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      Hepatic fat fraction and visceral adipose tissue fatty acid composition in mice: Quantification with 7.0T MRI : Quantification of Fat and Fatty Acid Composition in Mice with 7.0T MRI

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          The Preventable Causes of Death in the United States: Comparative Risk Assessment of Dietary, Lifestyle, and Metabolic Risk Factors

          Introduction Valid and comparable information on mortality caused by diseases, injuries, and their modifiable risk factors is important for health policy and priority setting [1],[2]. The standard death certificate is valuable for assigning deaths to specific diseases or injuries, but does not provide information on the modifiable risk factors that cause these diseases. Previous research has indicated that modifiable risk factors are responsible for a large number of premature deaths in the United States [1],[3]. However, prior analyses did not use consistent and comparable methods for the mortality effects of different risk factors. More importantly, previous analyses did not include any dietary risk factors. The only metabolic risk factor—i.e., those measured by physiological indicators such as blood pressure, blood glucose, serum cholesterol, and body mass index (BMI)—in these analyses was overweight–obesity. We estimated the number of deaths attributable to major dietary, lifestyle, and metabolic risk factors in the US using consistent, comparable, and current definitions, methods, and data sources. We conducted the analysis in the US because the results can inform priority-setting decisions for policies and programs that aim to improve the nation's health, e.g., Healthy People 2010 and (the forthcoming) Healthy People 2020. The US also has high-quality data on disease-specific mortality and on population exposure to a range of risk factors from nationally representative health examination and interview surveys. Our results provide, to our knowledge, the most comprehensive and comparable quantitative assessment of the mortality burden of important modifiable risk factors in the US population, and the only one to include the effects of multiple dietary and metabolic factors. Methods We conducted a population-level CRA (comparative risk assessment) for 12 major modifiable dietary, lifestyle, and metabolic risks. The CRA analysis estimates the number of deaths that would be prevented in the period of analysis if current distributions of risk factor exposure were changed to a hypothetical alternative distribution. The inputs to the analysis are (1) the current population distribution of risk factor exposure, (2) the etiological effect of risk factor exposures on disease-specific mortality, (3) an alternative exposure distribution, and (4) the total number of disease-specific deaths in the population. 10.1371/journal.pmed.1000058.t001 Table 1 Risk factors in this analysis, their exposure variables, theoretical-minimum-risk exposure distributions, disease outcomes, and data sources for exposure. Risk Factor Exposure Metric Exposure Data Sources TMRED±SD Disease Outcomesa High blood glucose Usual level of fasting plasma glucose [61] NHANES 2003–2006 (SD corrected for intra-individual variation) 4.9±0.3 mmol/l [61] IHD; stroke; renal failure; colorectal, breast, and pancreatic cancers High LDL cholesterol b Usual level of LDL cholesterol NHANES 2003–2006 (SD corrected for intra-individual variation) 2.0±0.44 mmol/lc [62] IHD; ischemic stroke; selected other cardiovascular diseases High blood pressure Usual level of systolic blood pressure NHANES 2003–2006 (SD corrected for intra-individual variation) 115±6 mmHg [63], [64] IHD, stroke, hypertensivedisease, other cardiovascular diseasesd, renal failure Overweight–obesity (high BMI) BMI NHANES 2003–2006 21±1 kg/m2 [21], [65] IHD; ischemic stroke; hypertensive disease; diabetes mellitus; corpus uteri, colon, kidney, and postmenopausal breast cancers; gallbladder cancer e High dietary trans fatty acids Usual percent of total calories from dietary trans fatty acids CSFII 1989–1991f 0.5%±0.05% of total calories from trans fatty acids [16] IHD Low dietary poly-unsaturated fatty acids (PUFA) (in replacement of saturated fatty acids; see Table 2 ) Usual percent of total calories from dietary PUFA NHANES 2003–2006 10%±1% of total calories from PUFA IHD, stroke Low dietary omega-3 fatty acids (seafood) Usual dietary omega-3 fatty acids in five categories adjusted for total caloriesg NHANES 2003–2006 250 mg/d [31] IHD, stroke High dietary salt (sodium) h Usual level of dietary sodium adjusted for total calories NHANES 2003–2006 0.5±0.05 g/d [66] IHD, stroke, hypertensivedisease, other cardiovascular diseases, stomach cancer, renal failure Low intake of fruits and vegetables Usual dietary fruit and vegetable intake adjusted for total caloriesi NHANES 2003–2006 600±50 g/d [67] IHD; ischemic stroke; colorectal, stomach, lung, esophagus, mouth, and pharyngeal cancers Alcohol use Current alcohol consumption volumes and patternsj; prevalence of alcohol use among emergency room patients; BAC levels of drivers in road traffic injuries NESARC 2001–2002, FARS 2005 and emergency room studies No alcohol usek IHD; ischemic stroke; hemorrhagic stroke; hypertensive disease; cardiac arrhythmias; diabetes mellitus; liver, mouth, and pharynx, larynx, breast, esophagus, colorectal, selected other cancersl; liver cirrhosis; acute and chronic pancreatitis; road traffic injuries; falls; homicide and suicide; other injuries; alcohol use disordersm; selected other cardiovascular diseases; hepatitis C; epilepsy; fetal effects of alcohol use during pregnancy; tuberculosis Physical inactivity Physical activity measured in four categories: inactive, low-active, moderately active, and highly activen NHANES 2003–2006 The whole population being highly active (≥1 h/wk of vigorous activity and at least 1,600 met·min/wk)o IHD; ischemic stroke; breast cancer and colon cancers; diabetes mellitus Tobacco smoking Current levels of Smoking Impact Ratio (SIR) (indirect indicator of accumulated smoking risk based on excess lung cancer mortality) [18] p Lung cancer mortality from adjusted vital registration in 2004 No smoking IHD; stroke; selected other cardiovascular diseases; diabetes mellitus; lung, esophagus, mouth and pharynx, stomach, liver, pancreas, cervix, bladder, kidney and other urinary cancers; leukemia; chronic obstructive pulmonary disease (COPD); other respiratory diseasesq tuberculosis; colorectal cancer and hypertensive disease r, burns and fire injuries, effects of smoking during pregnancy on maternal and perinatal conditions a Outcomes in italics are those for which the effects were not quantified in the main analysis due to weaker evidence on causality (e.g. tobacco smoking and colorectal cancer or high blood glucose and cancers) or because there were very few deaths from the disease (e.g. high BMI and gallbladder cancer). b We evaluated sensitivity to the choice of exposure metric by using total cholesterol instead of LDL-cholesterol (Table S1). c Two alternative TMREDs for LDL cholesterol with means of 1.6 mmol/l and 2.3 mmol/l were examined in sensitivity analysis (Table S1). d This category includes rheumatic heart disease, acute and subacute endocarditis, cardiomyopathy, other inflammatory cardiac diseases, valvular disorders, aortic aneurysm, pulmonary embolism, conduction disorders, peripheral vascular disorders, and other ill-defined cardiovascular diseases. e We did not include some of the cancers that were found to have significant association with BMI in a recent meta-analysis [17] either because there were very few deaths in the US (adenocarcinoma of esophagus and gallbladder cancer) or because there was not strong evidence on a causal effect from other studies (leukemia and multiple myeloma). We included non-Hodgkin lymphoma in a sensitivity analysis (Table S1). f The NHANES rounds in 2003–2006 include a 2-d dietary intake survey and could be used to estimate dietary trans fatty acids. However, a reliable source for the trans fat content of each food item was not available to us. We have used the intake estimates in the Continuing Survey of Food Intakes by Individuals (CSFII) 1989–1991 [68] in our analysis. g Omega-3 intake categories in the analysis were: 0 to 40 g (females) and >60 g (males). Binge drinking was defined as having at least one occasion of five or more drinks in the last month. k An alternative TMRED for alcohol use as regular drinking of small amounts of alcohol is considered in sensitivity analysis (Table S1). l This category includes ICD-9 codes 210–239. m This category includes ICD-9 codes 291, 303, and 305.0. n Categories of physical activity were defined as below using responses to questions regarding physical activity during the past 30 d: inactive, no moderate or vigorous physical activity; low-active, 40 g (females) and >60 g (males). Binge drinking was defined as having at least one occasion of five or more drinks in the last month. For IHD, the categories refer to non-binge drinkers. b For these risk factor–disease pairs, RRs in the source were reported for all ages combined. We used median age at event and the age pattern of excess risk from smoking and the same disease to estimate RRs for each age category. c This category includes ICD-9 codes 210–239. d These odds ratios were used to estimate PAF as described in the Methods section. e Used to estimated PAF for having drunk alcohol in the last 6 h before injury. 10.1371/journal.pmed.1000058.t005 Table 5 Sources and magnitudes of relative risks for the effects of physical inactivity on disease-specific mortality. Disease Outcome Source of RR Age Group Highly Active Recommended Level Active Insufficiently Active Inactive IHD Meta-analysis of 20 prospective cohort studies [87] a 30–69 1.00 1.15 1.66 1.97 70–79 1.00 1.15 1.51 1.73 80+ 1.00 1.15 1.38 1.50 Ischemic stroke Meta-analysis of 8 prospective cohort studies [87] a 30–69 1.00 1.12 1.23 1.72 70–79 1.00 1.12 1.21 1.55 80+ 1.00 1.12 1.18 1.39 Breast cancer Meta-analysis of 12 prospective cohort and 31 case-control studies [87] a 30–44 1.00 1.25 1.41 1.56 45–69 1.00 1.25 1.41 1.67 70–79 1.00 1.25 1.36 1.56 80+ 1.00 1.25 1.32 1.45 Colon cancer Meta-analysis of 11 prospective cohort and 19 case-control studies [87] a 30–69 1.00 1.07 1.27 1.80 70–79 1.00 1.07 1.21 1.59 80+ 1.00 1.07 1.16 1.39 Diabetes Meta-analysis of 13 prospective cohort and 9 case-control studies [87] a 30–69 1.00 1.21 1.50 1.76 70–79 1.00 1.21 1.43 1.60 80+ 1.00 1.21 1.34 1.45 Categories of physical activity were defined as below using responses to questions regarding physical activity during the past 30 d: inactive, no moderate or vigorous physical activity; low-active, <2.5 h/wk of moderate activity or <600 met·min/wk; moderately active: either ≥2.5 h/wk of moderate activity or ≥1 h of vigorous activity and ≥600 met·min/wk; highly active: ≥1 h/wk of vigorous activity and ≥1,600 met·min/wk. a The meta-analysis of RRs for physical inactivity used three categories: inactive, insufficiently active, and recommended-level active. For this analysis, we re-scaled the RRs to set the highly active group as the reference category. The ratio of excess risk from recommended-level active to high-active was from Manson et al. for IHD [69], Hu et al. for ischemic stroke [70], Patel et al. 2003 for breast cancer [71], and Chao et al. for colon cancer [72]. 10.1371/journal.pmed.1000058.t006 Table 6 Sources and magnitudes of relative risks for the effects of tobacco smoking on disease-specific mortality. Disease Outcome Source of RR Age Group Sex RR IHD American Cancer Society Cancer Preventions Study, Phase II (ACS CPS-II) [88] a 30–44 M 5.51 F 2.26 45–59 M 3.04 F 3.78 60–69 M 1.88 F 2.53 70–79 M 1.44 F 1.68 80+ M 1.05 F 1.38 Stroke ACS CPS-II [88] a 30–44 M 3.12 F 4.61 45–59 M 3.12 F 4.61 60–69 M 1.88 F 2.81 70–79 M 1.39 F 1.95 80+ M 1.05 F 1.00 Hypertensive disease (sensitivity analysis) b ACS CPS-II [88] a 30–44 M 5.93 F 2.38 45–59 M 3.23 F 4.05 60–69 M 1.96 F 2.67 70–79 M 1.48 F 1.74 80+ M 1.06 F 1.42 Selected other cardiovascular diseases b ACS CPS-II [88] a 30–44 M 6.91 F 2.65 45–59 M 3.68 F 4.65 60–69 M 2.15 F 3.00 70–79 M 1.58 F 1.89 80+ M 1.07 F 1.50 Diabetes mellitus Meta-analysis of 25 prospective cohort studies with 1.2 million participants [89] a — — 1.44 Lung cancer ACS CPS-II [90] a — M 21.3 F 12.5 Mouth, pharynx, and esophagus cancer ACS CPS-II [90] a — M 8.1 F 6.0 Stomach cancer ACS CPS-II [90] a — M 2.16 F 1.49 Liver cancer ACS CPS-II [90] a — M 2.33 F 1.50 Pancreas cancer ACS CPS-II [90] a — — 2.20 Cervix uteri cancer ACS CPS-II [90] a — F 1.50 Bladder cancer ACS CPS-II [90] a — M 3.00 F 2.40 Leukemia ACS CPS-II [90] a — M 1.89 F 1.23 Colorectal cancer (sensitivity analysis) ACS CPS-II [90], [91] a — M 1.32 F 1.41 Kidney and other urinary cancer ACS CPS-II [90] a — M 2.5 F 1.5 Chronic obstructive pulmonary disease ACS CPS-II [92] a — M 10.8 F 12.3 Other respiratory diseases c ACS CPS-II [92] a — M 1.90 F 2.20 Tuberculosis Meta-analysis of cohort, case-control, and cross-sectional studies [93] — — 1.62 a We used ACS CPS-II as the source of RRs because the Smoking Impact Ratio (SIR), which was used as the exposure metric for tobacco smoking in the main analysis, is calculated using ACS CPS-II cohort and because the study provided separate RRs for different cancers and cardiovascular diseases by age. The CPS-II RRs were also adjusted for multiple potential confounders. b For these disease outcomes, RRs in the source were reported for all ages combined. We used median age at event and the age pattern of excess risk from IHD to estimate RRs for each age category. c This category includes lower respiratory tract infections and asthma. 10.1371/journal.pmed.1000058.t007 Table 7 Sources and magnitudes of relative risks for the effects of metabolic risk factors on disease-specific mortality. Risk Factor Disease Outcome Source of RR Units Age Group Sex RR High blood glucose IHD Meta-analysis of 19 prospective cohort studies with 237,000 participants [7] a Per mmol/l increase 30–59 — 1.42 60–69 — 1.20 70+ — 1.20 Stroke Meta-analysis of 19 prospective cohort studies with 237,000 participants [7] a Per mmol/l increase 30–59 — 1.36 60–69 — 1.28 70+ — 1.08 Renal failure Randomized trial of 3,900 participants [94] Per mmol/l increase — 1.26 High LDL cholesterol IHD Meta-analysis of ten prospective cohort studies [12] Per mmol/l increase 30–44 — 2.94 45–59 — 2.10 60–69 — 1.59 70–79 — 1.27 80+ — 1.01 Ischemic stroke b Meta-analysis of nine prospective cohort studies [12] Per mmol/l increase 30–44 — 1.30 45–59 — 1.30 60–69 — 1.18 70–79 — 1.00c 80+ — 1.00c High total cholesterol (sensitivity analysis) IHD PSC meta-analysis of 61 prospective cohort studies with 900,000 European and North American participants [95] Per mmol/l increase 30–44 — 2.11 45–59 — 1.81 60–69 — 1.39 70–79 — 1.22 80+ — 1.18 Ischemic stroke PSC [95] Per mmol/l increase 30–44 — 1.51 45–59 — 1.37 60–69 — 1.12 70–79 — 1.00c 80+ — 1.00c High blood pressure IHD PSC [11] Per 20 mmHg increase 30–44 — 2.04 45–59 — 2.01 60–69 — 1.85 70–79 — 1.67 80+ — 1.49 Stroke PSC [11] Per 20 mmHg increase 30–44 — 2.55 45–59 — 2.74 60–69 — 2.33 70–79 — 2.00 80+ — 1.49 Hypertensive diseaseb PSC [11] Per 20 mmHg increase 30–44 — 4.78 45–59 — 5.02 60–69 — 4.55 70–79 — 4.10 80+ — 3.50 Other cardiovascular diseasesd PSC [11] Per 20 mmHg increase 30–44 — 2.52 45–59 — 2.11 60–69 — 1.89 70–79 — 1.56 80+ — 1.43 Overweight–obesity (high BMI) IHD APCSC meta-analysis of 33 prospective cohorts with 310,000 participants [65] e,f Per kg/m2 increase 30–44 — 1.14 45–59 — 1.09 60–69 — 1.08 70–79 — 1.05 80+ — 1.02 Ischemic stroke APCSC [65] Per kg/m2 increase 30–44 — 1.14 45–59 — 1.10 60–69 — 1.08 70–79 — 1.05 80+ — 1.03 Hypertensive disease APCSC [65] Per kg/m2 increase 30–44 — 1.22 45–59 — 1.18 60–69 — 1.14 70–79 — 1.11 80+ — 1.08 Postmenopausal breast cancer Meta-analysis of 31 prospective cohort studies [17] Per kg/m2 increase 45+ F 1.02 Colon cancer Meta-analysis of 22 prospective cohort studies in males and 19 in females [17] Per kg/m2 increase — M 1.04 F 1.02 Corpus uteri cancer Meta-analysis of 19 prospective cohort studies [17] Per kg/m2 increase — F 1.10 Kidney cancer Meta-analysis of 11 prospective cohort studies in males and 12 in females [17] Per kg/m2 increase — 1.05 Pancreatic cancer Meta-analysis of 12 prospective cohort studies in males and 11 in females [17] Per kg/m2 increase — M 1.01 F 1.02 Non-Hodgkin lymphoma (sensitivity analysis) Meta-analysis of six prospective cohort studies in males and seven in females [17] Per kg/m2 increase — — 1.01 Diabetes mellitus APCSC meta-analysis prospective cohort studies with 150,000 participants [96] Per kg/m2 increase 30–59 — 1.20 60–69 — 1.16 70+ — 1.11 a See Danaei et al. [61] for sensitivity to using RRs from systematic reviews of other epidemiological studies. b For these risk factor–disease pairs, RRs in the source were reported for all ages combined. We used median age at event and the age pattern of excess risk from another risk factor and the same disease (e.g., age pattern of total serum cholesterol and ischemic stroke was applied to LDL and ischemic stroke) or from the same risk factor and another disease (e.g., age pattern of excess risk for SBP and all cardiovascular diseases was applied to SBP and hypertensive disease) to estimate RRs for each age category. c We used a null association in those 70-y-old and older because RRs in two large meta-analyses of prospective studies [95], [97] were not statistically significant from null, and did not show consistent benefits for lower total cholesterol in these ages. There is some evidence from clinical trials that statins reduce the risk of stroke in older ages [98]. However, statins may reduce stroke mortality through other, non-cholesterol mechanisms such as stabilization of atherosclerotic plaques [99]. In the sensitivity analysis for high LDL cholesterol and ischemic stroke, we used an RR of 1.12 in these age groups. d This category includes rheumatic heart disease, acute and subacute endocarditis, cardiomyopathy, other inflammatory cardiac diseases, valvular disorders, aortic aneurysm, pulmonary embolism, conduction disorders, peripheral vascular disorders, and other ill-defined cardiovascular diseases. e We used meta-analyses of studies with measured weight and height because using self-reported weight and height can lead to bias in estimated RRs. The correlation between self-reported and measured weight, as found in selected studies [100], [101], does not remove the possibility of bias because even with perfect correlation, the absolute bias in self-reported weight and height may be a function of its true value. f The RRs reported for Asian and Australia–New Zealand populations were not significantly different in this meta-analysis providing empirical evidence on absence of significant effect modification in the multiplicative scale by ethnicity. A meta-analysis of studies in Europe and North America included studies [102] with self-reported height and weight and was thus not used in this analysis. The RRs reported in that meta-analysis ranged from 1.02 to 1.26 and the average RR weighted by number of cases was 1.07 per kg/m2 which is almost equal to the RR for 60- to 69-y-olds in this analysis. APCSC, Asia-Pacific Cohorts Studies Collaboration; PSC, Prospective Studies Collaboration. The studies used for etiological effect sizes included both randomized intervention studies of exposure reduction and observational studies (primarily prospective cohort studies) that estimated the effects of baseline exposure. The majority of observational studies used for effect sizes had adjusted for important potential confounding factors. Each RR used in our analysis represents the best evidence for the proportional effect of risk factor exposure on disease-specific mortality in the population based on the current causes and determinants of the population distribution of exposure (see also Discussion). We used RRs for blood pressure, LDL cholesterol, and FPG that were adjusted for regression dilution bias using studies that had repeated exposure measurement [7],[11], [12]; for blood pressure and LDL cholesterol, the adjusted magnitude is supported by effect sizes from randomized studies [13],[14]. Evidence from a large prospective study with multiple measurements of weight and height showed that regression dilution bias did not affect the RRs for BMI, possibly because there is less variability [15]. RRs for dietary salt and PUFA-SFA replacement were from intervention studies, and hence unlikely to be affected by regression dilution bias. RRs for dietary trans fatty acids were primarily from studies that had used cumulative averaging of repeated measurements [16] that reduces but may not fully correct for regression dilution bias. RRs for physical inactivity, alcohol use, smoking, and dietary omega-3 fatty acids and fruits and vegetables were not corrected for regression dilution bias due to insufficient current information from epidemiological studies on exposure measurement error and variability, which is especially important when error and variability of self-reported exposure may themselves differ across studies. For each risk factor–disease pair, we used the same RR for men and women except where empirical evidence indicated that the RR differed by sex: colon and pancreas cancers caused by high BMI [17], and all disease outcomes caused by alcohol use and tobacco smoking, for which there are sex differences in factors such as smoking duration and intensity [18] and type of alcohol consumed [19]. The RRs for some risk factor–disease associations vary by age, especially for cardiovascular diseases. We used consistent age-varying distributions of RRs across risk factors and diseases (Tables 2– 7). The current evidence suggests that when measured comparably the proportional effects of the risk factors considered in this analysis are similar across populations, e.g., Western and Asian populations [7],[20],[21]. The exception to this observation is the effects of alcohol use on ischemic heart disease (IHD) where the pattern of drinking (regular versus binge) determines the RR. We used both the average quantity of alcohol consumed as well as the drinking pattern in our analysis of exposure and RRs for alcohol use and IHD. The effects of alcohol on injuries and violence may also be modified by social, policy, and transportation factors. Therefore, we did not pool epidemiological studies on the injury effects of alcohol from different countries, but used data sources that appropriately measure effects in the US (Table 4). Disease-specific deaths The number of disease-specific deaths, by age and sex, was obtained from the NCHS, which maintains records for all deaths in the US. Although the US has automated (computerized) assignment of an International Classification of Diseases (ICD) code for the underlying cause of death, the validity and comparability of cause of death statistics may be affected at the time of medical certification, especially for cardiovascular causes and diabetes [22]–[24]. We adjusted for incomparability in cause of death assignment using previously described methods [22],[23]. This adjustment required information on multiple contributing causes of death and county of residence. We obtained county identifiers for all deaths in 2005 through a special request to the NCHS. Several risk factors have different effects on ischemic and hemorrhagic stroke (Table 1). Slightly more than 50% of stroke deaths in 2005 were assigned to unspecified subtype (ICD-10 code I-64). We redistributed these deaths to ischemic and hemorrhagic stroke using proportions from large epidemiological studies with high-quality diagnosis and cause-of-death assignment [25], stratified by age using a meta-analysis of stroke registries in Western populations [26]. Estimating Mortality Attributable to Risk Factors For each risk factor and for each disease causally associated with its exposure, we computed the proportional reduction in disease-specific deaths that would occur if risk factor exposure had been reduced to an alternative level. This is known as the population-attributable fraction (PAF) and measures the total effects of a risk factor (direct as well as mediated through other factors). For risks measured continuously (blood pressure, BMI, LDL cholesterol, FPG, dietary fruits and vegetables, and trans and polyunsaturated fatty acids), we computed PAFs using the following relationship. (1) Where x = exposure level; P(x) = actual distribution of exposure in the population; P′(x) = alternative distribution of exposure in the population; RR(x) = relative risk of mortality at exposure level x; and m = maximum exposure level. For risks measured in categories of exposure (smoking, physical inactivity, alcohol use, and dietary omega-3 fatty acids), we used the discrete version of the same estimator for PAF. We used a different method of estimating the PAFs for effects of alcohol use on injuries. A number of emergency room studies have collected information on alcohol consumption in the 6 h prior to the injury among injury patients. Injuries that occur among patients who had consumed alcohol prior to their injury were classified as “alcohol-related” injuries. Because some of these injuries would have occurred in the absence of alcohol, not all are caused by alcohol use; in other words, the proportion of alcohol-attributable injuries is lower than that of alcohol-related injuries. Highway studies have quantified the increased risk of road traffic deaths among drivers who have consumed alcohol according to the drivers' blood alcohol concentration, often reported as odds ratios (ORs). Ideally, ORs would be used in conjunction with data on population prevalence of intoxication to calculate PAF. Because intoxication data were not available, we used a slightly modified equation to calculate the PAF using ORs from highway studies and data on alcohol-related injuries: (2) The proportion of alcohol-related injuries was obtained from Fatality Analysis Reporting System (FARS) for road traffic injuries and from a meta-analysis of emergency room studies for other types of intentional and unintentional injuries [27], [28]. FARS is a census of fatal crashes maintained by the National Highway Traffic Safety Administration and includes information on the blood alcohol concentration (BAC) level of drivers involved in fatal crashes, regardless of whether the decedent was the driver or not. Beginning in 2001, National Center for Statistics and Analysis uses a multiple imputation method to impute ten values for each missing BAC value. Additional information on FARS is available at http://www-fars.nhtsa.dot.gov/Main/index.aspx. The sources for ORs are provided in Table 4. We calculated the number of deaths from each causally related disease outcome attributable to a risk factor by multiplying its PAF by total deaths from that disease. Disease-specific deaths attributable to each risk factor were summed to obtain the total (all-cause) attributable deaths. Deaths from different diseases attributable to a single risk factor are additive because in mortality statistics based on the ICD, each death is categorically assigned to a single underlying cause (disease) with no overlap between disease-specific deaths. However, the deaths attributable to individual risk factors often overlap and should not be summed (see Discussion). To measure the mortality effects of all non-optimal levels of exposure consistently and comparably across risk factors, we used an optimal exposure distribution, referred to as the theoretical-minimum-risk exposure distribution (TMRED), as the alternative exposure distribution (Table 1). The TMREDs were zero for risk factors for which zero exposure led to minimum risk (e.g., no tobacco smoking). For BMI, blood pressure, blood glucose, and LDL cholesterol, zero exposure is physiologically impossible. For these risks we used TMREDs based on the levels corresponding to the lowest mortality rate in epidemiological studies or the levels observed in low-exposure populations (Table 1). Alcohol use may be beneficial or harmful depending on the specific disease outcome and patterns of alcohol consumption [29], [30]. We used a TMRED of zero for alcohol in our primary analysis, and regular drinking of small amounts as the TMRED in a sensitivity analysis. The TMREDs for factors with protective effects (physical activity and dietary PUFA-SFA replacement, omega-3 fatty acids, and fruits and vegetables) were selected as the intake and activity levels to which beneficial effects may plausibly continue based on the evidence from current studies. For example, intake of omega-3 fatty acids seems to reduce IHD mortality at intakes up to 250 mg/d, but has relatively little additional mortality benefits at higher intakes [31]. In setting TMREDs for protective factors, we also took into account the levels observed in populations that have high intake, e.g., for fruits and vegetables. We conducted all analyses separately by sex and age group (30–44, 45–59, 60–69, 70–79, and ≥80 y). We restricted analyses to ≥30 y because there are limited data on the mortality effects of these risk factors at younger ages and because there are few deaths from diseases affected by these risks in younger ages (about 10,000 deaths from the relevant non-injury causes in Americans <30 y versus 1,745,000 in those ≥30 y). The exception was the effect of alcohol use on injuries for which we also included 0- to 29-y-olds because there are substantial injury deaths at these ages. Therefore, we can assess both the role of alcohol use as a cause of injuries in young drinkers and the effect of alcohol use by any drinker (e.g., an intoxicated driver) on injury in young nondrinkers. Uncertainty and Sensitivity Analyses We estimated the uncertainty of the number of deaths attributable to each risk factor as caused by sampling variability. To compute sampling uncertainty, we used a simulation approach to combine the uncertainties of exposure distributions and RRs in each age–sex group. In the simulation method, we drew repeatedly from the distributions of exposure mean and SD (for continuous risks) or prevalence in each exposure category (for categorical risks). The uncertainty of these parameters was characterized using normal, Chi-square, or binomial distributions. RRs for each disease were drawn from a log-normal distribution independently from exposure. Each set of exposure and disease-specific RR draws was used to calculate the PAFs for all diseases associated with the risk factor, separately by age and sex. We used 500 draws for each risk factor, and report 95% confidence intervals (CIs) based on the resulting distributions of 500 estimated attributable deaths. Further simulation details and computer code are available from the authors by request. In addition to sampling uncertainty, we examined the sensitivity of our results to important methodological factors and data sources. The methodological factors and data sources in the sensitivity analyses included the choice of exposure metrics, the shape of the exposure distribution, the TMREDs, disease outcomes causally associated with risk factors, and etiological effect sizes (Table S1). We used RRs adjusted for major potential confounders to estimate the causal components of risk factor–disease associations. However, if there is also a correlation between exposure and disease-specific mortality, due to correlations of exposure with other risks or other unobserved factors, the above equations may result in under- (when there is positive correlation) or over-estimation (negative correlation) of the true PAF when used with adjusted RRs [32]–[36]. To assess the effect of correlation, we also calculated PAFs that incorporated correlations between risk factors or between risk factors and underlying disease-specific mortality in multiple sensitivity analyses. Ideally the analyses of risk factor correlations would have used the complete multivariate distribution of exposure to all risk factors and disease outcomes. However, the sources in this analysis did not provide data on the joint exposure distributions of all risk factors together. Therefore, our analyses of risk factor correlation using current data sources were limited to risk factor pairs. Analyses were conducted using Stata version 10 (Stata Corp, College Station, Texas) and SAS version 9.1 (SAS Institute, Cary, NC). Results In the year 2005, 2,448,017 US residents died; 49% of these deaths were among men. Ninety-six percent of all deaths in the US were in people ≥30 y of age. After adjustment for comparability of cause-of-death assignment [22],[23], the four most common causes of death were IHD (434,000 deaths), lung cancer (163,000 deaths), stroke (150,000 deaths), and chronic obstructive pulmonary diseases (124,000 deaths). Total Mortality Effect of Risk Factors Tobacco smoking was responsible for an estimated 467,000 (95% CI 436,000–500,000) deaths and high blood pressure for 395,000 (372,000–414,000) deaths, each accounting for about one in five or six deaths in US adults in 2005 (Figure 1A, Table 8). Overweight–obesity, physical inactivity, and high blood glucose each caused 190,000–216,000 deaths (8%–9% of all deaths in adults). The mortality effects of individual dietary risk factors ranged from 15,000 deaths for low dietary PUFA (<1% of all deaths) to 82,000–102,000 deaths for low dietary omega-3 fatty acids, high dietary trans fatty acids, and high dietary salt. Alcohol use caused 90,000 deaths from road traffic and other injuries, violence, chronic liver disease, cancers, alcohol use disorders, hemorrhagic stroke, arrhythmias and hypertensive disease, but also averted a balance of 26,000 deaths from IHD, ischemic stroke, and diabetes, due to benefits among those who drank alcohol moderately and regularly. 10.1371/journal.pmed.1000058.g001 Figure 1 Deaths attributable to total effects of individual risk factors, by disease. Data are shown for both sexes combined (upper graph); men (middle graph); and women (lower graph). See Table 8 for 95% CIs. Notes: We used RRs for blood pressure, LDL cholesterol, and FPG that were adjusted for regression dilution bias using studies that had repeated exposure measurement [7],[11],[12]; for blood pressure and LDL cholesterol, the adjusted magnitude is supported by effect sizes from randomized studies [13],[14]. Evidence from a large prospective study using multiple measurements of weight and height showed that regression dilution bias did not affect the RRs for BMI, possibly because there is less variability [15]. RRs for dietary salt and PUFA were from intervention studies, and hence unlikely to be affected by regression dilution bias. RRs for dietary trans fatty acids were primarily from studies that had used cumulative averaging of repeated measurements [16] that reduces but may not fully correct for regression dilution bias. RRs for physical inactivity, alcohol use, smoking, and dietary omega-3 fatty acids and fruits and vegetables were not corrected for regression dilution bias due to insufficient current information from epidemiological studies on exposure measurement error and variability, which is especially important when error and variability of self-reported exposure may themselves differ across studies. Regression dilution bias often, although not always, underestimates RRs in multivariate analysis [48]. aThe figures show deaths attributable to the total effects of each individual risk. There is overlap between the effects of risk factors because of multicausality and because the effects of some risk factors are partly mediated through other risks. Therefore, the number of deaths attributable to individual risks cannot be added. bThe effect of high dietary salt on cardiovascular diseases was estimated through its measured effects on systolic blood pressure. cThe protective effects of alcohol use on cardiovascular diseases are its net effects. Regular moderate alcohol use is protective for IHD, ischemic stroke, and diabetes, but any use is hazardous for hypertensive disease, hemorrhagic stroke, cardiac arrhythmias, and other cardiovascular diseases. NCD, noncommunicable diseases. 10.1371/journal.pmed.1000058.t008 Table 8 Deaths from all causes (thousands of deaths) attributable to risk factors and the 95% confidence intervals of their sampling uncertainty. Risk factor Male Female Both Sexes Tobacco smoking 248 (226–269) 219 (196–244) 467 (436–500) High blood pressure 164 (153–175) 231 (213–249) 395 (372–414) Overweight–obesity (high BMI) 114 (95–128) 102 (80–119) 216 (188–237) Physical inactivity 88 (72–105) 103 (80–128) 191 (164–222) High blood glucose 102 (80–122) 89 (69–108) 190 (163–217) High LDL cholesterol 60 (42–70) 53 (44–59) 113 (94–124) High dietary salt (sodium) 49 (46–51) 54 (50–57) 102 (97–107) Low dietary omega-3 fatty acids (seafood) 45 (37–52) 39 (31–47) 84 (72–96) High dietary trans fatty acids 46 (33–58) 35 (23–46) 82 (63–97) Alcohol usea 45 (32–49) 20 (17–22) 64 (51–69) Low intake of fruits and vegetables 33 (23–45) 24 (15–36) 58 (44–74) Low dietary polyunsaturated fatty acids (PUFA) (in replacement of SFA) 9 (6–12) 6 (3–9) 15 (11–20) a Excludes uncertainty in intentional and unintentional injury outcomes because the attributable deaths used data sources that did not report sampling uncertainty. Mortality Effects of Risk Factors by Disease Most deaths attributable to these risks were from cardiovascular diseases (Figure 1). Cancers, respiratory diseases, diabetes, and injuries nonetheless accounted for at least 23% of all deaths caused by smoking, alcohol use, high blood glucose, physical inactivity, low intake of fruits and vegetables, and overweight–obesity. The single largest risk factor for cardiovascular mortality in the US was high blood pressure, responsible for an estimated 395,000 (95% CI 372,000–414,000) cardiovascular deaths (45% of all cardiovascular deaths), followed by overweight–obesity, physical inactivity, high LDL cholesterol, smoking, high dietary salt, high dietary trans fatty acids, and low dietary omega-3 fatty acids. Smoking had the largest effect on cancer mortality compared with any other risk factor, causing an estimated 190,000 (184,000–194,000) or 33% of all cancer deaths. Mortality Effects of Risk Factors by Sex and Age High blood pressure was the leading cause of death in women (231,000 deaths [95% CI 213,000–249,000], 19% of all female deaths), whereas smoking remains the leading cause of death in men (248,000 deaths [226,000–269,000], 21% of all male deaths). The leading causes of death in men and women were different because women have higher blood pressure and men higher cumulative (i.e., current and former) smoking. Overweight–obesity, physical inactivity, and high blood glucose were the third to fifth causes of death for both sexes (Figure 1B and 1C). High dietary salt was responsible for slightly more deaths than high LDL cholesterol in women. The mortality effects of all individual risk factors except alcohol use were almost equally divided between men and women (i.e., at least 40% of deaths attributable to each individual risk factor were either in men or in women). Seventy percent of all deaths attributable to alcohol use occurred in men (45,000 deaths), because men consumed more alcohol and had more binge drinking. Four percent of all deaths in the US occurred in people between 30 and 45 y of age. No individual risk factor was responsible for more than 7% of deaths in this age group. However, this age group bore 34% of alcohol-caused injuries (Table 9), making injury deaths in young adults the major mortality impact of alcohol use. Eighty percent of deaths attributable to high blood pressure and 68% and 70% of those attributable to high dietary salt and physical inactivity, respectively, occurred after 70 y of age (Table 9). Conversely, 40% or more of all deaths attributable to high LDL cholesterol, overweight–obesity, high dietary trans fatty acids, low dietary PUFA and omega-3 fatty acids, low intake of fruits and vegetables, alcohol use, and smoking occurred before 70 y of age (Table 9). As a result, when the young and middle-aged (≤70 y of age) mortality effects of these risk factors were evaluated, smoking was by far the leading cause of death in both men and women ≤70 y, followed by overweight–obesity (Figure 2). 10.1371/journal.pmed.1000058.g002 Figure 2 Deaths attributable to total effects of individual risk factors, by disease in those below 70 years of age. Data are shown for both sexes combined (upper graph); men (middle graph); and women (lower graph). See Figure 1 notes. 10.1371/journal.pmed.1000058.t009 Table 9 Distribution of cause-specific and all-cause deaths attributable to risk factors by age group and by sex. Risk Factor Disease 0–29 y 30–45 y 45–69 y ≥ 70 y Males Females High blood glucose Cardiovascular diseases NA 2 (1 to 3) 31 (24 to 40) 68 (58 to 75) 55 (43 to 68) 45 (32 to 57) Diabetes mellitusa NA 3 (3 to 3) 33 (33 to 33) 64 (64 to 64) 51 (51 to 51) 49 (49 to 49) Renal failure NA 1 (0 to 6) 21 (3 to 71) 77 (26 to 96) 53 (12 to 94) 47 (6 to 88) All causes NA 2 (2 to 3) 31 (26 to 36) 67 (61 to 72) 53 (46 to 61) 47 (39 to 54) High LDL cholesterol Cardiovascular diseases NA 4 (0 to 6) 40 (30 to 47) 55 (50 to 66) 53 (44 to 59) 47 (41 to 56) High blood pressure Cardiovascular diseases NA 1 (1 to 1) 19 (18 to 20) 80 (79 to 82) 42 (39 to 44) 58 (56 to 61) Overweight–obesity (high BMI) Cardiovascular diseases NA 5 (3 to 6) 41 (33 to 48) 55 (47 to 63) 55 (47 to 65) 45 (35 to 53) Cancers NA 2 (2 to 3) 42 (38 to 47) 55 (51 to 60) 40 (36 to 46) 60 (54 to 64) Diabetes mellitus NA 5 (4 to 5) 42 (38 to 47) 54 (48 to 58) 52 (46 to 58) 48 (42 to 54) All causes NA 4 (3 to 5) 41 (36 to 46) 55 (49 to 61) 53 (47 to 60) 47 (40 to 53) High dietary trans fatty acids Cardiovascular diseases NA 5 (3 to 7) 41 (31 to 50) 54 (45 to 65) 57 (46 to 67) 43 (33 to 54) Low dietary polyunsaturated fatty acids (PUFA) (in replacement of SFA) Cardiovascular diseases NA 7 (2 to 11) 40 (23 to 56) 53 (37 to 70) 59 (43 to 75) 41 (25 to 57) Low dietary omega-3 fatty acids Cardiovascular diseases NA 4 (3, 5) 36 (30 to 41) 60 (54 to 66) 53 (47 to 60) 47 (40 to 53) High dietary salt Cardiovascular diseases NA 3 (3 to 3) 28 (27 to 30) 69 (67 to 70) 47 (45 to 50) 53 (50 to 55) Cancers NA 5 (1 to 8) 36 (21 to 52) 59 (43 to 74) 58 (40 to 73) 42 (27 to 60) All causes NA 3 (3 to 3) 29 (27 to 30) 68 (66 to 70) 48 (45 to 50) 52 (50 to 55) Low intake of fruits and vegetables Cardiovascular diseases NA 3 (1 to 5) 35 (22 to 52) 62 (44 to 75) 55 (37 to 76) 45 (24 to 63) Cancers NA 3 (2 to 5) 56 (39 to 71) 41 (25 to 58) 62 (47 to 76) 38 (24 to 53) All causes NA 3 (2 to 5) 43 (32 to 57) 54 (39 to 66) 58 (45 to 71) 42 (29 to 55) Alcohol use b Cardiovascular diseases NA 11 (4 to 34) 131 (93 to 159) −42 (−75 to −7) 105 (85 to 126) −5 (−26 to 15) Cancers NA 5 (4 to 6) 55 (49 to 61) 40 (34 to 46) 64 (58 to 69) 36 (31 to 42) Diabetes mellitus NA 5 (4 to 6) 44 (40 to 49) 51 (46 to 55) 50 (45 to 55) 50 (45 to 55) Other noncommunicable diseasesc NA 15 (14 to 16) 68 (66 to 71) 17 (15 to 19) 74 (72 to 76) 26 (24 to 28) Injuriesd 31 (31 to 31) 34 (34 to 34) 29 (29 to 29) 6 (6 to 6) 77 (77 to 77) 23 (23 to 23) All causes 18 (16 to 23) 24 (21 to 30) 34 (20 to 40) 24 (20 to 30) 70 (62 to 73) 30 (27 to 38) Physical inactivity Cardiovascular diseases NA 2 (1 to 2) 24 (19 to 30) 74 (68 to 79) 49 (40 to 60) 51 (40 to 60) Cancers NA 5 (3 to 7) 42 (35 to 50) 53 (45 to 60) 24 (18 to 29) 76 (71 to 82) Diabetes mellitus NA 3 (2 to 5) 35 (28 to 43) 61 (52 to 69) 50 (40 to 61) 50 (39 to 60) All causes NA 2 (2 to 3) 28 (23 to 33) 70 (64 to 75) 46 (38 to 54) 54 (46 to 62) Tobacco smoking Cardiovascular diseases NA 4 (0 to 7) 51 (43 to 63) 44 (34 to 54) 49 (38 to 60) 51 (40 to 62) Cancers NA 1 (0 to 2) 43 (42 to 44) 56 (55 to 57) 61 (60 to 62) 39 (38 to 40) Other respiratory diseasese NA 0 (0 to 1) 21 (19 to 22) 79 (78 to 80) 46 (44 to 48) 54 (52 to 56) Diabetes mellitus NA 1 (0 to 3) 36 (30 to 41) 63 (57 to 68) 50 (44 to 57) 50 (43 to 56) All causes NA 2 (0 to 3) 39 (36 to 42) 59 (56 to 62) 53 (49 to 57) 47 (43 to 51) Numbers show percent in each age group or in each sex and the corresponding 95% confidence intervals of sampling uncertainty. a There is no sampling uncertainty for this outcome because all the deaths due to diabetes are by definition attributable to high blood glucose. b The negative proportions for alcohol use and cardiovascular diseases in older ages and in females occur because the protective effects are larger than the hazardous effects. c This category includes liver cirrhosis, acute and chronic pancreatitis, and alcohol use disorders. d We did not estimate sampling uncertainty for injury outcomes because the attributable deaths used data sources that did not report sampling uncertainty. e This category includes lower respiratory tract infections, asthma, and tuberculosis. Mortality Effects of Risk Factor by Exposure Level There was substantial variation in how deaths attributable to these risks were distributed below or above commonly used thresholds and guidelines (Table 10): close to two-thirds of deaths attributable to high blood pressure (66%), high BMI (63%), and high blood glucose (60%) occurred in people who would be clinically classified as hypertensive, obese, or diabetic, even though these groups make up only 10%–33% of the US adult population (note that the estimated benefits in these people would be achieved if risk factor levels are reduced to their TMREDs, and not simply to the clinical threshold). In contrast, more than one-half of deaths attributable to high LDL cholesterol were among people below the conventional threshold for defining dyslipidemia (3.37 mmol/l). 10.1371/journal.pmed.1000058.t010 Table 10 Distribution of risk factor exposure and attributable deaths by ranges or categories of exposure defined using common clinical and public health thresholds and guidelines. Risk Factor Source of Definition for Categories Exposure Categories Percentage of Attributable Deaths Percentage of Population (≥30 Years Old) High blood glucose a Definition of diabetes (FPG≥7 mmol/l) and impaired FPG (FPG 5.56 to 6.99 mmol/l) by American Diabetes Association [103] FPG≥7 mmol/l 60 10 FPG 5.56–6.99 mmol/l 34 29 FPG<5.56 mmol/l 6 61 High LDL cholesterol Definition of high LDL cholesterol in low risk (4.14 mmol/l) and moderate risk (3.37 mmol/l) individuals in Adult Treatment Panel III guidelines [104] LDL≥4.14 mmol/l 5 11 LDL 3.37–4.13 mmol/l 30 22 LDL<3.37 mmol/l 65 67 High blood pressure Definition of hypertension (SBP≥140 mmHg) [105] SBP≥140 mmHg 66 15 SBP<140 mmHg 34 85 Overweight–obesity (high BMI) Definition of obesity (BMI≥30 kg/m2) and overweight (BMI 25 to 29.9 kg/m2) BMI≥30 kg/m2 63 33 BMI 25–29.9 kg/m2 29 33 BMI<25 kg/m2 8 33 High dietary salt Recommended level of dietary sodium (<100 mmol/d) by American Heart Association [106] Dietary sodium≥100 mmol/d 88 75 Dietary sodium<100 mmol/d 12 25 Physical inactivity Definition of moderately active (600 met·min/wk) is the same as the recommended level of activity by Centers for Disease Control and Prevention [107] Inactive 74 31 Low-active 19 25 Moderately active 7 23 Highly active 0 21 Tobacco smoking — Current smokers 43 25 Former smokers 57 25 Never smokers 0 50 The proportion of population and mortality effects in different exposure categories. We have not included dietary risks other than dietary salt in this table primarily because current guidelines do not recommend a specific level of intake. a Deaths assigned to diabetes mellitus in the vital statistics and deaths attributable to renal failure are included in the ≥7 mmol/l category because all individuals whose deaths are assigned to diabetes or diabetic renal failure would, by definition, have been diagnosed with diabetes disease, and hence have FPG ≥7 mmol/l. The burden of smoking was almost equally distributed among current and former smokers, because harmful effects continue among many Americans who have quit smoking. Twenty-nine percent of the chronic disease mortality effects of alcohol use occurred among heavy drinkers (i.e., men who consumed more than 60 grams of pure alcohol or 4 drinks per day and women who consumed more than 40 grams per day); this group did not have any mortality benefits from alcohol use. In contrast, in those who had light alcohol consumption (up to 40 g per day for men and 20 g per day for women), the protective effects on IHD and diabetes mortality were larger than the hazardous effects from other chronic diseases, leading to an overall reduction in mortality in this group (unpublished results). Sensitivity Analyses The results of the sensitivity analyses in Table S1 show that the estimated numbers of deaths attributable to risk factors were most sensitive to the choice of the optimal exposure distribution (the TMRED) to which current risk factor exposure distributions were compared. For example, if the TMREDs for LDL cholesterol and BMI were 2.3 (instead of 2.0) mmol/l and 23 (instead of 21) kg/m2, respectively, the number of deaths attributable to them would be 18% and 19% lower. Similarly, lowering the TMRED of physical activity to the (less ambitious) current recommended level of 600 met·min per week (equivalent to 20 min of moderate activity every day) would prevent 62,000 (32%) fewer deaths than if people pursued a higher goal of 1,600 met·min per week (including at least one hour of vigorous activity per day). The TMRED for alcohol use must balance its harmful and beneficial effects. If the entire adult US population had light alcohol consumption, a total of 12,000 cardiovascular deaths would be prevented, largely among adults aged ≥45 y. However, this level of alcohol consumption would also cause an estimated 8,000 deaths due to road traffic accidents largely among adults aged <30 y. Incorporating correlation of a risk factor with disease-specific mortality and with other risks changed the estimated number of deaths attributable to a risk factor by 3%–31%, depending on the specific risk factor and disease. The results were robust to whether exposure in the population was approximated with a normal distribution and to the inclusion of the few disease outcomes for which the evidence of causal association was weaker. Mortality effects of dietary salt were sensitive to the magnitude of its effects on SBP, because there was an almost 2-fold difference between two separate meta-analyses of salt reduction trials [37],[38]. Discussion Our analysis of the mortality effects of major dietary, lifestyle, and metabolic risk factors in the US using comparable methods showed that tobacco smoking and high blood pressure were the leading risk factors for mortality, responsible for nearly one in five and one in six deaths in US adults, respectively. The large effects of tobacco smoking were caused by long-term cumulative exposure in current smokers as well as the remaining effects in former smokers, especially in men. The large numbers of deaths attributable to high blood pressure were related to high exposure levels, particularly in women [39]. Overweight–obesity, physical inactivity, and high blood glucose each caused about one in ten deaths, and both affected women disproportionately more than men. In those younger than 70 y of age, tobacco smoking was by far the leading modifiable cause of death, and overweight–obesity caused more deaths than did high blood pressure. Other lifestyle, metabolic, and dietary risk factors for chronic diseases also caused significant adult mortality, although their individual effects were 3%–24% of those of smoking. A comparison of our results with those of other risk factors is shown in Table S2. This comparison was done only for those risk factors included in previous analyses, because these analyses had included substantially fewer metabolic and dietary risks than ours. Each RR used in our analysis represents the best evidence for the impact of risk factor exposure on disease-specific mortality in the population, based on the current causes and determinants of the population distribution of exposure. The mortality effects of a risk factor may depend on whether an expected increase in exposure is prevented or whether exposure is reduced after it has risen. It may also depend on the specific intervention used to prevent or reverse risk factor exposure. The estimated effects of blood pressure, LDL cholesterol, omega-3 fatty acids, and PUFA-SFA replacement have been generally consistent between observational studies that measure exposure at baseline and intervention studies that reduce exposure prospectively [12],[14],[31]. There is also evidence that former smokers reduce their risk to that of never-smokers over time [40]. Although mortality effects of other risks in our analysis have not been tested in appropriately designed and powered intervention studies, trials and observational studies provide similarly valid results on related nonfatal events for some risks, e.g., effects of BMI on incident diabetes [41],[42]. Possibly the most important case of current discrepancy between prospective observational cohorts and intervention studies is the mortality effect of high blood glucose. Prospective studies have shown relatively large associations between usual FPG and mortality [7],[43], but randomized intervention studies have shown null effects, and declines as well as increases in mortality when glucose was lowered intensively relative to those who had conventional management [44],[45]. This discrepancy may reflect the actual intervention mechanism (lifestyle versus pharmacologic treatment) or the differential effects of avoiding an increase in blood glucose versus subsequent lowering. Alternatively, blood glucose may be a partial or confounded marker of other underlying metabolic dysfunction, so that interventions targeting only glucose may be unsuccessful at ameliorating all of the observed risk. Further research is needed on the causal effects of blood glucose on mortality risk and on the role of specific lifestyle and pharmacologic interventions. Finally, there is also a need to systematically examine whether salt reduction trials with sufficiently long follow-up duration can capture the full blood pressure–lowering benefits of having maintained low salt intake throughout the life course [37]. Our results estimate the total effects of each individual risk factor. Disease-specific deaths are caused by multiple factors acting simultaneously, and hence could be prevented by intervening on single or multiple risk factors, e.g., some IHD deaths may be prevented by reducing SBP, LDL cholesterol, smoking, or combinations of these risks [46]. Further, part of the effect of one risk factor may be mediated through another, e.g., dietary factors and physical inactivity may affect IHD with part of their effect occurring by changes in BMI, blood pressure, glucose, and LDL cholesterol. Deaths attributable to multiple causally related or overlapping risk factors should not be combined by simple addition. Future analyses, both in epidemiological cohorts and at the population level, should examine the individual and combined effects of multiple exposures that affect the same diseases, including how much of the effects of lifestyle and dietary risks are mediated through metabolic factors. Finally, the effects of dietary macronutrients may vary depending on the macronutrient replacement (e.g., for PUFA; see Table 2 for details). Therefore, the interpretation of results should take such replacement issues into account. There are a number of innovations and strengths in our analysis. This is, to our knowledge, the first population-level analysis of the mortality effects of risk factors to include a relatively large number of dietary and metabolic risk factors, and to use consistent and comparable methods. This comparative quantification helped identify the important roles of diet and physical inactivity, other lifestyle factors, and metabolic risks as preventable causes of death in the US population. Effect sizes were derived from large meta-analyses of either randomized trials or observational studies that had adjusted for important confounders. RRs from meta-analyses tend to reduce random error relative to individual studies; they may also reduce bias if the directions of bias are not the same in individual studies. We used exposure distributions and effect sizes that accounted for measurement error associated with one-off measurements to the extent possible. Our study presented deaths attributable to risk factors by age and sex, and by exposure level. The latter helped identify whether those whose exposure remains uncontrolled with current diagnosis and treatment programs versus those who are currently below clinical thresholds should be targeted for greatest effects on mortality. Finally, we quantified the sampling uncertainty of our estimates; we also analyzed how specific methods and data sources affected our quantitative results in extensive sensitivity analyses. This demonstrated that although the specific numerical results are uncertain, our overall findings on the relative mortality effects of these dietary, lifestyle, and metabolic risk factors are robust. Population level analyses of mortality effects of risk factors such as ours are also affected by some limitations and uncertainties. First, several potentially important risk factors were considered, but could not be included because sufficient or unbiased data on their national exposure distributions and/or effects on disease-specific mortality were not available, or because the evidence on causal effects was less convincing. Second, for many risks the choice of disease outcomes and effect sizes were derived from observational studies. In such cases, whether the collectivity of evidence established a causal association had to be assessed using multiple criteria, such as those proposed by Hill [47]. In such cases, the possibility of residual confounding cannot be excluded. Our ability to account for measurement error in exposure and to correct for regression dilution bias was limited to those risk factors for which relevant data were available from epidemiological studies; for other risks, our results should be considered as conservative estimates of the effects because regression dilution bias often, although not always, leads to lower RRs in multivariate analysis [48]. RRs from meta-analyses may not be completely generalizable to population-level effects; nevertheless, such estimation is indispensable to inform policy making. More importantly, in many cases there is empirical evidence to support the proposition that proportional effects are similar across populations, e.g., Western and Asian populations [7],[20],[21]. The hazardous effects of some risk factors accumulate gradually after exposure begins and decline slowly after exposure is reduced. This is illustrated by results from trials that have lowered blood pressure and cholesterol, and from studies in which some people quit smoking [13],[40]. Time-dependence of risk may further vary by disease, e.g., the effects of tobacco smoking on lung cancer versus cardiovascular diseases [49]. Because smoking prevalence has declined in the US, the use of the smoking impact ratio (SIR) as the metric of cumulative exposure [18] may have overestimated the cardiovascular deaths attributable to smoking. However, the difference between the estimated number of deaths using this method and using the measured prevalence of current and former smoking was <14% (Table S1). The use of RRs from cohort studies that started a few decades ago may overestimate the effects of BMI on diseases such as IHD if “mediators” such as SBP and cholesterol have been lowered over time in those with high BMI [50]–[52], but underestimate the effects for other diseases such as diabetes because the current US population gained weight at younger ages than the cohort participants. Future research should attempt to investigate time-dependent effects of blood glucose, BMI, physical activity, and dietary factors, because their exposures have changed in the US over time. The results of our analysis of dietary, lifestyle, and metabolic risk factors show that targeting a handful of risk factors has large potential to reduce mortality in the US, substantially more than the currently estimated 18,000 deaths averted annually by providing universal health insurance [53]. Global analyses also found that a relatively modest number of risk factors were responsible for a substantial proportion of mortality and disease burden in many world regions. At the same time the mix of leading risks varied across regions, as did risk factor levels in relation to economic development and urbanization [46],[54]. Therefore there is a need for national, and even subnational, analysis of the health consequences of these risks in countries at different levels of development using local exposure data [55]. The risk factors in this analysis can be influenced through both individual-level and population-wide interventions. In particular, effective interventions are available for tobacco smoking and high blood pressure, the leading two causes of mortality in the US [56]–[58]. Combinations of food industry regulation, pricing, and better information can also be effective in reducing exposure to dietary salt and trans fatty acids, especially in packaged foods and prepared meals. Despite the availability of interventions, blood pressure and tobacco smoking decline in the US have stagnated or even reversed [39],[59], and there has been a steady increase in overweight–obesity [60]. Research, implementation, monitoring, and evaluation related to interventions that reduce these modifiable risk factors should be a high priority. Supporting Information Table S1 Sensitivity of results to methodological choices and data sources. (0.08 MB DOC) Click here for additional data file. Table S2 Comparison of estimated number of deaths attributable to risk factors with those from previous studies. (0.07 MB DOC) Click here for additional data file.
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            Effects on Coronary Heart Disease of Increasing Polyunsaturated Fat in Place of Saturated Fat: A Systematic Review and Meta-Analysis of Randomized Controlled Trials

            Introduction Reduction in saturated fatty acid (SFA) consumption is traditionally a major focus of dietary recommendations to reduce coronary heart disease (CHD) risk. However, effects of such a strategy on clinical CHD events are surprisingly poorly established in both randomized controlled trials (RCTs) [1]–[8] and prospective cohort studies [9]. Prior meta-analyses of RCTs have either studied the effects of very heterogeneous dietary fat interventions on very heterogeneous combinations of cardiovascular outcomes [10], or studied effects of dietary fat interventions on intermediate risk markers, such as blood lipids [11]. Furthermore, although dietary guidelines often recommend reduction in SFA consumption, such guidelines often do not highlight any specific nutrient as preferable for replacing SFA in the diet [12]–[14], implying that any macronutrient replacement (unsaturated fats, carbohydrate, or protein) will produce similar effects. Consumption of polyunsaturated fatty acids (PUFA) lowers the total∶high-density lipoprotein cholesterol (TC∶HDL-C) ratio, perhaps the best single lipid predictor of CHD risk [15], to a greater extent than carbohydrate or any other major class of fatty acids [11]. PUFA consumption may also improve insulin resistance [16],[17] and reduce systemic inflammation [18]–[20]. These effects on risk factors suggest that PUFA may be an ideal replacement for SFA in the population. However, surprisingly, some scientists and organizations argue that consumption of n-6 PUFA, by far the predominant dietary PUFA, will actually increase CHD risk and have recommended reduced consumption [21]–[23], and the Institute of Medicine recommends only a relatively modest range of 5%–10% energy (%E) consumption from PUFA [24], limiting its plausibility as a meaningful replacement for SFA. Several controlled intervention trials have evaluated whether increasing PUFA consumption, as replacement for SFA, impacts risk of CHD events but results of these trials have been inconsistent, with the majority of studies demonstrating no significant benefits [1]–[8]. Thus, the demonstration of whether replacing SFA with PUFA affects CHD outcomes and, if so, the direction and magnitude of this effect are surprisingly understudied matters of scientific and public health importance. To investigate and quantify this effect, we performed a systematic review and meta-analysis of randomized controlled clinical trials that assessed the impact of increased PUFA consumption, as replacement for SFA, on CHD endpoints. Methods We followed the Quality of Reporting of Meta-analyses (QUOROM – now PRISMA (http://www.prisma-statement.org/)) [25] guidelines throughout the design, implementation, analysis, and reporting of this meta-analysis (see Text S1 for PRISMA Statement). Search Strategy We searched for all RCTs that randomized adults to increased total or n-6 PUFA consumption for at least 1 year without other major concomitant interventions (e.g., blood pressure or smoking control, other multiple dietary interventions, etc.), had an appropriate control group without this dietary intervention, and reported (or had obtainable from the authors) sufficient data to calculate risk estimates with standard errors for effects on occurrence of “hard” CHD events (myocardial infarction, CHD death, and/or sudden death). Studies were excluded if they were observational or otherwise nonrandomized; tested mainly n-3 (rather than total or n-6) PUFA interventions or evaluated only intermediate (e.g., lipid levels) or “soft” (e.g., angina) CHD endpoints; or were commentaries, reviews, or duplicate publications from the same study. We did not restrict to primary or secondary prevention trials, but included this as a prespecified factor for assessment of heterogeneity. We included both feeding trials and trials that utilized dietary advice; for both designs, the average change in PUFA consumption was assessed. Searches were performed of literature published through June 2009 using MEDLINE, Embase, AGRIS, AMED, HMIC, PsycINFO, Cochrane library, Web of Knowledge, CABI, CINAHL, conference abstracts (Zetoc), Faculty of 1,000, grey literature sources (SIGLE), related articles, and hand-searching of reference lists. Authors and experts were also directly contacted to identify potentially unpublished trials and, when necessary, request missing data or clarify methods or results. A full list of search terms for all databases is available (see Text S2 for Protocol). For example, for MEDLINE, search terms were (“Fatty Acids, Omega-6”[Mesh] OR “unsaturated fatty acid”[tiab] OR “unsaturated fatty acids”[tiab] OR “unsaturated fat”[tiab] OR “unsaturated fats”[tiab] OR “polyunsaturated fatty acid”[tiab] OR “polyunsaturated fatty acids”[tiab] OR “polyunsaturated fat”[tiab] OR “polyunsaturated fats”[tiab] OR “omega-6”[tiab] OR “linoleic”[tiab] OR “octadecadienoic acid”[tiab] OR “safflower oil”[tiab] OR “sesame oil”[tiab] OR “soybean oil”[tiab] OR “soyabean oil”[tiab] OR “corn oil”[tiab]) AND (“cardiovascular diseases”[Mesh] OR “cardiovascular disease”[tiab] OR “cardiovascular diseases”[tiab] OR “heart disease”[tiab] OR “heart diseases”[tiab] OR “myocardial infarction”[tiab] OR “myocardial infarctions”[tiab] OR “heart attack”[tiab] OR “heart attacks”[tiab] OR “sudden death”[tiab] OR “sudden deaths”[tiab] OR “coronary syndrome”[tiab]) and NOT (“Fatty Acids, Omega-3”[Mesh] OR “omega-3”[tw] OR “n-3”[tw] OR “stroke”[tiab] OR “strokes”[tiab] OR “cerebrovascular accident”[tiab] OR “cerebrovascular accidents”[tiab] OR “Case Reports”[Publication Type]); limited to humans, adults, and clinical trials or RCTs; through June 2009 without other date or language limitations. For other databases, search terms followed similar concepts with variations based on the database structure. Selection of Articles Of 346 identified articles, 290 were excluded based upon review of the title and abstract (Figure 1). Full texts of the remaining 54 manuscripts were independently assessed in duplicate by two investigators to determine inclusion/exclusion. Forty-six studies were excluded because they did not meet inclusion and exclusion criteria (Table S1). The independent duplicate inclusion/exclusion adjudications were 96% concordant on initial comparison. The rare differences were resolved by group consultation among all investigators, with unanimous consensus. 10.1371/journal.pmed.1000252.g001 Figure 1 Results of the systematic search strategy and study selection process. Data Extraction For each of the final identified trials, data were extracted independently and in duplicate by two investigators, including years the study was performed and reported, population characteristics, control and intervention diets, duration of follow-up, numbers and types of first CHD events during follow-up, risk ratios (RRs), and standard errors (SEs) of these estimates. When the latter were not available, they were directly calculated using binomial tests of proportions, given that most studies reported RRs rather than incidence rates; stronger findings were seen if SEs were directly calculated using person-time at risk for two reports using incidence rates (unpublished data). Differences in data extracted or quality assessment scores between investigators were very unusual and were resolved by consensus. Several different criteria have been proposed for judging quality of randomized trials in meta-analyses, although the validity and utility of different quality scores has been debated [26]. We assessed study quality using the validated Jadad scale [27], which includes criteria relating to randomization, blinding, and withdrawals and dropouts that are together summed to generate an overall quality score between 0 and 5. Following prior precedent [27], quality scores of 0–2 indicated lower-quality trials, and quality scores of 3–5 indicated higher-quality trials. Statistical Analysis The overall pooled effect was calculated using random effects meta-analysis, which accounts for heterogeneity in treatment effects among studies, using the methods of Dersimonian and Laird [28] with inverse-variance (SE) weighting. Heterogeneity between studies was evaluated using the Dersimonian and Laird Q-statistic, the I2 statistic, and meta-regression [28],[29]. Potential for publication bias was assessed by visually inspecting a funnel plot of the treatment effect versus SE [30] and statistically using the Begg adjusted-rank correlation test [31]. Prespecified potential sources of heterogeneity were explored using stratified inverse-variance weighted random effects meta-analysis and inverse-variance weighted metaregression, including trial duration (< or ≥ median for all trials), study population (primary versus secondary prevention), and overall quality score (0–2 versus 3–5). We also performed post-hoc secondary analyses for CHD mortality alone and total mortality, as well as based on selected study characteristics, such as enrollment design (excluding trials with open enrollment), extent of blinding, and type of dietary intervention (provision of meals versus dietary advice). Analyses were performed using STATA 10.1 (College Station, TX), with two-tailed alpha <0.05. Results The identified RCTs included a total of 1,042 CHD events among 13,614 participants (Table 1) [1]–[8],[32]–[34]. Average PUFA consumption ranged from 4.0%E to 6.4%E (weighted mean 5.0%E) in the control groups and from 8.0%E to 20.7%E (weighted mean 14.9%E) in the intervention groups. Diet was assessed in the majority of trials by either direct analysis of provided foods or by multiple-day weighed diet records. Four trials evaluated secondary prevention populations, three trials evaluated primary prevention populations, and one trial evaluated a mixed population of individuals with and without established CHD. Many of the trials had design limitations, such as single-blinding, inclusion of electrocardiographically defined clinical endpoints, or open enrollment. All trials utilized blinded endpoint assessment. Quality scores were in the modest range and relatively homogeneous: all trials had quality scores of either 2 or 3. Combining all trials, the pooled risk reduction for CHD events was 19% (RR = 0.81, 95% CI 0.70–0.95, p = 0.008) (Figure 2). Statistical evidence for substantial between-study heterogeneity was not present (Q-statistic p = 0.13; I2 = 37%). In evaluating potential for publication bias, the trial by Watts et al. [8] was clearly a potential outlier both in terms of sample size and risk reduction. Excluding this trial, there was little change in the overall pooled result: RR = 0.82, 95% CI 0.70–0.95; p heterogeneity = 0.11, I2 = 42%. Visual inspection of the resulting funnel plot indicated some potential for publication bias (Figure S1), with a borderline Begg's test (continuity corrected p = 0.07), although such determinations are limited when the number of studies is relatively small. 10.1371/journal.pmed.1000252.g002 Figure 2 Meta-analysis of RCTs evaluating effects of increasing PUFA consumption in place of SFA and occurrence of CHD events. 10.1371/journal.pmed.1000252.t001 Table 1 RCTs testing the effect on CHD events of increasing PUFA consumption in place of SFA. Study Population PUFA Intake - Control (%E) PUFA Intake – Intervention (%E) Design Intervention Strategy Blinding Dietary Assessment Method Follow-up No. of Events - Control No. of Events - Intervention CHD Outcome Quality Score Dayton 1968 – Los Angeles Veterans [1] 846 middle-aged and elderly semi-institutionalized men, with or without CHD 4.0a 14.9a Parallel randomized Partial feeding trial; ∼50% of meals eaten off-site Double-blind Direct analysis of provided foods Up to 8 y 71 53 Total MI + SCD 3 Medical Research Council 1968 – Soy oil [2] 393 ambulatory men with recent MI 4.4b 20.4b Parallel randomized Dietary advice; emphasis on soybean oil Blinded outcome assessment Multiple serial weighed diet records 2–7 y 51 45 Total MI + SCD 2 Leren 1970 – Oslo Diet-Heart Study [3] 412 middle-aged ambulatory men with prior MI 5.2c 20.7 Parallel randomized Dietary advice Blinded outcome assessment 7 to 14 day weighed diet records in a subset 5 yd 81 61 Total MI + SCD 2 Turpeinen 1979 – Finnish Mental Hospital (men) [4] ∼461 middle-aged institutionalized men without CHDe 4.3 12.9 Cluster-randomized cross-over design, open enrollmentf Feeding trial; meals provided Blinded outcome assessment Direct analysis of provided foods 6 y in each arm 47 25 MI (assessed by major or intermediate ECG change) + CHD death 2 Miettinen 1983 – Finnish Mental Hospital (women) [5] ∼357 middle-aged institionalized women without CHDe 4.3 12.9 Cluster-randomized cross-over design, open enrollmentf Feeding trial; meals provided Blinded outcome assessment Direct analysis of provided foods 6 y in each arm 46 27 MI (assessed by major or intermediate ECG change) + CHD death 2 Frantz 1989 – Minnesota Coronary Survey [6] 9,057 institutionalized men and women without CHD 5.2 14.7 Parallel randomized, open enrollment Feeding trial; meals provided Double-blind Direct analysis of provided foods Average 1 y, max 4.5 y 121 131 Total MI + SCD 3 Burr 1989 – Diet and Reinfarction Trial [7] 2,033 ambulatory men with recent MI 6.4b 8.9b Parallel randomized Dietary advice Blinded outcome assessment Questionnaire validated against 7 day weighed diet records 2 y 144 132 MI + CHD death 2 Watts 1992 – St Thomas' Atherosclerosis Regression Study [8] 55 ambulatory men with established CHD 5.2c 8.0 Parallel randomized Dietary advice; foods provided if requested Blinded outcome assessment Clinical interviews about dietary compliance 3.25 y 5 2 MI + death 2 a Linoleic acid consumption; total PUFA was not reported but would be very close. b Calculated from published data in the trial on %E from total fat, the polyunsaturated∶saturated fat ratio, and type of intervention oil consumed, and plausible relative amounts of PUFA versus other fats based on the other trials. c Imputed based upon the control diet in Frantz et al. (1989) that was also the median value among all control groups. d Primary endpoint; post-hoc 11 year results not used. e Results for incident CHD were reported among these participants without prevalent CHD. Results for total and cause-specific mortality were reported for all participants in a separate publication. f The units of randomization were long-term-stay hospitals, and subjects joined the trial when they were hospitalized or exited when discharged. ECG, electrocardiographic; MI, myocardial infarction; SCD, sudden cardiac death. Weighted by the inverse-variance of each trial, the mean increase in PUFA consumption in the intervention group, compared to the control group, was 9.9%E, corresponding to a risk reduction for each 5%E greater PUFA consumption of 10% (RR = 0.90, 95% CI 0.83–0.97). Weighted by the inverse-variance of each trial, the mean decrease in blood total cholesterol (TC) levels in the intervention group, compared to the control group, was 0.76 mmol/l (29 mg/dl), corresponding to an observed risk reduction of 24% for each 1 mmol/l reduction in TC (RR = 0.76, 95% CI = 0.62–0.93). The median duration of all trials was 4.25 years. Among the four trials with duration <4.25 years, the pooled RR was 0.91 (95% CI 0.76–1.10). Among the four trials with duration ≥4.25 years, the pooled RR was 0.73 (95% CI 0.61–0.87). In the four trials that evaluated exclusively or predominantly primary prevention populations, the pooled RR was 0.76 (95% CI 0.55–1.04). In the four trials that evaluated secondary prevention populations, the pooled RR was 0.84 (95% CI 0.72–0.98). For the six trials with a quality score of 2, the pooled RR was 0.78 (95% CI 0.66–0.91); for the two trials with a quality score of 3, the pooled RR was 0.91 (95% CI 0.63–1.31). Evaluating each of these potential sources of variation together in a metaregression model, study duration (p = 0.016), but not primary versus secondary prevention (p = 0.71) nor quality score (p = 0.78), was identified as a significant independent determinant of the extent of risk reduction. For each additional year of study duration, PUFA consumption lowered the relative risk of CHD events by an additional 9.2% in the intervention group (95% CI 1.7%–16.8%), compared with the control group. In secondary analyses restricted to CHD mortality alone (855 events, including 312 events from the full mortality report of one trial [34]), the pooled RR was 0.80 (95% CI 0.65–0.98). Evaluating total mortality due to all causes (2,472 events), the pooled RR was 0.98 (95% CI 0.89–1.08). The overall pooled result for CHD events was not substantially altered in post-hoc secondary analyses based on specific study design characteristics. For example, excluding the three reports (two trials) with open enrollment, the overall pooled RR was 0.83 (95% CI 0.72–0.95, p = 0.006). Excluding the Finnish mental hospital trial (two reports) that used a cluster-randomization design, the overall pooled RR was 0.87 (95% CI 0.76–1.00, p = 0.05). Only two trials were double-blind; restricting to these two studies, the pooled RR was 0.91 (95% CI 0.63–1.31), with wide confidence intervals indicative of limited statistical power. Restricting to the four reports that provided meals (i.e., that were feeding trials), the pooled RR was 0.76 (95% CI 0.55–1.04, p = 0.08). Restricting to the four trials that provided mainly dietary advice, the pooled RR was 0.84 (95% CI 0.72–0.98, p = 0.03). None of these subgroup analyses were significantly different from the main pooled result, as demonstrated by the 95% CIs in each subgroup analysis including the value of the main pooled RR estimate of 0.81. Discussion In this meta-analysis of RCTs, increasing PUFA consumption as a replacement for SFA reduced the occurrence of CHD events by 19%; each 5%E greater PUFA consumption reduced CHD risk by 10%. Whereas nearly all these trials were insufficiently powered to detect a significant effect individually, the pooled results demonstrate a significant benefit of replacing PUFA for SFA on clinical CHD events. Thus, this is only the second dietary intervention, together with consumption of long-chain omega-3 fatty acids (fish oil) [7],[35]–[37], that has now been clearly demonstrated to reduce cardiovascular events in RCTs. In short-term feeding trials, each 5%E of PUFA replacing SFA lowers low-density lipoprotein cholesterol (LDL-C) by 10 mg/dl, without an appreciable reduction in HDL-C, producing a lowering of the TC∶HDL-C ratio by 0.16; this can be compared to no significant change in the TC∶HDL-C ratio when SFA is replaced by carbohydrate [11]. In observational studies of adults aged 40–59 y, each 1 unit lower TC∶HDL-C is associated with 44% lower risk of CHD [15]. Based on these two sets of data, a 5%E increase in PUFA replacing SFA would be predicted, based on TC∶HDL-C effects alone, to reduce occurrence of CHD by 9% (Figure 3). Thus, the 10% risk reduction for a 5%E increase in PUFA replacing SFA demonstrated in the present meta-analysis of RCTs of clinical CHD outcomes is remarkably consistent with effects that would be predicted based on extension of the demonstrated lipid changes in short-term intervention trials to epidemiologic associations between TC∶HDL-C and CHD risk. A slightly greater risk reduction in studies of CHD events, compared with predicted effects based on lipid changes alone (Figure 3), is consistent with potential additional benefits of PUFA on other nonlipid pathways of risk such as insulin resistance [16],[17] and systemic inflammation [18]–[20]. Indeed, the impact of these additional benefits may be underestimated—the inevitable noncompliance in long-term dietary trials would attenuate true benefits, suggesting that the 10% risk reduction for a 5%E increase in PUFA in the present analysis may underestimate the full effects. Additionally, our analysis of heterogeneity indicates that longer-term trials showed greater benefits, suggesting that benefits of increasing PUFA consumption accrue over time. 10.1371/journal.pmed.1000252.g003 Figure 3 Effects on CHD risk of consuming PUFA, carbohydrate, or MUFA in place of SFA. Predicted effects are based on changes in the TC∶HDL-C ratio in short-term trials (e.g., each 5%E of PUFA replacing SFA lowers TC∶HDL-C ratio by 0.16) [11] coupled with observed associations between the TC∶HDL-C ratio and CHD outcomes in middle-aged adults (each 1 unit lower TC∶HDL-C is associated with 44% lower risk of CHD) [15]. Evidence for effects of dietary changes on actual CHD events comes from the present meta-analysis of eight RCTs for PUFA replacing SFA and from the Women's Health Initiative RCT for carbohydrate replacing SFA (n = 48,835, ∼3%E reduction in SFA over 8 years) [39]. Evidence for observed relationships of usual dietary habits with CHD events comes from a pooled analysis of 11 prospective cohort studies [38]. When all trials were pooled, CHD risk was reduced by 24% for each 1 mmol/l reduction in TC (95% CI 7%–38%). This finding is consistent with results of observational studies of usual TC levels and CHD risk. In a pooled analysis from 61 prospective cohort studies including nearly 900,000 adults, each 1 mmol/l lower TC was associated with 28% lower risk of CHD death in adults aged 60–69 (RR = 0.72, 95% CI 0.69–0.74) and 42% lower risk of CHD death in adults aged 50–59 (RR = 0.58, 95% CI 0.56–0.61) [15], the ranges of ages included in the present trials. A comparison of our findings to those of long-term prospective observational studies of PUFA consumption is also informative. The most robust evidence to date comes from a recent report of pooled individual-level data from 11 cohort studies in America, Europe, and Israel, including 344,696 adults and 5,249 CHD events [38]. Each 5%E of greater PUFA consumption, as a replacement for SFA, was associated with 13% lower risk of CHD (RR = 0.87, 95% CI 0.77–0.97) (Figure 3). Our finding in RCTs of 10% lower risk of CHD for each 5%E of greater PUFA consumption, as a replacement for SFA, strongly supports both the causality and magnitude of these observational findings. Because each of the RCTs in this meta-analysis tested the effects of consuming PUFA in place of SFA, the present findings cannot distinguish between potentially distinct benefits of increasing PUFA versus decreasing SFA. Thus, the present evidence alone is insufficient to conclude that increasing PUFA in place of any other nutrient will reduce CHD events. Notably, this evidence is similarly insufficient to conclude that decreasing SFA in place of any other nutrient will reduce CHD events. However, our findings indicate that a strategy of replacing SFA with PUFA is likely to reduce the occurrence of CHD. Other lines of evidence—in particular, findings from RCTs of lipid risk factors and prospective cohort studies of CHD events—can provide insights into whether benefits may be more strongly related to reduced SFA, increased PUFA, or both. Based on either the predicted effects on TC∶HDL-C, the results of a large RCT [39], or a pooled analysis of 11 prospective cohort studies [38], replacement of SFA with carbohydrate does not lower CHD risk (Figure 3). Evidence for CHD effects of replacing SFA with monounsaturated fatty acids (MUFA) is mixed (Figure 3); randomized trials have not tested the effects of replacing SFA with MUFA. Thus, the evidence is most consistent and robust for CHD benefits when SFA is replaced with PUFA, rather than with MUFA or carbohydrate, suggesting that lower risk may be more strongly related to increased PUFA rather than decreased SFA consumption. Recent ecological studies across nations over time also support this contention, with changes in population CHD mortality being most strongly related to increased consumption of vegetable oils that contained PUFA, particularly the n-3 PUFA alpha-linolenic acid, rather than decreases in animal fats or increases in overall vegetable consumption [40]. Further studies are needed to evaluate the role of MUFA or protein as a replacement for other macronutrients on risk of CHD. The eight trials in this meta-analysis were performed and reported with a relatively regular distribution over nearly three decades between 1968 and 1992. This broad time span could increase generalizability, and there is likely little reason to believe that the biologic effects of PUFA have changed in recent years. The use of random-effects meta-analysis allowed the pooling and estimation of overall variance of different trials that may also each be estimating a different “true” effect. All of these RCTs had blinded endpoint ascertainment that would limit the magnitude of potential differential (biased) assignment of types of events or causes of death. Many of the identified randomized trials in our meta-analysis had important design limitations (Table 1). For example, some trials provided all or most meals, increasing compliance but perhaps limiting generalizability to effects of dietary recommendations alone; whereas other trials relied only on dietary advice, increasing generalizability to dietary recommendations but likely underestimating efficacy due to noncompliance. Several of these trials were not double-blind, raising the possibility of differential classification of endpoints by the investigators that could overestimate benefits of the intervention. One trial used a cluster-randomization cross-over design that intervened on sites rather than individuals; and two trials used open enrollment that allowed participants to both drop-in and drop-out during the trial. The methods for estimating and reporting PUFA and SFA consumption in each trial varied, which could cause errors in our estimation of the quantitative benefit per %E replacement. One of the trials also provided, in addition to the main advice to consume soybean oil, sardines to the intervention group [3], so that observed benefits may be at least partly related to marine omega-3 PUFA rather than total PUFA consumption. Several of the trials specified use of vegetable oils containing, in addition to omega-6 PUFA, small amounts of the omega-3 PUFA alpha-linolenic acid [2]–[5],[8], although additional benefits of this plant-derived omega-3, compared with seafood-derived omega-3, are not yet clearly established [41]. Given these limitations of each individual trial, the quantitative pooled risk estimate should be interpreted with some caution. Nevertheless, this is the best current worldwide evidence from RCTs for effects on CHD events of replacing SFA with PUFA, and, as discussed above, the pooled risk estimate from this meta-analysis (10% lower risk per 5%E greater PUFA) is well within the range of estimated benefits from randomized controlled feeding trials of changes in lipid levels (9% lower risk per 5%E greater PUFA) and prospective observational studies of clinical CHD events (13% lower risk per 5%E greater PUFA). The consistency of the findings across these different lines of evidence provides substantial confidence in both the qualitative benefits and also a fairly narrow range of quantitative uncertainty. As in any meta-analysis, publication bias is a potential limitation. It seems unlikely that large dietary clinical trials would have been performed and not reported without any knowledge of the community of experts, and if smaller trials were performed and unpublished, their addition would be unlikely to substantially alter the pooled risk estimate given the numbers of subjects and events currently included. Additionally, our direct contact with experts minimized the possibility of missing unpublished studies. The findings of this meta-analysis cannot be extrapolated to effects of replacing SFA with carbohydrate or MUFA (Figure 3), which were not evaluated in the present trials. Results should also not be extrapolated to effects of increasing PUFA as replacement for carbohydrate, although based on changes in TC∶HDL-C in feeding studies [11], and observed relationships with clinical events in cohort studies [38],[42], one would predict CHD benefit from such replacement. Future trials should investigate these other dietary interventions, in particular increasing PUFA consumption as a replacement for carbohydrate and also MUFA. This current meta-analysis of RCTs of clinical CHD events, together with consistent findings from both prospective cohort studies of clinical CHD events and RCTs of intermediate risk factors, provides strong concordant evidence that consumption of PUFA, in place of SFA, lowers CHD risk. Our findings have several immediate implications. First, our results, together with data from other research paradigms discussed above, indicate that evidence-based population- and individual-level recommendations to reduce SFA consumption should specify the importance of replacement with PUFA. Second, because many of these trials used vegetable oils containing small amounts of plant-derived n-3 PUFA in addition to omega-6 PUFA, our findings as well as those of ecologic studies [40] would support focus on n-3 PUFA-containing vegetable oils, such as soybean or canola, to increase population PUFA intake. For example, daily consumption of 20 g soybean oil or 30 g canola oil, as an isocaloric replacement for other macronutrients, would increase PUFA consumption by ∼5%E on a 2000 kcal/d diet [43]. Third, our findings demonstrate reductions in CHD events, and no evidence for increased risk, in long-term trials utilizing PUFA consumption at very high levels (mean = 14.9%E, range 8.0%E –20.7%E). This suggests that current recommendations for an upper limit of PUFA consumption at 10%E [12]–[14] need to be revisited, particularly as PUFA appears to be the primary evidence-based replacement for SFA. Finally, whereas on a population-level even a small shift from SFA to PUFA consumption would produce meaningful reductions in CHD risk, the relatively modest magnitude of plausible benefit (∼10% lower risk for 5%E replacement) indicates a need for substantial policy focus on other dietary risk factors for CHD [44], in particular high consumption of salt and low consumption of seafood, whole grains, fruits, and vegetables. Supporting Information Figure S1 Funnel plot of the log-relative risks (beta) versus their standard error (s.e. of beta). (0.08 MB TIF) Click here for additional data file. Text S1 PRISMA statement. (0.08 MB DOC) Click here for additional data file. Text S2 Protocol. (0.09 MB DOC) Click here for additional data file. Table S1 List of excluded studies. (0.14 MB DOC) Click here for additional data file.
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              Fatty acid profiles of 80 vegetable oils with regard to their nutritional potential

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                Author and article information

                Journal
                Magnetic Resonance in Medicine
                Magn. Reson. Med.
                Wiley
                07403194
                August 2016
                August 2016
                November 03 2015
                : 76
                : 2
                : 510-518
                Affiliations
                [1 ]Laboratory of Imaging Biomarkers, Center of Research on Inflammation; UMR1149 INSERM-University Paris Diderot; Sorbonne Paris Cité Paris France
                [2 ]BHF Centre of Excellence, Division of Imaging Sciences and Biomedical Engineering; King's College London; King's Health Partners, St. Thomas' Hospital London United Kingdom
                [3 ]Department of Radiology; Beaujon University Hospital Paris Nord; Clichy France
                [4 ]Matière et Systèmes Complexes; UMR 7057 CNRS-University Paris Diderot; Sorbonne Paris Cité Paris France
                [5 ]Department of HPB and liver transplantation; Beaujon University Hospital Paris Nord; Clichy France
                [6 ]Department of Pathology; Beaujon University Hospital Paris Nord; Clichy France
                Article
                10.1002/mrm.25895
                26527483
                ae8b601f-ddd5-4177-93b5-f24d6ad5d150
                © 2015

                http://doi.wiley.com/10.1002/tdm_license_1.1

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