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Red meat and egg intake and serum ferritin concentrations in Colombian children: results of a population survey, ENSIN-2015

Published online by Cambridge University Press:  25 March 2020

Oscar F. Herran*
Affiliation:
Universidad Industrial de Santander, Bucaramanga, Santander, Colombia
Jhael N. Bermúdez
Affiliation:
Instituto Colombiano de Bienestar Familiar, Subdirección de Monitoreo y Evaluación, Bogotá, Colombia
María Del Pilar Zea
Affiliation:
Instituto Colombiano de Bienestar Familiar, Subdirección de Monitoreo y Evaluación, Bogotá, Colombia Facultad de Ciencias de la Salud, Universidad Javeriana de Cali, Cali, Colombia
*
*Corresponding author: Oscar F. Herran, fax +57 76323215, email [email protected]; [email protected]

Abstract

The present study aimed to (a) establish the frequency of consumption of red meat and eggs; (b) determine serum ferritin levels (μg/l); and (c) establish the relationship between serum ferritin and the consumption of red meat and eggs. In Colombia during 2014–2018, an analytical study was conducted in 13 243 Colombian children between the ages of 5 and 17 years, based on cross-sectional data compiled by ENSIN-2015 (Encuesta Nacional de la Situación Nutricional en Colombia-2015) on serum ferritin levels and dietary consumption based on a questionnaire of the frequency of consumption. Using simple and multiple linear regression, with the serum ferritin level as the dependent variable and the frequency of consumption as the main explanatory variable, the crude and adjusted partial regression coefficients (β) between serum ferritin levels and consumption were calculated. The frequency of habitual consumption of red meat was 0⋅49 (95 % CI 0⋅47, 0⋅51) times/d. The frequency of habitual egg consumption was 0⋅76 (95 % CI 0⋅74, 0⋅78) times per d. The mean serum ferritin level in men was 41⋅9 (95 % CI 40⋅6, 43⋅1) μg/l and in women, 35⋅7 (95 % CI 34⋅3, 37⋅7) μg/l (P < 0⋅0001). The adjusted β between the consumption of red meat and eggs and serum ferritin levels were β = 3⋅0 (95 % CI 1⋅2, 4⋅7) and β = 2⋅5 (95 % CI 1⋅0, 3⋅9) for red meat and eggs, respectively. In conclusion, red meat and eggs are determinants of serum ferritin levels in Colombia and, therefore, could be considered public policy options to reduce anaemia and Fe deficiency.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
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Copyright © The Author(s) 2020

Serum ferritin (SF; μg/l) is a good indicator of body Fe deposits and is the most specific laboratory test to determine Fe deficiency(Reference Bowman and Russell1). A low level without other abnormal results means depletion of Fe deposits(Reference Bowman and Russell1), while elevated values (in adults) increase the risk of altered glucose homeostasis, insulin resistance syndrome and CVD in carriers of hereditary haemochromatosis(Reference Garry, Hunt and Baumgartner2). However, the concentration of SF may be falsely high as a consequence of an inflammatory response in acute processes or tissue damage in chronic processes(Reference Bowman and Russell1Reference Nairz, Theurl and Wolf4). According to the Food and Nutrition Board of the United States National Academies of Sciences(5), the dietary reference intakes of Fe range between 4⋅1 and 7⋅9 mg/d for the 4–17 years age group(5). Fe present in animal-source foods is more bioavailable because it is found in its haem version, whose absorption is up to three times higher compared with non-haem Fe(Reference Bowman and Russell1,5) . Red meat and eggs are part of the traditional dietary pattern of the Colombian population(Reference Herrán, DelCastillo and Patiño6Reference Ocampo, Prada and Herrán8), and the prevalence of consumption in a month for these two items is over 90 %(9,10) . In addition, they are sources of haem Fe: 100 g of red meat and eggs have 2⋅7 and 1⋅7 mg, respectively(11), which is equivalent to 34 and 21 % of the recommended dietary intake/d for children between 5 and 17 years of age(5).

According to the latest Encuesta Nacional de la Situación Nutricional en Colombia (National Survey of the Nutritional Situation of Colombia (ENSIN-2015)), Fe deficiency (SF<15 μg/l) in children between 5 and 12 years of age was 8⋅8 %, and Fe-deficiency anaemia (Hb<120 g/l) was 17⋅7 %. In children between 13 and 17 years, deficiency was 10⋅3 % and anaemia due to deficiency was 15⋅3 % (Hb<120 g/l in women and Hb<130 g/l in men), figures that are considered public nutrition issues(10,12) ; this situation is common in developing countries(Reference Petry, Olofin and Hurrell13). Anaemia is the best-known consequence of all those resulting from Fe deficiency, but decreased muscle strength and ability to work(Reference Haas and Brownlie14), along with altered immune system and inability to regulate body temperature, are also common(Reference Beard, Borel and Derr15,Reference Beard16) . These are the most relevant outcomes at an early age but, in the long term, behavioural alterations and irreparable cognitive deficits in children may be observed(Reference De Andrade Cairo, Rodrigues Silva and Carneiro Bustani17Reference Subramaniam and Girish19).

Prevalence of usual consumption of red meat and eggs greater than 90 % confirm that the goal set for 2015 in the National Development Plan (Plan Nacional de Desarrollo (PND)) Colombia 2014–2018 was reached(20), although the recommendation to increase the percentage of people who consume meat and eggs on a daily basis should technically be understood as increasing the frequency/d of consumption rather than the prevalence. Furthermore, the Food-Based Dietary Guidelines for the Colombian population over 2 years of age(21) also make explicit recommendations on consumption: eating one egg, milk and dairy products daily. Although both documents recommend increasing the consumption of these foods, they do so from the perspective of sources of protein and not haem Fe.

The present study was proposed given that anaemia and Fe deficiency are endemic problems in the Colombian population and have devastating effects on children and on productivity in general. The objectives were: (a) to establish the frequency of red meat and egg consumption (times/d); (b) to determine SF levels among red meat and egg consumers; and (c) to establish the degree of relationship between SF and red meat and egg consumption in the population aged 5–17 years in Colombia.

Materials and methods

The present analytical study is based on cross-sectional data collected in 2015–2016 by the ENSIN-2015 regarding SF levels (μg/l) and dietary consumption, using an FFQ.

Study population

The ENSIN-2015(9,10) was carried out during the past 4 years in Colombia. In short, these surveys are designed to represent 99 % of the population through stratified multistage sampling. All thirty-three geodemographic units or departments are grouped based on similar geographic and sociodemographic characteristics. The municipalities in these units are randomly selected and form strata with a probability proportional to the size of the population. Clusters of approximately ten households are randomly selected within these strata and household members are invited to participate. The ENSIN-2015 included 44 202 households, which represented 4739 clusters of 177 strata. Consent to participate was obtained during the field operation.

Population and sample

The ENSIN-2015 included 151 343 people. The FFQ was applied to 28 903 subjects, of whom 14 092 were between 5 and 17 years old; they were inquired about their usual food intake in the last 30 d. SF levels were obtained in 41 439 subjects, of whom 36 978 were between 5 and 17 years old. A total of 28 253 subjects consumed two of the thirty-nine food items included in the FFQ, that is ‘Eggs’ and ‘Beef, veal, pork, capybara, rabbit, goat, domestic guinea pig’ – called red meat for the purposes of this study. The target population was redefined through subpopulations of interest. The first subpopulation was composed of children between 5 and 17 years old, consumers of red meat, who will not try any type of diet by medical prescription, without pregnancy, and with size ≥80 cm and size <200 cm and weight ≥12 kg and weight <200 kg in order to guarantee plausible data of nutritional status; this subpopulation included 12 106 children. The second subpopulation was defined as children between 5 and 17 years old, egg consumers, who will not try any type of diet by medical prescription, without pregnancy, and with size ≥80 cm and size <200 cm and weight ≥12 kg and weight <200 kg in order to guarantee plausible data of nutritional status; this subpopulation was made up of 12 702 children. Finally, a third subpopulation was established with the same characteristics described above, which allowed studying the children who usually consumed: (a) red meat and eggs; (b) red meat but not eggs; (c) no red meat but eggs; and (d) neither one; this subpopulation comprised 13 243 children. Since FFQ and SF data were obtained from different subsamples, 10 260 children had SF data in the red meat consumers group, 10 764 in the egg consumers group, and 16 582 in the red meat and egg consumers group.

Data sources

Trained staff administered questionnaires to household heads to obtain information on sociodemographics, food security and level of wealth of the household. In addition, nutritionists applied in randomly selected subsamples an FFQ for the last month, with nine categories to establish the frequency of usual food intake. Children under the age of 12 years were assisted by their caregivers to respond to the FFQ. The food and food group checklist was designed by nutritionists based on the nutrition problems identified in past ENSIN(9,10) and other sources. The list of items related to the response to frequency of consumption was adapted from two reproducibility and validity studies from other FFQ conducted in the Colombian population(Reference Bautista, Herrán and Pryer22,Reference Herrán and Ardila23) . Face validity was guaranteed for all items on the checklist. The FFQ methodology is in nutritional epidemiology the most used in the world. The measurement with an FFQ allows estimating the prevalence of consumption and its frequency in terms of times/d. These two indicators of consumption are good estimators of the amount consumed (g). Establishing the amount (g) of consumption through other methods, such as the 24-h recall or diet record methods, is complex and very expensive, which makes it unfeasible(Reference Bautista, Herrán and Pryer22,Reference Herrán and Ardila23) .

Anthropometric measurements were also taken by trained nutritionists and surveyors, using standardised techniques and calibrated equipment. Size was established using a portable measuring rod (Shorr Board Productions LCC), approaching the nearest 1 mm. Weight was established with SECA scales (model 874), approximating to 100 g. The nine responses in the FFQ on the frequency of consumption of these two food items were converted to a continuous variable, ‘times/d’.

SF levels were established in a random subsample of participants; for this purpose, blood was drawn by venepuncture from the median cubital vein. One sample was collected in an EDTA tube for plasma separation and another in a metal-free polypropylene tube without anticoagulant for serum separation. All samples were stored in liquid N2 until their processing at the National Health Institute (Instituto Nacional de Salud) of Colombia. Plasma ferritin was quantified in children aged 5 to 17 years using a competitive chemiluminescent immunoassay on an ADVIA Centaur analyser (Siemens HealthCare Diagnostics, Inc.). Plasma C-reactive protein (PCR) was quantified by turbidimetry in an ACS-180 analyser (Siemens Healthcare Diagnostics, Inc.). Since there is evidence of high SF values when there is acute or chronic inflammation(Reference Bowman and Russell1Reference Nairz, Theurl and Wolf4), and to ensure the plausibility of the results, the ENSIN-2015 corrected the SF values by the PCR level in children between 5 and 17 years old (SF = SForiginal −15, if PCR>0⋅5).

The variables of interest were the frequency of usual consumption (times/d) of red meat, eggs and the SF level. The two FFQ items ‘Eggs’ and ‘Beef, veal, pork, capybara, rabbit, goat, domestic guinea pig’ were chosen because of their high consumption prevalence and because they are sources of haem Fe. Moreover, SF was preferred to Hb, which is a protein used as a biomarker of Fe stores and Fe nutrition. Other covariates were also considered to correlate them with dietary intake and SF levels: sex, age, size, BMI – and its equivalent according to the International Obesity Task Force (IOTF)(Reference Cole, Bellizzi and Flegal24,Reference Cole and Lobstein25) –, state of food security in the household, wealth index, ethnicity, level of urbanism and the geographical region where the subjects live. The level of urbanism refers to people living in urban areas, including large cities. The rural category included suburban population centres close to small cities, municipal seats distant from small cities, and populations scattered or very distant from municipal seats. Household food security status was established using the Latin American and Caribbean Food Security (ELCSA) scale(9).

On the other hand, wealth was established based on the index designed for the international Demographic and Health Survey(Reference Rutstein26). This index was constructed through the analysis of main components based on household information, which included, among others, the type of construction material of the dwelling, the characteristics of the health services and, in general, the goods and services available in the household. The first component is used to create the index as a continuous variable (z-score), which is assigned to each subject within the household. The highest values represent the richest subjects. The wealth index was categorised by incorporating the complex sample design into quintiles according to the distribution achieved among all survey participants. The geographical region grouped several geodemographic units and, in general, they share the most relevant aspects of food culture(Reference Gutierres de Pineda27).

Data processing and statistical analysis

All analyses were conducted using the analysis plan for complex sample designs of Stata software, version 14.1(28). The analysis was conducted to estimate the average frequency of usual consumption (times/d) of red meat and eggs, with their corresponding 95 % CI, in the population of children aged 5 to 17 years and for each of the categories of covariates of interest. Using simple and multiple linear regression, having SF level as the dependent variable and consumption frequency as the main explanatory variable, crude and adjusted partial regression coefficients (β) were estimated – direction and strength of the association (correlation) – between the SF levels and the consumption frequency. In addition, adjusted differences between β were estimated for each of the covariate categories. To obtain the adjusted differences, a new term was created as the cross-product between frequency/d and SF level for each category of covariates (interaction). The adjusted differences and their corresponding 95 % CI incorporated the complex sample design and the multiple regression models included the following covariates: sex, age, stunted growth, BMI, food security level, wealth index, ethnicity, level of urbanism and region. Finally, using multiple linear regressions, crude and adjusted means and their corresponding 95 % CI were estimated for the SF levels in the consumption categories of the third subpopulation described above.

Ethical considerations

All analyses were carried out under the principles of the Helsinki Declaration(29). The used databases are in the public domain. This research is classified as ‘without risk’ according to Resolution 8430 of 1993 of the Colombian Ministry of Health(30). Since this is a secondary analysis of population studies, with anonymised data, no authorisation is required from the Health Research Ethics Committee of the Industrial University of Santander.

Results

The prevalence of red meat consumption was 93⋅3 (95 % CI 92⋅4, 94⋅1) %, with no difference by sex (P = 0⋅809). The prevalence of egg consumption was 96⋅6 (95 % CI 96⋅0, 97⋅1) %, with no difference by sex (P = 0⋅174). The mean frequency of usual red meat consumption was 0⋅49 (95 % CI 0⋅47, 0⋅51) times/d, with no difference by sex (P = 0⋅764). The mean frequency of usual egg consumption was 0⋅76 (95 % CI 0⋅74, 0⋅78) times/d, with no difference by sex (P = 0⋅890). The mean SF was 38⋅9 (95 % CI 38⋅0, 39⋅9) μg/l; 41⋅9 (95 % CI 40⋅6, 43⋅1) μg/l in men and 35⋅7 (95 % CI 34⋅3, 37⋅7) μg/l in women. This difference of 6⋅2 μg/l against women is statistically significant (P < 0⋅0001). The proportion of children who ate red meat and/or eggs was 90⋅6 (95 % CI 89⋅5, 91⋅5) %, in the first category of the third subpopulation; more specifically, it was 2⋅7 (95 % CI 2⋅3, 3⋅2) % for children who only ate meat, 6⋅0 (95 % CI 5⋅3, 6⋅9) % for children that only ate eggs, and 0⋅6 (95 % CI 0⋅4, 1⋅0) % for children who do not eat meat or eggs. Among meat and/or egg consumers, the average SF was 39⋅4 (se 0⋅5) μg/l; among meat-only consumers 36⋅2 (se 2⋅0) μg/l; among egg-only consumers 34⋅5 (se 1⋅1) μg/l; and among those who do not eat meat nor eggs 34⋅2 (se 1⋅5) μg/l (χ 2 for trend, P ≤ 0⋅0001) (Fig. 1).

Fig. 1. Serum ferritin levels in children between 5 and 17 years of age according to red meat and egg consumption, Colombia, ENSIN-2015 (Encuesta Nacional de la Situación Nutricional en Colombia-2015; National Survey of the Nutritional Situation of Colombia-2015). The line inside the box represents the median (quartile 2; Q2). The edges of the box represent quartile 1 (Q1) and quartile 3 (Q3), respectively. The limits of the whiskers represent up to 1·5 times the interquartile range (IQR = Q3 − Q1): Q1 − 1·5 or Q3 + 1·5. The points to the right and left represent extreme atypical values.

The daily frequency of red meat consumption (times/d) was lower among those with stunted growth, as food insecurity increased, among black/Afro-descendant and indigenous populations, in rural areas and in all regions compared with the central region. SF (μg/l) levels among meat consumers were lower in women, as food insecurity increased, in the black/Afro-descendant population, and in all regions compared with the central region, except in the Eastern and Atlantic regions (Table 1). The frequency of egg consumption (times/d) was lower among overweight children and in all regions compared with the central region. Egg consumption was higher as the wealth index increased. SF levels among egg consumers were lower in women, in the black/Afro-descendant population and in the Atlantic, Pacific and Amazon/Orinoquia regions. Children who were overweight and obese had higher levels of SF than those classified as normal (Table 2).

Table 1. Red meat consumption (times/d) and serum ferritin levels (μg/l) among red meat consumers in a population between 5 and 17 years of age, Colombia, ENSIN-2015

(Mean values with their standard errors; differences and 95 % confidence intervals)

ENSIN-2015, Encuesta Nacional de la Situación Nutricional en Colombia-2015 (National Survey of the Nutritional Situation of Colombia-2015); Ref, reference; H/A, height for age; Q, quintile.

* Based on BMI equivalents according to the International Obesity Task Force.

Based on the Latin American and Caribbean Food Security (ELCSA) Scale.

Table 2. Egg consumption (times/d) and serum ferritin levels (μg/l) among egg consumers in a population between 5 and 17 years of age, Colombia, ENSIN-2015

(Mean values with their standard errors; differences and 95 % confidence intervals)

ENSIN-2015, Encuesta Nacional de la Situación Nutricional en Colombia-2015 (National Survey of the Nutritional Situation of Colombia-2015); Ref, reference; H/A, height for age; Q, quintile.

* Based on BMI equivalents according to the International Obesity Task Force.

Based on the Latin American and Caribbean Food Security (ELCSA) Scale.

Tables 3 and 4 present the raw and adjusted β-coefficients between red meat and egg consumption (times/d) and SF levels (μg/l). The correlation between red meat and egg consumption and SF levels is evident: β = 3⋅0 (95 % CI 1⋅2, 4⋅7) and β = 2⋅5 (95 % CI 1⋅0, 3⋅9) for red meat and eggs, respectively. There were no differences in the correlations adjusted by the categories of the variables studied, except for Bogotá, where the correlation between egg consumption and SF levels was 5⋅4 times higher than the mean correlation in the general population (β = 13⋅4 (95 % CI 5⋅5, 21⋅3); Table 4). Fig. 2 shows how SF levels increase as the frequency of meat and eggs consumption increases.

Fig. 2. Adjusted serum ferritin levels and frequency of red meat and egg consumption (times/d). Colombia, ENSIN-2015 (Encuesta Nacional de la Situación Nutricional en Colombia-2015; National Survey of the Nutritional Situation of Colombia-2015).

Table 3. Partial regression coefficients (β), crude and adjusted, between serum ferritin (γ) and red meat consumption (Xi) (times/d) in a population between 5 and 17 years of age, Colombia, ENSIN-2015

ENSIN-2015, Encuesta Nacional de la Situación Nutricional en Colombia-2015 (National Survey of the Nutritional Situation of Colombia-2015); Ref, reference; Q, quintile; Nd, no data.

* Partial regression coefficient achieved in a simple linear regression model.

Partial regression coefficient achieved in a multiple linear regression model, where the dependent variable is the serum ferritin level (μ/l), and the main explanatory variable is the frequency/d of red meat consumption. The model was adjusted for sex, age, nutritional status, level of food insecurity in the household, wealth index, ethnicity, and geographical area and region.

Based on BMI equivalents according to the International Obesity Task Force.

§ Based on the Latin American and Caribbean Food Security (ELCSA) Scale.

Table 4. Partial regression coefficients (β), crude and adjusted, between serum ferritin (γ) and egg consumption (Xi) (times/d) in a population between 5 and 17 years of age, Colombia, ENSIN-2015

ENSIN-2015, Encuesta Nacional de la Situación Nutricional en Colombia-2015 (National Survey of the Nutritional Situation of Colombia-2015); Ref, reference; Q, quintile; Nd, no data.

* Partial regression coefficient achieved in a simple linear regression model.

Partial regression coefficient achieved in a multiple linear regression model, where the dependent variable is the serum ferritin level (μ/l), and the main explanatory variable is the frequency/d of egg consumption. The model was adjusted for sex, age, nutritional status, level of food insecurity in the household, wealth index, ethnicity, and geographical area and region.

Based on BMI equivalents according to the International Obesity Task Force.

§ Based on the Latin American and Caribbean Food Security (ELCSA) Scale.

Discussion

It could be established that, in children between 5 and 17 years of age in Colombia, the average frequency (times/d) of usual consumption of red meat is lower than the consumption of eggs. Red meat is consumed every 2 d, while two eggs are consumed every 3 d. In addition, the prevalence of red meat and egg consumption is high, above 95 %, and combined is greater than 90 %. However, in order to meet the consumption/d targets established in the National Development Plan (Plan Nacional de Desarrollo (PND))(20) and the Food-Based Dietary Guidelines(21), the average frequency of red meat consumption among the population should be doubled – by 100 % – and egg consumption should be increased by at least 25 %. SF levels are very similar among meat and egg consumers; however, meat and/or egg consumers, who are the majority, have higher SF levels than consumers of one of the two foods exclusively (Fig. 1). The correlation between frequency of red meat and egg consumption is similar and statistically significant, which corroborated that these foods are determinants of SF levels and are, therefore, public policy options to decrease anaemia and Fe deficiency.

The mean frequency of red meat consumption was lower in children with stunted growth (chronic malnutrition), and inversely correlated to the levels of food insecurity in the household, in the indigenous and black/Afro-descendant ethnic groups, in the rural area and in all regions when compared with the central region. This finding may be explained to a large extent by the monetary poverty associated with undernourished individuals or ethnic minorities and, also, with a lower structural development in the peripheral regions or their proximal variables such as the rural area(Reference Jara Navarro31Reference Latham37). Having meat on the table requires a greater relative cost than that needed to have eggs, besides physical infrastructure to ensure the cold chain and others required for slaughter, which makes meat production more complex and costly. More precisely and based on red meat and egg prices in November 2018, 1 g of Fe derived from meat costs at least 1⋅5 times more than one egg derivative.

Red meat, according to the WHO through the International Agency for Research on Cancer (IARC)(Reference De Vries, Quintero and Henríquez-Mendoza38,Reference Bouvard, Loomis and Guyton39) , was classified as a group 2A agent: probable carcinogen. The dose (portion + frequency/d) of red meat consumed in Colombia by children between 5 and 17 years of age, according to the ENSIN-2005, was 54 g – average estimate derived from the current intake through the 24-h dietary recall(9) –, and the frequency/d according to the ENSIN is decreasing: 0⋅57 in 2010 and 0⋅49 in 2015. At these doses, the risk for developing colorectal or other cancers is very low(Reference De Vries, Quintero and Henríquez-Mendoza3840); red meat is a risk factor for the development of cancer when the dose reaches average amounts greater than 100 g/d and a frequency of one or more times per d(Reference Bouvard, Loomis and Guyton3943). According to the Colombian Cattle Ranching Association (Federación Colombiana de Ganaderos (Fedegan)), in 2015, the consumption of beef among the general population was 19⋅1 kg per capita, while the consumption of pork was 7⋅8 kg per capita. The amount of beef, as well as its frequency, has been decreasing (it was 18⋅6 kg in 2017) but pork consumption is increasing (9⋅4 kg per capita)(44). With this in mind, policies that tend to increase red meat consumption are useful to increase SF levels and do not generate cancer risk.

Due to their amino-acid content and bioavailability, eggs are among the best sources of protein(Reference Bouvard, Loomis and Guyton39). In the 1990s, and even at the beginning of the 21st century, their consumption was questioned for their cholesterol content – between 300 and 400 mg per 100 g – even though there is not enough evidence to state that dietary cholesterol is a risk factor for the development of CVD(Reference Berger, Raman and Vishwanathan45Reference Clayton, Fusco and Kern48). According to the National Poultry Farmers Fund of Colombia (Fondo Nacional de Avicultores de Colombia) and the National Poultry Fund (Fondo Nacional Avícola (FENAVI)), the egg industry has been growing steadily in the last 9 years. In 2017, a figure of 279 units per capita consumed by the general population was reported and an increase of fifteen units was expected for 2018(49). According to the ENSIN, the frequency/d in this age group also increased, going from 0⋅69 in 2010 to 0⋅76 in 2015.

In Colombia, as in many parts of the world, anaemia and Fe deficiency have been treated, among other interventions, with the fortification of wheat flour and other grains. According to Decree 1944 of October 28, 1996, wheat flour must be fortified with vitamin B1, vitamin B2, niacin, folic acid and Fe. Each kg of wheat flour should have at least 44 mg of Fe through ferrous fumarate(50). In Colombia, only wheat flour is enriched. The consumption of eggs and red meat is visible, that of wheat flour is invisible. Flour is found in preparations such as bread, cakes, sauces, etc., which makes it difficult to estimate the prevalence, frequency/d and the amount consumed. Also, in Colombia, other situations make measurement even more difficult, e.g. there is the smuggling of flour at the borders; so much of what is consumed is not enriched. Enriched flour does not necessarily contain the same amounts, since the standard establishes a minimum level but is not mandatory, so some producers add ferrous fumarate above the minimum level. Therefore, it is not possible to introduce a non-haem indicator in the analysis.

Although many countries in the world fortify grains with Fe, few evaluate the impact of this intervention; Colombia is one of them. However, evidence consistently suggests that fortification increases SF levels, but not Hb levels(Reference Pachón51). The prevalence of anaemia and Fe deficiency in the Colombian population and in the age group studied here suggests that, while fortification of wheat flour is important as a public health measure, it is not sufficient, nor is it the only one that should be considered. Since the percentage of bioavailability of haem Fe is three times higher than that of non-haem Fe and, once consumed, its absorption can be increased up to four times if it is accompanied by acidic juices(Reference Callender, Marney and Warner52), dietary interventions based on the consumption of red meat and eggs within a comprehensive strategy consistent with Food-Based Dietary Guidelines, which address other public health problems such as childhood obesity, should be considered(21). Energy expenditure should be decisive in these strategies, because there is evidence of excessive protein consumption in children in Colombia(Reference Herrán, DelCastillo and Patiño6). In addition, red meat and eggs are part of the traditional consumption pattern, which actually protects children from excess weight in Colombia(Reference Ocampo, Prada and Herrán8).

In diets rich in cereals of vegetarians, the addition of eggs showed that due to phosphovitin contained in the yolk, Fe absorption may be decreased between 16 and 50 %(Reference Singh, Bains and Kaur53). However, in Colombia, eggs are not only consumed for Fe, but they are also the main source of protein of high biological value and the most economical. The prevalence of vegetarianism in Colombia is less than 1 %(10), and in any case, these findings in vitro would be in favour of the association reported here, because if this effect were important in Colombia, it would mitigate the associations reported.

Finally, all structural aspects that directly or indirectly constitute barriers for red meat and eggs to reach the plates of children and the Colombian population, in general, or, specifically, to the detriment of their availability and consumption, both in quantity and frequency/d, are against public health. Discouraging rural development, taxing the basic food basket and foods that are traditionally consumed by the population, the armed conflict, disinformation about the dietary properties of food and their relationship with chronic disease, the inability to control borders and allow contraband, poor phytosanitary control in the regions, the lack of energy infrastructure and other reasons external to the nutrition sector are the structural aspects referred to.

Scope and limitations of the study

Usual food consumption is stable in the medium and long term. The estimates made by the ENSIN-2005, and more recently by Federación Colombiana de Ganaderos (Fedegan) and Fondo Nacional Avícola (FENAVI), allow approximating reliably the amount (g) consumed by children. The frequency (times/d) estimated with an FFQ is the best mechanism to calculate the usual intake; therefore, the correlation found between SF levels and red meat and egg consumption with ENSIN-2015 data is plausible and also valid. The ENSIN-2015 is still being developed; future results of the 24-h recall, which allow incorporating the amount (g) of red meat and eggs consumed, will facilitate the understanding of the correlation between red meat and egg consumption with SF levels and the design of population-based dietary interventions. The results presented here on frequency/d of consumption can be used as a baseline to evaluate the impact of policies aimed at increasing red meat and egg consumption.

Acknowledgements

The present study received no specific grant from any funding agency, commercial or not-for-profit sectors.

O. F. H. and J. N. B. designed the study, obtained the databases of the ICBF (Instituto Colombiano de Bienestar Familiar; Colombian Family Welfare Institute), prepared the databases and conducted and led statistical analyses. O. F. H., J. N. B. and M. del P. Z. interpreted the results, prepared, reviewed and wrote the manuscript that was finally submitted. All authors reviewed the manuscript and approved the final version.

The authors declare that they have no conflicts of interest.

References

Bowman, B & Russell, R (editors) (2003) Current Knowledge of Nutrition. Scientific and Technical Publication, no. 592. Washington: PAHO.Google Scholar
Garry, PJ, Hunt, WC & Baumgartner, RN (2000) Effects of iron intake on iron stores in elderly men and women: longitudinal and cross-sectional results. J Am Coll Nutr 19, 262269.CrossRefGoogle ScholarPubMed
Nel, E, Kruger, HS, Baumgartner, J, et al. . (2015) Differential ferritin interpretation methods that adjust for inflammation yield discrepant iron deficiency prevalence. Matern Child Nutr 11, Suppl. 4, 221228.CrossRefGoogle ScholarPubMed
Nairz, M, Theurl, I, Wolf, D, et al. (2016) Iron deficiency or anemia of inflammation? Wien Med Wochenschr 166, 411423.CrossRefGoogle ScholarPubMed
Food and Nutrition Board, Institute of Medicine, National Academies (2018) Dietary Reference Intakes (DRIs), Recommended Dietary Allowances and Adequate Intakes, Vitamins. https://www.ncbi.nlm.nih.gov/books/NBK56068/table/summarytables.t2/?report=objectonly (accessed March 2020).Google Scholar
Herrán, O, DelCastillo, S & Patiño, GA (2017) Exceso de proteínas en la pobreza: la paradoja del exceso de peso en niños colombianos (Excess protein in poverty: the paradox of excess weight in Colombian children). Rev Chil Nutr 44, 4556.CrossRefGoogle Scholar
Herrán, OF, Patiño, GA & DelCastillo, SE (2016) La transición alimentaria y el exceso de peso en adultos evaluados con base en la Encuesta de la Situación Nutricional en Colombia, 2010 (The food transition and excess weight in adults evaluated based on the Survey of the Nutritional Situation in Colombia, 2010). Biomédica 36, 109120.Google Scholar
Ocampo, PR, Prada, GE & Herrán, OF (2014) Patrones de consumo alimentario y exceso de peso infantil; encuesta de la situación nutricional en Colombia, 2010 (Food consumption patterns and excess childhood weight; a survey of the nutritional situation in Colombia, 2010). Rev Chil Nutr 41, 351359.CrossRefGoogle Scholar
Profamilia, Instituto Nacional de Salud, Universidad de Antioquia, OPS, Instituto Colombiano de Bienestar Familiar (2005) National Survey of the Nutritional Situation of Colombia. Bogotá, DC: ICBF.Google Scholar
Ministerio de la Protección Social, Instituto Colombiano de Bienestar Familiar (2011) National Survey of the Nutritional Situation in Colombia, 2010. Bogotá, DC: ICBF.Google Scholar
Instituto Colombiano de Bienestar Familiar (2015) Colombian Food Composition Table. Bogotá, DC: ICBF.Google Scholar
Organización Mundial de la Salud (OMS) (2011) Concentraciones de hemoglobina para diagnosticar la anemia y evaluar su gravedad. WHO/NMH/NHD/MNM/11.1. VMNIS. Sistema de Información Nutricional sobre Vitaminas y Minerales (Hemoglobin concentrations to diagnose anemia and assess its severity. WHO/NMH/NHD/MNM/11.1. VMNIS. Vitamin and Mineral Nutrition Information System). Gibebra: OMS. https://www.who.int/vmnis/indicators/haemoglobin_es.pdf (accessed March 2020).Google Scholar
Petry, N, Olofin, I, Hurrell, R, et al. (2016) The proportion of anemia associated with iron deficiency in low, medium, and high human development index countries: a systematic analysis of national surveys. Nutrients 8, 693710.CrossRefGoogle ScholarPubMed
Haas, JD & Brownlie, T (2001) Iron deficiency and reduced work capacity: a critical review of the research to determine a causal relationship. J Nutr 131, 676S690S.CrossRefGoogle ScholarPubMed
Beard, JL, Borel, MJ & Derr, J (1990) Impaired thermoregulation and thyroid function in iron-deficiency anemia. Am J Clin Nutr 52, 813819.CrossRefGoogle ScholarPubMed
Beard, JL (2001) Iron biology in immune function, muscle metabolism and neuronal functioning. J Nutr 131, 568S580S.CrossRefGoogle ScholarPubMed
De Andrade Cairo, RC, Rodrigues Silva, L, Carneiro Bustani, N, et al. (2014) Iron deficiency anemia in adolescents; a literature review. Nutr Hosp 29, 12401249.Google ScholarPubMed
Li, W, Herrán, OF & Villamor, E (2017) Trends in iron, zinc, and vitamin A status biomarkers among Colombian children: results from 2 nationally representative surveys. Food Nutr Bull 38, 146157.CrossRefGoogle ScholarPubMed
Subramaniam, G & Girish, M (2015) Iron deficiency anemia in children. Indian J Pediatr 82, 558564.CrossRefGoogle ScholarPubMed
DPN (Departamento Nacional de Planeación) (2015) Plan Nacional de Desarrollo, 2014–2018 (National Development Plan, 2014–2018). Bogotá, Colombia: Departamento Nacional de Planeación.Google Scholar
Instituto Colombiano de Bienestar Familiar (ICBF) (2015) Guias Alimentarias Basadas en Alimentos: Para la Población Colombiana Mayor de 2 Años (Food Based Food Guides: For the Colombian Population Over 2 Years). ICBF. Bogotá, Colombia: ICBF.Google Scholar
Bautista, LE, Herrán, OF & Pryer, JA (2005) Development and simulated validation of a food-frequency questionnaire for the Colombian population. Public Health Nutr 8, 181188.CrossRefGoogle ScholarPubMed
Herrán, OF & Ardila, MF (2006) Validity and reproducibility of two semi-quantitative alcohol frequency questionnaires for the Colombian population. Public Health Nutr 9, 763770.CrossRefGoogle ScholarPubMed
Cole, TJ, Bellizzi, MC, Flegal, KM, et al. (2000) Establishing a standard definition for child overweight and obesity worldwide: international survey. Br Med J 320, 12401243.CrossRefGoogle ScholarPubMed
Cole, TJ & Lobstein, T (2012) Extended international (IOTF) body mass index cut-offs for thinness, overweight and obesity. Pediatr Obes 7, 284294.CrossRefGoogle ScholarPubMed
Rutstein, SO (2008) The DHS Wealth Index: Approaches for Rural and Urban Areas. Calverton, MD: Macro International.Google Scholar
Gutierres de Pineda, V (1994) Familia y cultura en Colombia (Family and Culture in Columbia), 3rd ed.Medellín, Colombia: Universidad de Antioquia.Google Scholar
StataCorp (2015) Stata Statistical Software: Release 14. College Station, TX: StataCorp LP.Google Scholar
Asociación Médica Mundial (2015) Declaración de Helsinki – Principios éticos para las investigaciones médicas en seres humanos (Declaration of Helsinki – Ethical principles for medical research in humans). https://www.wma.net/es/policies-post/declaracion-de-helsinki-de-la-amm-principios-eticos-para-las-investigaciones-medicas-en-seres-humanos/ (accessed November 2018).Google Scholar
Ministerio de Salud (Colombia) (1993) Resolución Numero 8430 de 1993 (Resolution number 8430 of 1993). https://www.minsalud.gov.co/sites/rid/Lists/BibliotecaDigital/RIDE/DE/DIJ/RESOLUCION-8430-DE-1993.PDF (accessed November 2018).Google Scholar
Jara Navarro, MI (2008) Hambre, desnutrición y anemia: una grave situación de salud pública (Hunger, malnutrition and anaemia: a serious public health situation). Rev Gerenc Polit Salud 7, 710.Google Scholar
von Grebmer, K, Torero, M, Olofinbiyi, T, et al. (2011) Índice global del hambre. El desafío del hambre: domar la volatilidad excesiva y los picos de los precios alimentarios (Global hunger index. The hunger challenge: control excessive volatility and spikes in food prices). Washington, DC: IFPRI. http://cdm15738.contentdm.oclc.org/utils/getfile/collection/p15738coll2/id/124875/filename/124876.pdf (accessed November 2014).Google Scholar
Herrán, OF, Patiño, GA & DelCastillo, SE (2015) Desigualdad y nutrición: encuesta de la situación nutricional en Colombia, 2010 (Inequality and nutrition: survey of the nutritional situation in Colombia, 2010). Rev Bras Saude Mater Infant 15, 401412.CrossRefGoogle Scholar
Programa de las Naciones Unidas para el Desarrollo (PNUD) (2013) Informe de Desarrollo Humano, 2013 (Human Development Report, 2013). New York: PNUD.Google Scholar
DNP, Consejo Nacional de Política Económica y Social (2007) National Food and Nutrition Security Policy, CONPES 113. Bogotá, DC: DNP.Google Scholar
FAO, OSAN (2014) Aproximación a los determinantes de la doble carga nutricional en Colombia (Approach to the Determinants of the Double Nutritional Burden in Colombia). Bogotá, DC: Food and Agriculture Organization of the United Nations.Google Scholar
Latham, MC (2002) Nutrición humana en el mundo en desarrollo (Human nutrition in the developing world). http://www.fao.org/docrep/006/w0073s/w0073s00.htm#Contents (accessed November 2018).Google Scholar
De Vries, E, Quintero, DC, Henríquez-Mendoza, G, et al. (2017) Population attributable fractions for colorectal cancer and red and processed meats in Colombia – a macro-simulation study. Colombia Med 48, 6469.Google ScholarPubMed
Bouvard, V, Loomis, D, Guyton, KZ, et al. (2015) Carcinogenicity of consumption of red and processed meat. Lancet Oncol 16, 15991600.CrossRefGoogle ScholarPubMed
Ministerio de Salud y Protección Social (2015) Riesgo de cáncer por consumo de carnes es bajo en Colombia. Minsalud. Boletín de Prensa No 289 de 2015 (Cancer risk due to meat consumption is low in Colombia. Minsalud Press release no. 289 of 2015). https://www.minsalud.gov.co/Paginas/Riesgo-de-cáncer-por-consumo-de-carnes-es-bajo-en-Colombia.aspx (accessed July 2018).Google Scholar
World Health Organization & Unión Internacional Contra el Cáncer (2005) Acción mundial contra el cancer (Global action against cancer). http://www.who.int/cancer/media/AccionMundialCancerfull.pdf (accessed October 2018).Google Scholar
World Health Organization (2018) Cáncer (Cancer). http://www.who.int/mediacentre/factsheets/fs297/es/ (accessed October 2018).Google Scholar
Federación Colombiana de Ganaderos (2018) Consumo|Fedegan. Estadísticas de consume (Consumption|Fedegan. consumption statistics). https://www.fedegan.org.co/estadisticas/consumo-0 (accessed November 2018).Google Scholar
Berger, S, Raman, G, Vishwanathan, R, et al. (2015) Dietary cholesterol and cardiovascular disease: a systematic review and meta-analysis. Am J Clin Nutr 102, 276294.CrossRefGoogle ScholarPubMed
Bautista, LE, Herrán, OF & Serrano, C (2001) Effects of palm oil and dietary cholesterol on plasma lipoproteins: results from a dietary crossover trial in free-living subjects. Eur J Clin Nutr 55, 748754.CrossRefGoogle ScholarPubMed
Zárate, A, Manuel-Apolinar, L, Basurto, L, et al. (2016) Colesterol y aterosclerosis. Consideraciones históricas y tratamiento (Cholesterol and atherosclerosis. Historical considerations and treatment). Arch Cardiol Méx 86, 163169.Google Scholar
Clayton, ZS, Fusco, E & Kern, M (2017) Egg consumption and heart health: a review. Nutrition 37, 7985.CrossRefGoogle ScholarPubMed
FENAVI (Federación Nacional de Avicultores de Colombia. Fondo Nacional Avicola) (2018) Huevo en cifras (Eggs in figures). http://fenavi.org/centro-de-noticias/noticia-destacada-del-centro-de-noticias/pollo-en-cifras-2/ (accessed November 2018).Google Scholar
Ministerio de Salud Publica (1996) Presidencia de la República de Colombia. DECRETO 1944 de Octubre 28 de 1996. Diario Oficial no. 42.909, de 30 de octubre de 1996 (Presidency of the Republic of Colombia. DECREE 1944 of October 28, 1996. Official Gazette no. 42.909, of October 30, 1996). https://www.icbf.gov.co/cargues/avance/docs/decreto_1944_1996.htm (accessed November 2018).Google Scholar
Pachón, H (2014) Avances en la fortificación de harina de trigo a nivel global (Advances in the fortification of wheat flour globally). An Venez Nutr 27, 3139.Google Scholar
Callender, ST, Marney, SR & Warner, GT (1970) Eggs and iron absorption. Br J Haematol 19, 657665.CrossRefGoogle ScholarPubMed
Singh, A, Bains, K & Kaur, H (2016) Effect of inclusion of key foods on in vitro iron bioaccessibility in composite meals. J Food Sci Technol 53, 20332039.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Serum ferritin levels in children between 5 and 17 years of age according to red meat and egg consumption, Colombia, ENSIN-2015 (Encuesta Nacional de la Situación Nutricional en Colombia-2015; National Survey of the Nutritional Situation of Colombia-2015). The line inside the box represents the median (quartile 2; Q2). The edges of the box represent quartile 1 (Q1) and quartile 3 (Q3), respectively. The limits of the whiskers represent up to 1·5 times the interquartile range (IQR = Q3 − Q1): Q1 − 1·5 or Q3 + 1·5. The points to the right and left represent extreme atypical values.

Figure 1

Table 1. Red meat consumption (times/d) and serum ferritin levels (μg/l) among red meat consumers in a population between 5 and 17 years of age, Colombia, ENSIN-2015(Mean values with their standard errors; differences and 95 % confidence intervals)

Figure 2

Table 2. Egg consumption (times/d) and serum ferritin levels (μg/l) among egg consumers in a population between 5 and 17 years of age, Colombia, ENSIN-2015(Mean values with their standard errors; differences and 95 % confidence intervals)

Figure 3

Fig. 2. Adjusted serum ferritin levels and frequency of red meat and egg consumption (times/d). Colombia, ENSIN-2015 (Encuesta Nacional de la Situación Nutricional en Colombia-2015; National Survey of the Nutritional Situation of Colombia-2015).

Figure 4

Table 3. Partial regression coefficients (β), crude and adjusted, between serum ferritin (γ) and red meat consumption (Xi) (times/d) in a population between 5 and 17 years of age, Colombia, ENSIN-2015

Figure 5

Table 4. Partial regression coefficients (β), crude and adjusted, between serum ferritin (γ) and egg consumption (Xi) (times/d) in a population between 5 and 17 years of age, Colombia, ENSIN-2015