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ORIGINAL RESEARCH article

Front. Nutr., 02 September 2024
Sec. Nutritional Epidemiology

Dietary patterns and association with Iron deficiency among children and adolescents aged 9–17 years in rural Guangzhou, China: a cross-sectional study

Jinhan Fu,Jinhan Fu1,2Chunzi ZengChunzi Zeng2Jie HuangJie Huang2Jiaying Guo,Jiaying Guo1,2Zheng Su,Zheng Su2,3Shiyun LuoShiyun Luo2Weiwei ZhangWeiwei Zhang2Zhoubin ZhangZhoubin Zhang2Huilian ZhuHuilian Zhu1Yan Li
Yan Li2*
  • 1School of Public Health, Sun Yat-sen University, Guangzhou, China
  • 2Department of Foodborne Diseases and Food Safety Risk Surveillance, Guangzhou Center for Disease Control and Prevention, Guangzhou, China
  • 3School of Public Health, Southern Medical University, Guangzhou, China

Background: Iron deficiency and iron deficiency anemia cause a huge disease burden worldwide. Diet is an important factor affecting the iron levels. This study aims to explore the dietary patterns of school-aged children in rural areas of Guangzhou and their association with iron deficiency.

Methods: Data on dietary surveys, lifestyle, demographic and laboratory tests were gathered from rural school-age children in Guangzhou. Factor analysis was applied to derive dietary patterns. Robust Poisson regression and subgroup analysis were used to analyze the association between dietary patterns and iron deficiency.

Results: A total of 2,530 children and adolescents aged 9–17 years were enrolled. The prevalence of iron deficiency was 13.36%. Four dietary patterns were identified including snack and fast-food pattern, fruit and vegetable pattern, cereal and tuber pattern and meat and offal pattern. Both children and adolescents in the Q4 group (the highest propensity) of snack and fast-food pattern and cereal and tuber pattern had a higher risk of iron deficiency than the Q1 group (the lowest propensity). Both children and adolescents in the Q4 group of meat and offal pattern and fruit and vegetable pattern had a lower risk of iron deficiency than the Q1 group. The results of stratified analysis showed the negative effect of snack and fast-food pattern and the protective benefits of meat and offal pattern are more obvious for boys, and the negative effect of cereal and tuber pattern were obvious for girls. The negative effect or protective benefits of the four dietary patterns were obvious for children aged 9–13.

Conclusion: Females, older children, and those with shorter sleep duration are at higher risk of iron deficiency. Snack and fast-food pattern and cereal and tuber pattern are risk factors for iron deficiency, and fruit and vegetable pattern and meat and offal pattern are protective factors for iron deficiency. The impact of diet on body iron levels is more obvious in boys and younger children. The findings of this study can provide evidence for formulating prevention and control measures on children and adolescents iron deficiency and iron deficiency anemia.

1 Introduction

Iron is an essential trace element in the human body, which participates in the transportation of oxygen and tissue respiration, maintains normal hematopoietic function, and maintains immune function. Iron deficiency (ID) is a common micronutrient deficiency (1), which refers to a state of reduced or depleted iron reserves in the body (2). According to the World Health Organization (WHO), 280 million children worldwide suffer from anemia, and ID is one of the main causes of anemia (3). In addition, the United Nations Millennium Development Goals (MDGs) also emphasize the severity of micronutrient deficiency, pointing out that more than 2 billion people lack essential minerals such as iron, which are essential for their growth, development and healthy life (4). From 2000 to 2020, the prevalence of anemia among Chinese children aged 0–14 years was 19.9% (5). A survey conducted in seven cities and two townships in China showed that ID detection rate in child was 35.5% and the anemia rate was 9.2% (6).

ID has a slow onset and is easily overlooked in the early stages. In its incipient stages, ID can impair enzyme activity and disrupt neurotransmitter synthesis and transmission, potentially resulting in symptoms such as mental depression and diminished appetite. As the condition progresses, it can develop into iron deficient anemia (IDA). School-aged Children are more prone to developing ID due to increased nutritional needs during their growth and development stages, leading to anemia, which in turn leads to delayed growth and development, decreased immune function, and brain development damage (7). Therefore, evaluating the iron reserves in school-aged children can move the key to preventing IDA forward, take timely intervention measures, and reduce the harm caused by related diseases.

The iron level in the body is influenced by various factors, including digestive system diseases, physiological status, chronic diseases, and diet. Diet is one of the main causes of ID, and ID can occur when there is insufficient iron intake or dietary factors interfere with absorption (8). Therefore, a thorough understanding of children’s dietary habits is crucial for preventing ID. Dietary patterns refers to the types, quantities, and proportions of various foods in daily diet (9), which provides a more comprehensive perspective for dietary analysis, helping to determine the impact of diet on the short-term and long-term health of the population. An investigation in Brazil found a correlation between vegetarian dietary patterns and diminished serum ferritin levels (10), while a study conducted in South Africa on children aged 5–12 also showed a positive correlation between plant protein and carbohydrate-rich diets and ID (11). Guangzhou is famous for Cantonese cuisine, which is a typical representative of the Eastern healthy dietary model and the South China dietary model (12). Our previous research found that the fast-food pattern was a risk factor for anemia in children and adolescents, while the meat and egg pattern was a protective factor (13), but the relationship between dietary patterns and iron reserve level in the body is still unclear. This study aims to explore the association between dietary patterns and ID among rural school-aged children and adolescents in Guangzhou, China, in order to support the MDGs 2.2 to eliminate malnutrition.

2 Materials and methods

2.1 Participants

This cross-sectional study was conducted from June 2022 to May 2023. A multi-stage stratified cluster random sampling method was used to select research participants (1). Five primary schools, five middle schools and two high schools were randomly selected in rural areas of Guangzhou (2). Three grades were selected from each primary school, three grades were selected from each middle school, and one grade was selected from each high school (3). Two to four classes of students were randomly selected from each grade for primary schools, two to five classes of students were randomly selected from each grade for middle schools, and five to six classes of students were randomly selected from that grade for high schools.

The sample size was calculated using the formula: N= d e f f μ α / 2 2 P ( 1 P ) δ 2 (14). The meanings and values of each parameter are as follows: the confidence level is taken as 95%, and μ α / 2 = 1.96 . Because the definition criteria of ID in China are not clear and unified, the limits of each study for determining ID are different. Through the comprehensive judgment of multiple research literatures (2, 6, 1517) and taking the average of multiple results, the ID detection rate of children and adolescents aged 6–17 years old in China is about 15%; the value of the design efficiency d e f f is taken as 2; the relative error r = 20%, δ = 20% × 15%. The sample size was 1,088 students according to the above formula. Considering the invalid questionnaires and rejection rate, the actual sample size was expanded by 10%, so at least 1,197 students were required for the survey. The screening process of the research participants is shown in Figure 1.

Figure 1
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Figure 1. Flowchart of the selection of research participants.

This study conducted a survey of 2,596 students. We excluded 28 students without the laboratory test results, 16 students with more than 10% missing dietary data (In the selected food items, data on consumption frequency or intake amounts were missing for more than 10%), and 21 students with incomplete basic information and lifestyle data. Ultimately, data from 2,530 students were included in the final analysis.

2.2 Survey content

Children and adolescents were interviewed face to face by the uniformly trained investigators. The survey content included questionnaires, physical examinations, and laboratory tests.

(1) Questionnaires: Demographic information, including age, gender, education level of parents. Lifestyle factors: boarding, smoking, alcohol consumption, moderate-intensity exercise, sleep duration and breakfast habits. Dietary survey: a semi-quantitative food frequency questionnaire (FFQ) was used to investigate the frequency of food consumption and intake food consumed by children and adolescents in the past month. Food models and atlas were used to help participants assess their food intake. This FFQ was based on the food frequency questionnaire derived from the China National Chronic Non-Communicable Disease and Nutrition Surveillance in 2015 (18), which was partially adapted to the dietary characteristics of children and adolescents in Guangzhou by a panel of experts in the fields of epidemiology and nutrition. There was study has shown that the FFQ has fair reliability and validity (19), and it also has good consistency in a dietary survey of Guangzhou (20). According to the Chinese Food Composition Table Standard Edition (6th edition) (21), 66 types of food across 16 categories were included in this FFQ.

(2) Physical examinations: height and weight were measured by a mechanical height meter and an electronic scale, with measurements accurate to 0.1 cm and 0.1 kg, respectively. The testing instruments and procedures adhered to the Chinese national standard of anthropometric measurement methods in health surveillance (22). The nutritional status of children and adolescents was indicated by the Body Mass Index (BMI), calculated as BMI = weight (kg)/ height (m2) (23).

(3) Laboratory tests: serum ferritin (SF) was measured by the Latex-enhanced Immunoturbidimetric Assay. Serum transferrin (TRF) and C-reactive protein (CRP) was measured by the Immunoturbidimetric Assay.

2.3 Iron deficiency definition

Serum ferritin deficiency is assessed according to the Expert Consensus on Nutritional Prevention and Treatment of Iron Deficiency Anemia (24), in conjunction with CRP levels. For participants aged 5 years and older, CRP ≤ 5 mg/L and SF < 25 μg/L or CRP > 5 mg/L and SF < 32 μg/L is defined as SF deficiency, which was defined as iron deficiency.

Serum transferrin was used as an auxiliary indicator. According to the National Health Industry Standards of the People’s Republic of China (25), TRF > 3.6 g/L was defined as TRF over-standard, suggesting the reduction of iron in body.

2.4 Dietary pattern establishment

Dietary patterns were constructed through the exploratory factor analysis, 66 food items were classified into 16 food categories, as shown in Supplementary Table S1. The correlation matrix between the 16 food categories was statistically tested, with the Kaiser–Meyer–Olkin (KMO) test yielding >0.8 and the Bartlett’s sphericity test yielding a significant p (p < 0.001), indicating that the correlation between variables was sufficient for factor analysis. Principal component analysis was used to determine the common factors, and factor rotation was performed to minimize the correlation between factors. Factors used to describe different dietary patterns were identified based on the eigenvalue (>1), the scree plot, their professional significance and interpretability. Factors with absolute factor loadings >0.3 (26) were retained as components of dietary patterns (27) in this study. Composite factor scores were grouped into quartiles, with Q1, Q2, Q3, and Q4 representing scores from lowest to highest, respectively.

2.5 Statistical analysis

The questionnaires were coded uniformly. Epidata version 3.1 was used for double data input to establish the original database. Factor analysis was used to construct dietary patterns. Data were described as mean (95% CI) for continuous variables and described as n (%) for categorical variables. Continuous variables were tested for normality and compared by Mann–Whitney U test. Categorical variables were compared by chi-square test and chi-square trend test.

Due to the prevalence of ID was greater than 10% in this cross-sectional study, the relationship between ID and independent variables may be overestimated if the odds ratio (OR) is continued to be used to report the parsed results. In this case, prevalence ratio (PR) is the best indicator of association. Therefore, robust Poisson regression analysis was fitted to identify predictors of ID. PR and 95% CI were calculated, while the linear trend of PRs was estimated. A univariate analytical model and a multivariate analytical model were developed for each dietary pattern. The univariate analytical model was unadjusted. Based on the survey and references, the multifactor analytical model was adjusted for age, gender, BMI, smoking (28), moderate to high intensity exercise (29). And other factors that need to be adjusted were determined based on the results of the single-factor analysis.

Based on the existing studies, the prevalence of ID in girls was higher than in boys (30, 31), gender was selected as a stratification variable. Additionally, recognizing the nutrient needs of children at different stages (31) and the differences in mental development. Age was used as another stratification variable and high school entrance age (14 years old) (32) as the grouping criterion. Because SF was the main indicator, stratified analysis was conducted only on it. The detailed stratification process is shown in Figure 2. SPSS version 26.0 was used for all computations, and a p-value (two-sided) < 0.05 was considered to be statistically significant. GraphPad Prism 9.5 and Office 2021 were used for graphs.

Figure 2
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Figure 2. Flowchart of the establishment of stratified analysis subgroups.

3 Results

3.1 Participant characteristics

A total of 2,530 children and adolescents with complete data (53.79% male, n = 1,361; 46.21% female, n = 1,169) were included in this study. The age range of the children and adolescents was between 9 and 17 years with a mean age of 12.94 years. The prevalence of SF deficiency was 13.36%, with 5.80% in boys and 22.16% in girls. Compared with non-SF-deficient counterparts, the children and adolescents with SF deficiency were more likely to be female, older, and have shorter sleep duration (p < 0.05). The ratio of serum transferrin over-standard was 32.06%, as shown in Table 1. Compared with the normal group, the children and adolescents with TRF over-standard were more likely to be female, higher BMI, have less breakfast and the high school of education level of mother (p < 0.05).

Table 1
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Table 1. Demographic information and lifestyle characteristics of the children and adolescents aged 9–17 years in rural Guangzhou between June 2022 and May 2023.

3.2 Dietary patterns

Dietary patterns, determined by principal component analysis, as depicted in Table 2 and Supplementary Figure S1. Four dietary patterns were generated and explained by factor loading and component analysis. Factor analysis selected four major dietary patterns from the 16 food groups, accounting for 13.06% (snack and fast-food pattern), 12.41% (fruit and vegetable pattern), 10.88% (cereal and tuber pattern) and 9.32% (meat and offal pattern) of variance, which together accounted for 45.66% of the total variance. The factor loading matrix of the food groups was obtained by the varimax rotation, as shown in Table 3. Snack and fast-food pattern mainly includes snack food, fast food, beverages and candy. Fruit and vegetable pattern mainly includes fresh fruits, fresh vegetables, mushrooms, algae, and nuts. Cereal and tuber pattern mainly includes grains, potatoes, beans, bean products and eggs. Meat and offal pattern mainly includes poultry, offal and red meat.

Table 2
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Table 2. Factor loadings and dietary patterns for 16 food groups obtained by factor analysis.

Table 3
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Table 3. Analysis of the correlation between dietary patterns and serum ferritin of the children and adolescents aged 9–17 years in rural Guangzhou between June 2022 and May 2023.

3.3 Characteristics of quartiles (Q) of dietary patterns in study participants

The characteristics of the Q1 (the lowest propensity) and Q4 (the highest propensity) quartiles of the four dietary patterns are shown in Supplementary Table S2. The analyses found that children and adolescents in Q4 group of snack and fast-food pattern were more likely to be older, males, have lower BMI, be boarding, have low parental education level, have the experience with smoking and alcohol, do more moderate to high intensity exercise, have shorter sleep duration and have less times of breakfast. Children and adolescents in Q4 group of fruit and vegetable pattern were more inclined to be younger, be boarding, have high parental education level, less drink and smoking, and have longer sleep duration. Children and adolescents in Q4 group of cereal and tuber pattern were more likely to be older, males, have a higher BMI, do more moderate to high intensity exercise and have more times of breakfast. Children and adolescents in Q4 group of meat and offal pattern were more likely to be older, males, have a higher BMI, be boarding, have high parental education level, have shorter sleep duration, and drink alcohol.

3.4 Association analysis between dietary patterns and iron deficiency

3.4.1 Analysis of dietary patterns and serum ferritin

As shown in Table 3, the results of the Mantel–Haenszel chi-square test showed that the level of tendency for snack and fast-food pattern, fruit and vegetable pattern, and meat and offal pattern were all found to have a linear relationship with the risk of SF (p < 0.05). The results of the Pearson correlation showed that in snack and fast-food pattern r = 0.044, with a p < 0.05, which suggested that the higher the tendency toward this pattern, the more prevalent of SF deficient. Additionally, the results of the Pearson correlation showed that in the fruit and vegetable pattern r = −0.048, and in the meat and offal pattern r = −0.093, both with p < 0.05. These suggested that the higher the tendency toward fruit and vegetable pattern and meat and offal pattern, respectively, the less severe the lack of SF.

Robust Poisson regression analysis showed that after adjusting for age, gender, BMI, moderate to high intensity exercise, sleep duration and smoking, children and adolescents in the Q4 group (the highest propensity) of snack and fast-food pattern had a higher risk of SF deficiency than the Q1 group (the low propensity) (PR = 1.467, 95%CI: 1.110 ~ 1.937, p = 0.007). Children and adolescents in the Q4 groups of cereal and tuber pattern had a higher risk of SF deficiency than the Q1 group (PR = 1.352, 95%CI: 1.027 ~ 1.779, p = 0.032). Conversely, Children and adolescents in the Q4 groups of fruit and vegetable pattern had a lower risk of SF deficiency than the Q1 group (PR = 0.717, 95%CI: 0.538 ~ 0.956, p = 0.023). And both children and adolescents in the Q4 and Q3 groups of meat and offal pattern had a lower risk of SF deficiency than the Q1 group (PR = 0.617, 95%CI: 0.458 ~ 0.831, p = 0.001), (PR = 0.682, 95%CI: 0.522 ~ 0.891, p = 0.005).

3.4.2 Analysis of dietary patterns and serum transferrin

As shown in Table 4, the results of the Mantel–Haenszel chi-square test showed that the level of tendency for meat and offal pattern was found to have a linear relationship with the risk of TRF (p < 0.05). The results of the Pearson correlation showed that in meat and offal pattern r = −0.051, with a p < 0.05, which suggested that the higher the tendency toward this pattern, the lower the degree to the TRF over-standard.

Table 4
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Table 4. Analysis of the correlation between dietary patterns and serum transferrin of the children and adolescents aged 9–17 years in rural Guangzhou between June 2022 and May 2023.

Robust Poisson regression analysis showed that after adjusting for age, gender, BMI, moderate to high intensity exercise, smoking, education level of mother and breakfast habits, children and adolescents in the Q4 groups of meat and offal pattern had a lower risk of TRF over-standard than the Q1 group (PR = 0.841, 95%CI: 0.714 ~ 0.992, p = 0.040).

3.4.3 Analysis of dietary patterns and serum ferritin of different genders and ages

The results of stratified analysis were shown in Figure 3. After stratifying by gender, boys in Q4 group of snack and fast-food pattern had a higher risk of SF deficiency than the Q1 group (PR = 2.569, 95%CI: 1.324 ~ 4.984, p = 0.005). Whereas, boys in Q4 and Q3 groups of meat and offal pattern had a lower risk of SF deficiency than the Q1 group (PR = 0.279, 95%CI: 0.138 ~ 0.565, p < 0.001), (PR = 0.414, 95%CI: 0.222 ~ 0.774, p = 0.006) (Figure 3A). Meanwhile, girls in Q4 group of cereal and tuber pattern were more likely to SF deficiency (PR = 1.420, 95%CI: 1.054 ~ 1.912, p = 0.021) than the Q1 group (Figure 3B).

Figure 3
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Figure 3. Layered analysis of serum ferritin among children and adolescents aged 9–17 years in rural Guangzhou between June 2022 and May 2023. PR (95% CI) for the highest propensity group (Q4), the third group (Q3), and the second group (Q2) compared to the lowest propensity group (Q1) for the four dietary patterns using robust Poisson regression analysis. (A) males, n = 1,361; (B) females, n = 1,169; (C) 9–13 years of age, n = 1744; (D) 14–17 years of age, n = 786. All models were adjusted for variables such as age or sex and BMI, moderate to high intensity exercise, sleep duration and smoking. “*” means p-value <0.05. The detailed tables are in Supplementary Table S3.

After stratifying by age, children aged 9–13 years in Q4 group of snack and fast-food pattern were more likely to SF deficiency than the Q1 group (PR = 1.501, 95%CI: 1.046 ~ 2.154, p = 0.028). Children aged 9–13 years in Q4 group of cereal and tuber pattern were more likely to SF deficiency than the Q1 group (PR = 1.725, 95%CI: 1.210 ~ 2.459, p = 0.003). Whereas children aged 9–13 years in Q4 group of fruit and vegetable pattern were less likely to SF deficiency than the Q1 group (PR = 0.637, 95%CI: 0.436 ~ 0.933, p = 0.021). Children aged 9–13 years in Q4 and Q3 group of meat and offal pattern were less likely to SF deficiency than the Q1 group (PR = 0.669, 95%CI: 0.464 ~ 0.963, p = 0.031), (PR = 0.611, 95%CI: 0.429 ~ 0.869, p = 0.006) (Figure 3C).

4 Discussion

Iron deficiency and iron deficiency anemia have caused a huge disease burden worldwide, threatening the lives and health of billions of people, and are also one of the five major causes of disease burden worldwide (2). In this study, the overall prevalence of ID among the participants was 13.36%, with rates of 5.8% in boys and 22.16% in girls. And the rate of transferrin over-standard was 32.06%. This prevalence of ID was similar to that of 12.60% among children aged 12–17 reported in Beijing (17). In addition, it is higher than the prevalence of 8.19% reported in a survey of children aged 6–12 years in Guangzhou (16), but lower than the prevalence of 18.64% in children aged 8–12 years in Lanzhou, China (15). And it also lower than the prevalence of 20.9% in adolescents aged 10–19 years in India (30). This difference may be caused by the different economic levels and demographic differences in population in different regions. However, the ratio of TRF over-standard was higher than prevalence of ID, possibly because in diagnosing ID, TRF has a higher sensitivity and a lower specificity than SF (2).

This study observed a higher prevalence of ID among girls compared to boys. This phenomenon may be attributed to the gradual maturation of sexual development in girls, leading to increased iron loss during menstruation (33). Furthermore, the prevalence of ID was higher among the older children and adolescents. This could be attributed to the accelerated growth and development during puberty (34), which leads to increased nutritional requirements and increases the possibility of nutritional deficiency. The results were in line with the findings from a previous study (31). The study also found that longer sleep duration was negatively correlated with ID, which was consistent with findings from a study in the United States linking ID to poor sleep quality (35).

Moreover, higher BMI and less breakfast were all associated with the higher rate of transferrin over-standard. Obesity was associated with higher levels of inflammation, which would affect the iron levels in body (36). And skipping breakfast might cause inadequate nutritional intake, which would lead to ID (37). The study also indicated a positive correlation between maternal education level and TRF over-standard. This was attributed to the fact that mothers with higher education levels typically prioritize career advancement, leading to an inadequate balance between work and family. Consequently, they had relatively less time to prepare home-cooked meals or tend to rely more on convenience foods (38). Prolonged consumption of these low-iron foods by children increases the likelihood of ID in body.

In this study, four dietary patterns were identified, including snack and fast-food pattern, fruit and vegetable pattern, cereal and tuber pattern, and meat and offal pattern. Notably, the cumulative contribution rate of snack and fast-food pattern was the highest (13.06%), which indicates that the eating habits of children and adolescents at this stage are significantly influenced by Western dietary culture (39). On the contrary, the other three dietary patterns reflected many characteristics of Cantonese cuisine. Cantonese cuisine forms a significant component of the Lingnan dietary pattern (40). Thus, this study holds crucial practical significance for providing nutritional guidance to children and adolescents with iron deficiency or insufficiency in Guangzhou and even the Lingnan region.

In this study, we found that both snack and fast-food pattern and cereal and tuber pattern were positively associated with the risk of ID. Snack and fast-food pattern was characterized by a higher intake of snack food, fast food, and beverages; cereal and tuber pattern was characterized by a higher intake of grains, potatoes and beans. The common feature of these two dietary patterns is that the food they contain either has low iron content or may interfere with iron absorption. For example, all foods of snack and fast-food pattern were generally of lower nutritional value, mainly in the form of higher energy density and saturated fat content, as well as higher added sugars and salt. Prolonged consumption of these foods could impair the ability of liver cells to absorb iron (41). And the sugary beverages could negatively affect iron metabolism, thereby reducing ferritin levels in the body (42). Moreover, these types of foods are actually low in iron. A study in Poland (43) showed that fast foods provided only 4% of the body’s recommended daily iron intake. At the same time, fast foods on the market were mainly composed of white meat such as fried chicken breast and chicken nuggets, which could not provide enough iron (12). In addition, the effect of cereal and tuber pattern was also consistent with the results in the existing studies, such as diet based on rice and wheat or whole wheat bread led to the development of ID (4446). This might be cause by the fact that most of the food in this dietary pattern was the staple food. However, these plant foods contained anti-nutritional factors such as phytic acid and tannin, which could form insoluble complexes with iron, thus reducing the bioavailability and intestinal absorption of iron. Moreover, iron in plant foods was mainly non-heme iron, and its bioavailability was lower than that of heme iron in animal foods (47). Therefore, even if the intake was high, the actual amount of iron absorbed and utilized by the human body might be insufficient.

Conversely, we found that both fruit and vegetable pattern and meat and offal pattern were negatively associated with the risk of ID. Fruit and vegetable pattern, which was characterized by a higher intake of fresh fruits and vegetables; meat and offal pattern, which was characterized by a higher intake of offal, red meat, and poultry. Both of the two dietary patterns contained foods that were high in iron or contained ingredients that facilitated iron absorption. For example, fresh fruits and vegetables were naturally rich sources of vitamin C, which played an important role in the absorption of iron. It not only enhanced the absorption of non-heme iron (48), but also promoted the export of iron from the gut into the circulatory system by altering the expression of hepcidin RNA in cells (49). A study also had shown that girls who did not eat enough fruit were at higher risk of low serum iron levels, and that eating green leafy vegetables such as amaranth could significantly increase serum hepcidin levels in girls, which could help prevent ID (50). What’s more, the foods such as meat and offal are rich in iron (8, 51), predominantly in the form of heme iron. Heme iron was a kind of stable iron combined with porphyrin in hemoglobin and myoglobin, which could be directly absorbed by intestinal mucosal epithelial cells. Therefore, it was less affected by other dietary factors and showed high bioavailability. A study conducted in Britain (52) was also indicated that increased consumption of animal foods would reduce the risk of ID. Moreover, the transferrin over-standard was only negatively associated with meat and offal pattern, providing further evidence that this pattern was protective for ID.

However, the three Pearson correlations between dietary patterns and SF and the one Pearson correlation between dietary patterns and TRF were weak in this study. This could be explained by two main factors. Firstly, the mechanisms of iron storage and release in the body involved multiple physiological processes, which were not a simple linear process. Secondly, the composition of the daily diet was complex, with components that both affected and promoted iron absorption. These two factors might be in a dynamic equilibrium state, which made the association between diet and iron reserves weak.

The multivariate analysis on the association between dietary pattern and TRF indicated that only meat and offal pattern was correlated with TRF. Children and adolescents who were more inclined toward meat and offal pattern had a lower risk of TRF over-standard. This was consistent with the effect of dietary patterns on SF, both indicated that meat and offal pattern was associated with a lower incidence of ID. And it implied that meat and offal pattern had the most pronounced effect on iron levels in the body, which was also in line with previous research (8) stating that meat and offal were good sources of iron intake.

In addition, the results of the stratified study showed that the negative effect of snack and fast-food pattern and the protective benefits of meat and offal pattern are more obvious for boys. Boys were more likely to choose fast foods and meat as food sources because they were more physically active and had higher energy expenditure. These foods were usually high in calories and protein, which could help them recover quickly and maintained the energy level needed for daily activities. A study conducted in Canadia (53) also indicated that men consumed fast foods more frequently than women. And the negative effect of cereal and tuber pattern was more obvious for girls. It was speculated that some girls might choose a vegetarian diet to maintain a slim figure, however, long-term vegetarian diet might lead to inadequate iron intake, which in turn affected iron reserves in the body (54). The negative effect or protective benefits of the four dietary patterns were obvious for children aged 9–13. This phenomenon might be related to the weak self-control ability and low cognitive development level of children in this age group (55). They might be more susceptible to the temptation of instant gratification and chose to eat more of their preferred foods. In addition, the cognitive abilities of children aged 9–13 were still developing compared with older children (56), which might affect their understanding of the importance of healthy diet. This result also indicated that early nutrition and health education for children is better.

However, the present study had several limitations. Firstly, the dietary data were collected based on the dietary intake of children and adolescents over the past month, and recall bias cannot be avoided. Secondly, the study only utilized two indicators for ID, which may not provide a comprehensive assessment. Further research could be conducted by incorporating additional indicators. Thirdly, the participants of this study were children and adolescents from the rural areas of Guangzhou. Therefore, the results need to be extrapolated with caution due to the potential differences in population structure and the dietary habits characteristic of the local area. Finally, the cross-sectional design of the study could not confirm causation. Prospective cohort studies are needed to clarify the relationship between dietary patterns and ID.

5 Conclusion

To sum up, the situation of iron deficiency among rural school-age children and adolescents in Guangzhou remains a significant concern. Four dietary patterns were identified in this study, including snack and fast-food pattern, fruit and vegetable pattern, cereal and tuber pattern, and meat and offal pattern. Snack and fast-food pattern and cereal and tuber pattern are risk factors for ID, and fruit and vegetable pattern and meat and offal pattern are protective factors for ID. The impact of diet on body iron levels is more obvious in boys and younger children. The findings of this study can provide evidence for formulating prevention and control measures on adolescent iron deficiency and iron deficiency anemia.

Data availability statement

The original contributions presented in the study are included in the article/Supplementary material, further inquiries can be directed to the corresponding author.

Ethics statement

The studies involving humans were approved by the Ethics Committee of the Guangzhou Center for Disease Control and Prevention. The studies were conducted in accordance with the local legislation and institutional requirements. Written informed consent for participation in this study was provided by the participants’ legal guardians/next of kin.

Author contributions

JF: Writing – review & editing, Methodology, Writing – original draft, Software, Investigation, Data curation, Conceptualization. CZ: Writing – review & editing, Investigation, Conceptualization. JH: Writing – review & editing, Investigation, Conceptualization. JG: Writing – review & editing, Investigation, Data curation. ZS: Writing – review & editing, Investigation, Data curation. SL: Writing – review & editing, Investigation. WZ: Writing – review & editing, Project administration. ZZ: Writing – review & editing, Project administration. HZ: Writing – review & editing, Supervision. YL: Methodology, Writing – review & editing, Investigation, Conceptualization.

Funding

The author(s) declare that financial support was received for the research, authorship, and/or publication of this article. This work was supported by the Guangzhou Municipal Science and Technology Bureau (grant numbers 2023A03J0451 and 2023A03J0940).

Acknowledgments

The authors would like to thank all participants of the study and the healthcare workers of the Zengcheng and Conghua Center for Disease Control and Prevention.

Conflict of interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher’s note

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Supplementary material

The Supplementary material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fnut.2024.1443849/full#supplementary-material

Abbreviations

ID, Iron deficiency; IDA, Iron deficiency anemia; FFQ, Food frequency questionnaire; BMI, Body mass index; SF, Serum ferritin; TRF, Serum Transferrin; CRP, C-reactive protein; KMO, Kaiser–Meyer–Olkin.

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Keywords: children, adolescents, dietary patterns, iron deficiency, Guangzhou, China

Citation: Fu J, Zeng C, Huang J, Guo J, Su Z, Luo S, Zhang W, Zhang Z, Zhu H and Li Y (2024) Dietary patterns and association with Iron deficiency among children and adolescents aged 9–17 years in rural Guangzhou, China: a cross-sectional study. Front. Nutr. 11:1443849. doi: 10.3389/fnut.2024.1443849

Received: 04 June 2024; Accepted: 20 August 2024;
Published: 02 September 2024.

Edited by:

Yong Zhao, Chongqing Medical University, China

Reviewed by:

Dantong Wang, Nestle Institute of Health Sciences (NIHS), Switzerland
Cristiane Simões De Souza, Universidade Federal de Goiás, Brazil

Copyright © 2024 Fu, Zeng, Huang, Guo, Su, Luo, Zhang, Zhang, Zhu and Li. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Yan Li, gzcdcliy@foxmail.com

Disclaimer: All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.