BACKGROUND OF STUDY
Tobacco smoking is a practice of burning tobacco and inhaling the smoke (consisting of gaseous phases and particles). A more broad definition may include taking tobacco smoke into the mouth, and then releasing it, as is done by some with tobacco pipes and cigars. The practice may have begun as early as 5000-3000 BC (Nagarajet al., 2014).Cigarette smoking is probably the most addictive and dependence producing form of object-specific, self-administered gratification known to man. According to present estimates, tobacco is responsible for causing more than 5 million deaths every year (World Health Organization, 2008).
The harmful effects of cigarette smoking on human health have been well documented. It has been known that cigarette smoke carries around 4000 chemicals including toxic metals, poisonous gases and free radicals (Schumacher et al., 2009). Amongst these constituents, free radicals are considered to be more dangerous as these owing to their unpaired electron are highly reactive and can cause oxidative damage to biomolecules and biomembranes (Senet al., 2010).
Smoking plays an important role in disturbing the antioxidant balance. Normally blood contains a healthy complement of antioxidants that keep oxidative damage to a minimum. Tobacco smoke contains abundant reactive oxygen species and also activated neutrophils released due to smoking also add to the pool of reactive oxygen species which deplete these antioxidant mechanisms leading to tissue damage (Kumar et al., 2010).
Malondialdehyde is a organic compound with the formula CH2 (CHO). This reactive species occurs naturally and is a marker for oxidative stress. Reactive oxygen species degrade polyunsaturated lipids present on cell membrane forming malondialdehyde. This aldehyde product is used as a biomarker to measure the level of oxidative stress in an organism (Nagarajet al., 2014).
Antioxidants depletion or deficiency may contribute to oxidative stress. Antioxidants not only protect against the direct injurious effects of oxidants, but also alter the inflammatory events that play an important role in the pathogenesis of oxidative stress related diseases (MacNee, 2010). Vitamin C is a water soluble free radical scavenger, can directly scavenge O2 and OH- radicals and help to neutralize physiological oxidant burden created by both exogenous and endogenous sources (Rai and Phadke, 2006).
Vitamin E, a well-known chain-breakingantioxidant in cell membrane protects themembrane against lipid peroxidation either directlyby scavenging the free radicals or indirectly bycontrolling the reduced glutathione levels.Vitamin E itself is kept in reduced state by vitaminC, another antioxidant vitamin (Shah et al., 2015).