Hostname: page-component-cd9895bd7-dzt6s Total loading time: 0 Render date: 2024-12-23T18:15:24.772Z Has data issue: false hasContentIssue false

Diet quality improvement and 30-year population health and economic outcomes: a microsimulation study

Published online by Cambridge University Press:  13 January 2021

Patricia M Herman*
Affiliation:
RAND Corporation, PO Box 2138, 1776 Main Street, Santa Monica, CA90407-2138, USA
PhuongGiang Nguyen
Affiliation:
RAND Corporation, PO Box 2138, 1776 Main Street, Santa Monica, CA90407-2138, USA
Roland Sturm
Affiliation:
RAND Corporation, PO Box 2138, 1776 Main Street, Santa Monica, CA90407-2138, USA
*
*Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective:

Diets closer aligned with nutritional guidelines could lower the risk of several chronic conditions and improve economic outcomes, such as employment and healthcare costs. However, little is known about the range, order of magnitude and timing of these potential effects.

Design:

We used a microsimulation approach to predict US population changes over 30 years in health and economic outcomes that could result from a substantial (but not impossible) improvement in diet quality – an improvement from the third to the fifth quintile of US scores on the Alternate Healthy Eating Index, 2010 version.

Setting:

Risk ratios from the literature for diabetes, heart disease and stroke were used to modify the Future Adult Model (FAM) to simulate outcomes from a higher-quality diet. Model parameter uncertainty was assessed using bootstrap and sensitivity analysis examined the variation in published risk ratios.

Participants:

FAM simulates outcomes for the US adult population aged 25 and older.

Results:

Improved diet quality initially leads to very small changes in chronic disease prevalence, but these accumulate over time. If diets improved beginning in 2019, after 30 years diabetes prevalence could be reduced by 5·9 million cases (11·5 %), heart disease prevalence by 4·0 million cases (7·2 %) and stroke prevalence by 1·9 million cases (10·3 %). These reductions in disease prevalence would be accompanied that same year by fewer deaths (88 000) and healthcare cost savings of $144·0 billion (2019 USD).

Conclusions:

This microsimulation study suggests that improvements in diet are likely to improve health and economic population outcomes over time.

Type
Research Paper
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - ND
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives licence (http://creativecommons.org/licenses/by-nc-nd/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the original work is unaltered and is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use or in order to create a derivative work.
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of The Nutrition Society

Poor diet quality is a risk factor for multiple chronic conditions, including CVD, type 2 diabetes and some cancers(1). In 2017, the Global Burden of Disease Study attributed 11 million deaths among adults 25 or older worldwide to dietary risk factors(2). Dietary factors independent from overweight/obesity were believed to be responsible for 18 % of all deaths in North America and for 22 % of all deaths (and 49 % of deaths from CVD) in Europe(2,Reference Meier, Grafe and Senn3) . In the USA, dietary risks were the primary cause of death and third leading cause of morbidity in 2016(Reference Mokdad, Ballestros and Echko4).

Three conceptual approaches have been used to connect dietary factors to health: nutrients, individual foods or eating patterns (complete diets). Nutrients are components of foods that are essential for human health, but new compounds continue to be identified in foods and there can be synergistic interactions between nutrients(Reference Tapsell, Neale and Satija5). Even individual foods (or food groups) are not consumed in isolation but rather in various combinations over time, that is, an ‘eating pattern’. Dietary components of an eating pattern have interactive and cumulative relationships. Therefore, eating patterns are more predictive of overall health status and disease risk than individual foods or nutrients(1,Reference Reedy and Subar6,Reference Burggraf, Teuber and Brosig7) . Index-based measures of eating patterns, such as the Healthy Eating Index (HEI) and the Alternate Healthy Eating Index (AHEI), have been developed to summarise diet quality(Reference Chiuve, Fung and Rimm8,Reference Guenther, Kirkpatrick and Reedy9) . Diets of better quality (scoring higher on these indices) are reliably associated with significant reduction in the risk of all-cause mortality, CVD, cancer and type 2 diabetes(Reference Chiuve, Fung and Rimm8,Reference Schwingshackl, Bogensberger and Hoffmann10Reference Schwingshackl and Hoffmann12) .

Although health benefits from following dietary guidelines are established, quantifying the economic impacts of realistic dietary improvements has been more elusive, especially when compared with the substantial literature on the cost consequences of obesity, where the large number of studies has warranted several systematic reviews(Reference Tremmel, Gerdtham and Nilsson13Reference Kim and Basu15). A 2017 WHO report reviewed the studies published between 2000 and 2016 on economic costs associated with unhealthy diets and low physical activity(Reference Candari, Cylus and Nolte16). This report found evidence from multiple studies on the economic costs of inactivity, but only found a single US study that examined the relationship between diet and (healthcare) costs(Reference Daviglus, Liu and Pirzada17). That study only considered fruit/vegetable consumption (rather than multiple food groups or overall diet) and contrasted Medicare claims among older men by high or low fruit/vegetable intake level.

We identified several additional analyses not included in the WHO review. Scrafford et al. examined the impact of diet quality on CHD, stroke, diabetes and cancer using the HEI-2015, and these conditions plus Alzheimer’s disease and hip fractures using the Mediterranean diet score (MED)(Reference Scrafford, Bi and Multani18). The current study estimated annual (direct and indirect) cost savings of $16·7 billion or $31·5 billion (2017 USD) assuming a 20 % increase in diet quality as measured by the MED or HEI-2015, respectively. An improvement to achieve 80 % of maximum MED or HEI-2015 scores was estimated to save $88·2 billion or $55·1 billion annually, respectively. Abdullah et al. (Reference Abdullah, Jones and Jones19) made annual estimates of the direct and indirect economic impacts of a Mediterranean-style diet but only included impacts on CHD and stroke. They estimated savings of $1·0 billion to $62·8 billion (2014 USD), for ‘very-pessimistic’ through ‘ideal’ scenarios for diet improvement. Both studies were static macro-level calculations that combined estimates from the literature on prevalence of diet quality and of targeted chronic diseases in the population, impact of diet quality on health outcomes and healthcare costs associated with each health outcome.

The remaining studies used a microsimulation approach focused on CVD, the CVD-PREDICT model. The authors used estimates from the literature on the health impact of moving to an optimal intake of ten food groups to modify the incidence of CVD in the model. Model results were published for the US population as a whole(Reference Jardim, Mozaffarian and Abrahams-Gessel20), for the US Supplemental Nutrition Assistance Program population(Reference Mozaffarian, Liu and Sy21) and for Medicare and Medicaid participants(Reference Lee, Mozaffarian and Sy22). Annual healthcare cost savings from moving to an optimal intake of the ten food groups for the whole US population were estimated as $50·4 billion (2018 USD)(Reference Jardim, Mozaffarian and Abrahams-Gessel20).

This paper used a different dynamic simulation model, the Future Adult Model (FAM; aka the Future Americans Model). This model has less clinical detail than the CVD-PREDICT but addresses the impact of diet on more chronic diseases, provides more information on economic outcomes and predicts these health and economic outcomes over 30 years. We used this model to compare a baseline diet scenario against a hypothetical scenario where diet quality was improved, that is, a 2-quintile increase in the AHEI-2010(Reference Chiuve, Fung and Rimm8). This increase corresponds to a median score shift in the AHEI-2010 from 48·6 to 62·7 in women and from 52·2 to 67·6 in men. This hypothetical improvement in diet quality reduced the risk for chronic conditions based on estimates from systematic reviews, and those risk reductions were fed into the FAM to simulate individual life trajectories over 30 years. This approach more realistically reflects the dynamics of population health than static calculations where interventions immediately result in equilibrium outcomes. Improving a health behaviour cannot instantly change the prevalence of chronic disease or retroactively prevent deaths. Rather, it lowers the likely incidence of future events and mortality. The benefits of better diet, whether in terms of health or economic outcomes, will only accrue over time.

Methods

The current study integrates the impact from the literature on disease incidence from a hypothetical change in diet quality with the FAM microsimulation to determine the impact on health and economic outcomes in the US adult population over 30 years. The RAND Human Subjects Protection Committee has determined that this project does not involve human subjects.

The Future Adult Microsimulation Model

The FAM is a dynamic microsimulation model that simulates individual life trajectories for a hypothetical cohort of US adults 25 years of age and older. The primary engine of the FAM is a set of transition equations between health states and economic outcomes estimated from the Panel Study of Income Dynamics (PSID). These estimates primarily used PSID data from 2001 through 2015. The transition module ages individuals over time. The simulated transitions are in 2-year steps and at every step a new group of 25/26-year-olds are added through a replenishing module. The replenishing module synthetically generates new members to match observed correlations between variables in the PSID adjusted for predicted trends in population demographics from the census and behavioural changes based on the National Health Interview Survey and the National Health and Nutrition Examination Survey.

In the transition module risk factors, chronic diseases, functional limitations and economic outcomes change probabilistically over time via estimated transition equations based on what was seen in the PSID data over time. Other characteristics of the individual do not change over time (e.g., sex, race/ethnicity or parents’ education) or are deterministic (e.g., age, characteristics that are a consequence of age such as Medicare eligibility). At times, the presence of certain chronic diseases affects the incidence models for other chronic diseases. For example, the presence of heart disease, cancer, hypertension and/or diabetes in one period affects the incidence of stroke in the next period. Hypertension and/or diabetes in one period affects the incidence of heart disease in the next period, and the presence of diabetes in one period affects the incidence of hypertension in the next period. More details on the FAM, including information on its validation, are found in its Technical Documentation(23).

Medical expenditures depend on individual’s chronic conditions, functional limitations and socio-demographics and are based on data from the Medical Expenditures Panel Survey (http://meps.ahrq.gov/mepsweb/) and Medicare Current Beneficiary Survey. We assumed our ‘intervention’ (assuming everyone moves from average to high-quality diets) changed the probabilities of transitions into chronic disease states for all individuals of the same gender by the same proportion. This simplification was necessary as we have no basis from the literature to assign differential effects of diet quality by socio-demographic characteristics, except for distinguishing men and women.

Model outcomes

The FAM model produces estimated outcomes for several components of the PSID survey (general health status, activities of daily living, incidence of disease, employment and use of social programmes), plus healthcare costs and quality-adjusted life-years from Medical Expenditures Panel Survey and Medicare Current Beneficiary Survey, for every 2 years over 30 years. The prevalence of diagnosed chronic disease is based on questions of the format ‘has a doctor ever told you that you have:’ diabetes, heart disease (which includes CHD, angina, congestive heart failure), stroke or cancer (or malignant tumour, excluding skin cancer). The PSID also captures general health status (using five-point scale from 1 = poor to 5 = excellent), and whether a person is disabled (difficulty doing any of a list of activities of daily living or instrumental activities of daily living by yourself or living in a nursing home). Economic outcomes include total healthcare costs (whether paid by government, private insurance or patients out-of-pocket) from Medical Expenditures Panel Survey and Medicare Current Beneficiary Survey and from the PSID whether the individual was working for pay and using Social Security and other income support programmes.

Diet quality and its impact on health

Many studies have examined the impact of diet quality on chronic disease incidence and mortality using large epidemiological studies and a range of different measures of diet quality and health outcomes(Reference Schwingshackl, Bogensberger and Hoffmann10,Reference Onvani, Haghighatdoost and Surkan24) . The publications reporting relative risks (RR) or hazard ratios for disease incidence, rather than mortality, were the best fit for incorporating into the structure of the FAM. After reviewing studies included in a large systematic review of the impact of diet quality on health(Reference Schwingshackl, Bogensberger and Hoffmann10), we utilised diet quality/disease estimates from a high-quality study (eight out of nine on the Ottawa Quality Assessment Scale(Reference Schwingshackl and Hoffmann12,Reference Stang25) ) by Chiuve et al. (Reference Chiuve, Fung and Rimm8), to inform the diet quality/disease risk link in our analysis.

The Chiuve et al. study(Reference Chiuve, Fung and Rimm8) was based on the analysis of two large datasets (the Nurses’ Health Study for women, n 79 495; and the Health Professionals Study for men, n 41 029) and used the AHEI-2010(Reference Burggraf, Teuber and Brosig7). The AHEI-2010 is derived from recent (2010) evidence of foods and nutrients predictive of chronic disease risk. Scores on the AHEI-2010 range from 0 to 110 with intakes on eleven food components each adding 0–10 points to the score (Table 1). The Chiuve et al. study used a consistent methodology to calculate RR for men and women and for the incidence of four chronic diseases tracked in the FAM and known to be affected by diet quality: diabetes, heart disease, stroke and cancer. The RR were estimated from multivariate Cox proportional hazard models adjusted for: age, energy (kcal/d), smoking status, BMI, aspirin use, physical activity, vitamin E supplementation, family history of myocardial infarction and colon cancer, personal history of hypertension and hypercholesterolaemia (except for the cancer model), and in women, family history of breast cancer, menopausal status and use of hormone therapy. The multivariate-adjusted RR (with 95 % CI) for each quintile of diet quality compared with the first (lowest, reference) quintile are shown in Table 2.

Table 1 Scoring for the Alternate Healthy Eating Index, 2010

Source: Adapted from Table 1 in Chiuve et al. J Nutr 2012; 142: 1009–1018.

Table 2 Relative risk of chronic disease by quintile of the Alternate Healthy Eating Index, 2010, for men and women

Q, quintile; W, women; M, men; RR, relative risk.

Source for the estimates by quintile: Adapted from Table 3 in Chiuve et al. J Nutr 2012; 142: 1009–1018.

The ‘intervention’ we analysed was a hypothetical improvement in diet quality from the third quintile to the fifth quintile – a substantial, but not impossible improvement. Key model assumptions were that: (1) the third quintile represented average diet quality for the US population in the base case and (2) with the intervention diet quality improved to the fifth quintile and stayed there for the duration of the model. The RR for that improvement was calculated as the ratio of the RR for those quintiles, shown in the second-to-last column in Table 2.

Analysis

All FAM outcomes and total population were projected over 30 years assuming the intervention started in 2019. Medical costs were adjusted to 2019 USD using the medical component of the Consumer Price Index (United States Bureau of Labor Statistics). We adjusted for time preferences by discounting costs and quality-adjusted life-years at a constant rate of 3 %.

The parameters (transition probabilities) in the FAM were estimated from the PSID. To account for uncertainty in those estimates, we employed a non-parametric bootstrap approach. We resampled individuals from PSID, estimated parameters for this bootstrap sample and then simulated population outcomes. We used 100 bootstrap replications, and from these sd we calculated 95 % CI (means of the outcomes are assumed to be normally distributed).

We separately considered the sensitivity of our results to uncertainty in our intervention assumptions by estimating outcomes based on RR that were one se above and below those used in the base case (Table 2).

All results were calculated using the FAM, Version 202(23).

Results

Table 3 shows the results from the FAM for a 2-quintile improvement in diet quality in US adults 10 and 30 years after initiation (2019) and differences compared with the status quo. Reductions in the future prevalence of diabetes, heart disease and stroke would be substantial – but only over time, not immediately, from 5·0 to 7·5 % fewer cases in year 10 and from 7·2 to 11·5 % fewer cases in year 30. Reductions in the prevalence of all types of cancer were more modest: 1·2 % fewer cases in year 10 and 0·7 % fewer cases in year 30.

Table 3 Results from the Future Adult Model of a 2-quintile improvement in diet quality 10 and 30 years after initiation (2019) compared with the status quo

ADL, activities of daily living, that is, daily self-care activities; IADL, instrumental activities of daily living, that is, those activities that allow an individual to live independently in a community.

* Presence of any of these chronic diseases: diabetes, heart disease, stroke, cancer, lung disease or hypertension.

Presence of two or more of these six chronic diseases: diabetes, heart disease, stroke, cancer, lung disease or hypertension.

Improved diet quality would also result in fewer people rating their health as fair or poor, and fewer people with either one (morbidity) or two or more (co-morbidity) chronic diseases. Fewer people would have died and the population would have gained almost 230 million additional quality-adjusted life-years in year 30.

Although the reduced mortality means that more people are alive and would use medical care, total medical costs decrease with improved diet quality. Expressed in 2019 USD, medical expenditures would decrease by $66·9 billion in year 10 and $144·0 billion in year 30. These amounts represent reductions of 1·5 and 1·7 % of total healthcare expenditures in those years. Figure 1 shows how the reductions in medical expenditures increase over time. Other economic benefits include 710 000 more people working for pay, and 17 000 fewer Supplemental Social Security Income claims, 199 000 fewer people considered disabled and 180 000 fewer Disability Insurance claims in year 30. Because people will live longer, our simulations show that an improved diet would mean just over a million additional individuals in the USA receiving Social Security payments that year. Interactive graphic presentation of the health and economic impacts of our assumed diet quality intervention over time is available on this link:https://www.rand.org/pubs/tools/TL363.html.

Fig. 1 Annual reductions in healthcare expenditures from improved diet quality (2019 USD). , Absolute change ($); , relative change (%)

Table 4 shows the results of the sensitivity analysis examining the uncertainty in the impact of improved diet quality RR we obtained from the literature. Except for cancer, the reductions in prevalence were maintained even at one se below the RR estimates.

Table 4 Sensitivity analysis of the effect of a 2-quintile improvement in diet quality 10 and 30 years after initiation (2019) compared with the status quo

se, standard error of the mean relative risk; RR, relative risk.

Discussion

Improvements in diet quality can have a substantial impact on population health, as well as a variety of economic outcomes. Using microsimulation, the FAM captures the impact of an improvement in diet quality on the number of new cases of chronic disease over the course of 30 years. In general, this model demonstrates how an improved diet can lead to an ongoing accumulation of better health and economic outcomes for the future. However, the dynamics can be complicated for specific conditions. For example, the reduction in prevalence of all cancers is greater at year 10 than at year 30. This is because fewer people are dying of diabetes, heart disease and stroke, and they live long enough to get cancer. There is a similar trend in the prevalence of those considered disabled in year 10, which is less than in year 30 for the same reason, because individuals are projected to live longer. As the incidence of chronic disease is avoided, there are fewer and fewer deaths each year until about year 10. However, from then until year 30 the death rate remains roughly constant as people age and die from other causes.

The most significant impact from improved diet quality on chronic disease incidence occurs in diabetes and heart disease, almost 6 million and 4 million fewer cases, respectively, in year 30. However, in terms of reducing the proportion of new cases, it is stroke (10 % fewer cases) that is second to diabetes (almost 12 % fewer cases). Diet quality does have some impact on cancer incidence with almost 230 000 or 1 % fewer cases in year 30, but this impact is substantially smaller than what is seen for other chronic diseases. This is likely because diet quality mainly effects the incidence of colorectal cancer(Reference Grosso, Bella and Godos26), and despite colorectal cancer being the third most common type of cancer, it only constitutes about 8·3 % of all new cancer cases(27).

We estimated that the diet quality intervention would lower healthcare costs every year across the 30-year study timeline with annual savings in year 10 of $65·9 billion and $144·0 billion in year 30 (2019 USD). The Scrafford et al. study(Reference Scrafford, Bi and Multani18) estimated the impact of diet quality on healthcare costs associated with the same chronic diseases as the FAM (CHD, stroke, diabetes and cancer) using the HEI-2015 (very similar to the AHEI-2010) as their measure of diet quality. They estimated annual direct healthcare cost savings from a 20 % increase in the HEI-2015 (moving from an average score of 59·3 on a 0–100 scale to a score of 71·2) of $23·3 billion (2017 USD) and direct cost savings of $40·8 billion from an increase in the HEI-2015 to 80 % of its maximum value (a score of 80). For comparison, our ‘intervention’ moved diet quality as measured by the AHEI-2010 (range 0–110) from a median of 48·6 for women to 62·7 (29 % increase) and from 52·2 for men to 67·6 (30 % increase). An increase to 80 % of the maximum AHEI-2010 score would be an increase to 88 (0·8 × 110). Therefore, if we had followed their methodology of applying diet quality RR estimates to current prevalence, our healthcare cost savings estimates, which were based on diet quality score increases of 29 and 30 %, should land somewhere between the Scrafford et al. 20 and 80 % estimates. Instead, our year 4 and 6 estimates generally match theirs (after adjusting dollars to similar years using the medical care CPI) possibly indicating a more realistic timing for these outcomes.

The CVD-PREDICT microsimulation(Reference Jardim, Mozaffarian and Abrahams-Gessel20) assumed optimal intake of different food groups and estimated healthcare cost savings for the US population as a whole of $50·4 billion (2018 USD). This model used several risk factors and their change over time to predict CVD and has been validated in terms of CVD mortality(Reference Pandya, Sy and Cho28). The authors adjusted their model using RR estimates from the literature as to the impact of optimal intakes of each of ten food groups on mortality(Reference Micha, Peñalvo and Cudhea29). Then they added estimates from various sources of the healthcare costs associated with CVD disease states(Reference Jardim, Mozaffarian and Abrahams-Gessel20). Model estimates at 5 years were used for their annual healthcare cost savings estimate for the USA as a whole, and their number ($50·4 billion) is higher than what FAM predicted in year 5 (about $34 billion). There could be several reasons why the two models would produce different estimates. However, one likely reason is that the FAM analysis moved individuals from mid- to high-quality diets defined by what was has been seen regarding actual diet quality in large samples. In contrast, the Jardim et al. study moved individuals to optimal levels of all food groups, which may not be as attainable.

All simulation studies are inherently speculative and depend on a number of assumptions and inputs that influence results. An advantage of our approach is that we use an internally consistent and well-established model built on panel data from a nationally representative sample that included socio-demographics, health states (including chronic disease) and several personal and household economic indicators. Population-based healthcare costs by disease state and socio-demographics are also part of the FAM, and healthcare cost and other outcomes were predicted over 30 years. One main limitation of our study comes from our need to incorporate estimates from outside the model on the linkage between diet quality and the incidence of chronic disease. We were able to obtain these estimates from one high-quality study that used large sample sizes and consistent methodology to estimate RR for both men and women and across four chronic diseases. However, in using these estimates we had to accept any flaws in the methods including in the diet quality index used. Also, even though the authors used multivariate models that controlled for other chronic diseases, these epidemiology-based estimates were not designed to adjust incidence across a simulation model’s causal web of risk factors leading to later outcomes. For example, because the incidence of diabetes affects the incidence of heart disease in the model, it is possible that adjusting both the incidence of diabetes and heart disease for higher diet quality overstates its impact, but the true net effect is unknown.

The most important assumptions, however, were that we modelled a hypothetical improvement in diet quality that moves all adults up by two quintiles on the AHEI-2010, that is, going from the third quintile (median scores of 48·6 for women and 52·2 for men) to the fifth quintile (median scores of 62·7 for women and 67·6 for men) of diet quality and we assume this improvement to be maintained for 30 years. Thus, our results should be considered an estimate of the health and economic cost of poor diet quality. We do not address the intervention that could accomplish this improvement in diet quality nor its costs. This average intervention runs somewhat counter to the idea of microsimulation and an improved approach in the future would take into account differences in base case diet quality across the population. A shift from the bottom (first quintile) to the middle (third) quintile of diet quality, for example, could have slightly different implications than from the middle to the top (fifth quintile), and average diet quality is known to vary by socio-demographic status(Reference Hiza, Casavale and Guenther30).

Summary and conclusions

There are few studies that indicate the health and economic impacts of improved diet quality. The 2019 report by the Global Burden of Disease Collaborators continues to be based on food groups and individual diet components, even though they acknowledge that summing health outcome estimates across individual components, which tend to be correlated, is likely to exaggerate total effects(2). The Global Burden of Disease acknowledges that ‘use of dietary pattern as the main exposure could potentially address this problem’, but has not yet made this switch(31). Diet quality indexes such as the HEI and the AHEI have substantially improved the measurement and understanding of dietary patterns beyond the focus on single foods or individual nutrients(Reference Reedy and Subar6). Over the last decade, obesity has dominated news headlines, but diet quality has independent and potentially larger health effects(Reference Echouffo-Tcheugui and Ahima32). This paper used a microsimulation approach to assess the potential health and economic effects of improving diet quality over time. We found substantial reductions in the prevalence of diabetes, heart disease and stroke that increase over time as well as related reductions in associated healthcare costs.

Acknowledgements

Acknowledgements: We are grateful to Bryan Tysinger for maintaining the microsimulation software, Adrian Salas for executing the cloud computing runs and Pedro Nascimento de Lima for creating a visualisation programme to display results. Financial support: Funding for the current study was provided through a grant from Pharmavite LLC, a dietary supplements company. Pharmavite had no role in the design, analysis or writing of this article. The maintenance of the Future Adult Model at RAND is supported by NIH grant R01HD087257. Conflict of interest: None. Authorship: R.S. and P.M.H. designed the study and collaborated on the first draft. P.N. performed the bulk of the analysis under the supervision of R.S. and built the results tables. All authors read, edited and approved the final draft. Ethics of human subject participation: RAND’s Human Subjects Protection Committee ruled the current study as not qualifying as human subjects research.

References

U.S. Department of Health and Human Services and U.S. Department of Agriculture (2015) 2015–2020 Dietary Guidelines for Americans, 8th ed. Washington, DC: U.S. Department of Health and Human Services and U.S. Department of Agriculture.Google Scholar
Global Burden of Disease Diet Collaborators (2019) Health effects of dietary risks in 195 countries, 1990–2017: a systematic analysis for the Global Burden of Disease Study 2017. Lancet 393, 19581972.CrossRefGoogle Scholar
Meier, T, Grafe, K, Senn, F et al. (2019) Cardiovascular mortality attributable to dietary risk factors in 51 countries in the WHO European Region from 1990 to 2016: a systematic analysis of the Global Burden of Disease Study. Eur J Epidemiol 34, 3755.CrossRefGoogle ScholarPubMed
Mokdad, AH, Ballestros, K, Echko, M et al. (2018) The state of US health, 1990–2016: burden of diseases, injuries, and risk factors among US states. JAMA 319, 14441472.Google ScholarPubMed
Tapsell, LC, Neale, EP, Satija, A et al. (2016) Foods, nutrients, and dietary patterns: interconnections and implications for dietary guidelines. Adv Nutr 7, 445454.CrossRefGoogle ScholarPubMed
Reedy, J & Subar, AF (2018) 90th anniversary commentary: diet quality indexes in nutritional epidemiology inform dietary guidance and public health. J Nutr 148, 16951697.CrossRefGoogle ScholarPubMed
Burggraf, C, Teuber, R, Brosig, S et al. (2018) Review of a priori dietary quality indices in relation to their construction criteria. Nutr Rev 76, 747764.10.1093/nutrit/nuy027CrossRefGoogle ScholarPubMed
Chiuve, SE, Fung, TT, Rimm, EB et al. (2012) Alternative dietary indices both strongly predict risk of chronic disease. J Nutr 142, 10091018.10.3945/jn.111.157222CrossRefGoogle ScholarPubMed
Guenther, PM, Kirkpatrick, SI, Reedy, J et al. (2014) The Healthy Eating Index-2010 is a valid and reliable measure of diet quality according to the 2010 Dietary Guidelines for Americans. J Nutr 144, 399407.CrossRefGoogle Scholar
Schwingshackl, L, Bogensberger, B & Hoffmann, G (2018) Diet quality as assessed by the healthy eating index, alternate healthy eating index, dietary approaches to stop hypertension score, and health outcomes: an updated systematic review and meta-analysis of cohort studies. J Acad Nutr Diet 118, 74100 e111.CrossRefGoogle ScholarPubMed
Onvani, S, Haghighatdoost, F, Surkan, PJ et al. (2017) Adherence to the healthy eating index and alternative healthy eating index dietary patterns and mortality from all causes, cardiovascular disease and cancer: a meta-analysis of observational studies. J Hum Nutr Diet 30, 216226.10.1111/jhn.12415CrossRefGoogle Scholar
Schwingshackl, L & Hoffmann, G (2015) Diet quality as assessed by the healthy eating index, the alternate healthy eating index, the dietary approaches to stop hypertension score, and health outcomes: a systematic review and meta-analysis of cohort studies. J Acad Nutr Diet 115, 780800. e785.CrossRefGoogle ScholarPubMed
Tremmel, M, Gerdtham, UG, Nilsson, PM et al. (2017) Economic burden of obesity: a systematic literature review. Int J Environ Res Public Health 14, 435.CrossRefGoogle ScholarPubMed
Tsai, AG, Williamson, DF & Glick, HA (2011) Direct medical cost of overweight and obesity in the USA: a quantitative systematic review. Obes Rev: Offl J Int Assoc Study Obes 12, 5061.10.1111/j.1467-789X.2009.00708.xCrossRefGoogle ScholarPubMed
Kim, DD & Basu, A (2016) Estimating the medical care costs of obesity in the United States: systematic review, meta-analysis, and empirical analysis. Value Health 19, 602613.10.1016/j.jval.2016.02.008CrossRefGoogle ScholarPubMed
Candari, CJ, Cylus, J & Nolte, E (2017) Assessing the Economic Costs of Unhealthy Diets and Low Physical Activity: An Evidence Review and Proposed Framework. Health Policy Series no. 47. Copenhagen: WHO Regional Office for Europe.Google Scholar
Daviglus, ML, Liu, K, Pirzada, A et al. (2005) Relationship of fruit and vegetable consumption in middle-aged men to medicare expenditures in older age: the Chicago Western Electric Study. J Am Diet Assoc 105, 17351744.CrossRefGoogle ScholarPubMed
Scrafford, CG, Bi, X, Multani, JK et al. (2019) Health economic evaluation modeling shows potential health care cost savings with increased conformance with healthy dietary patterns among adults in the United States. J Acad Nutr Diet 119, 599616.CrossRefGoogle ScholarPubMed
Abdullah, MM, Jones, JP & Jones, PJ (2015) Economic benefits of the Mediterranean-style diet consumption in Canada and the United States. Food Nutr Res 59, 27541.10.3402/fnr.v59.27541CrossRefGoogle ScholarPubMed
Jardim, TV, Mozaffarian, D, Abrahams-Gessel, S et al. (2019) Cardiometabolic disease costs associated with suboptimal diet in the United States: a cost analysis based on a microsimulation model. PLoS Med 16, e1002981.10.1371/journal.pmed.1002981CrossRefGoogle ScholarPubMed
Mozaffarian, D, Liu, J, Sy, S et al. (2018) Cost-effectiveness of financial incentives and disincentives for improving food purchases and health through the US Supplemental Nutrition Assistance Program (SNAP): a microsimulation study. PLoS Med 15, e1002661.CrossRefGoogle ScholarPubMed
Lee, Y, Mozaffarian, D, Sy, S et al. (2019) Cost-effectiveness of financial incentives for improving diet and health through Medicare and Medicaid: a microsimulation study. PLoS Med 16, e1002761.10.1371/journal.pmed.1002761CrossRefGoogle ScholarPubMed
Roybal Center for Health Policy Simulation (2016) The Future Americans Model. https://roybalhealthpolicy.usc.edu/fam/ (accessed June 2020).Google Scholar
Onvani, S, Haghighatdoost, F, Surkan, P et al. (2017) Adherence to the healthy eating index and alternative healthy eating index dietary patterns and mortality from all causes, cardiovascular disease and cancer: a meta-analysis of observational studies. J Hum Nutr Diet 30, 216226.CrossRefGoogle Scholar
Stang, A (2010) Critical evaluation of the Newcastle-Ottawa scale for the assessment of the quality of nonrandomized studies in meta-analyses. Eur J Epidemiol 25, 603605.10.1007/s10654-010-9491-zCrossRefGoogle ScholarPubMed
Grosso, G, Bella, F, Godos, J et al. (2017) Possible role of diet in cancer: systematic review and multiple meta-analyses of dietary patterns, lifestyle factors, and cancer risk. Nutr Rev 75, 405419.CrossRefGoogle ScholarPubMed
American Cancer Society (2019) Cancer Facts & Figures 2019. Atlanta: American Cancer Society.Google Scholar
Pandya, A, Sy, S, Cho, S et al. (2017) Validation of a cardiovascular disease policy microsimulation model using both survival and receiver operating characteristic curves. Med Decis Making 37, 802814.10.1177/0272989X17706081CrossRefGoogle ScholarPubMed
Micha, R, Peñalvo, JL, Cudhea, F et al. (2017) Association between dietary factors and mortality from heart disease, stroke, and type 2 diabetes in the United States. JAMA 317, 912924.CrossRefGoogle ScholarPubMed
Hiza, HA, Casavale, KO, Guenther, PM et al. (2013) Diet quality of Americans differs by age, sex, race/ethnicity, income, and education level. J Acad Nutr Diet 113, 297306.10.1016/j.jand.2012.08.011CrossRefGoogle Scholar
Global Burden of Disease Risk Factors Collaborators (2016) Global, regional, and national comparative risk assessment of 79 behavioural, environmental and occupational, and metabolic risks or clusters of risks, 1990–2015: a systematic analysis for the Global Burden of Disease Study 2015. Lancet 388, 16591724.10.1016/S0140-6736(16)31679-8CrossRefGoogle Scholar
Echouffo-Tcheugui, JB & Ahima, RS (2019) Does diet quality or nutrient quantity contribute more to health? J Clin Investig 129, 39693970.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Scoring for the Alternate Healthy Eating Index, 2010

Figure 1

Table 2 Relative risk of chronic disease by quintile of the Alternate Healthy Eating Index, 2010, for men and women

Figure 2

Table 3 Results from the Future Adult Model of a 2-quintile improvement in diet quality 10 and 30 years after initiation (2019) compared with the status quo

Figure 3

Fig. 1 Annual reductions in healthcare expenditures from improved diet quality (2019 USD). , Absolute change ($); , relative change (%)

Figure 4

Table 4 Sensitivity analysis of the effect of a 2-quintile improvement in diet quality 10 and 30 years after initiation (2019) compared with the status quo