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Intake and sources of dietary fibre and dietary fibre fractions in Finnish children

Published online by Cambridge University Press:  21 February 2023

Tuuli E. I. Salo*
Affiliation:
Department of Public Health and Welfare, Finnish Institute for Health and Welfare, FI-00271 Helsinki, Finland Unit of Health Sciences, Faculty of Social Sciences, Tampere University, FI-33014 Tampere, Finland
Sari Niinistö
Affiliation:
Department of Public Health and Welfare, Finnish Institute for Health and Welfare, FI-00271 Helsinki, Finland
Tuuli E. Korhonen
Affiliation:
Department of Public Health and Welfare, Finnish Institute for Health and Welfare, FI-00271 Helsinki, Finland
Helena Pastell
Affiliation:
Finnish Food Authority, Mustialankatu 3, FI-00790 Helsinki, Finland
Heli Reinivuo
Affiliation:
Department of Public Health and Welfare, Finnish Institute for Health and Welfare, FI-00271 Helsinki, Finland
Hanna-Mari Takkinen
Affiliation:
Department of Public Health and Welfare, Finnish Institute for Health and Welfare, FI-00271 Helsinki, Finland Unit of Health Sciences, Faculty of Social Sciences, Tampere University, FI-33014 Tampere, Finland Research, Development and Innovation Center, Tampere University Hospital, P.O. Box 2000, FI-33521 Tampere, Finland
Jorma Ilonen
Affiliation:
Immunogenetics Laboratory, Institute of Biomedicine, University of Turku, FI-20014 Turku, Finland
Jorma Toppari
Affiliation:
Research Centre for Integrative Physiology and Pharmacology, Institute of Biomedicine, University of Turku, FI-20520 Turku, Finland Department of Pediatrics, Turku University Hospital, FI-20520 Turku, Finland
Mikael Knip
Affiliation:
Pediatric Research Center, Children’s Hospital, University of Helsinki and Helsinki University Hospital, FI-00029 Helsinki, Finland Research Program for Clinical and Molecular Metabolism, Faculty of Medicine, University of Helsinki, FI-00014 Helsinki, Finland Department of Pediatrics, Tampere University Hospital, FI-33521 Tampere, Finland
Riitta Veijola
Affiliation:
Department of Pediatrics, PEDEGO Research Unit, Medical Research Center Oulu, University of Oulu and Oulu University Hospital, FI-90014 Oulu, Finland Department of Children and Adolescents, Oulu University Hospital, P.O. Box 10, FI-90029 Oulu, Finland
Suvi M. Virtanen
Affiliation:
Department of Public Health and Welfare, Finnish Institute for Health and Welfare, FI-00271 Helsinki, Finland Unit of Health Sciences, Faculty of Social Sciences, Tampere University, FI-33014 Tampere, Finland Research, Development and Innovation Center, Tampere University Hospital, P.O. Box 2000, FI-33521 Tampere, Finland Center for Child Health Research, Tampere University and Tampere University Hospital, FI-33014 Tampere, Finland
*
*Corresponding author: Tuuli E. I. Salo, email tuuli.salo@thl.fi
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Abstract

The current definition of dietary fibre was adopted by the Codex Alimentarius Commission in 2009, but implementation requires updating food composition databases with values based on appropriate analysis methods. Previous data on population intakes of dietary fibre fractions are sparse. We studied the intake and sources of total dietary fibre (TDF) and dietary fibre fractions insoluble dietary fibre (IDF), dietary fibre soluble in water but insoluble in 76 % aqueous ethanol (SDFP) and dietary fibre soluble in water and soluble in 76 % aqueous ethanol (SDFS) in Finnish children based on new CODEX-compliant values of the Finnish National Food Composition Database Fineli. Our sample included 5193 children at increased genetic risk of type 1 diabetes from the Type 1 Diabetes Prediction and Prevention birth cohort, born between 1996 and 2004. We assessed the intake and sources based on 3-day food records collected at the ages of 6 months, 1, 3 and 6 years. Both absolute and energy-adjusted intakes of TDF were associated with age, sex and breast-feeding status of the child. Children of older parents, parents with a higher level of education, non-smoking mothers and children with no older siblings had higher energy-adjusted TDF intake. IDF was the major dietary fibre fraction in non-breastfed children, followed by SDFP and SDFS. Cereal products, fruits and berries, potatoes and vegetables were major food sources of dietary fibre. Breast milk was a major source of dietary fibre in 6-month-olds due to its human milk oligosaccharide content and resulted in high SDFS intakes in breastfed children.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Nutrition Society

Higher intake of dietary fibre is associated with several health benefits, including but not limited to reduced risk of all-cause mortality, CVD, type 2 diabetes, obesity and colorectal cancer(Reference Kim and Je14). Higher intake of dietary fibre can also be considered a marker of an overall healthy diet, as dietary fibre is most abundant in minimally processed plant-based foods such as whole grains, fruits, vegetables, legumes, nuts and seeds(Reference Dhingra, Michael and Rajput5,Reference Stephen, Champ and Cloran6) . Dietary fibre differs from other nutrients in that it is an umbrella term for a diverse group of different compounds. The individual types of dietary fibre vary in their physicochemical and functional characteristics such as chain length, types of polymer linkages, solubility, viscosity and fermentability, resulting in differing health effects during passage through the gastro-intestinal tract(Reference Stephen, Champ and Cloran6,Reference Tungland and Meyer7) . Indeed, individual dietary fibre types have differing health claims authorised by the European Food Safety Authority, including reduction of the blood glucose rise after a meal, increase in faecal bulk, contribution to normal bowel function, contributions to an acceleration of intestinal transit, maintenance of normal blood cholesterol levels and contribution to weight loss in the context of an energy-restricted diet(8).

The history of studying dietary fibre has been complicated by changing definitions and analysis methods. As a results, certain types of dietary fibre have been either missed due to use of older methods that cannot measure all components or overestimated due to use of several methods that partially measure the same fibres twice(Reference Fuller, Beck and Salman9,Reference Westenbrink, Brunt and van der Kamp10) . The internationally approved CODEX definition for dietary fibre was finally adopted in June 2009 following 16 years of debate(11,Reference Jones12) . The definition includes previously poorly represented types of dietary fibre such as resistant starch, oligosaccharides, polydextrose and resistant maltodextrins(Reference Fuller, Beck and Salman9). The choice of including non-digestible oligosaccharides (NDO), which consist of less than ten monomeric units, has been left up to national decision making, but so far, most countries have opted to include them(Reference Jones13,Reference Dai and Chau14) .

Previously developed analysis methods have not been able to analyse all different dietary fibres according to the new definition. The enzymatic-gravimetric-liquid chromatographic AOAC Official method 2009·01 and its extension 2011·25 have been developed to match the new CODEX definition of dietary fibre(Reference McCleary, De Vries and Rader15,Reference McCleary, DeVries and Rader16) . The Finnish National Food Composition Database Fineli is among the first to be updated with new values since the establishment of the CODEX definition. The new data include total dietary fibre values as well as dietary fibre fractions matching the AOAC 2011·25 method: insoluble dietary fibre (IDF), soluble dietary fibre that precipitates in 76 % aqueous ethanol (SDFP; referred to as high-molecular-weight-soluble dietary fibre in earlier AOAC methods(Reference McCleary17,Reference McCleary, Sloane and Draga18) ) and soluble dietary fibre that remains soluble in 76 % aqueous ethanol (SDFS; referred to as low-molecular-weight dietary fibre or NDO in earlier AOAC methods(Reference McCleary17,Reference McCleary, Sloane and Draga18) ).

There are minimal previous data on population intakes of the different dietary fibre fractions. Furthermore, nutritional epidemiology requires up to date analysis methods and food composition databases to minimise systematic error sources. The purpose of this study is to assess the information gap by providing novel information on the intake and sources of dietary fibre and dietary fibre fractions in Finnish children, as well as observe differences between socio-demographic groups in dietary fibre intake.

Methods

Study population

The participants of the current study were sampled from the Type 1 Diabetes Prediction and Prevention (DIPP) Nutrition Study. The DIPP Nutrition Study was conducted as part of the main DIPP Study, which is a population-based birth cohort of Finnish children with HLA-conferred susceptibility to type 1 diabetes assessed from cord blood samples. All children with either medium or high susceptibility to type 1 diabetes born in Oulu University Hospital between September 1996 and September 2004, or Tampere University Hospital between 1997 and 2004 were invited to take part in the DIPP and DIPP Nutrition Studies. Participants of the DIPP Nutrition Study had information on dietary intake collected with 3-day food records until the age of 6 years in addition to the standard processes of the main DIPP Study. Information on sociodemographic factors was collected after the delivery with a structured questionnaire filled out by the parents.

This study assessed children’s dietary fibre intake at the ages of 6 months, 1, 3 and 6 years. All children in the DIPP Nutrition Study with at least one complete 3-day food record at any of the studied age points were included in the sample. 6-month-olds and 1-year-olds with missing growth information necessary for breast milk intake estimation were excluded at these age points. Children who developed autoimmunity were included.

Assessment of dietary intake

Three-day food records were collected at all the studied age points. The process of collecting the food records has been described in detail earlier(Reference Virtanen, Nevalainen and Kronberg-Kippilä19). Open-ended food records with detailed instructions and pre-set dates of three consecutive days, of which 2 weekdays and 1 weekend day were provided, with separate copies for the caretakers and for day care personnel. Household measures, package sizes and weights when available were used for portion size estimation. All food records were checked upon return by trained research nurses. Dietary data were handled by trained research nutritionists. The food record data were entered into Finessi, an in-house dietary calculation software of the Finnish Institute for Health and Welfare. Finessi utilises data from the Finnish National Food Composition Database Fineli, which is maintained and updated annually by the Finnish Institute for Health and Welfare.

The database Fineli includes both food ingredients, e.g. rolled oats, as well as dishes compiled from ingredients via individual recipes, e.g. oatmeal, which includes the ingredients rolled oats, iodised salt, and 1·5 % fat milk with added vitamin D. The ingredient information for dishes is commonly based on ingredient and nutrition values declared by the manufacturer for commercial foods, and information from commonly used cookery books in Finland for non-commercial foods. Nutrient values for dishes are further based on the comprehensive nutrient values of the individual ingredients. The database also takes into account the physicochemical effects the cooking process has on the nutritional values of the dishes. There are roughly 2000 ingredients and over 3000 compiled dishes in Fineli, depending on the version. Different versions of the database are used simultaneously for cohort data such as this study, since processing methods, ingredients of commercial foods, food fortification levels and products available on the market are time dependent, and the dietary data are collected over several years. Each food record was processed with a version of the database matching the time of collection.

Because of the structure of the database, and the fact that the dietary calculation software Finessi in linked with Fineli, all dietary data inserted into Finessi can be broken down into food ingredients. Furthermore, all food ingredients belong to an ingredient class, for example spinach and lettuce into the ingredient class ‘leaf vegetables’. Breaking all foods down into ingredients and summarising them according to ingredient classes (for example, combining all ingredients from ingredient classes ‘leaf vegetables’, ‘root vegetables’ and ‘fruit vegetables’ as well as other desired vegetable classes into the food source classification ‘vegetables’) enables carrying out source analysis, in which the intake of a nutrient deriving from different food sources is assessed.

In our study, we assessed the food sources of total dietary fibre as well as dietary fibre fractions according to the following food source classifications:

  1. 1. Wheat

  2. 2. Rye

  3. 3. Oat

  4. 4. Other cereal products (barley, rice and other cereals)

  5. 5. Fruits and berries (includes juices)

  6. 6. Vegetables (includes mushrooms)

  7. 7. Potatoes

  8. 8. Legumes, nuts and seeds

  9. 9. Formula

  10. 10. Others (all ingredients not included above: meats, dairy products, fats, condiments, sweets, etc. May include some fibre sources, e.g. chocolate, ketchup.)

In this study, breast-feeding status was determined in 6-month-olds and 1-year-olds based on whether they had received any breast milk on the recorded 3 days. Caretakers primarily recorded the frequency of breast-feeding, not the amount of breast milk consumed. The amount of breast milk was calculated retrospectively using estimated energy requirements based on child weight and the growth of the child, and the energy intake from other foods based on the food records(Reference Schoen, Sichert-Hellert and Kersting20). Energy and dietary fibre from breast milk were included in energy and dietary fibre intake for 6-month-olds and 1-year-olds. After the age of 1 year breast milk intake was not considered due to very infrequent and little use by older children. We did not include dietary fibre supplements.

Compiling of dietary fibre values

The Finnish Food Authority and the Finnish Institute for Health and Welfare were responsible for the process of updating dietary fibre values of Fineli. As mentioned previously, Fineli consists of both food ingredients and dishes. Since dishes are compiled from food ingredients, it was only necessary to produce updated dietary fibre values for food ingredients. Updating the values for food ingredients would allow recalculation of the values for dishes as well.

The Finnish Food Authority conducted novel dietary fibre analyses for 110 food ingredients with the AOAC 2011·25 method, which can separately analyse IDF, SDFP, and SDFS (TDF = IDF + SDFP + SDFS)(Reference Rainakari, Rita and Putkonen21,Reference Pastell, Putkonen and Rita22) . Values for additional ninety-six food ingredients were extracted from previous literature. Of these literature-based values, eighteen were based on AOAC 2009·01 (which separates HMWDF (IDF combined with SDFP), and SDFS) or AOAC 2011·twenty-five analyses, thirty-seven on AOAC 991·forty-three analyses (HMWDF, underestimates resistant starch, inulin and resistant maltodextrins) and forty one on other methods. After the analyses and literature review, values for 134 food ingredients were imputed from related foods. Values for additional thirty-nine food ingredients were derived from previous analyses carried out by the Finnish Food Authority. Finally, values for 1839 food ingredients could be calculated based on all the above and the recipes of the individual food ingredients. Not only dishes include recipes in Fineli, but food ingredients too, e.g. apple jam, which is at the same time a food ingredient, and has a recipe consisting of sugar, ‘water, tap water’ and ‘apple, average, with skin’.

Dietary fibre content of breast milk was based on previous literature on human milk oligosaccharides (HMO)(Reference Andreas, Kampmann and Mehring Le-Doare23). Although HMO secretion into breast milk varies between individuals as well as over the period of lactation, we estimated 100 grams of breast milk to contain 1·3 grams of HMO, which is a value previously reported for mature milk (120+ days of lactation)(Reference Andreas, Kampmann and Mehring Le-Doare23). Dietary fibre in breast milk was inserted into Fineli as SDFS since HMO are NDO.

Statistical methods

Dietary fibre intake was analysed both in grams per day as well as energy-adjusted for grams per megajoule. Medians and interquartile ranges were calculated to describe the intake of dietary fibre in different subgroups of the sample. Pearson’s chi-square test was used to test for differences in the frequencies of background variables between the age groups in order to assess differences in drop-out rate.

Age differences in absolute and energy-adjusted intake of total dietary fibre as well as dietary fibre fractions were tested separately for girls and boys. Sex differences in dietary fibre intake were tested separately according to age group and possible breastfeeding status subgroup within the age group. Differences in dietary fibre intake associated with breast-feeding status were tested separately according to age group and sex.

Age differences were assessed using univariate analysis of variance. Tukey’s honest significance difference post hoc test was used to determine which age groups differed in the age group tests. Sex and breastfeeding status differences were assessed with independent samples t test and the non-parametric Mann–Whitney U-Test as appropriate for data distribution. Data was normally distributed for all dietary fibre fractions in 3-year-olds and 6-year-olds but skewed for all fractions in 6-month-olds and SDFS in 1-year-olds.

Differences in energy-adjusted intake of total dietary fibre according to socio-demographic factors in 1-, 3-, and 6-year-olds were assessed using independent samples t test for binary variables, and univariate analysis of variance for non-binary variables. Breastfed 1-year-olds were excluded from the analysis to reduce within-group variance. Food sources of total dietary fibre and dietary fibre fractions were determined by source analysis, utilising the ingredient level dietary data as described previously. Statistical significance was predetermined as P-values ≤ 0·05. Multiple testing was controlled for using the false discovery rate (FDR) method(Reference Benjamini and Hochber24). Statistical analyses were carried out in IBM SPSS Statistics 27.

Ethical considerations

Informed consent is required for the genetic screening of the DIPP study. Parents of the DIPP study children have had high participation incentive. The ethics committees of all the universities and university hospitals participating in the DIPP study have approved the study.

The current study was observational and utilised already existing data from the DIPP Nutrition Study. Carrying out the study did not cause additional participation burden for the study participants but instead allowed the high-quality data that was produced with the combined effort of the participants and research staff to be analysed as exhaustively as possible.

Results

A total of 5193 children were included in the sample. The sub-sample sizes at each age point as well as other characteristics of the sample are presented in Table 1. Children born in the Oulu University Hospital region (P < 0·001), children of younger mothers (P = 0·003), children of less highly educated mothers (P = 0·048), and children of mothers who smoked during the pregnancy (P = 0·018) had higher drop-out rates. After correction for multiple testing with the FDR method however, only the region and mother’s age remained significant factors for drop-out rates (Table 1). At the age of 6 months, 58·5 % of the children were breastfed, while at the age of 1 year, only 18·4 % of the children were breastfed.

Table 1. Characteristics of the 5193 study participants

* Pearson’s χ 2 test.

Statistically significant on ≤ 0·05 level after correction for multiple testing with false discovery rate method.

Average intake of dietary fibre and dietary fibre fractions

Medians and interquartile ranges for absolute and energy-adjusted intake of total dietary as well as dietary fibre fractions are presented in Table 2.

Table 2. Absolute and energy-adjusted intakes of total dietary fibre (TDF), insoluble dietary fibre (IDF), dietary fibre soluble in water but insoluble in 76 % aqueous ethanol (SDFP) and dietary fibre soluble in water and soluble in 76 % aqueous ethanol (SDFS) in boys and girls by age and breast-feeding status

Differences in total dietary fibre intake according to age, sex, and breastfeeding status

Absolute intake of dietary fibre increased with age in both boys and girls (boys P < 0·001; girls P < 0·001), while energy-adjusted intake of total dietary fibre decreased with age (boys P < 0·001; girls P < 0·001). The post-hoc tests indicated that differences in energy-adjusted intake of total dietary fibre were not significant between 3- and 6-year-olds (boys 2·39 v. 2·30, P = 0·063, girls 2·37 g/MJ v. 2·34, P = 0·920). If breastfed and non-breastfed girls and boys were assessed separately, the peak in energy-adjusted dietary fibre intake occurred later, at the age of 1 year in non-breastfed children, as their intakes at the age of 6 months were considerably lower than those of breastfed counterparts.

Boys had higher intake of absolute total dietary fibre than girls at all age points within matched breast-feeding status subgroup (P < 0·001 for all subgroups). For energy-adjusted values, higher intake in boys was observed in non-breast-fed 1-year-olds (boys 2·82 g/MJ v. girls 2·73 g/MJ, P = 0·001), but there were no sex differences in breastfed 6-month-olds (P = 0·842), non-breastfed 6-month-olds (P = 0·428), breastfed 1-year-olds (P = 0·311), 3-year-olds (P = 0·245) or 6-year-olds (P = 0·151).

Breastfeeding status was associated with absolute intake of dietary fibre at the age of 6 months and 1 year. Breastfed boys and girls had higher absolute intakes at both age points than their non-breastfed counterparts, mostly due to considerably higher SDFS intake from breast milk (P < 0·001 in both sexes at both age points). This also translated into considerably higher energy-adjusted total dietary fibre intakes in both breastfed boys and girls at the ages of 6 months and 1 year (P < 0·001 in both sexes at both age points). Age, sex, and breastfeeding status differences in dietary fibre intake were unaffected by correction for multiple testing with the FDR method.

Proportions of dietary fibre fractions

The proportions of the different dietary fibre fractions in relation to total dietary fibre are presented in Table 3. Proportions were similar for non-breastfed 1-year-olds, 3-year-olds, and 6-year-olds with IDF as the major fraction, followed by SDFP and SDFS. For breastfed children however, the proportion of SDFS was distinctly higher, accounting for over 65 % of dietary fibre in 6-month-old boys and girls, and over 26 % in 1-year-olds.

Table 3. Percentages of dietary fibre fractions out of total dietary fibre: insoluble dietary fibre (IDF), dietary fibre soluble in water but insoluble in 76 % aqueous ethanol (SDFP) and dietary fibre soluble in water and soluble in 76 % aqueous ethanol (SDFS) of total dietary fibre in boys and girls by age and breast-feeding status

Socio-demographic differences

Differences in energy-adjusted total dietary fibre intake by socio-demographic factors are presented in Table 4. Significant differences in intake were observed for all socio-demographic factors. However, the differences were not always significant at all age points. Generally, children of older, more highly educated parents, those with no older siblings and those with non-smoking mothers had higher energy-adjusted intake of total dietary fibre. Socio-demographic differences in dietary fibre intake were unaffected by correction for multiple testing with the FDR method. Intakes of energy-adjusted dietary fibre fractions were highly correlated with TDF as well as each other, and socio-demographic differences in fraction intakes reflected those of TDF (data not shown).

Table 4. Differences in energy-adjusted intake of total dietary fibre (g/MJ) by age group and socio-demographic factors. Breastfed 1-year-olds excluded from analyses

* Independent samples t test.

Univariate analysis of variance.

Food sources of total dietary fibre and dietary fibre fractions

The food sources of total dietary fibre and dietary fibre fractions are presented in Fig. 1. The order of importance of different food sources resembled each other in 1-, 3-, and 6-year-olds, while often distinctly different in 6-month-olds. For 1-, 3-, and 6-year-olds, cereal products were the main source of total dietary fibre as well as all dietary fibre fractions, except SDFS in 1-year-olds. For total dietary fibre, cereal products were followed by fruits and berries, potatoes, and vegetables in these age groups. For IDF, fruits and berries were second, vegetables third, and potatoes the fourth most important sources. For SDFP, cereal products were followed by potatoes, and fruits and berries and vegetables played more minor roles. For SDFS, the primary source of 1-year-olds was breast milk, whereas for 3- and 6-year-olds vegetables followed cereal products, and the role of fruits and berries was less pronounced.

Fig. 1. Food sources of (a) total dietary fibre, (b) insoluble dietary fibre, (c) dietary fibre soluble in water but insoluble in 76 % aqueous ethanol and (d) dietary fibre soluble in water and soluble in 76 % aqueous ethanol (SDFS). Percentages under 2 not shown. 6 months n 4886, 1 year n 4416, 3 years n 3463, 6 years n 2349.

At 6 months, breast milk was the main source of total dietary fibre, and SDFS almost exclusively came from breast milk. As SDFS is the only fibre fraction present in breast milk (due to HMO) it did not contribute to IDF or SDFP. Instead, fruits and berries were the most important source of IDF, and potatoes were the primary source of SDFP.

Further examination of the cereal product sources of dietary fibre revealed a shift in the role of the different grains with the age of the children: oat was a more important source of dietary fibre for the younger children, while the proportions of wheat and rye increased with age. Rye was a distinct source of SDFS, in contrast to its less prominent role as a source of the other dietary fibre fractions.

Discussion

The present study describes intake and sources of total dietary fibre and dietary fibre fractions in children aged 6 months, 1 year, 3 years, and 6 years. Absolute intake of dietary fibre increased with age, but energy adjusted intake decreased with age. Breastfeeding was a major determinant of dietary fibre intake, contributing to higher total dietary fibre intake and a higher proportion of dietary fibre coming from the SDFS fraction. This was especially clear in 6-month-olds, where breast milk derived SDFS accounted for almost half of total dietary fibre intake. In older and non-breastfed children, insoluble dietary fibre was the major dietary fibre fraction, followed by the soluble dietary fibre fractions SDFP and SDFS. Important food sources of dietary fibre included cereal products, fruits and berries, potatoes, and vegetables, while the role of legumes, nuts, and seeds was relatively minor. We also studied socio-demographic differences in energy-adjusted intake of total dietary fibre in non-breastfed 1-year-olds, 3-year-olds, and 6-year-olds. Energy-adjusted intake of total dietary fibre was higher in children with older, more highly educated parents, and lower in those with smoking mothers.

Strengths of our study include utilising a representative, large sample with balanced drop-out, and follow-up through formative years of a child’s diet. Although prospective, self-reported dietary assessment methods may cause conscious or unconscious changes in food behaviour, our dietary data has been found to be of high quality in previous validation studies(Reference Uusitalo, Nevalainen and Salminen25,Reference Prasad, Takkinen and Uusitalo26) . Our study is among the first conducted using new, CODEX-compliant values for dietary fibre, and provides novel information on intake and sources of both total dietary fibre as well as dietary fibre fractions. To our knowledge, this is the first study assessing the role of HMO to dietary fibre intake in relation to the child’s total diet.

Regarding the weaknesses of the study, we must consider that dietary fibre fractions are merely an analytical classification and do not necessarily represent the diverse nature of dietary fibre accurately in terms of physiological effects. Furthermore, not all our updated database values were based on directly AOAC 2011·25 analysed values. This would, however, be unfeasible considering the number of entries in the database, as well as the fact that new, more refined dietary fibre analytical methods are still being developed(Reference McCleary, Ames and Cox27,Reference McCleary28) . In the future, the methods AOAC 2009·01 and 2011·25 will be replaced by the method AOAC 2017·16, as it is still a further improved version of the previous one. Due to the changes, the latest method better mimics physiological conditions and improves the analysis of resistant starch and some NDO. The scale of effects on dietary fibre results are however likely to be much smaller than the effect of the transition from older methods to the CODEX-compliant methods.

The levels of total dietary fibre intake of Finnish children are in line with previous results of children in selected countries(Reference Stephen, Champ and Cloran6). We did find very high energy-adjusted levels of dietary fibre intake in breastfed children, but there is no previous data on dietary fibre intake in breastfed children that would have included HMO. Based on previous literature updated dietary fibre analysis methods also produce higher dietary fibre values(Reference Rainakari, Rita and Putkonen21,Reference Pastell, Putkonen and Rita22,Reference Chen, McGee and Vandemark29,Reference Tobaruela, Santos and de Almeida-Muradian30) . Due to the introduction of a new definition and analytical methods, it may be necessary to re-evaluate dietary fibre intake recommendations, as updates may result in higher intakes than previously produced.

Dietary fibre density of the diet decreasing as the child adapts a diet more similar to the rest of the family has also been reported in German children(Reference Alexy, Kersting and Sichert-Hellert31). It is possible that parents are more mindful of the healthiness of their child’s diet when preparing food separately and adopting a diet more similar to the rest of the family lead to a decrease in nutrient and dietary fibre density. Also consistent with our findings, USA children within the lowest quartile of dietary fibre intake had less educated caregivers with less purchasing power compared with children in the highest quartile(Reference Finn, Jacquier and Kineman32). Other nutrients were not considered in our study but based on the sources of dietary fibre in our study children, a higher intake of dietary fibre could in general reflect a more nutrient-dense diet.

In source analyses, we did not find specific dietary fibre fractions to come from specific food groups. This would imply that source classifications such as cereal fibre or fruit fibre do not represent an analytically distinguishable dietary fibre type. Dietary fibre fraction analysis could provide an alternative classification method for studying health effects of different types of dietary fibre with reduced confounding effects by the food matrix.

Breast milk provides an infant with human milk oligosaccharides, which are vital for intestinal colonisation by gut microbiota, maturation of the immune system and in providing protection from infection(Reference Plaza-Díaz, Fontana and Gil33,Reference Singh, Niharika and Kondepudi34) . Mechanisms include providing structurally diverse energy sources for the microbiota, inhibition of microbial adhesion, cell signalling, short-chain fatty acid production and anti-inflammatory properties(Reference Plaza-Díaz, Fontana and Gil33,Reference Singh, Niharika and Kondepudi34) . Fructo- and galacto-oligosaccharides can be added to infant formulas to mimic the prebiotic content of breast milk, but based on our results, formulas can in no way replace breast milk as a source of NDO. More research is needed on HMO and the age and order of introduction to solid foods in relation to long-term child health.

Dysbiosis of the gut microbiota has been associated with the development of autoimmune diseases such as type 1 diabetes, and it is possible that appropriate prebiotic dietary fibre intake may ameliorate these processes(Reference Mishra, Wang and Nagpal35). However, what exactly is appropriate remains unclear, as higher intake of total dietary fibre has also been associated with increased risk of type 1 diabetes(Reference Hakola, Miettinen and Syrjälä36). This could, however, be due to contaminants in the fibre matrix rather than dietary fibre itself, as harmful associations of, e.g. trypsin inhibitors, mycotoxins, heavy metals, or pesticides, all common contaminants in the cereal fibre matrix, have been speculated(Reference Hakola, Miettinen and Syrjälä36).

Cereal products, the main source of dietary fibre in our study children aged 1, 3 and 6 years, are also sources of harmful mycotoxins, inorganic arsenic, cadmium and lead(Reference Hietaniemi, Rämö and Yli-Mattila37,Reference Suomi, Tuominen and Niinistö38) . While exposure to these substances does not seem to be an issue in adults, recent data indicate that safety levels may be exceeded in children. As much as 88 % of Finnish 3-year-olds and 64 % of Finnish 6-year-olds exceed the tolerable weekly intake of cadmium(Reference Suomi, Tuominen and Niinistö38). Diversifying dietary fibre sources in children could therefore be called for. Based on our results, there would be room for increasing the role of legumes, nuts and seeds in the diet of Finnish children.

Current recommendations for dietary fibre intake in children are inconsistent(39Reference Williams, Bollella and Wynder45) as well as loosely evidence based. Recommendations for dietary fibre intake in children are often based on extrapolation from adults, but children are not ‘little adults’ and dietary fibre may serve a multitude of health benefits in children beyond laxation(Reference Edwards, Xie and Garcia46). More research is needed to assess health effects of dietary fibre and dietary fibre fractions in children, especially young children with developing gut microbiota and immunity. The role of the different dietary fibre fractions on the development of gut microbiota, gut immunity and childhood-onset autoimmune diseases should be explored. New recommendations for intake of dietary fibre for children should consider the multifactorial nature of dietary fibre for children’s health.

The Finnish nutrition recommendations for infants from 2004(Reference Hasunen, Kalavainen and Keinonen47), around the time of the collection of our data, recommended exclusive breast-feeding until the age of 6 months. Introduction of solid foods was recommended to be started with spoon-fed purees made from potatoes, vegetables, fruits and berries. Cereal products, in the form of spoon-fed porridge, were to be added only after these introductory foods. The recommendations were reflected in our results: due to their later introduction, cereal products were a distinctly less important source of dietary fibre in children aged 6 months than at later age points. Also, a shift from oat as a more important source of dietary fibre in younger children to rye and wheat gaining importance in older children could be seen, as porridge is typically made from oat, but bread more commonly from wheat and rye in Finland. These food cultural phenomena could imply that our results can only be generalised to populations with similar food cultures as well as breast-feeding and early feeding recommendation.

The generalisability of our results may be restricted if other food composition databases are not updated with appropriate AOAC-method-based values as well. With the establishment of a CODEX definition for dietary fibre, homogenous analysis methods should allow different countries to utilise analysis results across borders. European food composition databases alone contain over 39 000 food entries, creating strong incentive for sharing the financial burden of database updating. Usage of outdated definitions and analytical methods not only hampers the exchange of database entries but also the comparability of study results. Mismatched dietary fibre definitions are an additional confounder that should be considered when studying dietary fibre, as the definition and analytical methods used can affect results related to the dietary fibre content and composition of foods. In young children, special consideration should be given to the inclusion of NDO and especially HMO in the definition of dietary fibre.

Conclusions

Our study based on updated CODEX-compliant food database values for dietary fibre and dietary fibre fractions found that the intake of dietary fibre fractions as well as the contribution of different food sources to dietary fibre intake shift through the first 6 years of life. Including oligosaccharides in the definition of dietary fibre values results in high intakes of total dietary fibre and SDFS in breastfed children, as breast milk is a major source of non-digestible oligosaccharides. In non-breastfed children, IDF is the major dietary fibre fraction followed by SDFP and SDFS, with cereal products, fruits and berries, potatoes and vegetables acting as the major food sources of dietary fibre.

Acknowledgements

This work was supported by the Academy of Finland (S.M.V., grants 63672, 79685, 79686, 80846, 201988, 210632, 129492, 126813, 276475 and 339922); the Yrjö Jahnsson Foundation (S.M.V.); the Juho Vainio Foundation (S.M.V.); the Competitive Research Funding of the Tampere University Hospital (S.M.V., grants 9E082, 9F089, 9G087, 9H092, 9J147, 9K149, 9L035, 9L117, 9M029, 9M114, 9N086, 9P017, 9P057, 9R012, 9R055, 9S015, 9S074, 9T072, 9U016, 9U065, 9V012, 9V072, 9X062 and 9AA020); Medical Research Funds of Turku (J.I., J.T.) and Oulu (R.V.) University Hospitals; the European Foundation for the Study of Diabetes (supported by EFSD/JDRF/Lilly) (S.M.V.); the Juvenile Diabetes Research Foundation (J.T., M.K., R.V., grants 197032, 4-1998-274, 4-1999-731, 4-2001-435, 1-SRA-2016-342-M-R, 1-41 SRA-2019-732-M-B); the Novo Nordisk Foundation and EU Biomed 2 (J.T., M.K., R.V., BMH4-CT98-3314); Sigrid Juselius Foundation (J.I., J.T., M.K., R.V.) and Doctoral Programs for Public Health (S.M.V.). The funders had no role in the design, analysis or writing of this article. The authors declare that there are no conflicts of interest.

T. E. I. S., S. N., T. E. K., H. P., H. R. and S. M. V. were responsible for formulating the current study design and study questions and participated in the data interpretation. T. E. I. S. carried out the data analyses and wrote the first manuscript. T. E. K, H. P. and H. R. designed and carried out the updating of the National Food Composition Database Fineli with new dietary fibre values. H.-M. T. handled the food consumption data processing and carried out the source analyses. J. I., J. T., R. V. and M. K. were responsible for the DIPP Study, and S. M. V. for the Nutrition Study within DIPP. All the authors reviewed the manuscript.

There are no conflicts of interest.

References

Kim, Y & Je, Y (2014) Dietary fiber intake and total mortality: a meta-analysis of prospective cohort studies. Am J Epidemiol 180, 565573.CrossRefGoogle ScholarPubMed
Yang, Y, Zhao, LG, Wu, QJ, et al. (2015) Association between dietary fiber and lower risk of all-cause mortality: a meta-analysis of cohort studies. Am J Epidemiol 181, 8391.CrossRefGoogle ScholarPubMed
Anderson, JW, Baird, P, Davis, RH, et al. (2009) Health benefits of dietary fiber. Nutr Rev 67, 188205.CrossRefGoogle ScholarPubMed
World Cancer Research Fund/American Institute for Cancer Research (2018) Continuous Update Project Expert Report 2018. Wholegrains, Vegetables and Fruit and the Risk of Cancer. https://www.wcrf.org/wp-content/uploads/2020/12/Wholegrains-veg-and-fruit.pdf (accessed June 2022).Google Scholar
Dhingra, D, Michael, M, Rajput, H, et al. (2012) Dietary fibre in foods: a review. J Food Sci Technol 49, 255266.CrossRefGoogle ScholarPubMed
Stephen, AM, Champ, MMJ, Cloran, SJ, et al. (2017) Dietary fibre in Europe: current state of knowledge on definitions, sources, recommendations, intakes and relationships to health. Nutr Res Rev 30, 149190.CrossRefGoogle ScholarPubMed
Tungland, BC & Meyer, D (2002) Nondigestible Oligo-and Polysaccharides (Dietary Fiber): their physiology and role in human health and food. Compr Rev Food Sci Food Saf 1, 90109.CrossRefGoogle ScholarPubMed
European Commission (2012) Commission Regulation (EU) No 432/2012 of 16 May 2012 establishing a list of permitted health claims made on foods, other than those referring to the reduction of disease risk and to children’s development and health. Text with EEA relevance. OJ L 136, 281320.Google Scholar
Fuller, S, Beck, E, Salman, H, et al. (2016) New horizons for the study of dietary fiber and health: a review. Plant Foods Hum Nutr 71, 112.CrossRefGoogle Scholar
Westenbrink, S, Brunt, K & van der Kamp, JW (2013) Dietary fibre: challenges in production and use of food composition data. Food Chem 140, 562567.CrossRefGoogle ScholarPubMed
Codex Alimentarius Commission (2009) ALINORM 09/32/26. Rome, Italy: FAO/WHO. http://www.codexalimentarius.net/web/archives.jsp (accessed June 2022).Google Scholar
Jones, JM (2013) Dietary fiber future directions: integrating new definitions and findings to inform nutrition research and communication. Adv Nutr 4, 815.CrossRefGoogle Scholar
Jones, JM (2014) CODEX-aligned dietary fiber definitions help to bridge the ‘fiber gap’. Nutr J 13, 34.CrossRefGoogle ScholarPubMed
Dai, FJ & Chau, CF (2017) Classification and regulatory perspectives of dietary fiber. J Food Drug Anal 25, 3742.CrossRefGoogle ScholarPubMed
McCleary, BV, De Vries, JW, Rader, JI, et al. (2010) Determination of total dietary fiber (CODEX Definition) by enzymatic-gravimetric method and liquid chromatography: collaborative study. J AOAC Int 93, 221233.CrossRefGoogle ScholarPubMed
McCleary, BV, DeVries, JW, Rader, JI, et al. (2012) Determination of insoluble, soluble, and total dietary fiber (CODEX definition) by enzymatic-gravimetric method and liquid chromatography: collaborative study. J AOAC Int 95, 824844.CrossRefGoogle ScholarPubMed
McCleary, BV (2007) An integrated procedure for the measurement of total dietary fibre (including resistant starch), non-digestible oligosaccharides and available carbohydrates. Anal Bioanal Chem 389, 291306.CrossRefGoogle ScholarPubMed
McCleary, BV, Sloane, N, Draga, A, et al. (2013) Measurement of total dietary fibre using AOAC method 2009.01 (AACC International Approved Method 32–45.01): evaluation and updates. Cereal Chem 90, 396414.CrossRefGoogle Scholar
Virtanen, SM, Nevalainen, J, Kronberg-Kippilä, C, et al. (2012) Food consumption and advanced β cell autoimmunity in young children with HLA-conferred susceptibility to type 1 diabetes: a nested case-control design. Am J Clin Nutr 95, 471478.CrossRefGoogle ScholarPubMed
Schoen, S, Sichert-Hellert, W & Kersting, M (2009) Validation of energy requirement equations for estimation of breast milk consumption in infants. Public Health Nutr 12, 23092316.CrossRefGoogle ScholarPubMed
Rainakari, AI, Rita, H, Putkonen, T, et al. (2016) New dietary fibre content results for cereals in the Nordic countries using AOAC 2011.25 method. J Food Compos Anal 51, 18.CrossRefGoogle Scholar
Pastell, H, Putkonen, T & Rita, H (2019) Dietary fibre in legumes, seeds, vegetables, fruits and mushrooms: comparing traditional and semi-automated filtration techniques. J Food Compos Anal 75, 17.CrossRefGoogle Scholar
Andreas, NJ, Kampmann, B & Mehring Le-Doare, K (2015) Human breast milk: a review on its composition and bioactivity. Early Hum Dev 91, 629635.CrossRefGoogle ScholarPubMed
Benjamini, Y & Hochber, GY (1995) Controlling the false discovery rate: a practical and powerful approach to multiple testing. J R Stat Soc B 57, 289300.CrossRefGoogle Scholar
Uusitalo, L, Nevalainen, J, Salminen, I, et al. (2013) Fatty acids in serum and diet—a canonical correlation analysis among toddlers. Matern Child Nutr 9, 381395.CrossRefGoogle ScholarPubMed
Prasad, M, Takkinen, HM, Uusitalo, L, et al. (2018) Carotenoid intake and serum concentration in young Finnish children and their relation with fruit and vegetable consumption. Nutrients 10, 1533.CrossRefGoogle ScholarPubMed
McCleary, BV, Ames, N, Cox, J, et al. (2019) Total Dietary Fiber (CODEX Definition) in foods and food ingredients by a rapid enzymatic-gravimetric method and liquid chromatography: collaborative study, first action 2017.16. J AOAC Int 102, 196207.CrossRefGoogle Scholar
McCleary, BV (2014) Modification to AOAC official methods 2009.01 and 2011.25 to allow for minor overestimation of low molecular weight soluble dietary fiber in samples containing starch. J AOAC Int 97, 896901.CrossRefGoogle ScholarPubMed
Chen, Y, McGee, R, Vandemark, G, et al. (2016) Dietary fiber analysis of four pulses using AOAC 2011.25: implications for human health. Nutrients 8, 829.CrossRefGoogle ScholarPubMed
Tobaruela, ED, Santos, AD, de Almeida-Muradian, LB, et al. (2018) Application of dietary fiber method AOAC 2011.25 in fruit and comparison with AOAC 991.43 method. Food Chem 238, 8793.CrossRefGoogle ScholarPubMed
Alexy, U, Kersting, M & Sichert-Hellert, W (2006) Evaluation of dietary fibre intake from infancy to adolescence against various references--results of the DONALD Study. Eur J Clin Nutr 60, 909914.CrossRefGoogle ScholarPubMed
Finn, K, Jacquier, E, Kineman, B, et al. (2019) Nutrient intakes and sources of fiber among children with low and high dietary fiber intake: the 2016 feeding infants and toddlers study (FITS), a cross-sectional survey. BMC Pediatr 19, 446.CrossRefGoogle ScholarPubMed
Plaza-Díaz, J, Fontana, L & Gil, A (2018) Human milk oligosaccharides and immune system development. Nutrients 10, 1038.CrossRefGoogle ScholarPubMed
Singh, RP, Niharika, J, Kondepudi, KK, et al. (2022) Recent understanding of human milk oligosaccharides in establishing infant gut microbiome and roles in immune system. Food Res Int Ott Ont 151, 110884.CrossRefGoogle ScholarPubMed
Mishra, S, Wang, S, Nagpal, R, et al. (2019) Probiotics and prebiotics for the amelioration of type 1 diabetes: present and future perspectives. Microorganisms 7, 67.CrossRefGoogle ScholarPubMed
Hakola, L, Miettinen, ME, Syrjälä, E, et al. (2019) Association of cereal, gluten, and dietary fiber intake with islet autoimmunity and type 1 diabetes. JAMA Pediatr 173, 953960.CrossRefGoogle ScholarPubMed
Hietaniemi, V, Rämö, S, Yli-Mattila, T, et al. (2016) Updated survey of Fusarium species and toxins in Finnish cereal grains. Food Addit Contam Part A 33, 831848.CrossRefGoogle ScholarPubMed
Suomi, J, Tuominen, P, Niinistö, S, et al. (2018) Dietary heavy metal exposure of Finnish children of 3 to 6 years. Food Addit Contam Part A 35, 13051315.CrossRefGoogle ScholarPubMed
Nordic Council of Ministers (2014) Nordic Nutrition Recommendations 2012. Integrating Nutrition and Physical Activity, 5th ed. Nord 2014:002. Copenhagen, Denmark: Nordic Council of Ministers.Google Scholar
EFSA Panel on Dietetic Products, Nutrition, and Allergies (2010) Scientific opinion on dietary reference values for carbohydrates and dietary fibre. EFSA J 8, 1462.Google Scholar
Institute of Medicine (2005) Dietary Reference Intakes for Energy, Carbohydrate, Fiber, Fat, Fatty Acids, Cholesterol, Protein, and Amino Acids (Macronutrients). Washington, DC: National Academies Press.Google Scholar
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, Australia: National Health and Medical Research Council.Google Scholar
Health Council of the Netherlands (2006) Guideline for Dietary Fibre Intake. Publication no. 2006/03E. The Hague, Netherlands: Health Council of the Netherlands.Google Scholar
Public Health Authority of the Slovak Republic (2015) Recommended Nutrition Doses for Population of the Slovak Republic (9th revision). https://www.uvzsr.sk/docs/info/hv/Recommended_Nutrition_Doses_for_Population_of_the_Slovak_Republic.pdf (accessed June 2022).Google Scholar
Williams, CL, Bollella, M & Wynder, EL (1995) A new recommendation for dietary fiber in childhood Pediatr 96, 985988.CrossRefGoogle ScholarPubMed
Edwards, CA, Xie, C & Garcia, AL (2015) Dietary fibre and health in children and adolescents. Proc Nutr Soc 74, 292302.CrossRefGoogle ScholarPubMed
Hasunen, K, Kalavainen, M, Keinonen, H, et al. (2004) Lapsi, perhe ja ruoka. Imeväis- ja leikki-ikäisten, odottavien ja imettävien äitien ravitsemussuositus (The Child, Family and Food. Nutrition recommendations for Infants and Young Children as well as Pregnant and Breastfeeding Mothers). Publications of the Ministry of Social Affairs and Health 2004:11. Helsinki, Finland: Ministry of Social Affairs and Health.Google Scholar
Figure 0

Table 1. Characteristics of the 5193 study participants

Figure 1

Table 2. Absolute and energy-adjusted intakes of total dietary fibre (TDF), insoluble dietary fibre (IDF), dietary fibre soluble in water but insoluble in 76 % aqueous ethanol (SDFP) and dietary fibre soluble in water and soluble in 76 % aqueous ethanol (SDFS) in boys and girls by age and breast-feeding status

Figure 2

Table 3. Percentages of dietary fibre fractions out of total dietary fibre: insoluble dietary fibre (IDF), dietary fibre soluble in water but insoluble in 76 % aqueous ethanol (SDFP) and dietary fibre soluble in water and soluble in 76 % aqueous ethanol (SDFS) of total dietary fibre in boys and girls by age and breast-feeding status

Figure 3

Table 4. Differences in energy-adjusted intake of total dietary fibre (g/MJ) by age group and socio-demographic factors. Breastfed 1-year-olds excluded from analyses

Figure 4

Fig. 1. Food sources of (a) total dietary fibre, (b) insoluble dietary fibre, (c) dietary fibre soluble in water but insoluble in 76 % aqueous ethanol and (d) dietary fibre soluble in water and soluble in 76 % aqueous ethanol (SDFS). Percentages under 2 not shown. 6 months n 4886, 1 year n 4416, 3 years n 3463, 6 years n 2349.