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. Author manuscript; available in PMC: 2019 Aug 21.
Published in final edited form as: J Am Coll Cardiol. 2018 Aug 21;72(8):914–926. doi: 10.1016/j.jacc.2018.02.085

Cardiovascular Disease Prevention by Diet Modification: JACC Health Promotion Series

Edward Yu 1,2, Vasanti S Malik 1, Frank B Hu 1,2,3
PMCID: PMC6100800  NIHMSID: NIHMS1500474  PMID: 30115231

Abstract

Reduction in excess calories and improvement in dietary composition may prevent many primary and secondary cardiovascular events. Current guidelines recommend diets high in fruits, vegetables, whole grains, nuts, and legumes; moderate in low-fat dairy and seafood; and low in processed meats, sugar-sweetened beverages, refined grains, and sodium. Supplementation can be useful for some people but cannot replace a good diet. Factors that influence individuals to consume a low-quality diet are myriad and include lack of knowledge, lack of availability, high cost, time scarcity, social and cultural norms, marketing of poor quality foods, and palatability. Governments should focus on cardiovascular disease as a global threat and enact policies that will reach all levels of society and create a food environment wherein healthy foods are accessible, affordable, and desirable. Health professionals should be proficient in basic nutritional knowledge to promote a sustainable pattern of healthful eating for cardiovascular disease prevention for both healthy individuals and those at higher risk

Keywords: Diet, Risk factors, Prevention, Epidemiology, Health Promotion

CONDENSED ABSTRACT:

Health professionals should emphasize the importance of reducing excess calories and eating diets high in fruits, vegetables, whole grains, nuts, and legumes; moderate in low-fat dairy and seafood; and low in processed meats, sugar-sweetened beverages, refined grains, and sodium. Knowledge of healthfulness of food and beverage groups is instrumental to promote healthy eating. Behavioral change begins with small steps, such as substituting whole grains for refined grains or water for sugar-sweetened beverages. Policies are needed to create a food environment wherein healthy foods are accessible, affordable, and desirable.

Introduction

Behavior modification is a key strategy that may prevent a large number of primary and secondary cardiovascular events (1). Suboptimal diet is responsible for an estimated 1 in 5 premature deaths globally from 1990–2016 (2).

Observational study of human diet and health outcomes are challenging due to difficulties in measuring dietary intakes (3) and potential problems with generalizability and confounding (4). While randomized trials provide stronger potential for causal inference, they typically have small sample sizes, short durations of follow-up, noncompliance, high attrition rates, and ethical constraints (5). Thus, current dietary recommendations are based on a combination of human observational and intervention trial evidence supplemented by findings from mechanistic studies (6).

In the present review, we first summarize the current state of knowledge regarding various food groups and nutrients. Subsequent sections explore factors driving individual food choice, where preventive action can be implemented, and what potential roadblocks may hinder progress.

PATHOPHYSIOLOGICAL EFFECTS OF DIETARY COMPONENTS

The Central Illustration demonstrates the prevention of cardiovascular disease and disease risk factors through a healthy eating pattern. Current evidence suggests that the impact of dietary composition is relatively consistent for primordial, primary, and secondary prevention of cardiovascular disease (CVD) with certain dietary factors that reduce CVD incidence also being important for secondary prevention among myocardial infarction (MI) survivors.

Central Illustration: Flow diagram of the development of cardiovascular disease and possible prevention by a healthy diet.

Central Illustration:

Avoiding excess calories is an integral part of halting the development of cardiovascular disease risk factors (i.e. primordial prevention). Unfavorable eating patterns are driven by a variety of biological, social, economic, and psychological factors , and a robust intervention from all levels of society may steer populations toward a healthier diet and prevent disease progression. Diet and other lifestyle changes remain crucial steps in primary and secondary prevention of cardiovascular disease, although the relative importance of medication and clinical procedures increases over time with disease progression. Abbreviations: AHEI, Alternative Healthy Food Index; CHD, coronary heart disease; CI, confidence interval; CVD, cardiovascular disease; DASH, Dietary Approaches to Stop Hypertension; MedDiet, Mediterranean Diet; RR, risk ratio; SSB, sugar sweetened beverage.

Excess Caloric Intake

Healthy eating is based on maintaining caloric balance. A large body of literature supports calorie restriction for cardiometabolic benefit, specifically for improvements in insulin sensitivity, blood glucose, and inflammation (7). Chronic positive energy balance leads to overweight and obesity, the details of which are discussed in a separate article in this series. For most people, significant and sustained weight loss through dieting is extremely difficult, and the majority of weight loss trials feature high degrees of dropout and noncompliance due to the difficulty of long-term caloric restriction (8). Emerging evidence suggests that dietary composition and overall diet quality are important for minimizing overconsumption, and that low-carbohydrate and Mediterranean diets are superior to low-fat diets in maintaining weight loss (9). Some, but not all trials that examine macronutrient composition for weight loss reported greater long-term benefit for individuals consuming higher amounts of protein and fat compared to those who consumed higher amounts of carbohydrates (1012).

Foods and Food Groups

Figure 1 shows the summary estimates from various meta-analyses of key individual foods and food groups, and dietary patterns with CVD. The failure of most supplementation trials to detect significant reductions in risk among healthy populations (13) has led to dietary recommendations primarily based on eating whole food items and maintaining high quality diets.

Figure 1: Summary of various meta-analyses for the associations of key foods and food groups, and dietary patterns with incident cardiovascular disease.

Figure 1:

High amounts of processed meat, SSB, and refined grain consumption are associated with greater CVD incidence; moderate coffee and alcohol intake, and high fruit/vegetable, dairy (low-fat), whole grain, fish, and nut intake are associated with lower incidence. High adherence to Mediterranean, DASH, AHEI, and Prudent dietary patterns are significantly predictive of lower CVD incidence. Abbreviations: AHEI, Alternative Healthy Food Index; CHD, coronary heart disease; CI, confidence interval; CVD, cardiovascular disease; DASH, Dietary Approaches to Stop Hypertension; MedDiet, Mediterranean Diet; RR, risk ratio; SSB, sugar sweetened beverage.

Intake of total fruits and vegetables has been inversely associated with CVD risk (14). However, benefits for subgroups have been less studied, and may vary considerably. Various phytochemicals and micronutrients such as folate, potassium, fiber, and flavonoids found in fruits and vegetables are hypothesized to be responsible for the observed benefits (15). Potatoes have been viewed with skepticism due to their high starch content; higher potato intake, especially from French fries, has been associated with greater risk of hypertension, type 2 diabetes (T2D), and CHD risk (1618).

Whole grain intake is associated with a substantially lower risk of CVD whereas refined grain intake is suggestive of an increased but nonsignificant association (19). The bran and germ layers, present in whole grains but removed from refined grains, are rich in fiber, lignans, micronutrients, fatty acids, and other phytonutrients (20). Depletion of these nutrients during the milling process partially explains why whole grain consumption is generally related to higher satiety and a lower glycemic response compared with refined grains (21).

Marine fish is rich in long-chain omega-3 fatty acids, which are thought to reduce arrhythmias, thrombosis, inflammation, blood pressure, as well as favorably modify the lipid profile (22). A meta-analysis suggests that a 15g/d increment in fish intake is associated with a HR = 0.96 (95% CI = 0.90, 0.98) for CHD mortality (23).

Nuts and legumes are beneficial through their high unsaturated fat, fiber, micronutrient, and phytochemical content (24). A meta-analysis of 25 observational studies found that a 4 serving/week increase in nut intake was associated with an HR = 0.76 (95% CI = 0.69, 0.84) for fatal CHD and HR = 0.78 (95% CI = 0.67, 0.92) for nonfatal CHD (24). Small intervention studies have reported lower total cholesterol, LDL-c, ApoB, and triglycerides among those randomized to consuming tree nuts compared to the control arms (25).

Dairy products have shown null or weakly inverse associations with CVD. For example, fermented dairy (i.e. sour milk products, cheese, yogurt) showed a HR per 20g/d = 0.98 (95% CI = 0.97–0.99) (26) with similar associations observed across different dairy products. Similar associations have also been observed for total dairy and T2D (HR per 200g/d = 0.97, 95% CI = 0.95, 1.00), and yogurt (HR per 80g/d = 0.86, 95% CI = 0.83, 0.90) (27). Potential benefits of fermented dairy may be due to its probiotics contents (28).

Intake of processed meat (i.e., hamburgers, hot dogs, deli meats) has been shown to increase the risk of CVD in a robust linear fashion (29,30). Higher consumption of unprocessed red meat has also been associated with increased risk of CVD mortality (29). Replacing processed and unprocessed red meat with other sources of protein such as fish, poultry, and nuts was associated with lower incidence of coronary heart disease (31). Low carbohydrate diets high in animal protein and fat were associated with higher risk of total and cardiovascular death among MI survivors (32). Important bioactive molecules in red meat include heme iron, sodium, nitrates, and L-carnitine that may lead to significant elevations in blood pressure, worsening oxidative stress, greater lipid peroxidation, and unfavorable alterations of the gut microbiome (33,34).

Beverages

Alcohol is related to CVD risk in a U-shaped relationship, with both abstainers and heavy drinkers having an increased risk compared to moderate drinkers (35). The exact nadir of risk differs according to age, sex, ethnicity, and baseline disease (36), but the consistent observation is that individuals who consume 1–2 drinks a day have the lowest risk (37). Moderate alcohol intake has been shown to increase HDL-c, apolipoprotein A1, adiponectin, and decrease fibrinogen levels (38,39).

Higher consumption of sugar-sweetened beverages has been associated with risk of CVD in a dose-dependent relationship (40). This association is partially mediated by an increase in body weight; high intake of liquid calories does not seem to reduce later intake of solid foods (41). Independent of weight change, intake of SSBs increase postprandial blood glucose and insulin concentrations through a high glycemic load, as well as conferring adverse effects on fat deposition, lipid metabolism, blood pressure, insulin sensitivity, and lipogenesis (42).

Regular consumption of coffee has been consistently associated with lower risk of CVD, with the greatest risk reduction occurring at around 3–5 cups per day conferring an 11% lower risk (43). Biological mechanisms for the cardioprotective effects of moderate coffee consumption include a high concentration of chlorogenic acid, micronutrients, lignans, and phytochemicals. Short term trials of coffee report higher insulin sensitivity and a favorable inflammatory marker profile, but excess intake (>8 cups/d) may lead to acute elevations in blood pressure (44).

Tea has likewise been reported to be inversely associated with CVD incidence (45). Tea flavonoids, specifically flavonols, have received considerable attention and are themselves independently associated with reduced CVD risk (46).

Dietary Patterns and Diet Quality

Dietary patterns and quality are the most comprehensive metrics of assessing eating habits and include indices based on a priori scoring, such as the Alternative Mediterranean diet score (aMED), Alternative Healthy Food Index (AHEI), and Dietary Approaches to Stop Hypertension (DASH) diet score, as well as exploratory methods including principal component analysis and cluster analysis (47). Holistic evaluation of the diet is useful because it captures potential food and nutrient interactions that studies of single nutritional items cannot (48).

Individual diet indices differ in their components and weighting, but most emphasize high intake of fruits and vegetables, whole grains, nuts; moderate intake of low/nonfat dairy and alcohol; and low intake of sodium, processed meats, added sugar, and saturated fat (49). In the Women’s Health Initiative, high HEI, AHEI, aMED, and DASH scores were consistently associated with around a 20% reduction in CVD mortality (50). Sotos-Prieto et al. reported that improvement in these scores was also associated with lower risk of total and CVD mortality in two large cohorts (51,52). Similar findings have been observed among MI survivors. Li et al, found that a greater increase in the AHEI score from pre- to post-MI was significantly associated with lower all-cause and cardiovascular mortality (53) and Lopez-Garcia et al. found that adherence to a Mediterranean-style dietary pattern was associated with lower all-cause mortality among individuals with CVD (54).

Principal component and factor analyses have generally identified two dietary patterns that explain most of the variation in population-level eating habits: prudent and Western. Prudent diets are rich in fruits, vegetables, legumes, whole grains, fish, and poultry, whereas Western diets include high amounts of processed meat, French fries, desserts, sugar sweetened beverages, red meat, and high-fat dairy (55). A meta-analysis of 22 cohort studies found that those in the highest category of adherence to a prudent diet had a 31% lower risk of CVD compared to those with the lowest adherence (56), whereas a Western dietary pattern was associated with a 14% increase in risk (56). The consistency of findings from cohort studies across many countries for various dietary factors and indices and similar findings from intervention trials support the causal role of a high quality diet in CVD prevention (57,58).

Carbohydrates

Both quality and quantity of carbohydrates are important in a healthy eating pattern. Diets high in glycemic index and glycemic load (metrics that rate foods based on magnitude of postprandial glucose level) have been associated with higher risk of CHD, whereas diets low in glycemic index or load have been inversely associated with CHD (59). In the Nurses’ Health Study and Health Professionals Follow-Up Study, a greater adherence to a low carbohydrate diet with higher amounts of plant-based fats and protein was associated lower all-cause and cardiovascular mortality among generally healthy individuals (60) and among MI survivors (32). However, greater adherence to a low carbohydrate diet high in animal sources of fat and protein was associated with higher all-cause and cardiovascular mortality among healthy individuals (60).

Added sugars such as sucrose and high fructose corn syrup derived from industrial processes have been associated with a significant increase in CVD risk (61), with the greatest source and majority of evidence originating from SSBs (includes soda, flavored fruit juices, sports drinks, and energy drinks), which accounts for 6.9% of daily calories in the US (62). Higher consumption of added sugars appears to increase risk of CVD independent of body weight or other dietary components (63), likely through lowered HDL-c (64), increased plasma triglyceride concentration (65), and higher blood pressure (66).

Dietary fiber has been consistently demonstrated to lower risk of CVD and improve cardiovascular risk factors in both observational (67) and dietary intervention studies (68,69). In a meta-analysis of 22 cohorts, a 7g/d increase in fiber intake was associated with a 9% decrease in CHD incidence (67). Intake of fiber, particularly cereal fiber has also been shown to reduce all-cause mortality among MI survivors, with a 27% (HR 0.73, 95% CI: 0.58, 0.91) reduction in risk of death in the highest compared to lowest quintile of cereal fiber intake (70). It is thought that the cardioprotective action of fiber operates through decreased LDL-c, decreased serum triglycerides, blunted postprandial glucose response (71), and changes in bile acid metabolism (72).

Dietary Fat

Of the three primary types of dietary fat—trans fatty acids, saturated fatty acids, and unsaturated (includes mono- and polyunsaturated fats) fatty acids—trans fatty acids have been most strongly associated with adverse cardiovascular outcomes (73), and its ban in the U.S. is one of the greatest success stories in public health, the details of which are discussed later in the review. Among the other types of fat, saturated fatty acids have received the most controversy. Higher intake of saturated fat has been found to be either harmful or neutral for CVD risk in most meta-analyses (74). One explanation for the inconsistent findings is that studies that most observational studies did not specify comparison or replacement macronutrient for saturated fat, , leaving carbohydrates (primarily from refined grains and added sugar) as the default comparison macronutrient.

Analyses that employed substitution models reported that substituting either carbohydrates or saturated fats with unsaturated fats was associated with lower risk of CVD, with polyunsaturated fat showing a consistently larger magnitude of benefit (75). Supplementation with long-chain omega-3 fatty acids, a type of polyunsaturated fat derived primarily from fish oil, has shown mixed results (76,77), and the potential benefits of omega-3 fatty acids on reductions in sudden cardiac death remains to be confirmed. Long-chain omega-3 fatty acids have been shown to maintain cell membrane fluidity, reduce blood viscosity and clotting tendency, and promote the formation of anti-inflammatory mediators (78,79).

FACTORS INFLUENCING FOOD CHOICE

Despite the immeasurable gains that researchers have made in understanding what constitutes a healthy diet, less attention has been given to understanding why people eat (or don’t eat) a healthy diet. Eating habits are forged over a lifetime and are influenced by a multitude of factors from all levels of society including biological, economic, physical, social, and psychological determinants (80). The assumption that most people would replace unhealthy dietary components in light of new scientific evidence is overly optimistic (80,81). Well-known randomized trials of diet, such as the Women’s Health Initiative (WHI), have not been successful in achieving target macronutrient compositions or sustaining them after 6 months despite targeted behavioral intervention and in the case of WHI, unrealistic goals for low fat intake (82,83). In contrast, the PREDIMED trial, which evaluated the effects of a Mediterranean diet vs. a low-fat control diet, achieved and sustained intervention goals over 4 years of follow-up (84), largely because olive oil and nuts were provided to participants.

Lack of nutrition knowledge has been suggested as a contributor to poor diet (85), particularly among low income or minority populations (86,87), and in low income countries (88,89), where access to education is limited. However, most individuals in high income countries appear to possess a reasonable level of nutritional knowledge, with elements such as fruits and vegetables being widely recognized as healthy and highly processed grain products, added sugar, and salt as unhealthy (90). In a large European study of 14,331 participants, lack of knowledge was not cited as a common barrier to healthy eating (91).

On the other hand, lack of availability of healthful foods has been identified as a potential driver of unhealthy eating. ‘Food deserts’ refer to areas with long distances to supermarkets and low access to fresh foods, while food swamps refer to areas with an abundance of unhealthy processed and fast foods (92,93). This simultaneous availability of cheap low-quality food and expensive or lack of availability of high-quality food can drive individuals to choose unhealthy eating options (94,95). These elements together create an obesogenic environment that can lead to excess adiposity and subsequent cardiometabolic disease (96).

Price is an important roadblock to better eating. Rao et al. reported in a recent metaanalysis that the healthiest diets cost approximately $1.50 a day, or about $550 more a year, than the unhealthiest diets defined by various dietary indices (97). Time scarcity has also been shown to promote poor food choice (98) and is a major factor in the decline of home cooking in recent decades (99). Eating out is a significant predictor of overconsumption, and lower micronutrient intake (100). Bernstein et al. suggest that affordable and healthy plant-based diets are achievable with proper knowledge and preparation time (101).

Palatability is an obvious but underappreciated determinant of diet. Human attraction to sweet and savory foods is rooted in evolutionary and anthropologic processes (102), a fact that food companies have exploited by adding large amounts of sugar and sodium to most processed products (103,104). A prominent example of this practice is with SSBs, where high amounts of added sugar coupled with the inability of liquid calories to trigger satiety may have contributed to the obesity epidemic and cardiometabolic risk in the United States (105107).

Branding and marketing are also major factors that influence both taste and choice. Advertising has long been known to affect taste, possibly by linking positive sensory thoughts with the target product (108). Regulations on food branding and restriction of advertising to children have also been proposed as ways to improve diet quality and reduce obesity (109,110).

Social determinants of food choice include influences of culture, friends/family, and community. Social norms have powerful influences on eating patterns, and that healthy food norms can result in healthier food choices (111). Sacks et al. reported that the number of support sessions attended was the strongest predictor of weight loss at 2 years (0.2 kg for every session attended) regardless of macronutrient composition (82). Recent analyses indicate that food choices tend to be shared among family members (112), and that alcohol drinking and snacking were the most “transmissible” eating patterns (113).

ROLE OF PREVENTIVE ACTION

Given the magnitude of the CVD burden in the US and globally and complexity of dietary risk factor modification, simultaneous prevention strategies and policies across multiple societal levels are needed to make a measurable impact on reducing prevalence rates. In contrast to clinical decision-making where the evidence base is dominated by randomized clinical trials and large cohort studies, there is a paucity of data evaluating preventive actions to improve diet. Thus, to gauge the effectiveness of prevention strategies we also consider different types of evidence such as natural experiments and simulation models and discuss actions that have great potential for benefit and scalability that represent important knowledge gaps.

Societal/A uthori tative

Nutrition and agricultural policies are powerful instruments for reducing CVD risk if they align with evidence-based dietary goals to improve diet quality. One example is nutrition labeling of industrially produced trans fats and legislation for removal of trans fats from the food supply, which was recently enacted in the US with the removal of trans fats from the FDA’s generally regarded as safe category. This action which will be implemented in 2018 is expected to reduce as many as 20,000 coronary events and 7,000 deaths from coronary causes each year in the United States (114).

Some governments are considering taxing select foods and beverages, particularly SSB’s, as a means to improve consumer choice and generate revenue. Whether these programs will have the desired effect is yet to be determined. Some studies have suggested that for such interventions to have an appreciable impact, tax increases of at least 10% are needed (115). In Mexico, a peso-per-liter (roughly $0.80 per liter) tax on sugar-sweetened beverages enacted in 2014 has resulted in an average reduction in sales of 7.6 % of taxed beverages two years after implementation. Households at the lowest socioeconomic level had the largest decreases in purchases of taxed beverages over this time and purchases of untaxed beverage increased 2.1% (116). To date, at least eight cities in the US have enacted an SSB tax along with a number of countries including Mexico, Chile, France, Norway, Finland, the United Kingdom and Hungary. Careful evaluation will be key in determining the effectiveness of these strategies on reducing intake of these beverages and subsequently on reducing prevalence of obesity and cardiometabolic disease.

Other pricing policies such as agricultural subsidies to increase accessibility and affordability of fruits, vegetables, legumes, nuts and whole grains should also be emphasized. In parts of the US, access to fruit and vegetables has been shown to differ by race and socioeconomic status (117). Amending the US farm bill, the primary agricultural policy tool in the US, could be an effective way to improve diet quality at the population level (118). In particular, this includes amending the Supplemental Nutrition Assistance Program, which provides US$75 billion per year in subsidies to 47 million US citizens that can be used for the purchase sugar-sweetened beverages and other foods and beverages that adversely affect health (119).

Government regulation of school lunch programs has the potential to improve diet quality of children on a large scale. In 2012 the nutrition standards of federally assisted meal programs were updated for the first time in 15 years, to reduce sodium, saturated fat and trans fats and increase fruits, vegetables and whole grains largely based on recommendations by the Institute of Medicine of the National Academies, as part of efforts to curb childhood obesity (120). Some of these nutrition standards including the sodium and whole grain requirements have been recently relaxed by the USDA due to concerns of perceived palatability and food wastage (121).

Regulations for labeling of calorie and nutrient content of foods—particularly saturated fat, trans fats, added sugar, and sodium levels—can guide consumers to make healthy and informed dietary choices. As part of the proposed revisions to the US Nutrition facts label, a line and % DV for added sugar will be included. Some countries have considered other strategies such as front-of-package labeling, which usually places a simple, clear label or symbol conveying essential nutrition information in a more prominent manner. For example, in the UK, a traffic light system on food packaging has been employed where high, medium and low levels of fat, saturated fat, sugar and salt are indicated by traffic light colors red, amber and green. Compared to nutrition facts panels, which consumers use to draw their own conclusions about how healthful a product is based on the nutrient content of foods, these systems would identify foods that benefit health to help consumers make healthy choices.

Displaying calorie information in menus at chain restaurants is another strategy the USDA is expected to implement in 2018. A systematic review and meta-analysis suggests that this strategy can be effective in reducing caloric intake (122). However, for greatest benefit, educational campaigns should precede or accompany food package and point-of-purchase nutrition labeling to raise awareness and help with interpretation among consumers.

Food marketing and advertising are able to create major shifts in food demand because marketing leads people to increase their consumption of advertised products (123). A growing body of evidence indicates that food marketing can influence the food preferences and consumption habits of children (124). However, evidence from systematic reviews is lacking, and few studies have evaluated the impact of advertising on energy intake or body weight. A systematic review of seven randomized trials aiming to assess the effect of television advertising on food intake of children from 4 to 12 years of age concluded that there is a positive association between television and energy intake, but this association is based on a limited number of trials lacking a solid ground of first-level evidence (125). In 2010, the WHO released a set of recommendations on the marketing of foods and nonalcoholic beverages high in fat, sugar, and salt to children in an effort to encourage healthy dietary choices and promote the maintenance of healthy weight (126). In France, marketing of foods high in fat, sugar, and salt is banned unless they are taxed and labeled with a health warning. At the same time, governments can institute zoning laws, if available, that limit the number of fast food restaurants in a given area.

Education/Comm unity

School-based programs and initiatives to improve diet by providing healthy school meals and healthier snack options in vending machines and cafeterias are effective strategies to improve diet quality in children. These strategies are likely to be more effective if reinforced through curriculum-based education about healthy diets and active lifestyles and efforts to engage parents and families. A recent systematic review including 115 school-based interventions concluded that moderately strong evidence supports the effectiveness of school-based interventions for preventing childhood obesity (127). Similar to the school setting, worksite-based interventions can overcome barriers to choosing a healthy lifestyle by providing resources and a socially supportive environment for change at a place where individuals spend much of their week and by offering programs at low or no cost. A meta-analysis of worksite-based physical activity programs in high-income countries showed significant positive improvements in body weight, cardiometabolic risk factors, physical activity and fitness, and diet quality as well as lower absenteeism and job stress (128). A systematic review of 17 studies in Europe focusing on promoting a healthy diet in the workplace found limited to moderate evidence of effectiveness for prevention of obesity and obesity-related conditions (129). Another systematic review of 16 studies mostly in Europe and North America found that diet-based worksite interventions of moderate methodological quality led to positive changes in fruits, vegetables, and total fat intake (130).

Physicians and other health-care providers should monitor the body weight of patients and be trained on how to measure waist circumference, which may be more informative than weight as a marker for cardiometabolic risk. Clinicians should provide suitable evidence-based advice about weight management (115) and refer individuals identified as high-risk for screening of metabolic risk factors. Evaluation of such actions is needed to address this evidence gap. Medical associations and nongovernmental organizations also have central roles in advocacy and can influence policy on issues related to health and the environment. For example, the American Heart Association released a scientific statement, calling for a reduction in intake of added sugar to improve health (131), which has become an integral part of the dialogue regarding regulation of sugar-sweetened beverages. Nutrition education in medical schools and continuing medical education programs can improve nutrition literacy and nutrition communication skills among health-care providers.

Individuals

Improvements in diet ultimately rest on individual behavioral change. Behavioral economics, the study of psychological influences on economical decision-making, has clear applications in eating habits via implementation of subconscious nudges that may enhance the effectiveness of nutritional policies (132). For example, displaying healthful foods more prominently in school cafeterias may draw more attention to them and thus may increase the purchase of these foods (132). Roberto and Kawachi suggested that the design of dietary interventions could be improved by altering default options, providing simple and meaningful nutrition information, carefully constructing and framing of public health messages and designing policies to minimize unintended consequences, such as compensation and substitution for unhealthy foods that were reduced with other equally unhealthy options (133). Combined with financial incentives to produce and purchase healthy foods and disincentives to produce and purchase unhealthy foods, ,regulation of food marketing and greater access to healthy foods help individuals create healthy environments in their homes and communities and make better food choices (134).

RECOMMENDATIONS AND CHALLENGES TO ACHIEVING HEALTHIER DIETS

Physicians, nurses, nutritionists, and community leaders are instrumental in improving diet quality. Basic nutritional skills include knowing: 1) what foods or beverages can be included in a healthy diet; 2) what it means for a food to be healthy; 3) where to access information on nutrition research. Additional nutritional skills may include: 4) how to read, interpret, and understand peer-reviewed nutrition literature; 5) pros and cons of supplementation; 6) information regarding fad diets and foods. Since nutritional research is dynamic and complex, it is unlikely for most healthcare professionals to keep abreast of the latest findings at all times. Thus, familiarity of well-established knowledge regarding which common food or beverages are healthy should be the starting point. Small changes are also meaningful. For example, consuming brown rice instead of white rice or choosing fruits or nuts instead of candy bars or potato chips as snacks are excellent first steps. Lastly, improved diet contributes to all stages of prevention, and health professionals should promote better eating, especially among healthy or young patients where no cardiovascular risk factors are apparent.

Achieving healthful eating is a major challenge with many anticipated roadblocks. Socioeconomic disparities has led to a widening gap in diet quality between rich and poor communities from 1999 to 2010 in the United States (135). Food insecurity is an important issue that low-income families often face where food choice is a luxury instead of a reality (136). Continued promotion of nutrition assistance programs and targeted policies for low-income women and children to improve diet quality will be important steps to help close the socioeconomic gap. Better meal offerings in schools are necessary to improve nutrition outcomes in low income families (137).

Pushback against regulation from the food and beverage industries continues to be an important issue. Consumers consistently cite ‘healthiness’ as a priority when buying food, often leading to the alignment of public health goals and the self-regulation of the food industry, as in the case of the elimination of trans fats from most foods before its government ban (138). However, as sugar-sweetened beverages move into the federal crosshairs, the beverage industry has begun to combat regulation with fierce lobbying and public relations campaigns despite clear support for both health and cost savings with the implementation of a penny-per-ounce tax (139). Nutrition labeling is another contentious issue where corporate resistance to highlighting calories, servings, and added sugar exemplifies the conflict between short-term profit and longterm health (140).

Advances in technology may facilitate dietary behavioral changes. Mobile phones are currently capable of scanning barcodes to produce nutritional information in an instant. Text messages encouraging healthier food choices have also been shown to be effective in intervention studies (141). Finally, camera, and web-based methods to assess diet may be more cost effective, easier to use, and less laborious (142).

SUMMARY AND FUTURE DIRECTIONS

Cardiovascular disease is a global health concern amenable to behavior modifications. Diet is a vital lifestyle component that affects cardiovascular risk through body weight and many other pathways. The large volume of nutritional literature produced in the last few decades emphasizes avoidance of excess caloric intake, greater consumption of fruits, vegetables, whole grains, fish, nuts, and legumes; moderate consumption of alcohol, coffee, and low-fat/fat free dairy; and lower consumption of processed meats, refined grains, sodium and sugar sweetened beverages. Most supplementation trials of individual vitamins or other nutrients among healthy persons do not produce the same magnitudes of risk reduction observed with consuming a high-quality diet. Thus, current preventive efforts should be focused on promotion of better overall eating habits with supplementation as a strategy for subgroups of individuals.

Various biological, economical, physical, social, and psychological factors influence food choices. Interventions targeting these factors can lead to meaningful improvements in long-term eating habits. Much of the improvement in diet quality observed in the US in recent years has been due to the phasing out of trans fats from the food supply, signifying that public policies arising from evidence-based approaches are instrumental in reducing CVD risk (135). Additional improvements in diet quality can be achieved from a combination of policy strategies across multiple levels including excise taxes on SSBs, economic incentives for the production of healthy foods, regulation of food marketing, healthy school and work environments and education campaigns. Health professionals and community leaders have a great responsibility to promote cardiovascular health and disease prevention but require a basic nutrition knowledge base. A concerted effort from all levels of society will be needed to fundamentally change the current food environment and the global food system.

Acknowledgement

This research is supported by NIH grants HL 60712 and DK46200. Edward Yu is supported by F31 DK114938.

ABBREVIATIONS

CHD

coronary heart disease

CI

confidence interval

CVD

cardiovascular disease

g/d

grams per day

HDL-c

high density lipoprotein cholesterol

HR

hazard ratio

LDL-c

low density lipoprotein cholesterol

MI

myocardial infarction

SSB

sugar sweetened beverage

Footnotes

Disclosures: None to report.

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