Hostname: page-component-586b7cd67f-rcrh6 Total loading time: 0 Render date: 2024-11-28T00:12:48.408Z Has data issue: false hasContentIssue false

Food choices to meet nutrient recommendations for the adult Brazilian population based on the linear programming approach

Published online by Cambridge University Press:  18 January 2018

Quenia dos Santos*
Affiliation:
Institute of Social Medicine, State University of Rio de Janeiro, Rio de Janeiro, RJ, Brazil Food Design and Consumer Behaviour Section, Department of Food Science, University of Copenhagen, Rolighedsvej 26, 1958 Frederiksberg C, Denmark
Rosely Sichieri
Affiliation:
Institute of Social Medicine, State University of Rio de Janeiro, Rio de Janeiro, RJ, Brazil
Nicole Darmon
Affiliation:
Markets, Organizations, Institutions and Stakeholders Strategies, Institut National de la Recherche Agronomique (INRA), Montpellier, France
Matthieu Maillot
Affiliation:
MS-Nutrition, Marseille, France
Eliseu Verly-Junior
Affiliation:
Institute of Social Medicine, State University of Rio de Janeiro, Rio de Janeiro, RJ, Brazil
*
* Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective

To identify optimal food choices that meet nutritional recommendations to reduce prevalence of inadequate nutrient intakes.

Design

Linear programming was used to obtain an optimized diet with sixty-eight foods with the least difference from the observed population mean dietary intake while meeting a set of nutritional goals that included reduction in the prevalence of inadequate nutrient intakes to ≤20 %.

Setting

Brazil.

Subjects

Participants (men and women, n 25 324) aged 20 years or more from the first National Dietary Survey (NDS) 2008–2009.

Results

Feasible solution to the model was not found when all constraints were imposed; infeasible nutrients were Ca, vitamins D and E, Mg, Zn, fibre, linolenic acid, monounsaturated fat and Na. Feasible solution was obtained after relaxing the nutritional constraints for these limiting nutrients by including a deviation variable in the model. Estimated prevalence of nutrient inadequacy was reduced by 60–70 % for most nutrients, and mean saturated and trans-fat decreased in the optimized diet meeting the model constraints. Optimized diet was characterized by increases especially in fruits (+92 g), beans (+64 g), vegetables (+43 g), milk (+12 g), fish and seafood (+15 g) and whole cereals (+14 g), and reductions of sugar-sweetened beverages (−90 g), rice (−63 g), snacks (−14 g), red meat (−13 g) and processed meat (−9·7 g).

Conclusion

Linear programming is a unique tool to identify which changes in the current diet can increase nutrient intake and place the population at lower risk of nutrient inadequacy. Reaching nutritional adequacy for all nutrients would require major dietary changes in the Brazilian diet.

Type
Research Papers
Copyright
Copyright © The Authors 2018 

Prevalence of inadequate nutrient intake is high in many parts of the world( Reference Roman Viñas, Ribas Barba and Ngo 1 , Reference Moshfegh, Goldman and Cleveland 2 ), including Brazil. According to the last Brazilian National Dietary Survey (2008/2009), the prevalence of inadequate nutrient intake is greater than 70 % for Ca, vitamins D and E, Mg and vitamin A in the adult and elderly population( Reference Araujo, Bezerra and Barbosa 3 , Reference Fisberg, Marchioni and Castro 4 ). Diet optimization methods can be used as a tool for achieving nutrient goals while planning feasible diets based on local and culturally specific foods for either a population or individuals( Reference Hlaing, Fahmida and Htet 5 Reference Darmon, Ferguson and Briend 7 ). Diet optimization is based on linear programming, which is a mathematical method that optimizes (minimizes or maximizes) a defined function (e.g. the least cost; the least difference between optimized and observed diets) while respecting multiple constraints, such as a set of nutrient recommendations. This method has been used in previous studies to formulate dietary patterns in accordance with nutrient-based recommendations( Reference Okubo, Sasaki and Murakami 8 , Reference Ferguson, Darmon and Fahmida 9 ) and to assess the impact of cost( Reference Darmon, Ferguson and Briend 10 , Reference Maillot, Darmon and Drewnowski 11 ) and environmental constraints( Reference Perignon, Masset and Ferrari 12 ) on nutritionally adequate food choices.

Studies conducted using diet optimization in Europe, the USA and Asia, among others, have identified the main dietary modifications needed to fulfil nutrient recommendations in the range of acceptable consumption constraints, at the population level( Reference Okubo, Sasaki and Murakami 8 , Reference Cleveland, Escobar and Lutz 13 , Reference Barré, Vieux and Perignon 14 ). However, applying results from these countries is difficult because food intake in Brazil has peculiarities, such as consumption of rice, beans and beef almost every day, and low consumption of fruits, vegetables, fish and dairy products. The aim of the present study was to identify the smallest modifications from the current food intake that could reach the target prevalence of 20 % or less of inadequate intake for each nutrient.

Methods

Study population

Dietary data from the first National Dietary Survey (NDS) were used. NDS was conducted along with the Household Budget Survey (HBS) 2008–2009 carried out by the Brazilian Institute of Geography and Statistics( 15 ). HBS used a two-stage sampling: the first randomly selected census tracts and the second proceeded with random selection of the households. The 12 800 sectors of the set of census tracts were grouped into 550 household strata with geographical and socio-economic homogeneity. The number of tracts randomly selected from each stratum was proportional to the number of households in this stratum. Households in each stratum were uniformly distributed throughout 12-month periods to accommodate seasonal variation in food intake.

Dietary intake was collected from two non-consecutive food records of adults and elderly people (n 25 324; aged 20 years or more, excluding pregnant and lactating women), in which the individual recorded all foods and beverages consumed, including the time of intake, quantities consumed in portion sizes and preparation form. Details on sampling data collection are available elsewhere( Reference Barbosa, Brito and Junger 16 ). A list of 305 foods were reported in the survey (many of them already grouped into subgroups; e.g. different types of breads into breads). From this list, we excluded non-food nutrient and energy sources such as coffee and tea (without sugar) and alcoholic beverages. To have a better interpretability and simplicity of the models, we considered only foods that together accounted for at least 95 % of the total energy and nutrient intakes (considering all nutrients used in this analysis), resulting in a final list of sixty-eight foods or food groups (called ‘food items’). Food contribution to total energy and nutrient intakes was calculated as food item energy or nutrient content divided by total energy or nutrient content from all foods. Mean population food intakes were calculated considering sampling weights for these sixty-eight food items and are referred to herein as ‘mean observed diet’.

Description of optimized models using linear programming

Linear programming for modelling diets was described previously elsewhere( Reference Briend, Darmon and Ferguson 17 ). An optimization model is defined by an objective function dependent on many variables (i.e. decision variables) restricted by various constraints. Decision variables are the quantities for the sixty-eight food variables that will be modelled to satisfy all the nutritional and acceptability constraints. In the present study, the diet optimization model was used to design a diet that provides nutrients meeting nutritional goals while departing as least as possible from the current observed mean diet. In other words, the quantities of foods in the optimized diet should be as close as possible to the mean observed food intakes. The objective function can also minimize undesirable deviations from nutrient goals (an undesirable deviation is the difference between the target and the optimized content for a nutrient)( Reference Ferguson, Darmon and Fahmida 9 ) which are not achievable. For example, an undesirable negative deviation of 50 mg occurs when the content for a given nutrient in the optimized diet is 250 mg instead of a target of 300 mg. The deviance for a nutrient expresses the least optimized difference between the target and the solution when the constraint cannot be met. Standardized deviation factors, (desired–actual)/desired, can be included in the model for all nutrients simultaneously. The following function was created:

$$Y{\equals}i{\equals}1i{\equals}g\left( {{{Q_{i}^{{opt}} {\minus}Q_{i}^{{obs}} } \over {Q_{i}^{{obs}} }}} \right){\plus}\mathop \sum\limits_{n{\equals}1}^{n{\equals}N} d_{n} ,$$

where Y is the objective function to be minimized, g is the total number of food items, $Q_{i}^{{opt}} $ is the quantity (in grams) of food item i in the optimized diet and $Q_{i}^{{obs}} $ is the mean quantity of the same item i in the observed diet; d n is the standardized deviation factor for nutrients n (N is the total of infeasible nutrients). This is a non-linear function due to the use of absolute function, which was linearized including a set of linear constraints following a similar procedure to that described in detail elsewhere( Reference Darmon, Ferguson and Briend 18 ). All linear programming models were run with the Optmodel Procedure of the statistical software package SAS version 9.4.

Input data for the model

Food composition database

The food composition data set specially compiled for Brazilian nutritional surveys( 19 ) was used. When individual foods were grouped into a single food item (e.g. different types of rice), the nutrient composition of the food item was the mean composition of the foods weighted by the frequency of reporting of each item that composes the group. All food items were categorized into six food groups (fruits, vegetables, seeds and legumes; cereals; dairy; cereals; meat; oils; others) and twenty-six food subgroups. Food classification was based on previous studies on household food availability in Brazil( Reference Levy-Costa, Sichieri and Pontes 20 , Reference Levy, Claro and Mondini 21 ), but collapsing foods with low frequency of intake such as manioc into the subgroup tubers. In addition, milk was split into whole milk and non-fat milk because of the saturated fat content; and leafy vegetables were classified as a separate group because they usually weigh much less compared with other vegetables, thus they are expected to be consumed in lower quantities.

Acceptability constraints

This term refers to boundaries in which the optimized diet can deviate from the observed mean intake. These limitations help avoid a diet that is culturally or socially unacceptable. Boundaries were based on 2d mean intakes of each food item per stratum; this procedure removes, at least in part, the within-person variance in dietary intake presented when dietary information is provided from one or few collection days, and approaches the mean usual intake in the stratum( Reference Beaton, Milner and Corey 22 ). Then, the 10th and 70th percentiles from the distribution of mean intakes were estimated and arbitrarily set as the lower and upper acceptability constraints, respectively (Table 1).

Table 1 Acceptability constraints on food content imposed in the linear programming model

Nutritional constraints

This term refers to nutritional goals that the optimized diet should meet. We focused on nutrients with a high prevalence of inadequate intake observed in Brazil( Reference Araujo, Bezerra and Barbosa 3 ). However, a wider set of nutrients was also included to prevent the optimized diet from being an unbalanced diet (e.g. to achieve Ca requirement an increase in saturated fat might be necessary, hence there was a need to impose constraints on saturated fat as well). For micronutrients such as Ca, Mg, Fe, P, Cu, Zn, vitamins A, B6, B12, C, D and E, thiamin, riboflavin, niacin and folate, the cut-offs were derived from the Estimated Average Requirement (EAR)( 23 25 ), targeting a prevalence of inadequate nutrient intake of 20 % or less. The EAR are the average daily nutrient intake levels estimated to meet the requirement of half the healthy individuals in a life stage and gender group( 26 ). Thus, if the population mean intake of a nutrient is at EAR level, under assumption of a normal distribution of intake, it means that 50 % of the population will be inadequate regarding their nutrient requirement( Reference Carriquiry 27 ). To reach the target of ≤20 % prevalence of inadequate nutrient intake, a set of constraints considering both EAR and current usual nutrient intake were developed. First, we estimated the distribution of usual nutrient intakes by age–sex group by removing within-person variance using proper methodology( Reference Tooze, Midthune and Dodd 28 ). The nutritional constraint (i.e. the lowest acceptable intake) for a given nutrient for each age–sex group was calculated as follows:

$${\rm Constraint}\,{\equals}\,{\rm Mean}_{{{\rm (age}{\minus}{\rm sex)}}} {\minus}{\rm P}_{{{\rm 20 (age}{\minus}{\rm sex)}}} {\plus}{\rm EAR}_{{\left( {{\rm age}{\minus}{\rm sex}} \right)}} ,$$

where the parameters are mean observed nutrient intake, 20th percentile of the usual nutrient intake and EAR for the nutrient. Finally, we calculated the overall mean constraints weighted by the frequency of age and sex subgroups in the population. Prevalence of inadequacy was calculated as the proportion of people with usual intake below the EAR assuming the same between-person variability in nutrient intake for both observed and optimized diets. For micronutrients with no EAR (K, Mn, vitamin K and pantothenic acid), we constrained the intake as equal to or higher than the observed mean intake. For Na, we considered only the intrinsic content in foods because there is no information on how accurate is the estimate of added salt in food preparations. The Na constraint was a 58 % reduction in mean observed Na intake as targeted by the Brazilian Ministry of Health as part of policies to reduce the salt in processed foods( Reference Nilson, Jaime and Resende 29 ). Red and processed meat was constrained to 500 g/week( 30 ). Total energy content was not constrained since there is no precise measure of the energy under-reporting in our population. Models were allowed to determine the amount of energy required to meet nutrient recommendations in accordance with the imposed food and nutrient constraints. Nutritional constraints for macro- and micronutrients, and the references used, are provided in Table 2.

Table 2 Macro- and micronutrient constraints imposed in the linear programming model

%E, percentage of energy.

* Micrograms of retinol activity equivalents.

Micrograms of dietary folate equivalents.

Institute of Medicine( 25 ).

§ World Health Organization( 39 ).

Observed intake.

Considering a 58 % reduction in salt intake from the Brazilian plan to reduce salt in processed foods( Reference Nilson, Jaime and Resende 29 ).

** Derived from the Estimated Average Requirement( 23 25 ).

Results

Mean age for this sample was 43 (sd 27·0) years; 47 % were male; 35 % were overweight and 16 % were obese. High school and college were reported by 39 % of the population; 46 % had monthly family income <1 minimum wage and 14 % >3 minimum wages (1 minimum wage = $US 180 or 430 Brazilian Reals; reference period was 15 January 2009).

It was not possible to find a feasible solution when all constraints were imposed on the model; infeasible nutrients were Ca, vitamins D and E, Mg, Zn, fibre, linolenic acid, monounsaturated fat and Na. A feasible solution was obtained after relaxing the nutritional constraints for these limiting nutrients by including a deviation variable in the model, and the results for the optimized diet refer to this model. Observed and optimized mean nutrient contents and estimated prevalence of nutrient inadequacy are shown in Table 3. The maximum achievable contents for the limiting nutrient were 513 mg (Ca), 263 mg (Mg), 10·2 mg (Zn), 3·3 µg (vitamin D), 5·6 mg (vitamin E), 1·4 g (linolenic acid), 16·8 g (monounsaturated fat) and 23·2 g (fibre), and the minimum for Na was 1143·3 mg (13 % reduction from the mean observed intake). The remaining nutritional constraints were fully satisfied. Estimated prevalence of nutrient inadequacy was reduced by 60–70 % for P, niacin, vitamin A, thiamin, riboflavin, vitamin B6, vitamin C and folate. Modest reductions of estimated prevalence of nutrient inadequacy were observed for Mg (24 %) and Ca (5 %). Vitamins D and E kept the same high inadequacy (99 %). The optimized diet also increased the mean content of nutrients with no EAR by about 30 %. Percentages of energy from macronutrients were within the acceptable range in both the observed and optimized diets. Mean saturated fat and trans-fat were reduced in the optimized diet and fell within the adequate value. Total weight and energy were slightly higher in the optimized v. the observed diet (1247 v. 1156 g and 6966 v. 6816 kJ (1665 v. 1629 kcal), respectively).

Table 3 Nutrient contents and estimated prevalence of inadequacy in the observed and optimized diets

%E, percentage of energy.

Observed diet of Brazilian adults (men and women aged 20 years or more, n 25 324) from the first National Dietary Survey 2008–2009. Optimized diet obtained by linear programming, using sixty-eight foods, to achieve the least difference from the observed population mean dietary intake while meeting a set of nutritional goals including a reduction in prevalence of inadequate nutrient intakes to ≤20 %.

* For nutrients with an Estimated Average Requirement established.

Micrograms of retinol activity equivalents.

Micrograms of dietary folate equivalents.

The food group contents in the observed and optimized diets are presented in Table 4. The optimized diet was characterized by increases especially in fruits (+92 g), beans (+64 g), vegetables (+43 g), whole milk (+12 g), fish and seafood (+15 g) and whole cereals (+14 g). Within the groups, some individual food items required a higher increase to meet nutritional goals. Among the fruits, the most important changes occurred to açaí (increased from 2·3 to 18·7 g), acerola (from 5 to 14 g) and orange (from 49 to 58 g). All fruits increased at the upper acceptability constraint. Among the vegetables, increases in tomato and courgette of about 3·5 g each were highlighted. On the other hand, sugar-sweetened beverages had the highest reduction (about −90 g), followed by rice (−63 g), snacks (−14 g), red meat (−13 g) and processed meats (−9·7 g).

Table 4 Food contents in the observed and optimized diets

Observed diet of Brazilian adults (men and women aged 20 years or more, n 25 324) from the first National Dietary Survey 2008–2009. Optimized diet obtained by linear programming, using sixty-eight foods, to achieve the least difference from the observed population mean dietary intake while meeting a set of nutritional goals including a reduction in prevalence of inadequate nutrient intakes to ≤20 %.

* Optimized – observed, difference (in grams).

Discussion

In the present study, we demonstrate that it is possible to increase nutrient intakes, thus lowering the prevalence of inadequacy to less than 20 % for the majority of the nutrients evaluated, and still reach other nutritional goals such energy share of macronutrients including free sugars and fatty acids. Most foods in the optimized diet did not differ strongly from the observed diet (up to 20 g difference), except for beans and fruits (which increased) and rice and sugar-sweetened beverages (which decreased). Beans are one of the most frequently consumed foods( Reference Souza, Pereira and Yokoo 31 ) with the highest mean population intake in Brazil( 15 ). Along with the fact of having substantial content of nutrients, beans are among the five most important sources for most nutrients (exceptions are vitamins A, B12 and C). In addition, they are the main food source of fibre, Ca, Mg, P, Fe, K, Cu and vitamin E in the Brazilian diet (results from the analysis of food energy and nutrient contributions as described in the ‘Methods’ section, data not shown). This explains why the optimized diet demanded a higher amount of beans.

Higher demands for fruits and vegetables to meet nutritional goals were also described in studies from the USA( Reference Cleveland, Escobar and Lutz 13 ), France( Reference Darmon, Ferguson and Briend 10 , Reference Maillot, Darmon and Drewnowski 11 , Reference Barré, Vieux and Perignon 14 ), Japan( Reference Okubo, Sasaki and Murakami 8 ) and New Zealand( Reference Wilson, Nghiem and Ni Mhurchu 32 ). On the other hand, sugar-sweetened beverages and rice were lower in the optimized diet, and this reduction was probably needed to accommodate higher quantities of macronutrients and fats from nutrient-dense foods included in the optimized diet. Similarly, reduction in red and processed meat was needed mainly due to the Na and saturated fat contents, being replaced in part by chicken and fish, which reflects the moderate inverse correlation of chicken and fish consumption with red meat observed in the population (data not shown).

For some nutrients, a solution could be reached only after relaxing their constraints. This resulted in the estimated prevalence of inadequacy for Ca and vitamins D and E remaining high and practically unaltered. To reach the initial target of less than or equal to 20 % of inadequacy, the mean intake of some key foods should be allowed to exceed the upper limit of acceptability imposed. For example, one of the Ca-richest foods are dairy products( 23 ). Dairy’s content in the optimized diet is at the upper limit of acceptability; a higher content would potentially be non-realistic or unaffordable. For example, an additional amount of 600 g in the mean intake of milk (the most important dairy product in Brazil) would be necessary to fulfil the Ca requirement, which certainly is a non-realistic amount (the 95th percentile for dairy intake is 212 g). Regarding vitamins D and E, considering the richest foods, an additional amount of 210 g in the mean intake of fish, and 145 g in nuts, would overcome the inadequacy for those nutrients, respectively; however, both amounts are well above the highest intake observed in the population. The high inadequacy of vitamins D and E, however, might not be of special concern due to the assumptions made in the recommendation intake definition. The established amount of intake of vitamin D needed to maintain a range of bone health outcomes assumes minimal sun exposure because of high imprecision in sunlight exposure due to skin pigmentation, latitude, use of sunscreens, cultural differences in dressing habits, among others( 23 ). It is likely that tropical countries, such as Brazil, need less vitamin D from diet than countries from higher latitudes; but, to date, we cannot detail how much solar exposure by itself fulfils the physiological vitamin D needs( 33 ). In fact, the mean serum 25-hydroxyvitamin D concentration in a sample of Brazilians measured throughout the four seasons was about 50 mmol/l for adults and elderly men and women. This means that about half of the sample did not present vitamin D deficiency in spite of very high prevalence of Ca and vitamin D intake inadequacy (85 and 99 %, respectively)( Reference Martini, Verly and Marchioni 34 ). In addition, both the Institute of Medicine and WHO reports stated that there is insufficient information to define indicators for vitamin E adequacy( 24 , 33 ) and they are based mainly on the mean intake observed in the USA and other European countries( 33 ).

Limiting nutrients (i.e. nutrients for which the recommended value is not achievable in an optimized diet) were also found in previous studies using linear programming for both individual and mean diet modelling; such as vitamin E, K and Na for the American population( Reference Masset, Monsivais and Maillot 35 , Reference Gao, Wilde and Lichtenstein 36 ), vitamin D, Mg, Na, Ca and vitamin E for the French population( Reference Maillot, Vieux and Amiot 6 , Reference Maillot, Darmon and Drewnowski 11 ), and fibre and vitamin A for the Japanese population( Reference Okubo, Sasaki and Murakami 8 ). As pointed out in the last study( Reference Okubo, Sasaki and Murakami 8 ), these differences in limiting nutrients found in various countries might be explained by the differences in both dietary patterns and dietary recommendations adopted. In the present study, unlike the others, we did not use the EAR value as a nutrition target. Instead, we derived the target that should be reached in the optimized diet in a way that at least 80 % of the population would have an intake higher than the EAR. Moreover, we did not use the Adequate Intake as a target for nutrients with no EAR established because it consists of a set of intake recommendations in which there is not enough information to define a mean requirement, being derived from mean intake in healthy American and Canadian populations, which could be even lower than the actual unknown need( 26 ).

The feasibility of such changes in the optimized diet may be a point of debate. In fact, participation of beans in the Brazilian household food basket has decreased throughout the last three decades( Reference Levy-Costa, Sichieri and Pontes 20 , Reference Levy, Claro and Mondini 21 ). Price of and access to fruits and vegetables may act as a barrier to encourage their consumption especially for low-income families( Reference Darmon, Ferguson and Briend 18 ). However, the acceptability constraints imposed to our model were more restrictive than the ones used in other studies that modelled population mean diet( Reference Okubo, Sasaki and Murakami 8 , Reference Barré, Vieux and Perignon 14 ). Such acceptability constraints were obtained from mean sample strata intakes, which represent actual mean intakes in delimited sectors with geographical and socio-economic homogeneity. This makes the distribution of mean intakes more heterogeneous, and this is the reason we opted for such restrictive constraints. From our point of view, more flexible percentiles such as the 90th or 95th would result in a very non-realistic or unaffordable diet.

Some limitations, however, should be addressed. First, there is no set of nutrient recommendations derived specifically for the Brazilian population and the Dietary Reference Intakes adopted here were established for the US population, which implies that the requirements taken into account (among other factors) are the mean weight and height, and food pattern and diversity; the latter is related to nutrient bioavailability. Second, the Brazilian food composition data set does not comprise a food and nutrient list sufficient to be used in national surveys; thus we calculated nutrient contents using the US Department of Agriculture food composition using the Nutrition Data System for Research (NDS-R) program, version 2008( 37 ). Nevertheless, both the Dietary Reference Intakes and the US Department of Agriculture food composition have been used to estimate nutrient intakes and prevalence of inadequacy in the Brazilian population( Reference Araujo, Bezerra and Barbosa 3 , Reference Fisberg, Marchioni and Castro 4 ), which put both observed and optimized diets under the same uncertainties. Third, to estimate the prevalence of nutrient inadequacy, we assumed the intake variability in the optimized diet to be the same as in the observed diet, which is consistent with a scenario where everyone modifies their intake by the same level. Finally, the optimal solution lies in the assumptions underlying diet modelling. For example, the choice of the target for the nutrient adequacy and the acceptability constraints were arbitrary. However, we did not consider other targets for adequacy because the prevalence of inadequacy, in most of the cases, was either too high or low; thus higher targets (e.g. 30 %) or lower (e.g. 10 %) would not affect this figure, especially for those highly inadequate nutrients. Sensitivity analysis can be performed to check some of the model assumptions, and it provides the extension of the objective values and the variable values (optimized food quantities) changes while the nutrient composition or other constraints change. It also provides information on the relative importance of a given food or nutrient in the solution by assessing the robustness of the model after removing any/some food(s) or constraint(s)( Reference Buttriss, Briend and Darmon 38 ).

Conclusion

In conclusion, the present study showed that changes in the current diet, respecting constraints of acceptability, increased nutrient intakes and placed the population at lower risk of nutrient inadequacies. However, to meet nutritional adequacy for all nutrients would require major dietary changes. Given all the uncertainties, such as food composition, measurement error in dietary reporting and nutrient bioavailability, these amounts in the optimized diet should not be seen as rigorous food intake targets. Instead, it gives us a picture of which components of the diet should be focused upon in interventions or programmes to promote healthy food patterns.

Acknowledgements

Financial support: This research received no specific grant from any funding agency in the public, commercial or not-for-profit sectors. S.Q. was financed (PhD fellowship) by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES). CAPES had no role in the design, analysis or writing of this article. Conflict of interest: The authors declare no confiicts of interest. Authorship: S.Q. and E.V.-J. performed the statistical analyses, interpreted the data and wrote the paper; R.S., N.D. and M.M. performed the interpretation of the data and wrote the paper. All authors actively participated in the manuscript preparation, and they all read and approved the final version of the manuscript. Ethics of human subject participation: Not applicable.

References

1. Roman Viñas, B, Ribas Barba, L, Ngo, J et al. (2011) Projected prevalence of inadequate nutrient intakes in Europe. Ann Nutr Metab 59, 8495.Google Scholar
2. Moshfegh, A, Goldman, J & Cleveland, L (2005) What We Eat in America. NHANES 2001–2002: Usual Nutrient Intakes from Food Compared to Dietary Reference Intakes. Washington, DC: US Department of Agriculture, Agricultural Research Service.Google Scholar
3. Araujo, MC, Bezerra, IN, Barbosa, FdS et al. (2013) Consumo de macronutrientes e ingestão inadequada de micronutrientes em adultos. Rev Saude Publica 47, Suppl. 1, 177S189S.Google Scholar
4. Fisberg, RM, Marchioni, DML, Castro, MAd et al. (2013) Ingestão inadequada de nutrientes na população de idosos do Brasil: Inquérito Nacional de Alimentação 2008–2009. Rev Saude Publica 47, Suppl. 1, 222S230S.Google Scholar
5. Hlaing, LM, Fahmida, U, Htet, MK et al. (2015) Local food-based complementary feeding recommendations developed by the linear programming approach to improve the intake of problem nutrients among 12–23-month-old Myanmar children. Br J Nutr 116, Suppl. 1, S16S26.Google Scholar
6. Maillot, M, Vieux, F, Amiot, MJ et al. (2010) Individual diet modeling translates nutrient recommendations into realistic and individual-specific food choices. Am J Clin Nutr 91, 421430.Google Scholar
7. Darmon, N, Ferguson, E & Briend, A (2002) Linear and nonlinear programming to optimize the nutrient density of a population’s diet: an example based on diets of preschool children in rural Malawi. Am J Clin Nutr 75, 245253.Google Scholar
8. Okubo, H, Sasaki, S, Murakami, K et al. (2015) Designing optimal food intake patterns to achieve nutritional goals for Japanese adults through the use of linear programming optimization models. Nutr J 14, 57.CrossRefGoogle ScholarPubMed
9. Ferguson, EL, Darmon, N, Fahmida, U et al. (2006) Design of optimal food-based complementary feeding recommendations and identification of key ‘problem nutrients’ using goal programming. J Nutr 136, 23992404.Google Scholar
10. Darmon, N, Ferguson, EL & Briend, A (2006) Impact of a cost constraint on nutritionally adequate food choices for French women: an analysis by linear programming. J Nutr Educ Behav 38, 8290.Google Scholar
11. Maillot, M, Darmon, N & Drewnowski, A (2010) Are the lowest-cost healthful food plans culturally and socially acceptable? Public Health Nutr 13, 11781185.Google Scholar
12. Perignon, M, Masset, G, Ferrari, G et al. (2016) How low can dietary greenhouse gas emissions be reduced without impairing nutritional adequacy, affordability and acceptability of the diet? A modelling study to guide sustainable food choices. Public Health Nutr 19, 26622674.Google Scholar
13. Cleveland, LE, Escobar, AJ, Lutz, SM et al. (1993) Method for identifying differences between existing food intake patterns and patterns that meet nutrition recommendations. J Am Diet Assoc 93, 556563.CrossRefGoogle ScholarPubMed
14. Barré, T, Vieux, F, Perignon, M et al. (2016) Reaching nutritional adequacy does not necessarily increase exposure to food contaminants: evidence from a whole-diet modeling approach. J Nutr 146, 21492157.Google Scholar
15. Instituto Brasileiro de Geografia e Estatística (2011) Análise do Consumo Alimentar Pessoal no Brasil, 2008–2009 (Family Budget Survey, 2008–2009). Rio de Janeiro: IBGE.Google Scholar
16. Barbosa, FS, Brito, FSB & Junger, W (2013) Assessing usual dietary intake in complex sample design surveys. Rev Saude Publica 47, Suppl. 1, S171S176.Google Scholar
17. Briend, A, Darmon, N, Ferguson, E et al. (2003) Linear programming: a mathematical tool for analyzing and optimizing children’s diets during the complementary feeding period. J Pediatr Gastroenterol Nutr 36, 1222.Google Scholar
18. Darmon, N, Ferguson, EL & Briend, A (2002) A cost constraint alone has adverse effects on food selection and nutrient density: an analysis of human diets by linear programming. J Nutr 132, 37643771.Google Scholar
19. Instituto Brasileiro de Geografia e Estatística (2011) Tabela de Composição Nutricional dos Alimentos Consumidos no Brasil. Rio de Janeiro: IBGE.Google Scholar
20. Levy-Costa, RB, Sichieri, R, Pontes, NS et al. (2005) Household food availability in Brazil: distribution and trends (1974–2003). Rev Saude Publica 39, 530540.CrossRefGoogle ScholarPubMed
21. Levy, RB, Claro, RM, Mondini, L et al. (2012) Distribución regional y socioeconómica de la disponibilidad domiciliaria de alimentos en Brasil, 2008–2009. Rev Saude Publica 46, 615.Google Scholar
22. Beaton, GH, Milner, J, Corey, P et al. (1979) Sources of variance in 24-hour dietary recall data: implications for nutrition study design and interpretation. Am J Clin Nutr 32, 25462559.Google Scholar
23. Institute of Medicine (2011) Dietary Reference Intakes for Calcium and Vitamin. D. Washington, DC: National Academies Press.Google Scholar
24. Institute of Medicine (2000) Dietary Reference Intakes for Vitamin C, Vitamin E, Selenium, and Carotenoids. Washington, DC: National Academies Press.Google Scholar
25. Institute of Medicine (2006) Dietary Reference Intakes: The Essential Guide to Nutrient Requirements. Washington, DC: National Academies Press.Google Scholar
26. Institute of Medicine (2000) Dietary Reference Intakes: Applications in Dietary Assessment. Washington, DC: National Academies Press.Google Scholar
27. Carriquiry, AL (1999) Assessing the prevalence of nutrient inadequacy. Public Health Nutr 2, 2333.Google Scholar
28. Tooze, JA, Midthune, D, Dodd, KW et al. (2006) A new statistical method for estimating the usual intake of episodically consumed foods with application to their distribution. J Am Diet Assoc 106, 15751587.Google Scholar
29. Nilson, EAF, Jaime, PC & Resende, DdO (2012) Iniciativas desenvolvidas no Brasil para a redução do teor de sódio em alimentos processados. Rev Panam Salud Publica 32, 287292.Google Scholar
30. World Cancer Research Fund (2007) Food, Nutrition, Physical Activity, and the Prevention of Cancer: A Global Perspective. Washington, DC: AICR.Google Scholar
31. Souza, AdM, Pereira, RA, Yokoo, EM et al. (2013) Alimentos mais consumidos no Brasil: Inquérito Nacional de Alimentação 2008–2009. Rev Saude Publica 47, Suppl. 1, 190S199S.CrossRefGoogle Scholar
32. Wilson, N, Nghiem, N, Ni Mhurchu, C et al. (2013) Foods and dietary patterns that are healthy, low-cost, and environmentally sustainable: a case study of optimization modeling for New Zealand. PLoS One 8, e59648.Google Scholar
33. Food and Agriculture Organization of the United Nations & World Health Organization (2002) Vitamin and Mineral Requirements in Human Nutrition. Joint FAO/WHO Expert Consultation . Geneva: WHO.Google Scholar
34. Martini, LA, Verly, E Jr, Marchioni, DML et al. (2013) Prevalence and correlates of calcium and vitamin D status adequacy in adolescents, adults, and elderly from the health survey – São Paulo. Nutrition 29, 845850.Google Scholar
35. Masset, G, Monsivais, P, Maillot, M et al. (2009) Diet optimization methods can help translate dietary guidelines into a cancer prevention food plan. J Nutr 139, 15411548.Google Scholar
36. Gao, X, Wilde, PE, Lichtenstein, AH et al. (2006) The 2005 USDA Food Guide Pyramid is associated with more adequate nutrient intakes within energy constraints than the 1992 Pyramid. J Nutr 136, 13411346.CrossRefGoogle Scholar
37. University of Minnesota, Nutrition Coordinating Center (2003) University of Minnesota Nutrition Data System for Research – NDSR. http://www.ncc.umn.edu/ndsr-database-page/ (accessed February 2017).Google Scholar
38. Buttriss, JL, Briend, A, Darmon, N et al. (2014) Diet modelling: how it can inform the development of dietary recommendations and public health policy. Nutr Bull 39, 115125.CrossRefGoogle Scholar
39. World Health Organization (2003) Diet, Nutrition and the Prevention of Chronic Diseases. Report of a Joint WHO/FAO Expert Consultation. WHO Technical Report Series no. 916. Geneva: WHO.Google Scholar
Figure 0

Table 1 Acceptability constraints on food content imposed in the linear programming model

Figure 1

Table 2 Macro- and micronutrient constraints imposed in the linear programming model

Figure 2

Table 3 Nutrient contents and estimated prevalence of inadequacy in the observed and optimized diets

Figure 3

Table 4 Food contents in the observed and optimized diets