Objetivos: Determinar el comportamiento de los marcadores de estrés oxidativo y genotoxicidad en individuos expuestos ocupacionalmente, por tiempos prolongados, al plomo.

Material y método: Fueron estudiados 57 sujetos, de ellos, 27 trabajadores con edades comprendidas entre 35 y 64 años, expuestos al plomo por períodos de 8 a 44 años. El grupo control estuvo conformado por 30 individuos, con edades comprendidas entre 36 y 65 años, sin exposición ocupacional conocida a agentes químicos o físicos. Todos los participantes fueron incluidos en el estudio luego de emitir su consentimiento informado. Los marcadores de daño oxidativo y de defensa antioxidante, fueron medidos mediante métodos espectrofotométricos. Además, se determinó el daño al ADN mediante ensayo Cometa.

Resultados: En los trabajadores expuestos se observó un incremento significativo en la concentración plasmática de peróxidos totales. Por otra parte, mostraban una disminución significativa en la actividad de la glutatión reductasa.

Conclusiones: Los resultados de este estudio permitirán el empleo de marcadores de efecto para el seguimiento de los trabajadores expuestos al plomo. 

Nava-Ruíz C, Méndez-Armenta M. Efectos neurotóxicos de metales pesados (cadmio, plomo, arsénico

y talio). Arch Neurocien (Mex). 2011;16(3):140-7.

Fontana D, Lascano VM, Solá N, Martínez S, Virgolini M, Mazzieri MR. Lead poisoning and pharmacological treatment. Revista de Salud Pública.

;17(1):49-59.

Sinicropi MS, Amantea D, Caruso A, Saturnino C.

Chemical and biological properties of toxic metals

and use of chelating agents for the pharmacological

treatment of metal poisoning. Arch Toxicol. 2010;

:501–20.

Revista Cubana de Salud y Trabajo 2015;16(3):20-5

Pérez C, Riverón G, Fernández IM, del Castillo NP, Martinez O, et al.

Afaf Abbass Sayed Saleh. Potential effects of some

antioxidants against lead toxicity. International Journal of Advanced Research. 2014;2(5):824-34.

Ahamed M, Siddiqui MKJ. Low level lead exposure

and oxidative stress: Current opinions. Clinica Chimica

Acta. 2007;383:57-64.

Cabaravdic M., Mijanovic M., Kusturica J.,

Cabaravdic A. Occupational exposure of workers at

gas station to inorganic lead. Med Arch.

;64(2):107-9.

Gurer-Orhan H, Sabir HU, Ozgunes H. Correlation

between clinical indicator of lead poisoning and oxidative stress parameters in controls and lead exposed

workers. Toxicology. 2004;195:147–54.

Kasperczyk S, Birkner E, Kasperczyk A, Kasperczyk

J. Lipid, lipid peroxidation and 7-ketocholesterol in

workers exposed to lead. Human Exp Toxicol.

;24:287–95.

Bechara EJH. Lead poisoning and oxidative stress.

Free Radic Biol Med. 2004;36.

Martínez SA, Cancela LM, Virgolini MB. El estrés

oxidativo como mecanismo de acción del plomo.

Implicancias terapéuticas. Acta Toxicológica Argentina. 2011;19(2):61-79.

Witko-Sarsat V, Friendlander M, Nguyen-Khoa T,

Capeillère-Blandin C, Nguyen AT, Canteloup S, et al.

Advanced oxidation protein products as novel mediators of inflammation and monocytes activation in

chronic renal failure. J Immunol. 1998;161:2524-32.

Harma M, Erel O. Increased oxidative stress in patients with hydatidiform mole. Swiss Med Wkly.

;133:563-66.

Collins AR, Dobson VL, Dusinska M, Kennedy G,

Stetina R. The comet assay: what can it really tell

us? Mutat Res. 1997;375:183-93.

Marklund S, Marklund G. Involvement of superoxide anion radical in the autoxidation of pyrogallol

and a convenient assay for superoxide dismitase. Eur

J Biochem. 1974;47:469-74.

Aebi H. Catalase in vitro. Meth Enzymol. 1984;105:

Paglia DE, Valentine WN. Studies on the quantitative and qualitative characterization of erythrocyte

glutathione peroxidase. J Lab Clin Med. 1967;70:

-69.

Calberg I, Mannervik B. Glutathione reductase.

Meth Enzymol. 1985;113:485-90.

Sedlak J, Lindasy RH. Estimation of total protein

bound and non-protein sulfhydryl group in tissue

with Ellman`s reagent. Anal Biochem. 1968;25:192-

Wang Q, Zhao HH, Chen JW, Hao QL, Gu KD, Zhu

YX, Zhou YK, Ye LX. delta-aminolevulinic acid

dehydratase activity, urinary delta-aminolevulinic

acid concentration and zinc protoporphyrin level

among people with low level of lead exposure. Int J

Hyg Environ Health. 2010;213(1):52-8.

Patrick L. Lead toxicity part II: the role of free radical damage and the use of antioxidants in the pathology and treatment of lead toxicity. Altern Med Rev.

b;11:114–27.

Jomova K, Valko M. Advances in metal-induced

oxidative stress and human disease. Toxicology.

;283(2-3):65-87.

Martínez SA, Simonella S, Hansen C, Rivolta S,

Cancela LM, Virgolini MB. Blood lead levels and

enzymatic biomarkers of environmental lead exposure in children in Córdoba, Argentina, after the ban

of leaded gasoline. Hum Exp Toxicol. 2013;32(5):

-63.

Kasperczyk S, Birkner E, Kasperczyk A, ZalejskaFiolka J. Activity of superoxide dismutase and catalase in people protractedly exposed to lead compounds. Ann Agric Environ Med. 2004;11(2):291-6.

Gautam P, Flora SJ. Oral supplementation of gossypin during lead exposure protects alteration in

heme synthesis pathway and brain oxidative stress in

rats. Nutrition. 2010;26(5):563-70.

Pande M, Flora SJS. Lead-induced oxidative damage

and its response to combined administration of lipoic

acid and succimers in rats. Toxicology. 2002;177:

–96.

Garcon G, Leleu B, Zerimech F, Marez T, Haguenoer JM, Furon D, Shirali P. Biologic markers of

oxidative stress and nephrotoxicity as studied in

biomonitoring of adverse effects of occupational exposure to lead and cadmium. J Occup Environ Med.

;46(11):1180-6.

Hoffman DJ, Heinz GH, Sileo L, Audet DJ, Campbell JK, LeCaptain LJ, Obrecht HH. J. Toxicol. Environ. Health. 2000;59:235–52.

Prasad AS. Zinc: role in immunity, oxidative stress

and chronic inflammation. Curr Opin Clin Nutr Metab Care. 2009;12:646–52.

Flora SJS, Pachauri V. Chelation in metal intoxication.

Int J Environ Res Public Health. 2010;7:2745–88.