breaks and gene mutations in nasopharyngeal cancer patients undergoing radiation therapy. Mutation Research504(1-2): 85–90.
13.
Cárdenas-BustamanteOVarona-UribeMPatiño-FlorezRI, et al. (2007) xposición a Solventes Orgánicos y Efectos Genotóxicos en Trabajadores de Fábricas de Pinturas en Bogotá [Bogotá paint-industry workers exposure to organic solvents and genotoxic effects]. Revista de Salud Publica (Bogota, Colombia)9(2): 275–288.
14.
CassiniCCalloniCBortoliniG, et al. (2011) Occupational risk assessment of oxidative stress and genotoxicity in workers exposed to paints during a working week. International Journal of Occupational Medicine & Environmental Health24(3): 308–319.
15.
CavalloDUrsiniCLFresegnaAM, et al. (2021) Occupational exposure in industrial painters: sensitive and noninvasive biomarkers to evaluate early cytotoxicity, genotoxicity and oxidative stress. International Journal of Environmental Research and Public Health18(9): 4645.
16.
CelikADilerSBEkeD (2010) Assessment of genetic damage in buccal epithelium cells of painters: micronucleus, nuclear changes, and repair index. DNA and Cell Biology29(6): 277–284.
17.
CetintepeSPHazarMBilinmişI, et al. (2023) Evaluation of genotoxicity, oxidative stress and immune parameters of auto-paint workers. Environmental Research237(Pt 1): 116970.
18.
ChangFKMaoIFChenML, et al. (2011) Urinary 8-hydroxydeoxyguanosine as a biomarker of oxidative DNA damage in workers exposed to ethylbenzene. Annals of Occupational Hygiene55(5): 519–525.
19.
ChenRDickFSempleS, et al. (2001) Exposure to organic solvents and personality. Occupational and Environmental Medicine58(1): 14–18.
20.
DavidENiculescuVC (2021) Volatile organic compounds (VOCs) as environmental pollutants: occurrence and mitigation using nanomaterials. International Journal of Environmental Research and Public Health18(24): 13147.
21.
de OliveiraHMDagostimGPda SilvaAM, et al. (2011) Occupational risk assessment of paint industry workers. Indian Journal of Occupational and Environmental Medicine15(2): 52–58.
22.
DickFD (2006) Solvent neurotoxicity. Occupational and Environmental Medicine63(3): 221–2179.
23.
Dos Reis FilhoAPSilveiraMADDemarcoNR, et al. (2019) Increased DNA damage, instability and cytokinesis defects in occupationally exposed car painters. In Vivo33(6): 1807–1811.
24.
DuanHLengSPanZ, et al. (2009) Biomarkers measured by cytokinesis-block micronucleus cytome assay for evaluating genetic damages induced by polycyclic aromatic hydrocarbons. Mutation Research677(1-2): 93–99.
25.
EdokpoloBYuQJConnellD (2014) Health risk assessment of ambient air concentrations of benzene, toluene and xylene (BTX) in service station environments. International Journal of Environmental Research and Public Health11(6): 6354–6374.
26.
FenechM (2008) The micronucleus assay determination of chromosomal level DNA damage. Methods in Molecular Biology410: 185–216.
27.
FenechMKnasmuellerSNersesyanA, et al. (2024) The buccal micronucleus cytome assay: new horizons for its implementation in human studies. Mutation Research894: 503724.
28.
FuchsJHengstlerJGHummrichF, et al. (1996) Transient increase in DNA strand breaks in car refinishing spray painters. Scandinavian Journal of Work, Environment & Health22(6): 438–443.
29.
GhobakhlooSKhoshakhlaghAHMoraisS, et al. (2023) Exposure to volatile organic compounds in paint production plants: levels and potential human health risks. Toxics11(2): 111.
30.
GhoshNVitti KrushnaPSharmaJD, et al. (2023) Evaluation of skin absorption potential of chemicals relevant to painting trades. ACS Chemical Health & Safety30(4): 204–211.
31.
GuhaNSteenlandNKMerlettiF, et al. (2010) Bladder cancer risk in painters: a meta-analysis. Occupational and Environmental Medicine67(8): 568–573.
32.
GuhaNMerlettiFSteenlandNK, et al. (2011) Lung cancer risk in painters: a meta-analysis. Ciência & Saúde Coletiva16(8): 3613–3632.
33.
HsuDJChungSHDongJF, et al. (2018) Water-based automobile paints potentially reduce the exposure of refinish painters to toxic metals. International Journal of Environmental Research and Public Health15(5): 899.
34.
IARC Working Group on the Evaluation of Carcinogenic Risks to Humans (2012) Chemical agents and related occupations. IARC Monographs on the Evaluation of Carcinogenic Risks to Humans / World Health Organization, International Agency for Research on Cancer100(Pt F): 9–562.
35.
JodehSChakirAHanbaliG, et al. (2023) Method development for detecting low level volatile organic compounds (VOCs) among workers and residents from a carpentry work shop in a Palestinian village. International Journal of Environmental Research and Public Health20(9): 5613.
36.
KamalAMalikRN (2012) Hematological evidence of occupational exposure to chemicals and other factors among auto-repair workers in rawalpindi, Pakistan. Osong Public Health and Research Perspectives3(4): 229–238.
37.
KanuPriyaKumarSGuptaR, et al. (2023) Association of glutathione-S-transferase polymorphism with genetic damage in paint workers. Molecular Biology Reports50(6): 4899–4905.
38.
KasperczykETarhonskaKJablonskaE (2025) Genotoxicity induced by carcinogenic agents or occupational exposure with sufficient evidence for bladder cancer. Journal of Clinical Medicine14(13): 4492.
39.
KaukiainenARialaRMartikainenR, et al. (2004) Solvent-related health effects among construction painters with decreasing exposure. American Journal of Industrial Medicine46(6): 627–636.
40.
KianmehrMHajaviJGazeriJ (2017) Assessment of DNA damage in blood lymphocytes of bakery workers by comet assay. Toxicology and Industrial Health33(9): 726–735.
41.
KimBR (2011) VOC emissions from automotive painting and their control: a review. Environmental Engineering Research16(1): 1–9.
42.
KimJHMoonJYParkEY, et al. (2011) Changes in oxidative stress biomarker and gene expression levels in workers exposed to volatile organic compounds. Industrial Health49(1): 8–14.
43.
KimBYoonJHChoiBS, et al. (2013) Exposure assessment suggests exposure to lung cancer carcinogens in a painter working in an automobile bumper shop. Safety and Health at Work4(4): 216–220.
44.
LaurenceCB (2001) Managed care and technology adoption in health care: evidence from magnetic resonance imaging. Journal of Health Economics20(3): 395–421.
45.
LeeKHIchibaMZhangJ, et al. (2003) Multiple biomarkers study in painters in a shipyard in Korea. Mutation Research, Genetic Toxicology and Environmental Mutagenesis540(1): 89–98.
46.
Londoño-VelascoEMartínez-PerafánFCarvajalS, et al. (2019) Evaluation of oxidative and methylating DNA damage in painters occupationally exposed to organic solvents and paints. Biomedica39(3): 464–477.
47.
MaksoudNAalKAGhandourN, et al. (2018) Assessment of hematotoxicity and genotoxicity among paint workers in Assiut governorate: a case control study. Egyptian Journal of Food Science8: 6.
48.
Martino-RothMGViégasJRothDM (2003) Occupational genotoxicity risk evaluation through the comet assay and the micronucleus test. Genetics and Molecular Research2(4): 410–417.
49.
MoroAMBruckerNCharãoM, et al. (2012) Evaluation of genotoxicity and oxidative damage in painters exposed to low levels of toluene. Mutation Research746(1): 42–48.
50.
NoamGG (2001) Psychoanalysis: adolescence (Clinical–Developmental approach). In: SmelserNJBaltesPB (eds) International Encyclopedia of the Social & Behavioral Sciences. Oxford: Pergamon, 12302–12308.
51.
O'ConnorDHouDYeJ, et al. (2018) Lead-based paint remains a major public health concern: a critical review of global production, trade, use, exposure, health risk, and implications. Environment International121(Pt 1): 85–101.
ParkJLeeCGRyuSY (2006) Factors related to the prevalence of respiratory symptoms in workers in a petrochemical complex. Journal of Occupational Health48(3): 216–222.
55.
Piña-CalvaAMadrigal-BujaidarEFuentesMV, et al. (1991) Increased frequency of chromosomal aberrations in railroad car painters. Archives of Environmental Health46(6): 335–339.
56.
PintoDCeballosJMGarcíaG, et al. (2000) Increased cytogenetic damage in outdoor painters. Mutation Research467(2): 105–111.
57.
Roma-TorresJTeixeiraJPSilvaS, et al. (2006) Evaluation of genotoxicity in a group of workers from a petroleum refinery aromatics plant. Mutation Research604(1-2): 19–27.
58.
RossnerPBoffettaPCeppiM, et al. (2005) Chromosomal aberrations in lymphocytes of healthy subjects and risk of cancer. Environmental Health Perspectives113(5): 517–520.
59.
SaironiAAwangNIthninA, et al. (2023) Effect of paint exposure among paint workers and DNA damage: a scoping review. Malaysian Journal of Medicine and Health Sciences19(4): 342–353.
60.
ScéloGMetayerCZhangL, et al. (2009) Household exposure to paint and petroleum solvents, chromosomal translocations, and the risk of childhood leukemia. Environmental Health Perspectives117(1): 133–139.
61.
SilvaJMSantos-MelloR (1996) Chromosomal aberrations in lymphocytes from car painters. Mutation Research368: 21–25.
62.
SinghZChadhaPSharmaM (2016) Health hazards of solvent exposure in paint and coating industry: a review. Indian Journal of Occupational and Environmental Medicine20(3): 103–110.
63.
SmuldersSLuytsKBrabantsG, et al. (2014) Toxicity of nanoparticles embedded in paints compared with pristine nanoparticles in mice. Toxicological Sciences141(1): 132–140.
64.
TestaAFestaFRanaldiR, et al. (2005) A multi-biomarker analysis of DNA damage in automobile painters. Environmental and Molecular Mutagenesis46(3): 182–188.
TolbertPEShyCMAllenJW (1992) Micronuclei and other nuclear anomalies in buccal smears: methods development. Mutation Research271(1): 69–77.
67.
VillariniMGuerreraEVanniniS, et al. (2021) Cytogenetic biomonitoring of road tunnel construction workers: buccal micronucleus cytome assay. Annali di Igiene: Medicina Preventiva e di Comunita33(4): 307–321.
