CONTRIBUTI SCIENTIFICI – Scientific Papers
Volume:
Biochimica Clinica, aop
Pubblicato on-line:
Novembre 12, 2024
DOI:
10.19186/BC_2024.048
Analysis of the association of plasma lead levels and markers of calcium homeostasis among occupational lead-exposure workers
AUTORI
ABSTRACT
Background: lead (Pb) is one of the occupational toxicants and is used as a petrol additive to reduce engine spark knock. Pb in the environment may result from natural or industrial sources. In humans, leaded petrol can cause various biological effects depending on the level and duration of the exposure. The aim of this study was to explore the effect of occupational Pb-exposure on calcium homeostasis markers and to verify the possible correlation.
Methods: 100 petrol station workers were selected for the Pb-exposed group, with an equal number of non-exposed subjects chosen as control group. Venous blood samples were collected from both groups and standard procedures were used to measure the biochemical parameters.
Results: the study most relevant results were: the Pb-exposed group showed higher plasma Pb and parathyroid hormone (PTH) levels, and lower levels of total calcium, vitamin D, calcitonin, phosphorus, albumin, and total protein compared to the control group. The results of multivariate general linear model (GLM) analysis showed a significant total variability (all dependent variables) attributable to Pb-exposure (partial η2 = 0.707, p <0.001). Between-subjects effects test showed the largest effect of plasma Pb on PTH and vitamin D (partial η2 = 1.00, p <0.001).
Conclusion: the results suggest that elevation in the plasma levels of Pb is associated in the Pb-exposed subjects to decreased levels of all studied markers of calcium homeostasis, except PTH, compared to the control group.
BIBLIOGRAFIA
- Rai R, El-Zaemey S, Dorji N, Rai BD, Fritschi L. Exposure to occupational hazards among health care workers in low-and middle-income countries: a scoping review. Int J Environ Res Public Health 2021;18:2603.
- Che Huei L, Ya-Wen L, Chiu Ming Y, Li Chen H, Jong Yi W, Ming Hung L. Occupational health and safety hazards faced by healthcare professionals in Taiwan: A systematic review of risk factors and control strategies. SAGE Open Medicine 2020;8:2050312120918999.
- Bertin M, Bodin J, Fouquet N, Bonvallot N, Roquelaure Y. Multiple exposures and coexposures to occupational hazards among agricultural workers: a systematic review of observational studies. Saf Health Work 2018;9:239-48.
- Kim WJ, Jeong BY. Exposure time to work-related hazards and factors affecting musculoskeletal pain in nurses. Appl Sci 2024;14:2468.
- Giwercman A, Skakeback NE. The human testis – an organ at risk. Int J Androl 1992;15:373-5.
- Danzo BJ. Environmental xenobiotics may distrucpt normal endocrine function by interfering with binding of physiological ligands to steroid receptor and binding protein. Environ Health Perspect 1997;105:294-301.
- Karrari P, Mehrpour O, Abdollahi M. A systematic review on status of lead pollution and toxicity in Iran; Guidance for preventive measures. Daru 2012;20:2.
- Wani AL, Ara A, Usmani JA. Lead toxicity: a review. InterdiscipToxicol 2015;8:55-64.
- Anetor JI, Akingbola TS, Adeniyi FA, Taylor GO. Decreased total and ionized calcium levels and hematological indices in occupational lead exposure as evidence of the endocrine disruptive effect of lead. IJOEM 2005;9:15-21.
- Himani, Kumar R, Ansari JA, Mahdi AA, Sharma D, Karunanand B, et al. Blood lead levels in occupationally exposed workers involved in battery factories of Delhi-NCR region: effect on vitamin D and calcium metabolism. Indian J Clin Biochem 2020;35:80-7.
- Wang X, Liang H, Wang Y, Cai C, Li J, Li X, et al. Risk factors of renal dysfunction and their interaction in level-low lead exposure paint workers. BMC Public Health 2018;18:1-7.
- Harari F, Sallsten G, Christensson A, Petkovic M, Hedblad B, Forsgard N, et al. Blood lead levels and decreased kidney function in a population-based cohort. Am J Kidney Dis 2018; 72:381-9.
- Parsons PJ, Slavin W. A rapid Zeeman graphite furnace atomic absorption spectrometric method for the determination of lead in blood. Spectrochimica Acta Part B: Atomic Spectroscopy 1993;48:925-39.
- Weinfurt, K. P. Multivariate analysis of variance. In Grimm L & P. Yarnold P. Eds. Reading and understanding multivariate statistics. Washington DC: American Psychological Association, 1995.
- Tabachnick BG, Fidell LS. Using multivariate statistics (4th ed.) Needham Heights. MA: Pearson Education, 2001.
- Damstra T. Toxicological properties of lead. Envrion Health Perspect 1977;19:297-07.
- Anetor JI. Serum uric acid and standardized urinary protein: reliable bioindicators of lead nephropathy in Nigerian lead workers. Afr J Biomed Res 2002:5;19-24.
- Gidlow DA. Lead toxicity. Occup Med 2004;54:76-81.
- Dongre NN, Suryakar AN, Patil AJ, Hundekari IA, Devarnavadagi BB. Biochemical effects of lead exposure on battery manufacture workers with reference to blood pressure, calcium metabolism and bone mineral density. Indian J Clin Biochem 2013;28:65‑70.
- Anetor JI, Ajose OA, Adebiyi JA, Akingbola TS, Iyanda AA, Ebesunu MO, et al. Decreased thiamine and magnesium levels in the potentiation of the neurotoxicity of lead in occupational lead exposure. Biol Trace Elem Res 2007;116:43-51.
- Kristal-Bouneh E, Froom P, Yerushalmi N, Harari G, Ribak J. Calcitropic hormones and occupational lead exposure. Am J Epidemil 1998;147:458–63.
- Upadhyay K, Viramgami A, Bagepally BS, Balachandar R. Association between blood lead levels and markers of calcium homeostasis: a systematic review and meta-analysis. Sci Rep 2022;12:1850.
- Firoozichahak A, Rahimnejad S, Rahmani A, Parvizimehr A, Aghaei A, Rahimpoor R. Effect of occupational exposure to lead on serum levels of lipid profile and liver enzymes: An occupational cohort study. Toxicol Rep 2022;9:269-75.
- Li JW, Xu C, Fan Y, Wang Y, Xiao YB. Can serum levels of alkaline phosphatase and phosphate predict cardiovascular diseases and total mortality in individuals with preserved renal function? A systemic review and meta-analysis. PLoS One 2014;9:e102276.
- Ścisło L, Staszkiewicz M, Walewska E, Wojtan S, Paplaczyk M, Kózka M. Albumin and total protein concentration–selected parameters of catabolic reaction and nutritional status among patients with craniocerebral injuries diagnosed with surgically treated cerebrovascular diseases. Medical Studies/Studia Medyczne 2021;37:211-7.
- Kshirsagar MS, Patil AJ, Patil JA. Impact of occupational lead exposure on liver and kidney function tests on silver jewellery workers. JCDR 2019;13:BC01-BC04.
- Kalahasthi R, Barman T, Jamalpur RP, Adepu VK. Assessment of diagnostic accuracy and optimal cut points of blood lead levels on serum proteins among workers exposed to Pb at a lead battery plant. Int J Med Biochem 2019;2:81-7.
- Naveh-Many T, Silver J. Regulation of calcitonin gene transcription by vitamin D metabolites in vivo in the rat. J Clin Investig 1988;81:270-3.
- Malik K, Rathore S, Chandel M. Correlation of lead exposure on calcium metabolism, vitamin d3 in battery manufacturing workers. IJMSDR 2021;5:17-23.
- Ren W, Gu Y, Zhu L, Wang L, Chang Y, Yan M, et al. The effect of cigarette smoking on vitamin D level and depression in male patients with acute ischemic stroke. Compr Psychiatry 2016;65:9–14.
- Jorde R, Saleh F, Figenschau Y, Kamycheva E, Haug E, Sundsfjord J. Serum parathyroid hormone (PTH) levels in smokers and non-smokers. The fifth Tromsø study. Eur J Endocrinol 2005;152:39-45.
- Mousavi SE, Amini H, Heydarpour P, Chermahini FA, Godderis L. Air pollution, environmental chemicals, and smoking may trigger vitamin D deficiency: Evidence and potential mechanisms. Environ Int 2019;122:67-90.
