Hostname: page-component-78c5997874-mlc7c Total loading time: 0 Render date: 2024-11-04T02:39:12.316Z Has data issue: false hasContentIssue false
  • English
  • Français

Association of an evolutionary-concordance lifestyle pattern score with incident CVD among Black and White men and women

Published online by Cambridge University Press:  09 August 2022

Ziling Mao ,
Alyssa N. Troeschel ,
Suzanne E. Judd ,
James M. Shikany ,
Emily B. Levitan ,
Monika M. Safford  and
Roberd M. Bostick Open the ORCID record for Roberd M. Bostick [Opens in a new window]
Ziling Mao
Affiliation:
Department of Epidemiology, Rollins School of Public Health, Emory University, Atlanta, GA, USA
Alyssa N. Troeschel
Affiliation:
Department of Epidemiology, Rollins School of Public Health, Emory University, Atlanta, GA, USA
Suzanne E. Judd
Affiliation:
Department of Biostatistics, School of Public Health, University of Alabama at Birmingham, Birmingham, AL, USA
James M. Shikany
Affiliation:
Department of Medicine, Division of Preventive Medicine, University of Alabama at Birmingham, Birmingham, AL, USA
Emily B. Levitan
Affiliation:
Department of Epidemiology, School of Public Health, University of Alabama at Birmingham, Birmingham, AL, USA
Monika M. Safford
Affiliation:
Department of Medicine, Weill Cornell Medical College, New York, NY, USA
Roberd M. Bostick*
Affiliation:
Department of Epidemiology, Rollins School of Public Health, Emory University, Atlanta, GA, USA
*
* Corresponding author: Roberd M. Bostick, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Dietary and lifestyle evolutionary discordance is hypothesised to play a role in the aetiology of CVD, including CHD and stroke. We aimed to investigate associations of a previously reported, total (dietary plus lifestyle) evolutionary-concordance (EC) pattern score with incident CVD, CHD and stroke. We used multivariable Cox proportional hazards regression to investigate associations of the EC score with CVD, CHD and stroke incidence among USA Black and White men and women ≥45 years old in the prospective REasons for Geographic and Racial Differences in Stroke study (2003–2017). The EC score comprised seven equally weighted components: a previously reported dietary EC score (using Block 98 FFQ data) and six lifestyle characteristics (alcohol intake, physical activity, sedentary behaviour, waist circumference, smoking history and social network size). A higher score indicates a more evolutionary-concordant dietary/lifestyle pattern. Of the 15 467 participants in the analytic cohort without a CVD diagnosis at baseline, 1563 were diagnosed with CVD (967 with CHD and 596 with stroke) during follow-up (median 11·0 years). Among participants in the highest relative to the lowest EC score quintile, the multivariable-adjusted hazards ratios and their 95 % CI for CVD, CHD and stroke were, respectively, 0·73 (0·62, 0·86; P trend < 0·001), 0·72 (0·59, 0·89; P trend < 0·001) and 0·76 (0·59, 0·98; P trend = 0·01). The results were similar by sex and race. Our findings support that a more evolutionary-concordant diet and lifestyle pattern may be associated with lower risk of CVD, CHD and stroke.

Keywords

Evolutionary-concordance lifestyleEvolutionary-concordance dietDietsLifestylesCVD riskProspective cohort studies
Type
Research Article
Information
British Journal of Nutrition , Volume 129 , Issue 8 , 28 April 2023 , pp. 1405 - 1414
Check for updates
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of The Nutrition Society

CVD is the leading cause of death and a major cause of disability globally(1). Evidence suggests that a large portion of the CVD burden is attributable to modifiable factors, such as smoking, unhealthy diets, excess adiposity and physical inactivity(Reference Roth, Johnson and Abate2). One potential explanation for this link is through the evolutionary discordance hypothesis, which posits that modern departure from the diet and lifestyle patterns of our hunter-gatherer ancestors may be a primary contributor to chronic disease risk(Reference Konner and Eaton3). This hypothesis led to an increasing popularity of the Paleolithic diet pattern (hereafter referred to as the evolutionary-concordant diet pattern), estimated from archeological and paleontological evidence and studies of extant hunter-gatherer populations and characterised by high intakes of fruits, vegetables, lean meats and nuts and low intakes of grains, dairy products, refined fats and sugars and salt(Reference Konner and Eaton3,Reference Eaton and Konner4) . Other lifestyle behaviours that are more evolutionary concordant include high levels of physical activity, low levels of sedentary behaviour, limited alcohol consumption, energy balances that limit excess adiposity, not using tobacco and high social connectiveness(Reference Eaton and Konner4Reference Eaton, Shostak and Konner6).

Evidence from clinical trials suggests that a more evolutionary-concordant diet pattern may be associated with more favourable CVD risk factors and biomarkers(Reference de Menezes, Sampaio and Carioca7,Reference Ghaedi, Mohammadi and Mohammadi8) . Also, observational studies suggest that a more evolutionary-concordant diet pattern may be inversely associated with ageing-related diseases(Reference Whalen, McCullough and Flanders9,Reference Cheng, Um and Prizment10) and CVD mortality(Reference Whalen, Judd and McCullough11,Reference Cheng, Um and Prizment12) . Multiple dietary and lifestyle behaviours coexist and may interact to influence health. Thus, evolutionary-concordance (EC) scores (comprising diet and other lifestyle factors) were developed and reported to reflect the relative closeness of someone’s dietary and lifestyle patterns to evolutionary-concordant patterns(Reference Cheng, Um and Prizment10,Reference Cheng, Um and Prizment12,Reference Troeschel, Hartman and Flanders13) . EC scores were previously reported to be associated with incident colorectal cancer(Reference Cheng, Um and Prizment10) and all-cause and cause-specific mortality(Reference Cheng, Um and Prizment12,Reference Troeschel, Hartman and Flanders13) . However, only two studies (a prospective study among Spanish adults and a cross-sectional study among Australian adults) reported an association of a dietary EC score with CVD(Reference Wong, Grech and Louie14,Reference de la, Zazpe and Goni15) , and no study has reported an association of a lifestyle EC score, with or without a dietary component, with incident CVD.

Therefore, in the present study, we investigated associations of a previously reported, seven-component EC score(Reference Troeschel, Hartman and Flanders13) (comprising an EC diet score, alcohol consumption, physical activity, sedentary behaviour, waist circumference, tobacco smoking history and social network size) with incident CVD, CHD and stroke, in a large, prospective cohort of White and Black American men and women. We hypothesised that more evolutionary-concordant diet and lifestyle patterns would be associated with lower CVD, CHD and stroke risk.

Methods

Study population and data collection

Details of the REasons for Geographic and Racial Differences in Stroke REGARDS) prospective cohort study were previously described(Reference Howard, Cushman and Pulley16). Briefly, the REGARDS cohort was enrolled January 2003–October 2007 using a stratified random sampling design within geographic-race-sex strata to recruit White and Black American men and women ≥45 years old representing the USA ‘stroke belt’ (North Carolina, South Carolina, Georgia, Arkansas, Tennessee, Alabama, Mississippi and Louisiana) and non-stroke belt regions of the contiguous 48 USA states. REGARDS was conducted according to the guidelines laid down in the declaration of Helsinki, and all procedures involving human subjects/patients were approved by the university of Alabama-Birmingham institutional review board (approval # IRB-020925004). Written informed consent was obtained from all study participants at enrollment. The telephone response and cooperation rates(17) were 33 % and 49 %, respectively(Reference Howard, Kleindorfer and Judd18). A total of 30 239 participants were initially enrolled. After enrollment, information on participant demographics, medical history and lifestyle behaviours (physical activity, alcohol consumption, social network size, sedentary behaviour and smoking history) were collected via computer-assisted telephone interviews, followed approximately 3–4 weeks later by an in-home visit conducted by trained study staff to conduct anthropometry, including waist circumference, and measure blood pressures. During the in-home visit, participants were also given the previously validated, self-administered 110-item Block98 FFQ to assess their usual diet over the past year, to complete and return by mail(Reference Boucher, Cotterchio and Kreiger19). Total energy and nutrient intakes were calculated by adding energy and nutrients from all food and supplement sources using the dietary database developed by Block et al.(Reference Block, Hartman and Dresser20) and maintained by NutritionQuest(21). Physical activity and alcohol intakes were assessed via open-ended questions regarding how many times per week the participant engaged in physical activity intense enough to work up a sweat (a previously validated measure)(Reference Washburn, Adams and Haile22,Reference Washburn, Goldfield and Smith23) and on current consumption of alcoholic beverages (reported as drinks per day, week, month or year), respectively. Self-reported measures of alcohol intake were previously shown to be reasonably valid(Reference Del Boca and Noll24,Reference Del Boca and Darkes25) . Sedentary behaviour was assessed via the self-reported average number of hours the participant spent watching television or video(Reference Salmon, Owen and Crawford26) (response choices were none, > 0–6 h/week, 1 h/d, 2 h/d, 3 h/d and 4+ h/d). Social network size was assessed via two open-ended questions regarding the self-reported number of friends and relatives the participant felt ‘close’ to (i.e. ‘feel at ease with, can talk to about private matters, and can call on for help’)(Reference Berkman and Syme27)

Of the 30 239 participants enrolled, for the present analyses, we excluded those with data anomalies (n 56), missing dietary data (n 8547) or lifestyle EC components (n 1810), with an implausible waist circumstance (≤ 51 cm) (n 20), with a BMI < 18·5 kg/m2 (n 207), lost to follow-up (n 168) or diagnosed with CHD (n 3287) or stroke (n 677) at baseline, yielding an analytic sample of 15 467 participants (51·2 % of cohort participants). The characteristics of the excluded participants were similar to those included except that they were more likely to have comorbid conditions, be Black American and have incomes < $20k (the latter two were mostly attributable to missing FFQ data).

Evolutionary-concordance score components and calculations

Details of the construction of the equal-weight, multi-component total EC score were previously published(Reference Troeschel, Hartman and Flanders13) and are summarised below. A seven-component total EC score, which included one thirteen-component dietary EC score and six major lifestyle factors (alcohol intake, physical activity, sedentary behaviour, excess adiposity, smoking history and social network size), was developed to reflect overall closeness to a more evolutionary-concordant total (including lifestyle and diet) pattern(Reference Troeschel, Hartman and Flanders13). A lifestyle EC score limited to the six non-dietary major lifestyle factors was also calculated. Details on how each of the EC score’s components was calculated and scored are described below and summarised in Table 1. Briefly, we first categorised each of the seven components into five categories, as described further below, which we assigned values from 1 to 5, with higher scores indicating greater evolutionary concordance, and then we summed the individual components’ scores such that the total score could range from 7 to 35.

Table 1. Components and construction of the total evolutionary-concordance score* in the REasons for Geographic and Racial Differences in Stroke cohort study (REGARDS)

hrs., hours; yrs., years; EC, evolutionary-concordance; wk., week.

* The possible range for the seven-component score was 7–35; a higher score indicates a more evolutionary-concordant lifestyle pattern.

Self-reported average hours per week spent watching television or video (none, 1–6 h/week, 1 h/d, 2 h/d, 3 h/d and ≥ 4 h/d); response categories ‘none’ and ‘1–6 h/week’ combined for inclusion in a five-point scale.

Measured by trained personnel during an in-home visit.

§ See text and online Supplemental Table 1 for details on the construction of the thirteen-component diet score; of a possible score range of 13 to 65, the actual score range in the study population was 17–60; a higher score indicates a more evolutionary-concordant dietary pattern.

|| Self-reported times per week the participant engaged in physical activity intense enough to work up a sweat (open-ended).

Self-reported number of friends and relatives the participant felt ‘close’ to (open-ended).

As previously described, the thirteen-component dietary EC score, with a possible range from 13 to 65, was calculated using FFQ data(Reference Whalen, Judd and McCullough11), except that alcohol was excluded from the diet score(Reference Troeschel, Hartman and Flanders13). Briefly, each of the thirteen dietary components (online Supplemental Table 1) was divided into quintiles based on the sex-specific distribution of intakes at baseline. For the lowest to the highest quintile, respective scores of 1–5 were assigned for dietary exposures for which higher intakes were considered more evolutionarily concordant (vegetables, fruits, lean meats, fish, nuts, diversity of fruits and vegetables and Ca (calculated as the residuals from the regression of total Ca intake on total dairy intake to account for Ca intake fully adjusted for dairy intake)), and scores of 5–1 for dietary exposures for which lower intakes were considered more evolutionarily concordant (red/processed meats, dairy products, grains, baked goods, sugar-sweetened beverages and Na). These values were then summed, with a higher score indicating a more evolutionary-concordant diet pattern. When included as a total EC score component, the dietary EC score was categorised according to quintiles of its distribution in the analytic population at baseline, and the quintiles assigned values of 1–5, with a higher score indicating higher evolutionary concordance.

To calculate the total EC score, we first categorised the information on the six non-dietary lifestyle factors as described below, and then assigned scores to each category according to the values shown in Table 1. From self-reported information on current alcohol intake (drinks per week), we categorised alcohol intake as none and sex-specific quartiles among those who drank. We defined never smokers as those who reported smoking < 100 cigarettes in their lifetime and categorised former and current smokers according to quartiles of smoking pack-years (calculated by multiplying the average number of packs smoked per day by the years smoked). To reflect excess adiposity for our analyses, we used waist circumference rather than BMI (waist circumference was more directly associated with risk for various outcomes in REGARDS than was BMI(Reference Troeschel, Hartman and Flanders13,Reference Kramer, Gutiérrez and Judd28) , and hip circumference was not measured). We categorised waist circumference (cm), measured by trained personnel during the in-home visit, according to sex-specific quintiles. Given the limited response options for physical activity and sedentary behaviour, we combined responses according to intervals shown in Table 1. We then summed the values for the six lifestyle components and the dietary EC component to yield the total EC score, with a higher score indicating higher overall evolutionary concordance.

Collection of outcome information and time to follow-up

Our primary outcome of interest was incident CVD, defined as the first occurrence of CHD (fatal or non-fatal myocardial infarction or death due to CHD), or stroke (fatal or non-fatal, ischaemic or haemorrhagic). We also considered incident CHD and stroke separately as secondary outcomes of interest in the present study. Briefly, study participants or their designated proxies were contacted by study staff every 6 months to ascertain CVD events and deaths(Reference Howard, Cushman and Pulley16). For reported hospitalisations, physician visits and deaths, REGARDS personnel retrieved medical records, death certificates and autopsy reports, and CVD events and related deaths were adjudicated by a committee of trained adjudicators(Reference Howard, Cushman and Pulley16).

We calculated follow-up time as the time between the date of baseline questionnaire completion and the date of a CHD or stroke diagnosis (for CVD analyses, for participants who became diagnosed with both, we used the date of the first diagnosis), the date of death or the end of the last follow-up (31 December 2017), whichever was first.

Statistical analyses

Main analyses

We summarised participant characteristics at baseline overall and by total EC score quintiles, using descriptive statistics. To investigate associations of the total, dietary and lifestyle EC score quintiles with incident CVD, CHD and stroke, we used multivariable Cox proportional hazards regression models to calculate adjusted hazards ratios (HR) and their corresponding 95 % CI. We included the median values of each score quintile as continuous variables in corresponding models to test for trend. We also estimated the cumulative incidence of CVD, CHD and stroke, using methods for competing risks analysis in all models(Reference Gray29,Reference Liu, Nickleach and Zhang30) and reported it within quintiles of the total, dietary and lifestyle EC scores.

We identified potential model covariates based on biological plausibility and previous literature. In all multivariable models, we adjusted for age (years), race (Black, White), annual household income (< $20k, 20–34k, 35–74k, ≥75k, missing), education status (< high school, high school, some ≥college and ≥college), health insurance (yes/no), sex/current postmenopausal hormone (PMH) use (male, female with PMH use, female without PMH use), region of residence (stroke belt/non-stroke belt), statin use (yes/no), family history of CVD in a first-degree relative (yes/no), regular (≥twice/week) aspirin use (yes/no), regular (≥twice/week) non-aspirin non-steroidal anti-inflammatory drug (NSAID) use (yes/no), total energy intake (kcal/d), history of diabetes mellitus (yes/no), history of hypertension (yes/no), baseline systolic and diastolic blood pressures (mmHg), history of cancer (yes/no) and history of kidney failure (yes/no). Approximately 11 % of participants were missing data on income, so we conducted analyses using a missing indicator variable for missing income (< 5 % were missing data on all other covariates, so missing indicators were not used for those variables). The dietary EC score model additionally adjusted for the individual lifestyle EC score components (alcohol intake, smoking history, waist circumference, physical activity, sedentary behaviour and social network). The lifestyle EC score model additionally adjusted for the dietary EC score. We assessed proportional hazards assumptions using Schoenfeld residuals for each exposure and covariate.

Supplemental and sensitivity analyses

We conducted stratified analyses to assess whether the associations of total EC score quintiles with incident CVD, CHD and stroke differed by categories of selected participant characteristics at baseline. For these analyses, we stratified on sex, age (< 65/≥ 65 years), race (Black/White), region (stroke belt/non-stroke belt), comorbidity conditions (defined as cancer, kidney failure, diabetes, statin user or hypertension) (yes/no) and smoking status (ever/never smoked). We included EC score quantile x stratification factor interaction terms in the Cox proportional hazards regression models to assess potential multiplicative statistical interaction; to test for the statistical significance of the interaction terms, we used likelihood ratios based on models with and without the interaction terms. For the analysis stratified on smoking status, we excluded smoking from the total EC score and additionally adjusted for smoking history (pack-years) for those who ever smoked. For the analysis stratified on comorbidity status, since the number of cases in the ‘no comorbidity’ stratum was small, we analysed that stratum according to total EC score tertiles; to facilitate comparisons across comorbidity strata and between the ‘yes comorbidity’ stratum and strata of other stratification factors, we categorised the ‘yes comorbidity’ stratum according to total EC score tertiles and quintiles.

We also conducted several sensitivity analyses. To investigate the relative importance of each of the total EC score’s components, we first assessed the multivariable-adjusted associations of the seven independent components in the EC score – each modeled using the five categories described in Table 1 – with incident CVD. The model for each individual score component additionally adjusted for the other six components. Second, we removed individual components from the total EC score (with replacement) one at a time and estimated the associations of the seven reduced scores (each comprising six components) with incident CVD. We then calculated the proportional change in the estimated association of the highest relative to the lowest quintile of each reduced EC score with incident CVD from that for the original total EC score as follows: (HR’ - HR)/HR × 100 %, where HR’ is the HR for a reduced EC score–CVD association, and HR is the HR for the original total EC score–CVD association. As a final sensitivity analysis, to rule out potential reverse causation bias, we excluded participants who became newly diagnosed with CVD within the first year of follow-up.

We conducted all analyses using SAS, version 9.4 (SAS Institute). All P-values were two-sided. We considered P-values ≤ 0·05 or 95 % CI that excluded 1·0 statistically significant.

Results

During follow-up (median 11·0 years, range 0·1–14·8 years), a total of 1563 participants were diagnosed with CVD (967 with CHD, 596 with stroke). Participants in the higher relative to the lower total EC score quintiles were more likely to be White, female, less formally educated, without comorbid conditions, have incomes < $20k/year and take PMH (among women) and, on average, had a lower BMI (Table 2).

Table 2. Selected characteristics of the participants according to quintiles of the total evolutionary-concordance (EC) score at baseline (2003–2007) in the REGARDS cohort study

(Percentages; mean values and standard deviations, n 15 467)

EC, evolutionary-concordance; REGARDS, REasons for Geographic and Racial Differences in Stroke; PMH, postmenopausal hormone; NSAID, non-steroidal anti-inflammatory drug; TV, television.

* Values presented are mean (sd) or percentages. The following variables had missing values: income (11.0 %), insurance (0.1 %), regular NSAID use (0.3 %), regular aspirin use (0.1 %).

See text and Table 1 for details; total EC score quintile ranges were quintile 1, 7–18; quintile 2, 19–20; quintile 3, 21–22; quintile 4, 23–25; quintile 5, 26–35; a higher score indicates a more evolutionary-concordant lifestyle pattern.

North Carolina, South Carolina, Arkansas, Georgia, Tennessee, Alabama, Mississippi and Louisiana.

§ PMH use is described among women only (n 9184). The denominators used to calculate the percentage of women who used PMH within total EC score quintiles were quintile 1, n 1966; quintile 2, n 1466; quintile 3, n 1621; quintile 4, n 2317; quintile 5, n 1814.

|| At least twice/week.

See online Supplemental Table 1 for details; of a possible score range of 13 to 65, the actual score range in the study population was 17–60; a higher score indicates a more evolutionary-concordant dietary pattern.

** Self-reported times per week the participant engaged in physical activity intense enough to work up a sweat.

Associations of the evolutionary-concordance scores with incident CVD, CHD and stroke

Age- and multivariable-adjusted associations of the total, dietary and lifestyle EC scores with incident CVD, CHD and stroke are presented in Table 3. There were statistically significant trends for decreasing hazards of incident CVD, CHD and stroke with an increasing total EC score, and the point estimates for all three outcomes were nearly identical. For example, among participants in the highest relative to the lowest total EC score quintile, the multivariable-adjusted hazards of incident CVD, CHD and stroke over the follow-up period were statistically significantly 27 %, 28 % and 24 % lower, respectively. There also were statistically significant trends for decreasing hazards of incident CVD with increasing dietary and lifestyle EC scores, although the estimated associations were more modest than those for the total EC score. For example, among participants in the highest relative to the lowest dietary and lifestyle EC score quintiles, the multivariable-adjusted hazards for CVD were statistically significantly 16 % and 21 % lower, respectively. The estimated inverse associations of the dietary and lifestyle EC scores with CHD and stroke were also more modest than those for the total EC score, but only the findings for the lifestyle EC score were statistically significant.

Table 3. Associations of evolutionary-concordance (EC) scores with incident CVD, CHD and stroke among participants in the REGARDS cohort study (n 15 476), 2003–2017

(Hazards ratios and 95 % confidence intervals)

EC, evolutionary-concordance; REGARDS, REasons for Geographic and Racial Differences in Stroke; HR, hazards ratio; ref., reference.

* For construction of scores, see text and Table 1; a higher score indicates a more evolutionary-concordant lifestyle pattern; lifestyle EC score comprised all score components in Table 1 except for the dietary EC score.

CVD includes CHD and stroke.

From Cox proportional hazards model, adjusted only for age (years).

§ From multivariable Cox proportional hazards models. All fully adjusted models adjusted for age (years), race (Black/White), income (< $20 k, 20–34 k, 35–74 k, ≥75 k, missing), education status (< high school, high school, some college, ≥college), health insurance (yes/no), sex/postmenopausal hormone use (male, female with postmenopausal hormone use, female without postmenopausal hormone use), statin use (yes/no), baseline systolic and diastolic blood pressures (mmHg), region (stroke belt/non-stroke belt), history of diabetes mellitus (yes/no), history of hypertension (yes/no), history of cancer (yes/no), history of kidney failure (yes/no), regular (twice/week or more) aspirin use (yes/no), regular (twice/week or more) non-aspirin NSAID use (yes/no), total energy intake; the model for CHD was additionally adjusted for family history of CHD in a first-degree relative (yes/no), the model for stroke was additionally adjusted for family history of stroke in a first-degree relative (yes/no), and the model for CVD was additionally adjusted for family history of CVD (CHD or stroke) in a first-degree relative (yes/no). The dietary EC score model was additionally adjusted for the six individual lifestyle EC score components (alcohol, smoking, waist circumference, physical activity, sedentary behaviour and social network size; see Table 1 for details). The lifestyle EC score model was additionally adjusted for the dietary EC score.

|| P trend calculated by including the median values of the EC score quintiles as a continuous variable in the corresponding model.

Throughout the study follow-up period, individuals with higher total, dietary and lifestyle EC scores had a lower cumulative incidence of CVD, CHD and stroke than those with lower scores (online Supplemental Fig. 1), consistent with the estimated HR in Table 2. The 14-year cumulative incidences for CVD, CHD and stroke among those in the highest relative to the lowest total EC score quintile were 15·3 % v. 11·5 %, 11·0 % v. 7·8 % and 5·7 % v. 4·8 %, respectively (online Supplemental Fig. 1 and Supplemental Table 2).

Stratified and supplemental analyses

There were no statistically significant or substantial differences in the total EC score–incident CVD associations according to subgroups of selected participant characteristics (online Supplemental Table 3). However, there were some suggestions that the inverse total EC score–incident CVD associations were slightly stronger among Black participants, those residing in the USA stroke belt region, and those with a comorbidity at baseline, but the 95 % CI for the corresponding HR across these strata overlapped considerably (online Supplemental Table 3).

Associations of 1) the total EC score’s individual components and 2) the reduced EC scores, after removing (and replacing) each of the seven components from the total EC score one at a time, with incident CVD are summarised in Supplemental Table 4. Of the individual score components, smoking, followed by waist circumference and then diet, was most strongly associated with incident CVD; among those in the highest relative to the lowest category of smoking and waist circumference, the HR (95 % CI) were 1·52 (1·32, 1·76), 1·27 (1·07, 1·50) and 0·84 (0·70, 1·00), respectively. No single component appeared to account for our findings; however, removal of smoking, waist circumference and diet from the total EC score attenuated the inverse EC score–CVD risk association most (by 15·1 %, 9·6 % and 6·8 %, respectively). However, removal of sedentary behaviour and social network size (which individually were not associated with CVD risk) from the total EC score strengthened the inverse EC score–CVD risk association. In post hoc analyses, concurrent removal of sedentary behaviour and social network size from the total and lifestyle scores further strengthened the associations of those EC scores with CVD risk; for example, among those in the highest relative to the lowest reduced total and lifestyle EC score quintiles, the HR (95 % CI) were 0·67 (0·57, 0·80) and 0·67 (0·56, 0·79), respectively. Excluding participants who became newly diagnosed with CVD during the first year of follow up had only minimal effects on our results (online Supplemental Table 5).

Discussion

Our findings support that a more evolutionary-concordant diet and lifestyle pattern may be associated with lower CVD, CHD and stroke risk among Black and White men and women. Also, in our study, among the seven individual components of our EC score, tobacco smoking contributed the most to the total EC score–incident CVD association, followed by waist circumference (as a marker of central adiposity) and then diet.

Previous evidence from basic science and epidemiologic literature supports that each component of our total EC score could be plausibly linked to lower risk of CVD, including CHD and stroke. An evolutionary-concordant dietary pattern is characterised by higher intakes of fruits and vegetables, nuts and fish – all foods that may be linked to lower CVD risk(Reference Rodríguez-Monforte, Flores-Mateo and Sánchez31,Reference Tapsell, Neale and Probst32) via their anti-oxidative and anti-inflammatory properties(Reference Brown and Hu33Reference Casas-Agustench, Bulló and Salas-Salvadó36). An evolutionary-concordant dietary pattern is also characterised by lower consumption of high fat meats, which are associated with higher CVD risk(Reference McAfee, McSorley and Cuskelly37,Reference Zhong, Van Horn and Greenland38) . Modern red and processed meats are high in saturated fats, which are associated with higher oxidative stress and inflammation(Reference Ghosh, Kewalramani and Yuen39Reference Tappel41). Substantial literature supports that physical activity is inversely associated with CVD risk(Reference Kraus, Powell and Haskell42,Reference Lacombe, Armstrong and Wright43) ; this association may be due to physical activity’s contribution to energy balance (and thus adiposity), lower risk lipid/lipoprotein profiles and lower systemic inflammation(Reference Warburton, Nicol and Bredin44,Reference Pedersen and Saltin45) . Tobacco smoking and heavy alcohol consumption may increase oxidative stress(Reference Vaart, Postma and Timens46Reference Lymperaki, Makedou and Iliadis48). Excess central adiposity (assessed as waist circumference in the present study) is associated with higher CVD risk(Reference Koliaki, Liatis and Kokkinos49,Reference Dwivedi, Dubey and Cistola50) , possibly via higher inflammation and adverse effects on hormones levels and metabolism(Reference Elagizi, Kachur and Lavie51). Previous meta-analyses suggested that longer sedentary time is associated with higher CVD risk(Reference Wilmot, Edwardson and Achana52,Reference Biswas, Oh and Faulkner53) , possibly via several potential mechanisms, including glucose metabolism and inflammatory and oxidative stress pathways(Reference Carter, Hartman and Holder54). Social isolation may be linked to CVD development via several mechanisms, such as causing changes to vascular stress responses and reduced inflammatory responses(Reference Valtorta, Kanaan and Gilbody55,Reference Xia and Li56) . A recent meta-analysis supports that social isolation may be associated with higher CVD risk(Reference Leigh-Hunt, Bagguley and Bash57).

In our study, consistent with the evolutionary discordance hypothesis, participants with lifestyles considered to be the most evolutionary-concordant had approximately 30 % lower CVD risk than those with lifestyles considered to be the least concordant. Previous studies or reviews have reported dietary(Reference Jew, AbuMweis and Jones58Reference Lindeberg60) or lifestyle(Reference Zhang, Chen and Pan61Reference Zhang, Pan and Chen66) patterns/scores that were similar to our EC scores, and their results support our findings of an inverse association of overall more evolutionary-concordant (‘healthier’) lifestyle patterns with CVD risk(Reference Jew, AbuMweis and Jones58Reference Zhang, Pan and Chen66). Despite the differences in the construction of these scores, most of these previously reported lifestyle scores/patterns were developed based on consensus healthy standards and have some common components (e.g. diet, tobacco smoking and physical activity)(Reference Jew, AbuMweis and Jones58Reference Zhang, Pan and Chen66).

To our knowledge, only two reported studies investigated an association of an EC diet pattern (‘Paleolithic diet’ pattern) with CVD(Reference Wong, Grech and Louie14,Reference de la, Zazpe and Goni15) . Consistent with our results, a prospective cohort study among Spanish adults (n 18 210) reported a statistically significant association of an EC dietary score with incident CVD (HRQ5 v . Q1 = 0·45 95 % CI, 0·27, 0·76; P trend = 0·007)(Reference de la, Zazpe and Goni15). Inconsistent with our results, a cross-sectional study among Australian adults (n 5376) reported a null association of an evolutionary-concordant diet pattern with prevalent CVD (OR = 1·08; 95 % CI, 0·71–1·65; P trend = 0·65)(Reference Wong, Grech and Louie14). The inconsistency could be due to the different study design (cross-sectional rather than prospective) and outcome (prevalence rather than incidence) or to study population differences. Neither of the two studies investigated non-dietary factors as score components(Reference Wong, Grech and Louie14,Reference de la, Zazpe and Goni15) . Three previous studies investigated and reported associations of evolutionary-concordant lifestyle patterns with other chronic diseases (colorectal cancer)(Reference Cheng, Um and Prizment10) or mortality(Reference Cheng, Um and Prizment12,Reference Troeschel, Hartman and Flanders13) . A more evolutionary-concordant lifestyle pattern score (comprising physical activity, BMI and tobacco use), alone and jointly with a more evolutionary-concordant diet pattern score (comprising 14 components), was associated with lower risk of incident colorectal cancer(Reference Cheng, Um and Prizment10) and all-cause, all-CVD and all-cancer mortality(Reference Cheng, Um and Prizment12) in the prospective Iowa Women’s Health Study (n 35 221 White women, ages 55–69 years). The prospective REGARDS cohort study also reported statistically significant inverse associations of the identical EC score used in the present study with all-cause, all-CVD and all-cancer mortality(Reference Troeschel, Hartman and Flanders13).

In the present study, we found that for each given EC score, its estimated inverse associations with CHD and stroke (and thus CVD) incidence were of similar magnitude, suggesting the possibility of approximately equal importance of diet and lifestyle to both CHD and stroke (and thus CVD) incidence, and thus to their prevention. We also estimated that the total EC score was most strongly associated with the three outcomes, followed by the lifestyle score, then the diet score. While these findings suggest that lifestyle may contribute more strongly than diet to CVD risk, they also support that both contribute to CVD risk and thus that adopting a combination of more evolutionary-concordant diets and lifestyle behaviours may help minimise it.

No single total EC score component appeared to account for our findings, and most components, though not all (e.g., sedentary behaviour and social network size), were estimated to be associated with CVD risk. However, among the seven EC score components, smoking, followed by waist circumstance and then diet individually were most strongly associated with incident CVD and their removal from the total EC score most strongly attenuated the total EC score–CVD association. Inclusion of sedentary behaviour and social network size in the total EC score attenuated the association of the score with CVD. The findings for all but sedentary behaviour and social network size are consistent with previous literature(Reference Kopp59Reference Zhang, Pan and Chen66). Evidence from basic science literature suggests that sedentary behaviour and social isolation are biologically linked to CVD risk(Reference Valtorta, Kanaan and Gilbody55,Reference Xia and Li56) , and recent epidemiologic studies and meta-analyses support that longer sedentary times(Reference Biswas, Oh and Faulkner53,Reference Carter, Hartman and Holder54) and higher social isolation(Reference Valtorta, Kanaan and Gilbody55Reference Leigh-Hunt, Bagguley and Bash57) are associated with higher CVD risk. In our study, we did not have a comprehensive assessment of sedentary behaviour, so we used time spent watching television as a surrogate. This may have resulted in exposure misclassification, which would have attenuated our results for sedentary behaviour, and by extension the lifestyle score. Similarly, not having a comprehensive assessment of social connectiveness, we used social network size as a surrogate, which may also have attenuated our results. We also note that physical activity was estimated to be only modestly, not statistically significantly, inversely associated with CVD risk, but did contribute to the strength of the inverse total EC score–incident CVD association. We further note that physical activity was assessed via a single open-ended question regarding how many times per week the participant engaged in physical activity intense enough to work up a sweat. Although this measure of physical activity was previously validated(Reference Washburn, Adams and Haile22,Reference Washburn, Goldfield and Smith23) and found to be statistically significantly inversely associated with all-cause mortality in REGARDS(Reference Troeschel, Hartman and Flanders13), it may have been a less accurate measure than was used in other study populations; such measurement error could have led to an under-estimate of the contribution of physical activity to CVD risk. We note that the emphasis of our analyses and paper is on the collective contributions of multiple exposures for which evolutionary discordance is known, and as hypothesised, found that the total EC score was strongly inversely associated with CVD, CHD and stroke risk. We hypothesise that measuring all total EC score components with the highest levels of validity and in populations with a wide diversity of exposures (given that the scores are calculated based on within-study population differences) would yield stronger inverse total EC score–CVD risk associations than was found in the present study, thus supporting the role of evolutionary discordance in the aetiology of CVD.

Strengths of our study include the prospective design and large, diverse, well-characterised study population. Also, for reported hospitalisations, physician visits and deaths, REGARDS personnel retrieved medical records, death certificates and autopsy reports, and CVD events and related deaths were adjudicated by a committee of trained adjudicators according to a strict protocol(Reference Howard, Cushman and Pulley16), thus reducing outcome misclassification. To our knowledge, this is the first investigation of an EC score that includes dietary and lifestyle factors with incident CVD, CHD and stroke. In addition to the limitations of our sedentary behaviour, social network size and physical activity variables discussed above, our study has other limitations. First, the diet and all lifestyle score components, except waist circumference, were self-reported, and all exposure information was collected only at baseline, which may have produced misclassification error. However, this would be regarded as non-differential in a prospective study, and generally attenuates estimated associations. Second, as with most diet or lifestyle ‘pattern’ scores, we assigned equal weights to the EC score components, but each score component may not contribute equally to the outcomes. Third, our results may not be generalisable to the entire USA population, as all participants agreed to participate in a long-term study, and Black participants and those living in the USA ‘stroke belt’ region were oversampled. However, we observed no statistically significant differences in the total EC score–CVD association by race or residential region. Finally, we had no information on occupational exposures, and as with all observational studies, residual confounding cannot be ruled out.

In conclusion, our findings, combined with those from previous studies, suggest that a more evolutionary-concordant diet and lifestyle pattern may be associated with lower CVD, CHD and stroke risk among White and Black men and women. Of our seven EC score components, not smoking, not having excess central adiposity and having a more evolutionary-concordant diet (e.g. higher intakes of various fruits and vegetables, fish, lean meat and nuts and lower intakes of red and processed meat, dairy products and sugar-sweetened beverages) most strongly contributed to our findings of an inverse total EC score–CVD risk association. For future investigations of associations of EC scores with CVD risk, more comprehensive, precise assessments of sedentary behaviours, social connectiveness, and perhaps physical activity and adiposity, are needed.

Acknowledgements

The authors thank the other investigators who are not listed as co-authors on the present manuscript, the staff and the participants of the REGARDS study for their valuable contributions. A full list of participating REGARDS investigators and institutions can be found at: https://www.uab.edu/soph/regardsstudy/.

This work was supported by a cooperative agreement (SJ, grant number U01 NS041588) co-funded by the National Institute of Neurological Disorders and Stroke (NINDS) and the National Institute on Aging (NIA), National Institutes of Health, Department of Health and Human Service and by R01 HL80477 from the National Heart Lung and Blood Institute (NHLBI); additional funding was provided by The Anne and Wilson P. Franklin Foundation (RMB). The content is solely the responsibility of the authors and does not necessarily represent the official views of the NINDS, NIA, NHLBI or The Anne and Wilson P. Franklin Foundation. Representatives of the NINDS were involved in the review of the manuscript but were not directly involved in the collection, management, analysis or interpretation of the data.

All authors contributed to the study conception and design, data interpretation, and manuscript writing. R. M. B. and Z. M. were primarily responsible for the project conception and design. S. J., J. M. S., E. B. L. and M. M. S. collected the data. Z. M. and A. N. T. were primarily responsible for data analyses. Z. M. and R. M. B. were primarily responsible for interpreting the data and writing the manuscript. R. M. B. supervised the analysis project and manuscript writing. All authors read and approved the final manuscript.

Supplementary material

For supplementary material/s referred to in this article, please visit https://doi.org/10.1017/S0007114522002549

References

World Health Organization (2020) Global Health Estimates 2020: Deaths by Cause, Age, Sex, by Country and by Region, 2000–2019. https://www.who.int/data/gho/data/themes/mortality-and-global-health-estimates/ghe-leading-causes-of-death (accessed December 2021).Google Scholar
Roth, GA, Johnson, CO, Abate, KH, et al. (2018) The burden of cardiovascular diseases among US states, 1990–2016. JAMA Cardiol 3, 375389.Google ScholarPubMed
Konner, M & Eaton, SB (2010) Paleolithic nutrition: twenty-five years later. Nutr Clin Pract 25, 594602.CrossRefGoogle ScholarPubMed
Eaton, SB & Konner, M (1985) Paleolithic nutrition. A consideration of its nature and current implications. N Engl J Med 312, 283289.CrossRefGoogle ScholarPubMed
Eaton, SB, Konner, M & Shostak, M (1988) Stone agers in the fast lane: chronic degenerative diseases in evolutionary perspective. Am J Med 84, 739749.CrossRefGoogle ScholarPubMed
Eaton, SB, Shostak, M & Konner, M (1988) The Paleolithic Prescription: A Program of Diet & Exercise and a Design for Living.  New York: Harper & Row, Publishers.Google Scholar
de Menezes, EVA, Sampaio, HAC, Carioca, AAF, et al. (2019) Influence of Paleolithic diet on anthropometric markers in chronic diseases: systematic review and meta-analysis. Nutr J 18, 41.CrossRefGoogle ScholarPubMed
Ghaedi, E, Mohammadi, M, Mohammadi, H, et al. (2019) Effects of a Paleolithic diet on cardiovascular disease risk factors: a systematic review and meta-analysis of randomized controlled trials. Adv Nutr 10, 634646.CrossRefGoogle ScholarPubMed
Whalen, KA, McCullough, M, Flanders, WD, et al. (2014) Paleolithic and Mediterranean diet pattern scores and risk of incident, sporadic colorectal adenomas. Am J Epidemiol 180, 10881097.CrossRefGoogle ScholarPubMed
Cheng, E, Um, CY, Prizment, AE, et al. (2018) Evolutionary-concordance lifestyle and diet and Mediterranean diet pattern scores and risk of incident colorectal cancer in Iowa women. Cancer Epidemiol Biomarkers Prev 27, 11951202.CrossRefGoogle ScholarPubMed
Whalen, KA, Judd, S, McCullough, ML, et al. (2017) Paleolithic and Mediterranean diet pattern scores are inversely associated with all-cause and cause-specific mortality in adults. J Nutr 147, 612620.CrossRefGoogle ScholarPubMed
Cheng, E, Um, CY, Prizment, A, et al. (2018) Associations of evolutionary-concordance diet, Mediterranean diet and evolutionary-concordance lifestyle pattern scores with all-cause and cause-specific mortality. Br J Nutr, 110. doi: 10.1017/S0007114518003483.Google ScholarPubMed
Troeschel, AN, Hartman, TJ, Flanders, WD, et al. (2021) A novel evolutionary-concordance lifestyle score is inversely associated with all-cause, all-cancer, and all-cardiovascular disease mortality risk. Eur J Nutr 60, 34853497.CrossRefGoogle ScholarPubMed
Wong, MMH, Grech, A & Louie, JCY (2020) Dietary patterns and cardiovascular disease in Australian adults: findings from the 2011–2012 Australian Health Survey. Nutr Metab Cardiovasc Dis 30, 738748.CrossRefGoogle Scholar
de la, OV, Zazpe, I, Goni, L, et al. (2021) A score appraising Paleolithic diet and the risk of cardiovascular disease in a Mediterranean prospective cohort. Eur J Nutr 61, 957971.CrossRefGoogle Scholar
Howard, VJ, Cushman, M, Pulley, L, et al. (2005) The reasons for geographic and racial differences in stroke study: objectives and design. Neuroepidemiology 25, 135143.CrossRefGoogle ScholarPubMed
AAPOR (2004) Standard Definitions: Final Dispositions of Case Codes and Outcome Rates for Surveys, 3rd ed. Lenexa, KS: American Association for Public Opinion Research.Google Scholar
Howard, VJ, Kleindorfer, DO, Judd, SE, et al. (2011) Disparities in stroke incidence contributing to disparities in stroke mortality. Ann Neurol 69, 619627.CrossRefGoogle ScholarPubMed
Boucher, B, Cotterchio, M, Kreiger, N, et al. (2006) Validity and reliability of the Block98 food-frequency questionnaire in a sample of Canadian women. Public Health Nutr 9, 8493.CrossRefGoogle Scholar
Block, G, Hartman, AM, Dresser, CM, et al. (1986) A data-based approach to diet questionnaire design and testing. Am J Epidemiol 124, 453469.CrossRefGoogle ScholarPubMed
NutritionQuest Questionnaires and Screeners (2020) Assessment & Analysis Services. https://nutritionquest.com/assessment/list-of-questionnaires-and-screeners/ (accessed August 2020).Google Scholar
Washburn, RA, Adams, LL & Haile, GT (1987) Physical activity assessment for epidemiologic research: the utility of two simplified approaches. Prev Med 16, 636646.CrossRefGoogle ScholarPubMed
Washburn, RA, Goldfield, SR, Smith, KW, et al. (1990) The validity of self-reported exercise-induced sweating as a measure of physical activity. Am J Epidemiol 132, 107113.CrossRefGoogle ScholarPubMed
Del Boca, FK & Noll, JA (2000) Truth or consequences: the validity of self-report data in health services research on addictions. Addict 95, S347360.CrossRefGoogle ScholarPubMed
Del Boca, FK & Darkes, J (2003) The validity of self-reports of alcohol consumption: state of the science and challenges for research. Addict 98, 112.CrossRefGoogle ScholarPubMed
Salmon, J, Owen, N, Crawford, D, et al. (2003) Physical activity and sedentary behavior: a population-based study of barriers, enjoyment, and preference. Health Psychol 22, 178188.CrossRefGoogle ScholarPubMed
Berkman, LF & Syme, SL (1979) Social networks, host resistance, and mortality: a nine-year follow-up study of Alameda County residents. Am J Epidemiol 109, 186204.CrossRefGoogle ScholarPubMed
Kramer, H, Gutiérrez, OM, Judd, SE, et al. (2016) Waist circumference, body mass index, and ESRD in the REGARDS (Reasons for Geographic and Racial Differences in Stroke) Study. Am J Kidney Dis 67, 6269.CrossRefGoogle ScholarPubMed
Gray, R (1988) A class of K-sample tests for comparing the cumulative incidence of a competing risk. Ann Stat 16, 11411154.CrossRefGoogle Scholar
Liu, Y, Nickleach, DC, Zhang, C, et al. (2018) Carrying out streamlined routine data analyses with reports for observational studies: introduction to a series of generic SAS macros. F1000Res 7, 1955.CrossRefGoogle ScholarPubMed
Rodríguez-Monforte, M, Flores-Mateo, G & Sánchez, E (2015) Dietary patterns and CVD: a systematic review and meta-analysis of observational studies. Br J Nutr 114, 13411359.CrossRefGoogle ScholarPubMed
Tapsell, LC, Neale, EP & Probst, Y (2019) Dietary patterns and cardiovascular disease: insights and challenges for considering food groups and nutrient sources. Curr Atheroscler Rep 21, 9.CrossRefGoogle ScholarPubMed
Brown, AA & Hu, FB (2001) Dietary modulation of endothelial function: implications for cardiovascular disease. Am J Clin Nutr 73, 673686.CrossRefGoogle ScholarPubMed
Guardia, T, Rotelli, AE, Juarez, AO, et al. (2001) Anti-inflammatory properties of plant flavonoids. Effects of rutin, quercetin and hesperidin on adjuvant arthritis in rat. Farmaco 56, 683687.CrossRefGoogle ScholarPubMed
Calder, PC (2010) n-3 fatty acids and inflammatory processes. Nutrients 2, 355374.CrossRefGoogle ScholarPubMed
Casas-Agustench, P, Bulló, M & Salas-Salvadó, J (2010) Nuts, inflammation and insulin resistance. Asia Pac J Clin Nutr 19, 124130.Google ScholarPubMed
McAfee, AJ, McSorley, EM, Cuskelly, GJ, et al. (2010) Red meat consumption: an overview of the risks and benefits. Meat Sci 84, 113.CrossRefGoogle ScholarPubMed
Zhong, VW, Van Horn, L, Greenland, P, et al. (2020) Associations of processed meat, unprocessed red meat, poultry, or fish intake with incident cardiovascular disease and all-cause mortality. JAMA Intern Med 180, 503512.CrossRefGoogle ScholarPubMed
Ghosh, S, Kewalramani, G, Yuen, G, et al. (2006) Induction of mitochondrial nitrative damage and cardiac dysfunction by chronic provision of dietary n-6 polyunsaturated fatty acids. Free Radic Biol Med 41, 14131424.CrossRefGoogle Scholar
van Beelen, VA, Aarts, JM, Reus, A, et al. (2006) Differential induction of electrophile-responsive element-regulated genes by n-3 and n-6 polyunsaturated fatty acids. FEBS Lett 580, 45874590.CrossRefGoogle ScholarPubMed
Tappel, A (2007) Heme of consumed red meat can act as a catalyst of oxidative damage and could initiate colon, breast and prostate cancers, heart disease and other diseases. Med Hypotheses 68, 562564.CrossRefGoogle ScholarPubMed
Kraus, WE, Powell, KE, Haskell, WL, et al. (2019) Physical activity, all-cause and cardiovascular mortality, and cardiovascular disease. Med Sci Sports Exerc 51, 1270.CrossRefGoogle ScholarPubMed
Lacombe, J, Armstrong, ME, Wright, FL, et al. (2019) The impact of physical activity and an additional behavioural risk factor on cardiovascular disease, cancer and all-cause mortality: a systematic review. BMC Public Health 19, 116.CrossRefGoogle Scholar
Warburton, DE, Nicol, CW & Bredin, SS (2006) Health benefits of physical activity: the evidence. CMAJ 174, 801809.CrossRefGoogle ScholarPubMed
Pedersen, BK & Saltin, B (2015) Exercise as medicine–evidence for prescribing exercise as therapy in 26 different chronic diseases. Scand J Med Sci Sports 25, 172.CrossRefGoogle ScholarPubMed
Vaart, HV, Postma, DS, Timens, W, et al. (2004) Acute effects of cigarette smoke on inflammation and oxidative stress: a review. Thorax 59, 713721.CrossRefGoogle ScholarPubMed
Das, SK & Vasudevan, DM (2007) Alcohol-induced oxidative stress. Life Sci 81, 177187.CrossRefGoogle ScholarPubMed
Lymperaki, E, Makedou, K, Iliadis, S, et al. (2015) Effects of acute cigarette smoking on total blood count and markers of oxidative stress in active and passive smokers. Hippokratia 19, 293297.Google ScholarPubMed
Koliaki, C, Liatis, S & Kokkinos, A (2019) Obesity and cardiovascular disease: revisiting an old relationship. Metabolism 92, 98107.CrossRefGoogle ScholarPubMed
Dwivedi, AK, Dubey, P, Cistola, DP, et al. (2020) Association between obesity and cardiovascular outcomes: updated evidence from meta-analysis studies. Curr Cardiol Rep 22, 25.CrossRefGoogle ScholarPubMed
Elagizi, A, Kachur, S, Lavie, CJ, et al. (2018) An overview and update on obesity and the obesity paradox in cardiovascular diseases. Prog Cardiovasc Dis 61, 142150.CrossRefGoogle ScholarPubMed
Wilmot, EG, Edwardson, CL, Achana, FA, et al. (2012) Sedentary time in adults and the association with diabetes, cardiovascular disease and death: systematic review and meta-analysis. Diabetologia 55, 28952905.CrossRefGoogle ScholarPubMed
Biswas, A, Oh, PI, Faulkner, GE, et al. (2015) Sedentary time and its association with risk for disease incidence, mortality, and hospitalization in adults: a systematic review and meta-analysis. Ann Intern Med 162, 123132.CrossRefGoogle ScholarPubMed
Carter, S, Hartman, Y, Holder, S, et al. (2017) Sedentary behavior and cardiovascular disease risk: mediating mechanisms. Exerc Sport Sci Rev 45, 8086.CrossRefGoogle ScholarPubMed
Valtorta, NK, Kanaan, M, Gilbody, S, et al. (2018) Loneliness, social isolation and risk of cardiovascular disease in the English Longitudinal Study of Ageing. Eur J Prev Cardiol 25, 13871396.CrossRefGoogle ScholarPubMed
Xia, N & Li, H (2018) Loneliness, social isolation, and cardiovascular health. Antioxid Redox Signal 28, 837851.CrossRefGoogle ScholarPubMed
Leigh-Hunt, N, Bagguley, D, Bash, K, et al. (2017) An overview of systematic reviews on the public health consequences of social isolation and loneliness. Public Health 152, 157171.CrossRefGoogle ScholarPubMed
Jew, S, AbuMweis, SS & Jones, PJ (2009) Evolution of the human diet: linking our ancestral diet to modern functional foods as a means of chronic disease prevention. J Med Food 12, 925934.CrossRefGoogle ScholarPubMed
Kopp, W (2019) How western diet and lfestyle drive the pandemic of obesity and civilization diseases. Diabetes Metab Syndr Obes 12, 22212236.CrossRefGoogle ScholarPubMed
Lindeberg, S (2012) Paleolithic diets as a model for prevention and treatment of Western disease. Am J Hum Biol 24, 110115.CrossRefGoogle Scholar
Zhang, YB, Chen, C, Pan, XF, et al. (2021) Associations of healthy lifestyle and socioeconomic status with mortality and incident cardiovascular disease: two prospective cohort studies. BMJ 373, n604.CrossRefGoogle ScholarPubMed
Eguchi, E, Iso, H, Tanabe, N, et al. (2012) Healthy lifestyle behaviours and cardiovascular mortality among Japanese men and women: the Japan collaborative cohort study. Eur Heart J 33, 467477.CrossRefGoogle ScholarPubMed
Díaz-Gutiérrez, J, Ruiz-Canela, M, Gea, A, et al. (2018) Association between a healthy lifestyle score and the risk of cardiovascular disease in the SUN cohort. Rev Esp Cardiol (Engl Ed) 71, 10011009.CrossRefGoogle ScholarPubMed
Li, Y, Pan, A, Wang, DD, et al. (2018) Impact of healthy lifestyle factors on life expectancies in the US population. Circulation 138, 345355.CrossRefGoogle ScholarPubMed
Barbaresko, J, Rienks, J & Nöthlings, U (2018) Lifestyle indices and cardiovascular disease risk: a meta-analysis. Am J Prev Med 55, 555564.CrossRefGoogle ScholarPubMed
Zhang, YB, Pan, XF, Chen, J, et al. (2021) Combined lifestyle factors, all-cause mortality and cardiovascular disease: a systematic review and meta-analysis of prospective cohort studies. J Epidemiol Community Health 75, 9299.Google ScholarPubMed
Figure 0

Table 1. Components and construction of the total evolutionary-concordance score* in the REasons for Geographic and Racial Differences in Stroke cohort study (REGARDS)

Figure 1

Table 2. Selected characteristics of the participants according to quintiles of the total evolutionary-concordance (EC) score at baseline (2003–2007) in the REGARDS cohort study(Percentages; mean values and standard deviations, n 15 467)

Figure 2

Table 3. Associations of evolutionary-concordance (EC) scores with incident CVD, CHD and stroke among participants in the REGARDS cohort study (n 15 476), 2003–2017(Hazards ratios and 95 % confidence intervals)

Supplementary material: File

Mao et al. supplementary material

Mao et al. supplementary material

Download Mao et al. supplementary material(File)
File 184.8 KB