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Review

Breakfast Characteristics and Its Association with Daily Micronutrients Intake in Children and Adolescents–A Systematic Review and Meta-Analysis

by
Natalia Giménez-Legarre
1,2,3,*,†,
María L. Miguel-Berges
1,2,3,†,
Paloma Flores-Barrantes
1,2,3,
Alba M. Santaliestra-Pasías
1,2,3,4,‡ and
Luis A. Moreno
1,2,3,4,‡
1
GENUD (Growth, Exercise, Nutrition and Development) Research Group, Facultad de Ciencias de la Salud, Universidad de Zaragoza, 50009 Zaragoza, Spain
2
Instituto Agroalimentario de Aragón (IA2), 50013 Zaragoza, Spain
3
Instituto de Investigación Sanitaria Aragón (IIS Aragón), 50009 Zaragoza, Spain
4
Centro de Investigación Biomédica en Red de Fisiopatología de la Obesidad y Nutrición (CIBERObn), Instituto de Salud Carlos III, 28029 Madrid, Spain
*
Author to whom correspondence should be addressed.
These authors contributed equally to this work.
These authors contributed equally to this work.
Nutrients 2020, 12(10), 3201; https://doi.org/10.3390/nu12103201
Submission received: 25 August 2020 / Revised: 2 October 2020 / Accepted: 16 October 2020 / Published: 20 October 2020
(This article belongs to the Section Nutrition and Public Health)
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Abstract

:
Breakfast is an important source of key nutrients in the diet. For this reason, the aim of this review was to investigate the associations between breakfast consumption and daily micronutrients intake in both children and adolescents (aged 2–18 years). A peer-reviewed systematic search was conducted in three datasets (PubMed, Scopus and Cochrane Library) in February 2020 in English and Spanish. Two independent reviewers evaluated 3188 studies considering the AXIS critical appraisal and PRISMA methodologies. Meta-analysis was carried out comparing results according to type of breakfast consumed (Ready to eat cereals (RTEC) breakfast or other types of breakfast) and breakfast skipping. Thirty-three articles were included in the systematic review (SR) and 7 in the meta-analysis. In the SR, we observed that those children and adolescents who usually consume RTEC at breakfast had a higher consumption of B-vitamins than those not consuming RTEC at breakfast. Breakfast consumers had a higher mineral intake (iron, calcium, magnesium, potassium, zinc, and iodine) than breakfast skippers. In the Meta-Analysis, RTEC consumers had significantly higher vitamin C intake than breakfast skippers (Standard Mean Difference (SMD), −4.12; 95% confidence intervals (CI): −5.09, −3.16). Furthermore, those children who usually consume breakfast had significantly higher daily intake of calcium than breakfast skippers (SMD, −7.03; 95%CI: −9.02, −5.04). Our review proposes that breakfast consumption seems to be associated with higher daily micronutrients intake than breakfast skippers.

1. Introduction

Breakfast is extensively recognized as an important component of a healthy lifestyle and represents an important source of key nutrients in the diet for both adults and young population groups [1,2,3,4,5], showing several benefits of its consumption [2,3,4]. The International Breakfast Research Initiative (IBRI), developed in six countries, observed that there was a general breakfast pattern. In children, the proportion of breakfast consumers was very high (from 87.4% in US to 98.9% in Denmark) but declined with adolescence (from 74.2% in US to 87.9% in Canada) [6].
Breakfast consumption showed a protective effect against obesity and overweight [7]; for this reason, breakfast consumption is important because of its inverse association with body fat [8,9]. For instance, previous authors observed that children with obesity were more likely to skip breakfast [9,10,11], and these children had a high risk of chronic diseases as type 2 diabetes [12,13,14], dyslipidemia or cardiovascular diseases [7,8,15]. Likewise, previous authors observed that some vitamin deficiencies could be associated with fatness and other diseases, [16,17,18] and can be considered a critical public health issue [19,20]. Some studies also observed that in both children and adolescents, breakfast consumption has a positive effect on cognitive performance [21]. Nevertheless, breakfast is the meal that they most frequently skipped [22,23].
It has been suggested that children should consume about 20% of their daily energy intake (EI) at breakfast [24,25,26]. Different studies showed that those who often skip breakfast had lower EI and macronutrient’s intake compared with those who usually consumed breakfast [16,27,28,29]. Breakfast consumption has been associated with a better intake of vitamins and minerals in both children and adolescents [30]. In the same way, it has been observed that those adolescents who usually consume breakfast are more likely to meet recommended intakes of some minerals such as iron, calcium, zinc, magnesium, and copper, and vitamins A, B6, B1, C, D, E, and folate [31]. However, no systematic analysis of these associations was previously performed.
Nowadays, ready-to-eat-cereals (RTEC) at breakfast have become increasingly popular due to the desire for an easy alternative [32]. RTEC are increasingly consumed, and children and adolescents prefer RTEC instead of other cereal-based foods, such as bread [33,34]. In a previous Spanish study, RTEC consumption was associated with a low risk for inadequate micronutrients intake in children, adolescents and young adults [35].
To the authors’ knowledge, this is the first systematic review (SR) regarding the association between breakfast consumption and daily micronutrients intake. However, a recent SR and meta-analysis observed that breakfast consumption is associated with healthier food and beverages consumption and also better macronutrient intake [36].
The aim of this SR is to observe the associations between characteristics and frequency of breakfast consumption and total daily diet composition in terms of micronutrients intake.

2. Methodology

2.1. Protocol

This SR is the follow up of a previous SR that has been published [36]. Both SR shared the same methodology, including different studies taking into consideration the specific aims of each one. This SR has been performed following the criteria and methodology established by the Preferred Reporting Items for Systematic reviews and Meta-Analyses Protocols (PRISMA) [37]. The SR was registered in ‘Prospero’ CRD42020142570. Using the PICO principle (Participants, Intervention, Control, Outcomes), a specific question was constructed (Table 1) [38].

2.2. Search Strategy

Journal articles were identified by searching in electronic databases and scanning references and lists of articles. The search strategy was applied to PubMed, Scopus and the Cochrane Library databases in February 2020. The search strategy used to identify the article was as follows: (“Breakfast”(Mesh) OR “Breakfast”(tiab)) AND (“Food”(Mesh) OR “Beverages”(Mesh) OR “Diet, Food and Nutrition”(Mesh) OR “Diet”(Mesh) OR “Eating”(Mesh) OR “Feeding Behavior”(Mesh) OR “Nutritional Requirements”(Mesh) OR “Nutritional Status”(Mesh) OR “Nutritive Value”(Mesh) OR “breakfast skipping” (tiab) OR “meal Skipping”(tiab) OR “Fasting”(Mesh) OR “Food preferences”(Mesh) OR “Diet therapy”(Mesh) OR “Energy Intake”(Mesh) OR “nutrient”(Mesh)) AND (“Child, Preschool”(Mesh) OR “Child”(Mesh) OR “Adolescent”(Mesh) OR “breakfast skipping” OR “meal skipping”).

2.3. Selection Criteria

The following inclusion criteria were used: (1) types of studies: cross-sectional, longitudinal, descriptive study or case control study, (2) participants between 2–18 years, (3) original studies in which assessment of breakfast has been done/performed, and (4) publications in English and Spanish.
All articles were collected into an online citation manager (EndNote® Online, EndNote X9.1, Clarivate Analytics) and were screened for potential relevance according to title and abstract based on inclusion and exclusion criteria. The full text of all those studies fulfilling the inclusion criteria were collected and were evaluated for relevance according to the aim of the SR. In doubtful cases, studies were discussed with the SR team. Detailed information regarding publication’s year, study design, setting, participants, and results on micronutrient outcomes were extracted. The literature search was not limited by any range of years.

2.4. Systematic Review Process and Data Extraction, and Synthesis

Two reviewers independently (NGL and PFB) evaluated all studies. Titles and abstracts were examined, and full relevant articles were obtained and assessed using the mentioned inclusion and exclusion criteria. Inter-reviewer disagreements were resolved by consensus, and in some cases, a third reviewer was consulted to solve disagreements. Figure 1 shows in a flowchart the search results.

2.5. Quality and Risk of Bias Assessment

The Appraisal tool for Cross-sectional Studies (AXIS) was used to assess the risk of bias and the methodological quality of included studies [39]. The tool consists of a 20-question-list, which included the study design, target population, sample size and selection, sampling frame, reliability and validity of the measurements, methodology, ethical issues, and conflict of interest. The details of the assessment of each included study are shown in the supplementary section, Table S1. Given that the tool does not provide an accumulated score on quality, the results have been summarized on Table 2 in order to obtain a general view of the quality of all the included studies.

2.6. Statistical Analyses

All analyses were performed using Open Meta (Analyst) software (open-source, cross-platform software for advanced meta-analyst). Two possibilities for comparison groups were assessed: RTEC breakfast versus skip breakfast, and other types of breakfast versus skip breakfast. Mean difference (MD) with 95% confidence intervals (95%CI) was used for comparing micronutrients (in milligrams (mg) or micrograms (μg)) between skip breakfast, RTEC breakfast and other types of breakfast. Also, for continuous data, random effects models with DerSimonian and Laird values were applied. For each outcome, effect sizes were calculated.
When information was available, the I2 statistic and its associated p value was used to test the heterogeneity, which describes as a proportion of the total variance the variance between studies [40]. Low heterogeneity was indicated with a value of <25%; high heterogeneity was indicated with a value of >50% to 75%, and high heterogeneity was indicated with a value of >75%. The absence of heterogeneity was determined with a non-significant p value.

3. Results

3.1. Literature Search and Screening

The included studies are summarized in Figure 1. A total of 3674 eligible papers were identified: 2544 from PubMed, 620 from Scopus, 505 from the Cochrane Library, and 5 were identified through other sources (Figure 1).
After duplicates exclusion and title reading, 3188 articles were assessed for eligibility. Finally, only 33 full-text articles met the inclusion criteria and 7 of them were considered for meta-analysis.

3.2. Study Design Characteristics

All the included articles were published in English and Spanish. From the 33 included articles, only 3 articles (9.1%) were longitudinal versus 90.9% of the studies (n = 30), which were cross-sectional. From the 33 included studies, 17 were performed in representative samples of the correspondent population [16,28,41,42,43,44,45,46,47,48,49,50,51,52,53,54,55]. Table 3 shows details of the articles, which included the impact of breakfast consumption on micronutrients intake. The studies were conducted between 1981–2018 in the following countries: United States (US) (n = 11) [30,41,44,49,51,52,55,56,57,58,59], United Kingdom (UK) (n = 5) [3,29,47,60,61], Canada (n = 3) [42,43,54], Spain (n = 2) [62,63], Australia (n = 3) [45,46,53], México (n = 1) [28], Ireland (n = 1) [64], Belgium (n = 1) [65], Cyprus (n = 1) [66], France (n = 1) [50], Malaysia (n = 1) [67], Japan (n = 1) [68], and 3 were combined European countries [16,48,66]. Data came from three sources: most of them were national health studies (60.6%) [3,28,30,41,42,43,44,45,46,47,51,52,53,54,55,56,57,59,61,68], 30.3% were original studies [29,49,50,58,60,62,63,64,65,67] and the rest were European multi-center studies (9.0%). Results of the studies have been differentiated according to the age of the participants, ranging from 2–12 years for children, and from 13–18 years for adolescents. Included studies were performed in children 39.3% (n = 13) [28,29,47,49,51,52,56,57,58,62,63,66,67], 12.1% (n = 4) adolescents [16,48,64,65], and both children and adolescents 48.4% (n = 16) [3,30,41,42,43,44,45,46,50,53,54,55,59,60,61,68].

3.3. Reporting Methods

Results are presented in Table 3 in alphabetic order per author’s last name.
Outcome variables were analyzed using 24 h Dietary Recalls (24 h-DR) (n = 26) or Food Records (FR) (n = 8). Two studies assessed diet with both 24 h-DR and Food Frequency Questionnaire (FFQ) questionnaires. Fulfilling of questionnaires was dependent on the methodology, the questionnaires used and on the age of the participants (interview with parents or caregivers, reported by parents or caregivers or self-reported by the children or adolescents).
Several articles assessing the consumption of RTEC were included (n = 22, 66.6%). Frequency and quantity consumed per week were assessed as well as the association of its consumption with different behaviors and health outcomes. Comparison groups according to breakfast consumption and/or type of breakfast consumed were the following: (n = 8) ‘frequency of consumption of RTEC’ [29,47,49,56,58,61,64,69], (n = 8) ‘RTEC consumers versus non-RTEC consumers’ [46,48,50,54,57,59,62,67], (n = 5) ‘breakfast skippers versus breakfast consumers versus RTEC consumers’ [41,42,44,45,52], (n = 8) ‘frequency of breakfast consumption (breakfast skippers versus breakfast consumers) [3,16,30,43,46,51,53,68], (n = 3) comparisons between different types of breakfast [28,55,66], (n = 2) comparisons between nutritional composition of breakfast [50,63], and one of them considered breakfast quality [65]. Two studies had two comparison groups according to breakfast consumption.
Of the relevant studies (n = 30), 90.9% showed associations between breakfast consumption and daily vitamins intake. Breakfast consumption and vitamin C intake was the most evaluated relationship in the vitamins group, which was analyzed in 27 studies; from which 15 showed significant associations.
Breakfast consumption and B vitamins’ associations were widely analyzed and in most of the studies, positive significant associations were found. Thiamin intake was found to be positively associated with breakfast consumption in 19 out of 22 studies, riboflavin in 19 out of 22, niacin in 12 out of 20, pyridoxine in 16 out of 20, folate in 18 out of 22, and cobalamin in 11 out of 15. Pantothenic acid (vitamin B5) intake was only assessed in two studies, from which positive and significant associations with breakfast consumption were also found.
Vitamin A and vitamin D were positively associated with breakfast consumption in 12 studies. On the other hand, intake of vitamin E was evaluated in 11 studies and most of them (9 studies) did not find significant associations. Vitamin K was evaluated in four studies, and in three of them the authors did not find significant associations.
Breakfast consumption and mineral dietary intakes were assessed in 32 studies. The association between breakfast consumption and calcium intake was the most frequent relationship, evaluated in 31 studies in the minerals group. Positive associations were found between breakfast consumption and iron intake (26/29), sodium (11/20) and zinc (14/18). Iodine was evaluated in two studies and both showed significant associations. Magnesium and potassium intakes were positively associated with breakfast consumption in 15 studies. Regarding phosphorous, only one author found significant associations (1/12). However, every study found significant associations between breakfast consumption and copper and manganese intake.

3.4. Meta-Analysis Results: Measurement of the Effect of the Relationship between Type of Breakfast and Micronutrients Intake

Differences in vitamins and minerals consumption between RTEC breakfast consumers and breakfast skippers are shown in Figure 2 (vitamins) and Figure 3 (minerals).
Regarding vitamins intake, as presented in Figure 2A, in children, RTEC consumers had significantly higher daily consumption of thiamine (vitamin B1) than children who usually skip breakfast (SMD, −16.378; 95%CI: −29.110, −3.647). However, heterogeneity amongst studies was high (I2 = 99.97%; p < 0.001). Figure 2B shows that RTEC consumers had significantly higher daily intake of riboflavin (vitamin B2) than children who usually skip breakfast (SMD, −14.757; 95%CI: −20.247, −9.268). Heterogeneity amongst studies was very high (I2 = 99.94; p < 0.001). Analyzing the consumption of Vitamins A and C, Figure 2C,D shows that those children who usually consume RTEC had a significantly higher intake in both vitamins than those who usually skip breakfast (SMD, −10.407; 95%CI: −14.147, −6.667 and SMD, −4.127; 95%CI: −5.091, −3.162), respectively, the heterogeneity amongst studies being very high (I2 = 99.91; p < 0.001 and I2 = 99.4; p < 0.001, respectively).
Regarding minerals consumption, Figure 3A,B shows that children who usually ate RTEC breakfast had significantly higher daily consumption of calcium and iron than children who skipped breakfast (SMD, −12.650; 95%CI: −14.616, −10.685 and SMD, −19.534; 95%CI: −27.887, −11.181, respectively), the heterogeneity between studies being very high (I2 = 99.26; p < 0.001 and I2 = 99.91; p < 0.001, respectively). Likewise, as it is shown in Figure 3C,E, RTEC consumers had a significantly higher magnesium and potassium intake than breakfast skippers (SMD, −10.903; 95%CI: −18.078, −3.729) and (SMD, −6.972; 95%CI: −10.689, −3.254), respectively. The heterogeneity between studies was high (I2 = 99.96; p < 0.001 and I2 = 99.91; p < 0.001, respectively). Concerning sodium, no significant associations were observed between those children who usually consume RTEC breakfast and breakfast skippers (Figure 3D).
Differences in vitamins and minerals intake between consumption of other types of breakfast and skipping breakfast are shown in Figure 4 (vitamins) and Figure 5 (minerals).
Regarding thiamine (vitamin B1), no significant associations were observed between breakfast consumers and those children skipping breakfast (Figure 4A). Nevertheless, those children who eat breakfast had a higher significantly daily riboflavin (vitamin B2) consumption than those children who usually skip breakfast (SMD, −8.511; 95%CI: −10.911, −6.112) (Figure 4B). The heterogeneity between studies was high (I2 = 99.89%; p < 0.001).
Regarding Vitamin A and C, Figure 4C,D shows that breakfast consumers had a significantly higher consumption of vitamin A and C than those children who usually skip breakfast (SMD, −7.998; 95%CI: −10.417, −5.579 and SMD, −6.928; 95%CI: −9.471, −4.385, respectively). The heterogeneity amongst studies was high, (I2 = 99.9%; p < 0.001) and (I2 = 99.93%; p < 0.001), respectively.
When analyzing minerals intake, Figure 5A,B shows that those who usually consume breakfast had significantly higher daily intake of calcium and iron than breakfast skippers, (SMD, −7.034; 95%CI: −9.029, −5.040) and (SMD, −6.552; 95%CI: −9.242, −3.861), respectively. The heterogeneity between studies was high, (I2 = 99.89%; p < 0.001) and (I2 = 99.94%; p < 0.001), respectively. Regarding magnesium intake (Figure 5C), breakfast consumers had a higher consumption in respect to breakfast skippers (SMD, −8.101; 95%CI: −12.564, −3.638). Nevertheless, the heterogeneity between studies was high (I2 = 99.97%; p < 0.001).
Likewise, as shown in Figure 5D,E, it was observed that breakfast consumers had higher consumption of sodium and potassium in respect to breakfast skippers, (SMD, −3.395; 95%CI: −5.554, −1.236) and (SMD, −7.181; 95%CI: −10.556, −3.807), respectively. The heterogeneity amongst studies was high, (I2 = 99.93%; p < 0.001) and (I2 = 99.95%; p < 0.001), respectively.

4. Discussion

To the author’s knowledge, this is the first SR taking into consideration the association between breakfast consumption and daily micronutrients intake. The most important finding was the association between breakfast consumption and a higher daily vitamins and minerals intake in both children and adolescents.
Articles included assessed diet using individual or combined FR, 24h-DR, and FFQ. The most common strategy to collect dietary information was through face-to-face interview (n = 11; 33.33%). Nine studies (27.27%) included a self-reported questionnaire, five studies included caregiver-reported questionnaires (15.15%), and eight studies (24.24%) a combination of self- and caregiver-reported questionnaires. Likewise, when assessing dietary intake, it is important to evaluate how nutrients were computed; however, only a few studies (n = 7) reported the reference of the used food composition tables [28,50,62,63,65,67,68].
Most of the studies included in this SR compared the dietary intake of breakfast consumers or consumers of different types of breakfast, for instance RTEC-based breakfast with breakfast-skippers. Actually, of the 30 included studies, the main issue was breakfast’s RTEC consumption (n = 22; 66.66%). RTEC include many types of cereals, refined, whole grain, sweetened, and unsweetened, but in the markets and industry predominantly exists RTEC refined and sweetened. Several previous studies recognized that RTEC consumption at breakfast is associated with a healthier diet [32,52,54,56,67,71] but, in a previous review, authors suggested that RTEC with functional and best nutrient profiles should be developed [72]. In another review, RTEC consumption was related with a healthier dietary pattern (DP), nevertheless, total sugar intake was also high [73]. Some RTEC have high fiber content and have been fortified with essential nutrients as vitamins and minerals, but usually they are low in fat and high in carbohydrates, polysaccharides and sugar [59,74]. Previous studies suggested that RTEC could promote breakfast consumption as RTEC consumption was frequent among breakfast consumers [75]. Nevertheless, for future studies it would be important to investigate or differentiate the cereal consumed e.g., oats, muesli or RTEC sweetened, as not all types of cereals are good sources of micro- and macro-nutrients [46].

4.1. Breakfast Consumption and Vitamins Intake

Taking into consideration some specific foods consumed at breakfast, such as RTEC, some studies compared children or adolescents’ RTECs with non-RTEC consumers at breakfast. Some authors showed associations between RTEC consumption and vitamins intake. Five articles showed that RTEC consumers, both in children and adolescents [44,50,53,56,58], had a higher vitamin A intake than those who usually skip breakfast. Papoutsou et al. showed that those who eat milk and pastries or other types of breakfast had lower intakes of vitamin A [66] than those children who eat regularly RTEC at breakfast. Regarding B vitamins intake, Morgan et al. [49] observed that children who eat RTEC three or more times per week had a higher intake of the B vitamins group. Also, children and adolescents who usually consume RTEC had a high intake of the following B-vitamins: thiamine [42,50,52,54,56,60,61,62,67], riboflavin [42,44,48,50,52,54,56,58,60,61,62,67], niacin [42,44,56,58,60,67], pyridoxine [42,44,50,54,56,60,62], biotin [48], folate [29,42,44,50,52,53,56,59,61,62,64], and cobalamin [44,52,53,54,58,64]. Furthermore, our meta-analysis showed similar results for the difference in micronutrients intake between children consuming RTEC breakfast and those skipping breakfast. In children, those who usually consume RTEC had a high intake of thiamine, riboflavin, vitamin A, and vitamin C.
In the same way, in both children and adolescents, RTEC consumers compared with those who consume other types of breakfast had higher intakes of thiamine, riboflavin, pyridoxine, folate, vitamin A, and vitamin C [42,66]. These results are in line with the frequent fortification of RTEC with vitamins and other micronutrients [59,74]. Previous research showed that the fortified cereal’s consumption with milk produces some benefits in terms of the vitamins and iron intake, and significant improvement in biomarkers of nutritional status [76].
Different authors observed significant associations between breakfast consumption and vitamins intake. Breakfast consumers had a higher intake of vitamin A [41,43,51,68], thiamine [16,43,46,51,68], riboflavin [16,43,46,51], niacin [16,46,51], folate [16,46,51,68], and vitamin D [16,43] than breakfast skippers. Furthermore, an additional included study observed that regular breakfast consumption is associated with higher intakes and higher blood concentrations of some vitamins [16]. Additionally, our meta-analysis presented similar results. Breakfast consumers had a higher intake of riboflavin, vitamin A and vitamin C.
Breakfast consumption has been consistently associated with a better favorable nutrient intake [16,42]; in this sense, a previous study observed that breakfast skippers were significantly less likely to eat the recommended five servings of fruits and vegetables a day [16,77]. Furthermore, those children who usually consume breakfast usually consume more healthful breakfast foods like fruits, cereals, bread or milk [77].

4.2. Breakfast Consumption and Minerals Intake

Thirty-two articles (96.96%) investigated the association between breakfast consumption and minerals intake. Considering specific food groups consumed at breakfast, some authors observed a positive association between RTEC consumed at breakfast and the following minerals: calcium [42,44,48,50,54,56,58,59,60,67], iron [29,42,44,46,47,49,50,52,54,56,58,59,60,61,67], sodium [46], magnesium [42,50,54,56], zinc [50,54,56,59], potassium [42,46,48,54,58], phosphorous [42,46,48,50], iodine [46,62], and copper [50]. Also, two additional studies showed that calcium intake increased with cereal consumption [53,64]. Milk and dairy products used to be the major breakfast constituents in most of the countries [78,79] and provide a high source of vitamins and minerals such as calcium, vitamin D, magnesium, or phosphorous [80,81,82]. Furthermore, two articles showed that those who usually consume RTEC had a high consumption of milk and dairy products [48,57]. In contrast, Ortega et al. presented that dairy breakfast consumption was associated with high daily calcium intake, but this does not depend solely on breakfast consumption [63].
Children and adolescents who usually consume breakfast had higher intakes of calcium [3,30,41,43,45,46,68], iron [3,41,43,45,68], potassium [43,68], magnesium [43,68], zinc [43,68], and iodine [3] than breakfast skippers. In agreement with our SR, our meta-analysis presents similar results, breakfast consumers had a higher consumption of iron, calcium and magnesium. In the same way, Mattys et al. showed that adolescents with good quality breakfast consumed a higher intake of iron, magnesium and phosphorous [65].
It is important to mention that in a previous intervention study, [24] authors observed that adolescents who used to consume breakfast had more adequate vitamins and minerals intakes than those used to skip breakfast. It is worth noticing that approximately 92% of all RTEC are fortified with essential nutrients, however, in different previous studies, authors showed that children and adults who regularly consume RTEC increase their daily vitamins and minerals intake [31,83].

4.3. Potential Influencing Factors of Heterogeneity

We have to acknowledge that important heterogeneity was found for both types of analyzed groups, skipping breakfast versus RTEC breakfast or consumption of others types of breakfast. The high heterogeneity can be explained by the large range of subject’s age (2–16 years) and sample size of the included studies (min. 200, max. 12,281 participants) and the used dietary assessment method (24 h-DR, FR or FFQ). Responses may vary depending on the respondent of these questionnaires (children, adolescents, parents or caregivers) and the socio-cultural desirability. To address these differences, the included meta-analysis was done by age subgroups, showing no differences in their heterogeneity.

4.4. Strengths and Limitations

Our study has some limitations. Firstly, the studies’ design, as most of the included articles were cross-sectional, and it is not possible to determine cause–effect associations between exposure and outcome variables. Half of the studies were not performed in representative samples of the correspondent population, compromising their representativeness. Furthermore, the methodology has its own limitations, for example, some of the included articles evaluated the dietary intake with one 24 h-DR, which is not representative of the habitual diet. Nevertheless, this method is accepted for studying the intake in a large sample of the population and estimating the mean nutrients intake. Reported dietary intake could provide biased results (under or over-reporting) due to social desirability. Furthermore, we only included publications in English and Spanish, and we had to refuse two studies wrote in other different languages (Chinese and Korean). On the other hand, the number of comparison groups is large, making it difficult to obtain conclusions. Only one study analyzed the association between breakfast consumption and blood vitamins concentrations, and it was no possible to compare the results [16].
One of the strengths of the current manuscript is that, to our knowledge, this is the first systematic review and meta-analysis analyzing the associations between breakfast consumption and overall daily micronutrients intake. Also, the included studies were developed in four different continents (America, Asia, Europe and Oceania), which is interesting because they offer a global perspective. On the other hand, the population included in the studies were children and adolescents, and it is important because this means breakfast consumption during youth. Finally, some of the studies were included in the meta-analysis allowing to weight the effect of breakfast on micronutrient intake in young population.

5. Conclusions

Breakfast consumption seems to be associated with higher vitamins and minerals intake. On the other hand, the most frequent food consumed at breakfast was RTEC, and RTEC consumption at breakfast might have beneficial effects in daily vitamins and minerals intake. However, it is important to know the nutritional profile of the RTEC consumed, as they usually have a high-added sugars and/or fat content, and these components should be avoided.
Dietary habits change over the years, and therefore breakfast foods tend also to change. In this sense, it is essential to develop new studies to recognize breakfast consumption impact and its relationship with overall health. Additional studies should be developed to investigate the relationship of the different foods and beverages consumed at breakfast in terms of vitamins and minerals intake and their status.

Supplementary Materials

The following are available online at https://www.mdpi.com/2072-6643/12/10/3201/s1. Table S1. Quality appraisal findings.

Author Contributions

N.G.-L., A.M.S.-P. and L.A.M. had the idea for the article; N.G.-L. and P.F.-B. performed the literature search and data analysis, N.G.-L. and M.L.M.-B. performed the meta-analysis, N.G.-L., P.F.-B., A.M.S.-P., M.L.M.-B. and L.A.M. drafted the manuscript, and critically revised the work. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Acknowledgments

The first author, Natalia Giménez-Legarre received financial support by a grant from Fundación Cuenca Villoro (Zaragoza, Spain). Additionally, the second author, Paloma Flores-Barrantes received financial support by a grant from the Aragón’s Regional Government (Diputación General de Aragón, DGA).

Conflicts of Interest

Authors declare no conflict of interest.

Abbreviations

95%CI95% confidence intervals
24 h-DR24 h-dietary recalls
μgMicrogram
AXISThe Appraisal tool for Cross-sectional Studies
BFBreakfast
DPDietary Pattern
EIEnergy Intake
FFQFood Frequency Questionnaire
FRFood Records
IBRIInternational Breakfast Research Initiative
MDMean Difference
mgMilligrams
MUFAMonounsaturated Fatty Acids
N.ANot Available
PICOParticipants, Intervention, Control, Outcomes
PRISMAPreferred Reporting Items For Systematic Reviews and Meta-Analysis.
PUFAPolyunsaturated Fatty Acids
RTECReady to eat cereal
SFSaturated fat
SRSystematic Review
UKUnited Kingdom
USUnited States
yYears

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Figure 1. Flowchart diagram of study selection and search.
Figure 1. Flowchart diagram of study selection and search.
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Figure 2. Random-effects meta-analysis of the effects of relationships between Ready to Eat Cereal (RTEC) breakfast and breakfast-skipping concerning vitamin B1 (A), vitamin B2 (B), vitamin A (C), and vitamin C (D) intake. CI: confidence intervals.
Figure 2. Random-effects meta-analysis of the effects of relationships between Ready to Eat Cereal (RTEC) breakfast and breakfast-skipping concerning vitamin B1 (A), vitamin B2 (B), vitamin A (C), and vitamin C (D) intake. CI: confidence intervals.
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Figure 3. Random-effects meta-analysis of the effects of relationships between RTEC breakfast and breakfast-skipping concerning calcium (A), iron (B), magnesium (C), sodium (D), and potassium (E) intake.
Figure 3. Random-effects meta-analysis of the effects of relationships between RTEC breakfast and breakfast-skipping concerning calcium (A), iron (B), magnesium (C), sodium (D), and potassium (E) intake.
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Figure 4. Random-effects meta-analysis of the effects of relationships between consumption of other types of breakfast and breakfast-skipping concerning vitamin B1 (A), vitamin B2 (B), vitamin A (C), and vitamin C (D) intake.
Figure 4. Random-effects meta-analysis of the effects of relationships between consumption of other types of breakfast and breakfast-skipping concerning vitamin B1 (A), vitamin B2 (B), vitamin A (C), and vitamin C (D) intake.
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Figure 5. Random-effects meta-analysis of the effects of relationships between consumption of other types of breakfast and breakfast-skipping concerning calcium (A), iron (B), magnesium (C), sodium (D), and potassium (E) intake.
Figure 5. Random-effects meta-analysis of the effects of relationships between consumption of other types of breakfast and breakfast-skipping concerning calcium (A), iron (B), magnesium (C), sodium (D), and potassium (E) intake.
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Table
Table 1. Inclusion and exclusion criteria based on PICOS (Participants, Intervention, Control, Outcomes) principles.
Table 1. Inclusion and exclusion criteria based on PICOS (Participants, Intervention, Control, Outcomes) principles.
PICOSInclusion CriteriaExclusion Criteria
ParticipantPopulation older than 2 years and younger than 18 years; both sexes; all nationalitiesPopulation with different ages. Participants with any reported or known illness.
InterventionBreakfast consumers (Ready to Eat Cereals (RTEC), other types of breakfast)Not having breakfast data
Control/Comparator groupBreakfast skippersNot having breakfast data
OutcomeTotal daily intake of micronutrients.Other outcomes not related with breakfast consumption
Table
Table 2. Appraisal Tool for Cross-Sectional Studies (AXIS).
Table 2. Appraisal Tool for Cross-Sectional Studies (AXIS).
Assessment CriteriaNo. of Satisfactory Studies
1. Were the aims/objectives of the study clear?33
2. Was the study design appropriate for the stated aim(s)?33
3. Was the sample size justified?22
4. Was the target/reference population clearly defined? (Is it clear who the research was about?)33
5. Was the sample frame taken from an appropriate population base so that it closely represented the target/reference population under investigation?27
6. Was the selection process likely to select subjects/participants that were representative of the target/reference population under investigation?24
7. Were the measures undertaken to address and categorize non-responders?1
8. Were the risk factor and outcome variables measured appropriate to the aims of the study?32
9. Were the risk factor and outcome variables measured correctly using instruments/measurements that had been trialed, piloted or published previously?13
10. Is it clear what was used to determine statistical significance and/or precision estimates? (e.g., p values, Cis)33
11. Were the methods (including statistical methods) sufficiently described to enable them to be repeated? 33
12. Were the basic data adequately described?25
13. Does the response rate raise concerns about non-response bias?1
14. If appropriate, was information about non-responders described?0
15. Were the results internally consistent?33
16. Were the results for the analyses described in the methods presented?32
17. Were the authors’ discussions and conclusions justified by the results? 33
18. Were the limitations of the study discussed?23
19. Were there any funding sources or conflicts of interest that may affect the authors’ interpretation of the results? 22
20. Was ethical approval or consent of participants attained?28
Table
Table 3. Characteristics, description and summary of outcomes of articles included in the systematic review (SR) on breakfast and micronutrients intake.
Table 3. Characteristics, description and summary of outcomes of articles included in the systematic review (SR) on breakfast and micronutrients intake.
Author Country, Year and Type of StudyAimSample and Characteristics of Participants £ Data Source and
Dietary Assessment of Breakfast (BF)		Principal Outcome about
Micronutrients
Affenito, S. et al. 2005 [30]United States (US) N.A
Longitudinal 		To examine the association between BF frequency and Ca and fiber intake.n = 2379
Girls. 9–19 y		National Heart, Lung, and Blood Institute Growth and Health Study
3 day-Food records		Frequent BF consumption was associated with more intake of Ca regardless of the total amount of EI consumed (p < 0.001).
Affenito S. et al. 2013 [41]US 2004–2005
Cross-sectional		To examine the association of RTEC consumption and dietary nutrients intake. n = 2298
5–18 y		The third School Nutrition Dietary Assessment Study
1–24 h dietary recall		BF consumption improves the intake of vitA, Ca and Fe (p < 0.05).
Afeiche, M. et al. 2017 [28]Mexico, 2012
Cross-sectional		To compare BF dietary patterns (DP) with BF skipping and the associations with total-day diet energy and nutrients intake.n = 3760
4–13 y		Mexican National Health and Nutrition Survey
1–24 h dietary recall 		BF skippers consumed less B vitamins (riboflavin, niacin, pyridoxine, folate and cobalamin), Ca, vitD, Fe, Zn, Na, and K than BF consumers. The sweetened beverages and milk and sweetened breads DP had the lowest intakes of Fe, Zn and K at BF.
Albertson A. et al. 2003 [56]US 1998–1999
Cross-sectional		To assess the relationship between RTEC frequency consumption and nutrients intake in children.n = 603
4–12 y		American household surveys
14–Food records		RTEC frequency of consumption was not associated to Na, vitE, but it was associated with high intake of vitA, pyridoxine, vitC, thiamin, riboflavin, niacin, folate, Ca, Mg, Fe and Zn (p = 001).
Albertson A. et al. 2008 [57]US 1987
Longitudinal		To assess the association between RTEC consumption and energy and nutrients intake.n = 2379
9–10 y		The National Heart, Lung, and Blood Institute Growth Health Study
1–24 h dietary recalls 		RTEC consumers did not differ from non-RTEC consumers in Na intake (N.S).
Balvin Frantzen, L. et al. 2013 [58]US 2001–2004
Longitudinal 		To assess the association between frequency of RTEC consumption and nutrients intake.n = 625
Mean age = 9.13 y		BIENESTAR Study
3–24 h dietary recalls 		Baseline data analysis concludes that frequency of RTEC consumption was positively associated with the intake of vitD, vitC, riboflavin, niacine, cobalamin, Ca, Fe, and K. (p < 0.05).
Barr, S. et al. 2014 [42]Canada 2004
Cross-sectional		To assess the effect of skipping BF, consuming BF and consuming BF with RTEC on intake of nutrients.n = 12,281
4–18 y		Canadian Community Health Survey, 2004.
1–24 h dietary recall 		RTEC consumers had a higher intake of thiamin, pyridoxine, vitD, Ca, Fe, Mg, P, and K than other-BF consumers and non-BF consumers. Both BF consumers and RTEC consumers had higher intakes of vitA, folate and vitC compared with BF skippers. RTEC consumers had higher intakes of riboflavin than non-RTEC consumers and BF skippers. Other-BF consumers had higher intake of niacin than other groups (p < 0.05).
Barr, SI. et al 2018 [43]Canada 2015
Cross-sectional		To compare daily EI and nutrients intake of BF consumers and BF skippers.n = 2331
6–12 y
n = 2026
13–17 y 		Canadian Community Health Survey-Nutrition
1–24 h dietary recall		Children and adolescents who usually consume BF had a higher intake of thiamin, vitC, Fe, and Mg (p < 0.5).
In adolescents, BF consumers had a high intake of vitA, riboflavin, cobalamin, vitD and K (p < 0.01), pyridoxine, Ca (p < 0.01), and Zn (p < 0.5).
Barton, B. et al. 2005 [59]US 1985
Cross-sectional		To assess the association of BF and RTEC consumption with intake of nutrients. n = 2379
9–19 y		National Heart, Lung and Blood Institute Growth and Health study
3–24 h dietary recalls 		RTEC consumption increases the intake of Ca, Fe, folate, vitC, and Zn.
Coulthard, J. et al. 2017 [3]United Kingdom (UK) 2008–2012
Cross-sectional		To assess differences in nutrients intake between BF skippers and BF consumers.n = 1686
4–18 y		National Diet and Nutrition Survey
4–Food records 		Children and adolescents had significantly higher mean intakes of folate, Ca and I, and significantly lower mean intakes of Na for days on which BF was consumed compared with non-BF days. Frequency of BF consumption was positively associated with folate, Na, Ca, Fe, and I (p < 0.05).
Deshmukh-Taskar, P. et al. 2010 [70]US 1999–2006
Cross-sectional		To assess the relationship between skipping BF or having lunch with nutrients intake, nutrient adequacy and adiposity. n = 930
9–13 y
n = 1805
14–18 y 		NHANES
1–24 h dietary recall		In both children and adolescents, BF skippers had a lower intake of vitA, vitC, riboflavin, cobalamin, folate, Ca, P, Mg, K, and Zn than the other groups (p < 0.05). RTEC consumers had lower Na intake than the other groups (p < 0.05).
Thiamine, niacin, pyridoxine and Fe intake was significantly higher in the RTEC consumers group (p < 0.05).
Fayet-Moore, F. et al. 2016 [46]Australia 2007
Cross-sectional		To assess the impact of BF skipping, BF with RTEC and BF without RTEC on nutrient intake.n = 4487
2–16 y		Australian National Children’s Nutrition and Physical Activity Survey
2–24 h dietary recall 		BF consumers had a higher intake of total Ca, folate, Mg and Zn than BF skippers. RTEC consumers had higher intake of Fe, P, K, I, and Na (p < 0.001). BF consumers, and to a higher degree RTEC consumers, were more likely to meet the EAR of Ca and Fe than BF skippers (p < 0.001).
Fayet-Moore, F. et al. 2017 [45]Australia
2011–2012
Cross-sectional		To investigate the impact of BF skipping, BF with RTEC and BF without RTEC on daily nutrients intake. n = 2821
2–18 y		National Nutrition and Physical Activity Survey
1–24 h dietary recall		BF skippers had lower niacin, Fe, thiamin, riboflavin, folate and Ca, intake whereas they had a higher Na intake than BF consumers (p < 0.001).
Fulgoni, VL. et al. 2019 [55]US
2011–2014
Cross sectional		To compare diet quality and nutrient intake among children consuming an oatmeal-containing BF versus those of children consuming other popular BF.n = 5876
2–18 y		NHANES
1–24 h dietary recall		Oatmeal consumers had a significantly higher intake of Ca, Fe, Mg, K, folate, vitA, and vitD than BF skippers.
In children and adolescents, RTEC consumers had a higher intake of Ca, Fe, Mg, K, vitA, and vitE than those who usually consume “Doughnuts, sweets rolls and pastries”; higher intake of Mg and K than those who usually consume “Pancakes, waffles, French toast” and higher intakes of Ca, Fe and Mg than consumers of “Eggs and omelettes”.
RTEC consumers (lower and higher sugar) had a higher intake of Fe and folate than those children and adolescents who usually consume oatmeal BF.
Gibson, S. et al. 1995 [60]UK
N.A
Cross-sectional		To examine the relation ship between RTEC frequency of consumption and total daily nutrients intake. n = 2705
10–15 y		7-day weighed records Frequency of RTEC consumption in boys and girls was positively associated with Ca, Fe, thiamin, riboflavin, niacin, and pyridoxine intake.
Gibson, S. et al. 1999
[47]		UK
N.A
Cross-sectional		To examine associations between RTEC consumption and iron intake.n = 904
1.5–4.5 y		UK National Diet and Nutrition Survey
4 day weighed records		High RTEC consumers had significantly higher Fe intakes than low cereal consumers. (p < 0.0001). They did not have a significantly higher intake of Ca compared to the other groups (p = 0.06).
Gibson, S. et al. 2003 [61]UK
N.A
Cross-sectional		To examine the impact of RTEC on micronutrient status.n = 1688
4–18 y		The National Diet and Nutrition Survey of Young People
7–24 h dietary recalls		The highest tertile of RTEC intake had 20–60% higher intake of iron, B vitamins and vitD, compared with the first tertile. A positive association between Fe, thiamin, riboflavin and folate was observed across tertiles of RTEC consumption (p < 0.001).
Matthys, C. et al. 2007 [65]Belgium
1997
Cross-sectional		To describe BF consumption patterns and overall nutrients profile.n = 341
13–18 y		Food Consumption Survey
7–24 h dietary recalls		Good quality of BF was associated with higher intake of Ca, Mg, thiamin, riboflavin and vitC and P compared to low quality of BF consumers (p < 0.001). Specifically, girls with good quality of BF had a significantly higher intake of Ca, P, Fe, Mg, thiamin, riboflavin, and vitC (p < 0.001).
McNulty, H. et al. 1996 [64]Ireland 1990
Cross-sectional		To establish the contribution of RTEC to the overall nutrients intake. n = 1015
12–15 y		1–24 h dietary recallHigher RTEC consumption was associated with higher cobalamin intake, except for boys aged 12 years. Folate intake significantly increased with increasing intake of fortified BF cereals in the younger adolescents (p < 0.05). Ca intake increased with increasing BF cereals intake in all age and sex groups (p < 0.05).
Michels, N. et al. 2015 [48]Europe
2006–2007
Cross-sectional		To analyze the association of RTEC consumption frequency with dietary intake.n = 1215
12.5–17.5 y		HELENA Study
1 Food Frequency Questionnaire
2–24 h dietary recalls		Ca, P, K, riboflavin, pantothenic acid, biotin, and VitD intakes were significantly higher in the RTEC consumers group (p < 0.05).
Mielgo-Ayuso, J. et al. 2017 [16]European countries 2006–2007
Cross-sectional		To examine the association between BF consumption patterns and vitamins intaken = 1058
12.5–17.5 y		HELENA Study
2–24 h dietary recalls 		BF consumption was associated with high intakes of vitD and folate in both sexes, with high intakes of pyridoxine and vitE in girls (p < 0.05).
Mohd Nasir, M.T. et al. 2017 [67]Malaysia 2013
Cross-sectional		To compare foods consumed at breakfast and nutrient intake for the total day between RTEC consumers and non-RTEC consumersn = 1819
6–12 y		MyBreakfast study
Children 6–9 y: 2 day food records
Children 10–12 y: 2–24 h dietary recalls		RTEC consumers had a higher daily intake of vitC, thiamine, riboflavin, niacin, Ca, and Fe (p < 0.05). Non-RTEC consumers had a higher intake of Na than RTEC consumers (p < 0.05). No significant associations in vitA and P were observed between RTEC consumers and non-RTEC consumers.
Morgan, K.J. et al. 1981 [49]US 1977
Cross-sectional		To assess BF consumption pattern and relate it with nutrients intaken = 657
5–12 y 		7 day food recordsBF had a significant contribution to child’s daily nutrients intake. RTEC consumers for 3 or more times per week had higher intake of Fe and B vitamins (p < 0.001) than non-RTEC consumers.
Murakami, K. et al. 2018 [68]Japan 2012
Cross-sectional		To assess BF consumption and its association with daily dietary intake of nutrients, food groups and overall diet quality.n = 1444
6–11 y
n = 1134
12–17 y		National Health and Nutrition Survey 2012
1 Dietary record		BF consumers had higher intakes of vitK, folate, vitC, Ca, Mg, and P in both age groups.
Children who usually consumed BF had a higher intake of vitA, vitK and vitC than BF skippers (p < 0.05).
In adolescents, BF consumers had a higher intake of K and Fe than BF skippers (p < 0.05).
In both children and adolescents, BF skippers had a lower intake of pyridoxine, folate, pantothenic acid, Ca, Mg, P, and Zn than BF consumers (p < 0.05).
Ortega, RM. Et al. 1996 [62]Spain N.A
Cross-sectional		To analyze the influence of RTEC consumption at BF upon dietary habits. n = 200
9–13 y		4–24 h dietary recallsThe intake of thiamine, pyridoxine, folate, β-carotene (p < 0.05), riboflavin, and I (p < 0.1) was higher in the group of RTEC consumers.
Ortega, RM. et al. 1998 [63]Spain N.A
Cross-sectional		To assess the association between Ca and milk products consumed at BF with their total daily intake. n = 200
9–13 y		7–24 h dietary recalls BF with <20% of total EI included lower quantities of Ca than larger BF (p < 0.05). These adolescents also consumed less Ca over the rest of the day.
Papoutsou, S. et al. 2014 [66]Cyprus 2007–2008
Cross-sectional 		To investigate the association of BF pattern consumption with children’s diet quality in a sample from Cyprus.n = 1558
4–8 y		IDEFICS Study
1–24 h dietary recall		Milk and pastry consumers had lower intake of Fe, Na, thiamin, riboflavin, and pyridoxine than RTEC consumers. Other—BF, milk and pastry consumers had lower intakes of vitA and vitC. Milk consumers had a lower intake of Mg than the other groups. Milk and pastry consumers had a higher intake of Mg and P (p < 0.05).
Preziosi, P. et al. 1999 [50]France N.A
Cross-sectional		To examine the associations between the intake of different types of BF and dietary intakes.n = 1108
2–18 y		1–24 h dietary recallPercent of RDA for Ca, P, magnesium, and Fe were exceeded in non-RTEC and RTEC consumers but was significantly higher in the group of RTEC consumers (p < 0.05). RDA for thiamine and riboflavin were also reached in both groups but RTEC consumers had higher intakes of both nutrients (p < 0.001 and p < 0.01). Percent of RDA for magnesium, Zn, copper, pyridoxine, folate, vitC, vitA, and vitE were also higher in the RTEC group.
Ramsay, SA. Et al. 2018 [51]US 2005–2012
Cross-sectional		To examine food intake, nutrients intake and overall diet quality among BF consumers and BF skippers. n = 8590
2–12 y		NHANES
1–24 h dietary recall 		BF skippers did not meet the average amount of nutrients of children who consumed BF. BF skippers consumed less vitA, folate, Fe, and Ca than those who consumed BF.
Ruxton, CH. et al. 1996 [29]UK Scotland
1991–1992
Cross-sectional		To provide new data on the BF habit of childrenn = 136
5–9 y		7–24 h dietary recall The overall diets of children in the high RTEC group were higher in micronutrients than the other groups. Folate and Fe in the low RTEC group were below recommendations.
Vatanparast, H. et al. 2019 [54]Canada 2015 Cross-sectionalTo evaluate how RTEC consumption contributed to daily energy and nutrient intakes and then compare them with non-consumersn = 3810
6–12 y
n = 2379
12–18 y		The Canadian diet, the recent nationally representative dietary survey
1–24 h dietary recall 		Children and adolescents who usually consume RTEC had significantly higher intake of pyridoxine, vitD, riboflavin, thiamine, K, Ca, Fe, and Mg than non-RTEC consumers.
In children, RTEC consumers had a higher intake of cobalamin and Zn than non-RTEC consumers.
In adolescents, RTEC consumers had a lower intake of Na than non-RTEC consumers.
Williams, B.M. et al. 2009 [52]US 1999–2002 Cross-sectionalTo assess if BF dietary patterns are associated with nutrients intake and nutritional adequacy. n = 1389
2–12 y		NHANES
1–24 h dietary recall 		RTEC consumers had a higher intake of vitA, cobalamin, thiamine, riboflavin, folate, and Fe (p ≤ 0.05).
Williams, P. et al. 2007 [53]Australia 1995 Cross-sectionalTo assess the contribution of BF to the nutrition of Australian children and adolescents. n = 3007
2–18 y		National Health Survey
1–24 h dietary recall
1 FFQ		Higher RTEC consumption was associated with higher cobalamin intake, except for boys aged 12 years. Folate intake significantly increased with increasing intake of RTEC in younger adolescents. (p < 0.05). Ca intake increased with increasing BF cereal intake in all age and sex groups. (p < 0.05).
£ = All the studies included boys and girls in their analysis, except those in which it was specified that only one gender was included. Abbreviations: N.A: Not available; BF: Breakfast; Y = Years; EI: Energy intake; RTEC: Ready to eat cereal; DP: Dietary Pattern; RDA: recommended dietary allowances; vitA: vitamin A; vitC: vitamin C; vitE: vitamin E; vitD: vitamin D; vitK: vitamin K; Mg: magnesium; Zn: zinc; Ca: Calcium; Na: Sodium; K: potassium; Fe: iron; I: Iodine; P: Phosphorus; Ω = IDEFICS—Identification and prevention of dietary- and lifestyle-induced health effects in children and infants; HELENA—Healthy Lifestyle in Europe by Nutrition in Adolescence.; NHANES—National Health and Nutrition Examination Survey; FFQ: Food Frequency Questionnaire.
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Giménez-Legarre, N.; Miguel-Berges, M.L.; Flores-Barrantes, P.; Santaliestra-Pasías, A.M.; Moreno, L.A. Breakfast Characteristics and Its Association with Daily Micronutrients Intake in Children and Adolescents–A Systematic Review and Meta-Analysis. Nutrients 2020, 12, 3201. https://doi.org/10.3390/nu12103201

AMA Style

Giménez-Legarre N, Miguel-Berges ML, Flores-Barrantes P, Santaliestra-Pasías AM, Moreno LA. Breakfast Characteristics and Its Association with Daily Micronutrients Intake in Children and Adolescents–A Systematic Review and Meta-Analysis. Nutrients. 2020; 12(10):3201. https://doi.org/10.3390/nu12103201

Chicago/Turabian Style

Giménez-Legarre, Natalia, María L. Miguel-Berges, Paloma Flores-Barrantes, Alba M. Santaliestra-Pasías, and Luis A. Moreno. 2020. "Breakfast Characteristics and Its Association with Daily Micronutrients Intake in Children and Adolescents–A Systematic Review and Meta-Analysis" Nutrients 12, no. 10: 3201. https://doi.org/10.3390/nu12103201

APA Style

Giménez-Legarre, N., Miguel-Berges, M. L., Flores-Barrantes, P., Santaliestra-Pasías, A. M., & Moreno, L. A. (2020). Breakfast Characteristics and Its Association with Daily Micronutrients Intake in Children and Adolescents–A Systematic Review and Meta-Analysis. Nutrients, 12(10), 3201. https://doi.org/10.3390/nu12103201

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