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Substitution of sugar-sweetened beverages for other beverages and the risk of developing coronary heart disease: Results from the Harvard Pooling Project of Diet and Coronary Disease
Journal Pre-proof Substitution of sugar-sweetened beverages for other beverages and the risk of developing coronary heart disease: Results from the Harvard Pooling Project of Diet and Coronary Disease
Amélie Keller, Eilis J. O'Reilly, Vasanti Malik, Julie E. Buring, Ingelise Andersen, Lyn Steffen, Kim Robien, Satu Männistö, Eric B. Rimm, Walter Willett, Berit Heitmann PII:
S0091-7435(19)30453-0
DOI:
https://doi.org/10.1016/j.ypmed.2019.105970
Reference:
YPMED 105970
To appear in:
Preventive Medicine
Received date:
12 July 2019
Revised date:
9 October 2019
Accepted date:
22 December 2019
Please cite this article as: A. Keller, E.J. O'Reilly, V. Malik, et al., Substitution of sugarsweetened beverages for other beverages and the risk of developing coronary heart disease: Results from the Harvard Pooling Project of Diet and Coronary Disease, Preventive Medicine(2018), https://doi.org/10.1016/j.ypmed.2019.105970
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© 2018 Published by Elsevier.
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Substitution of sugar-sweetened beverages for other beverages and the risk of developing coronary heart disease: results from the Harvard Pooling Project of Diet and Coronary Disease Amélie Keller1 (MPH), Eilis J O’Reilly2,4 (ScD), Vasanti Malik2,3(ScD), Julie E. Buring5(Dr.), Ingelise Andersen6(PhD), Lyn Steffen7(PhD), Kim Robien8(PhD), Satu Männistö9(PhD), Eric B. Rimm 2,3,10(ScD), Walter
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Willett2,3,10(M.D., Dr. P.H), Berit Heitmann1, 11,12(PhD) 1
Research Unit for Dietary Studies at The Parker Institute, Bispebjerg and Frederiksberg Hospital, Part of Copenhagen University Hospital, The Capital Region, Frederiksberg, Denmark 3
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Department of Nutrition, Department of Epidemiology, Harvard T.H. Chan School of Public Health, Boston, MA, USA
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Schoolof Public Health, University College Cork, Ireland
Division of Preventive Medicine, Brigham and Women’s Hospital and Harvard Medical School, Boston, MA, USA
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Section of Social Medicine, Department of Public Health, University of Copenhagen, Denmark
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Division of Epidemiology and Community Health, School of Public Health, University of Minnesota, USA
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Department of Exercise and Nutrition Sciences, Milken Institute School of Public Health, George Washington University, USA Institute for Health and Welfare Chronic Disease Prevention Unit, Finland
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Channing Division of Network Medicine, Brigham and Women's Hospital, Boston, MA, USA
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The Boden Institute of Obesity, Nutrition, Exercise & Eating Disorders, The University of Sydney, Sydney, New South Wales Australia Section for General Practice, Department of Public Health, University of Copenhagen, Denmark
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Corresponding author: Amélie Keller Post-doc Research Unit for Dietary Studies at the Parker Institute, Frederiksberg og Bispebjerg Hospital Nordre Fasanvej 57, Vej 8, Indgang 11 2000 Frederiksberg Denmark Email: [email protected] Funding: This project was supported by the Danish Heart Foundation, Region Hovedstaden, Etly og Jørgen Stjerngrens Fond, the Swiss Foundation for Nutrition Research, Oticon fonden, Niehls Bohr fondet. The funders had no role in the study design; in the collection, analysis, and interpretation of data; in the writing of the report; and in the decision to submit the article for publication. Conflict of interest: None of the authors had any conflicts of interest. Running title: Sugar-sweetened beverages and heart diseases Word count: 2529
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Abbreviations: ARIC - The Atherosclerosis Risk in Communities Study ASB - Artificially-Sweetened Beverages ATBC - The Alpha-Tocophenol and Beta-Carotene Cancer Prevention Study BMI – Body Mass Index CHD – Coronary Heart Disease CI - Confidence Intervals
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CVD – Cardiovascular Disease
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FFQ – Food Frequency Questionnaire
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HPFS - The Health Professionals Follow-up Study HPP - Harvard Pooling Project
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HR – Hazard Ratio
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IWHS - The Iowa Women’s Health Study
NHS - The Nurses’ Health Study TEI - Total Energy Intake
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T2DM – Type 2 diabetes mellitus
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MI – Myocardial Infarction
SSB – Sugar-Sweetened Beverages WHS - The Women’s Health Study
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Abstract Sugar-sweetened beverage (SSB) intake is associated with metabolic disorders. The reduction of SSB intake has been promoted to prevent death and disability from chronic diseases. We investigated the association between SSB intake and the risk of coronary events and death, and assessed if substitution of coffee, tea, milk, fruit juice and artificially-sweetened beverages (ASB) for SSBs was associated with a reduced risk of coronary events and death. This was a follow-up study in which data from six studies were pooled and
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standard observational analyses were performed. Diet intake was assessed at baseline by food-frequency
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questionnaires. Hazard ratios (HRs) with 95% confidence intervals for the incidence of coronary events and
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deaths were calculated by Cox proportional hazards regression. The effect of substituting another beverage for SSBs was calculated by taking the difference in the individual effect estimates. During the median 8.2-
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year follow-up, 4,248 coronary events and 1,630 coronary deaths were documented among 284,345
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individuals. 355 ml daily increase of SSB intake was associated with an increased risk of coronary events (HR: 1.08; 95%CI: 1.02, 1.14) and possibly coronary death (HR: 1.05; 95%CI: 0.96, 1.16). Substitution
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analyses suggested that replacing SSBs with coffee (HR: 0.93; 95%CI: 0.87, 1.00) or ASB (HR: 0.89; 95%CI:
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0.83, 0.97), might be associated with a lower risk of developing coronary events. We found that SSB intake was associated with an increased risk of coronary events and possibly coronary death. Our findings also suggest that replacing SSB’s with ASBs or coffee may lower the risk of developing CHD.
Key words Sugar-sweetened beverages; coronary heart diseases, substitution, Harvard Pooling Project
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Introduction One-half of US adults consumes ≥1 sugar-sweetened beverage (SSB) daily, representing 6.5% of total energy intake (TEI) (1). Direct associations between SSB consumption and weight gain, obesity (2) and type2 diabetes mellitus (T2DM) have been shown (3,4); and each additional daily serving of SSBs has been associated with a 22% increased risk of myocardial infarction (MI) and 13% increased risk of stroke (5). A recent meta-analysis of published studies found that SSB consumption is positively associated with
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coronary heart disease (CHD), stroke and heart failure (6). Furthermore, high intake of SSBs has also been
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associated with increased blood pressure and hyperlipidemia (7,8). As one-third of deaths worldwide are
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attributable to cardiovascular disease (CVD), mainly CHD (9), evaluation of potential strategies for reducing the burden of CHD is needed.
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Although individual studies have shown an inverse association between coffee, tea and possibly milk
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intakes (10–12) and the risk of CVD and limiting SSB consumption is recommended by public health agencies, there is insufficient evidence of what constitutes appropriate replacement beverages to make
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recommendations related to lowering the risk of developing CHD. Previous substitution studies have shown
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that substitution of water, milk, artificially-sweetened beverage (ASB), plain tea or coffee for SSBs was associated with a lower risk of weight gain, obesity and T2DM (4,13–16). In regards to cardiovascular health, results from intervention studies evaluating the effect of replacing SSBs by other beverages on CVDs showed discrepant results (17–19); while results from observational studies suggested that substituting SSBs with fruit juice and water or coffee was associated with a lower risk of metabolic syndrome (20) and stroke (21), respectively. Therefore, we aimed to (1) supplement the growing evidence regarding the association between SSB intake and the risk of incident CHD using standardized modeling of the exposure and confounding variables to remove potential sources of noncomparability and heterogeneity that occur in the published literature, and (2) to assess whether substitution of coffee, tea, milk, fruit juice and ASB for SSBs was associated with a lower risk of CHD events and deaths.
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Subjects and Methods Six of the eleven studies from the Harvard Pooling Project (HPP) of Diet and Coronary Disease were included. The HPP inclusion criteria were prospective studies with ≥150 incident coronary cases, assessment of usual dietary intake, and a validation of the diet assessment method(22). Only participants aged ≥35 years, without a history of CVD, diabetes, or cancer or extreme energy intake and with information on specific beverage consumption were included. The following studies met these criteria: The
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Atherosclerosis Risk in Communities Study (ARIC)(23); The Alpha-Tocophenol and Beta-Carotene Cancer
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Prevention Study (ATBC)(24); The Health Professionals Follow-up Study (HPFS)(25); The Iowa Women’s
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Health Study (IWHS)(26); The Women’s Health Study (WHS)(27); The Nurses’ Health Study (1980-1986 (NHS 80); 1986-1996 (NHS 86))(28). Two of the six included studies were randomized primary prevention studies
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and the others were prospective cohort studies. In the ATBC study, which was a clinical trial, analyses were
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also adjusted for the arm to which participants were randomized (placebo or intervention). WHS analyses
Exposure measures
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were not adjusted for trial arm as the study was ongoing at inclusion into the HPP.
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Diet intake was assessed at baseline by food-frequency questionnaires (FFQ). SSBs included carbonated/non-carbonated and caffeinated/non-caffeinated sodas, sport drinks and fruit drinks with any type of added sugar. Caffeinated coffee included all types of plain (unsweetened) coffee with caffeine and total coffee also included decaffeinated coffee. Tea included all types of plain (unsweetened) tea. Milk included only non-sweetened cow milk, either whole-fat, low-fat or total milk (whole-fat and low-fat combined). Fruit juice included only 100% fruit juice. ASB included any diet drinks sweetened with artificial sweeteners. The volume or frequency of a serving was used to assess the quantity of each beverage
consumed daily. Frequency data were converted to volume consumed/day on the basis of the frequency and study-specific serving size for each item. We calculated the consumption of beverage types by summing the related individual beverages listed in each study.
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Outcome measures The outcome measures were fatal CHD and nonfatal MI. Standardized criteria, questionnaires supplemented by medical records, autopsy reports or death certificates reviewed by physicians(29,30), were used to ascertain CHD events and death in each study. In this study, CHD events refer to any first incident CHD events, first event can be fatal CHD, and CHD death refers to total incident CHD death. The IWHS used self-reported CHD events; therefore only CHD death was used. Due to insufficient number of
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CHD deaths among women in ARIC and WHS, only total coronary events were included in this analysis.
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Statistical analyses
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Hazard ratios (HRs) with 95% confidence intervals (CIs) for the incidence of coronary events and deaths were calculated by Cox proportional hazards regression. The time metric was survival from entry into the
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study and stratification on age in years at baseline and calendar year at baseline questionnaire was
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performed. Person-years of follow-up were calculated from baseline until the date of event, death, or end of follow-up. Follow-up was censored at 10 years to minimize misclassification of exposure.
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The study-logs (sex-specific in ARIC) of HRs were weighted by the inverse of their variances, and a pooled
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estimate of the HRs was computed using the fixed-effects model, analyses using the random-effects model were also run as sensitivity analyses (data not shown). Between-study heterogeneity was calculated using the I-squared (I2) test. Effect modification by sex was also investigated by the I2 test for between-group heterogeneity. SSB consumption was primarily modelled continuously. Categorical analyses (<1 serving/d; 1-2 serving/d; >2 servings/d) were also performed (Supplementary data: Tables S2-3). The effect of substituting another beverage for SSBs was calculated by including them in the same model and taking the difference in the individual effect estimates (ß-coefficients). The 95% CI for the substitution effects were calculated using variances and covariance of the effect estimates for each beverage (the square root of the sum of their variances − (2 × covariance) (31,32). Women and men have different risks of CVD(33), therefore, sexspecific associations were also examined. Potential confounders and mediators were considered and
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stepwise added into the analyses. Nutrient intakes, including quintiles of cereal-fiber; trans-fatty acid; polyunsaturated fatty acid: saturated fatty acid ratio, were included in the model as potential confounders. TEI and Body Mass Index (BMI) were considered both confounders and mediators; therefore, they were added to the model individually. Baseline hypertension and high cholesterol were also added to the model as potential confounders. The crude model included only SSB and the stratification variables (smoking, physical activity, education,
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alcohol intake); model 1 further considered confounding by nutrient intakes; model 2 further included total energy; model 3 further included BMI; and model 4 further included baseline hypertension and high
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cholesterol.
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Individuals developing CHD in the first years of follow-up may have changed their dietary consumption due
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to pre-existing symptoms. Therefore, sensitivity analyses excluding individuals who developed CHD within
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the first two years of follow-up were performed. Ethics
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all participants was obtained.
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All included studies were previously approved by a national or institutional review board and consent from
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Results Characteristics of participants from included studies are presented in Table 1. During the median 8.2-year follow-up, 4,248 CHD events and 1,630 CHD deaths occurred among 284,345 individuals (Supplementary data: Figure S1). The daily median intake of SSBs was 48ml with 37% reporting no drinking of SSBs in the previous year. In the following, all results refer to Model 3. Combined HRs for 355 ml (12oz) daily increase of SSB intake and coronary events are shown in Table 2 and
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Figure 1, and CHD deaths are shown in Supplementary data: Table S1 and Figure S2. There was a positive
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association between daily increase in SSB intake and overall risk of coronary events in men (HR for 355
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ml/day:1.10; 95%CI:1.02-1.17) and in men and women combined (HR for 355 ml/day:1.08; 95%CI:1.021.14) but the results were not significant among women (HR for 355 ml/day:1.06; 95%CI:0.97-1.15). There
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was non-significant positive association between SSB intake and risk of coronary deaths in men and women
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combined (HR for 355 ml/day :1.05; 95%CI:0.96-1.16 I2=0%, p-heterogeneity=0.50). There was no indication of effect modification by sex (p>0.05). Results from the random effects model were similar (data not
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shown). No associations were seen between categories of SSB intake and the risk of coronary deaths, but
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there was an increased risk of coronary events among individuals consuming 1-2 servings SSBs per day compared to less than 1 serving (HR:1.15; 95%CI:1.00-1.33) (Supplementary data: Tables S2-S3). Combined HRs for substitution of SSB’s with coffee, tea, milk, fruit juice, and ASB (355ml/d) and coronary events are shown in Table 3, and coronary deaths are shown in Supplementary data: Table S4. Substituting caffeinated coffee for SSBs was inversely associated with the overall risk of coronary events (HR:0.92; 95%CI:0.86-0.99; I2=0%, p-heterogeneity=0.42). There was an inverse association between substitution of total coffee for SSBs and the risk of coronary events among women (HR:0.91; 95%CI:0.840.98; I2=25%, p-heterogeneity=0.25) and women and men combined (HR:0.93; 95%CI:0.87-1.00; I2=10%, pheterogeneity=0.34), but not among men (HR:1.00; 95%CI:0.87-1.15; I2=0%, p-heterogeneity=0.44) (Figure 2.
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There was a suggestion of an inverse association between substitution of tea for SSBs with the risk of coronary events (HR:0.94; 95%CI: 0.87-1.01; I2=0%, p-heterogeneity=0.72). Substituting ASBs for SSBs was inversely associated with coronary events (HR:0.89; 95%CI:0.83-0.97; I2=28%, p-heterogeneity=0.23) (Figure 3). There was a suggestion of an overall inverse association between substitution of low-fat milk (HR:0.96; 95%CI:0.90-1.03; I2=0%, p-heterogeneity=0.76) and total milk (HR:0.96; 95%CI:0.90-1.03; I2=0%, p-
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heterogeneity=0.50) for SSBs and the risk of coronary events. Substituting whole-fat milk for SSBs tended to decrease the risk of coronary events among men (HR:0.89; 95%CI:0.80-1.00; I2=58%, p-heterogeneity=0.08)
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but not among women (HR:1.13; 95%CI:0.96-1.34; I2=0%, P=0.84; p-heterogeneity by sex=0.02).
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Overall, substituting SSBs with other beverages was not associated with a different risk of coronary death.
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There was no indication of effect modifications by sex (p>0.05), except for substitution of whole-fat milk for
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SSBs and coronary events (p-heterogeneity=0.02).
Results from the random-effects model were similar to the fixed-effects model (data not shown).
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similar results (data not shown).
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Sensitivity analyses excluding individuals developing CHD within the first two years of follow-up showed
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Discussion This study suggests that daily increase of SSB intake is associated with an increased risk of coronary events. These results are in accordance with recent evidence suggesting a direct association between SSB intake and CHD (6,8). In addition, this study reports several novel findings. Substitution analyses suggested that replacing SSBs with ASBs or coffee lowers the risk of developing CHD events. Although not statistically significant, substituting tea, total milk, or low-fat milk for SSBs might also have inverse associations with
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coronary events risk development
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Recent evidence suggests that tea and coffee consumption is associated with a reduced CVD risk (11,12).
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One previous study found that substituting SSBs with coffee was associated with a lower risk of stroke and a trend towards a reduced risk with substitution with tea (21). To our knowledge, no previous studies
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estimated the effect of substituting tea or coffee for SSBs and the subsequent CHD risk. Tea constituents
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might ameliorate endothelial function, lipid profile and have anti-inflammatory, antioxidant or antithrombotic properties(12). Regular coffee contains caffeine which may elevate blood pressure;
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however it has been shown that caffeine consumption in the form of coffee was less likely to be associated
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with hypertension than caffeine consumed as SSBs. Thus, non-caffeine components in coffee may have antagonist physiological effects to those of caffeine (34). This study is the first to show a lower incidence of CHD events associated with replacing SSBs by ASBs. These findings might be counter intuitive as some recent evidence suggests a positive association between ASB intake and adverse health outcomes (35). However, challenges related to assessing the association between ASB intake and diseases development from cross-sectional studies or cohorts with short duration, such as reverse causation and residual confounding, may account for some studies findings(35). In line with our results, substitution of ASBs for SSBs was associated with reduced risk of stroke among men and women; and weight losses of 2% to 2.5% in two recent studies (17,21). Thus, compared with SSB’s, ASBs may be a healthier option for the prevention of coronary events.
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A pooled analysis of 10 prospective studies suggested a beneficial effect of milk consumption in reducing the risk of coronary heart disease and ischemic stroke (36); however, one previous study did not find any association between substitution of low fat milk for SSBs and the risk of stroke (21). Hence, the present study is the first to show a possible beneficial effect of substituting SSBs by milk, especially low-fat milk. Milk intake has been shown to increase high density lipoprotein cholesterol level which has antiatherogenic properties and may also have antihypertensive properties due to its mineral content (calcium,
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potassium, phosphorus, magnesium) (10,37).
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Data about water intake were incomplete or missing in most of the included studies; therefore, substitution of water for SSBs was not assessed. The paucity of data on water intake can be explained by the lack of
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focus on collecting such information in past cohort studies(38).
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Strengths and limitations
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To our knowledge, no previous study has examined the long-term effects of replacing SSBs with other beverages on the risk of coronary events and deaths. Our results have good generalizability among Western
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middle-aged populations, but may not be extrapolated to other populations. By using the Harvard Pooling
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Project of Diet and Coronary Disease we had a large sample size and great statistical power for total CHD, but power for fatal CHD was much less. Publication bias did not affect our pooled analyses as individual study inclusion criteria were independent from publication status. Selection bias was also limited as dietary assessment was conducted, at baseline, prior to disease development(39). The availability of dietary intake at baseline only prevented us from investigating change in beverage intake across time or to reduce random measurement error through statistical analysis. Individuals who changed drinking patterns may have been misclassified with respect to exposure; therefore, follow-up was censored at 10 years. Furthermore, sensitivity analyses excluding individuals who developed CHD within the first two-years of follow-up were performed; and similar results were found.
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Average SSB intake was relatively low; therefore it is likely that the effect of substituting SSBs by other beverages would be particularly important among populations with a higher SSB consumption such as young adults, non-Hispanic black and Mexican-American adults, individuals with low socioeconomic statuses and recent cohorts of same age individuals(40). BMI might be considered to be more of a mediator than a confounder in the association between SSB intake and CHD development; therefore, by controlling for BMI the effect of SSB’s may have been
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underestimated. Indeed, BMI might influence the frequency and quantity of SSB intake and
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overweight/obese individuals may have changed their beverage intake pattern in an attempt to lose weight prior to baseline diet assessment.
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We adjusted for a number of known potential confounders; however, residual confounding can never be
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excluded and additional confounding from other CHD risk factors could potentially explain our findings.
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Conclusion
This study shows that SSB intake is associated with an increased risk of coronary events and possibly
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coronary death. Our findings also suggest that replacing SSBs with ASBs or coffee may lower the risk of developing CHD events.
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Acknowledgments We would like to thank Dr. Ascherio for his contribution in obtaining the data. The Authors thank the ARIC, NHS, HPFS, WHS, IWHS and ATBC study participants. The Atherosclerosis Risk in Communities study has been funded in whole or in part with Federal funds from the National Heart, Lung, and Blood Institute, National Institutes of Health, Department of Health
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and Human Services (contract numbers HHSN268201700001I, HHSN268201700002I, HHSN268201700003I, HHSN268201700004I and HHSN268201700005I). The authors thank the staff and
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participants of the ARIC study for their important contributions. Funding was also supported by
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R01HL59367.
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Funding
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This project was supported by the Danish Heart Foundation, Region Hovedstaden, Etly og Jørgen Stjerngrens Fond, the Swiss Foundation for Nutrition Research, Oticon fonden, Niehls Bohr fondet. The
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funders had no role in the study design; in the collection, analysis, and interpretation of data; in the writing
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of the report; and in the decision to submit the article for publication.
Authors contribution
Berit L. Heitmann, Ingelise Andersen and Amélie Keller designed the study and formulated the research question. Eilis O’Reilly and Amélie Keller performed the statistical analyses. Vasanti Malik and Eilis O´Reilly provided feedback on the study design. Amélie Keller wrote the manuscript. Eric Rimm and Walter Willet provided interpretation of data and critical revision of the manuscript for important intellectual content. The remaining investigators (Julie E. Buring, Lyn Steffen, Kim Robien and Satu Männistö) represent the offsite investigators of the individual cohort studies. All of these investigators provided feedback on the manuscript. Conflict of interest: None.
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Transparency declaration The lead author, Amélie Cléo Keller, affirms that the manuscript is an honest, accurate, and transparent account of the study being reported; that no important aspects of the study have been omitted; and that
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any discrepancies from the study as originally planned (and, if relevant, registered) have been explained.
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Table 1: Baseline characteristics of participants from included studies CHD cases Study and sex
SSB intake
Baseline cohort1
Year of FFQ
Mean age, y
Median Follow-up, person-y
Total CHD events
CHD deaths
Median (ml/d)
Nondrinkers %
Male
5,238
1987
54.6
269
52
127.3
21.0
Female2
6,481
9.2 45,860 9.2 58,199
41.4
36.5
Male
21,141
1985
57.3
6.0 121,813
534
47.1
32.1
Male
41,684
1986
53.4
9.7 382,573
420
52.1
33.9
Female
29,528
1986
61.4
291
29.8
42.4
Female
81,412
1980
Female
61,700
Female
37,161
ARIC
53.9
123
ro
1339
1272
-p
HPFS
WHS
6.5 513,930
397
97
26.0
38.7
1986
52.6
10.0 606,997
696
208
29.6
47.1
1993
53.9
5.3 190,198 8.2 2,207,823
152
10
29.8
43.8
4248
1630
47.9
37
na
284,345 (23.9)
10.0 288,253
46.9
Jo ur
NHS4 1986
lP
NHS4 1980
re
IWHS3
All Studies5
of
ATBC
54.3
1
Sample size after exclusion of participants with baseline cardiovascular diseases, diabetes mellitus, cancer, very high or very low
caloric intake and missing information on SSB intake. Events censored at 10 years follow-up. 2
Insufficient events of coronary death for analysis among women
3
IWHS only had self-reported data on CHD events, therefore only CHD deaths were used
4
Number of participants only counted once
5
Percentage of males in parentheses
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Table 2: Combined hazard ratio (HR) for coronary events for one serving daily increase of SSB intake All
Women 2
Men 2
HR (95%CI)
I test for betweenstudies heterogeneity (p-value)
N
HR (95%CI)
I test for betweenstudies heterogeneity (p-value)
N
HR (95%CI)
Crude Model
1.16 (1.11,1.22)
0.0% (0.70)
284,289
1.18 (1.10,1.27)
0.0% (0.90)
216,226
Model 1
1.08 (1.03, 1.14) 1.09 (1.04, 1.15) 1.08 (1.02, 1.14) 1.08 (1.02,1.13)
0.0% (0.46) 0.0% (0.74) 0.0% (0.61) 0.0% (0.67)
284,289
1.06 (0.98, 1.15) 1.08 (1.00, 1.17) 1.06 (0.97, 1.15) 1.06 (0.97,1.15)
24.4% (0.27) 0.0% (0.41) 0.0% (0.41) 0.0% (0.40)
216,226
Model 2 Model 3 Model 4
284,289 280,886 274,754
P l a
re
213,759 143,184
N
P-value, test for effect modification by sex
1.15 (1.08,1.23)
33.8% (0.22)
68,063
0.63
1.10 (1.02, 1.18) 1.10 (1.03, 1.18) 1.10 (1.02, 1.17) 1.09 (1.02,1.17)
0.0% (0.52) 0.0% (0.80) 0.0% (0.55) 0.0% (0.65)
68,063
0.53
68,063
0.68
67,127
0.51
131,570
0.61
f o
ro
-p
216,226
2
I test for betweenstudies heterogeneity (p-value)
n r u
Age at baseline (y) and the calendar year in which the baseline questionnaire was returned were entered into the model through the strata statement. Within each study, HRs with 95% CIs for the incidence of a coronary events was calculated by using Cox proportional hazards regression with time in study (y) as the time metric. The study-specific logs of HRs were
o J
weighted by the inverse of their variances, and a combined estimate of the HRs was computed by using a fixed-effects model. A crude model included only SSB and the stratification variables (smoking, physical activity, education and alcohol); model 1 considered confounding by diet and included quintiles of cereal fibers; quintiles of trans-fat; quintiles of polyunsaturated fat/saturated fat ratio; model 2 further included total energy; model 3 further included BMI; model 4 then included intermediate variables: baseline hypertension and high cholesterol. One serving = 355ml.
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Table 3: Combined hazard ratio (HR) for coronary events by substitution of one serving sugar-sweetened beverages (SSB) with one serving of coffee, tea, milk, fruit juice or artificially-sweetened beverages (ASB) All HR (95%CI)
Caffeinated coffee for SSB
Crude model Model 1 Model 2 Model 3 Model 4
Total Coffee for SSB
Crude model Model 1 Model 2 Model 3 Model 4
Women 2
I test for betweenstudies heterogeneity (p-value)
N
0.91 (0.86, 0.97) 0.90 (0.84, 0.96) 0.98 (0.91, 1.04) 0.92 (0.86, 0.99) 0.94 (0.87, 1.00)
0.0% (0.46) 7.3% (0.37) 63.6% (0.02) 0.0% (0.42) 16.2% (0.31)
284,345
0.92 (0.86, 0.98) 0.97 (0.91, 1.04) 0.94 (0.87, 1.00) 0.93 (0.87, 1.00) 0.95 (0.88, 1.01)
10.9% (0.34) 36.5% (0.19) 6.3% (0.36) 10.1% (0.34) 13.1% (0.33)
2
HR (95%CI)
284,345 284,345
274,754
n r u
272,626 272,626 272,626 269,173 212,864
I test for betweenstudies heterogeneity (p-value)
N
HR (95%CI)
0.0% (0.92) 5.2% (0.37) 17.2% (0.31) 0.0% (0.56) 0.0% (0.52)
216,282
re
0.93 0.82, 1.06) 1.00 (0.87, 1.14) 1.01 (0.88, 1.16) 0.91 (0.84, 0.98) 1.02 (0.89, 1.17)
0.0% (0.59) 0.0% (0.63) 30.9% (0.23) 25.0% (0.25) 26.4% (0.24)
209,801
-p
216,282 216,282 213,759 143,184
209,801 209,801 207,283 102,422
2
I test for betweenstudies heterogeneity (p-value)
N
P-value, 2 I test for between -groups heterogeneity
0.88 0.81, 0.96) 0.89 (0.81, 0.97) 0.89 (0.81, 0.98) 0.90 (0.81, 1.01) 0.91 (0.83, 1.00)
62.8% (0.10) 52.4% (0.15) 66.5% (0.08) 61.5% (0.12) 66.3% (0.09)
68,063
0.22
68,063
0.72
68,063
0.01
67,127
0.57
131,570
0.38
0.91 (0.85, 0.98) 0.96 (0.889, 1.040) 0.91 (0.84, 0.99) 1.00 (0.87, 1.15) 0.92 (0.851, 1.00)
66.4% (0.09) 76.6% (0.04) 0.0% (0.56) 0.0% (0.44) 0.0% (0.42)
62,825
0.75
62,825
0.64
62,825
0.24
61,890
0.24
110,442
0.23
f o
ro
0.95 (0.87, 1.03) 0.91 (0.83, 0.99) 1.07 (0.97, 1.17) 0.94 (0.86, 1.03) 0.96 (0.88, 1.06)
P l a
280,886
o J
Men
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Table 3: (continued) All HR (95%CI)
Tea for SSB
N
Women HR (95%CI)
2
I test for betweenstudies heterogeneity (p-value)
Men HR (95%CI)
N
f o
o r p
Crude model
0.87 (0.81, 0.94)
0.0% (0.60)
283,862
0.84 (0.75, 0.93)
7.7% (0.35)
Model 1
0.97 (0.89, 1.05) 0.94 (0.87, 1.01) 0.94 (0.87, 1.01) 0.95 (0.88, 1.02)
0.0% (0.87) 0.0% (0.54) 0.0% (0.72) 0.0% (0.69)
283,862
1.06 (0.91, 1.22) 0.94 (0.84, 1.05) 0.95 (0.84, 1.06) 0.95 (0.84, 1.06)
e
0.88 (0.82, 0.94) 1.01 (0.95, 1.09) 0.97 (0.91, 1.04) 0.96 (0.90, 1.03)
31.9% (0.19) 0.0% (0.69) 0.0% (0.69) 0.0% (0.76)
284,344
0.0% (0.75) 0.0% (0.66) 0.0% (0.61) 0.0% (0.68)
216,282
o J
0.79 (0.70, 0.89) 0.96 (0.85, 1.09) 0.97 (0.86, 1.10) 0.97 (0.85, 1.09)
0.96 (0.90, 1.03)
0.0% (0.78)
274,754
0.96 (0.84, 1.08)
0.0% (0.62)
143,184
Model 2 Model 3 Model 4
Low fat milk for SSB
2
I test for betweenstudies heterogeneity (p-value)
Crude model Model 1 Model 2 Model 3
Model 4
283,862 280,403
l a
273,788
n r u
284,344 284,344 280,885
r P
0.0% (0.95) 35.1% (0.20) 7.8% (0.35) 17.0% (0.31)
2
2
I test for betweenstudies heterogeneity (p-value)
N
P-value, I test for betweengroups heterogeneity
215,799
0.90 (0.82, 0.99)
0.0% (0.80)
68,063
0.36
215,799
0.93 (0.85, 1.03) 0.94 (0.85, 1.03) 0.94 (0.85, 1.03) 0.94 (0.86, 1.04)
0.0% (0.93) 0.0% (0.81) 0.0% (0.81) 0.0% (0.86)
68,063
0.16
68,063
0.95
67,127
0.88
131,570
0.98
0.92 0.85, 1.00) 1.04 (0.95,1.13) 0.97 (0.90,1.06) 0.96 (0.89,1.05)
33.7% (0.22) 0.0% (0.50) 1.9% (0.36) 0.0% (0.40)
68,062
0.03
68,062
0.33
68,062
0.98
67,126
0.98
0.97 (0.88,1.05)
0.0% (0.49)
131,570
0.89
215,799 213,276 142,218
216,282 216,282 213,759
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Table 3: (continued) All HR (95%CI)
Whole fat milk for SSB
Crude model Model 1 Model 2 Model 3 Model 4
Total milk for SSB
Crude model Model 1 Model 2 Model 3 Model 4
2
Women HR (95%CI)
I test for betweenstudies heterogeneity (p-value)
N
1.03 (0.95, 1.12) 1.05 (0.96, 1.15) 0.94 (0.86, 1.02) 0.95 (0.87, 1.04) 0.97 (0.88, 1.06)
62.2% (0.01) 49.0% (0.07) 42.6% (0.11) 46.2% (0.08) 39.9% (0.13)
284,345
0.93 (0.87, 0.99) 0.97 (0.90, 1.03) 0.97 (0.90, 1.03) 0.96 (0.90, 1.03) 0.97 (0.90, 1.03)
10.2% (0.35) 0.0% (0.46) 0.0% (0.45) 0.0% (0.50) 0.0% (0.65)
284,345 284,345 280,886
J
u o
rn
284,344 284,344 284,344 280,885 274,754
Men HR (95%CI)
N
0.0% (0.87) 0.0% (0.83) 0.0% (0.81) 0.0% (0.84) 0.0% (0.93)
e
o r p
0.91 (0.81, 1.01) 1.00 (0.89, 1.13) 1.000 (0.89, 1.12) 1.01 (0.90, 1.13) 1.01 (0.89, 1.13)
0.0% (0.79) 0.0% (0.83) 0.0% (0.80) 0.0% (0.90) 0.0% (0.88)
216,282
r P
216,282 216,282 216,282 213,759 143,184
216,282 216,282 213,759 143,184
2
I test for betweenstudies heterogeneity (p-value)
N
P-value, I test for betweengroups heterogeneity
0.94 (0.85,1.04) 1.03 (0.93,1.15) 0.88 (0.79,0.98) 0.89 (0.80,1.00) 0.90 (0.81,1.00)
59.4% (0.09) 80.7% (0.01) 59.1% (0.09) 57.7% (0.09) 41.6% (0.18)
68,063
0.001
68,063
0.48
68,063
0.03
67,127
0.02
131,570
0.01
0.94 (0.87,1.02) 0.95 (0.87,1.03) 0.95 (0.87,1.03) 0.94 (0.87,1.02) 0.95 (0.87,1.03)
62.9% (0.07) 52.4% (0.12) 52.5% (0.12) 49.6% (0.14) 31.5% (0.23)
68,062
0.62
68,062
0.44
68,062
0.46
67,126
0.36
131,570
0.42
f o
1.28 (1.09, 1.49) 1.11 (0.94, 1.31) 1.10 (0.93, 1.29) 1.13 (0.96, 1.34) 1.16 (0.98, 1.37)
l a
274,754
2
I test for betweenstudies heterogeneity (p-value)
2
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Table 3: (continued) All HR (95%CI)
Fruit juice for SSB
Crude model Model 1 Model 2 Model 3 Model 4
ASB for SSB
0.79 (0.71, 0.89) 0.96 (0.86, 1.08) 0.98 (0.88, 1.10) 0.97 (0.85, 1.07) 1.11 (1.11, 1.11)
2
Women HR (95%CI)
I test for betweenstudies heterogeneity (p-value)
N
0.0% (0.51) 3.0% (0.31) 27.6% (0.22) 0.0% (0.44) 58.6% (0.03)
284,277 284,277 284,277 280,818
l a
274,620
n r u
Crude model
0.79 (0.66, 0.95) 1.03 (0.87, 1.23) 1.08 (0.91, 1.28) 1.02 (0.85, 1.22) 0.97 (0.81, 1.16)
2
I test for betweenstudies heterogeneity (p-value) 0.0% (0.57) 0.0% (0.53) 15.1% (0.32) 0.0% (0.58) 0.0% (0.51)
f o
o r p
e
r P
Men HR (95%CI)
N
216,215 216,215 216,215 213,692 143,050
0.79 (0.69, .92) 0.92 (0.79,1.06) 0.92 (0.79, .06) 0.91 (0.79,1.06) 1.11 (1.11, .11)
2
I test for betweenstudies heterogeneity (p-value)
N
P-value, I test for betweengroups heterogeneity
39.2% (0.19) 32.4% (0.23) 27.4% (0.25) 34.0% (0.22) 80.0% (0.01)
68,062
0.98
68,062
0.31
68,062
0.16
67,126
0.35
131,570
0.14
0.84 0.0% 284,289 0.836 0.0% 216,226 0.84 0.0% 68,063 0.97 (0.78, 0.90) (0.73) (0.76, 0.93) (0.43) (0.75, 0.93) (0.79) Model 1 0.92 0.0% 284,289 0.94 27.6% 216,226 0.90 0.0% 68,063 0.61 (0.85, 0.99) (0.48) (0.84, 1.04) (0.25) (0.81, 1.01) (0.74) Model 2 0.94 19.7% 284,289 0.96 43.1% 216,226 0.91 0.0% 68,063 0.48 (0.86, 1.01) (0.29) (0.86, 1.07) (0.15) (0.81, 1.02) (0.51) Model 3 0.89 27.7% 280,830 0.91 49.4% 213,703 0.87 0.0% 67,127 0.60 (0.83, 0.97) (0.23) (0.82, 1.02) (0.12) (0.78, 0.98) (0.40) Model 4 0.88 26.8% 305,480 0.90 50.4% 173,910 0.87 0.0% 131,570 0.63 (0.82, 0.96) (0.23) (0.81, 1.01) (0.11) (0.77, 0.97) (0.46) Age at baseline (y) and the calendar year in which the baseline questionnaire was returned were entered into the model through the strata statement. Within each study, HRs with 95% CIs for the incidence of a coronary events was calculated by using Cox proportional hazards regression with time in study (y) as the time metric. The study-specific logs of HRs were weighted by the inverse of their variances, and a combined estimate of the HRs was computed by using a fixed-effects model. A crude model included only SSB and the stratification variables (smoking, physical activity, education and alcohol); model 1 further included confounding by diet and included quintiles of cereal fibers; quintiles of trans-fat; quintiles of poly-unsaturated fat/saturated fat ratio; model 2 further included total energy; model 3 further included BMI; model 4 further included baseline hypertension and high cholesterol. One serving = 355ml
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Figure 1: Association between one serving daily increase of SSBs (355ml) and the risk of developing coronary events
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Age at baseline (y) and the calendar year in which the baseline questionnaire was returned were entered into the model through the strata statement (Model 3). Within each study, HRs with 95% CIs for the incidence of a coronary event was calculated by using Cox proportional hazards regression with time in study (y) as the time metric. The studyspecific logs of HRs were weighted by the inverse of their variances, and a combined estimate of the HRs was computed by using a fixed-effects model. Analyses were stratified by sex and adjusted for smoking, physical activity, alcohol intake, education, alcohol, diet (quintiles of cereal fiber; quintiles of trans-fat; quintiles of poly-unsaturated fat/saturated fat ratio), energy and BMI. The diamonds represent the combined hazard ratios and 95% CI. ARIC, Atherosclerosis Risk in Communities Study; ATBC, Alpha-Tocopherol and Beta-Carotene Cancer Prevention Study; HPFS, Health Professionals Follow-Up Study; IWHS, Iowa Women’s Health Study; NHS80, Nurses’ Health Study 1980; NHS86, Nurses’ Health Study 1986; WHS, Women’s Health Study
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Figure 2: Hazard ratio (HR) for all coronary events by substitution of one serving sugar-sweetened beverages (SSB) with one serving of coffee
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Age at baseline (y) and the calendar year in which the baseline questionnaire was returned were entered into the model through the strata statement (Model 3). Within each study, HRs with 95% CIs for the incidence of a coronary events was calculated by using
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Cox proportional hazards regression with time in study (y) as the time metric. The study-specific logs of HRs were weighted by the
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inverse of their variances, and a combined estimate of the HRs was computed by using a fixed-effects model. Analyses were
stratified by sex and adjusted for smoking, physical activity, alcohol intake, education, alcohol, diet (quintiles of cereal
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fiber; quintiles of trans-fat; quintiles of poly-unsaturated fat/saturated fat ratio), energy and BMI. The diamonds represent the combined hazard ratios and 95% CI. ARIC, Atherosclerosis Risk in Communities Study; ATBC, Alpha-
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Tocopherol and Beta-Carotene Cancer Prevention Study; HPFS, Health Professionals Follow-Up Study; IWHS, Iowa Women’s Health Study; NHS80, Nurses’ Health Study 1980; NHS86, Nurses’ Health Study 1986; WHS, Women’s Health Study. One serving = 355ml
Figure 3: Hazard ratio (HR) for all coronary events by substitution of one serving sugar-sweetened beverages (SSB) with one serving of artificially-sweetened beverages Age at baseline (y) and the calendar year in which the baseline questionnaire was returned were entered into the model through the strata statement (Model 3). Within each study, HRs with 95% CIs for the incidence of a coronary events was calculated by using Cox proportional hazards regression with time in study (y) as the time metric. The study-specific logs of HRs were weighted by the inverse of their variances, and a combined estimate of the HRs was computed by using a fixed-effects model. Analyses were
stratified by sex and adjusted for smoking, physical activity, alcohol intake, education, alcohol, diet (quintiles of cereal fiber; quintiles of trans-fat; quintiles of poly-unsaturated fat/saturated fat ratio), energy and BMI. The diamonds represent the combined hazard ratios and 95% CI. ARIC, Atherosclerosis Risk in Communities Study; ATBC, Alpha-
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Tocopherol and Beta-Carotene Cancer Prevention Study; HPFS, Health Professionals Follow-Up Study; IWHS, Iowa Women’s Health Study; NHS80, Nurses’ Health Study 1980; NHS86, Nurses’ Health Study 1986; WHS, Women’s Health Study. One serving = 355ml
Highlights Pooled analysis of four large cohort studies and two intervention studies
Higher consumption of sugar-sweetened (SSB) beverages is associated with greater risk of coronary
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events
Replacing SSB by artificially-sweetened beverage decreases the risk of developing coronary events
Replacing SSB by coffee decreases the risk of developing coronary events
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Figure 1
Figure 2
Figure 3
Amélie Keller, Eilis J. O'Reilly, Vasanti Malik, Julie E. Buring, Ingelise Andersen, Lyn Steffen, Kim Robien, Satu Männistö, Eric B. Rimm, Walter Willett, Berit Heitmann PII:
S0091-7435(19)30453-0
DOI:
https://doi.org/10.1016/j.ypmed.2019.105970
Reference:
YPMED 105970
To appear in:
Preventive Medicine
Received date:
12 July 2019
Revised date:
9 October 2019
Accepted date:
22 December 2019
Please cite this article as: A. Keller, E.J. O'Reilly, V. Malik, et al., Substitution of sugarsweetened beverages for other beverages and the risk of developing coronary heart disease: Results from the Harvard Pooling Project of Diet and Coronary Disease, Preventive Medicine(2018), https://doi.org/10.1016/j.ypmed.2019.105970
This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
© 2018 Published by Elsevier.
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Substitution of sugar-sweetened beverages for other beverages and the risk of developing coronary heart disease: results from the Harvard Pooling Project of Diet and Coronary Disease Amélie Keller1 (MPH), Eilis J O’Reilly2,4 (ScD), Vasanti Malik2,3(ScD), Julie E. Buring5(Dr.), Ingelise Andersen6(PhD), Lyn Steffen7(PhD), Kim Robien8(PhD), Satu Männistö9(PhD), Eric B. Rimm 2,3,10(ScD), Walter
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Willett2,3,10(M.D., Dr. P.H), Berit Heitmann1, 11,12(PhD) 1
Research Unit for Dietary Studies at The Parker Institute, Bispebjerg and Frederiksberg Hospital, Part of Copenhagen University Hospital, The Capital Region, Frederiksberg, Denmark 3
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Department of Nutrition, Department of Epidemiology, Harvard T.H. Chan School of Public Health, Boston, MA, USA
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Schoolof Public Health, University College Cork, Ireland
Division of Preventive Medicine, Brigham and Women’s Hospital and Harvard Medical School, Boston, MA, USA
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Section of Social Medicine, Department of Public Health, University of Copenhagen, Denmark
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Division of Epidemiology and Community Health, School of Public Health, University of Minnesota, USA
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Department of Exercise and Nutrition Sciences, Milken Institute School of Public Health, George Washington University, USA Institute for Health and Welfare Chronic Disease Prevention Unit, Finland
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Channing Division of Network Medicine, Brigham and Women's Hospital, Boston, MA, USA
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The Boden Institute of Obesity, Nutrition, Exercise & Eating Disorders, The University of Sydney, Sydney, New South Wales Australia Section for General Practice, Department of Public Health, University of Copenhagen, Denmark
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Corresponding author: Amélie Keller Post-doc Research Unit for Dietary Studies at the Parker Institute, Frederiksberg og Bispebjerg Hospital Nordre Fasanvej 57, Vej 8, Indgang 11 2000 Frederiksberg Denmark Email: [email protected] Funding: This project was supported by the Danish Heart Foundation, Region Hovedstaden, Etly og Jørgen Stjerngrens Fond, the Swiss Foundation for Nutrition Research, Oticon fonden, Niehls Bohr fondet. The funders had no role in the study design; in the collection, analysis, and interpretation of data; in the writing of the report; and in the decision to submit the article for publication. Conflict of interest: None of the authors had any conflicts of interest. Running title: Sugar-sweetened beverages and heart diseases Word count: 2529
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Abbreviations: ARIC - The Atherosclerosis Risk in Communities Study ASB - Artificially-Sweetened Beverages ATBC - The Alpha-Tocophenol and Beta-Carotene Cancer Prevention Study BMI – Body Mass Index CHD – Coronary Heart Disease CI - Confidence Intervals
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CVD – Cardiovascular Disease
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FFQ – Food Frequency Questionnaire
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HPFS - The Health Professionals Follow-up Study HPP - Harvard Pooling Project
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HR – Hazard Ratio
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IWHS - The Iowa Women’s Health Study
NHS - The Nurses’ Health Study TEI - Total Energy Intake
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T2DM – Type 2 diabetes mellitus
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MI – Myocardial Infarction
SSB – Sugar-Sweetened Beverages WHS - The Women’s Health Study
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Abstract Sugar-sweetened beverage (SSB) intake is associated with metabolic disorders. The reduction of SSB intake has been promoted to prevent death and disability from chronic diseases. We investigated the association between SSB intake and the risk of coronary events and death, and assessed if substitution of coffee, tea, milk, fruit juice and artificially-sweetened beverages (ASB) for SSBs was associated with a reduced risk of coronary events and death. This was a follow-up study in which data from six studies were pooled and
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standard observational analyses were performed. Diet intake was assessed at baseline by food-frequency
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questionnaires. Hazard ratios (HRs) with 95% confidence intervals for the incidence of coronary events and
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deaths were calculated by Cox proportional hazards regression. The effect of substituting another beverage for SSBs was calculated by taking the difference in the individual effect estimates. During the median 8.2-
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year follow-up, 4,248 coronary events and 1,630 coronary deaths were documented among 284,345
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individuals. 355 ml daily increase of SSB intake was associated with an increased risk of coronary events (HR: 1.08; 95%CI: 1.02, 1.14) and possibly coronary death (HR: 1.05; 95%CI: 0.96, 1.16). Substitution
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analyses suggested that replacing SSBs with coffee (HR: 0.93; 95%CI: 0.87, 1.00) or ASB (HR: 0.89; 95%CI:
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0.83, 0.97), might be associated with a lower risk of developing coronary events. We found that SSB intake was associated with an increased risk of coronary events and possibly coronary death. Our findings also suggest that replacing SSB’s with ASBs or coffee may lower the risk of developing CHD.
Key words Sugar-sweetened beverages; coronary heart diseases, substitution, Harvard Pooling Project
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Introduction One-half of US adults consumes ≥1 sugar-sweetened beverage (SSB) daily, representing 6.5% of total energy intake (TEI) (1). Direct associations between SSB consumption and weight gain, obesity (2) and type2 diabetes mellitus (T2DM) have been shown (3,4); and each additional daily serving of SSBs has been associated with a 22% increased risk of myocardial infarction (MI) and 13% increased risk of stroke (5). A recent meta-analysis of published studies found that SSB consumption is positively associated with
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coronary heart disease (CHD), stroke and heart failure (6). Furthermore, high intake of SSBs has also been
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associated with increased blood pressure and hyperlipidemia (7,8). As one-third of deaths worldwide are
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attributable to cardiovascular disease (CVD), mainly CHD (9), evaluation of potential strategies for reducing the burden of CHD is needed.
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Although individual studies have shown an inverse association between coffee, tea and possibly milk
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intakes (10–12) and the risk of CVD and limiting SSB consumption is recommended by public health agencies, there is insufficient evidence of what constitutes appropriate replacement beverages to make
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recommendations related to lowering the risk of developing CHD. Previous substitution studies have shown
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that substitution of water, milk, artificially-sweetened beverage (ASB), plain tea or coffee for SSBs was associated with a lower risk of weight gain, obesity and T2DM (4,13–16). In regards to cardiovascular health, results from intervention studies evaluating the effect of replacing SSBs by other beverages on CVDs showed discrepant results (17–19); while results from observational studies suggested that substituting SSBs with fruit juice and water or coffee was associated with a lower risk of metabolic syndrome (20) and stroke (21), respectively. Therefore, we aimed to (1) supplement the growing evidence regarding the association between SSB intake and the risk of incident CHD using standardized modeling of the exposure and confounding variables to remove potential sources of noncomparability and heterogeneity that occur in the published literature, and (2) to assess whether substitution of coffee, tea, milk, fruit juice and ASB for SSBs was associated with a lower risk of CHD events and deaths.
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Subjects and Methods Six of the eleven studies from the Harvard Pooling Project (HPP) of Diet and Coronary Disease were included. The HPP inclusion criteria were prospective studies with ≥150 incident coronary cases, assessment of usual dietary intake, and a validation of the diet assessment method(22). Only participants aged ≥35 years, without a history of CVD, diabetes, or cancer or extreme energy intake and with information on specific beverage consumption were included. The following studies met these criteria: The
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Atherosclerosis Risk in Communities Study (ARIC)(23); The Alpha-Tocophenol and Beta-Carotene Cancer
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Prevention Study (ATBC)(24); The Health Professionals Follow-up Study (HPFS)(25); The Iowa Women’s
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Health Study (IWHS)(26); The Women’s Health Study (WHS)(27); The Nurses’ Health Study (1980-1986 (NHS 80); 1986-1996 (NHS 86))(28). Two of the six included studies were randomized primary prevention studies
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and the others were prospective cohort studies. In the ATBC study, which was a clinical trial, analyses were
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also adjusted for the arm to which participants were randomized (placebo or intervention). WHS analyses
Exposure measures
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were not adjusted for trial arm as the study was ongoing at inclusion into the HPP.
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Diet intake was assessed at baseline by food-frequency questionnaires (FFQ). SSBs included carbonated/non-carbonated and caffeinated/non-caffeinated sodas, sport drinks and fruit drinks with any type of added sugar. Caffeinated coffee included all types of plain (unsweetened) coffee with caffeine and total coffee also included decaffeinated coffee. Tea included all types of plain (unsweetened) tea. Milk included only non-sweetened cow milk, either whole-fat, low-fat or total milk (whole-fat and low-fat combined). Fruit juice included only 100% fruit juice. ASB included any diet drinks sweetened with artificial sweeteners. The volume or frequency of a serving was used to assess the quantity of each beverage
consumed daily. Frequency data were converted to volume consumed/day on the basis of the frequency and study-specific serving size for each item. We calculated the consumption of beverage types by summing the related individual beverages listed in each study.
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Outcome measures The outcome measures were fatal CHD and nonfatal MI. Standardized criteria, questionnaires supplemented by medical records, autopsy reports or death certificates reviewed by physicians(29,30), were used to ascertain CHD events and death in each study. In this study, CHD events refer to any first incident CHD events, first event can be fatal CHD, and CHD death refers to total incident CHD death. The IWHS used self-reported CHD events; therefore only CHD death was used. Due to insufficient number of
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CHD deaths among women in ARIC and WHS, only total coronary events were included in this analysis.
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Statistical analyses
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Hazard ratios (HRs) with 95% confidence intervals (CIs) for the incidence of coronary events and deaths were calculated by Cox proportional hazards regression. The time metric was survival from entry into the
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study and stratification on age in years at baseline and calendar year at baseline questionnaire was
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performed. Person-years of follow-up were calculated from baseline until the date of event, death, or end of follow-up. Follow-up was censored at 10 years to minimize misclassification of exposure.
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The study-logs (sex-specific in ARIC) of HRs were weighted by the inverse of their variances, and a pooled
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estimate of the HRs was computed using the fixed-effects model, analyses using the random-effects model were also run as sensitivity analyses (data not shown). Between-study heterogeneity was calculated using the I-squared (I2) test. Effect modification by sex was also investigated by the I2 test for between-group heterogeneity. SSB consumption was primarily modelled continuously. Categorical analyses (<1 serving/d; 1-2 serving/d; >2 servings/d) were also performed (Supplementary data: Tables S2-3). The effect of substituting another beverage for SSBs was calculated by including them in the same model and taking the difference in the individual effect estimates (ß-coefficients). The 95% CI for the substitution effects were calculated using variances and covariance of the effect estimates for each beverage (the square root of the sum of their variances − (2 × covariance) (31,32). Women and men have different risks of CVD(33), therefore, sexspecific associations were also examined. Potential confounders and mediators were considered and
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stepwise added into the analyses. Nutrient intakes, including quintiles of cereal-fiber; trans-fatty acid; polyunsaturated fatty acid: saturated fatty acid ratio, were included in the model as potential confounders. TEI and Body Mass Index (BMI) were considered both confounders and mediators; therefore, they were added to the model individually. Baseline hypertension and high cholesterol were also added to the model as potential confounders. The crude model included only SSB and the stratification variables (smoking, physical activity, education,
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alcohol intake); model 1 further considered confounding by nutrient intakes; model 2 further included total energy; model 3 further included BMI; and model 4 further included baseline hypertension and high
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cholesterol.
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Individuals developing CHD in the first years of follow-up may have changed their dietary consumption due
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to pre-existing symptoms. Therefore, sensitivity analyses excluding individuals who developed CHD within
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the first two years of follow-up were performed. Ethics
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all participants was obtained.
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All included studies were previously approved by a national or institutional review board and consent from
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Results Characteristics of participants from included studies are presented in Table 1. During the median 8.2-year follow-up, 4,248 CHD events and 1,630 CHD deaths occurred among 284,345 individuals (Supplementary data: Figure S1). The daily median intake of SSBs was 48ml with 37% reporting no drinking of SSBs in the previous year. In the following, all results refer to Model 3. Combined HRs for 355 ml (12oz) daily increase of SSB intake and coronary events are shown in Table 2 and
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Figure 1, and CHD deaths are shown in Supplementary data: Table S1 and Figure S2. There was a positive
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association between daily increase in SSB intake and overall risk of coronary events in men (HR for 355
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ml/day:1.10; 95%CI:1.02-1.17) and in men and women combined (HR for 355 ml/day:1.08; 95%CI:1.021.14) but the results were not significant among women (HR for 355 ml/day:1.06; 95%CI:0.97-1.15). There
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was non-significant positive association between SSB intake and risk of coronary deaths in men and women
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combined (HR for 355 ml/day :1.05; 95%CI:0.96-1.16 I2=0%, p-heterogeneity=0.50). There was no indication of effect modification by sex (p>0.05). Results from the random effects model were similar (data not
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shown). No associations were seen between categories of SSB intake and the risk of coronary deaths, but
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there was an increased risk of coronary events among individuals consuming 1-2 servings SSBs per day compared to less than 1 serving (HR:1.15; 95%CI:1.00-1.33) (Supplementary data: Tables S2-S3). Combined HRs for substitution of SSB’s with coffee, tea, milk, fruit juice, and ASB (355ml/d) and coronary events are shown in Table 3, and coronary deaths are shown in Supplementary data: Table S4. Substituting caffeinated coffee for SSBs was inversely associated with the overall risk of coronary events (HR:0.92; 95%CI:0.86-0.99; I2=0%, p-heterogeneity=0.42). There was an inverse association between substitution of total coffee for SSBs and the risk of coronary events among women (HR:0.91; 95%CI:0.840.98; I2=25%, p-heterogeneity=0.25) and women and men combined (HR:0.93; 95%CI:0.87-1.00; I2=10%, pheterogeneity=0.34), but not among men (HR:1.00; 95%CI:0.87-1.15; I2=0%, p-heterogeneity=0.44) (Figure 2.
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There was a suggestion of an inverse association between substitution of tea for SSBs with the risk of coronary events (HR:0.94; 95%CI: 0.87-1.01; I2=0%, p-heterogeneity=0.72). Substituting ASBs for SSBs was inversely associated with coronary events (HR:0.89; 95%CI:0.83-0.97; I2=28%, p-heterogeneity=0.23) (Figure 3). There was a suggestion of an overall inverse association between substitution of low-fat milk (HR:0.96; 95%CI:0.90-1.03; I2=0%, p-heterogeneity=0.76) and total milk (HR:0.96; 95%CI:0.90-1.03; I2=0%, p-
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heterogeneity=0.50) for SSBs and the risk of coronary events. Substituting whole-fat milk for SSBs tended to decrease the risk of coronary events among men (HR:0.89; 95%CI:0.80-1.00; I2=58%, p-heterogeneity=0.08)
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but not among women (HR:1.13; 95%CI:0.96-1.34; I2=0%, P=0.84; p-heterogeneity by sex=0.02).
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Overall, substituting SSBs with other beverages was not associated with a different risk of coronary death.
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There was no indication of effect modifications by sex (p>0.05), except for substitution of whole-fat milk for
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SSBs and coronary events (p-heterogeneity=0.02).
Results from the random-effects model were similar to the fixed-effects model (data not shown).
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similar results (data not shown).
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Sensitivity analyses excluding individuals developing CHD within the first two years of follow-up showed
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Discussion This study suggests that daily increase of SSB intake is associated with an increased risk of coronary events. These results are in accordance with recent evidence suggesting a direct association between SSB intake and CHD (6,8). In addition, this study reports several novel findings. Substitution analyses suggested that replacing SSBs with ASBs or coffee lowers the risk of developing CHD events. Although not statistically significant, substituting tea, total milk, or low-fat milk for SSBs might also have inverse associations with
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coronary events risk development
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Recent evidence suggests that tea and coffee consumption is associated with a reduced CVD risk (11,12).
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One previous study found that substituting SSBs with coffee was associated with a lower risk of stroke and a trend towards a reduced risk with substitution with tea (21). To our knowledge, no previous studies
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estimated the effect of substituting tea or coffee for SSBs and the subsequent CHD risk. Tea constituents
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might ameliorate endothelial function, lipid profile and have anti-inflammatory, antioxidant or antithrombotic properties(12). Regular coffee contains caffeine which may elevate blood pressure;
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however it has been shown that caffeine consumption in the form of coffee was less likely to be associated
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with hypertension than caffeine consumed as SSBs. Thus, non-caffeine components in coffee may have antagonist physiological effects to those of caffeine (34). This study is the first to show a lower incidence of CHD events associated with replacing SSBs by ASBs. These findings might be counter intuitive as some recent evidence suggests a positive association between ASB intake and adverse health outcomes (35). However, challenges related to assessing the association between ASB intake and diseases development from cross-sectional studies or cohorts with short duration, such as reverse causation and residual confounding, may account for some studies findings(35). In line with our results, substitution of ASBs for SSBs was associated with reduced risk of stroke among men and women; and weight losses of 2% to 2.5% in two recent studies (17,21). Thus, compared with SSB’s, ASBs may be a healthier option for the prevention of coronary events.
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A pooled analysis of 10 prospective studies suggested a beneficial effect of milk consumption in reducing the risk of coronary heart disease and ischemic stroke (36); however, one previous study did not find any association between substitution of low fat milk for SSBs and the risk of stroke (21). Hence, the present study is the first to show a possible beneficial effect of substituting SSBs by milk, especially low-fat milk. Milk intake has been shown to increase high density lipoprotein cholesterol level which has antiatherogenic properties and may also have antihypertensive properties due to its mineral content (calcium,
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potassium, phosphorus, magnesium) (10,37).
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Data about water intake were incomplete or missing in most of the included studies; therefore, substitution of water for SSBs was not assessed. The paucity of data on water intake can be explained by the lack of
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focus on collecting such information in past cohort studies(38).
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Strengths and limitations
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To our knowledge, no previous study has examined the long-term effects of replacing SSBs with other beverages on the risk of coronary events and deaths. Our results have good generalizability among Western
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middle-aged populations, but may not be extrapolated to other populations. By using the Harvard Pooling
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Project of Diet and Coronary Disease we had a large sample size and great statistical power for total CHD, but power for fatal CHD was much less. Publication bias did not affect our pooled analyses as individual study inclusion criteria were independent from publication status. Selection bias was also limited as dietary assessment was conducted, at baseline, prior to disease development(39). The availability of dietary intake at baseline only prevented us from investigating change in beverage intake across time or to reduce random measurement error through statistical analysis. Individuals who changed drinking patterns may have been misclassified with respect to exposure; therefore, follow-up was censored at 10 years. Furthermore, sensitivity analyses excluding individuals who developed CHD within the first two-years of follow-up were performed; and similar results were found.
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Average SSB intake was relatively low; therefore it is likely that the effect of substituting SSBs by other beverages would be particularly important among populations with a higher SSB consumption such as young adults, non-Hispanic black and Mexican-American adults, individuals with low socioeconomic statuses and recent cohorts of same age individuals(40). BMI might be considered to be more of a mediator than a confounder in the association between SSB intake and CHD development; therefore, by controlling for BMI the effect of SSB’s may have been
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underestimated. Indeed, BMI might influence the frequency and quantity of SSB intake and
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overweight/obese individuals may have changed their beverage intake pattern in an attempt to lose weight prior to baseline diet assessment.
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We adjusted for a number of known potential confounders; however, residual confounding can never be
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excluded and additional confounding from other CHD risk factors could potentially explain our findings.
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Conclusion
This study shows that SSB intake is associated with an increased risk of coronary events and possibly
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coronary death. Our findings also suggest that replacing SSBs with ASBs or coffee may lower the risk of developing CHD events.
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Acknowledgments We would like to thank Dr. Ascherio for his contribution in obtaining the data. The Authors thank the ARIC, NHS, HPFS, WHS, IWHS and ATBC study participants. The Atherosclerosis Risk in Communities study has been funded in whole or in part with Federal funds from the National Heart, Lung, and Blood Institute, National Institutes of Health, Department of Health
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and Human Services (contract numbers HHSN268201700001I, HHSN268201700002I, HHSN268201700003I, HHSN268201700004I and HHSN268201700005I). The authors thank the staff and
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participants of the ARIC study for their important contributions. Funding was also supported by
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R01HL59367.
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Funding
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This project was supported by the Danish Heart Foundation, Region Hovedstaden, Etly og Jørgen Stjerngrens Fond, the Swiss Foundation for Nutrition Research, Oticon fonden, Niehls Bohr fondet. The
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funders had no role in the study design; in the collection, analysis, and interpretation of data; in the writing
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of the report; and in the decision to submit the article for publication.
Authors contribution
Berit L. Heitmann, Ingelise Andersen and Amélie Keller designed the study and formulated the research question. Eilis O’Reilly and Amélie Keller performed the statistical analyses. Vasanti Malik and Eilis O´Reilly provided feedback on the study design. Amélie Keller wrote the manuscript. Eric Rimm and Walter Willet provided interpretation of data and critical revision of the manuscript for important intellectual content. The remaining investigators (Julie E. Buring, Lyn Steffen, Kim Robien and Satu Männistö) represent the offsite investigators of the individual cohort studies. All of these investigators provided feedback on the manuscript. Conflict of interest: None.
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Transparency declaration The lead author, Amélie Cléo Keller, affirms that the manuscript is an honest, accurate, and transparent account of the study being reported; that no important aspects of the study have been omitted; and that
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any discrepancies from the study as originally planned (and, if relevant, registered) have been explained.
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Table 1: Baseline characteristics of participants from included studies CHD cases Study and sex
SSB intake
Baseline cohort1
Year of FFQ
Mean age, y
Median Follow-up, person-y
Total CHD events
CHD deaths
Median (ml/d)
Nondrinkers %
Male
5,238
1987
54.6
269
52
127.3
21.0
Female2
6,481
9.2 45,860 9.2 58,199
41.4
36.5
Male
21,141
1985
57.3
6.0 121,813
534
47.1
32.1
Male
41,684
1986
53.4
9.7 382,573
420
52.1
33.9
Female
29,528
1986
61.4
291
29.8
42.4
Female
81,412
1980
Female
61,700
Female
37,161
ARIC
53.9
123
ro
1339
1272
-p
HPFS
WHS
6.5 513,930
397
97
26.0
38.7
1986
52.6
10.0 606,997
696
208
29.6
47.1
1993
53.9
5.3 190,198 8.2 2,207,823
152
10
29.8
43.8
4248
1630
47.9
37
na
284,345 (23.9)
10.0 288,253
46.9
Jo ur
NHS4 1986
lP
NHS4 1980
re
IWHS3
All Studies5
of
ATBC
54.3
1
Sample size after exclusion of participants with baseline cardiovascular diseases, diabetes mellitus, cancer, very high or very low
caloric intake and missing information on SSB intake. Events censored at 10 years follow-up. 2
Insufficient events of coronary death for analysis among women
3
IWHS only had self-reported data on CHD events, therefore only CHD deaths were used
4
Number of participants only counted once
5
Percentage of males in parentheses
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Table 2: Combined hazard ratio (HR) for coronary events for one serving daily increase of SSB intake All
Women 2
Men 2
HR (95%CI)
I test for betweenstudies heterogeneity (p-value)
N
HR (95%CI)
I test for betweenstudies heterogeneity (p-value)
N
HR (95%CI)
Crude Model
1.16 (1.11,1.22)
0.0% (0.70)
284,289
1.18 (1.10,1.27)
0.0% (0.90)
216,226
Model 1
1.08 (1.03, 1.14) 1.09 (1.04, 1.15) 1.08 (1.02, 1.14) 1.08 (1.02,1.13)
0.0% (0.46) 0.0% (0.74) 0.0% (0.61) 0.0% (0.67)
284,289
1.06 (0.98, 1.15) 1.08 (1.00, 1.17) 1.06 (0.97, 1.15) 1.06 (0.97,1.15)
24.4% (0.27) 0.0% (0.41) 0.0% (0.41) 0.0% (0.40)
216,226
Model 2 Model 3 Model 4
284,289 280,886 274,754
P l a
re
213,759 143,184
N
P-value, test for effect modification by sex
1.15 (1.08,1.23)
33.8% (0.22)
68,063
0.63
1.10 (1.02, 1.18) 1.10 (1.03, 1.18) 1.10 (1.02, 1.17) 1.09 (1.02,1.17)
0.0% (0.52) 0.0% (0.80) 0.0% (0.55) 0.0% (0.65)
68,063
0.53
68,063
0.68
67,127
0.51
131,570
0.61
f o
ro
-p
216,226
2
I test for betweenstudies heterogeneity (p-value)
n r u
Age at baseline (y) and the calendar year in which the baseline questionnaire was returned were entered into the model through the strata statement. Within each study, HRs with 95% CIs for the incidence of a coronary events was calculated by using Cox proportional hazards regression with time in study (y) as the time metric. The study-specific logs of HRs were
o J
weighted by the inverse of their variances, and a combined estimate of the HRs was computed by using a fixed-effects model. A crude model included only SSB and the stratification variables (smoking, physical activity, education and alcohol); model 1 considered confounding by diet and included quintiles of cereal fibers; quintiles of trans-fat; quintiles of polyunsaturated fat/saturated fat ratio; model 2 further included total energy; model 3 further included BMI; model 4 then included intermediate variables: baseline hypertension and high cholesterol. One serving = 355ml.
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Table 3: Combined hazard ratio (HR) for coronary events by substitution of one serving sugar-sweetened beverages (SSB) with one serving of coffee, tea, milk, fruit juice or artificially-sweetened beverages (ASB) All HR (95%CI)
Caffeinated coffee for SSB
Crude model Model 1 Model 2 Model 3 Model 4
Total Coffee for SSB
Crude model Model 1 Model 2 Model 3 Model 4
Women 2
I test for betweenstudies heterogeneity (p-value)
N
0.91 (0.86, 0.97) 0.90 (0.84, 0.96) 0.98 (0.91, 1.04) 0.92 (0.86, 0.99) 0.94 (0.87, 1.00)
0.0% (0.46) 7.3% (0.37) 63.6% (0.02) 0.0% (0.42) 16.2% (0.31)
284,345
0.92 (0.86, 0.98) 0.97 (0.91, 1.04) 0.94 (0.87, 1.00) 0.93 (0.87, 1.00) 0.95 (0.88, 1.01)
10.9% (0.34) 36.5% (0.19) 6.3% (0.36) 10.1% (0.34) 13.1% (0.33)
2
HR (95%CI)
284,345 284,345
274,754
n r u
272,626 272,626 272,626 269,173 212,864
I test for betweenstudies heterogeneity (p-value)
N
HR (95%CI)
0.0% (0.92) 5.2% (0.37) 17.2% (0.31) 0.0% (0.56) 0.0% (0.52)
216,282
re
0.93 0.82, 1.06) 1.00 (0.87, 1.14) 1.01 (0.88, 1.16) 0.91 (0.84, 0.98) 1.02 (0.89, 1.17)
0.0% (0.59) 0.0% (0.63) 30.9% (0.23) 25.0% (0.25) 26.4% (0.24)
209,801
-p
216,282 216,282 213,759 143,184
209,801 209,801 207,283 102,422
2
I test for betweenstudies heterogeneity (p-value)
N
P-value, 2 I test for between -groups heterogeneity
0.88 0.81, 0.96) 0.89 (0.81, 0.97) 0.89 (0.81, 0.98) 0.90 (0.81, 1.01) 0.91 (0.83, 1.00)
62.8% (0.10) 52.4% (0.15) 66.5% (0.08) 61.5% (0.12) 66.3% (0.09)
68,063
0.22
68,063
0.72
68,063
0.01
67,127
0.57
131,570
0.38
0.91 (0.85, 0.98) 0.96 (0.889, 1.040) 0.91 (0.84, 0.99) 1.00 (0.87, 1.15) 0.92 (0.851, 1.00)
66.4% (0.09) 76.6% (0.04) 0.0% (0.56) 0.0% (0.44) 0.0% (0.42)
62,825
0.75
62,825
0.64
62,825
0.24
61,890
0.24
110,442
0.23
f o
ro
0.95 (0.87, 1.03) 0.91 (0.83, 0.99) 1.07 (0.97, 1.17) 0.94 (0.86, 1.03) 0.96 (0.88, 1.06)
P l a
280,886
o J
Men
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Table 3: (continued) All HR (95%CI)
Tea for SSB
N
Women HR (95%CI)
2
I test for betweenstudies heterogeneity (p-value)
Men HR (95%CI)
N
f o
o r p
Crude model
0.87 (0.81, 0.94)
0.0% (0.60)
283,862
0.84 (0.75, 0.93)
7.7% (0.35)
Model 1
0.97 (0.89, 1.05) 0.94 (0.87, 1.01) 0.94 (0.87, 1.01) 0.95 (0.88, 1.02)
0.0% (0.87) 0.0% (0.54) 0.0% (0.72) 0.0% (0.69)
283,862
1.06 (0.91, 1.22) 0.94 (0.84, 1.05) 0.95 (0.84, 1.06) 0.95 (0.84, 1.06)
e
0.88 (0.82, 0.94) 1.01 (0.95, 1.09) 0.97 (0.91, 1.04) 0.96 (0.90, 1.03)
31.9% (0.19) 0.0% (0.69) 0.0% (0.69) 0.0% (0.76)
284,344
0.0% (0.75) 0.0% (0.66) 0.0% (0.61) 0.0% (0.68)
216,282
o J
0.79 (0.70, 0.89) 0.96 (0.85, 1.09) 0.97 (0.86, 1.10) 0.97 (0.85, 1.09)
0.96 (0.90, 1.03)
0.0% (0.78)
274,754
0.96 (0.84, 1.08)
0.0% (0.62)
143,184
Model 2 Model 3 Model 4
Low fat milk for SSB
2
I test for betweenstudies heterogeneity (p-value)
Crude model Model 1 Model 2 Model 3
Model 4
283,862 280,403
l a
273,788
n r u
284,344 284,344 280,885
r P
0.0% (0.95) 35.1% (0.20) 7.8% (0.35) 17.0% (0.31)
2
2
I test for betweenstudies heterogeneity (p-value)
N
P-value, I test for betweengroups heterogeneity
215,799
0.90 (0.82, 0.99)
0.0% (0.80)
68,063
0.36
215,799
0.93 (0.85, 1.03) 0.94 (0.85, 1.03) 0.94 (0.85, 1.03) 0.94 (0.86, 1.04)
0.0% (0.93) 0.0% (0.81) 0.0% (0.81) 0.0% (0.86)
68,063
0.16
68,063
0.95
67,127
0.88
131,570
0.98
0.92 0.85, 1.00) 1.04 (0.95,1.13) 0.97 (0.90,1.06) 0.96 (0.89,1.05)
33.7% (0.22) 0.0% (0.50) 1.9% (0.36) 0.0% (0.40)
68,062
0.03
68,062
0.33
68,062
0.98
67,126
0.98
0.97 (0.88,1.05)
0.0% (0.49)
131,570
0.89
215,799 213,276 142,218
216,282 216,282 213,759
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Table 3: (continued) All HR (95%CI)
Whole fat milk for SSB
Crude model Model 1 Model 2 Model 3 Model 4
Total milk for SSB
Crude model Model 1 Model 2 Model 3 Model 4
2
Women HR (95%CI)
I test for betweenstudies heterogeneity (p-value)
N
1.03 (0.95, 1.12) 1.05 (0.96, 1.15) 0.94 (0.86, 1.02) 0.95 (0.87, 1.04) 0.97 (0.88, 1.06)
62.2% (0.01) 49.0% (0.07) 42.6% (0.11) 46.2% (0.08) 39.9% (0.13)
284,345
0.93 (0.87, 0.99) 0.97 (0.90, 1.03) 0.97 (0.90, 1.03) 0.96 (0.90, 1.03) 0.97 (0.90, 1.03)
10.2% (0.35) 0.0% (0.46) 0.0% (0.45) 0.0% (0.50) 0.0% (0.65)
284,345 284,345 280,886
J
u o
rn
284,344 284,344 284,344 280,885 274,754
Men HR (95%CI)
N
0.0% (0.87) 0.0% (0.83) 0.0% (0.81) 0.0% (0.84) 0.0% (0.93)
e
o r p
0.91 (0.81, 1.01) 1.00 (0.89, 1.13) 1.000 (0.89, 1.12) 1.01 (0.90, 1.13) 1.01 (0.89, 1.13)
0.0% (0.79) 0.0% (0.83) 0.0% (0.80) 0.0% (0.90) 0.0% (0.88)
216,282
r P
216,282 216,282 216,282 213,759 143,184
216,282 216,282 213,759 143,184
2
I test for betweenstudies heterogeneity (p-value)
N
P-value, I test for betweengroups heterogeneity
0.94 (0.85,1.04) 1.03 (0.93,1.15) 0.88 (0.79,0.98) 0.89 (0.80,1.00) 0.90 (0.81,1.00)
59.4% (0.09) 80.7% (0.01) 59.1% (0.09) 57.7% (0.09) 41.6% (0.18)
68,063
0.001
68,063
0.48
68,063
0.03
67,127
0.02
131,570
0.01
0.94 (0.87,1.02) 0.95 (0.87,1.03) 0.95 (0.87,1.03) 0.94 (0.87,1.02) 0.95 (0.87,1.03)
62.9% (0.07) 52.4% (0.12) 52.5% (0.12) 49.6% (0.14) 31.5% (0.23)
68,062
0.62
68,062
0.44
68,062
0.46
67,126
0.36
131,570
0.42
f o
1.28 (1.09, 1.49) 1.11 (0.94, 1.31) 1.10 (0.93, 1.29) 1.13 (0.96, 1.34) 1.16 (0.98, 1.37)
l a
274,754
2
I test for betweenstudies heterogeneity (p-value)
2
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Table 3: (continued) All HR (95%CI)
Fruit juice for SSB
Crude model Model 1 Model 2 Model 3 Model 4
ASB for SSB
0.79 (0.71, 0.89) 0.96 (0.86, 1.08) 0.98 (0.88, 1.10) 0.97 (0.85, 1.07) 1.11 (1.11, 1.11)
2
Women HR (95%CI)
I test for betweenstudies heterogeneity (p-value)
N
0.0% (0.51) 3.0% (0.31) 27.6% (0.22) 0.0% (0.44) 58.6% (0.03)
284,277 284,277 284,277 280,818
l a
274,620
n r u
Crude model
0.79 (0.66, 0.95) 1.03 (0.87, 1.23) 1.08 (0.91, 1.28) 1.02 (0.85, 1.22) 0.97 (0.81, 1.16)
2
I test for betweenstudies heterogeneity (p-value) 0.0% (0.57) 0.0% (0.53) 15.1% (0.32) 0.0% (0.58) 0.0% (0.51)
f o
o r p
e
r P
Men HR (95%CI)
N
216,215 216,215 216,215 213,692 143,050
0.79 (0.69, .92) 0.92 (0.79,1.06) 0.92 (0.79, .06) 0.91 (0.79,1.06) 1.11 (1.11, .11)
2
I test for betweenstudies heterogeneity (p-value)
N
P-value, I test for betweengroups heterogeneity
39.2% (0.19) 32.4% (0.23) 27.4% (0.25) 34.0% (0.22) 80.0% (0.01)
68,062
0.98
68,062
0.31
68,062
0.16
67,126
0.35
131,570
0.14
0.84 0.0% 284,289 0.836 0.0% 216,226 0.84 0.0% 68,063 0.97 (0.78, 0.90) (0.73) (0.76, 0.93) (0.43) (0.75, 0.93) (0.79) Model 1 0.92 0.0% 284,289 0.94 27.6% 216,226 0.90 0.0% 68,063 0.61 (0.85, 0.99) (0.48) (0.84, 1.04) (0.25) (0.81, 1.01) (0.74) Model 2 0.94 19.7% 284,289 0.96 43.1% 216,226 0.91 0.0% 68,063 0.48 (0.86, 1.01) (0.29) (0.86, 1.07) (0.15) (0.81, 1.02) (0.51) Model 3 0.89 27.7% 280,830 0.91 49.4% 213,703 0.87 0.0% 67,127 0.60 (0.83, 0.97) (0.23) (0.82, 1.02) (0.12) (0.78, 0.98) (0.40) Model 4 0.88 26.8% 305,480 0.90 50.4% 173,910 0.87 0.0% 131,570 0.63 (0.82, 0.96) (0.23) (0.81, 1.01) (0.11) (0.77, 0.97) (0.46) Age at baseline (y) and the calendar year in which the baseline questionnaire was returned were entered into the model through the strata statement. Within each study, HRs with 95% CIs for the incidence of a coronary events was calculated by using Cox proportional hazards regression with time in study (y) as the time metric. The study-specific logs of HRs were weighted by the inverse of their variances, and a combined estimate of the HRs was computed by using a fixed-effects model. A crude model included only SSB and the stratification variables (smoking, physical activity, education and alcohol); model 1 further included confounding by diet and included quintiles of cereal fibers; quintiles of trans-fat; quintiles of poly-unsaturated fat/saturated fat ratio; model 2 further included total energy; model 3 further included BMI; model 4 further included baseline hypertension and high cholesterol. One serving = 355ml
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2
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Figure 1: Association between one serving daily increase of SSBs (355ml) and the risk of developing coronary events
of
Age at baseline (y) and the calendar year in which the baseline questionnaire was returned were entered into the model through the strata statement (Model 3). Within each study, HRs with 95% CIs for the incidence of a coronary event was calculated by using Cox proportional hazards regression with time in study (y) as the time metric. The studyspecific logs of HRs were weighted by the inverse of their variances, and a combined estimate of the HRs was computed by using a fixed-effects model. Analyses were stratified by sex and adjusted for smoking, physical activity, alcohol intake, education, alcohol, diet (quintiles of cereal fiber; quintiles of trans-fat; quintiles of poly-unsaturated fat/saturated fat ratio), energy and BMI. The diamonds represent the combined hazard ratios and 95% CI. ARIC, Atherosclerosis Risk in Communities Study; ATBC, Alpha-Tocopherol and Beta-Carotene Cancer Prevention Study; HPFS, Health Professionals Follow-Up Study; IWHS, Iowa Women’s Health Study; NHS80, Nurses’ Health Study 1980; NHS86, Nurses’ Health Study 1986; WHS, Women’s Health Study
ro
Figure 2: Hazard ratio (HR) for all coronary events by substitution of one serving sugar-sweetened beverages (SSB) with one serving of coffee
-p
Age at baseline (y) and the calendar year in which the baseline questionnaire was returned were entered into the model through the strata statement (Model 3). Within each study, HRs with 95% CIs for the incidence of a coronary events was calculated by using
re
Cox proportional hazards regression with time in study (y) as the time metric. The study-specific logs of HRs were weighted by the
lP
inverse of their variances, and a combined estimate of the HRs was computed by using a fixed-effects model. Analyses were
stratified by sex and adjusted for smoking, physical activity, alcohol intake, education, alcohol, diet (quintiles of cereal
na
fiber; quintiles of trans-fat; quintiles of poly-unsaturated fat/saturated fat ratio), energy and BMI. The diamonds represent the combined hazard ratios and 95% CI. ARIC, Atherosclerosis Risk in Communities Study; ATBC, Alpha-
Jo ur
Tocopherol and Beta-Carotene Cancer Prevention Study; HPFS, Health Professionals Follow-Up Study; IWHS, Iowa Women’s Health Study; NHS80, Nurses’ Health Study 1980; NHS86, Nurses’ Health Study 1986; WHS, Women’s Health Study. One serving = 355ml
Figure 3: Hazard ratio (HR) for all coronary events by substitution of one serving sugar-sweetened beverages (SSB) with one serving of artificially-sweetened beverages Age at baseline (y) and the calendar year in which the baseline questionnaire was returned were entered into the model through the strata statement (Model 3). Within each study, HRs with 95% CIs for the incidence of a coronary events was calculated by using Cox proportional hazards regression with time in study (y) as the time metric. The study-specific logs of HRs were weighted by the inverse of their variances, and a combined estimate of the HRs was computed by using a fixed-effects model. Analyses were
stratified by sex and adjusted for smoking, physical activity, alcohol intake, education, alcohol, diet (quintiles of cereal fiber; quintiles of trans-fat; quintiles of poly-unsaturated fat/saturated fat ratio), energy and BMI. The diamonds represent the combined hazard ratios and 95% CI. ARIC, Atherosclerosis Risk in Communities Study; ATBC, Alpha-
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26
Tocopherol and Beta-Carotene Cancer Prevention Study; HPFS, Health Professionals Follow-Up Study; IWHS, Iowa Women’s Health Study; NHS80, Nurses’ Health Study 1980; NHS86, Nurses’ Health Study 1986; WHS, Women’s Health Study. One serving = 355ml
Highlights Pooled analysis of four large cohort studies and two intervention studies
Higher consumption of sugar-sweetened (SSB) beverages is associated with greater risk of coronary
of
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events
Replacing SSB by artificially-sweetened beverage decreases the risk of developing coronary events
Replacing SSB by coffee decreases the risk of developing coronary events
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Figure 1
Figure 2
Figure 3