Dietary patterns and CVD: a systematic review and meta-analysis of observational studies

Míriam Rodríguez-Monforte; Gemma Flores-Mateo; Emília Sánchez

doi:10.1017/S0007114515003177

Dietary patterns and CVD: a systematic review and meta-analysis of observational studies

Published online by Cambridge University Press: 07 September 2015

Míriam Rodríguez-Monforte ,

Gemma Flores-Mateo and

Emília Sánchez

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Míriam Rodríguez-Monforte*: Affiliation:
Blanquerna School of Health Science, Facultat de Ciències de la Salut Blanquerna, Universitat Ramon Llull, Barcelona 08025, Spain
Gemma Flores-Mateo: Affiliation:
Research Support Unit for Tarragona-Reus, Institut Universitari d’Investigació en Atenció Primària Jordi Gol (IDIAP Jordi Gol), 43202 Tarragona, Spain CIBERobn Physiopathology of Obesity and Nutrition, Institute of Health Carlos III (ISCIII), 28029 Madrid, Spain
Emília Sánchez: Affiliation:
Blanquerna School of Health Science, Facultat de Ciències de la Salut Blanquerna, Universitat Ramon Llull, Barcelona 08025, Spain
*: *Corresponding author: M. Rodríguez-Monforte, fax +34 93 253 3086, email miriamrm@blanquerna.url.edu

Article contents

Abstract
Methods
Results
Discussion
Supplementary material
Footnotes
References

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Abstract

Epidemiological studies show that diet is linked to the risk of developing CVD. The objective of this meta-analysis was to estimate the association between empirically derived dietary patterns and CVD. PubMed was searched for observational studies of data-driven dietary patterns that reported outcomes of cardiovascular events. The association between dietary patterns and CVD was estimated using a random-effects meta-analysis with 95 % CI. Totally, twenty-two observational studies met the inclusion criteria. The pooled relative risk (RR) for CVD, CHD and stroke in a comparison of the highest to the lowest category of prudent/healthy dietary patterns in cohort studies was 0·69 (95 % CI 0·60, 0·78; I2=0 %), 0·83 (95 % CI 0·75, 0·92; I2=44·6 %) and 0·86 (95 % CI 0·74, 1·01; I2=59·5 %), respectively. The pooled RR of CHD in a case–control comparison of the highest to the lowest category of prudent/healthy dietary patterns was 0·71 (95 % CI 0·63, 0·80; I2=0 %). The pooled RR for CVD, CHD and stroke in a comparison of the highest to the lowest category of western dietary patterns in cohort studies was 1·14 (95 % CI 0·92, 1·42; I2=56·9 %), 1·03 (95 % CI 0·90, 1·17; I2=59·4 %) and 1·05 (95 % CI 0·91, 1·22; I2=27·6 %), respectively; in case–control studies, there was evidence of increased CHD risk. Our results support the evidence of the prudent/healthy pattern as a protective factor for CVD.

Keywords

Dietary patterns CVD Systematic reviews Meta-analyses

Type: Systematic Reviews
Information: British Journal of Nutrition , Volume 114 , Supplement 9 , 14 November 2015 , pp. 1341 - 1359

DOI: https://doi.org/10.1017/S0007114515003177 [Opens in a new window]
Copyright: Copyright © The Authors 2015

CVD is the world’s leading cause of morbidity and mortality, affecting millions of people in developed and developing countries⁽ ¹ ^, Reference Celermajer, Chow and Marijon ² ⁾. In Europe, a decline in CVD deaths has been observed, particularly in affluent countries⁽ Reference Levi, Chatenoud and Bertuccio ³ ⁾. Analysis from the WHO MONICA (Multinational MONitoring of trends and determinants in CArdiovascular disease) project attributed this lower CVD incidence and more than two-thirds of the decline in CHD deaths to a reduced exposure to risk factors, such as smoking or high blood cholesterol levels⁽ Reference Tunstall-Pedoe, Kuulasmaa and Mahonen ⁴ ⁾. Nevertheless, CVD remains the major cause of overall death and premature deaths in Europe, especially in people younger than 75 years, accounting for 42 and 38 % of all deaths in women and men, respectively. In addition to 4·3 million deaths every year, there is an enormous individual and societal burden of cardiovascular ill-health⁽ Reference Murray, Vos and Lozano ⁵ ⁾. Similarly, some studies have found that a large proportion of the decline in mortality – from approximately 44 % in the USA, Italy, England and Spain, for example, to as much as 72 % in Finland – can be attributed to reduced exposure to risk factors⁽ Reference Capewell ⁶ ^– Reference Laatikainen, Critchley and Vartiainen ⁹ ⁾. The interrelationship between many chronic conditions and their risk factors also means that targeting key CVD risk factors may help prevent cancer and diabetes⁽ Reference Amine, Baba and Belhadj ¹⁰ ⁾.

Multiple risk factors for CVD, such as family history, obesity, diabetes, hypertension and hypercholesterolaemia, are well established⁽ Reference Perk, De Backer and Gohlke ¹¹ ⁾. Furthermore, the evolution of the disease depends on how many factors can be modified throughout life. The existing research shows the importance of dietary and lifestyle changes in the prevention of CVD⁽ ¹² ^, ¹³ ⁾.

The multiple ways of studying relationships between CVD and diet, specific nutrients, food groups or dietary patterns offer the possibility to study the association of foods and nutrients of a specific type of diet with the risk of disease. The link between diet and the risk of a specific disease can be analysed by evaluating dietary patterns. A technique known as dietary pattern analysis has evolved in nutritional epidemiology as a complementary approach to the study of individual foods. Furthermore, there are two different ways to define dietary patterns: ‘a priori’, focusing on the construction of patterns that reflect hypothesis-oriented combinations of foods and nutrients, and ‘a posteriori’, which builds on exploratory statistical methods and uses the observed dietary data in order to extract dietary patterns. Both ways show positive and negative aspects; ‘a priori’ methods are based on predefined diet quality indices, using current nutrition knowledge, and identify a desirable pattern adherence to which could maximise health benefits. On the contrary, ‘a posteriori’ methods use dietary data in-hand but might be debatable in relating diet and disease; the extracted dietary patterns may have little relation to morbidity and mortality when nutrients or foods relevant to the aetiology of diseases are not included in their definition. However, focus on ‘a posteriori’ dietary patterns helps avoid increased heterogeneity⁽ Reference Hu ¹⁴ ^, Reference Tucker and Jacques ¹⁵ ⁾. Diverse classifications have been used to group the different dietary patterns, primarily categorising them as healthy or prudent v. unhealthy or western⁽ Reference Shu, Wang and Wang ¹⁶ ^, Reference Reedy, Krebs-Smith and Miller ¹⁷ ⁾. The Mediterranean dietary pattern approach, classified as a prudent or healthy dietary pattern, is one of the best established⁽ Reference Martínez-González and Bes-Ratrollo ¹⁸ ^– Reference Schwingshackl, Missbach and König ²¹ ⁾. Several studies have reported a weak association between dietary patterns and CVD risk, especially those dietary patterns with high fat, dairy products, fried foods and meat intake classified as western or unhealthy. Our systematic review and meta-analysis complements the latest meta-analysis on this topic by analysing a larger population (610 691 participants), adding studies that identified dietary patterns by cluster analysis and considering not only CVD or stroke mortality but also CVD outcomes such as clinical CVD, CHD, stroke and overall CVD⁽ Reference Fei, Hou and Chen ²² ^– Reference McEvoy, Cardwell and Woodside ³² ⁾.

The objective of this study was to systematically review and synthesise the results from observational studies and to clarify the association between empirically defined (a posteriori) dietary patterns and CVD outcomes.

Methods

Search strategy

We searched PubMed for relevant studies published through September 2014 using the following combination of Medical Subject Heading (MeSH) terms and text words, with no language limitations: (‘dietary patterns’[All Fields] OR ‘dietary intake’[All Fields]) AND ((‘mortality’[Subheading] OR ‘mortality’[All Fields] OR ‘mortality’[MeSH Terms]) OR (‘myocardial infarction’[MeSH Terms] OR (‘myocardial’[All Fields] AND ‘infarction’[All Fields]) OR ‘myocardial infarction’[All Fields]) OR (‘stroke’[MeSH Terms] OR ‘stroke’[All Fields]) OR (‘peripheral vascular diseases’[MeSH Terms] OR (‘peripheral’[All Fields] AND ‘vascular’[All Fields] AND ‘diseases’[All Fields]) OR ‘peripheral vascular diseases’[All Fields] OR (‘peripheral’[All Fields] AND ‘arterial’[All Fields] AND ‘disease’[All Fields]) OR ‘peripheral arterial disease’[All Fields]) OR ((‘hypertension’[MeSH Terms] OR ‘hypertension’[All Fields]) OR ‘elevated blood pressure’[All Fields])).The search strategy retrieved 1578 citations (Fig. 1). We included all observational studies that assessed the association of dietary patterns analysed by cluster analysis, factor analysis or principal component analysis (PCA) with CVD outcomes. We limited the search to clinical CVD, defined a priori as CHD (including myocardial infarction and ischaemic heart disease), stroke (cerebrovascular disease and ischaemic stroke) and overall CVD.

Fig. 1 Flow diagram of the study selection process. HR, hazard ratio; OR, odds ratio; RR, relative risk.

Two investigators (M. R.-M and G. F.-M.) independently reviewed each of the 1578 papers identified and applied the following exclusion criteria: (a) no original research (i.e. reviews, editorials, non-research letters); (b) case reports or case series; (c) ecological studies; (d) lack of data on dietary patterns; (e) studies without CVD, cardiovascular death or cardiovascular events as the end point; (f) studies not conducted in humans or adult population; (g) studies without measures of association (hazard ratios, OR, relative risks (RR)); and (h) observational designs other than cohort or case–control. Fig. 1 summarises the study selection process. Any discrepancies were resolved by consensus.

After retrieval of articles from the search, the reference lists of all selected articles were checked for other potentially relevant articles; six additional papers were identified.

Data extraction and quality assessment

Two investigators (M. R.-M. and G. F.-M.) independently abstracted the articles that met the selection criteria. They resolved discrepancies by consensus. The investigators of the original studies were contacted if relevant information on eligibility or key study data were not available in the published report. The following information was recorded from all studies: study design, geographic region, sex, sample size, dietary assessment method, dietary patterns identified and by which a posteriori method, factors adjusted for in each study, outcome and outcome assessment, population age range and follow-up time (cohort studies), naming of patterns, factor loadings per pattern and total variance (Tables 1 and 2, and see online Supplementary Material). Measures of association (OR, RR, hazard ratios) and their 95 % CI were abstracted.

Table 1 Prospective cohort studies of dietary patterns and CVD (Hazard ratios, risk ratios and 95 % confidence intervals)

NOS, Newcastle–Ottawa Scale; AMI, acute myocardial infarction; FA, factor analyses; BP, blood pressure; WHR, waist:hip ratio; CA, cluster analyses; MMSE, Mini-Mental State Examination; GDS, Geriatric Depression Scale; PASE, activity score for the elderly; PCA, principal component analyses. Currently, mortality is included; MESA, Multi-Ethnic Study of Atherosclerosis; CRP, C-reactive protein; EPIC, European Prospective Investigation into Cancer and Nutrition; JACC, Japan Collaborative Cohort Study; HEALS, Health Effects of Arsenic Longitudinal Study; REGARDS, Reasons for Geographic and Racial Differences in Stroke; GRAS, Geisinger Rural Aging Study; SUN, Seguimiento Universidad de Navarra.

* Quality assessment of cohort studies with the NOS. The full NOS score is 9 points. Scores ≥7 were considered high-quality.

Table 2 Case–control studies of dietary patterns and CVD (Hazard ratios, risk ratios and 95 % confidence intervals)

NOS, Newcastle–Ottawa Scale; AMI, acute myocardial infarction; FA, factor analyses; WHR, waist:hip ratio; BP, blood pressure.

* Quality assessment of case–control studies with the NOS. The full NOS score is 9 points. Scores ≥7 were considered with high-quality.

We defined those patterns having generally healthy characteristics as prudent/healthy and those patterns having generally less-healthy characteristics as unhealthy/western, on the basis of the food loading reported within individual studies. The prudent/healthy pattern tended to have high-factor loading for food such as fruit, vegetables, whole grains, fish and poultry. The unhealthy/western pattern was characterised by high-factor loadings for foods such as meat, processed meat, refined grains, sweets, sugar drinks and fried foods. When several healthy and unhealthy patterns were reported, we first selected the pattern that explained the maximum of variation in food groups⁽ Reference Shimazu, Kuriyama and Hozawa ²⁵ ^, Reference Guallar-Castillon, Rodriguez-Artalejo and Tormo ²⁶ ^, Reference Stricker, Onland-Moret and Boer ²⁸ ^, Reference Zazpe, Sánchez-Tainta and Toledo ³¹ ^, Reference Panagiotakos, Pitsavos and Chrysohoou ³⁹ ⁾ and then the pattern that fulfilled the most healthy or unhealthy criteria, determined by the highest factor loadings⁽ Reference Chan, Chan and Woo ³⁰ ^, Reference Cai, Shu and Gao ³⁷ ^, Reference Chen, McClintock and Segers ⁴³ ^, Reference Judd, Gutiérrez and Newby ⁴⁴ ^, Reference Guo, Li and Wang ⁴⁷ ⁾.

As the studies were observational, the quality assessment was based on the Newcastle–Ottawa Assessment Scale (NOS), using a star system for cohort and case–control studies. The NOS is one of the more comprehensive instruments for assessing the quality of non-randomised studies in meta-analyses. The eight-item instrument consists of three subscales: selection of subjects (four items), comparability of subjects (one item) and assessment of outcome/exposure (three items). High-quality responses earn a star and the comparability question earns up to two stars, yielding a maximum total of nine stars. The present study dichotomised the NOS scores, considering ≥7 points an indication of high methodological quality⁽ Reference Wells, Shea and O’Connell ³³ ⁾ (Appendices 1 and 2).

Statistical analysis

Cohort studies and case–control studies were analysed separately. The results of dietary patterns were variously reported as quintiles, quartiles or dietary factor scores and CVD risk or outcomes. A meta-analysis was conducted to combine the results and evaluate the risk of CVD in the highest compared with the lowest categories of prudent/healthy and western/unhealthy dietary patterns. Heterogeneity was quantified using the I ² statistic, which describes the proportion of total variation in study estimates that is due to heterogeneity⁽ Reference Higgins and Thompson ³⁴ ⁾. Each study’s estimate and se was used to produce a forest plot that yielded a pooled estimate.

To explore sources of heterogeneity, we performed a subgroup analysis to evaluate whether results differed depending on the number of FFQ items (categorised as median number of <101 or ≥101 FFQ items or other information source), geographic area (Asia or other countries), a posteriori approach (PCA, factor analysis or cluster analysis), sex (men, women or both), sample size (categorised as >40 011 or ≥40 011 participants, according to median sample size in the meta-analysis), adjustment or non-adjustment for all key confounders (considering as key confounders age, sex, family history of CVD, CHD or stroke, diabetes, hypertension and BMI) and incidence or mortality outcomes. We did not perform subgroup analysis of case–control studies because of the limited number of such studies that reported an association between dietary patterns and CVD outcomes.

Assessment of the relative influence of each study was based on pooled estimates, omitting one study at a time (sensitivity analysis). Finally, publication bias was assessed using the Egger test and funnel plots. Statistical analyses were conducted using the Stata software (version 11; StataCorp LP).

Results

Study selection

The search strategy retrieved 1578 articles in the PubMed index. Of these citations, 1542 publications were excluded on the basis of title and abstract and twenty were excluded after full-text review. The remaining twenty-two observational studies, all published between 2000 and 2014, were included in the meta-analysis⁽ Reference Osler, Heitmann and Gerdes ²³ ^– Reference Zazpe, Sánchez-Tainta and Toledo ³¹ ^, Reference Hu, Rimm and Stampfer ³⁵ ^– Reference Guo, Li and Wang ⁴⁷ ⁾ (Fig. 1). The studies were conducted in Europe⁽ Reference Osler, Heitmann and Gerdes ²³ ^, Reference Guallar-Castillon, Rodriguez-Artalejo and Tormo ²⁶ ^, Reference Stricker, Onland-Moret and Boer ²⁸ ^, Reference Zazpe, Sánchez-Tainta and Toledo ³¹ ^, Reference Akesson, Weismayer and Newby ³⁸ ^, Reference Panagiotakos, Pitsavos and Chrysohoou ³⁹ ^, Reference Brunner, Mosdol and Witte ⁴¹ ⁾, America⁽ Reference Hu, Rimm and Stampfer ³⁵ ^, Reference Fung, Stampfer and Manson ³⁶ ^, Reference Heidemann, Schulze and Franco ⁴⁰ ^, Reference Judd, Gutiérrez and Newby ⁴⁴ ^, Reference Martinez-Ortiz, Fung and Baylin ⁴⁵ ⁾, Asia⁽ Reference Shimazu, Kuriyama and Hozawa ²⁵ ^, Reference Maruyama, Iso and Date ²⁷ ^, Reference Chan, Chan and Woo ³⁰ ^, Reference Cai, Shu and Gao ³⁷ ^, Reference Chen, McClintock and Segers ⁴³ ^, Reference Guo, Li and Wang ⁴⁷ ⁾ and Australia⁽ Reference Harriss, English and Powles ²⁴ ⁾. There were nineteen cohort studies⁽ Reference Osler, Heitmann and Gerdes ²³ ^– Reference Zazpe, Sánchez-Tainta and Toledo ³¹ ^, Reference Hu, Rimm and Stampfer ³⁵ ^– Reference Judd, Gutiérrez and Newby ⁴⁴ ⁾ (Table 1) and three case–control studies⁽ Reference Martinez-Ortiz, Fung and Baylin ⁴⁵ ^– Reference Guo, Li and Wang ⁴⁷ ⁾ (Table 2). The number of cases ranged from 449⁽ Reference Hsiao, Mitchell and Coffman ²⁹ ⁾ to 74 942⁽ Reference Cai, Shu and Gao ³⁷ ⁾. All the selected studies assessed total CVD, CVD mortality, CHD and stroke as the end point; Nettleton et al.⁽ Reference Nettleton, Polak and Russell ⁴² ⁾ also assessed revascularisation. All of these papers met most of the present study’s quality criteria (Tables 1 and 2).

Meta-analysis of prudent/healthy dietary pattern

Totally, eighteen cohort studies⁽ Reference Osler, Heitmann and Gerdes ²³ ^– Reference Stricker, Onland-Moret and Boer ²⁸ ^, Reference Hsiao, Mitchell and Coffman ²⁹ ^, Reference Zazpe, Sánchez-Tainta and Toledo ³¹ ^, Reference Hu, Rimm and Stampfer ³⁵ ^– Reference Judd, Gutiérrez and Newby ⁴⁴ ⁾ and three case–control studies⁽ Reference Martinez-Ortiz, Fung and Baylin ⁴⁵ ^– Reference Guo, Li and Wang ⁴⁷ ⁾ were included in the meta-analysis of prudent/healthy dietary pattern and CVD outcomes. Ten cohort studies analysed the association between the prudent/healthy dietary pattern and CHD risk⁽ Reference Osler, Heitmann and Gerdes ²³ ^, Reference Shimazu, Kuriyama and Hozawa ²⁵ ^– Reference Stricker, Onland-Moret and Boer ²⁸ ^, Reference Hu, Rimm and Stampfer ³⁵ ^, Reference Cai, Shu and Gao ³⁷ ^, Reference Akesson, Weismayer and Newby ³⁸ ^, Reference Brunner, Mosdol and Witte ⁴¹ ^, Reference Chen, McClintock and Segers ⁴³ ⁾. Five studies also analysed the association between a prudent/healthy dietary pattern and total CVD risk and CVD mortality⁽ Reference Harriss, English and Powles ²⁴ ^, Reference Zazpe, Sánchez-Tainta and Toledo ³¹ ^, Reference Panagiotakos, Pitsavos and Chrysohoou ³⁹ ^, Reference Heidemann, Schulze and Franco ⁴⁰ ^, Reference Nettleton, Polak and Russell ⁴² ⁾. Eight cohort studies⁽ Reference Shimazu, Kuriyama and Hozawa ²⁵ ^, Reference Maruyama, Iso and Date ²⁷ ^, Reference Stricker, Onland-Moret and Boer ²⁸ ^, Reference Chan, Chan and Woo ³⁰ ^, Reference Fung, Stampfer and Manson ³⁶ ^, Reference Cai, Shu and Gao ³⁷ ^, Reference Chen, McClintock and Segers ⁴³ ^, Reference Judd, Gutiérrez and Newby ⁴⁴ ⁾ described the relationship between prudent/healthy dietary pattern and the risk of stroke.

The association between dietary pattern and CVD was estimated using a random-effects meta-analysis with 95 % CI. In all, twenty-one observational studies met the inclusion criteria. Overall, in a comparison of the highest to the lowest category of prudent/healthy dietary patterns in cohort studies, the pooled RR for CVD, CHD and stroke was 0·69 (95 % CI 0·60, 0·78; P _{heterogeneity}=0·687; and I ²=0 %), 0·83 (95 % CI 0·75, 0·92; P _{heterogeneity}=0·054; and I ²=44·6 %) and 0·86 (95 % CI 0·74, 1·01; P _{heterogeneity}=0·008; I ²=59·5 %), respectively. In case–control studies, the pooled RR for CHD was 0·71 (95 % CI 0·63, 0·80; P _{heterogeneity}=0·560; I ²=0 %) (Fig. 2).

Fig. 2 Meta-analysis of prudent/healthy dietary pattern and CVD in observational studies. Relative risks (RR) correspond to comparisons of extreme categories of exposure within each study. The area of each square is proportional to the inverse of the variance of the log RR. Horizontal lines represent 95 % confidence intervals. Diamonds represent pooled estimates from inverse-variance-weighted random-effects models. AMI, acute myocardial infarction.

To further explore the reasons for heterogeneity, we performed subgroup analysis according to sex, geographic area, sample size, number of FFQ items, incidence or mortality outcomes, a posteriori approach and adjustments for confounders (Table 3). As shown in Table 4, most subgroups showed no significant association with heterogeneity between dietary patterns and CVD outcomes.

Table 3 Subgroup analyses for prudent/healthy dietary pattern (Pooled relative risk values and 95 % confidence intervals)

PCA, principal component analysis; FA, factor analysis; CA, cluster analysis.

* Key confounding factors are age, sex, family history of CVD, CHD or stroke, diabetes, hypertension and BMI.

Table 4 Subgroup analyses for western/unhealthy dietary pattern (Pooled relative risk values and 95 % confidence intervals)

PCA, principal component analysis.

* Key confounding are age, sex, family history of CVD, CHD or stroke, diabetes, hypertension and BMI.

In sensitivity analyses, exclusion of individual studies did not modify the estimates substantially, with pooled RR of CVD, CHD and stroke in cohort studies ranging from 0·65 to 0·70, 0·80 to 0·84 and 0·82 to 0·89, respectively. In case–control studies, the pooled RR of CHD in case–control studies ranged from 0·70 to 0·73. The funnel plot showed reasonable symmetry and a non-significant Egger test for publication bias (P=0·278) (Appendix 3).

Meta-analysis of western/unhealthy dietary pattern

In all, sixteen cohort studies⁽ Reference Osler, Heitmann and Gerdes ²³ ^– Reference Zazpe, Sánchez-Tainta and Toledo ³¹ ^, Reference Hu, Rimm and Stampfer ³⁵ ^– Reference Cai, Shu and Gao ³⁷ ^, Reference Panagiotakos, Pitsavos and Chrysohoou ³⁹ ^, Reference Heidemann, Schulze and Franco ⁴⁰ ^, Reference Chen, McClintock and Segers ⁴³ ^, Reference Judd, Gutiérrez and Newby ⁴⁴ ⁾ were included in the meta-analysis of western/unhealthy dietary pattern and CVD. Eight studies⁽ Reference Osler, Heitmann and Gerdes ²³ ^, Reference Shimazu, Kuriyama and Hozawa ²⁵ ^– Reference Stricker, Onland-Moret and Boer ²⁸ ^, Reference Hu, Rimm and Stampfer ³⁵ ^, Reference Cai, Shu and Gao ³⁷ ^, Reference Chen, McClintock and Segers ⁴³ ⁾ analysed the relationship between a western/unhealthy dietary pattern and CHD incidence. Five studies⁽ Reference Harriss, English and Powles ²⁴ ^, Reference Hsiao, Mitchell and Coffman ²⁹ ^, Reference Zazpe, Sánchez-Tainta and Toledo ³¹ ^, Reference Panagiotakos, Pitsavos and Chrysohoou ³⁹ ^, Reference Heidemann, Schulze and Franco ⁴⁰ ⁾ analysed the relationship between a western/unhealthy dietary pattern and CVD and CVD mortality risk. Eight studies⁽ Reference Shimazu, Kuriyama and Hozawa ²⁵ ^, Reference Maruyama, Iso and Date ²⁷ ^, Reference Stricker, Onland-Moret and Boer ²⁸ ^, Reference Chan, Chan and Woo ³⁰ ^, Reference Fung, Stampfer and Manson ³⁶ ^, Reference Cai, Shu and Gao ³⁷ ^, Reference Chen, McClintock and Segers ⁴³ ^, Reference Judd, Gutiérrez and Newby ⁴⁴ ⁾ also analysed the relationship between a western/unhealthy dietary pattern and the risk of stroke. Three case–control studies⁽ Reference Martinez-Ortiz, Fung and Baylin ⁴⁵ ^– Reference Guo, Li and Wang ⁴⁷ ⁾ were also included.

Totally, nineteen observational studies met the inclusion criteria. Overall, the pooled RR for CVD, CHD and stroke in a comparison of the highest to the lowest category of western/unhealthy dietary patterns in cohort studies was 1·14 (95 % CI 0·92, 1·42; P _{heterogeneity}=0·055; and I ²=56·9 %), 1·03 (95 % CI 0·90, 1·17; P _{heterogeneity}=0·012; and I ²=59·4 %) and 1·05 (95 % CI 0·91, 1·22; P _{heterogeneity}=0·190; I ²=27·6 %), respectively (Fig. 3).

Fig. 3 Meta-analysis of western/unhealthy dietary pattern and CVD in observational studies. Relative risks (RR) correspond to comparisons of extreme categories of exposure within each study. The area of each square is proportional to the inverse of the variance of the log RR. Horizontal lines represent 95 % confidence intervals. Diamonds represent pooled estimates from inverse-variance-weighted random-effects models. AMI, acute myocardial infarction.

The pooled RR for CHD in case–control studies was 1·61 (95 % CI 1·17, 2·21), with statistically significant heterogeneity between studies (P _{heterogeneity}=0·006; I ²=80·5 %). The sensitivity analysis indicates that a single study was the main origin of heterogeneity among studies (forty-five). The heterogeneity decreased (I ²=0 %; P=0·953) after Martinez study was excluded; however, the association remained was significant (the pooled RR was 1·35 (95 % CI 1·22, 1·49). Other sources of heterogeneity produced only non-significant differences (Table 4).

In sensitivity analyses, exclusion of individual studies did not modify pooled RR substantially: CHD risk ranged from 0·99 to 1·06, stroke risk from 1·01 to 1·08 and CVD risk from 1·08 to 1·23 in cohort studies, and CVD risk ranged from 1·35 to 2·10 in case–control studies. The funnel plot was reasonably symmetric and the Egger test for publication bias did not reach statistical significance (P=0·219) (Appendix 4).

Discussion

Our meta-analysis evaluated the results from published cohort and case–control studies involving approximately 610 691 participants, all of which investigated the association between a posteriori dietary patterns and CVD. The findings indicated that healthier patterns are associated with a lower risk for all clinical cardiovascular end points, except for stroke. When we pooled the results of cohort or case–control studies, the association between unhealthy/western dietary patterns and an increased risk of CHD, CVD mortality and stroke was not clearly established. Because there was significant heterogeneity among case–control studies, a sensitivity analysis was conducted to explore possible explanations for heterogeneity. After deleting the study that was the main origin of the heterogeneity, the summary ranged from 1·61 (95 % CI 1·7, 2·21) to 1·21 (95 % CI 1·22, 1·49), which suggested that the association remained significant and our findings were reliable and robust.

Despite a statistically significant association between unhealthy dietary patterns and CVD risk in some studies, the pooled estimation was non-significant. According to our findings, following an unhealthy pattern is not always synonymous with developing CVD. There are several reasons why the unhealthy/western pattern may not necessarily represent the food choices that pose the highest CVD risk. Maruyama et al.⁽ Reference Maruyama, Iso and Date ²⁷ ⁾ studied an unhealthy pattern defined by milk and dairy products, butter, margarine, fruits, coffee and tea that was protective against stroke risk. Judd et al.⁽ Reference Judd, Gutiérrez and Newby ⁴⁴ ⁾ also included a pattern defined by high intake of sweets and saturated fats that was associated with a reduction in stroke risk. In both cases, adherence to that pattern could be associated with a higher risk of cancer or some kind of CHD that might lead to death before a stroke could occur.

The adjusted confounding factors differed in the included studies. All of the studies were adjusted for age and sex. Most of them also were adjusted for BMI, diabetes or hypertension⁽ Reference Harriss, English and Powles ²⁴ ^, Reference Shimazu, Kuriyama and Hozawa ²⁵ ^, Reference Maruyama, Iso and Date ²⁷ ^, Reference Stricker, Onland-Moret and Boer ²⁸ ^, Reference Chan, Chan and Woo ³⁰ ^, Reference Zazpe, Sánchez-Tainta and Toledo ³¹ ^, Reference Akesson, Weismayer and Newby ³⁸ ^, Reference Panagiotakos, Pitsavos and Chrysohoou ³⁹ ^, Reference Brunner, Mosdol and Witte ⁴¹ ^– Reference Chen, McClintock and Segers ⁴³ ^, Reference Martinez-Ortiz, Fung and Baylin ⁴⁵ ^, Reference Iqbal, Anand and Ounpuu ⁴⁶ ⁾. However, family history as a non-modifiable risk factor for CVD and high cholesterol levels as a modifiable risk factor for CVD⁽ Reference Mendis, Puska and Norrving ⁴⁸ ⁾ were not considered⁽ Reference Osler, Heitmann and Gerdes ²³ ^, Reference Shimazu, Kuriyama and Hozawa ²⁵ ^, Reference Maruyama, Iso and Date ²⁷ ^, Reference Hsiao, Mitchell and Coffman ²⁹ ^– Reference Zazpe, Sánchez-Tainta and Toledo ³¹ ^, Reference Cai, Shu and Gao ³⁷ ^, Reference Brunner, Mosdol and Witte ⁴¹ ^– Reference Guo, Li and Wang ⁴⁷ ⁾, and it should be taken into account in future research. Only four studies adjusted for all key confounding factors⁽ Reference Hu, Rimm and Stampfer ³⁵ ^, Reference Fung, Stampfer and Manson ³⁶ ^, Reference Akesson, Weismayer and Newby ³⁸ ^, Reference Panagiotakos, Pitsavos and Chrysohoou ³⁹ ⁾. The subgroup analysis by adjusted confounders in CHD cohort studies showed low heterogeneity, but the association remained significant, which confirmed our findings.

We identified two prominent general dietary patterns: a healthy/prudent and an unhealthy/western pattern. Following a healthy or unhealthy dietary pattern is also culturally and socially mediated. The factor loadings per pattern analysis reflected the foods most commonly consumed within the healthy dietary patterns, considering cultural differences. Authors from Asian countries study dietary patterns very divergent from those of Europe or America⁽ Reference Shimazu, Kuriyama and Hozawa ²⁵ ^, Reference Maruyama, Iso and Date ²⁷ ^, Reference Chan, Chan and Woo ³⁰ ^, Reference Hu, Rimm and Stampfer ³⁵ ^– Reference Cai, Shu and Gao ³⁷ ^, Reference Heidemann, Schulze and Franco ⁴⁰ ^, Reference Chen, McClintock and Segers ⁴³ ^– Reference Martinez-Ortiz, Fung and Baylin ⁴⁵ ^, Reference Guo, Li and Wang ⁴⁷ ⁾. In the subgroup analysis by country, the studies conducted in Europe and America showed that the unhealthy/western dietary pattern was a risk factor for stroke but was not associated with CHD, and the pooled results from studies of Asian countries showed a non-significant association. The studies from China or Japan defined other dietary patterns as normal for the general population; for example, Chen et al.⁽ Reference Chen, McClintock and Segers ⁴³ ⁾ includes a pattern named ‘gourd and root vegetable’ in China and Shimazu et al.⁽ Reference Shimazu, Kuriyama and Hozawa ²⁵ ⁾ includes a Japanese dietary pattern represented by high intake of soyabean products, fish, seaweed, vegetables and green tea.

Many reports have shown that the association of diet with CVD is plausible⁽ ¹² ^, ⁴⁹ ^, ⁵⁰ ⁾. One of the most representative examples is the association with cardiovascular risk prevention linked to the Mediterranean dietary pattern, based on fish and plant foods such as fruits, vegetables, cereals, legumes, wholegrain products, nuts and olive oil and the moderate consumption of red wine, along with low consumption of red meat, dairy products and SFA⁽ Reference Estruch, Ros and Salas-Salvadó ¹⁹ ^– Reference Schwingshackl, Missbach and König ²¹ ⁾.

Different biological mechanisms might explain the results of the meta-analysis regarding the effect on CVD outcome of following a healthy or an unhealthy dietary pattern. The prudent/healthy dietary pattern included high-factor loadings for vegetables, fruit, legumes, whole grains, fish and poultry, whereas the western/unhealthy pattern included high-factor loadings for red and processed meat, refined grains, French fries, sweets, desserts, high-fat dairy products and alcohol. The consumption of vegetables and fruits is protective: the more the better, and no upper limit has been found. The higher proposed population goal of 600 g/d is in line with the most recent global population goal proposed by the World Cancer Research Fund in 2009⁽ ⁵¹ ^, Reference Romaguera, Vergnaud and Peeters ⁵² ⁾. Several systematic reviews on this subject⁽ Reference He, Nowson and Lucas ⁵³ ^, Reference He, Nowson and MacGregor ⁵⁴ ⁾ have shown that the consumption of fruit (>2 servings/d, 200 g) and vegetables (>2 servings/d, 200 g) significantly reduces the risk of CHD and stroke. Furthermore, the intake of fruit, vegetables, whole grains and legumes increases the amount of fibre, which can have protective value against CVD⁽ Reference Pereira, O’Reilly and Augustson ⁵⁵ ^, Reference Threapleton, Greenwood and Burley ⁵⁶ ⁾. Antioxidants – such as vitamin C, flavonoids, K and folates – that can be found in fruits and vegetables also might influence the decrease in CVD risk⁽ ⁵⁰ ⁾.

In addition, oily fish and nuts contain PUFA (n-3 fatty acid), which reduce the risk of CHD⁽ ⁵⁷ ⁾. Some studies have provided evidence that a modest increase (1–2 servings/week) in fish consumption reduces CHD mortality by 36 %⁽ Reference Mozaffarian and Rimm ⁵⁸ ^, Reference Raatz, Silverstein and Jahns ⁵⁹ ⁾, and that 2–4 servings/week can decrease the risk of stroke by 18 %⁽ Reference He, Song and Daviglus ⁶⁰ ⁾. Nevertheless, fish was included as a component in the unhealthy pattern in some studies, and related to an increased acute myocardial infarction, stroke and CVD risk⁽ Reference Guallar-Castillon, Rodriguez-Artalejo and Tormo ²⁶ ^, Reference Hsiao, Mitchell and Coffman ²⁹ ^, Reference Chen, McClintock and Segers ⁴³ ^, Reference Judd, Gutiérrez and Newby ⁴⁴ ^, Reference Guo, Li and Wang ⁴⁷ ⁾.

On the other hand, the intake of refined grains, deep-fried potatoes, sweets (especially sugar-sweetened soft drinks), desserts and high-fat dairy products increases the amount of saturated and trans-saturated fat, dietary sugars and salt consumed. These three dietary components have been shown to directly or indirectly increase CVD risk⁽ Reference Bernstein and Willett ⁶¹ ^– Reference Johnson, Appel and Brands ⁶³ ⁾. Moderate alcohol consumption might be protective against CVD according to different epidemiological studies because of the content of polyphenols. However, increasing the intake above 10 g/d for women and 20 g/d for men may increase the risk of CVD⁽ Reference Opie and Lecour ⁶⁴ ⁾.

According to our results, alcohol seems to have an important role in the studies included in the unhealthy pattern, especially in European and American cultures. According to Zazpe et al.⁽ Reference Zazpe, Sánchez-Tainta and Toledo ³¹ ⁾ and Judd et al.⁽ Reference Judd, Gutiérrez and Newby ⁴⁴ ⁾, it was considered a negative predisposing factor.

The main limitation of our study is that factor loadings for individual foods in the different dietary patterns were not identical between the included studies, which may result in a misclassification bias. Descriptions of the factor loadings for individual food items for the dietary patterns analysed in our meta-analysis were not exactly equal between studies, and included different food items. Despite this, there were similarities in the type of foods that generally featured within the healthy patterns (fruit, vegetables, whole grains, fish and poultry) and the western patterns (meat, processed meat, refined grains, sweets, sugar drinks and fried foods) (see online Supplementary Material)⁽ Reference McEvoy, Cardwell and Woodside ³² ⁾. Depending on the predominant factor loadings per food in each pattern, the influence of that pattern would generally be considered healthy or unhealthy. This means that, commonly, dietary patterns mix different kinds of foods, but the ones that are more predominant will define the final influence of that pattern.

Another limitation could be the inclusion of a posteriori dietary patterns, which can vary depending on the population and are more complex to standardise and compare across cohorts and population groups.

Confounding factors within the different studies also had an important role in the final results.

Another limitation of this meta-analysis is related to the heterogeneity found. However, this heterogeneity was not explained by the study design, number of FFQ items, geographic area, type of a posteriori approach, quality assessment, sex or sample size. Our study population was rather heterogeneous, which can increase residual confounding, biasing the estimate to the null, but it leads to generalisability⁽ Reference Heidemann, Schulze and Franco ⁴⁰ ⁾.

Finally, dietary patterns may represent a lifestyle in general and, even the adjustment for known and suspected confounders, residual confounding cannot be ruled out because of the observational nature of the studies included⁽ Reference Martinez, Marshall and Sechrest ⁶⁵ ^, Reference Williams, Prevost and Whichelow ⁶⁶ ⁾.

To the best of our knowledge, this is the first meta-analysis of empirically derived dietary patterns to relate dietary patterns and CVD outcomes. Dietary patterns are becoming an essential approach to discovering the association of diet with the risk of a specific pathology. These patterns may be a consequence of cultural and ethnic heritage and of many environmental factors, including the availability of foods, the ability to purchase and prepare foods, the numerous advertisements for foods and the efforts of the government and the nutrition community to foster healthy diets⁽ Reference Shu, Wang and Wang ¹⁶ ⁾.

Four meta-analyses relating dietary patterns to different CVD events are also in line with our results and conclude that, despite a need for further studies to confirm the findings, adherence to a prudent/healthy dietary pattern is associated with a lower risk of CVD mortality but not significantly associated with stroke mortality or CHD risk and, furthermore, that a western/unhealthy dietary pattern is not associated with CHD or stroke mortality⁽ Reference Fei, Hou and Chen ²² ^, Reference McEvoy, Cardwell and Woodside ³² ^, Reference Kontogianni and Panagiotakos ⁶⁷ ^, Reference Hou, Li and Wang ⁶⁸ ⁾. Our meta-analysis adds to these findings a similar conclusion about other outcomes such as CVD or stroke incidence and mortality in cohort and case–control studies.

In summary, this meta-analysis strengthens the evidence in support of a prudent/healthy dietary pattern as a protective factor for CVD, especially CHD, but it fails to demonstrate a direct association between adherence to unhealthy dietary patterns and CVD incidence. These results may help reaffirm the clinical advice from health professionals such as physicians, nurses or dietitians in this field.

Acknowledgements

The authors thank the editor and anonymous reviewers for their constructive and valuable comments, which helped the authors improve the manuscript.

The preparation of the manuscript was supported by the Foundation IDIAP Jordi Gol.

M. R.-M. and G. F.-M. formulated the research question, designed the study, carried it out and analysed the data. M. R.-M. and E. S. discussed the results and wrote the paper. All authors contributed to the revision of the manuscript, and read and approved the final version.

There are no conflicts of interest.

Supplementary material

For supplementary material/s referred to in this article, please visit http://dx.doi.org/doi:10.1017/S0007114515003177

Appendix 1 Quality assessment scheme for cohort studies (Newcastle–Ottawa Scale (NOS))

Appendix 2 Quality assessment scheme for case–control studies (Newcastle–Ottawa Scale (NOS))

Appendix 3 Publication bias, prudent/healthy dietary pattern.

Appendix 4 Publication bias, western/unhealthy dietary pattern.

Footnotes

A study can be awarded a maximum of one star for each numbered item within the selection and outcome categories. A maximum of two stars can be given for comparability.

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