Obesity

Obesity is an important risk factor for CVD, and is also somewhat associated with risk and management of respiratory diseases. According to evidence from the Framingham Heart Study, more cases of heart failure in women (14%) than men (11%) can be attributed to obesity (Haslam, 2005). Greater measures of BMI (Hu, Willett et al. 2004) or waist circumference (Lennep, Westerveld et al. 2002; Behan and Mbizo, 2007) have been associated with increased risk for CVD for women. In developed countries such as the U.K., more women than men are exhibiting risky waist circumference measures (Haslam, 2005). Furthermore, women's risk changes as they age. While men tend to gain more abdominal weight than women prior to menopause, after menopause women's fat distribution is increasingly localized in the abdominal area (Ley, Lees et al. 1992; Horiuchi, 1997). This may contribute to women's increased risk of developing CVD post-menopause.

Some evidence indicates that obesity is also associated with greater risk for respiratory disease. In particular, obesity may cause changes in estrogen levels that exacerbate respiratory diseases, such as asthma and COPD, by increasing bronchial hyper-responsiveness (BHR) (Sood, Dawson et al. 2005).

Smoke and airborne contaminant exposure

Smoke exposure, both active and passive, is directly associated with the development of both chronic respiratory and cardiovascular diseases. Women may be more susceptible to the damaging effects of smoke on both their lung and heart health. Evidence from Denmark reveals that given the same amount of tobacco use, women are more likely to develop lung diseases earlier and have more severe expression (Prescott, Bjerg et al. 1997). Studies conducted in the U.S., Japan and Taiwan have also found that women who are exposed to similar levels of environmental tobacco smoke (ETS) have a greater risk for developing lung cancer than men (Hirayama, 1981; Bennett, Alavanja et al. 1999; Lee, Ko et al. 2000). Other potential risks to respiratory health include toxic airborne pollutants such as: moulds, nitrous dioxide, formaldehyde, radon and emission from wood burning stoves or the burning of fossil fuels (Public Health Agency of Canada 2007), which have been shown to have either a stronger or similar impact on women, as compared to men in studies conducted in Italy, Taiwan and the U.S. (Biggeri, Pasetto et al. 2004; Chiu, Cheng et al. 2006; Kennedy, Chambers et al. 2007).

Women's enhanced susceptibility to the respiratory health effects of cigarettes and airborne contaminants may be due to biological factors such as: greater deposition of toxic substances in the lung, impaired clearance of toxins, and/or exaggerated biological responses to these toxins (Sin, Cohen et al. 2007). Some evidence shows that women may have increased bronchial hyper-responsivity when compared with men, which increases women's risk of developing respiratory diseases (including asthma and COPD), when confronted with smoke and airborne contaminant exposure (Kanner, Connett et al. 1994). Women also have relatively smaller airways in comparison to men, which may enhance their susceptibility to smoke and pollutant exposures (Caracta, 2003). Further, gastrin releasing peptide receptor (GRPR) can cause growth stimulation in lung cancers and may be activated at an earlier stage in women who are exposed to tobacco smoke, either actively or passively (Caracta, 2003). An increased expression of the receptor in females for all levels of smoking has been reported (Caracta, 2003). Lastly, estrogen mediates and potentially enhances the effects of smoke exposure, radon or cooking fumes (Zang and Wynder, 1996; Tang, Rundle et al. 1998; Siegfried, 2001).

Active and passive smoking also increases women's risk of cardiovascular disease (CVD). Smoking has been identified as a stronger risk factor for myocardial infarction (MI) in women than in men, has been linked with early menopause, and has an unfavorable effect on plasma lipoproteins (Lennep, Westerveld et al. 2002). More than half of MI's in middle-aged women are due to smoking (Mather, 2004), and relative risk is approximately 50% higher in female smokers compared with male smokers for both MI and all cause mortality (Prescott, Scharling et al. 2002). Evidence also reveals that exposure to ETS increases women's risk of dying from heart disease (Kaur, Cohen et al. 2004; Barnoya and Glantz, 2005). Some evidence suggests that the anti-oestrogenic effects of smoking may increase women's susceptibility to heart disease, but further research is required (Prescott, Scharling et al. 2002).

Gender and diversity related patterns of exposure

Gender roles impact how and when women smoke and are exposed to ETS. For the first time, in many parts of the world, young women's smoking rates are more often equal to or surpassing boys’, contrary to past trends (Wilson, 2000), and women are more often exposed to ETS (Siegfried, 2001). While more men than women report smoking in their workplace, women are more often exposed to ETS in the home (Ernster, Kaufman et al. 2000). Exposure to ETS is widely perceived to be more of a risk for women, due to the lag in smoking trends between men and women resulting in more non-smoking women living with smoking men (Siegfried, 2001). As well, women working at home may be more often subjected to indoor allergens and other airborne contaminants (Harvard Women's Health Watch, 2003).

Furthermore, women who are living on a low income may have greater risk of being exposed to ETS (Amos, Sanchez et al. 2008). Women living on a low income may be more likely to be exposed to smoke, despite the presence of smoke free policies, and have less capacity to control and limit exposures. For example, Levy et al. (2006) found that smoke-free laws had a larger impact on reducing smoke exposure in medium-education versus low-education females (Levy, Mumford et al. 2006).

Radon, fumes from cooking fuels and heating stoves and SHS are three lung carcinogens to which women are exposed by virtue of spending more time in the home, and are a particular threat in developing countries (Siegfried, 2001). For example, studies have found that women were more exposed to biomass (animal manure, peat, etc) in both China (Ramirez-Venegas, Sansores et al. 2006; Sin, Greaves et al. 2007), and Turkey (Behera and Jindal, 1991; Kiraz, Kart et al. 2003; Wang, Zhang et al. 2005) resulting in respiratory symptoms and diseases. In developed countries, however, these risks can be perceived to be either minimal, or not necessarily gender related (Ernster, 1996). While environmental factors such as smoke and airborne contaminant exposure have significant health impacts, there are additional sex, gender and diversity factors that enhance the role of environmental factors in the development of chronic diseases for women.

Obesogenic environments

Environmental conditions may impede women's ability to engage in physical activity, acquire healthful foods, and therefore manage their weight. Obesogenic environments are described as the promotion of inexpensive, energy dense but nutrient deficient foods, and labor saving devices and under-investment in mass transit (Giskes, Kamphuis et al. 2007). As Chopra indicates, these environmental changes can be linked to global processes, such as global economics and the marketing strategies of large food industry corporations (Chopra and Darnton-Hill, 2004). For example, increasing densities of fast food restaurants, marketing and the low pricing of fatty foods, and larger portion sizing are all part of this process (Block, Scribner et al. 2004; Cummins and Macintyre, 2006; Lake and Townshend, 2006; Giskes, Kamphuis et al. 2007). In addition, sprawling communities, heavy traffic and lack of safety also affect access and ability to engage in physical activity, thereby increasing rates of obesity (Booth, Pinkston et al. 2005; Joshu, Boehmer et al. 2008).

Jilcott and colleagues’ U.S.-based study (2006), identified a number of environmental factors which were associated with women's health behaviors and capacity to engage in healthy behaviors (Jilcott, Keyserling et al. 2006). For example, women reported the following barriers: lack of restaurants with healthy food choices (41%), lack of farmers markets or fresh produce (50%), not enough affordable exercise facilities (52%), or women appropriate physical activity programs (42%), heavy traffic (47%), and speeding drivers (53%). Overall, women expressed little awareness of affordable exercise venues or nutrition classes. Similarly, in another U.S. study, high risk women who participated in focus groups cited a number of physical factors which challenged their ability to engage in physical activities, including: weather, limited daylight, lack of sidewalks, traffic and distance (Eyler, Vest et al. 2002). Environmental factors structure women's capacity to engage in preventive health behaviors and may therefore enhance women's risk of chronic respiratory and cardiovascular diseases.

Economically deprived areas

As stated by Kjellstrom et al. (2007), “social determinants often cause their health effects via webs or pathways of environmental exposures” (Kjellstrom, Friel et al. 2007). Clearly, women living on a low income are more likely to live in environments that don't support healthy living (Chaturvedi, 2003; Mobley, Root et al. 2006). For example, participants in two Swedish studies who were living in the most deprived neighborhoods were at a greater risk for smoking, obesity, and physical inactivity, even after adjusting for individual socioeconomic status (Sundquist, Malmstrom et al. 1999; Cubbin, Sundquist et al. 2006). Similarly, Winkleby et al. (2007) suggest that neighborhoods may contribute to morbidity and mortality from heart disease due to psychosocial stress, limited access to healthy foods and exercise opportunities, and other health care opportunities (Winkleby, Sundquist et al. 2007). Furthermore, women who are living on a low income may encounter different or greater risks due to the interactions between sex, gender, socioeconomic status and environment.

Environmental factors that produce chronic stress may also lead to unhealthy behaviors or impede women from attending to their health (DeSalvo, Gregg et al. 2005). A deprived neighborhood has been characterized as an area with high poverty and low educational attainment, as well as a high concentration of households headed solely by women (Ming, Browning et al. 2007). Such areas often have physical signs of deprivation, such as pollution, noise, run-down housing, litter and few spaces for recreation (Ming, Browning et al. 2007). Moreover, the effect of area depravation may be even greater for women than for men. For example, in an American study by Borders et al. (2006), females with lower income had greater odds of obesity, yet economic disparities in men were not significantly associated with greater odds of obesity (Borders, Rohrer et al. 2006). In one Swedish study which explored gender differences in area effect, women's risk of developing coronary heart disease (CHD) was 1.9 times higher than for women living in low-deprivation areas; while for men, it was 1.5 times higher (Winkleby, Sundquist et al. 2007). These differences are partially related to gendered roles and patterns which influence how women and men navigate their environment. Safety concern may be a particularly pertinent barrier to women's health, especially in economically deprived areas. For example, U.S.-based evidence suggests that while women on a low income may be required to be physically active as a form of transport (Ming, Browning et al. 2007), the stress associated with commuting through deprived areas may negate the potential health benefits of being physically active (Bostock, 2001).

Non-white minorities often live in more socially and economically deprived areas, with fewer health resources or opportunities for healthy living (Graham-Garcia, Raines et al. 2001). For example, the consumption of a more energy dense diet is increasingly occurring at lower income levels in the U.S. Block et al. (2004) found that predominantly black and low income neighborhoods in the U.S. had a greater density of fast food restaurants (Block, Scribner et al. 2004). Other U.S.-based research has found that lower income neighborhoods have fewer supermarkets,¹ more neighborhood grocery stores, more fast food outlets, less fitness facilities and higher obesity rates than higher income areas (Morland, Wing et al. 2002). There are also numerous structural barriers to health for women living in rural areas, including: poverty, access to health care providers, health infrastructure and social isolation (Taylor, Hughes et al. 2002). A study by Chikani and colleagues (2005) found that women living in rural areas in the U.S. were at greater risk for coronary heart disease (CHD) (exhibiting more obesity, poorer diet, and higher blood pressure) (Chikani, Reding et al. 2005).

Finally, area deprivation increases morbidity and mortality risk, even for women and men with above average income or education who are living in deprived areas (Winkleby, Sundquist et al. 2007). Although the mechanisms by which area level influences health are unclear, evidence suggests that area level has significance beyond even individual level indicators of socioeconomic status (SES). A U.S. study by Ming et al. (2007) found that the effects of neighborhood SES had a stronger effect than household income in influencing physical activity (Ming, Browning et al. 2007). Furthermore, they found that women's physical activity was more responsive to neighborhood context, when compared to men. Overall, these findings reveal that sex, gender and diversity overlap and interact with the environment in multiple ways, often increasing heart and lung health risks for women, particularly sub-populations of women.