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Healthy lifestyle factors associated with reduced cardiometabolic risk

Published online by Cambridge University Press:  31 January 2011

L. Shi*
Affiliation:
College of Nursing and Health Sciences, University of Massachusetts Boston, 100 Morrissey Boulevard, Boston, MA02125, USA
J. A. Morrison
Affiliation:
Cincinnati Children's Hospital Medical Center, 3333 Burnet Avenue, Cincinnati, OH45229, USA
J. Wiecha
Affiliation:
College of Nursing and Health Sciences, University of Massachusetts Boston, 100 Morrissey Boulevard, Boston, MA02125, USA
M. Horton
Affiliation:
College of Nursing and Health Sciences, University of Massachusetts Boston, 100 Morrissey Boulevard, Boston, MA02125, USA
L. L. Hayman
Affiliation:
College of Nursing and Health Sciences, University of Massachusetts Boston, 100 Morrissey Boulevard, Boston, MA02125, USA
*
*Corresponding author: L. Shi, fax +1 617 287 7527, email ling.shi@umb.edu
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Abstract

Minimal data are available regarding the cumulative effects of healthy lifestyle behaviours on cardiometabolic risk. The objective of the present study was to examine a combination of healthy lifestyle behaviours associated with cardiometabolic risk reduction. The analysis was based on a cross-sectional study of 1454 participants from the population-based Lipid Research Clinic's Princeton Follow-up Study. The healthy lifestyle factors included fruit and vegetable intake ≥ 5 servings/d, meat intake ≤ 2 servings/d, never smoking, consuming 2–6 alcoholic drinks/week, television (TV) viewing time ≤ 2 h/d and moderate to vigorous physical activity ≥ 4 h/week. The combination of healthy lifestyle behaviours was strongly and negatively associated with the presence of cardiometabolic risk, as well as with a composite cardiometabolic risk score after adjustment for race, age, generation and sex. With each additional healthy lifestyle factor, cardiometabolic risk decreased by 31 % (OR 0·69; 95 % CI 0·61, 0·78). A higher healthy lifestyle score was associated with a lower prevalence of cardiometabolic risk (P for trend < 0·001). Compared with individuals having 0–1 healthy lifestyle behaviours, those with 5 or 6 healthy lifestyle behaviours had a 70 % lower prevalence of cardiometabolic risk (OR 0·30; 95 % CI 0·13, 0·67). Healthy lifestyle behaviours including sufficient fruit and vegetable intake, less meat intake, less TV viewing time, abstinence from smoking, modest alcohol intake and regular exercise are associated with reduced cardiometabolic risk.

Type
Full Papers
Copyright
Copyright © The Authors 2011

Cardiometabolic risk is an umbrella term encompassing risk factors for CVD and type 2 diabetes, including increased TAG, fasting glucose, blood pressure, abdominal obesity and reduced HDL-cholesterol(Reference Brunzell, Davidson and Furberg1). An estimated seventy-six million US adults(Reference Ford2) and 2·9 million adolescents of 12–19 years of age(Reference Cook, Auinger and Li3) have the metabolic syndrome and the presence of any three of the above-mentioned five factors. The National Cholesterol Education Program Adult Treatment Panel III guidelines also include elevated LDL-cholesterol in its definition of the metabolic syndrome(4). A previous study has identified the metabolic syndrome as a significant predictor of the development of CVD and type 2 diabetes(Reference Gami, Witt and Howard5). Similarly, the Framingham Risk Score, which includes age, sex, cigarette smoking and the above-mentioned factors, was found to be associated with CHD and stroke(Reference Wannamethee, Shaper and Lennon6).

Metabolic, clinical and epidemiological studies have examined the influence of individual dietary and lifestyle factors on adverse cardiometabolic outcomes, showing that diets characterised by high polyunsaturated fat, low glycaemic index or glycaemic load, and increased consumption of fish, fruits, vegetables, nuts and whole grains appear to reduce the risk of cardiometabolic diseases(Reference Hu and Willett7). Furthermore, increased television (TV) viewing time(Reference Katzmarzyk, Church and Craig8Reference Dunstan, Barr and Healy10), psychosocial stressors(Reference Rugulies11, Reference Wassertheil-Smoller, Shumaker and Ockene12), cigarette smoking(Reference Mitchell, Hwang and Vasan13, Reference Tamura, Tanaka and Okamura14), and both excessive drinking and abstinence from alcohol(Reference Kawano15) were associated with increased cardiovascular risk and mortality.

Healthy dietary and lifestyle patterns tend to co-exist and inter-relate with each other; therefore, it is important to examine dietary and lifestyle factors as a whole. However, only minimal data are available regarding the cumulative effects of healthy lifestyle behaviours on cardiometabolic risk. Stampfer et al. (Reference Stampfer, Hu and Manson16) examined the effect of a combination of modifiable factors including smoking, alcohol drinking, physical activity, BMI and diet on the risk of CHD among 84 129 women in the Nurses' Health Study. The outcome of interest was major coronary events which occurred rarely among subjects within the low-risk categories, making it hard to provide reliable estimates of the effects(Reference Stampfer, Hu and Manson16). A few studies have identified diet and lifestyle behaviours associated with the risk of heart failure(Reference Djoussé, Driver and Gaziano17) and hypertension(Reference Forman, Stampfer and Curhan18), but the effect of these behaviours on the clustering of cardiometabolic risk factors (rather than the actual disease) has not been evaluated.

The present study was based on a population-based, cross-sectional sample from the Lipid Research Clinic (LRC)'s Princeton Follow-up Study (PFS) to examine the effect of a combination of lifestyle behaviours (including fruit and vegetable intake, meat intake, smoking, alcohol consumption, physical activity and TV viewing time) on cardiometabolic risk reduction.

Methods

Study population

The analysis was based on 1454 participants from the PFS (1998–2003) who were followed up from the National Heart, Lung and Blood Institute LRC Prevalence Study in Cincinnati (1973–8). A detailed description of the LRC and PFS has been published elsewhere(Reference Tyroler19Reference Friedman, Morrison and Daniels21). Briefly, the LRC was a multi-centre, multi-stage epidemiological study of lipids in eleven different populations in the USA and Canada. The LRC study in Cincinnati examined about 7000 students in grades 1–12 and 4500 parents in the Princeton School District. A family identification number was used to identify the familial correlation among parents and children from the same family. Stage 1 measured total cholesterol and TAG in all subjects plus demographic data. Stage 2 measured lipid profiles, blood pressure, BMI, triceps skinfolds, 24 h diet recalls, family history of CVD and twelve-channel clinical chemistries in random and hyperlipidaemic subsets of all stage 1 subjects. Stage 3 repeated stage 2 measures in all first-degree relatives of random and hyperlipidaemic index cases from stage 2, except for blood pressure.

After an average 26 years since their initial participation in the LRC study, eligible former schoolchildren were invited to participate in the PFS along with a sibling or a parent to assess the changes in lifestyles and cardiometabolic risk factors(Reference Tyroler19Reference Friedman, Morrison and Daniels21). Among the 1454 PFS participants, 26 % were black and 56 % were female. There were 432 parents (age 66·5 (sd 6·6) years) and 1022 adult children (age 39·6 (sd 4·9) years).

The study was conducted according to the guidelines laid down in the Declaration of Helsinki, and all procedures involving human subjects were approved by the Cincinnati Children's Hospital institutional review board. Written informed consent was obtained from all subjects. The University of Massachusetts Boston institutional review board approved the data analysis protocol.

Measures and definitions of healthy lifestyle and cardiometabolic risk in the Princeton Follow-up Study

Participants were assessed for sociodemographic characteristics, smoking, alcohol use, medical history and family history of certain diseases using standardised self-administered questionnaires. Dietary intake was measured by a Block-Quantified Food Frequency questionnaire. Information on physical activity was collected through a 7 d physical activity recall using the Paffenbarger Physical Activity Questionnaire, which had been validated against pedometer readings, treadmill tests and VO2max(Reference Paffenbarger, Wing and Hyde22Reference Ainsworth, Leon and Richardson24). Participants' weight, height, waist circumference, blood pressure, LDL-cholesterol, HDL-cholesterol, total cholesterol, TAG, glucose and insulin were measured following standard procedures(Reference Laskarzewski, Morrison and Mellies25).

Diet measures chosen for inclusion in the present study were daily servings of meat, vegetables and fruits. Lifestyle factors were smoking (never/ever smoker), alcohol use (number of alcoholic beverages per week), physical activity (hours of moderate to vigorous physical activity (MVPA) per week) and TV viewing hours per d. Each of these six lifestyle factors has a substantial research base indicating potential reduction in cardiometabolic risk(Reference Wannamethee, Shaper and Lennon6Reference Manson, Greenland and LaCroix9, Reference Wassertheil-Smoller, Shumaker and Ockene12Reference Djoussé, Driver and Gaziano17).

Healthy lifestyle behaviour was defined based on public health recommendations and evidence from the previous literature on associations between individual lifestyle factors and cardiometabolic diseases. For fruit and vegetable intake, the Food Pyramid developed by the US Department of Agriculture recommends 3–5 servings of vegetables and 2–4 servings of fruits each day(26); therefore, a healthy behaviour for fruit and vegetable intake was defined as ≥ 5 servings/d. Because the Food Pyramid recommends 2–3 servings of meat daily(26), we defined a healthy behaviour for meat intake as ≤ 2 servings/d. The cut-off points for smoking status, alcohol consumption, TV viewing time and MVPA time were determined based on the findings from previous studies(Reference Manson, Greenland and LaCroix9, Reference Kawano15, Reference Djoussé, Driver and Gaziano17). For example, the healthy alcohol drinking behaviour was defined as at least 1–2 drinks/week. This is based on the finding that compared with non-drinkers ( < 1 drink/week), regular drinkers had a decreased risk of ischaemic stroke(Reference Kawano15). For TV viewing time, subjects with TV viewing time < 2 h/d had a lower CVD mortality compared with those with more than 2 h/d; therefore, ≤ 2 h TV viewing time was defined as a healthy behaviour(Reference Manson, Greenland and LaCroix9). For physical activity, previous studies found that at least 30 min of MVPA/d, corresponding to 3·5 h/week, was associated with a reduction in the risk of CHD and stroke(Reference Kawano15, Reference Djoussé, Driver and Gaziano17). The MVPA data in the present study were recorded in integers; therefore, we used 4 h/week as our cut-off point. We tested these cut-off points in exploratory data analysis, and found consistent relationships between each healthy lifestyle behaviour, as defined above, and cardiometabolic risk reduction. A combination of healthy lifestyle behaviours included daily fruit and vegetable intake ≥ 5 servings, daily meat intake ≤ 2 servings, never smoking, consuming 2–6 alcoholic drinks/week, TV viewing ≤ 2 h/d and MVPA ≥ 4 h/week. The presence of each behaviour was given a score of 1, so the healthy lifestyle score ranged from 0 to 6.

The primary outcome, cardiometabolic risk, was defined as having at least three of the following conditions: BMI ≥ 25 kg/m2, waist circumference ≥ 102 cm among men or ≥ 88 cm among women, blood pressure ≥ 130/85 mmHg or use of medication for hypertension; fasting blood glucose ≥ 1000 mg/l or use of glucose-lowering medication, total cholesterol ≥ 2000 mg/l, LDL-cholesterol ≥ 1300 mg/l, total TAG ≥ 1500 mg/l or drug treatment for elevated total TAG; and HDL-cholesterol < 400 mg/l in men or < 500 mg/l in women or drug treatment for reduced HDL-cholesterol. The cardiometabolic risk measures were based on recommendations from the Adult Treatment Panel III, the American Heart Association/National Heart, Lung and Blood Institute and the International Diabetes Federation(4, Reference Grundy, Cleeman and Daniels27, Reference Alberti, Zimmet and Shaw28). The secondary outcome of the present study was the composite cardiometabolic risk score, defined as an individual's total number of risk factors. This score varied between 0 and 9.

Statistical analyses

Means and standard deviations were calculated for continuous variables; numbers and proportions were calculated for categorical variables. A mixed-effect generalised linear regression model was used to evaluate associations of individual lifestyle factors with cardiometabolic risk in univariate analyses adjusted for within-family correlation identified by the same family identification number. Covariates including age, sex, race and generation were added to the model in multivariate analyses. OR and 95 % CI were obtained.

Next, each healthy lifestyle factor and the global healthy lifestyle score were examined as predictors of the presence/absence of cardiometabolic risk. The variables for individual healthy lifestyle factors were dichotomous (yes/no). The healthy lifestyle score was initially treated as a continuous variable, but only 1·2 % (eighteen) of the subjects had a healthy lifestyle score of 0, and only 2·6 % (thirty-eight) and 0·07 % (one) had scores of 5 or 6. Consequently, we collapsed the data into five groups to achieve robust sample sizes at the extremes: 0–1 as the reference group, 2, 3, 4 and 5–6. Four dummy variables were created for the five groups of the global healthy lifestyle score. An ordinal score was given to each category of the healthy lifestyle score, and then an analysis of P for a trend test was performed to examine the trend of cardiometabolic risk with increasing healthy lifestyle scores. Coefficients were obtained using the mixed-effect logistic regression because the outcome, cardiometabolic risk, was a binary variable.

We then used the composite score of cardiometabolic risk (i.e. the number of cardiometabolic risks) as the outcome variable. The composite score was categorised into four groups: 0–2 (reference group), 3–4, 5–6 and 7–9, so that each group had a similar sample size. Since the outcome was ordinal, the mixed-effect ordered logistic regression was used to model the likelihood of having 3–4 cardiometabolic risk factors, 5–6 cardiometabolic risk factors and 7–9 cardiometabolic risk factors, v. having 0–2 cardiometabolic risk factors (the reference group), on individual healthy lifestyle factors and then on the healthy lifestyle score, after adjustment for age, sex, race, generation and within-family correlation.

All P values were two-sided, and the significance level was set at 0·05. Data were analysed with Statistical Analysis Software version 9.1 (SAS Institute, Cary, NC, USA).

Results

Table 1 summarises the prevalence of cardiometabolic risk according to demographic characteristics of the study population. Overall, 50·9 % (740 out of 1454) of the subjects had cardiometabolic risk. Males (53 %) and females (49·3 %) had a similar prevalence of cardiometabolic risk, as did Blacks (52·8 %) and Whites (50·2 %) (all P values>0·05). First-generation participants (parents) had a higher prevalence of cardiometabolic risk compared with their children, 66·9 % (289 out of 432) in parents v. 44·1 % (451 out of 1022) in their children (P < 0·001). Within generation, age was positively associated with cardiometabolic risk.

Table 1 Prevalence of cardiometabolic risk* by demographic characteristics

(Number of participants and percentage or mean values and standard deviations)

*  Cardiometabolic risk was defined as having at least three of the following conditions: BMI ≥ 25 kg/m2, waist circumference ≥ 102 cm among men or ≥ 88 cm among women, blood pressure ≥ 130/85 mmHg or use of medication for hypertension; fasting blood glucose ≥ 1000 mg/l or use of glucose-lowering medication, total cholesterol ≥ 2000 mg/l, LDL-cholesterol ≥ 1300 mg/l, total TAG ≥ 1500 mg/l or drug treatment for elevated total TAG; and HDL-cholesterol < 400 mg/l in men or < 500 mg/l in women or drug treatment for reduced HDL-cholesterol.

The univariate and multivariate analyses of associations between individual lifestyle factors and cardiometabolic risk are summarised in Table 2. Daily fruit intake and frequency of alcohol consumption were associated with a decreased prevalence of cardiometabolic risk after adjusting for sex, age, race and generation, whereas daily meat intake, cigarette smoking and TV viewing time were associated with increased cardiometabolic risk (Table 2).

Table 2 Reductions and increases in cardiometabolic risk associated with individual lifestyle factors

(Odds ratios and 95 % confidence intervals)

TV, television.

P < 0·05

 Adjusted for intra-cluster correlation within family.

 Adjusted for age, race, sex, generation and intra-cluster correlation within family.

Then, each lifestyle factor was categorised dichotomously, generating six healthy lifestyle factors, including high fruit and vegetable consumption ( ≥ 5 servings/d), low meat consumption ( ≤ 2 servings/d), never smoking, consuming alcohol regularly (2–6 drinks/week), regularly participating in MVPA ( ≥ 4 h/week) and less TV viewing ( ≤ 2 h/d). About a third (437 out of 1454 or 30·1 %) of the participants had 2 healthy lifestyle behaviours, and 40·6 % (590 out of 1454) and 15·5 % (226 out of 1454) had 3 and 4 healthy lifestyle behaviours, respectively. The remaining 162 subjects (11·1 %) had 0 or 1 healthy lifestyle behaviour, and 39 (2·7 %) had 5 or 6 healthy lifestyle behaviours. As shown in Table 3, in the univariate model adjusted for the intra-cluster correlation within family, low meat consumption (OR 0·77; 95 % CI 0·61, 0·96), regular consumption of alcohol (OR 0·66; 95 % CI 0·52, 0·83), regularly participating in MVPA (OR 0·80; 95 % CI 0·63, 1·00) and less TV viewing time (OR 0·42; 95 % CI 0·23, 0·78) were inversely associated with cardiometabolic risk. These factors remained significant in multivariate analyses after adjustment for race, age, generation and sex, except for physical activity which became marginally significant. In addition, high fruit and vegetable consumption (OR 0·71; 95 % CI 0·55, 0·93) and never smoking (OR 0·69; 95 % CI 0·51, 0·92) were also inversely associated with cardiometabolic risk.

Table 3 Reductions in cardiometabolic risk associated with individual lifestyle factors

(Odds ratios and 95 % confidence intervals)

MVPA, moderate to vigorous physical activity; TV, television.

P < 0·05

 Adjusted for intra-cluster correlation within family.

 Adjusted for age, race, sex, generation and intra-cluster correlation within family.

Next, we examined the healthy lifestyle score, which was the sum of the six healthy lifestyle factors. Fig. 1 shows that with each increment of the healthy lifestyle score, the prevalence of cardiometabolic risk decreased on average by 31 % (OR 0·69; 95 % CI 0·61, 0·78). A linear trend was observed. Compared with individuals having 0–1 healthy lifestyle score, those with 3 healthy lifestyle behaviours had a 47 % lower prevalence of cardiometabolic risk (OR 0·53; 95 % CI 0·36, 0·78), those with 4 healthy lifestyle behaviours had a 68 % lower cardiometabolic risk (OR 0·32; 95 % CI 0·20, 0·51), and those with 5 or 6 healthy lifestyle behaviours had a 70 % lower risk (OR 0·30; 95 % CI 0·13, 0·67). A higher healthy lifestyle score was associated with a lower prevalence of cardiometabolic risk (P for trend < 0·001).

Fig. 1 Linear trend between the global healthy lifestyle score and cardiometabolic risk.

Table 4 presents results from the ordered logistic regression on the association between healthy lifestyle factors and the composite score of cardiometabolic risk, which are further visualised in Fig. 2. There were statistically significant inverse relationships between the presence of healthy lifestyle behaviours and cardiometabolic risk score. For example, individuals who consumed alcohol regularly, compared with those who did not, had 27 % lower odds of a composite cardiometabolic risk score of 3–4 v. 0–2 (OR 0·73; 95 % CI 0·54, 0·98), and the protective effect of alcohol consumption increased as the cardiometabolic risk score increased. The findings were similar for the healthy lifestyle score. With every increment in healthy lifestyle score, the odds of a cardiometabolic risk score of 3–4 v. 0–2 were 18 % lower (OR 0·82; 95 % CI 0·72, 0·95), the odds of having the score as 5–6 v. 0–2 were 32 % lower (OR 0·68; 95 % CI 0·59, 0·79), and the odds of having the score as 7–9 v. 0–2 were 36 % lower (OR 0·64; 95 % CI 0·53, 0·78).

Table 4 Associations between individual healthy lifestyle factors, global healthy lifestyle score and the composite score of cardiometabolic risk

(Odds ratios and 95 % confidence intervals)

MVPA, moderate to vigorous physical activity; TV, television.

P < 0·05.

 Adjusted for age, race, sex, generation and intra-cluster correlation within family.

Fig. 2 Associations between healthy lifestyle factors and composite score of cardiometabolic risk. , OR of the cardiometabolic risk composite score 3–4 v. 0–2; , OR of the cardiometabolic risk composite score 5–6 v. 0–2; , OR of the cardiometabolic risk composite score 7–9 v. 0–2. Veg, vegetables; w, weeks; MVPA, moderate to vigorous physical activity; TV, television.

Discussion

Results from the present study indicated that a combination of healthy lifestyle factors including sufficient fruit and vegetable intake, less meat intake, abstinence from smoking, moderate drinking, regular exercise and less TV viewing time was associated with a decreased cardiometabolic risk. Each additional healthy lifestyle factor was associated with a 31 % reduction in cardiometabolic risk. Cardiometabolic risk decreased in a graded manner as the number of healthy lifestyle factors increased. These results support the hypothesis that reductions in cardiometabolic risk are associated with both individual and cumulative adherence to healthy lifestyle behaviours(Reference Lloyd-Jones, Hong and Labarthe29). When individual lifestyle factors were examined individually, most, but not all, factors were associated with cardiometabolic risk reduction.

The lifestyle factors in the present study have been examined individually or jointly by other researchers, and the present study adds to this literature by focusing on precursors to the actual disease rather than on frank disease outcomes as has typically been the case. For example, Chiuve et al. (Reference Chiuve, McCullough and Sacks30) found that a low-risk lifestyle including healthy diet, not smoking, alcohol consumption 5–30 g/d, MVPA ≥ 30 min/d and maintaining BMI < 25 kg/m2 resulted in a 62 % reduction in CHD among men of middle age or later in life. Djoussé et al. (Reference Djoussé, Driver and Gaziano17) found that a combination of BMI < 25 kg/m2, not smoking, exercise ≥ 5 times/week, alcohol intake ≥ 5 drinks/week, breakfast cereal ≥ 1 serving/week and fruits and vegetables ≥ 1 serving/week reduced the risk of heart failure. In another study, adherence to the Mediterranean diet, no smoking and exercise were associated with reduced total cholesterol, LDL-cholesterol and TAG(Reference Sofi, Gori and Marcucci31). In addition, several studies have documented the effects of other lifestyle factors such as folic acid supplementation(Reference Forman, Stampfer and Curhan18, Reference Mangoni, Sherwood and Swift32, Reference van Dijk, Rauwerda and Steyn33), dairy consumption(Reference Moore, Singer and Bradlee34), whole-grain intake(Reference Liu, Manson and Stampfer35) and psychosocial stressors(Reference Yusuf, Hawken and Ounpuu36). To the best of our knowledge, no studies have examined the effect of a combination of healthy lifestyle factors on cardiometabolic risk, which is a precursor of CVD and type 2 diabetes(Reference Wilson, Agostino and Parise37). By targeting lifestyle behaviours associated with cardiometabolic risk, we can prevent and manage risk for cardiometabolic disease and adverse outcomes of these disease processes at the early stages of development.

The present study found that fruit and vegetable intakes, when viewed on a continuous scale, were not significantly associated with cardiometabolic risk, whereas a high intake of fruits and vegetables ( ≥ 5 servings/d) was associated with reduced cardiometabolic risk. This suggests a possible threshold effect of fruit and vegetable consumption on cardiometabolic health. The present findings are consistent with the results of a previous epidemiological study, which found a similar protective effect of a high fruit and vegetable intake. For example, in a study in the USA, compared with people consuming < 3 servings of fruits and vegetables per d, those consuming 5–7 servings per d had a 73 % lower risk for myocardial infarction(Reference Rimm, Ascherio and Giovannucci38). A study in India found that people consuming 3·5 servings of vegetables per d had a threefold lower risk of IHD than did those consuming 0·8 servings/d(Reference Rastogi, Reddy and Vaz39).

Strengths of the present study include the population-based dataset, the objective measurement of cardiometabolic risk and the robustness of the results from different analyses. Healthy lifestyle factors were tested individually and jointly as a composite healthy lifestyle score, while the outcome, cardiometabolic risk, was measured both dichotomously and as a composite risk score. The results were largely consistent across the analyses, corroborating the evidence of the effect of a healthy lifestyle on cardiometabolic risk. The finding that MVPA was not individually associated with cardiometabolic risk reduction and showed no discernible dose–response pattern is surprising in the light of substantial literature to the contrary and may indicate a low validity of the MVPA data (see later for further discussion on a possible recall error in physical activity data). The absence of a statistically significant effect of cigarette smoking, conversely, probably reflects the sample size given the width of the CI.

The study is limited, however, by the cross-sectional design, which does not allow us to establish the time sequence of exposure and outcome, therefore preventing us from inferring causality. The selection bias in the cross-sectional design may also affect the estimated associations from the present study. Participants with a very unhealthy lifestyle and lethal cardiometabolic outcomes may not be included in the study, which is likely to lead to an underestimation of the effect of the lifestyle factors on cardiometabolic risk. A prospective, longitudinal study is desired to obtain more conclusive evidence on the temporal relationship between lifestyle and cardiometabolic risk.

Physical activity was measured by 7 d physical activity recall using the Paffenbarger Physical Activity Questionnaire in the present study(Reference Paffenbarger, Wing and Hyde22). Physical activity is a complex behaviour with four major components, frequency, intensity, duration and mode, which makes it difficult to obtain accurate measurement of all these components(Reference Heyward40). The 7 d recall method is practical and feasible for administering to large populations of individuals; however, due to its subjective nature in methodology, it is subject to recall error and unable to quantify physical activity with sufficient accuracy and precision. When compared with the doubly labelled water method, which is the criterion method to evaluate physical activity-related energy expenditure, this 7 d recall method has a low accuracy in the estimation of physical activity-related energy expenditure for individuals under free-living conditions. In addition, it is imprecise with an underestimation of physical activity-related energy expenditure in the most-active individuals and an overestimation in the least-active individuals(Reference Leenders, Sherman and Nagaraja41). It was found that MVPA was not individually associated with cardiometabolic risk reduction in the present study, indicating a low validity of the MVPA data measured by the 7 d recall method.

Another limitation of the present study is that some potential confounders such as education and income plus unknown confounders were not adjusted for, so a potential confounding effect could not be ruled out. Future study should use a longitudinal study design to examine the impacts of lifestyle in early life on cardiometabolic risk in later life. In addition, diet appears to be important for cardiometabolic risk in the present study, but we used only three aspects of dietary intake – fruits, vegetables and meat. Other dietary components such as total energy intake, fat, sugar, fibre intake, etc., which may influence CVD risk, were not included in the analyses.

Results from the present study provide further evidence supporting the beneficial effect of healthy lifestyle behaviours on cardiometabolic risk. It has important public health implications regarding the prevention of cardiometabolic disease.

Acknowledgements

L. S., J. A. M., J. W. and L. L. H. designed the study; L. S. performed the statistical analyses and wrote the manuscript; M. H. conducted the literature review; J. A. M., L. L. H. and J. W. edited the manuscript and helped with the interpretation and discussion of results. All authors approved the final manuscript. The authors do not have any conflicts of interest. The present study was supported by research grant HL62394 from the National Institutes of Health (J. A. M.) and the Joseph P. Healey from the University of Massachusetts Boston (L. S.).

References

1Brunzell, J, Davidson, M, Furberg, C, et al. (2008) Lipoprotein management in patients with cardiometabolic risk: consensus statement from the American Diabetes Association and the American College of Cardiology Foundation. Diabetes Care 31, 811822.Google Scholar
2Ford, E (2005) Prevalence of the metabolic syndrome defined by the International Diabetes Federation among adults in the U.S. Diabetes Care 28, 27452749.Google Scholar
3Cook, S, Auinger, P, Li, C, et al. (2008) Metabolic syndrome rates in United States adolescents, from the National Health and Nutrition Examination Survey, 1999–2002. J Pediatr 152, 165170.Google Scholar
4Expert Panel on Detection E, and Treatment of High Blood Cholesterol in Adults. Executive summary of the third report of the National Cholesterol Education Program (NCEP) Expert Panel on Detection, Evaluation, and Treatment of High Blood Cholesterol in Adults (Adult Treatment Panel III). (2001) JAMA 285, 24862497.Google Scholar
5Gami, A, Witt, B, Howard, D, et al. (2007) Metabolic syndrome and risk of incident cardiovascular events and death: a systematic review and meta-analysis of longitudinal studies. J Am Coll Cardiol 49, 403414.Google Scholar
6Wannamethee, S, Shaper, A, Lennon, L, et al. (2005) Metabolic syndrome vs Framingham Risk Score for prediction of coronary heart disease, stroke, and type 2 diabetes mellitus. Arch Intern Med 165, 26442650.Google Scholar
7Hu, F & Willett, W (2002) Optimal diets for prevention of coronary heart disease. JAMA 288, 25692578.Google Scholar
8Katzmarzyk, P, Church, T, Craig, C, et al. (2009) Sitting time and mortality from all causes, cardiovascular disease, and cancer. Med Sci Sports Exerc 41, 9981005.Google Scholar
9Manson, J, Greenland, P, LaCroix, A, et al. (2002) Walking compared with vigorous exercise for the prevention of cardiovascular events in women. N Engl J Med 347, 716725.Google Scholar
10Dunstan, D, Barr, E, Healy, G, et al. (2010) Television viewing time and mortality. The Australian Diabetes, Obesity and Lifestyle Study (AusDiab). Circulation 121, 384391.Google Scholar
11Rugulies, R (2002) Depression as a predictor for coronary heart disease a review and meta-analysis. Am J Prev Med 23, 5161.Google Scholar
12Wassertheil-Smoller, S, Shumaker, S & Ockene, J (2004) Depression and cardiovascular sequelae in postmenopausal women. Arch Intern Med 164, 289298.Google Scholar
13Mitchell, G, Hwang, S, Vasan, R, et al. (2010) Arterial stiffness and cardiovascular events. The Framingham Heart Study. Circulation 121, 505511.Google Scholar
14Tamura, U, Tanaka, T, Okamura, T, et al. (2010) Changes in weight, cardiovascular risk factors and estimated risk of coronary heart disease following smoking cessation in Japanese male workers: HIPOP-OHP Study. J Atheroscler Thromb 17, 1220.Google Scholar
15Kawano, Y (2010) Physio-pathological effects of alcohol on the cardiovascular system: its role in hypertension and cardiovascular disease. Hypertens Res 33, 181191.Google Scholar
16Stampfer, M, Hu, F, Manson, J, et al. (2000) Primary prevention of coronary heart disease in women through diet and lifestyle. N Engl J Med 343, 1622.Google Scholar
17Djoussé, L, Driver, JA & Gaziano, JM (2009) Relation between modifiable lifestyle factors and lifetime risk of heart failure. JAMA 302, 394400.Google Scholar
18Forman, JP, Stampfer, MJ & Curhan, GC (2009) Diet and lifestyle risk factors associated with incident hypertension in women. JAMA 302, 401411.Google Scholar
19Tyroler, HA (1980) Epidemiology of plasma high-density lipoprotein cholesterol levels. The Lipid Research Clinics Program Prevalence Study. Introduction. Circulation 62, IV1IV3.Google Scholar
20Morrison, J, Kelly, K & Horvitz, R (1982) Parent–offspring and sibling lipid and lipoprotein associations during and after sharing of household environments: the Princeton School District Family Study. Metabolism 31, 158164.Google Scholar
21Friedman, LA, Morrison, JA, Daniels, SR, et al. (2006) Sensitivity and specificity of pediatric lipid determinations for adult lipid status: findings from the Princeton Lipid Research Clinics Prevalence Program Follow-up Study. Pediatrics 118, 165172.Google Scholar
22Paffenbarger, R, Wing, A & Hyde, R (1978) Physical activity as an index of heart attack risk in college alumni. Am J Epidemiol 108, 161175.Google Scholar
23Pereira, M, FitzGerald, S, Gregg, E, et al. (1997) A collection of physical activity questionnaires for health-related research: Paffenbarger physical activity questionnaire. Med Sci Sports Exerc 29, 8388.Google Scholar
24Ainsworth, B, Leon, A, Richardson, M, et al. (1993) Accuracy of the college alumnus physical activity questionnaire. J Clin Epidemiol 46, 14031411.Google Scholar
25Laskarzewski, P, Morrison, J & Mellies, M (1980) Relationships of measurements of body mass to plasma lipoproteins in schoolchildren and adults. Am J Epidemiol 111, 395406.Google Scholar
26US Department of Agriculture (2003) The Food Guide Pyramid. http://www.nal.usda.gov/fnic/Fpyr/pmap.htm.Google Scholar
27Grundy, S, Cleeman, J & Daniels, S (2005) Diagnosis and management of the metabolic syndrome: an American Heart Association/National Heart, Lung, and Blood Institute Scientific Statement. Circulation 112, 27352752.Google Scholar
28Alberti, K, Zimmet, P & Shaw, J (2005) The metabolic syndrome – a new worldwide definition. Lancet 366, 10591062.Google Scholar
29Lloyd-Jones, DM, Hong, Y, Labarthe, D, et al. (2010) Defining and setting national goals for cardiovascular health promotion and disease reduction: The American Heart Association's strategic impact goal through 2020 and beyond. Circulation 121, 586613.Google Scholar
30Chiuve, SE, McCullough, ML, Sacks, FM, et al. (2006) Healthy lifestyle factors in the primary prevention of coronary heart disease among men. Circulation 114, 160167.Google Scholar
31Sofi, F, Gori, A, Marcucci, R, et al. (2007) Adherence to a healthful life attenuates lipid parameters among a healthy Italian population. Nutr Metab Cardiovasc Dis 17, 642648.Google Scholar
32Mangoni, A, Sherwood, R & Swift, C (2002) Folic acid enhances endothelial function and reduces blood pressure in smokers: a randomized controlled trial. J Intern Med 252, 497503.Google Scholar
33van Dijk, R, Rauwerda, J, Steyn, M, et al. (2001) Long-term homocysteine-lowering treatment with folic acid plus pyridoxine is associated with decreased blood pressure but not with improved brachial artery endothelium-dependent vasodilation or carotid artery stiffness: a 2-year, randomized, placebo-controlled trial. Arterioscler Thromb Vasc Biol 21, 20722079.Google Scholar
34Moore, L, Singer, M & Bradlee, M (2005) Intake of fruits, vegetables, and dairy products in early childhood and subsequent blood pressure change. Epidemiology 16, 411.Google Scholar
35Liu, S, Manson, J & Stampfer, M (2000) A prospective study of whole-grain intake and risk of type 2 diabetes mellitus in US women. Am J Public Health 90, 14091415.Google Scholar
36Yusuf, S, Hawken, S, Ounpuu, S, et al. (2004) Effect of potentially modifiable risk factors associated with myocardial infarction in 52 countries (the INTERHEART study): case–control study. Lancet 364, 937952.Google Scholar
37Wilson, PWF, Agostino, RBD, Parise, H, et al. (2005) Metabolic syndrome as a precursor of cardiovascular disease and type 2 diabetes mellitus. Circulation 112, 30663072.Google Scholar
38Rimm, E, Ascherio, A, Giovannucci, E, et al. (1996) Vegetable, fruit, and cereal fiber intake and risk of coronary heart disease among men. JAMA 175, 447451.Google Scholar
39Rastogi, T, Reddy, K, Vaz, M, et al. (2004) Diet and risk of ischemic heart disease in India. Am J Clin Nutr 79, 582592.Google Scholar
40Heyward, V (2006) Advanced Fitness Assessment and Exercise Prescription, 5th ed.Champaign, IL: Human Kinetics.Google Scholar
41Leenders, N, Sherman, W, Nagaraja, H, et al. (2001) Evaluation of methods to assess physical activity in free-living conditions. Med Sci Sports Exerc 33, 12331240.Google Scholar
Figure 0

Table 1 Prevalence of cardiometabolic risk* by demographic characteristics(Number of participants and percentage or mean values and standard deviations)

Figure 1

Table 2 Reductions and increases in cardiometabolic risk associated with individual lifestyle factors(Odds ratios and 95 % confidence intervals)

Figure 2

Table 3 Reductions in cardiometabolic risk associated with individual lifestyle factors(Odds ratios and 95 % confidence intervals)

Figure 3

Fig. 1 Linear trend between the global healthy lifestyle score and cardiometabolic risk.

Figure 4

Table 4 Associations between individual healthy lifestyle factors, global healthy lifestyle score and the composite score of cardiometabolic risk(Odds ratios and 95 % confidence intervals)

Figure 5

Fig. 2 Associations between healthy lifestyle factors and composite score of cardiometabolic risk. , OR of the cardiometabolic risk composite score 3–4 v. 0–2; , OR of the cardiometabolic risk composite score 5–6 v. 0–2; , OR of the cardiometabolic risk composite score 7–9 v. 0–2. Veg, vegetables; w, weeks; MVPA, moderate to vigorous physical activity; TV, television.