nutrients

Article

Adequacy of Usual Vitamin and Mineral Intake in
Spanish Children and Adolescents: ENALIA Study

Ana M. López-Sobaler 1,*, Aránzazu Aparicio 1, Liliana G. González-Rodríguez 2,
Esther Cuadrado-Soto 1, Josefa Rubio 3, Victoria Marcos 3, Rosa Sanchidrián 3, Sara Santos 3,
Napoleón Pérez-Farinós 3, Marian Ángeles Dal Re 3, Carmen Villar 3, Teresa Robledo 3,
J. Javier Castrodeza 3 and Rosa M. Ortega 1

1 VALORNUT Research Group, Department of Nutrition, Faculty of Pharmacy, Complutense University,
Plaza Ramón y Cajal s/n, Madrid 28040, Spain; araparic@ucm.es (A.A.);
esther.cuadrado90@gmail.com (E.C.-S.); rortega@ucm.es (R.M.O.)

2 VALORNUT Research Group, Faculty of Health Sciences, Alfonso X El Sabio University,
Villanueva de la Cañada, Madrid 28691, Spain; liligoro@uax.es

3 Spanish Agency for Consumer Affairs, Food Safety and Nutrition, Ministry of Health,
Social Services and Equality, C/Alcalá 56, Madrid 28071, Spain; jrubiom@msssi.es (J.R.);
VMarcos@msssi.es (V.M.); rsanchidrian@msssi.es (R.S.); ssantos@msssi.es (S.S.); nperezf@msssi.es (N.P.-F.);
mdalre@msssi.es (M.Á.D.-R.); cvillar@msssi.es (C.V.); trobledo@msssi.es, (T.R.); preaecosan@msssi.es (J.J.C.)

* Correspondence: asobaler@ucm.es; Tel.: +34-91-3941732; Fax: +34-91-3941810

Received: 24 October 2016; Accepted: 8 February 2017; Published: 13 February 2017

Abstract: Background: The National Dietary Survey on the Child and Adolescent Population in Spain
(ENALIA) provides data to assess the usual micronutrient intake among Spanish infants, children,
and adolescents. Methods: Cross-sectional survey (November 2012–July 2014) of a representative
sample of Spanish children and adolescents (six months–17 years) (n = 1862). Dietary information
was collected using two non-consecutive one-day food diaries (six months–10 years old) or two 24 h
dietary recalls (11 years and older) separated by at least 14 days. Estimates were calculated using the
Iowa State University method and PC-SIDE software (version 1.0, department of statistics, center
for agricultural and rural development, Ames, IA, USA) to account for within- and between-person
variation. Results: Usual intake of vitamin D was insufficient in practically all individuals. Vitamin E,
folate, and calcium were insufficient, especially from nine years of age, and magnesium and iodine
from 14 years of age. The percentage of subjects with insufficient intakes was higher among females.
Sodium intake was excessive in a considerable percentage of the population, especially in males, and
it increased with age. Finally, over half of children under four years of age had zinc usual intakes that
exceeded the Tolerable Upper Level. Conclusion: Vitamin and mineral intake in Spain should be
improved, especially in late childhood and adolescence. Nutritional intervention and educational
strategies are needed to promote healthy eating habits and correct micronutrient inadequacies in
Spanish children and adolescents.

Keywords: usual intake; children; adolescents; micronutrient; vitamins; minerals; Spain

1. Introduction

Early childhood is the most rapid period of development and following a balanced diet in
these stages is essential to ensure optimal growth and development [1]. Adolescence is another
critical period of growth, during which the requirements for vitamins, minerals and trace elements
increase substantially [2]. In addition, dietary habits are developed in childhood and adolescence and
tend to remain through later stages of life [3–5], and unbalanced dietary habits during infancy and
adolescence can have long-term implications, such as osteoporosis [6] and cardiovascular diseases [7].

Nutrients 2017, 9, 131; doi:10.3390/nu9020131 www.mdpi.com/journal/nutrients

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Nutrients 2017, 9, 131 2 of 18

This information highlights the importance of monitoring nutritional status and implementing health
education programs in childhood and adolescence.

Dietary surveys provide insight into dietary habits and food intake and help estimate the adequacy
of the nutrient intake of different groups in a population, monitor their changes and develop nutritional
interventions. One of the challenges in dietary surveys is the assessment of usual intakes, i.e., the
long-term dietary information. Single or repeated 24 h dietary recalls or food records are used for
dietary assessment in large epidemiological studies [8] because they provide rich detail about food
and beverage intakes. However, the within-person variation in short-term dietary data is large, so
the intakes measured for a single day may provide a poor estimate of the long-term intake [9,10].
Repeated short-term measures are then needed, at least in a subgroup, to provide valid estimations
for the population distributions of the usual dietary intake. Some methods have been developed
for estimating the usual dietary intake based on repeated short-term measures [11], but few studies,
especially in children, have applied them.

Until now the reference study on children and young people in Spain was the enKid study. It was
conducted between 1998 and 2000 on 2855 Spanish children and adolescents aged between two and
24 years [12]. Dietary intake was assessed with one 24 h dietary recall and a second 24 h recall was used
on a subsample (25%) to correct for the intra-individual variation to estimate usual nutrient intakes.
Nutritional adequacy in Spanish children and adolescents was, in general, adequate, although high
inadequate intakes of vitamins D, E, A, folate, iron, calcium, and magnesium were found. Adolescents
were those with the highest nutritional risk, especially among girls.

The ENALIA study (“Encuesta Nacional de ALimentación en Población Infantil y Adolescente
de España” or “National Dietary Survey in Spanish Children and Adolescents”) is a cross-sectional
survey that was carried out in Spain and sought to collect accurate food consumption data in children
and adolescents in a way that is consistent with other European countries [13–15]. The ENALIA study
was designed and developed by the AECOSAN (Spanish Agency for Consumer Affairs, Food Safety,
and Nutrition) at the Ministry of Health, Social Services, and Equality to understand and monitor the
diet of Spanish children and adolescents and to provide current data as a reference to analyze dietary
trends over time. Thus, the present study provides recent data on the usual micronutrient intake from
food and beverage sources for Spanish children, from six months until 18 years of age, and establishes
the proportion of subjects who are most at risk for nutrient inadequacy and/or adverse effects.

2. Materials and Methods

2.1. Study Design

The ENALIA study was a cross-sectional survey conducted in Spain on a national sample of
children and adolescents (six months–18 years old). The design, protocol, and methodology of the
ENALIA study have been already described elsewhere [16,17] and followed the European Food
Safety Agency (EFSA) “EU Menu” guidance recommendations [15]. This survey had a stratified
cluster-sampling design and was representative at a national level. Briefly, the ENALIA study was
designed to collect food consumption data and information on eating habits in Spanish children and
adolescents between six months and 18 years of age.

The study was conducted according to the guidelines laid down in the Declaration of Helsinki.
Depending on the age of participants, information was given to parents, tutors, or other legal
representatives, and consent and assent from each participant were obtained before proceeding
with the study interviews. The Spanish Agency of Consumption, Food Security, and Nutrition
(AECOSAN), belonging to the Spanish Ministry of Health, Social Services and Equality, approved the
study. In accordance with the Spanish Ethical Review System, ethical approval was exempt from ethical
review because this is a population-based survey, no intervention were done, no human biological
samples were collected, and all data from the study were anonymized and de-identified.



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2.2. Sample

The target population was people under 18 years old living in households in Spain. The ENALIA
study began in November 2012 and ended in July 2014. Institutionalized populations were excluded.
Recruitment was done via home visits and for children under four years of age, also in kindergartens,
since in Spain they are only for the day care of the children. Subjects were randomly chosen
from all 17 autonomous regions in Spain, according to a random multistage sampling procedure,
considering census section and municipality, population size (<10,000, 10,000–100,000, 100,000–500,000,
>500,000 inhabitants), age, and sex. To capture the inter-seasonal variability in consumption patterns,
subjects were uniformly distributed over the four different seasons, and the schedule was organized
to capture an adequate proportion of weekdays and weekend days at the population group level.
The sample was also distributed uniformly over the weeks in a month. The recruitment process
included five contacts: an initial contact with household by phone or at nurseries/kindergarten
(for children under three years of age), a second contact by letter (including the general questionnaire
and the diary/24 h recall), two more contacts by phone (to confirm the consent to participate, to
conduct the general questionnaire in the third contact, and the first diary/24 h recall in the fourth
contact), and a fifth final contact with a household visit (where the second diary/24 h recall and
anthropometric study were done).

The ENALIA final sample included 1862 children aged six months to 17.9 years. The participation
rate was 68.9%. Table 1 describes the sample size by age and gender.

2.3. Dietary Study

Dietary information was collected using two different methodologies depending on the child’s
age: two non-consecutive one-day food diaries separated by at least 14 days, for children from six
months to 10 years of age or two 24 h dietary recalls, separated by at least 14 days, for adolescents
(11 years old and over). In younger groups of children (under 11 years old), parents and caregivers were
responsible for completing the food diaries and the other questionnaires, and requested collaboration
and/or information from other proxy persons about the child’s out-of-home diet. The recalls were
conducted using specific software (ENIA-Soft) (version 5.0, Demométrica SL, Madrid, Spain) in
computer-assisted interviews by trained interviewers and nutritionists/dieticians. Food diaries were
also recorded using this software, since guided the interviewer during data collection, facilitating the
homogenous collection of information. The software included a database with coded foods, a database
with standard recipes, a database with weights and household measurements, and a database with
pictures and portion weights from a validated photographic food atlas for Spanish children and
adolescents [16]. The pictures were used for the correct identification of the dishes, which were then
disaggregated into their ingredients according to standard recipes. It was possible to adapt standard
recipes to the actual ingredients used (including salt). Consumed amounts were estimated using the
pictures complemented by household measures and portions indicated in standard recipes. For both
food records and 24 h recalls participants were asked about the use of salt at each eating occasion
(during preparation, cooking and at the table), and the type of salt consumed (regular or iodized).
A food propensity questionnaire (which included the frequency of use of supplements) that was
specially designed for infants and adolescents complemented both methods [16]. Of the 1862 children,
1780 provided two dietary records/recalls.

Nutrient intake was calculated from dietary records/recalls using the Spanish Food Composition
Tables [18] completed with additional data on nutrient composition for specific brands and
enriched/fortified foods. There was only information on the frequency of use of supplements,
not on quantities and brands used, so any data on nutrient intake represented only that from food
and beverages. Niacin was expressed as equivalents of niacin (preformed niacin + tryptophan/60).
For vitamin A from β-carotene, a conversion factor of 1/6 was used, whereas for the other carotenoids,
a conversion factor of 1/12 was used. Vitamin E was expressed as alpha-tocopherol equivalents, and



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folate intake was calculated as µg of dietary folate equivalents (DFE) (food folate + 1.7 × synthetic
folic acid content of fortified food).

2.4. Socio-Demographic and Anthropometric Information

A general questionnaire asked about sociodemographic data, such as the birth date of the
participant, place/country of origin of the participant and his/her parents, academic level and
profession of parents, and about the health status of the participant (e.g., special diet, use of drugs,
chronic or acute diseases).

Anthropometric data of the participant were measured at the interviewee’s home by trained
interviewers and following standardized procedures [19]. A stadiometer was used to measure stature
in subjects aged two years and older, and an infantometer was used to measure the recumbent length
of subjects aged six to 24 months old. Stature and length were measured in meters. A digital weight
scale with an accuracy of 0.1 kg was used.

2.5. Statistical Analysis

Sample weight factors for each participant were calculated to account for nonresponses and to
weight the sample to known population demographic characteristics. Since the average intake of
a small number of days of dietary record/recall (observed intakes) does not adequately reflect the
usual intake, it is necessary to statistically model the dietary data to eliminate day-to-day variation in
food consumption [12]. We used the method developed by Nusser et al. [20], also known as the Iowa
State University (ISU) method. Briefly, the ISU method consists of three steps: (1) a transformation
step that maps intakes into a normal scale; (2) an estimation step to estimate the parameters of usual
intake by using a measurement error framework; and (3) a back-transformation step to return the
estimated usual intakes to their original scale. The ISU method was implemented using the PC-SIDE
software (version 1.0, 2003), which was designed for this purpose. This program estimated the
percentiles of usual nutrient intake distributions and the proportions above or below the defined
Dietary Reference Intakes (DRI) cut-off values. The interview day (day 1 or day 2), the day of the week,
season, and sample weighting factor were considered in the adjustment of dietary data, stratifying by
sex and age group.

To assess vitamin and mineral adequacy, the Estimated Average Requirement (EAR) cut-off
point method was used [21]. We used the Institute of Medicine’s (IOM) DRIs since the Spanish DRIs
do not provide estimated average requirement (EAR) values we required for our analyses. IOM’s
DRI are regularly updated and frequently used compared to reference values provided by other
scientific bodies of organizations. The proportion of the population with usual intakes less than the
EAR provides an estimate of the proportion of the group whose intakes do not meet the nutrient
requirement. There are only established EARs for iron and zinc for children under one year of age.
The Adequate Intake (AI) cannot be used to determine the proportion of individuals in a group with
an inadequate nutrient intake. For Fe, we used the probability approach recommended by the Institute
of Medicine [22] because the presence of menstruating women skews the requirement distribution
curve and renders the EAR cut-off point inappropriate. For nutrients with established Tolerable Upper
Intake Levels (ULs), the proportion of children with usual intakes exceeding the UL were computed.

The plausibility of energy intakes was assessed using the Goldberg’s cut-off method [23] updated
by Black [24], following the methodology applied in other European children [25]. Basal metabolic
rate (BMR) was estimated by Schofield equations [26], taking into account age, sex, body height,
and weight [23,24]. Age- and sex-specific cut-offs for children and adolescents were calculated as
suggested [27], using specific reference values for the within-subject coefficient of variation for energy
intake (EI), BMR, and physical activity, as given in Nelson et al. [28] and Black [24]. Under reporters
were identified as those with EI/BMR ratios up to 0.73–1.08, while over reporters were identified by
EI/BMR ratios above 2.29–2.88, depending on the subject’s age and sex.



Nutrients 2017, 9, 131 5 of 18

Statistical analyses were performed using the statistical software package SPSS version 20.0 for
Windows. A p value < 0.05 indicated statistical significance. The normality of the distribution of age,
anthropometric and EI/BMR data was checked using the Kolmogorov–Smirnov test. Differences
between males and females were examined with the Student’s t test or the Mann-Whitney U test,
depending on whether or not the data were normally distributed. Categorical variables were compared
using the χ2 test. Dietary intakes of the participants were expressed as the means and standard
deviations, medians, and 5th and 95th percentiles.

3. Results

Characteristics of the studied sample are shown in Table 1. The highest percentage of users
of dietary supplements was found in the group of children between six and 12 months (24.7%).
The percentage of users in other age groups ranged from 3.6% (in children between four and eight
years) to 7.7% (14–18 years). The most used supplement in children between six and 12 months was
vitamin D (20.3% of children), while only 1.5% of children between one and three years used it. In the
other age groups, less than 0.5% of children used vitamin D supplements. Regarding multivitamins
with or without minerals, their use ranged from 1.0% in children between six and 12 months and 3.4%
in children between nine and 13 years.

The percentage of under-reporters ranged from 0.6% (children aged six to 12 months) to 19.8%
(adolescents aged 14–17 years). On the other hand, overestimation was higher in younger children
(16%) and lower in adolescents (0.4%). The data presented in the rest of this report have not been
adjusted for under-reporting.

The usual intakes (from food and beverage sources only) of vitamins and minerals are presented
in Tables 2 and 3, respectively. Dietary inadequacy regarding vitamins was particularly high for
vitamin D, which was inadequate in almost all of the population, followed by vitamin E, especially in
adolescents over 14 years. Water-soluble vitamin intakes were adequate in general, except for folate,
because more than 50% of the participants over nine years of age had intakes below the specific sex-age
EAR. Vitamins A, C, and thiamin intakes (in females) were also inadequate in a subset of adolescents
(10.1%–13.0%, 7.8%–5.4% and 8.2%, respectively). The vitamin intakes did not exceed the ULs, except
that of folate in a subset of children between one and three years of age (4.4%–6.1%, Table 2).

Regarding the usual intake of minerals, the prevalence of inadequate intakes in children below
four years of age was low (<5%), except for iron in children between six and 12 months and for
iodine in children between one and three years, where a subset of infants (10.9%–14.2% for iron and
11.0%–7.8% for iodine, Table 3) had inadequate intakes. The prevalence of mineral inadequacy in
older children and adolescents was in general very low, except for those of calcium (especially in
children over nine years of age), magnesium and iodine (in adolescents 14 years old and over). Mineral
inadequacy tended to be higher in adolescent females. There are no established EARs for potassium,
but the median and 95th percentile intakes suggest that a low percentage of the participants had
suitable potassium intakes.

The usual intake of minerals exceeded the ULs for sodium in a high percentage of children and
adolescents, and the prevalence of higher usual intakes increased with age (Table 3). In addition,
more than half of the population had usual zinc intakes that exceeded the ULs in children between six
months and four years of age.



Nutrients 2017, 9, 131 6 of 18

Table 1. Characteristics of the studied sample in the ENALIA study.

Total Boys Girls

n 1862 967 895
Age (years), X ± SD 8.8 ± 4.9 8.9 ± 4.9 8.8 ± 4.8
Age group, n (%)

6–12 months 292 (15.7) 138 (14.3) 154 (17.2)
1–3 years 407 (21.9) 218 (22.5) 189 (21.1)
4–8 years 418 (22.5) 211 (21.8) 207 (23.1)
9–13 years 470 (25.2) 243 (25.1) 227 (25.4)
14–17 years 275 (14.8) 157 (16.2) 118 (13.2)

Anthropometric
characteristics

Weight (kg), X ± SD 34.25 ± 18.15 35.36 ± 19.23 33.07 ± 16.88 *
Height (cm), X ± SD 131.6 ± 30.4 133.0 ± 31.5 130.1 ± 29.1 *
BMI (kg/m2), X ± SD 18.1 ± 3.1 18.1 ± 3.0 18.0 ± 3.1
Z-BMI, X ± SD 0.33 ± 1.20 0.37 ± 1.27 0.29 ± 1.13

Community size a n, (%)
<10,000 358 (19.2) 184 (19.0) 174 (19.4)
10,000–100,000 761 (40.9) 380 (39.3) 381 (42.6)
100,000–500,000 466 (25.0) 256 (26.5) 210 (23.5)
>500,000 277 (14.9) 147 (15.2) 130 (14.5)

Father’s education (%)
Mandatory or less b 573 (31.1) 300 (31.4) 273 (30.8)
Secondary 536 (29.1) 283 (29.7) 253 (28.6)
University 731 (39.7) 371 (38.9) 360 (40.6)

Mother’s education (%)
Mandatory or less b 455 (24.5) 239 (24.8) 216 (24.2)
Secondary 504 (27.1) 256 (26.6) 248 (27.8)
University 898 (48.4) 469 (48.7) 429 (48.0)

Dietary supplements
Vitamin D 28 (1.5) 12 (1.2) 16 (1.7)
Vitamin B complex 7 (0.4) 5 (0.5) 2 (0.2)
Vitamin C 11 (0.6) 5 (0.5) 6 (0.7)
Multivitamins 13 (0.7) 6 (0.6) 7 (0.8)
Multivitamins and

minerals 27 (1.4) 15 (1.6) 12 (1.3)
Iron 7 (0.4) 5 (0.5) 2 (0.2)
Calcium 7 (0.4) 4 (0.4) 3 (0.3)
Fatty acids 14 (0.8) 6 (0.7) 8 (0.9)
Others 32 (1.7) 17 (1.8) 15 (1.7)
Total 131 (7.0) 63 (6.6) 68 (7.5)

Dietary information
1st recall/record 1862 (100) 967 (100) 895 (100)
2nd recall/record 1780 (95.6) 924 (95.6) 856 (95.6)

Energy intake (kcal/day)
6–12 months 1065 ± 157 1109 ± 161 1019 ± 138
1–3 years 1449 ± 210 1479 ± 214 1380 ± 173
4–8 years 1749 ± 211 1847 ± 211 1652 ± 157
9–13 years 1993 ± 254 2109 ± 229 1879 ± 225
14–17 years 2151 ± 436 2375 ± 406 1881 ± 295

EI/BMR
6–12 months 2.22 ± 0.47 2.22 ± 0.43 2.21 ± 0.51
1–3 years 1.88 ± 0.50 1.87 ± 0.46 1.90 ± 0.55
4–8 years 1.62 ± 0.51 1.64 ± 0.50 1.59 ± 0.52
9–13 years 1.43 ± 0.46 1.41 ± 0.46 1.45 ± 0.45
14–17 years 1.30 ± 0.38 1.32 ± 0.38 1.27 ± 0.37

a number of inhabitants; b ≤10 years of education; * p < 0.05, significant differences between sex groups.
Abbreviations: ENALIA: Encuesta Nacional de ALimentación en Población Infantil y Adolescente de España
(National Dietary Survey in Spanish Children and Adolescents); SD: Standard deviation; BMI: Body Mass Index;
Z-BMI: z-score for BMI-for-age; EI/BMR: Observed Energy intake/Basal Metabolic Rate ratio.



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Table 2. Usual intakes (from food and beverage sources only) of vitamins in Spanish children and adolescents and inadequate intakes.

Boys Girls

Mean SD Median (P5–P95) EAR <EAR (%) UL >UL (%) Mean SD Median (P5–P95) EAR <EAR (%) UL >UL (%)

Vitamin A (µg/day)
6–12 months 903 161 895 (653–1181) 500 * 849 80 845 (726–988) 500 *
1–3 years 879 224 860 (547–1278) 210 0.0 860 209 836 (562–1240) 210 0.0
4–8 years 884 273 845 (516–1387) 275 0.0 807 297 753 (432–1365) 275 0.1
9–13 years 922 339 863 (493–1552) 445 2.7 947 327 891 (527–1553) 420 1.0
14–17 years 1048 376 987 (553–1748) 630 10.1 799 322 738 (402–1406) 485 13.0

Vitamin D (µg/day)
6–12 months 3.3 1.4 3.1 (1.4–5.9) 10 * 38 0.0 3.0 1.5 2.8 (1.1–5.7) 10 * 38 0.0
1–3 years 2.6 1.4 2.3 (0.9–5.2) 10 99.8 63 0.0 2.3 1.0 2.1 (0.9–4.1) 10 100 63 0.0
4–8 years 2.2 0.7 2.1 (1.2–3.5) 10 100 75 0.0 2.1 1.4 1.8 (0.7–4.8) 10 99.7 75 0.0
9–13 years 2.8 1.1 2.6 (1.4–5.0) 10 100 100 0.0 2.9 1.2 2.7 (1.3–5.1) 10 100 100 0.0
14–17 years 4.3 0.7 4.2 (3.3–5.4) 10 100 100 0.0 2.1 0.5 2.1 (1.4–3.0) 10 100 100 0.0

Vitamin E (mg TE a/day)
6–12 months 9.7 2.6 9.6 (5.7–14.2) 5 * 9.0 2.8 8.8 (4.9–13.8) 5 *
1–3 years 8.9 3.1 8.5 (4.7–14.7) 5 7.2 200 0.0 8.1 2.7 7.7 (4.5–13.0) 5 9.1 200 0.0
4–8 years 8.1 1.9 7.9 (5.2–11.6) 6 13.5 300 0.0 7.6 1.7 7.4 (5.1–10.6) 6 16.6 300 0.0
9–13 years 9.5 2.2 9.4 (6.2–13.5) 9 43.1 600 0.0 9.5 2.4 9.2 (6.0–13.8) 9 45.9 600 0.0
14–17 years 10.7 2.7 10.4 (6.7–15.6) 12 71.3 800 0.0 9.3 2.1 9.1 (6.2–13.1) 12 89.0 800 0.0

Thiamin (mg/day)
6–12 months 0.7 0.2 0.7 (0.4–1.0) 0.3 * 0.6 0.2 0.6 (0.4–0.9) 0.3 *
1–3 years 1.0 0.2 0.9 (0.7–1.2) 0.4 0.0 0.9 0.2 0.9 (0.7–1.3) 0.4 0.0
4–8 years 1.3 0.2 1.2 (0.9–1.6) 0.5 0.0 1.1 0.2 1.0 (0.8–1.4) 0.5 0.0
9–13 years 1.4 0.3 1.4 (1.1–1.9) 0.7 0.0 1.3 0.2 1.3 (1.0–1.8) 0.7 0.0
14–17 years 1.7 0.5 1.7 (1.1–2.6) 1 2.1 1.2 0.3 1.2 (0.9–1.7) 0.9 8.2

Riboflavin (mg/day)
6–12 months 1.3 0.3 1.3 (0.8–1.8) 0.4 * 1.2 0.3 1.2 (0.6–1.7) 0.4 *
1–3 years 1.6 0.3 1.6 (1.1–2.1) 0.4 0.0 1.6 0.3 1.6 (1.1–2.1) 0.4 0.0
4–8 years 1.8 0.3 1.8 (1.3–2.3) 0.5 0.0 1.6 0.3 1.6 (1.2–2.1) 0.5 0.0
9–13 years 1.9 0.4 1.9 (1.3–2.6) 0.8 0.0 1.8 0.4 1.7 (1.2–2.5) 0.8 0.0
14–17 years 2.2 0.5 2.2 (1.5–3.2) 1.1 0.3 1.6 0.4 1.6 (1.1–2.4) 0.9 1.4

Niacin (mg Eq. Niacin/day)
6–12 months 16.6 4.0 16.3 (10.5–23.5) 4 * 15.2 3.7 15.0 (9.4–21.5) 4 *
1–3 years 23.6 3.9 23.4 (17.7–30.4) 5 0.0 23.0 4.6 22.5 (16.3–31.1) 5 0.0
4–8 years 30.4 5.2 30.0 (22.7–39.5) 6 0.0 25.9 4.0 25.6 (19.9–33.0) 6 0.0
9–13 years 34.0 5.5 33.6 (25.8–43.7) 9 0.0 31.0 6.0 30.6 (21.9–41.5) 9 0.0
14–17 years 40.6 6.2 40.2 (31.1–51.4) 12 0.0 31.8 5.8 31.4 (23.0–41.9) 11 0.0



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Table 2. Cont.

Boys Girls

Mean SD Median (P5–P95) EAR <EAR (%) UL >UL (%) Mean SD Median (P5–P95) EAR <EAR (%) UL >UL (%)

Vitamin B6 (mg/day)
6–12 months 1.3 0.3 1.3 (0.8–1.9) 0.3 * 1.2 0.3 1.2 (0.7–1.8) 0.3 *
1–3 years 1.6 0.3 1.5 (1.1–2.1) 0.4 0.0 30 0.0 1.6 0.4 1.5 (1.0–2.3) 0.4 0.0 30 0.0
4–8 years 1.9 0.3 1.9 (1.5–2.5) 0.5 0.0 40 0.0 1.7 0.4 1.6 (1.1–2.3) 0.5 0.0 40 0.0
9–13 years 2.0 0.4 2.0 (1.5–2.7) 0.8 0.0 60 0.0 1.9 0.5 1.9 (1.2–2.8) 0.8 0.0 60 0.0
14–17 years 2.5 0.5 2.5 (1.8–3.3) 1.1 0.0 80 0.0 1.8 0.4 1.8 (1.3–2.5) 1 0.4 80 0.0

Vitamin B12 (µg/day)
6–12 months 1.7 0.5 1.6 (1.0–2.5) 0.5 * 1.5 0.5 1.4 (0.8–2.4) 0.5 *
1–3 years 3.2 0.8 3.1 (2.2–4.7) 0.7 0.0 3.2 0.9 3.1 (2.0–4.9) 0.7 0.0
4–8 years 4.3 0.9 4.2 (3.0–5.9) 1 0.0 4.2 0.9 4.0 (2.9–5.8) 1 0.0
9–13 years 5.2 1.3 5.0 (3.4–7.5) 1.5 0.0 4.8 2.0 4.4 (2.6–8.6) 1.5 0.0
14–17 years 6.1 0.9 6.1 (4.8–7.7) 2 0.0 4.5 1.2 4.3 (2.9–6.8) 2 0.1

Folate (µg DFE b/day)
6–12 months 232 48.8 231 (155–316) 80 * 212.9 47.3 213 (134–290) 80 *
1–3 years 214 51.8 209 (139–307) 120 1.4 300 6.1 210.4 48.7 207 (138–297) 120 1.6 300 4.4
4–8 years 222 35.8 219 (168–285) 160 2.6 400 0.0 215.7 46.0 211 (149–299) 160 9.7 400 0.1
9–13 years 255 64.7 247 (164–373) 250 51.9 600 0.0 250.0 65.0 242 (158–368) 250 55.0 600 0.0
14–17 years 303 74.9 294 (197–439) 330 68.1 800 0.0 242.7 61.2 236 (155–353) 330 91.3 800 0.0

Vitamin C (mg/day)
6–12 months 135 21.9 134 (101–172) 50 * 130 18.7 129 (100–162) 50 *
1–3 years 103 39.6 98 (49–176) 13 0.0 400 0.0 94 35.2 90 (43–157) 13 0.0 400 0.0
4–8 years 95 33.4 91 (49–157) 22 0.0 650 0.0 91 40.3 83 (39–166) 22 0.3 650 0.0
9–13 years 108 43.0 102 (49–188) 39 1.7 1200 0.0 107 39.9 102 (52–180) 39 1.2 1200 0.0
14–17 years 127 52.5 119 (56–225) 63 7.8 1800 0.0 112 41.4 107 (55–187) 56 5.4 1800 0.0

a TE: alpha-tocopherol equivalents; b DFE: dietary folate equivalents; * Adequate intake (AI) and, therefore, the percentage of subjects with inadequate intakes have not been calculated.
Abbreviations: EAR: Estimated average requirement; UL: Tolerable Upper Intake Levels.



Nutrients 2017, 9, 131 9 of 18

Table 3. Usual intakes of minerals and trace elements (from food and beverage sources only) in Spanish children and adolescents and inadequate intakes.

Boys Girls

Mean SD Median (P5-P95) EAR <EAR (%) UL >UL (%) Mean SD Median (P5-P95) EAR <EAR (%) UL >UL (%)

Calcium (mg/day)
6–12 months 733 177.3 731 (444–1025) 260 * 1500 0.0 690 198.9 690 (363–1013) 260 * 1500 0.0
1–3 years 928 178.5 925 (639–1227) 500 0.8 2500 0.0 879 161.9 866 (633–1165) 500 0.4 2500 0.0
4–8 years 956 159.1 950 (707–1231) 800 16.0 2500 0.0 903 147.6 896 (674–1158) 800 25.0 2500 0.0
9–13 years 1025 212.5 1012 (699–1395) 1100 66.1 3000 0.0 959 167.7 949 (701–1251) 1100 80.6 3000 0.0
14–17 years 1147 264.4 1126 (751–1615) 1100 46.0 3000 0.0 860 195.9 853 (552–1195) 1100 88.6 3000 0.0

Phosphorus (mg/day)
6–12 months 701 208.5 689 (379–1063) 275 * 657 218.3 641 (328–1042) 275 *
1–3 years 1182 242.9 1170 (804–1601) 380 0.0 3000 0.0 1127 237.8 1106 (777–1550) 380 0.0 3000 0.0
4–8 years 1322 196.6 1311 (1019–1662) 405 0.0 3000 0.0 1211 136.8 1205 (996–1445) 405 0.0 3000 0.0
9–13 years 1441 205.7 1430 (1123–1797) 1055 2.1 4000 0.0 1299 184.4 1292 (1008–1614) 1055 8.7 4000 0.0
14–17 years 1639 239.1 1630 (1261–2046) 1055 0.4 4000 0.0 1273 208.0 1265 (944–1627) 1055 14.6 4000 0.0

Iron (mg/day)
6–12 months 12.9 4.70 12.9 (5.1–20.7) 6.9 10.9 40 0.0 11.7 4.26 11.9 (4.4–18.4) 6.9 14.2 40 0.0
1–3 years 11.1 3.36 10.7 (6.4–17.2) 3 0.0 40 0.0 10.7 2.99 10.4 (6.3–16.1) 3 0.0 40 0.0
4–8 years 11.3 1.93 11.2 (8.4–14.7) 4.1 0.0 40 0.0 10.2 1.96 10.0 (7.4–13.7) 4.1 0.0 40 0.0
9–13 years 12.7 1.69 12.6 (10.1–15.6) 5.9 0.0 40 0.0 12.1 1.98 12.0 (9.2–15.6) 5.7 0.0 40 0.0
14–17 years 15.6 3.11 15.3 (10.9–21.1) 7.7 0.0 45 0.0 12.0 2.43 11.8 (8.3–16.3) 7.9 2.9 45 0.0

Potassium (mg/day)
6–12 months 1782 401.0 1768 (1147–2465) 700 * 1652 351.3 1642 (1092–2247) 700 *
1–3 years 2272 407.6 2263 (1618–2958) 3000 * 2187 374.1 2174 (1595–2824) 3000 *
4–8 years 2647 213.1 2642 (2306–3007) 3800 * 2403 335.0 2389 (1875–2975) 3800 *
9–13 years 2872 481.7 2846 (2126–3706) 4500 * 2590 463.9 2568 (1867–3389) 4500 *
14–17 years 3270 610.9 3233 (2333–4335) 4700 * 2590 494.8 2565 (1822–3445) 4700 *

Sodium (mg/day)
6–12 months 394 164.8 361 (197–706) 370 * 394 130.2 373 (224–637) 370 *
1–3 years 1246 338.2 1203 (775–1865) 1000 * 1500 20.4 1158 323.9 1112 (719–1756) 1000 * 1500 13.9
4–8 years 1858 362.4 1820 (1333–2509) 1200 * 1900 41.5 1825 361.1 1781 (1317–2481) 1200 * 1900 37.8
9–13 years 2519 577.5 2447 (1710–3572) 1500 * 2200 68.4 2177 571.7 2092 (1411–3237) 1500 * 2200 42.3
14–17 years 2911 857.4 2785 (1756–4497) 1500 * 2300 75.1 2307 325.4 2285 (1812–2876) 1500 * 2300 49.0

Zinc (mg/day)
6–12 months 6.2 1.73 6.3 (3.3–9.0) 2.5 1.5 5 76.0 5.7 1.67 5.8 (2.9–8.4) 2.5 2.8 5 67.3
1–3 years 7.5 1.46 7.4 (5.3–10.1) 2.5 0.0 7 61.2 7.3 1.67 7.2 (4.9–10.3) 2.5 0.0 7 54.8
4–8 years 8.8 1.45 8.6 (6.7–11.4) 4 0.0 12 2.6 7.9 1.08 7.8 (6.3–9.8) 4 0.0 12 0.2
9–13 years 9.8 0.98 9.7 (8.3–11.5) 7 0.0 23 0.0 8.7 1.38 8.6 (6.6–11.2) 7 9.2 23 0.0
14–17 years 11.3 1.50 11.2 (9.0–13.9) 8.5 2.1 34 0.0 8.9 1.20 8.9 (7.1–11.0) 7.3 6.3 34 0.0



Nutrients 2017, 9, 131 10 of 18

Table 3. Cont.

Boys Girls

Mean SD Median (P5-P95) EAR <EAR (%) UL >UL (%) Mean SD Median (P5-P95) EAR <EAR (%) UL >UL (%)

Magnesium (mg/day)
6–12 months 123.0 28.3 121 (79–172) 75 * 112.6 21.9 112 (78–150) 75 *
1–3 years 196.7 38.9 195 (135–263) 65 0.0 190.2 36.3 188 (134–253) 65 0.0
4–8 years 248.1 27.4 247 (205–295) 110 0.0 228.0 18.4 227 (199–259) 110 0.0
9–13 years 280.1 39.9 278 (218–349) 200 1.4 255.8 32.7 254 (205–312) 200 3.4
14–17 years 321.7 66.4 317 (222–439) 340 63.5 256.7 48.5 254 (182–341) 300 81.8

Selenium (µg/day)
6–12 months 25.7 11.4 23.7 (10.9–47.3) 20 * 60 1.1 22.5 7.9 21.7 (10.9–36.6) 20 * 60 0.0
1–3 years 60.2 15.9 58.9 (36.5–88.4) 17 0.0 90 4.2 58.8 21.4 55.9 (29.5–98.2) 17 0.2 90 8.4
4–8 years 90.4 20.1 88.3 (61.2–126.5) 23 0.0 150 0.8 81.0 10.5 80.4 (64.7–99.2) 23 0.0 150 0.0
9–13 years 109.1 14.2 108.3 (87.1–133.7) 35 0.0 280 0.0 95.8 11.1 95.3 (78.6–114.9) 35 0.0 280 0.0
14–17 years 131.3 24.0 129.8 (94.5–173.2) 45 0.0 400 0.0 105.3 19.5 103.8 (75.8–139.7) 45 0.0 400 0.0

Iodine (µg/day)
6–12 months 76.8 13.0 76.5 (56.2–98.8) 130 * 69.6 13.8 69.8 (46.7–92.1) 130 *
1–3 years 84.6 17.0 83.2 (59.3–114.5) 65 11.0 200 0.0 85.5 15.4 84.5 (62.1–112.3) 65 7.8 200 0.0
4–8 years 87.3 16.1 85.6 (64.1–116.1) 65 5.9 300 0.0 84.1 13.3 82.8 (64.9–107.9) 65 5.1 300 0.0
9–13 years 104.3 15.0 103.0 (82.0–131.0) 73 0.6 600 0.0 86.5 16.0 84.6 (63.9–115.6) 73 19.8 600 0.0
14–17 years 107.2 22.9 104.6 (74.6–148.5) 95 31.9 900 0.0 91.2 13.3 90.1 (71.4–114.8) 95 64.3 900 0.0

* Adequate intake (AI) and, therefore, the percentage of subjects with inadequate intakes have not been calculated.



Nutrients 2017, 9, 131 11 of 18

4. Discussion

This paper provides recent estimates of the vitamin, mineral, and trace element intake
distributions, from food and beverage sources only, in a representative sample of Spanish infants,
toddlers, children, and adolescents. The usual micronutrient intakes in the ENALIA study meet or
exceed their requirements, except for those of vitamin D, which was practically insufficient in all
individuals, and vitamin E, folate, calcium, magnesium, and iodine, especially in adolescents and
females. Sodium intake is excessive in a considerable percentage of the population, especially in males,
and increases with age. Finally, the usual intake of zinc exceeds the UL in children less than four years
of age.

Data on intake distributions in children, corrected for the day-to-day variation, are very scarce in
Europe [29]. As for studies in Spain, the enKid study, conducted between 1998 and 2000, has been the
reference study until now. Although the intakes were adjusted for random intra-individual variation,
the proportion of the population that is at risk for deficits was estimated, using the recommended intake
(RI) for the Spanish population and/or one-third and two-thirds of the RI as cut-off points [12]. The key
findings were that vitamins A, D, E, folate, iron, calcium, and magnesium were the nutrients most likely
to be associated with inadequate intakes, and that adolescents aged between 14 and 17 years were the
group with the highest nutritional risk, especially among girls. Due to the methodology followed, the
enKid study could not assess the risk of excessive intakes. In this sense, the ENALIA study provides
current data on the usual intakes from food and beverage sources and the risk of inadequate intakes in
Spanish children and adolescents using the EAR and the UL as the IOM recommends [21].

Both food diaries and dietary recalls are prone to under-/over-reporting, and there is debate
about whether or not to eliminate misreporters in dietary studies, since the exclusion of potential
misreporters may create a biased sample. The exclusion of under-/over-reporters might have induced
selection bias since the misreporters might have a special food choice or eating behavior. In addition,
under-reporting includes both under-recording and under-eating, and some over-reporters could
eat much more than usual during the period of study as well. It has also been suggested that
low energy reporting may be just as common among plausible energy reporters as among those
defined as under-reporters [30], so that selectively excluding those with implausible energy intakes
could bias the results. In addition, during childhood, diet tends to be highly variable from day
to day and the identification of under-reporters is difficult [31,32]. Therefore, and following EFSA
recommendations [33], we did not exclude potential misreporters from the analysis.

This study highlights the very low intake of vitamin D, which is insufficient in all age groups and
sexes, and the fact that almost all individuals have intakes that are at risk. Vitamin D deficiency is a
worldwide health problem, and similar data have been described in infants in the Netherlands [34],
Finland [32], and Belgium [35], and in European adolescents [36]. The high prevalence of inadequate
intakes may be justified by the fact that vitamin D is found naturally only in a few foods, and even
food fortification has a modest effect on vitamin D status [37]. Vitamin D is found naturally in fish, egg
yolk, and offal, such as liver [38]. Typical fortified foods are milk, breakfast cereals, and margarine [39].
However, consumption of these foods (eggs, fish, cereals, and dairy) is low in a significant percentage
of Spanish children and adolescents [40]. Although we could not assess the risk of inadequacy or
excessive intake of vitamin D in children between six and 12 months, we must consider that 20% of
the children in the group used vitamin D supplements. In addition, although the use of multivitamin
supplements was much lower, it may also contribute to the intake of vitamin D. On the other hand,
less than 1% of children older than 12 months used vitamin D supplements and less than 7% used
multivitamin supplements that could also contribute to the intake of this vitamin. Taking this into
account, we can concluded that, in spite of the lack of data on the supplements, the risk of insufficiency
is high in all children, with those between six and 12 months being at the lowest risk. Additionally,
although vitamin D can be synthesized by sunlight, sun exposure is not always sufficient to offset the
low dietary intake [41]. In fact, the serum levels of vitamin D are insufficient in Spanish schoolchildren,
since 47% had hypovitaminosis, and 35% had a clear deficiency in vitamin D [42].



Nutrients 2017, 9, 131 12 of 18

The usual mean vitamin E intakes were less than the EARs in some subgroups of children,
especially those over nine years of age, similar to what was observed in other toddlers and
preschoolers [35] and in adolescents in the Healthy Lifestyle in Europe by Nutrition in Adolescence
(HELENA) study [36]. Vitamin E deficiency is rarely found in adults, but is more frequently found
in children, likely because they have limited stores and are growing rapidly, thereby allowing such
deficiency symptoms to be readily apparent [43]. A recent systematic review concluded that vitamin E
intake was insufficient in 61% of the reviewed studies and that 13% of the subjects, mainly newborns
and children, were below the functional deficiency threshold for vitamin E, which suggests that the
α-tocopherol status is inadequate in a substantial part of the studied populations [44].

Folate intake is inadequate in a high proportion of children and adolescents over nine years
of age (Table 2). The risk of inadequacy is higher in adolescent females. Similar results have been
shown in other studies in adolescents [36,45]. Folate is essential for optimal growth, development, and
maintenance of health throughout all life stages. Adequate folate status among reproductive-aged
women is critical, given the important biological role of folate in gene expression, cell division,
and reproduction [2]. Folate is important not only for the prevention of neural tube defects during
pregnancy but also for the prevention of cardiovascular disease (CVD) and some malignancies [46].
Thus, the low folate intake among Spanish adolescents is of great concern.

Regarding minerals, the risk of inadequate calcium intake is especially high in children over
nine years of age and is even higher in females (Table 3). Diethelm et al. [36] showed low intakes in
European adolescents in the HELENA study, and Ortega et al. [47] found low intakes of calcium in a
representative sample of Spanish schoolchildren between seven and 11 years of age. Although it is
an essential nutrient, there is controversy about whether calcium intake in the population is high or
insufficient [48]. The same goes for the consumption of dairy products [49], which are the main source
of this mineral [47]. While some authors have suggested that the intake of dairy products is high in
Spanish children [50], others have indicated that it is insufficient and can clearly be improved [47,51].
Some authors indicated that their consumption may be associated with an increased risk of some
cancers, such as prostate and ovary [52], and even bone fractures [53], but other studies suggested
that high intakes of calcium probably protect against colorectal cancer, bladder cancer, gastric cancer,
and breast cancer, and that dairy intake does not seem to be associated with the risk of pancreatic
cancer, ovarian cancer, or lung cancer, whereas the evidence for prostate cancer risk is inconsistent [54].
In addition, the evidence confirms that milk and dairy intake has a positive effect on bone health in
childhood and adolescence, decreases the risk of childhood obesity, improves body composition in
adults, and contributes to lower risk of developing type 2 diabetes [54].

As for iron intake, the EARs are exceeded in almost all subgroups, except for a small but important
subset of six- to 12-month-old infants whose usual intakes were below the EAR (10.9% in males, 14.2%
in females, Table 3). These figures correspond only to iron intake from foods and beverages, and since
the use of iron supplements/multivitamins with minerals that could contain iron was very low in this
age group, it is unlikely that the use of supplements had a significant impact on iron intake. These data
are similar to those found in recently in the USA [55] and Spain [56], and could be consistent with the
figures for prevalence of iron deficiency (9.6%) and iron deficiency anemia (4.3%) found in children
below 12 months in Spain [57]. Since iron deficiency during early years may interfere with cognitive
development [58], it is necessary to pay more attention to this problem.

On the other hand, the percentage of adolescent girls with inadequate iron intake is low relative
to other studies, although differences may be due not only to different eating patterns of children
and adolescents within Europe [59], but also to methodological differences. For example, the enKid
study [12] found 26% and 34% of girls between 10–13 years and 14–17 years, respectively, had intakes
lower than two-thirds of the AI (AI = 18 mg/day). This cut-off point is close to the EAR established for
children between nine and 13 years, but is lower than that the EAR for adolescents between 14–17 years.
Data from the HELENA study in European adolescents [60] found 3% of insufficient intakes in boys
and 12.2% in girls between 12.5 and 17.5 years. However, this study assumed that all girls were



Nutrients 2017, 9, 131 13 of 18

menstruating, which may have slightly overestimated the percentage of girls below the EAR in the
younger girls. Additionally, the EAR cut-point method was used for estimating the prevalence of
inadequate intakes, and this may produce an underestimation of the true prevalence of inadequate
intakes among girls.

The usual intake of sodium exceeds the UL in a considerable percentage of children in all age and
sex groups, although the prevalence of excessive intakes is higher in males (Table 3). Similar results
have been shown in other groups of preschoolers [35] and European adolescents [36]. In addition, the
median intake of potassium is below the AI. Some studies indicate that elevated blood pressure, which
may lead to stroke, CVD, and kidney disease, is associated with increased sodium and inadequate
potassium intake [61]. Consequently, these increased sodium intakes and inadequate potassium
intakes are a cause of concern for Spanish children and adolescents. We must bear in mind the inability
to precisely account for added salt, so it is likely that sodium intake is even greater than that recorded.
The best method for estimating sodium intake is the measurement of its excretion over 24 h, since
dietary surveys and databases detailing food composition underestimate sodium intake. In this sense,
the Spanish Food Composition Tables [18] include data from both analytical and bibliographic sources,
as well as information provided by the manufacturers. The latest update has been made on the
sodium data, based on analytical data of more than 1000 brands of processed foods (snacks, biscuits,
preserved vegetables, fish and meat, sausages, prepared dishes, etc.). On the other hand, data on
sodium excreted in 24 h urine from 205 Spanish schoolchildren aged between seven and 11 years have
recently been published [62]. The mean 24 h urinary excretion of sodium was 132.7 ± 51.4 mmol/24 h,
equivalent to 3052 ± 1182 mg Na/24 h (salt equivalent: 7.8 ± 3.1 g/day). Moreover, 84.5% of subjects
aged ≤10 years had intakes of >4 g of salt per day, and 66.7% of those aged >10 years had intakes of
>5 g salt per day. This is in line with our dietary results, which, although subject to error, confirm
the need to take measures to reduce salt intake in Spanish children and adolescents. Previous studies
indicated that the main sources of sodium in Spanish schoolchildren were added salt (at table or
cooking) (21.3%), chip potatoes (12.1%), bread (11.3%), and cured and cooked ham [50]. Therefore,
it seems prudent to reduce the consumption of processed products, and to promote the consumption
of non-processed fresh foods with low sodium content.

The usual magnesium intake is insufficient in 63.5% of adolescent males and 81.8% of females
(Table 3). The median intake in the adolescent group is similar to that reported in the HELENA
study [36]. Accumulating evidence supports the notion that magnesium plays significant roles in
promoting strength and cardiorespiratory function [63], and an inverse association between dietary
magnesium and metabolic syndrome and its components has been shown [64].

Some small but important subsets of children have a high risk of inadequate intake of iodine,
and the risk is highest in adolescent females over 14 years (Table 3). Other studies have also found
inadequate intakes of iodine in other groups of adolescents [36,59]. It is difficult to estimate the intake
of iodine because much of the intake of this mineral comes from iodized table salt. Although we
considered the use of table salt in our study and the subjects were asked about the type of salt used,
it is possible that the use of iodized salt has not been properly determined.

Finally, the usual zinc intake exceeds the UL in children up to four years of age, although there was
a group of girls over nine years old with intakes at risk of deficiency (9.2% and 6.3% in girls between
nine and 13 years and over 14 years, respectively, Table 3). Goldbohm et al. [34] observed that 17% of
children aged 10 to 48 months in the Netherlands have excessive intakes of zinc, and Butte et al. [65]
described a similar situation in toddlers and preschoolers in the USA, which is justified by the frequent
use of fortified foods containing zinc such as infant formula, infant cereals, and ready-to-eat cereals.
We must keep in mind, however, that the validity of the UL for zinc for infants and children aged
one to three years has been questioned based on the paucity of data used to establish the UL and the
absence of zinc toxicity with usual zinc intakes in the US pediatric population [65].

Our study has some limitations and strengths. First, the food composition tables may not
accurately reflect the nutrient composition of the food. It is appreciated that there is variability in



Nutrients 2017, 9, 131 14 of 18

the composition of foods, likely due to differences in season, cultivar, or variety. On the other hand,
the Spanish Food Composition Tables used included enriched/fortified foods commonly available
in Spain, and additional composition data for specific brands were taken into account. Fortification
values can differ between countries, so data from food composition tables from other countries might
not be adequate. Our study did not account for the use of supplements of vitamins and minerals,
so the results of this study are limited to the dietary intake of micronutrients. Although parents may
be reliable reporters of their children’s food intake at home, meals out of parental control are prone
to being misreported, as are the estimation of their portion sizes [66]. Finally, causality for dietary
intake not meeting the dietary guidelines cannot be confirmed due to the lack of biochemical data and
functional parameters. On the other hand, one of the major strengths of the present study, in addition
to its large sample size, is its representativeness of the population and the use of standardized and
validated procedures. The 24 h dietary record in children and 24 h dietary recalls in adolescents
provide rich detail about the types and amounts of food consumed and were shown to be less prone to
systematic bias compared with food frequency questionnaires [67]. Application of the ISU method
corrected the data for day-to-day variation, although we should still bear in mind that the true intake
distributions remain unknown because of the lack of objective validation data. The assessment period
in our study covered an entire year, considering seasonal variations in diet, and because all days of the
week were included in the study, the effects of the day of the week could be removed.

5. Conclusions

This paper provides recent data on the dietary vitamin and mineral intake from food and beverage
sources of Spanish children. Public health initiatives should ensure that children and adolescents follow
an adequate, balanced diet because the health behaviors adopted during the early years of life and
adolescence can be maintained in adulthood, and improving them would help prevent many chronic
diseases related to diet. Such initiatives should include the promotion of a Mediterranean Diet style,
including more fish, eggs, cereals, and dairy products which are source of vitamin D, and lowering the
consumption of processed foods which are sources of sodium. Additionally, the collaboration between
the administration and the industry aiming to reduce more of the sodium content of processed foods
is also desirable. Clinical and biological assessment of the nutritional status of a representative sample
of Spanish children and adolescents focusing on the micronutrients of concern would seem advisable.

Acknowledgments: The present study was carried out by the AECOSAN (Spanish Agency for Food and
Nutritional Safety, Spanish Ministry of Health and Consumer Affairs, Spain) and was co-supported by the
EFSA (European Food and Safety Authority) within the call for tender CFT/EFSA/DCM/2012/01: “Support to
national dietary surveys in compliance with the EFSA Guidance on General principles for the collection of national
food consumption data in the view of a pan-European dietary survey”—second support. Contract Number
CFT/EFSA/DCM/2012/01/CT05.

Author Contributions: M.J.R., V.M., N.P.-F., R.S. and M.A.D.-R., conceived the study; M.J.R., V.M. and R.S. were
responsible for the design, protocol, methodology, and follow-up checks of the study; A.M.L.-S. and R.M.O.
provided continuous scientific advice for the study; A.M.L.-S., A.A., L.G.G.-R., E.C.-S. and N.P.-F., analyzed the
data; A.M.L.-S., R.M.O., S.S. and N.P.-F. drafted and wrote the manuscript; M.A.D.-R., C.V., T.R. and J.J.C. helped
to draft the manuscript and critically reviewed it. All authors read and approved the final manuscript.

Conflicts of Interest: The authors declare no conflict of interest. The founding sponsors had no role in the design
of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, and in the
decision to publish the results.

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© 2017 by the authors; licensee MDPI, Basel, Switzerland. This article is an open access
article distributed under the terms and conditions of the Creative Commons Attribution
(CC BY) license (http://creativecommons.org/licenses/by/4.0/).

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http://creativecommons.org/licenses/by/4.0/.

	Introduction 
	Materials and Methods 
	Study Design 
	Sample 
	Dietary Study 
	Socio-Demographic and Anthropometric Information 
	Statistical Analysis 

	Results 
	Discussion 
	Conclusions