Hostname: page-component-78c5997874-dh8gc Total loading time: 0 Render date: 2024-11-19T09:57:50.004Z Has data issue: false hasContentIssue false
  • English
  • Français

Demographic and socio-economic factors related to food intake and adherence to nutritional recommendations in a cohort of pre-school children

Published online by Cambridge University Press:  10 February 2011

Lise Dubois ,
Anna Farmer ,
Manon Girard ,
Daniel Burnier  and
Marion Porcherie
Lise Dubois*
Affiliation:
Department of Epidemiology and Community Medicine, Faculty of Medicine, Institute of Population Health, University of Ottawa, 1 Stewart Street, Office 303, Ottawa, Ontario K1N 6N5, Canada
Anna Farmer
Affiliation:
Department of Agricultural, Food and Nutritional Science and the Centre for Health Promotion Studies, University of Alberta, Edmonton, Alberta, Canada
Manon Girard
Affiliation:
Department of Epidemiology and Community Medicine, Faculty of Medicine, Institute of Population Health, University of Ottawa, 1 Stewart Street, Office 303, Ottawa, Ontario K1N 6N5, Canada
Daniel Burnier
Affiliation:
Department of Epidemiology and Community Medicine, Faculty of Medicine, Institute of Population Health, University of Ottawa, 1 Stewart Street, Office 303, Ottawa, Ontario K1N 6N5, Canada
Marion Porcherie
Affiliation:
Department of Epidemiology and Community Medicine, Faculty of Medicine, Institute of Population Health, University of Ottawa, 1 Stewart Street, Office 303, Ottawa, Ontario K1N 6N5, Canada
*
*Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective

To examine: (i) children's food intake and adherence to both Canada's Food Guide for Healthy Eating and Dietary Reference Intakes; and (ii) the social and demographic factors related to children's food intake.

Design

A cross-sectional study.

Setting

Data were obtained through the Quebec Longitudinal Study of Child Development 1998–2010, a representative sample (n 2103) of children born in 1998 in the province of Quebec, Canada. Information on energy, macronutrient and food consumption was derived from responses to a 24 h dietary recall interview addressed to children's mothers and day-care staff when the children were 4 years old.

Subjects

A total of 1549 children aged 4 years who participated in a nutritional sub-study.

Results

The mean daily total energy intake was 6360 kJ (1520 kcal) for girls and 6916 kJ (1653 kcal) for boys. For boys and girls alike, energy intake was comprised of approximately 54 % carbohydrates, 31 % fats and 15 % proteins. The mean number of servings consumed from each of the four essential food groups closely approached the dietary recommendations made by Canada's Food Guide for Healthy Eating; however, <2 % of the children in the present study actually met the full dietary guidelines. The dietary intake of pre-school children was associated with socio-economic and demographic factors, most notably mother's level of education, mother's immigrant status and sex of the child.

Conclusions

Diet-related disparities associated with socio-economic and demographic factors exist from as early as 4 years of age.

Keywords

Food intakeNutritional recommendationsSocio-economic factors
Type
Research paper
Information
Public Health Nutrition , Volume 14 , Issue 6 , June 2011 , pp. 1096 - 1104
Copyright
Copyright © The Authors 2011

Income is only one among many factors affecting the extent and nature of food purchases(Reference Halbwachs1). Social, cultural and family dynamics all exert an influence on the contents of a given household's shopping basket(Reference Régnier2). Consumer behaviours, tastes and adherence to nutritional recommendations are socially shaped, and are an object of social distinction(Reference Bourdieu3, Reference Régnier and Masullo4). Disparities in food consumption are also observed in childhood(Reference Roos, Johansson and Kasmel5, Reference Taylor, Evers and McKenna6). National nutrition surveys such as the Continuing Survey of Food Intakes by Individuals (CSFII)(Reference Wilkinson-Enns, Mickle and Goldman7) and the National Health and Nutrition Examination Survey (NHANES)(8) have shown that children and adolescents are consuming products high in sugar and fat, and low in nutrient value(Reference Kant and Graubard9, Reference Subar, Krebs-Smith and Cook10). It is also reported that children and adolescents rarely meet nutritional recommendations for intakes of fruit, vegetables and whole-grain products(Reference Troiano, Briefel and Carroll11, Reference Skinner, Carruth and Houck12). In their review of the literature on fruit and vegetable intakes among children and adolescents aged 6–18 years, Rasmussen et al.(Reference Rasmussen, Krolner and Klepp13) reported that gender, age, socio-economic position, preferences, parental intake and home availability/accessibility were the determinants supported by the greatest amount of evidence. Regarding ethnicity, studies showed lower fat intakes in immigrants from South Asian countries in comparison with populations born in the USA(Reference Kim, Yu and Liu14, Reference Xie, Gilliland and Li15). Most studies also support the idea that high parental education is positively associated with a higher intake of healthy foods(Reference Roos, Johansson and Kasmel5, Reference Sausenthaler, Kompauer and Mielck16, Reference Serra-Majem, Ribas and Perez-Rodrigo17). However, it is unclear whether these associations also play a role in influencing the dietary intakes of younger children. Kranz and Siega-Riz(Reference Kranz and Siega-Riz18) reported an inverse relationship between mother's education and the intake of added sugars in pre-school children. When analysing the diet of >10 000 children aged 3 years from the Avon Longitudinal Study of Pregnancy and Childhood (ALSPAC), North and Emmett(Reference North and Emmett19) showed that children's junk food intake was significantly associated with having a younger, less-educated mother and a mother of lower social class. As only a few studies have examined dietary adequacy in pre-school children(Reference Nicklaus and Boggio20), and even fewer have investigated the socio-economic determinants of healthy eating for this age group, the present study contributes to an area that is not well understood. Hence, the aim of the present paper is to examine the social and demographic factors related to children's food intakes and dietary adherence to both Canada's Food Guide to Healthy Eating (1992–2007) and Dietary Reference Intakes (DRI)(21) in use at the time of the present study.

Methods

The analyses were performed using data from the Quebec Longitudinal Study of Child Development (QLSCD) 1998–2010, conducted by Santé Québec, a division of the Institut de la Statistique du Québec (ISQ) in Canada(Reference Dubois, Bédard and Girard22, Reference Dubois and Girard23). The QLSCD was established to examine the role of familial and social factors on children's health, as well as on their cognitive and behavioural development. It followed a representative sample (n 2103) of children born in 1998 in the province of Quebec, Canada. The representative sample was chosen by a random selection of children born throughout the year in each public health geographical area of the province, thus minimizing the effect of seasonality and ensuring geographical representation. Twins and children with major diseases or handicaps at birth were excluded from the study. The children were selected from the master birth register and were first examined at 5 months of age (gestational age adjusted for preterm birth) and subsequently at 1-year intervals.

Of the 2103 infants included in the first cycle of the study, 1944 were still part of the survey in 2002. Of this group, 1549 participated in the nutrition evaluation phase of the study. The age of the children included in the present study varied from 44 to 56 months, with a mean age of 49 (sd 3·12) months. Energy, macronutrient and food consumption levels were derived from a 24 h multiple-pass dietary recall interview administered by trained nutritionists in children's homes(Reference Desrosiers, Dubois and Bédard24). Caregivers were asked to indicate the foods (e.g. type, quantity and recipes) consumed during the 24 h period preceding the interview. For children attending day care (n 390), trained nutritionists went to their home and also queried day-care kitchen staff regarding the child's food intake (e.g. time, meal and quantity) for the same 24 h period. To assess for inter- and intra-child variability in the consumption of energy and macronutrients (carbohydrates, protein and fats), a second 24 h dietary recall was administered to 50 % of the sample. All statistical analyses were conducted using adjusted data with results based on usual food consumption patterns and not solely on a single-day recall. A two-step procedure was used: first, a normalizing transformation; and second, a linear transformation that provides a distribution of intakes without the intra-individual component(Reference Desrosiers, Dubois and Bédard24, Reference Liu, Stamler and Dyer25). The 24 h recalls were administered evenly across all days in the week. Energy and macronutrient consumption levels, along with servings of food for each meal and for each child, were evaluated according to the Canadian Nutrient File (26) and the US Department of Agriculture (USDA) recipe file(27), which calculate usual consumption levels of food in accordance with Canada's Food Guide to Healthy Eating. Dietary data were managed using a validated nutrient analysis software developed by Micro Gesta (version 73·0, Quebec, Canada) specifically for Canadian nutritional studies.

On the basis of the results of a literature review, different factors that may relate to the quality of children's diet were selected to examine their role as potential determinants. Family type (single-parent family or not), household annual income (<$CAN20 000, $CAN20 000–39 999, $CAN40 000–59 999 and ≥$CAN60 000), income level (sufficient, insufficient and very insufficientFootnote *), mother's education (no high-school diploma, high-school diploma, college diploma and university degree), mother's age group (<25, 25–29, 30–34 and ≥35 years) and immigrant status (immigrant or not) were included in the analyses. Other variables such as mother's BMI (from self-reported weight and height), number of overweight/obese parents and sex of the child were also included. Children's level of physical activity and their energy intake were used as control variables. The degree of children's physical activity was measured through one survey question that asked mothers: ‘In your opinion, is your child's level of physical activity less than or more than children of the same age and same sex?’ Mothers were asked to respond with one of the following categories: ‘much higher’, ‘slightly higher’, ‘equal’, ‘slightly less’, ‘much less than’ and ‘do not know’. To examine children's dietary adherence to nutritional recommendations, children's food intakes were compared with both Canada's Food Guide to Healthy Eating (1992–2007) and DRI(21). In correspondence with current American dietary guidelinesFootnote , Canada's Food Guide to Healthy Eating in place at the time of the present study recommended the consumption of 5–10 servings of vegetables and fruit, 5–12 servings of grain products, 2–4 servings of milk and alternatives and 2–3 servings of meat and alternatives per day.

Data were weighted by a factor based on the inverse of the selection probability, the probability of non-response and the post-stratification and attrition rates; this ensured that data were longitudinally representative of the infants born in 1998 in the population(Reference Cox and Cohen28). To correct for response bias, the weights provided by ISQ were used. The rates obtained through the present study are therefore comparable to those of other surveys on the same population that use weighted responses, independent of the distribution of the sample(Reference Desrosiers, Dubois and Bédard24). Preliminary analyses indicated that children participating in the nutrition study (n 1549) were representative of not only infants born in 1998 in the province of Quebec but also of children of the same age (4 years) in the Quebec population. Statistical analyses were based on individuals with no missing values for any of the studied variables. Of the 1549 children, 1522 (98 % of the sample) were part of the analyses. The impact of missing data was analysed by conducting with-and-without analyses. Given that missing data did not impact the results, children with missing data were excluded from the analyses.

Statistical analyses were conducted using the SAS statistical software package version 8·2 (SAS Institute Inc., Cary, NC, USA). Pairwise mean comparisons were verified using a one-way ANOVA and Tukey's adjustment of P values. Food servings, in categories, were compared using the χ 2 test of association. Adjusted OR as well as their CI were estimated using logistic regression. In the multivariate regression analyses (Tables 2 and 3), sociodemographic variables were selected from the univariate analyses (Table 1) on the basis of their level of significance in relation to the outcome variables. Significance level was set at 5 %.

Table 1 Mean energy and macronutrient intakes and the prevalence of children attaining the dietary recommendations for four food groups by different characteristics in 4-year-old children from the province of Quebec (from 24 h dietary recall)

%E, percentage of energy.

1 kcal = 4·184 kJ.

*Statistically significant association between the characteristic and the dependent variable (P value ≤ 0·05).

Results

Table 1 presents the association between different factors and dietary consumption in terms of energy, macronutrient and food group servings with respect to recommendations made by Canada's Food Guide to Healthy Eating for the studied population. Children's mean daily total energy intake was 6644 kJ (1588 kcal)/d. For boys and girls alike, energy intake was comprised of approximately 54 % carbohydrates, 31 % fats and 15 % proteins. Boys (P < 0·0001), children of immigrant mothers (P = 0·005), those living in single-parent families (P = 0·01) and those from families with very insufficient income (P = 0·01) consumed more energy than did other children. In terms of food group servings, children consumed a mean of 3·5 servings of fruit and vegetables, 4 servings of grain products, 2 servings of milk products and 2 servings of meat and alternatives per day (data not presented). Only 17 % of children consumed the recommended ≥5 servings of fruit and vegetables or grain products per day. Half (47·7 %) of the children consumed the recommended 2 servings of milk products per day, whereas 39 % of children consumed the recommended 2 servings of meat and alternatives per day. The consumption of vegetables and fruit was associated with sex of the child (P = 0·03), mother's immigrant status (P = 0·04) and education (P ≤ 0·0001), household annual income (P = 0·0009) and mother's BMI (P = 0·004), whereas the consumption of grain products was associated with sex of the child (P ≤ 0·0001), mother's immigrant status (P ≤ 0·0001), single parenting (P = 0·01) and family income (P = 0·02). The consumption of milk products was associated with family income (P = 0·01) and the consumption of meat and alternatives was associated with sex of the child (P ≤ 0·0001) and single parenting (P = 0·02).

The adjusted means for energy intake and macronutrient consumption are presented in Table 2. Boys consumed more energy than did girls (P < 0·0001), and children of immigrant mothers consumed more energy than did children of non-immigrant mothers (P < 0·0001), independently of children's level of physical activity. The proportion of fat consumed was higher in children from non-immigrant mothers (P = 0·04) and in children from mothers with no high-school diploma (P < 0·0001). The proportion of energy intake derived from protein was higher in children of immigrant mothers (P = 0·01) and in children of more highly educated mothers (P < 0·0001).

Table 2 Adjusted mean energy and macronutrient intakes by different characteristics

%E, percentage of energy.

1 kcal = 4·184 kJ.

*Statistically significant association between the characteristic and the dependent variable (P value ≤ 0·05).

†Adjusted for child's sex, mother's immigrant status, mother's education, single parenting, income level and physical activity level.

‡Adjusted for child's sex, mother's immigrant status, mother's education, single parenting, income level, and physical activity level, and carbohydrates, lipids and proteins as proportion of energy.

The adjusted OR for consuming ≥5 servings of vegetables and fruit per day was 2·2 in children of non-immigrant mothers, in comparison with children of immigrant mothers (P = 0·002), and was as high as 8·5 in children of mothers with a university diploma in comparison with children of mothers with no high-school diploma (P < 0·0001; Table 3). The adjusted OR for consuming ≥5 servings of grain products per day was 5·0 in boys, in comparison with girls (P < 0·0001), and 0·4 in children of non-immigrant mothers, in comparison with children of immigrant mothers (P < 0·0001). The adjusted OR of consuming ≥2 servings of milk products per day was 0·7 in boys in comparison with girls (P = 0·003), and 1·5 in children of mothers with a university diploma, in comparison with children of mothers with no high-school diploma (P = 0·03). The adjusted OR of consuming ≥2 servings of milk products per day in children living in households with insufficient or very insufficient income was 0·6, in comparison with children living in households with sufficient income (P = 0·0009). The adjusted OR for consuming ≥2 servings of meat and alternatives per day was 1·9 for boys, in comparison with girls (P < 0·0001).

Table 3 Adjusted OR for attaining dietary recommendations for food group servings at 4 years of age by different characteristics

Ref., reference category.

*Statistically significant OR and 95% CI (P value ≤ 0·05).

†Adjusted for child's sex, mother's immigrant status, mother's education, single parenting, income level, energy and physical activity level.

Discussion

The present study found that children consumed macronutrients in the proportions recommended by Canadian dietary guidelines, which suggest that 45–65 % of energy intake should be derived from carbohydrates, 25–35 % from fats and 10–30 % from proteins(29). With regard to daily total energy intake, it is difficult to determine whether the levels reported in the present study are well adapted to this population; energy intake is dependent upon children's level of physical activity, and this was documented through parental report and not directly measured(Reference Dubois and Girard23). However, the observed levels of energy intake concur with values observed through the NHANES. Across the years 1999–2000, NHANES reported that children aged 3–5 years consumed a mean daily energy intake of 6786 kJ (1622 kcal)(Reference Briefel and Johnson30). American figures (NHANES) and those reported in the present study are clearly higher than what is advised by the Nordic Nutrition Recommendations for children aged 2–5 years, which stipulate a daily energy intake of 5293 kJ (1265 kcal)(31). Using various dietary methodologies and sample sizes, a summary of European studies reported by Lambert et al.(Reference Lambert, Agostoni and Elmadfa32) allows for other comparisons. For instance, energy intakes for boys aged 4–6 years are reported to range from 5293 kJ (1265 kcal)/d in the UK to 7694 kJ (1839 kcal)/d in Austria. Corresponding intakes for girls vary from 5096 kJ (1218 kcal)/d to 9590 kJ (2292 kcal)/d across these same countries. For 4–6-year-old boys, the proportion of energy intakes derived from carbohydrates is reported to vary from 44 % in Greece to 56·8 % in Russia. As a percentage of total energy, the fat intakes of 4–6-year-old girls are also reported to vary from 35·5 % in the UK to 41 % in Greece, whereas protein intakes vary from 11·7 % in Russia to 13·6 % in the Netherlands. In the American survey (NHANES), 13·2 % of energy intake came from proteins, 55·4 % from carbohydrates and 32·9 % from fats in children under 6 years of age(8). The results of the present study suggest that the contribution of protein to children's energy intakes exceeds levels reported in most European studies reviewed by Lambert et al.(Reference Lambert, Agostoni and Elmadfa32). On the contrary, intakes of fat, as a percentage of energy intake, appear to be lower in Quebec than in most European countries. However, total energy intake and the percentage of energy intake from carbohydrates in the present study are comparable to those of most studies.

The mean number of servings of foods consumed from each of the four essential food groups by children of this cohort closely approached the dietary recommendations made by Canada's Food Guide to Healthy Eating; however, <2 % of children actually met the dietary guidelines of all four food groups simultaneously (data not presented). Unlike the findings observed in the present study, a Spanish study of 1112 children aged 6–7 years found that a majority of children maintained the dietary recommendations made by the USDA(Reference Royo-Bordonada, Gorgojo and Martin-Moreno33). Compared with findings observed in the USA through a study of children included in the CSFII, the mean number of servings of milk products consumed by children in the present study cohort was equal to the number of servings consumed by children in the CSFII, but was lower for servings of grain products and meat and alternatives(Reference Munoz, Krebs-Smith and Ballard-Barbash34). Compared with results from the ALSPAC study, a cohort of 1026 children aged 1·5 years, the percentage of vegetable/fruit non-consumers (2·5 %) between studies is comparable(Reference Cowin and Emmett35) (data not presented).

The present study indicates that mother's immigrant status, mother's level of education and sex of the child are especially central socio-economic and demographic factors that relate to children's food intakes. With regard to mother's immigrant status, the findings of the present study concur partially with a study from the Canadian province of Ontario where the immigrant population of adults is reported to consume less fat and more carbohydrates(Reference Pomerleau, Ostbye and Bright-See36, Reference Pomerleau, Ostbye and Bright-See37). As Pomerleau et al.(Reference Pomerleau, Ostbye and Bright-See36, Reference Pomerleau, Ostbye and Bright-See37) reported, the differences between the diets of children of immigrant mothers and children of non-immigrant mothers may reflect food consumption patterns of different countries of origin, which may also relate to food availability within those countries. For instance, many studies have reported that immigrants from South Asian countries have lower fat intakes than non-immigrants(Reference Kim, Yu and Liu14). Since immigrants are often in a situation of cultural and dietary transition, various studies have examined the association between this transition and dietary patterns. For example, Renzaho et al.(Reference Renzaho, Swinburn and Burns38) recently reported that the maintenance of traditional cultural orientation among African migrant children (3–12-year-olds) to Australia was associated with lower rates of obesity and sedentary behaviours. Given that in the present study cohort only 2·8 % of mothers were from European countries whereas 11 % originated from non-European countries(Reference Desrosiers, Dubois and Bédard24), the results suggest that, in this population, immigrants may still be adhering to traditional diets that are high in grains. Children of immigrant mothers are also more likely to be raised in a low-income family compared with children of Canadian-born mothers(39), and this may explain why in the present study it was observed that children of immigrant mothers consumed less fruit and vegetables than did children of non-immigrant mothers. Some studies report that lower-income families tend to consume fewer fruit and vegetables and less varied diets(Reference Kirkpatrick and Tarasuk40, Reference Rogers and Emmett41). However, in the present study, income level was controlled for and the relationship between a mother's immigrant status and children's lower fruit and vegetable intake remained. Thus, it is possible that the dietary choices of new immigrants may be influenced by several other determinants, apart from income level and poverty, including culture, access to information, availability of healthy and acceptable foods and acculturation(Reference Hyman, Guruge and Makarchuk42).

With regard to the association between mother's level of education and children's food intake, our results are in accordance with findings from the British National Diet and Nutrition Study that analysed the diet of 1675 children aged 1·5–4·0 years; this aforementioned study found that children of mothers with a low level of education and children from families where the head of the household had a manual occupation were less likely to meet the recommended guidelines for macronutrient intakes(Reference Watt, Dykes and Sheiham43). Most studies support a positive association between parental level of education and intakes of healthy foods(Reference Roos, Johansson and Kasmel5, Reference Sausenthaler, Kompauer and Mielck16, Reference Serra-Majem, Ribas and Perez-Rodrigo17). Since recent studies(Reference Régnier and Masullo4) have reported that different socio-economic groups are largely familiar with nutritional recommendations, it may be hypothesized that nutritional recommendations (such as other medical recommendations regarding child care, smoking, etc.) may be valued differently in lower socio-economic groups. Furthermore, as nutritional recommendations are usually encouraged and advocated by medical professionals and individuals from higher socio-economic groups, such recommendations may be perceived by individuals from lower socio-economic groups as an attempt to impose a moral constraint or ‘an attempt to impose a control on their bodies or the ones of their children’(Reference Régnier and Masullo4), as such individuals may be more concerned with meeting daily needs or maintaining other values and pleasures of life. Further research is needed to examine this hypothesis.

Finally, the findings of the present study on the association between the sex of a child and food intake contrast with findings from the ALSPAC study, which found that, among 7-year-old children, girls ate more fruit and vegetables in comparison with boys(Reference Glynn, Emmett and Rogers44). However, as was observed in the present study, being a boy was associated with a higher intake of grain products. It is possible that, as was found in the ALSPAC study, boys may be consuming greater quantities of breakfast cereals in comparison with girls, who appear to be more likely to skip breakfast than boys(Reference Rampersaud, Pereira and Girard45). However, this hypothesis remains to be tested. With regard to fruit and vegetable intakes, in 1998 the CSFII survey found that boys consumed more of all foods except fruit and vegetables(Reference Wilkinson-Enns, Mickle and Goldman7). However, using data from the 1999–2002 NHANES, Lorson et al.(Reference Lorson, Melgar-Quinonez and Taylor46) recently reported that among children aged 2–18 years of age boys consumed significantly more vegetables than did girls. As boys also consumed significantly more French fries than did girls (the leading source of vegetables in the study reported by Lorson et al.(Reference Lorson, Melgar-Quinonez and Taylor46)), it should not be automatically assumed that boys consumed more dark green or orange vegetables than did girlsFootnote *. At this pre-school age, children's preferences and differences between boys and girls are certainly influenced by the food environment that the parent provides. In a study on 3–4-year-old children, Johnson and Birch(Reference Johnson and Birch47) reported differences in how boys and girls are parented regarding food and eating practices. Their results showed that ‘restrained’ mothers attempted to restrain their daughters and not their sons. These results indicate that differential pressure for thinness between boys and girls begins during the pre-school period. These differences in parental child-feeding practices may also explain why boys were found to consume more energy than were girls in the present study. Analyses conducted by Dubois and Girard(Reference Dubois and Girard48) using data from the QLSCD showed that a higher proportion of mothers overestimated weights for boys than for girls. The authors hypothesized that mothers of young children may be influenced by social desirability and have different standards of what is acceptable in weight for boys and girls. It is also possible that boys’ energy needs are higher than that of girls because of larger body height and weight. In fact, Desrosiers et al.(Reference Desrosiers, Dubois and Bédard24), who also used data from the QLSCD, reported sex differences in mean weight and height even at the age of 4 years: 17·2 kg for boys v. 16·6 kg for girls; 104 cm for boys v. 102·8 for girls. Finally, the fact that children's level of physical activity was incorporated among the control variables is limited by the reported rather than measured nature of this variable.

Strengths, limitations and conclusion

The results of the present study should be considered in the context of its strengths and limitations. The large representative population-based sample and the high response rate (85 %) obtained are the most important strengths of the present study. Although the 24 h recall method is considered to be one of the best measures used to estimate dietary intake, it is known that this method may be biased by a high proportion of under-reporters(Reference Black, Goldberg and Jebb49). For instance, there is an increased tendency among obese parents to under-report children's dietary intakes in comparison with non-obese parents(Reference Heitmann and Lissner50). Some studies also report that snack foods are commonly under-reported(Reference Krebs-Smith, Graubard and Kahle51). To avoid these biases, O'Connor et al.(Reference O'Connor, Ball and Steinbeck52) recommend that children aged 6–9 years complete three 24 h recall interviews to minimize errors associated with under-reporting. Although we did not reach this recommended objective, energy, macronutrient and food consumption patterns were derived from a 24 h dietary recall interview conducted by trained nutritionists and a second 24 h dietary recall was administered to 50 % of the sample to assess for inter- and intra-child variability in the consumption of energy and macronutrients. The absence of information on parental food intake is a noteworthy limitation as it has been shown that parental fruit and vegetable intake is a strong predictor of children's fruit and vegetable intake(Reference Cooke, Wardle and Gibson53). However, given that diet quality is tributary to socio-economic factors such as those measured in the present study(Reference Northstone and Emmett54), it is assumed that the lack of this information has a minimal impact on the results. Another limitation to the study results is the absence of information on children's weight and height.

Overall, the present study revealed that even for pre-school children dietary intakes were associated with socio-economic and demographic factors, most notably with mother's level of education, immigrant status and sex of the child. Children of mothers with no high-school diploma consumed fewer proteins, more fats (by percentage of total energy intake) and were less likely to consume the recommended servings of fruit and vegetables in comparison with children of mothers with a higher level of education. Children of immigrant mothers consumed significantly more energy but less fruit and vegetables than did children of non-immigrant mothers. The present study also revealed that the odds for consuming the recommended servings of grain products and meat and alternatives were higher in boys than in girls, whereas for milk products the odds were higher in girls than in boys. Reducing diet-related disparities and promoting healthy eating involve a complex interaction of factors. When efforts to improve the nutrition and health of young children are planned, these diet-related disparities need to be taken into account.

Acknowledgements

The research work of L.D. was supported by the Canada Research Chair Program. The present study has been partly financed by the Canadian Institute of Health Information, Population Health Initiative and by the Canadian Institute of Health Research. Analyses were performed using data from the Longitudinal Study of Child Development in Québec (LSCDQ) 1998–2010, conducted by Santé Québec, a division of the Institut de la Statistique du Québec, and funded by the Ministry of Health and Social Services of Québec. No conflict of interest is declared. L.D. is the director of the study (questionnaire development, data analysis, interpretation of the data, etc.); M.G. planned and performed the statistical data analysis; A.F., D.B. and M.P. contributed to literature review, content analysis and writing of the manuscript. All authors have seen and approved the manuscript and have met all requirements for authorship.

Footnotes

* Families are classified as having ‘sufficient income’ when the household income is above the low-income threshold determined by Statistics Canada (2006). When income is between 60 % and 90 % of the low-income threshold, households are classified as having ‘insufficient income’; income levels <60 % of the low-income threshold are considered as ‘very insufficient’. Statistics Canada (2006), Low Income Cut-offs for 2005 and Low Income Measures for 2004, catalogue no. 75F0002MIE, vol. 4.

Dietary Guidelines for Americans. http://www.cnpp.usda.gov/Publications/DietaryGuidelines/2005/2005DGPolicyDocument.pdf

* For vegetables classification, see MyPyramid on the USDA website: www.mypyramid.gov

References

1. Halbwachs, M (1938) Esquisse d'une Psychologie des Classes Sociales. Paris: Presses Universitaires de France.Google Scholar
2. Régnier, F (2009) Obésité, goûts et consommation. Intégration des normes d'alimentation et appartenance sociale. Rev Fr Sociol 50, 747773.CrossRefGoogle Scholar
3. Bourdieu, P (1984) Distinction: A Social Critique of the Judgement of Taste. Cambridge, MA: Harvard University Press.Google Scholar
4. Régnier, F & Masullo, A (2008) Une Affaire de Goût? Réception et Mise en Pratique des Recommendations Nutritionnelles. Paris: INRA.Google Scholar
5. Roos, G, Johansson, L, Kasmel, A et al. (2001) Disparities in vegetable and fruit consumption: European cases from the north to the south. Public Health Nutr 4, 3543.CrossRefGoogle ScholarPubMed
6. Taylor, JP, Evers, S & McKenna, M (2005) Determinants of healthy eating in children and youth. Can J Public Health/Rev Can Sante Publique 96, Suppl. 3, S20S26.Google ScholarPubMed
7. Wilkinson-Enns, C, Mickle, SJ & Goldman, JD (2002) Trends in food and nutrient intakes by children in the United States. Fam Econ Nutr Rev 14, 5668.Google Scholar
8. National Centre for Health Statistics (2003) Dietary intake of ten key nutrients for public health, United States: 1999–2000. Adv Data 334, 14.Google Scholar
9. Kant, AK & Graubard, BI (2003) Predictors of reported consumption of low-nutrient-density foods in a 24-h recall by 8–16 year old US children and adolescents. Appetite 41, 175180.CrossRefGoogle Scholar
10. Subar, AF, Krebs-Smith, SM, Cook, A et al. (1998) Dietary sources of nutrients among US children, 1989–1991. Pediatrics 102, 913923.CrossRefGoogle ScholarPubMed
11. Troiano, RP, Briefel, RR, Carroll, MD et al. (2000) Energy and fat intakes of children and adolescents in the United States: data from the National Health and Nutrition Examination Surveys. Am J Clin Nutr 72, Suppl. 5, 1343S1353S.CrossRefGoogle ScholarPubMed
12. Skinner, JD, Carruth, BR, Houck, KS et al. (1999) Longitudinal study of nutrient and food intakes of white preschool children aged 24 to 60 months. J Am Diet Assoc 99, 15141521.CrossRefGoogle ScholarPubMed
13. Rasmussen, M, Krolner, R, Klepp, K-I et al. (2006) Determinants of fruit and vegetable consumption among children and adolescents: a review of the literature. Part I: quantitative studies. Int J Behav Nutr Phys Act 3, 22.CrossRefGoogle ScholarPubMed
14. Kim, KK, Yu, ES, Liu, WT et al. (1993) Nutritional status of Chinese-American, Korean-American, and Japanese-American elderly. J Am Diet Assoc 93, 14161422.Google Scholar
15. Xie, B, Gilliland, FD, Li, YF et al. (2003) Effects of ethnicity, family income, and education on dietary intake among adolescents. Prev Med 36, 3040.CrossRefGoogle ScholarPubMed
16. Sausenthaler, S, Kompauer, I, Mielck, A et al. (2007) Impact of parental education and income inequality on children's food intake. Public Health Nutr 10, 2433.Google Scholar
17. Serra-Majem, L, Ribas, L, Perez-Rodrigo, C et al. (2002) Determinants of nutrient intake among children and adolescents: results from the enKid study. Ann Nutr Metab 46, 3138.CrossRefGoogle ScholarPubMed
18. Kranz, S & Siega-Riz, AM (2002) Sociodemographic determinants of added sugar intake in preschoolers 2 to 5 years old. J Pediatr 140, 667672.CrossRefGoogle ScholarPubMed
19. North, K & Emmett, P (2000) Multivariate analysis of diet among three-year-old children and associations with socio-demographic characteristics. Eur J Clin Nutr 54, 7380.CrossRefGoogle ScholarPubMed
20. Nicklaus, S, Boggio, V et al. (2004) A prospective study of food preferences in childhood. Food Qual Prefer 15, 805818.CrossRefGoogle Scholar
21. Institute of Medicine (1998) Dietary Reference Intakes: A Risk Assessment Model for Establishing Upper Intake Levels for Nutrients. Washington, DC: National Academy Press.Google Scholar
22. Dubois, L, Bédard, B, Girard, M et al. (2000) Etude Longitudinale du Développement des Enfants du Québec (ELDEQ 1998–2002). Les Nourrissons de 5 Mois. Québec: Institut de la Statistique du Québec.Google Scholar
23. Dubois, L & Girard, M (2002) L'alimentation des Enfants d’Âge Préscolaire. Etude Longitudinale du Développement des Enfants du Québec (ELDEQ 1998–2002). Québec: Institut de la Statistique du Québec.Google Scholar
24. Desrosiers, H, Dubois, L, Bédard, B et al. (2005) Enquête de Nutrition Auprès des Enfants Québecois de 4 Ans. Québec: Institut de la Statistique du Québec.Google Scholar
25. Liu, K, Stamler, J, Dyer, A et al. (1978) Statistical methods to assess and minimize role of intra-individual variability in obscuring relationship between dietary lipids and serum cholesterol. J Chron Dis 31, 399418.CrossRefGoogle ScholarPubMed
26. Health Canada (2001) Canadian Nutrient File. Ottawa: Health Canada.Google Scholar
27. US Department of Agriculture (2004) Food and Nutrient Database for Dietary Studies, 1.0. 2004. Beltsville, MD: Agricultural Research Service, Food Surveys Research Group.Google Scholar
28. Cox, B & Cohen, S (1985) Methodological Issues for Health Care Surveys. New York: Marcel Dekker.Google Scholar
29. Institute of Medicine (2002) Dietary Reference Intakes for Energy, Carbohydrate, Fiber, Fat, Fatty Acids, Cholesterol, Protein and Amino Acids. Washington, DC: National Academy Press.Google Scholar
30. Briefel, RR & Johnson, CL (2004) Secular trends in dietary intake in the United States. Ann Rev Nutr 24, 401431.CrossRefGoogle ScholarPubMed
31. Nordic Council of Ministers (2004) Nordic Nutrition Recommendations 2004. Integrating Nutrition and Physical Activity. Copenhagen: NCM.Google Scholar
32. Lambert, J, Agostoni, C, Elmadfa, I et al. (2004) Dietary intake and nutritional status of children and adolescents in Europe. Br J Nutr 92, Suppl. 2, S147S211.CrossRefGoogle ScholarPubMed
33. Royo-Bordonada, MA, Gorgojo, L, Martin-Moreno, JM et al. (2003) Spanish children's diet: compliance with nutrient and food intake guidelines. Eur J Clin Nutr 57, 930939.CrossRefGoogle ScholarPubMed
34. Munoz, KA, Krebs-Smith, SM, Ballard-Barbash, R et al. (1997) Food intakes of US children and adolescents compared with recommendations. Pediatrics 100, 323329.CrossRefGoogle ScholarPubMed
35. Cowin, I & Emmett, P (2000) Diet in a group of 18-month-old children in South West England, and comparison with the results of a national survey. J Hum Nutr Diet 13, 87100.CrossRefGoogle Scholar
36. Pomerleau, J, Ostbye, T & Bright-See, E (1998) Place of birth and dietary intake in Ontario I. Energy, fat, cholesterol, carbohydrate, fiber, and alcohol. Prev Med 27, 3240.Google Scholar
37. Pomerleau, J, Ostbye, T & Bright-See, E (1998) Place of birth and dietary intake in Ontario II. Protein and selected micronutrients. Prev Med 27, 4149.CrossRefGoogle ScholarPubMed
38. Renzaho, AMN, Swinburn, B & Burns, C (2008) Maintenance of traditional cultural orientation is associated with lower rates of obesity and sedentary behaviours among African migrant children to Australia. Int J Obes (Lond) 32, 594600.CrossRefGoogle ScholarPubMed
39. Statistics Canada (2003) The Rise in Low-Income Rates Among Immigrants in Canada. Ottawa: Statistics Canada.Google Scholar
40. Kirkpatrick, S & Tarasuk, V (2003) The relationship between low income and household food expenditure patterns in Canada. Public Health Nutr 6, 8997.Google Scholar
41. Rogers, I & Emmett, P (2003) The effect of maternal smoking status, educational level and age on food and nutrient intakes in preschool children: results from the Avon Longitudinal Study of Parents and Children. Eur J Clin Nutr 57, 854864.CrossRefGoogle ScholarPubMed
42. Hyman, I, Guruge, S, Makarchuk, MJ et al. (2002) Promotion of healthy eating among new immigrant women in Ontario. Can J Diet Pract Res 63, 125129.CrossRefGoogle ScholarPubMed
43. Watt, RG, Dykes, J & Sheiham, A (2001) Socio-economic determinants of selected dietary indicators in British pre-school children. Public Health Nutr 4, 12291233.CrossRefGoogle ScholarPubMed
44. Glynn, L, Emmett, P & Rogers, I (2005) Food and nutrient intakes of a population sample of 7-year-old children in the south-west of England in 1999/2000 – what difference does gender make? J Hum Nutr Diet 18, 719.Google Scholar
45. Rampersaud, GC, Pereira, MA, Girard, BL et al. (2005) Review – breakfast habits, nutritional status, body weight, and academic performance in children and adolescents. J Am Diet Assoc 105, 743760.CrossRefGoogle ScholarPubMed
46. Lorson, BA, Melgar-Quinonez, HR & Taylor, CA (2009) Correlates of fruit and vegetable intakes in US children. J Am Diet Assoc 109, 474478.CrossRefGoogle ScholarPubMed
47. Johnson, SL & Birch, LL (1994) Parents and childrens adiposity and eating style. Pediatrics 94, 653661.CrossRefGoogle ScholarPubMed
48. Dubois, L & Girard, M (2007) Accuracy of materinal reports of pre-schoolers’ weights and heights as estimates of BMI values. Int J Epidemiol 36, 132138.CrossRefGoogle ScholarPubMed
49. Black, AE, Goldberg, GR, Jebb, SA et al. (1991) Critical evaluation of energy-intake data using fundamental principles of energy physiology. 2. Evaluating the results of published surveys. Eur J Clin Nutr 45, 583599.Google ScholarPubMed
50. Heitmann, BL & Lissner, L (2005) Can adverse effects of dietary fat intake be overestimated as a consequence of dietary fat underreporting? Public Health Nutr 8, 13221327.CrossRefGoogle ScholarPubMed
51. Krebs-Smith, SM, Graubard, BI, Kahle, LL et al. (2000) Low energy reporters vs others: a comparison of reported food intakes. Eur J Clin Nutr 54, 281287.Google Scholar
52. O'Connor, J, Ball, EJ, Steinbeck, KS et al. (2001) Comparison of total energy expenditure and energy intake in children aged 6–9 y. Am J Clin Nutr 74, 643649.Google Scholar
53. Cooke, LJ, Wardle, J, Gibson, EL et al. (2004) Demographic, familial and trait predictors of fruit and vegetable consumption by pre-school children. Public Health Nutr 7, 295302.Google Scholar
54. Northstone, K & Emmett, P (2005) Multivariate analysis of diet in children at four and seven years of age and associations with socio-demographic characteristics. Eur J Clin Nutr 59, 751760.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Mean energy and macronutrient intakes and the prevalence of children attaining the dietary recommendations for four food groups by different characteristics in 4-year-old children from the province of Quebec (from 24 h dietary recall)

Figure 1

Table 2 Adjusted mean energy and macronutrient intakes by different characteristics

Figure 2

Table 3 Adjusted OR for attaining dietary recommendations for food group servings at 4 years of age by different characteristics