Today, the study about lipoproteins is very important because the mortality and morbidity due to metabolism disorders has increased. Research interest in lipids and lipoprotein metabolism has increased due to the establishment of the roles played by lipids, lipoproteins and Apo lipoproteins in the development of cardiovascular disease (CVD) (Durstine et al., 2001; Booth et al., 2002; Asikainen et al., 2004; Coelho et al., 2005; Brown et al., 2007). Suboptimal levels of lipids and lipoproteins represent a major risk factor for cardiovascular disease (CVD), the number one cause of mortality in the United States (American College of Sports Medicine, 1998).
Coronary heart disease (CHD) is the most important cause of mortality in developed countries. All heart attacks, with rare exceptions, are caused by atherosclerosis, or a narrowing and “hardening†of the coronary arteries resulting from fatty deposits called plaque. This process, by which the wall of the artery is infiltrated by deposits of cholesterol and calcium, narrows the lumen (the internal orifice) of the artery. When the degree of narrowing reaches a critical level, blood flow to the portion of the heart supplied by that artery is stopped and this causes injury to the heart muscle, thus, a heart- attack occurs. If the reduction in blood flow is not total and is only temporary, relative to muscle needs, permanent damage does not result but the individual may experience angina pectoris – chest pain as a result of too little blood and oxygen to a portion of the heart in response to its needs (a process called ischemia) (Münzel et al., 2010).
According to Bimenya et al. (2006), public servants, who were mainly University graduates, were found to have abnormally high levels of plasma lipids. Plasma lipid and lipoprotein levels have been shown to be influenced by age, sex, socioeconomic status, genetics, race, diet, cigarette smoking coffee and alcohol intake, and medication as well as habitual and leisure time physical activity. Increased physical activity has been reported to produce favorable changes in the lipid and lipoprotein profiles (Kraus et al., 2002; Nieman et al., 2002). Apo lipoprotein B is combined with heparin and glucose amino glycan; this chemical interaction leads to atherosclerosis (LeMura et al., 2000; Meilahn et al., 1988; Lakshman et al., 1996).
An increasing number of studies focus on the role of reactive oxygen species (ROS) in the pathogenesis of premature ageing as well as of numerous civilization diseases, such as cardiovascular diseases (Karaouzene et al., 2011). It has been suggested that higher antioxidant potential can protect the organism against undesirable ROS activity and thus prevent disease incidence (Briasoulis et al., 2009).
Relationship of CHD to antioxidant defenses may be modified not only by many demographic, anthropometric, physiological, and biochemical confounders but also by different exogenic substances such as applied medications or cigarette smoking (Hutcheson and Rocic, 2012; Ndrepepa et al., 2013). Total antioxidant capacity (TAC) assessment is an established methodology to measure different elements of antioxidant defense system together (Cervellati et al., 2014).
Coronary heart disease can be classified as “typical†CVD such as fatal myocardial infarction(MI) and sudden death, and “atypical†CVD, such as fatal heart failure and chronic arrhythmias. When further explored, the etiologies of these coronary diseases in relation to major cardiovascular risk factors are different. Death rates from typical and atypical CVD are inversely related, with mean age at death for atypical being significantly higher than typical.
The relationship of risk factors with typical CVD is direct and significant for age, systolic blood pressure, serum cholesterol and smoking habits (Menotti et al., 2006). Atherosclerosis, being a chronic process, undergoes a series of changes in the arterial walls before the clinical endpoints set in. Rupture of the plaque is the final event that results in a clinical endpoint, often stroke or MI (Kanjilal et al., 2008). The increasing pressure on health resources has led to risk stratification as a primary prevention effort to accurately determine and intervene early in the natural history of disease by moving closer to the proximal direct causes of disease and improving prediction (Stampfer et al., 2004).
Risk factors are traits and life-style habits that increase a person’s chances of having cardiovascular diseases. Some risk factors cannot be changed or modified, while other risk factors are modifiable (Münzel et al., 2010). The most important risk factors for cardiovascular disease are high blood pressure, high blood cholesterol and cigarette smoking. Other factors that may increase the risk for cardiovascular disease are diabetes, obesity, being physically inactive and having an unhealthy reaction to stress. The concept of risk factors has evolved only over the past 45 years or so, and new factors are periodically added to the list as our comprehension of the disease process grows
Although risk-scoring systems that evaluate conventional risk factors greatly improve risk prediction, multiple studies demonstrate that 20% to 25% of all future events occur in individuals with only one of these factors (Ridker et al., 2004). With evolving understanding of the pathophysiology of CVD, it is more than likely that other risk factors may greatly influence an individual’s overall risk burden (Hemann et al., 2007). As a result, a series of biomarkers such as Hcy and CRP reflecting inflammation, hemostasis, thrombosis, and oxidative stress have been evaluated as potential clinical tools in an effort to improve risk prediction (Ridker et al., 2004).
The close association between traditional risk factors, atherosclerotic burden, and risk for clinical CVD has allowed multivariate risk prediction equations to be developed to better estimate CVDrisk. The Framingham Risk Score calculates the absolute risk of CVD events for patients with no known previous history of CVD, stroke, or peripheral vascular disease (Sheridan et al., 2003). What is apparent is that the Framingham equation may not accurately estimate the risk of vascular disease in some ethnic groups (Cappuccio et al., 2002). However, given the lack of prospective data in large ethnically mixed populations including Nigeria, these risk equations are the best available tools to guide the decision making process of prevention in general practice.
There is a dramatic increase in incidence of CVD in the developing world as earlier predicted by World Health Organization (Murray and Lopez, 1996). It is increasingly recognized that developing countries are undergoing an epidemiologic transition, accompanied by an increasing burden of CVD linked to urbanization and lifestyle modifications (Dominguez et al., 2006). The health transition is occurring at an increased pace in urban societies widely exposed to lifestyle modernization, sedentary occupation, and to lipid- and sugar-rich foods often poor in fiber and micronutrients.
In Nigeria the extent of most CVD’s and risk factors at population level remains largely unknown. For the past 25 years, high blood pressure has become established in Nigeria. This has been attributed to consumption of sodium salt and alcohol, psychological stress, obesity, physical inactivity and other dietary factors (Trowell, 1980; Lowe, 1993).  Although the exact genetic markers of CVD remain unknown in Nigeria, different environmental mediators contribute to the development of this disease.  It therefore essential to identify the risk factors involved in order to develop preventive strategies.
To understand who is at risk and what risk actually means to an individual, one first needs to understand how diseases of the heart and circulatory systemâ€â€particularly heart attacks-develop (Münzel et al., 2010).   However, the present state of knowledge on such dependence is still not complete (Münzel et al., 2010): while numerous discrepancies have been observed in studies and no unequivocal answer has been reached on the appropriate cluster of thesefactors for the incidence of metabolic syndrome among Nigerians.   Furthermore, the impact of occupational demand on civil servant in Nigeria has not received much attention. In addition, that the incidence of CVD is related to antioxidant potential is an issue of current debate in literature, and information on Nigerian population  is especially limited. This underscores the following aim and objectives of this study.
The overall aim of this study is to assess the cardiovascular and antioxidant status of some working class women in Ambrose Alli University, Ekpoma; with major focus on the effect of the activity patterns.
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