Comparative Study of the Urban Fine Dust’s Effects on Blood Cells of Male Rats in Different Cities of Khuzestan Province (Iran)
Subject Areas : Journal of Animal Biology
Najmeh Soleimani
1
,
Mohammad Reza Dayer
2
,
Hassan Faridnouri
3
1 - Department of Biochemistry, Damghan University, Damghan, Iran
2 - Department of Biology, Shahid Chamran University of Ahvaz, Ahvaz, Iran
3 - Department of Biochemistry, Damghan University, Damghan, Iran
Keywords: Iran, Khuzestan, Blood cells, Particulates Matter,
Abstract :
Particles in fine dust have the first rank of carcinogens, making their study necessary. The previous results showed that particles with aerodynamic diameters of 2.5 and 10 micrometers are more permeable and pass through respiratory filters and are the main cause of damage. In this study, the effect of fine particulate matters in different cities of Khuzestan province of Iran on blood cells of male rats was compared. Thirty adult male rats were divided into six equal groups, including control, Ahvaz, Ramhormoz, Andimeshk, Abadan, and Susangerd and were treated for two months. The results of blood cell analysis showed an increase in the number of white blood cells, especially lymphocytes in Ahvaz group, while the volume of platelets was significantly reduced. In most groups, a significant decrease was observed in RDW and the amount of hematocrit in Ramhormoz and Susangerd groups showed a significant increase compared to the control group. Therefore, given the different heavy metals composition, fine dusts have different effects on blood parameters, depending on their amount and duration of exposure.
- Barman T., Kalahasthi R., Rajmohan H., 2014. Effects of lead exposure on the status of platelet indices in workers involved in a lead-acid battery manufacturing plant. Journal of Exposure Science and Environmental Epidemiology, 24: 629-633.
- Broomandi P., Dabir B., Bonakdarpour B., Rashidi Y., 2017. Identification of dust storm origin in South–West of Iran. Journal of Environmental Health Science and Engineering, 15: 1-14.
- Du Y., Xu X., Chu M., Guo Y., Wang J., 2016. Air particulate matter and cardiovascular disease: the epidemiological, biomedical and clinical evidence. Journal of Thoracic Disease, 8: 8-19.
- Faghihzadeh F., Adibi P., Rafiei R., Hekmatdoost A., 2014. Resveratrol supplementation improves inflammatory biomarkers in patients with nonalcoholic fatty liver disease. Nutrition Research, 34: 837-843.
- Fiati Kenston S.S., Su H., Li Z., Kong L., Wang Y., Song X., 2018. The systemic toxicity of heavy metal mixtures in rats. Toxicology Research, 7: 396-407.
- Gaber H.S., El-Kasheif M.A., Ibrahim S.A., Authman M., 2013. Effect of water pollution in El-Rahawy drainage canal on hematology and organs of freshwater fish. World Applied Science Journal, 21: 329-341.
- Geravandi S., Goudarzi G., Mohammadi M.J., Taghavirad S.S., Salmanzadeh S., 2015. Sulfur and Nitrogen Dioxide Exposure and the Incidence of Health Endpoints in Ahvaz, Iran. Health Scope, 4: 1-6.
- Golalipour M.J., Roshandel D., Roshandel G., Ghafari S., Kalavi M., Kalavi K., 2007. Effect of lead intoxication and D-penicillamine treatment on hematological indices in rats. International Journal of Morphology, 25: 717-722.
- Han X., Lu X., Wu Y., 2017. Health risks and contamination levels of heavy metals in dusts from parks and squares of an industrial city in semi-arid area of china. International Journal of Environmental Research and Public Health, 14: 1-12.
- Kim J.W., Park S., Lim C.W., Lee K., Kim B., 2014. The role of air pollutants in initiating liver disease. Toxicological Research, 30: 65-70.
- Li N., Xia T., Nel A.E., 2008. The role of oxidative stress in ambient particulate matter-induced lung diseases and its implications in the toxicity of engineered nanoparticles. Free Radical Biology and Medicine, 44: 1689-1699.
- Manisalidis I., Stavropoulou E., Stavropoulos A., Bezirtzoglou E., 2020. Environmental and health impacts of air pollution: A review. Frontiers in public health, 8: 1-13.
- Nikinmaa M., Huestis W.H., 1984. Adrenergic swelling of nucleated erythrocytes: cellular mechanisms in a bird, domestic goose, and two teleosts, striped bass and rainbow trout. Journal of Experimental Biology, 113: 215-224.
- Okediran B., Biobaku K., Olaifa F., Atata A., 2017. Haematological and antioxidant enzyme response to Lead toxicity in male Wistar rats. Ceylon Journal of Science, 46: 31-37.
- Poursafa P., Kelishadi R., Amini A., Amini A., Amin M.M., Lahijanzadeh M., 2011. Association of air pollution and hematologic parameters in children and adolescents. Journal de Pediatria, 87: 350-356.
- Ray R.R., 2016. editor Haemotoxic effect of lead: A review. Proceedings of the Zoological Society, 161-172.
- Seaton A., Soutar A., Crawford V., Elton R, McNerlan S, Cherrie J, et al.,1999. Particulate air pollution and the blood. Thorax, 54: 1027-1032.
- Shah S.L., Altindağ A., 2005. Alterations in the immunological parameters of Tench (Tinca tinca L. 1758) after acute and chronic exposure to lethal and sublethal treatments with mercury, cadmium and lead. Turkish Journal of Veterinary and Animal Sciences, 29: 1163-1165.
- Singh S., Kaur S., Singh D., 2017. Food toxicology-past, present, and the future (the Indian perspective). Food Safety in the 21st Century: Elsevier, pp: 91-110.
- Soleimani Z., Parhizgari N., Rad H.D., Akhoond M.R., Kermani M., Marzouni M.B., 2015. Normal and dusty days’ comparison of culturable indoor airborne bacteria in Ahvaz, Iran. Aerobiologia, 31: 127-141.
- Wang Y., Tang Y., Li Z., Hua Q., Wang L., Song X., 2020. Joint toxicity of a multi-heavy metal mixture and chemoprevention in sprague dawley rats. International Journal of Environmental Research and Public Health, 17: 1-15.
- Zahir F., Rizwi S.J., Haq S.K., Khan R.H., .2005. Low dose mercury toxicity and human health. Environmental Toxicology and Pharmacology, 20: 351-360.
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