Hostname: page-component-cd9895bd7-p9bg8 Total loading time: 0 Render date: 2024-12-25T01:39:35.050Z Has data issue: false hasContentIssue false

Carbohydrate intakes, food sources and tracking in Australian young children

Published online by Cambridge University Press:  23 October 2024

Tinsae Shemelise Tesfaye*
Affiliation:
Institute for Physical Activity and Nutrition (IPAN), School of Exercise and Nutrition Sciences, Deakin University, Geelong, VIC, Australia
Ewa A. Szymlek-Gay
Affiliation:
Institute for Physical Activity and Nutrition (IPAN), School of Exercise and Nutrition Sciences, Deakin University, Geelong, VIC, Australia
Karen J. Campbell
Affiliation:
Institute for Physical Activity and Nutrition (IPAN), School of Exercise and Nutrition Sciences, Deakin University, Geelong, VIC, Australia
Miaobing Zheng
Affiliation:
Institute for Physical Activity and Nutrition (IPAN), School of Exercise and Nutrition Sciences, Deakin University, Geelong, VIC, Australia
*
*Corresponding author: Tinsae Shemelise Tesfaye, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Carbohydrate intake and key food sources of carbohydrates in early childhood are poorly understood. The present study described total carbohydrate intake and subtypes (i.e. starch, sugar), their primary food sources and their tracking among young Australian children. Data from children at ages 9 months (n 393), 18 months (n 284), 3·5 years (n 244) and 5 years (n 240) from the Melbourne InFANT Program were used. Three 24-hour recalls assessed dietary intakes. The 2007 AUSNUT Food Composition Database was used to calculate carbohydrates intake and food groups. Descriptive statistics summarised total carbohydrate and subtype intake and their main food sources. Tracking was examined using Pearson correlations of residualised scores between time points. Total carbohydrate, starch and sugar intakes (g/d) increased across early childhood. The percentage of energy from total carbohydrates (% E) remained stable overtime (48·4–50·5 %). From ages 9 months to 5 years, the %E from total sugar decreased from 29·4 % to 22·6 %, while the %E from starch increased from 16·7 % to 26·0 %. Sources of total carbohydrate intake changed from infant formula at 9 months to bread/cereals, fruits and milk/milk products at 18 months, 3·5 and 5 years. Across all time points, the primary sources of total sugar intake were fruit, milk/milk products and cakes/cookies, whereas main food groups for starch intake included bread/cereals, cakes/cookies and pasta. Weak to moderate tracking of total carbohydrates, total sugar and starch (g/d) was observed. These findings may have the potential to inform the refinement of carbohydrate intake recommendations and design of interventions to improve children’s carbohydrate intake.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of The Nutrition Society

The primary role of dietary carbohydrates is to provide energy to the body’s cells, organs and tissues, particularly the brain, which requires glucose for its metabolism(1,2) . They also play a crucial role in the growth and development of children(Reference Stephen, Alles and de Graaf3). Nevertheless, the consumption of simple carbohydrates with a high sugar content has been linked to poor overall dietary quality, an increased risk of obesity, chronic diseases and a higher risk of dental caries in children(2,4) . Conversely, consuming foods containing starch or complex carbohydrates such as whole grains, fruits, vegetables and pulses, along with high intakes of dietary fibre, has been shown to have a positive health impact(2,4) .

Carbohydrates can be classified in many ways and may be expressed using varying terminology. Nutritionally, carbohydrates can be categorised into two main groups: ‘digestible/glycaemic/available carbohydrates’ defined as those digested and absorbed in the human small intestine, providing carbohydrates to body cells, and ‘non-digestible/unavailable carbohydrates’ such as dietary fibre, defined as those passing to the large intestine, where they nourish intestinal bacteria(Reference Stephen, Alles and de Graaf3Reference Niinikoski and Ruottinen5). Digestible carbohydrates are further classified into simple (sugar) and complex carbohydrates (starch)(Reference Stephen, Alles and de Graaf3,Reference Samaniego-Vaesken, Partearroyo and Valero6) . The term ‘sugars’ refers to both monosaccharides (galactose, fructose and glucose) and disaccharides (lactose and sucrose), which contribute to the sweet taste of our food(4,Reference Samaniego-Vaesken, Partearroyo and Valero6Reference Cummings and Stephen8) . In the literature, other classifications include sugars naturally occurring in foods (e.g. ‘intrinsic’ sugars) v. sugars added to foods during processing or preparation (e.g. ‘added’ or ‘extrinsic’ sugars’)(4,Reference Cummings and Stephen8) .

Even though carbohydrates are an essential energy source, contributing approximately half of the dietary energy intake in most countries worldwide, the intake of carbohydrates in children is poorly understood(Reference Niinikoski and Ruottinen5). Studies investigating carbohydrate intake trends and key sources during early childhood are sparse and have been conducted in the USA(Reference Grimes, Szymlek-Gay and Campbell9), Asia(Reference Lim, Toh and van Lee10) and European countries(Reference Samaniego-Vaesken, Partearroyo and Valero6,Reference Huysentruyt, Laire and Van Avondt11) . Previous studies on carbohydrate intake and main food sources in Australian children have primarily focused on total carbohydrates(Reference Zhou, Gibson and Gibson12,Reference Moumin, Netting and Golley13) , or specific types such as sugar(Reference Devenish, Ytterstad and Begley14) or fibre(Reference Thorsteinsdottir, Campbell and Heitmann15), with most utilising cross-sectional data only. Australia’s most recent national nutrition survey (2011–2012)(16) revealed total carbohydrate, total sugar and starch intakes, as well as key food sources in children aged 2–8 years. However, it is important to note that the survey did not include children under 2 years of age.

Furthermore, evidence indicates dietary habits may be shaped at a young age, maintained throughout life with tracking over time and have enduring impact on health(Reference Schwartz, Scholtens and Lalanne17,Reference Langley-Evans18) . However, carbohydrate intake trends and tracking in early childhood remain unclear. Given the crucial role of carbohydrates in human health, there is an urgent need for longitudinal data on carbohydrate intakes, food sources and tracking to gain a deeper understanding of children’s carbohydrate intake in order to identify evidence-based solutions. Investigating trends in carbohydrate intakes, including subtypes like sugar and starch, and identifying main food sources can guide refinement of recommended intakes and food-based dietary guidelines for young Australian children, as well as inform the design of nutrition interventions to optimise carbohydrate intakes. Thus, the present study aimed to (1) describe the intakes of total carbohydrates and their subtypes (starch and total sugar), (2) describe their main food sources and (3) analyse tracking among young Australian children across the first 5 years of life (at 9 and 18 months and 3·5 and 5 years).

Methods

Study population

The present study is a secondary analysis of data from the Melbourne Infant Feeding Activity and Nutrition Trial (InFANT) Program(Reference Campbell, Hesketh and Crawford19). Detailed study protocol and intervention outcomes were reported previously(Reference Campbell, Hesketh and Crawford19Reference Campbell, Lioret and McNaughton21). Briefly, it was a 15-month intervention study aimed at preventing childhood obesity among 542 first-time mothers and their children from when their infants were aged 4–18 months(Reference Campbell, Hesketh and Crawford19). Without a specific focus on carbohydrates, nutrition education was provided to parents in the intervention group, while parents in the control group received standard care(Reference Campbell, Lioret and McNaughton21). The cohort was then followed up with no intervention when the children were 3·5 and 5 years old(Reference Hesketh, Campbell and Salmon20). Ethics approval was obtained from Deakin University Human Research Ethics Committee (ID no. EC 175-2007) and the Victorian Office for Children (ref: CDF/07/ 1138).

Demographic and socio-economic measures

At study baseline (when the children were four months old), parents reported information on child sex, age, gestational age, maternal country of birth (Australia or other), maternal education, maternal employment status, maternal height and pre-pregnancy body weight(Reference Campbell, Abbott and Zheng22). Mothers reported a child’s birth weight based on birth records. Weight for gestational age was classified as small for gestational age if the child’s birth weight was below the 10th percentile, appropriate for gestational age if birth weight was between the 10th and 90th percentiles and large for gestational age if birth weight was above the 90th percentile(23). At ages 4 and 18 months, mothers reported the timing of breast-feeding cessation and introduction of complementary foods(Reference Campbell, Hesketh and Crawford19). Breast-feeding duration and timing of solid food introduction were then coded as dichotomous variables, using the cut-off of 6 months (< 6 months, ≥ 6 months), consistent with previous publications from this cohort(Reference Thorsteinsdottir, Campbell and Heitmann15,Reference Zheng, Lioret and Hesketh24) . Maternal education attainment was classified as below university (high school/certificate/diploma/trade) or university (university degree or higher). Self-reported maternal pre-pregnancy BMI was calculated as weight in kilograms divided by height in meters squared(Reference Lioret, Mcnaughton and Spence25,Reference Zheng, Yu and He26) .

Child anthropometric characteristics

Trained research staff measured children’s length/height and weight at ages 9 and 18 months and 3·5 and 5·0 years(Reference Campbell, Lioret and McNaughton21,Reference Zheng, Yu and He26) . Height/length was measured barefoot twice to the nearest 1 mm with (Seca 210; Seca Deutschland) or a portable stadiometer (Invicta IPO955; Oadby). Children’s weight was measured to the nearest 10 g with calibrated digital scales (Tanita 1582; Tanita Corp), wearing light clothes and without shoes. The mean of two measurements was used in the current analyses.

Dietary assessment

Child’s dietary intake was assessed by telephone-administered multiple-pass three 24-hour recalls at ages 9 months, 18 months, 3·5 years and 5 years by trained nutritionists(Reference Hesketh, Campbell and Salmon20,Reference Campbell, Lioret and McNaughton21) . Parents of children were interviewed on 3 nonconsecutive days, including 2 weekdays and 1 weekend day. Ninety-six percent of the telephone calls were unscheduled to minimise response bias. A food measurement booklet consisting of photographs of standard portion sizes and examples of measurements were provided to parents to assist with portion size estimation(Reference Lioret, Mcnaughton and Spence25). Consistent with previous studies(Reference Campbell, Abbott and Zheng22,Reference Lioret, Mcnaughton and Spence25) , breast-feeding was recorded as minutes spent breast-feeding and then converted to volume using a conversion factor of 10 ml per minute up to a maximum of 100 ml for any one feed. If breast milk was expressed, the volumes estimated from caregiver reports were used(Reference Campbell, Abbott and Zheng22). The dietary data collected were converted into daily energy intake (kJ/d), total carbohydrate intake (g/d), total sugar intake (g/d) and starch intake (g/d) using the 2007 Australian Food, Supplement, and Nutrient Food Composition Database (AUSNUT 2007)(27). The percentages of total carbohydrates, total sugar and starch in relation to total energy intake (% of energy) were also calculated. Food sources of total carbohydrates, total sugar and starch in the diet were categorised into thirty food groups (online Supplementary Table S1) following the standard food grouping in the 2007 AUSNUT database(27). Mean values and standard deviations of daily intake of total carbohydrates (g/d), total sugar and starch, along with the respective percentage contributions to total energy intake, were computed for each food group. Aligned with previous approaches used in the Melbourne InFANT program(Reference Campbell, Abbott and Zheng22,Reference Lioret, Mcnaughton and Spence25) , this analysis used the mean daily dietary intake over 3 days.

Statistical analysis

The current analyses included the data of children at ages 9 months,18 months, 3·5 years and 5 years (n 542). Data were excluded for children from non-first-time mothers (n 14) and those with fewer than 3 days of dietary recalls or outlier total energy intake (±3 standard deviations). Additional exclusions were made at 9 and 18 months in line with previous publication from the InFANT study(Reference Campbell, Abbott and Zheng22). Specifically, children younger than 7 months or older than 11 months were excluded from the analysis at age 9 months (n 30), while those younger than 16 months or older than 20 months were excluded from the sample at age 18 months (n 85). No age exclusion was applied to 3·5 and 5 year follow-ups. The age ranges at each time point for the current analysis are 7–10 months, 15–29 months, 3–4 years and 4–5 years. After implementing these exclusion criteria, the final analysis included samples of n 393 at 9 months, n 284 at 18 months, n 244 at 3·5 years and n 240 at 5 years (online Supplementary Fig. S1). Since there were no statistical differences observed in total carbohydrate, sugar and starch intakes between the intervention and control groups apart from sugar intakes at age 18 months (online Supplementary Table S2), the data from both groups were pooled for the current analyses. The present study used t tests or ANOVA to compare total carbohydrate, total sugar and starch intake by cohort characteristics. Descriptive statistics were used to summarise daily intakes of energy (kJ/d), total carbohydrates (g/d), carbohydrate intake per body weight (g/kg/d), % of energy from carbohydrates and key food sources of carbohydrate intake at all time points. Similarly, intakes of total sugar and starch (g/d), % of energy from total sugar and starch and key food sources at all time points were calculated. Frequencies and proportions were reported for categorical variables, while means and standard deviations (sd) were presented for continuous variables.

To assess tracking across all time points, residualised intake scores were created by regressing the children’s carbohydrate and subtypes (total sugar and starch) intake after adjusting for age, sex and total energy intake(Reference Willett28). Pearson product–moment correlations were calculated to the adjusted residual carbohydrate intake scores between different time points. Statistical assumptions were satisfied for all the models examined. Further, sensitivity analyses were conducted to evaluate tracking by including only the samples followed at all time points (9 months, 18 months, 3·5 years and 5 years). Consistent with previous publications(Reference Campbell, Abbott and Zheng22,Reference Lioret, Mcnaughton and Spence25) , the interpretation of these correlation coefficients was based on the following recommendations: < 0·3 for weak tracking, 0·3–0·6 for moderate tracking and > 0·6 for high tracking(Reference Cohen29). Stata v17 (StataCorp LLC) was used for all the statistical analyses.

Results

Of 393 children, 52·4 % of participants were boys, and the majority of the children had an appropriate birth weight for gestational age (82·7 %). Most of the children were breastfed for more than 6 months (75·9 %) and introduced to solid foods at or after the age of 6 months (90·9 %). Most mothers (79·3 %) were born in Australia, 7·2 % were in paid employment and 58·2 % had a university education.

Comparisons of total carbohydrate, total sugar and starch intakes (g/d) at age 9 months by child and maternal characteristics are shown in Table 1. There was a statistically significant difference in mean carbohydrate, total sugar and starch intakes between boys and girls, with higher intakes observed in boys than in girls (P ≤ 0·001). No significant difference was observed for total carbohydrates, total sugar and starch by child birthweight. Compared with children who were breastfed for 6 months or more and introduced to solids after 6 months of age, those who were breastfed for < 6 months and introduced to solids early (< 6 months) had higher total carbohydrate (P ≤ 0·001), total sugar (P ≤ 0·001) and starch intakes (P ≤ 0·001). The mean total sugar intakes of children whose mothers were in paid employment were significantly higher than those of children whose mothers were unemployed (P = 0·02). Similarly, children with mothers below a university degree had higher total carbohydrate and starch intakes than children whose mothers had a university degree or higher (P < 0·001). However, no significant difference was observed in the total sugar intake of children by maternal education status.

Table 1. Comparison of mean (sd) total carbohydrate, total sugar and starch (g/d) intake at age 9 months by child and maternal characteristics (n 393) at 9 months in the Melbourne infant feeding activity and nutrition trial program

(Mean values and standard deviations)

CHO, carbohydrate. SGA, small for gestational age, AGA, appropriate for gestational age, LGA, large for gestational age.

* n differs for each variable due to missing data.

Differences between CHO, total sugar and starch were assessed by t test or ANOVA,

employed: (part time /full time paid employment at time of data collection), unemployed (student/maternity leave/home duties/unemployed).

Dietary carbohydrate intake

Dietary energy, total carbohydrate, starch and total sugar intakes over four time points are described in Table 2. From ages 9 months to 5 years, the mean daily energy and total carbohydrate intake (g/d) increased from 3490 kJ/d to 5889 kJ/d and 99·7–174 g/d, respectively. Likewise, total sugar and starch intakes (g/d) increased throughout early childhood. Total carbohydrate intake per kg body weight appeared to be steady from 9 to 18 months of age but decreased afterward. The proportion of total carbohydrates to total energy remained stable overtime (48·4–50·5 %). Nevertheless, the percentage of energy from total sugar decreased from 29·4 % at 9 months to 22·6 % at 5 years, while the percentage of energy from starch increased from 16·7 % at 9 months to 26·0 % at 5 years.

Table 2. Energy, total carbohydrate and starch intake at 9 months, 18 months, 3·5 years and 5 years in Melbourne infant feeding activity and nutrition trial program*

(Mean values and standard deviations)

* Nutrient reference values (NRV) for carbohydrates (adequate intake (AI): age 0–6 months: 60 g/d, age 7–12 months: 95 g/d), no NRV for age 1–5 years, acceptable macronutrient distribution range (AMDR) for carbohydrates is 45–65 % of energy for all time points.

Food sources of total carbohydrate, total sugar and starch

At the age of 9 months, the predominant source of total carbohydrates (24 %) in infants was infant formula, followed by breads/cereals (16·1 %), fruits (12·9 %), breast milk (10·5 %) and milk and milk products (6·9 %) (Table 3). At 18 months, 3·5 years and 5 years, the major sources of total carbohydrates shifted to breads/cereals, followed by fruits, milk and milk products and cakes/cookies. Other key contributors to total carbohydrate intake, ranging from 4 % to 5 %, included infant cereals, infant foods, pasta, sweet snacks and sugar-sweet beverages.

Table 3. Main total carbohydrate food sources at ages 9 months, 18 months, 3·5 years and 5 years in Melbourne infant feeding activity and nutrition trial program

(Percentages; mean values and standard deviations)

CHO: Total carbohydrates;

* Percentage of children who consumed food at least once during data collection.

Includes dairy milk, yoghurt, cheese, frozen milk products and custard.

Regarding total sugar intake, fruits were the primary source of total sugar at all time points (28·5–33·1 %), followed by milk and milk products (18·4–33·4 %) (Fig. 1). Breads/cereals, cakes/cookies, sugar-sweetened beverages and sweet snacks were important food groups each contributing approximately 3–4 % of total sugar intake. Finally, across all time points the primary sources of starch intake were breads/cereals (26·4–52·5 %) followed by cakes/cookies (6·8–17·7 %), pasta (8·4–9·9 %) and potatoes (4·5–6·2 %) (Fig. 2).

Fig. 1. Main total sugar food sources at ages 9 months (n 393), 18 months (n 284), 3·5 years (n 244) and 5 years (n 240) in Melbourne Infant Feeding Activity and Nutrition Trial Program.

Fig. 2. Main starch food sources at ages 9 months (n 393), 18 months (n 284), 3·5 years (n 244) and 5 years (n 240) in Melbourne Infant Feeding Activity and Nutrition Trial Program.

Tracking of total carbohydrates, sugar and starch intakes

Residualised total carbohydrate intake at 9 and 18 months showed a weak yet statistically significant correlation (r = 0·24; P ≤ 0·001). In contrast, no tracking was observed for carbohydrate intake between 9 months and 3·5 years (r = 0·07; P = 0·29), or between 9 months and 5 years (r = 0·06; P = 0·37) (Table 4). Similar weak correlations at ages 9 and 18 months were observed for total sugar (r = 0·15; P = 0·02) and starch intake (r = 0·18; P = 0·004). No evidence of tracking was found for sugar or starch between 9 months and 3·5 years (r = 0·11; P = 0·12; r = 0·12; P = 0·08), or for starch between 9 months and 5 years (r = 0·09; P = 0·15). Additionally, residualised total carbohydrate intake at 18 months showed a moderate correlation with scores at 3·5 years (r = 0·30; P ≤ 0·001) and a weak correlation at 5 years (r = 0·15; P = 0·05). However, residualised total sugar and starch intakes at 18 months significantly correlated with intakes at 3·5 and 5 years of age (r ranging from 0·23–0·34). A moderate and highly significant correlation was observed at ages 3·5 years and 5 years for total carbohydrate (r = 0·39; P < 0·0001), total sugar (r = 0·39; P ≤ 0·0001) and starch intakes (r = 0·41; P ≤ 0·001).

Table 4. Tracking of total carbohydrate, sugar and starch at ages 9 months, 18 months, 3·5 years and 5 years in Melbourne infant feeding activity and nutrition trial program

CHO, total carbohydrates.

* Pearson correlation of linear regression predicted residuals of carbohydrates, total sugar and starch at each timeline, n at each compared age is as follows: 9 months and 18 months (n 256), 9 months and 3·5 years (n 213), 9 and 5 years (n 211), 18 months and 3·5 years (n 178), 18 months and 5 years (n 175) and 3·5 and 5 years (n 204).

Sensitivity analysis

When evaluating carbohydrate, sugar and starch intake tracking using samples followed at all time points (9 months, 18 months, 3·5 years and 5 years) (n 141), broadly similar correlations were observed, with some exceptions (see online Supplementary Table S6). Weak correlation was found for carbohydrate intake between 9 months and 3·5 years (r = 0·21; P = 0·01), while no significant correlations were observed for sugar (r = 0·10; P = 0·23) and starch (r = 0·12; P = 0·15) intake between 9 months and 18 months.

Discussion

In a cohort of Australian young children, the intakes of total carbohydrates and subtypes (sugar, starch) (g/d) increased over time in the first years of life. The proportion of total carbohydrates to total energy intake remained relatively stable across all time points. However, the percentage of energy from total sugar decreased, while the percentage of energy from starch increased. Sources of total carbohydrates intake changed over time, shifting from infant formula to breads/cereals, fruits, milk and milk products and cakes/cookies. Regarding total sugar intake, fruits and milk and milk products were the key food sources over time. However, discretionary foods, such as cakes/cookies and sweet snacks, gained importance at ages 3·5 and 5 years. Food groups that contributed most to starch intake were breads/cereals, cakes/cookies and pasta. Weak to moderate tracking of total carbohydrate, total sugar and starch was observed across the first 5 years of life.

Our study is the first to use longitudinal data to report total carbohydrate, total sugar and starch intakes from ages 9 months to 5 years. The total carbohydrate intake (100–170 g/d) observed in our cohort is similar to those (111–192 g/d) reported in a cross-sectional study of USA children from age 1 to 5 years(Reference Bailey, Catellier and Jun30). Similarly, findings from a longitudinal cohort conducted in European countries (Belgium, Germany, Italy, Poland and Spain) demonstrated an increase in total carbohydrate intake with age, from 150 g/d at 3 years to 192 g/d at 8 years(Reference Jaeger, Koletzko and Luque31). In the current study, the proportion of total energy intake from dietary carbohydrates ranged from 48·4 to 50·5 %. Previous studies conducted in Germany(Reference Foterek, Hilbig and Kersting32) and other European countries (Belgium, Italy, Poland and Spain)(Reference Jaeger, Koletzko and Luque31) showed that the percentage contribution of total carbohydrates to energy ranged from 51·0 to 53·2 % among young children. It is crucial to note that this European study(Reference Jaeger, Koletzko and Luque31) involved older children aged 3–8 years and used weighed food records to collect dietary intakes. Therefore, our findings are not directly comparable with these studies due to differences in age, dietary assessment methods and country-specific food composition tables.

Consistent with two reviews that examined sugar(Reference Stephen, Alles and de Graaf3,Reference Newens and Walton33) and starch consumption(Reference Stephen, Alles and de Graaf3) in young children across different countries, our study revealed that the percentage of energy from total sugars is high in infancy (29·4 %) but gradually decreased throughout early childhood, reaching 22·6 % at age 5. Meanwhile, the percentage of energy from starch increased from 16·7 % at 9 months to 26·0 % at 5 years. The observed trend can be explained by the high consumption of breast milk in infancy, which was the major contributor to total sugar intake, following fruits and milk/milk products. For example, in our study, at 9 months of age, breast milk ranked as the third largest contributor to total sugar, contributing 18 % of total sugar. Unsurprisingly, by 18 months, the percentage of total sugar from breast milk had declined, contributing 1·6 % to the overall total sugar intake. This change might be attributed to the progressive replacement of breast milk with complementary foods, resulting in children obtaining their energy from a wider variety of sources.

Many national and regional authorities, such as the WHO(Reference Mann, Cummings and Englyst34), the European Food Safety Authority(4) and guidelines from the United Kingdom (UK)(35), the USA, Canada(36) and Australia(1), have established dietary recommendations for carbohydrate intake for children in the form of the recommended proportion of total energy from carbohydrates. However, the specific figures/ ranges differ amongst these authorities, ranging from a lower limit of 40 % energy to 55–75 % energy. Dietary guidelines in the USA(36) also provide Adequate Intake and Recommended Dietary Allowance for children aged 0–12 months and 1–8 years, respectively. Similarly, adequate intake for children aged 0–12 months is provided in Australia(1). However, these values are subject to ambiguity and ongoing debate as they have been determined from the nutrient composition of breast milk obtained from a small sample of USA lactating women and rely on information primarily tailored for adults(1,36) . The review of international recommendations on carbohydrate intakes by Buyken et al. (Reference Buyken, Mela and Dussort37) also showed a wide variation in the methods used to derive these guidelines, including differences in terminology and carbohydrates classifications, as well as variations in the choice and number of selected health outcomes. Similarly, there is inconsistency among quantitative dietary recommendations for sugar intakes across different authorities(Reference Buyken, Mela and Dussort37). This variation and lack of uniformity within the expert community adversely impact the acceptance and implementation of recommendations. Additionally, this poses a challenge in evaluating children’s adherence to dietary carbohydrate intake guidelines.

The current study is one of the few studies to examine key food sources of total carbohydrates, starch and total sugar intake during early childhood. Consistent with findings from Belgium(Reference Huysentruyt, Laire and Van Avondt11) and Spain(Reference Samaniego-Vaesken, Partearroyo and Valero6), main sources of total carbohydrates in young children were breads/cereals, milk and milk products and cakes/cookies. In addition, our study showed that the predominant sources of total sugar intake were fruits, milk and milk products, broadly consistent with previous studies(Reference Samaniego-Vaesken, Partearroyo and Valero6). Naturally occurring sugars from fruits and milk products, which contributed to the highest percentage to the total sugar intake in the present study, are less concerning, as there is no sound evidence of adverse effects from an excessive intake of intrinsic sugars (naturally occurring sugars)(Reference Redruello-Requejo, Samaniego-Vaesken and Partearroyo38,39) . Indeed, a review by European Society for Pediatric Gastroenterology, Hepatology and Nutrition Committee suggested sugars should preferably be consumed in its natural form such as human milk, milk, unsweetened dairy products and fresh fruits(Reference Fidler Mis, Braegger and Bronsky40). In addition, intrinsic sugars are more likely to be present in foods alongside useful nutrients such as fibre, vitamins and minerals(Reference Fidler Mis, Braegger and Bronsky40). In contrast, a study conducted among USA infants and toddlers aged 0–24 months(Reference Grimes, Szymlek-Gay and Campbell9) revealed a higher percentage of total sugar originating from juices, sugar-sweetened beverages and sweet bakery products, higher than the contributions outlined in the present study. Despite these food groups having a lower contribution in our study, their intake increased at later ages (3·5 and 5 years). The increased consumption of sugar from discretionary foods as children age might suggest that children gain more autonomy over their dietary choices, while parents may find it more challenging to promote healthier diet options(Reference Manohar, Hayen and Do41).

Breads/cereals contributed to the majority of starch intakes at ages 9 and 18 months and 3·5 and 5 years in our study (45–53 %). High starch contributions from cereals also have previously been observed in Spanish children(Reference Samaniego-Vaesken, Partearroyo and Valero6). The role of starch from breads/cereals in health varies by the specific types of breads/cereals consumed. Wholegrain breads/cereals contain more fibre, vitamins, minerals and antioxidants than refined cereal foods such as white bread because many of the nutrients occur in the outer layer of the grain, which is lost during processing in refined cereals(42,Reference Klerks, Bernal and Roman43) . Data from the national nutrition survey revealed that the a majority of Australians consume less than half of the recommended amount of wholegrain foods and consume an excessive quantity of refined cereal products(44). Similarly in our study, white breads were more frequently consumed than wholegrains. There is a need to raise awareness among parents about increasing their children’s consumption of wholegrain breads/cereals, which offer better health benefits. Notably, in our study, the second primary source of starch intake, excluding the 9-month time point, was cakes/cookies. These foods are typically high in saturated fats and added sugars and have been associated with an increased risk of obesity and chronic diseases and also displace the intake of other healthy core food groups such as vegetables, fruits, wholegrains, dairy and meats(Reference Johnson, Hendrie and Golley45,Reference Johnson, Bell and Zarnowiecki46) . It is, therefore, important to reduce the intake of starch from discretionary foods in young children as evidence has shown that children who consume these foods at a young age are also likely to consume them later, increasing their risk of developing chronic diseases(Reference Manohar, Hayen and Do41,Reference Spence, Campbell and Lioret47) .

While tracking of a range of nutrients from early childhood has been reported previously(Reference Campbell, Abbott and Zheng22,Reference Lioret, Mcnaughton and Spence25) , our study is the first to assess tracking of total carbohydrates and their subtypes (sugars and starch) from as early as age 9 months to age 5 years. Consistent with existing literature on other nutrients(Reference Campbell, Abbott and Zheng22,Reference Lioret, Mcnaughton and Spence25) , we found consistent weak to moderate tracking of total carbohydrate, total sugar and starch intake in early childhood. It is worth highlighting that tracking was observed not only between consecutive time points but also over an extended duration, such as 9 months to 5 years. This may suggest that eating behaviours and taste preferences may develop early, and these in turn may influence dietary intake throughout the life course, underscoring the importance of implementing dietary interventions early in life.

This novel study has several strengths including repeated dietary measurements and assessment of dietary intake through three non-consecutive 24-hour recalls, which yielded high-quality dietary intake data. The generalisability of the study findings may be limited because the study consisted of a high proportion of highly educated mothers (58 %) and first-time mothers. Given added sugar’s potential effect on diet quality and the risk of chronic disease, distinctions between total and added sugars would be informative(Reference Louie and Tapsell48). However, our study did not distinguish between added sugar and total sugar intakes. The primary reason for this was the absence of specific data on added sugars or intrinsic sugars in the food composition tables and databases we utilised (AUSNUT 2007). However, the WHO still supports the importance of assessing ‘total sugar’ since it is the most practical term for describing and measuring sugars, and other terms can pose challenges for analysis and lead to confusion among consumers(Reference Cummings and Stephen8). Recall bias and dietary misreporting are also another possible limitation. However, participants reporting extreme energy intakes were excluded from the current analysis to mitigate the impact of dietary misreporting.

The current study may have the potential to contribute to the refinement of carbohydrate and subtype dietary recommendations in early childhood. This is achieved by offering in-depth insights into early childhood carbohydrate and subtype intake trends. Additionally, identifying the key food sources of carbohydrate and subtype intakes may contribute to dietary monitoring to identify suboptimal sources, providing valuable insights for developing specific dietary guidelines and strategies to improve carbohydrate intake in young children. Our study also suggests that reducing the intake of sugar and starch from discretionary foods and promoting healthier alternatives such as wholegrains in children’s diets is beneficial. However, additional research is required in a nationally representative and diverse population to better understand the changes in carbohydrate intake across early childhood and to identify key food sources. There is also an urgent need to include the assessment of carbohydrate intake in young children, including those aged younger than 2 years, at a national level. A global initiative is necessary to develop more rigorous dietary or nutrient reference values for carbohydrates, sugar and starch. This can be achieved by harmonising the criteria for recommendations and study methodologies related to the intake of various types of carbohydrates, sugars and starch in infants and children as well as collecting similar data across countries. The food regulatory bodies could consider mandating nutritional labelling of food products in Australia to declare the amount and types of specific sugars (added or intrinsic sugars) on packaged foods. Finally, further research will be desirable to distinguish between different types of sugar (added v. intrinsic) and various food sources of sugar (e.g. intact fruit v. purees) to better understand the sugar intake of children under 5 years of age.

Conclusion

The present study uses longitudinal data to provide novel evidence on the intake of total carbohydrates and subtypes (sugar, starch) among Australian children aged 9 months to 5 years. Moreover, it offers insight into the contribution of food sources to carbohydrate intakes. These findings may contribute valuable data to inform the refinement of dietary recommendations for total carbohydrate, sugar and starch intakes in young Australian children and the design of early childhood interventions that aim to optimise children’s carbohydrate intake. Further investigation in a nationally representative population is warranted.

Acknowledgements

We acknowledge the contribution of parents and children who participated in the InFANT program.

The Melbourne InFANT Program was supported by the National Health and Medical Research Council (grant 425801), and the follow-ups were funded by a National Health and Medical Research Council Project Grant (APP1008879). T. S. T. is supported by Deakin University Postgraduate Research Scholarship (DUPR), M. Z. is supported by the Australian Research Council Discovery Early Career Researcher Award Fellowship (DE240100635).

M. Z. and E. A. S.-G. designed the study. T. S. T., M. Z. and E. A. S.-G. performed the statistical analysis. T. S. T. drafted the manuscript. M. Z., E. A. S.-G., K. J. C. and T. S. T. critically reviewed and edited the manuscript, approved the final version and agreed on the submission of the manuscript. K. J. C. led the Infant Feeding Activity and Nutrition Trial Program, including all dietary data collection. All authors have read and agreed to the published version of the manuscript.

The authors declare that they have no conflict of interest.

The study was conducted in accordance with the Declaration of Helsinki and approved by the Deakin University Ethics Committee (ID number: 394 EC 175-2007) and by the Victorian Office for Children (Ref: 80 CDF/07/1138). Informed Consent Statement. Written informed consent was obtained from parents.

Supplementary material

For supplementary material/s referred to in this article, please visit https://doi.org/10.1017/S0007114524002198

References

National Health and Medical Research Council, Australian Government Department of Health and Ageing & New Zealand Ministry of Health (2006) Nutrient Reference Values for Australia and New Zealand. Canberra: National Health and Medical Research Council.Google Scholar
WHO (2023) Carbohydrate Intake for Adults and Children: WHO Guideline. Geneva: World Health Organization. Licence: CC BY-NC-SA 3.0 IGO.Google Scholar
Stephen, A, Alles, M, de Graaf, C, et al. (2012) The role and requirements of digestible dietary carbohydrates in infants and toddlers. Eur J Clin Nutr 66, 765779.CrossRefGoogle ScholarPubMed
EFSA Panel on Dietetic Products, Nutrition, and Allergies (NDA) (2010) Scientific Opinion on Dietary Reference Values for carbohydrates and dietary fibre. EFSA Journal 8, 1462 (p. 77).Google Scholar
Niinikoski, H & Ruottinen, S (2012) Is carbohydrate intake in the first years of life related to future risk of NCDs? Nutr Metab Cardiovasc Dis 22, 770774.CrossRefGoogle ScholarPubMed
Samaniego-Vaesken, ML, Partearroyo, T, Valero, T, et al. (2020) Carbohydrates, starch, total sugar, fiber intakes and food sources in Spanish children aged one to < 10 years-results from the EsNuPI study. Nutrients 12, 3171.CrossRefGoogle ScholarPubMed
Pawellek, I, Grote, V, Theurich, M, et al. (2017) Factors associated with sugar intake and sugar sources in European children from 1 to 8 years of age. Eur J Clin Nutr 71, 2532.CrossRefGoogle ScholarPubMed
Cummings, JH & Stephen, AM (2007) Carbohydrate terminology and classification. Eur J Clin Nutr 61, S518.CrossRefGoogle ScholarPubMed
Grimes, CA, Szymlek-Gay, EA, Campbell, KJ, et al. (2015) Food sources of total energy and nutrients among U.S. infants and toddlers: National Health and Nutrition Examination Survey 2005–2012. Nutrients 7, 67976836.CrossRefGoogle ScholarPubMed
Lim, SX, Toh, JY, van Lee, L, et al. (2018) Food sources of energy and macronutrient intakes among infants from 6 to 12 months of age: the growing up in Singapore towards healthy outcomes (GUSTO) Study. Int J Environ Res Public Health 15, 488.CrossRefGoogle ScholarPubMed
Huysentruyt, K, Laire, D, Van Avondt, T, et al. (2016) Energy and macronutrient intakes and adherence to dietary guidelines of infants and toddlers in Belgium. Eur J Nutr 55, 15951604.CrossRefGoogle ScholarPubMed
Zhou, SJ, Gibson, RA, Gibson, RS, et al. (2012) Nutrient intakes and status of preschool children in Adelaide, South Australia. Med J Aust 196, 696700.CrossRefGoogle ScholarPubMed
Moumin, NA, Netting, MJ, Golley, RK, et al. (2022) Usual nutrient intake distribution and prevalence of inadequacy among Australian children 0–24 months: findings from the Australian Feeding Infants and Toddlers Study (OzFITS) 2021. Nutrients 14, 1381.CrossRefGoogle ScholarPubMed
Devenish, G, Ytterstad, E, Begley, A, et al. (2019) Intake, sources, and determinants of free sugars intake in Australian children aged 12–14 months. Matern Child Nutr 15, e12692.CrossRefGoogle ScholarPubMed
Thorsteinsdottir, F, Campbell, KJ, Heitmann, BL, et al. (2023) Longitudinal trajectories of dietary fibre intake and its determinants in early childhood: results from the Melbourne InFANT Program. Nutrients 15, 1932.CrossRefGoogle ScholarPubMed
Australian Bureau of Statistics (2011) Australian Health Survey: Nutrition First Results – Foods and Nutrients [Internet]. Canberra: ABS; 2011 December. https://www.abs.gov.au/statistics/health/health-conditions-and-risks/australian-health-survey-nutrition-first-results-foods-and-nutrients/latest-release (accessed 13 February 2024).Google Scholar
Schwartz, C, Scholtens, PA, Lalanne, A, et al. (2011) Development of healthy eating habits early in life. Review of recent evidence and selected guidelines. Appetite 57, 796807.CrossRefGoogle ScholarPubMed
Langley-Evans, SC (2015) Nutrition in early life and the programming of adult disease: a review. J Hum Nutr Diet 28, 114.CrossRefGoogle ScholarPubMed
Campbell, K, Hesketh, K, Crawford, D, et al. (2008) The Infant Feeding Activity and Nutrition Trial (INFANT) an early intervention to prevent childhood obesity: cluster-randomised controlled trial. BMC Public Health 8, 103.CrossRefGoogle Scholar
Hesketh, K, Campbell, K, Salmon, J, et al. (2013) The Melbourne Infant Feeding, Activity and Nutrition Trial (InFANT) Program follow-up. Contemp Clin Trials 34, 145151.CrossRefGoogle ScholarPubMed
Campbell, KJ, Lioret, S, McNaughton, SA, et al. (2013) A parent-focused intervention to reduce infant obesity risk behaviors: a randomized trial. Pediatrics 131, 652660.CrossRefGoogle ScholarPubMed
Campbell, KJ, Abbott, G, Zheng, M, et al. (2017) Early life protein intake: food sources, correlates, and tracking across the first 5 years of life. J Acad Nutr Diet 117, 11881197 e1181.CrossRefGoogle ScholarPubMed
Australian Institute of Health and Welfare (2023) Australia’s Mothers and Babies [Internet]. Canberra: Australian Institute of Health and Welfare. https://www.aihw.gov.au/reports/mothers-babies/australias-mothers-babies (accessed 15 June 2024).Google Scholar
Zheng, M, Lioret, S, Hesketh, KD, et al. (2021) Association between longitudinal trajectories of lifestyle pattern and BMI in early childhood. Obesity (Silver Spring) 29, 879887.CrossRefGoogle ScholarPubMed
Lioret, S, Mcnaughton, SA, Spence, AC, et al. (2013) Tracking of dietary intakes in early childhood: the Melbourne InFANT Program. Eur J Clin Nutr 67, 275281.CrossRefGoogle ScholarPubMed
Zheng, M, Yu, HJ, He, QQ, et al. (2021) Protein intake during infancy and subsequent body mass index in early childhood: results from the Melbourne InFANT program. J Acad Nutr Diet 121, 17751784.CrossRefGoogle ScholarPubMed
Food Standards Australia New Zealand (FSANZ) (2007) Australian Food, Supplement & Nutrient Database (AUSNUT 2007). Available online https://www.foodstandards.gov.au/science-data/monitoringnutrients/ausnut/ausnut2007.Google Scholar
Willett, WC (2013) Nutritional Epidemiology. New York, NY: Oxford University Press.Google Scholar
Cohen, J (2013) Statistical Power Analysis for the Behavioral Sciences. New York: Academic Press.CrossRefGoogle Scholar
Bailey, RL, Catellier, DJ, Jun, S, et al. (2018) Total Usual Nutrient Intakes of US Children (under 48 months): findings from the Feeding Infants and Toddlers Study (FITS) 2016. J Nutr 148, 1557S1566S.CrossRefGoogle ScholarPubMed
Jaeger, V, Koletzko, B, Luque, V, et al. (2022) Distribution of energy and macronutrient intakes across eating occasions in European children from 3 to 8 years of age: The EU Childhood Obesity Project Study. Eur J Nutr 62, 165174.CrossRefGoogle ScholarPubMed
Foterek, K, Hilbig, A, Kersting, M, et al. (2016) Age and time trends in the diet of young children: results of the DONALD study. Eur J Nutr 55, 611620.CrossRefGoogle ScholarPubMed
Newens, KJ & Walton, J (2016) A review of sugar consumption from nationally representative dietary surveys across the world. J Hum Nutr Diet 29, 225240.CrossRefGoogle Scholar
Mann, J, Cummings, JH, Englyst, HN, et al. (2007) FAO/WHO scientific update on carbohydrates in human nutrition: conclusions. Eur J Clin Nutr 61, S132S137.CrossRefGoogle Scholar
Scientific Advisory Committee on Health (SACN) (2015) Carbohydrates and Health. London: The Stationery Office.Google Scholar
Institute of Medicine (2005) Dietary Reference Intakes for Energy, Carbohydrate, Fiber, Fat, Fatty Acids, Cholesterol, Protein, and Amino Acids. Washington, DC: The National Academies Press.Google Scholar
Buyken, AE, Mela, DJ, Dussort, P, et al. (2018) Dietary carbohydrates: a review of international recommendations and the methods used to derive them. Eur J Clin Nutr 72, 16251643.CrossRefGoogle Scholar
Redruello-Requejo, M, Samaniego-Vaesken, ML, Partearroyo, T, et al. (2022) Dietary intake of individual (intrinsic and added) sugars and food sources from Spanish children aged one to < 10 years-results from the EsNuPI study. Nutrients 14, 1667.CrossRefGoogle ScholarPubMed
WHO (2015) Guideline: Sugars Intake for Adults and Children. Geneva: World Health Organization.Google Scholar
Fidler Mis, N, Braegger, C, Bronsky, J, et al. (2017) Sugar in infants, children and adolescents: a position paper of the European society for paediatric gastroenterology, hepatology and nutrition committee on nutrition. J Pediatr Gastroenterol Nutr 65, 681696.CrossRefGoogle ScholarPubMed
Manohar, N, Hayen, A, Do, L, et al. (2021) Early life and socio-economic determinants of dietary trajectories in infancy and early childhood – results from the HSHK birth cohort study. Nutr J 20, 76.CrossRefGoogle ScholarPubMed
National Health and Medical Research Council (2013) Australian Dietary Guidelines. Canberra: National Health and Medical Research Council.Google Scholar
Klerks, M, Bernal, MJ, Roman, S, et al. (2019) Infant cereals: current status, challenges, and future opportunities for whole grains. Nutrients 11, 473.CrossRefGoogle Scholar
National Health and Medical Research Council (Australia) (2013) Eat for Health: Australian Dietary Guidelines: Summary. Canberra, Australia: National Health and Medical Research Council.Google Scholar
Johnson, BJ, Hendrie, GA & Golley, RK (2016) Reducing discretionary food and beverage intake in early childhood: a systematic review within an ecological framework. Public Health Nutr 19, 16841695.CrossRefGoogle ScholarPubMed
Johnson, BJ, Bell, LK, Zarnowiecki, D, et al. (2017) Contribution of discretionary foods and drinks to Australian children’s intake of energy, saturated fat, added sugars and salt. Children (Basel) 4, 104.Google ScholarPubMed
Spence, AC, Campbell, KJ, Lioret, S, et al. (2018) Early childhood vegetable, fruit, and discretionary food intakes do not meet dietary guidelines, but do show socioeconomic differences and tracking over time. J Acad Nutr Diet 118, 16341643 e1631.CrossRefGoogle Scholar
Louie, JC & Tapsell, LC (2015) Association between intake of total v. added sugar on diet quality: a systematic review. Nutr Rev 73, 837857.CrossRefGoogle Scholar
Figure 0

Table 1. Comparison of mean (sd) total carbohydrate, total sugar and starch (g/d) intake at age 9 months by child and maternal characteristics (n 393) at 9 months in the Melbourne infant feeding activity and nutrition trial program(Mean values and standard deviations)

Figure 1

Table 2. Energy, total carbohydrate and starch intake at 9 months, 18 months, 3·5 years and 5 years in Melbourne infant feeding activity and nutrition trial program*(Mean values and standard deviations)

Figure 2

Table 3. Main total carbohydrate food sources at ages 9 months, 18 months, 3·5 years and 5 years in Melbourne infant feeding activity and nutrition trial program(Percentages; mean values and standard deviations)

Figure 3

Fig. 1. Main total sugar food sources at ages 9 months (n 393), 18 months (n 284), 3·5 years (n 244) and 5 years (n 240) in Melbourne Infant Feeding Activity and Nutrition Trial Program.

Figure 4

Fig. 2. Main starch food sources at ages 9 months (n 393), 18 months (n 284), 3·5 years (n 244) and 5 years (n 240) in Melbourne Infant Feeding Activity and Nutrition Trial Program.

Figure 5

Table 4. Tracking of total carbohydrate, sugar and starch at ages 9 months, 18 months, 3·5 years and 5 years in Melbourne infant feeding activity and nutrition trial program

Supplementary material: File

Tesfaye et al. supplementary material

Tesfaye et al. supplementary material
Download Tesfaye et al. supplementary material(File)
File 115.3 KB