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Associations between self-reported fruit and vegetable consumption and home availability of fruit and vegetables among Greek primary-school children

Published online by Cambridge University Press:  01 November 2008

Eleni Koui
Affiliation:
Department of Exercise, Nutrition and Health Sciences, Centre for Sport, Exercise and Health, University of Bristol, Tyndall Avenue, Bristol BS8 1TP, UK
Russell Jago*
Affiliation:
Department of Exercise, Nutrition and Health Sciences, Centre for Sport, Exercise and Health, University of Bristol, Tyndall Avenue, Bristol BS8 1TP, UK
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Abstract

Objective

To examine whether the self-reported fruit and vegetable consumption of Greek primary-school children is associated with the home availability of fruit and vegetables.

Design

Cross-sectional study.

Setting

Five primary schools in the city of Pyrgos in south-west Greece.

Subjects

One hundred and sixty-seven students in fifth and sixth grades.

Methods

Fruit and vegetable consumption was assessed using an FFQ. Home availability of fruit and vegetables was assessed using a modified version of a US home availability questionnaire. Participant BMI was assessed and parental education obtained by self-report. Hierarchical regression models that took account of the clustering of participants in schools were used to examine the relationship between consumption and availability after controlling for parental education and BMI.

Results

Regression analyses showed that home availability of fruit was a significant predictor of consumption (β = 0·524, Z = 9·77, P < 0·001) in a model that explained 46 % of the overall variance. Home availability of vegetables was a significant predictor of vegetable intake (β = 0·378, Z = 6·23, P < 0·001) in a model that explained 29 % of the overall variance.

Conclusion

Home availability of fruit and vegetables was associated with consumption among Greek primary-school children. The association between home availability of fruit and intake was higher than the associations that have been reported in other samples. Results support focusing on the home availability of fruit and vegetables as a potential mediator of consumption that could be manipulated as a means of increasing fruit and vegetable intake among children.

Type
Research Paper
Copyright
Copyright © The Authors 2007

Fruit and vegetables are an important source of micronutrientsReference Woodside, McCall, McGartland and Young(1). Fruit and vegetable consumption has been shown to reduce the risk of developing a number of diseases including some forms of cancerReference Block, Patterson and Subar(2), CHDReference Joshipura, Hu and Manson(3) and obesityReference Epstein, Gordy, Raynor, Beddome, Kilanowski and Paluch(4). Fruit and vegetable consumption during childhood may also reduce the risk of a number of childhood illnesses including respiratory symptomsReference Antova, Pattenden and Nikiforov(5). Unfortunately, despite the well-established benefits of fruit and vegetable consumption, nutritional surveys consistently show that many children and adults do not meet nutritional guidelinesReference Brady, Lindquist, Herd and Goran(6Reference Hoare, Henderson, Bates, Prentice, Birch, Swan and Farron8). A recent pan-European survey reported that there was considerable variability between countries in the fruit and vegetable consumption of 11-year-olds, with no consistent geographical variabilityReference Yngve, Wolf and Poortvliet(9). The considerable variability in the fruit and vegetable consumption of adolescents in neighbouring countries such as Spain (40 g vegetables/d) and Portugal (80 g vegetables/d) suggests a need to identify intake and specific predictors of intake in each countryReference Yngve, Wolf and Poortvliet(9).

The mediating variable model indicates that, in order to change youth fruit and vegetable intake, we need to examine the key predictors of fruit and vegetable intake and then manipulate those variables as a means of changing behaviourReference Baranowski, Anderson and Carmack(10Reference Baranowski, Klesges, Cullen and Himes12). A number of key psychosocial predictors of children’s fruit and vegetable consumption, such as attitudes, self-efficacy, preferences and knowledge, have been associated with youth fruit and vegetable consumptionReference Blanchette and Brug(13, Reference Steptoe, Perkins-Porras, McKay, Rink, Hilton and Cappuccio14). Interventions that have attempted to manipulate these variables have had limited successReference Blanchette and Brug(13, Reference Knai, Pomerleau, Lock and McKee15). Home availability of fruits and vegetables is a proximal environmental variable that has been consistently related to fruit and vegetable intake among North AmericanReference Cullen, Baranowski, Owens, Marsh, Rittenberry and de Moor(16) and Northern European youthReference Bere and Klepp(17Reference Jago, Baranowski and Baranowski19). Home availability is particularly interesting as it is potentially a relatively easy variable to manipulate and an increase in home availability is likely to result in an increase in consumptionReference Jago, Baranowski and Baranowski(19).

Data from the Pro-Children study has shown that, like consumption, home availability of fruits and vegetables differs across European countriesReference Sandvik, De Bourdeaudhuij and Due(20). A comparison of the fruit and vegetable availability in ten European countries reported that Greece and Spain had the highest levels of fruit and vegetable availabilityReference Naska, Vasdekis and Trichopoulou(21). Interestingly, data from the Pro-Children study indicated that Spanish adolescents reported some of the lowest levels of both fruit and vegetable consumption of the ten countries studied. This would appear to contradict the possible link between consumption and home availability and suggests a need to examine associations in other countries, particularly countries with high levels of availability.

There is very little information about the fruit and vegetable consumption of Greek adolescents, a nation that has previously been identified as a country with a high availability of fruit and vegetables. There is also no information about the association between fruit and vegetable availability and consumption among this groupReference Jago, Baranowski and Baranowski(19). As availability is likely higher in this groupReference Naska, Vasdekis and Trichopoulou(21), examination of whether availability is associated with intake and the strength of any association would provide further information on the possible importance of home availability as a target for intervention. The present study addressed these issues by examining associations between self-reported fruit and vegetable consumption and self-reported fruit and vegetable home availability in a sample of Greek primary-school children.

Methods

Participants

Participants were recruited from five randomly selected primary schools in the city of Pyrgos in south-west Greece in summer 2006. After an initial explanation of the study by the lead author, all fifth and sixth grade students in the schools were encouraged to take home to their parents study information packs that included informed consent and assent formsReference Jago and Bailey(22). Of the 368 eligible students in the schools, informed consent and assent were obtained from 167 (45 %) students. The study was approved by the University of Bristol Ethics and Research Committee.

Measures

Socio-economic status was assessed based on a previous Greek questionnaireReference Krassas, Tzotzas, Tsametis and Konstantinidis(23) that assessed maternal and paternal education according to the length of participation in formal education (<6 years, 6–12 years, >12 years). Fruit and vegetable intake was assessed using an FFQ that included two fruit juices, sixteen fruit and sixteen vegetable items. The FFQ was adapted from a previously validated FFQ that was shown to have good reliability and validity among 9–14-year-old US childrenReference Cullen, Baranowski, Baranowski, Hebert and de Moor(24). The questionnaire asks how many servings of each item the respondent has consumed during the last week, with a serving being a single helping of that food. Respondents are told to include fresh, frozen and canned foods. The original items were created on the basis of the most commonly consumed fruit, juices and vegetables reported in the US Continuing Survey of Food Intake by IndividualsReference Cullen, Baranowski, Baranowski, Hebert and de Moor(24). However, as there is no equivalent data set for Greece, the items were reviewed by the first author and other Greek dietitians and modified according to the foods most likely to be consumed. Deleted foods were 100 % grape juice, 100 % other juice, kiwi, grapefruit, apple sauce, celery, potato salad, corn, broccoli, coleslaw and sweet potatoes, while added foods were cherries, nectarines, aubergines, courgettes, potatoes, pulses (lentils/beans), cucumber and radishes. The FFQ asks about the previous seven days and asks respondents to report consumption for each item in seven categories: none, 1 serving, 2–3 servings, 4–6 servings, 7 servings, 8–14 servings, 15 or more servings in the past week. Prior to completion the first author provided the students with instructions and was available to answer any questions.

Home availability of fruits and vegetables was reported by the student using a modified version of the Cullen questionnaireReference Cullen, Baranowski, Owens, Marsh, Rittenberry and de Moor(16). The Cullen questionnaire has been validated against self-inventories and has been used widelyReference Cullen, Klesges, Sherwood, Baranowski, Beech, Pratt, Zhou and Rochon(25). The questionnaire asks, using a yes/no response, whether fruits and vegetables on the given list were available in the student’s home during the past week. The questionnaire was modified to include the foods on the revised Greek FFQ. All questionnaires were translated into Greek and the translation checked for accuracy by another bilingual Greek dietitian. All measures were completed in a school classroom with the lead author available to answer any participant’s questions.

Anthropometric assessments

Body weight was assessed to the nearest 0·1 kg according to a standard protocol using a digital scaleReference Lohman, Roche and Martorell(26). Height was assessed to 0·5 cm using a standard protocol and a measuring tapeReference Lohman, Roche and Martorell(26). All measurements were taken by a registered dietitian and BMI was calculated (kg/m2). For descriptive purposes, BMI was also used to classify participants as normal weight, overweight and obese according to the cut-off points for childhood obesity of the International Obesity Task ForceReference Cole, Bellizzi, Flegal and Dietz(27).

Data reduction

Data from the FFQ were reduced using the mean value of the category (thus 2–3 servings was coded as 2·5, 4–6 was coded as 5, 8–14 was coded as 11, 15 or more was coded as 15). The total weekly servings were then divided by seven to obtain the daily consumption of each item. As evidence suggests that youth view fruit and juices separately (e.g. negative peer influences for eating vegetables, but not fruits or juices)Reference Cullen, Baranowski, Baranowski, Warnecke, de Moor, Nwachokor, Hajek and Jones(28), fruits and juices were combined and summed with separate analyses performed for summed vegetable (excluding potatoes) consumption. The number of fruits and vegetables available in the home was summed for each participant.

Statistical analysis

Descriptive statistics, means, standard deviations and percentages, were calculated for all variables. Cronbach’s alpha was run to assess the internal consistency of the intake and availability measures in this sample. Bivariate correlations were performed among fruit and juice and vegetable availability and intake, age and BMI. Participant-reported fruit consumption and fruit availability were then dichotomised as low (less than the mean) or high (greater than or equal to the mean). A Pearson χ 2 test was then used to test for differences in these groupings. This process was then repeated separately for vegetable consumption and availability.

Hierarchical linear regression models that took account of the clustering of participants in schools were calculated to examine the extent to which availability predicted consumption. Models were run using the xtreg command in the STATA statistical software package version 9·0 (StataCorp, College Station, TX, USA) with intake (either vegetable or fruit and juice) as the dependent variable and availability (either vegetable or fruit and juice) as the independent variable while also controlling for gender (male as the reference group). School was included as a random effect. As youth fruit and vegetable consumption has previously been reported to vary by the respondent’s adiposity, BMI was also included in the modelsReference Cullen, Baranowski, Klesges, Watson, Sherwood, Story, Zakeri, Leachman-Slawson and Pratt(29, Reference Perez-Rodrigo, Aranceta Bartrina, Serra Majem, Moreno and Delgado Rubio30). Father’s education was also included in the models, but as father’s and mother’s education were significantly correlated (r = 0·633, P < 0·001), mother’s education was excluded. The within-school R 2, the between-school R 2 and the overall R 2, which is analogous to the R 2 obtained from non-nested models, were also produced.

Results

Descriptive statistics for the 167 students who took part in this study are shown in Table 1. The sample was 52 % female and 37 % of the participants were overweight with an additional 11 % obese. Parental education data were obtained for only 118 of the 167 participants. The mean daily fruit and juice consumption was 3·1 servings, with 2·7 servings of vegetables (excluding potatoes). The mean number of fruits available in the home was 7·0 and 8·1 for vegetables. Cronbach’s α for fruit intake was 0·808 and 0·848 for vegetable intake (excluding potatoes), indicating high internal consistency for these measures in this sample. Cronbach’s α for fruit availability was 0·632 and 0·596 for vegetable availability (excluding potatoes), suggesting reasonable internal consistency.

Table 1 Descriptive statistics for participant characteristics, fruit and vegetable intake, and fruit and vegetable availability: Greek primary-school children

Pearson correlations between intake, availability and demographic variables are presented in Table 2. Fruit availability was significantly correlated with vegetable availability (r = 0·589, P < 0·001), fruit intake (r = 0·707, P < 0·001) and vegetable intake (r = 0·459, P < 0·001). Vegetable availability was significantly correlated with fruit intake (r = 0·472, P < 0·001) and vegetable consumption (r = 0·510, P < 0·001). Fruit intake was significantly correlated with vegetable intake (r = 0·687, P < 0·001) while vegetable intake was significantly associated with age (r = 0·155, P = 0·046).

Table 2 Correlations among diet, availability and demographic variables: Greek primary-school children

Correlation was statistically significant: *P < 0·05; **P < 0·001.

The cross-tabulations showing the association between self-reported fruit and vegetable availability and intake are presented in Table 3. Participants who reported a low consumption of vegetables were likely to reside in homes with limited vegetable availability. The same pattern was also evident for fruit.

Table 3 Cross-tabulation of high and low fruit and vegetable consumption and availability: Greek primary-school children

The regression model predicting vegetable consumption (excluding potatoes) for the 118 participants with complete data for all variables is shown in Table 4. The home availability of vegetables was a significant predictor (Z = 6·23, P < 0·001) of consumption, while the consumption in the highest maternal education group was significantly lower (Z = −2·02, P = 0·043) than in the lowest education group. The model accounted for 29 % of the variance within schools and 28 % of the overall variance but only 5 % of the variance between schools.

Table 4 Regression model predicting mean daily vegetable consumption: Greek primary-school children

The regression model predicting fruit consumption for the 118 participants with complete data for all variables is shown in Table 5. Fruit availability was the only significant predictor of consumption (Z = 9·77, P < 0·001) in a model that accounted for 47 % of the variance within schools, 10 % of the variance between schools and 46 % of the overall variance.

Table 5 Regression model predicting mean daily fruit and juice consumption: Greek primary-school children

Discussion

The present study has shown that fruit and vegetable availability are significantly associated with consumption among Greek primary-school students. Moreover, we have also shown that these associations were maintained after accounting for age, gender, BMI and father’s education in models that control for the clustering of participants within schools. Interestingly, cross-tabulations showed that participants with low consumption were likely to live in homes with low availability of fruit and vegetables. Although respondents with high consumption tended to be approximately evenly split among those residing in low and high availability households, this finding suggests that home availability is an important influence on Greek children’s fruit and vegetable consumption. Moreover, home availability might be a particularly important influence on children with low consumption and could be a key intervention target for this group.

Our results are similar those reported previously among US and Northern European adolescents. For example, among Norwegian sixth and eighth grade students a fruit and vegetable accessibility scale that included availability items was correlated (r = 0·44) with fruit and vegetable intake obtained from an FFQReference Bere and Klepp(17). Similarly, among fourth to sixth grade students in Houston, Texas the availability of fruits and vegetables was correlated (r = 0·21) with intake obtained via a food recordReference Cullen, Baranowski, Owens, Marsh, Rittenberry and de Moor(16).

The associations found in the present study are stronger than those reported earlier, with a correlation of 0·7 for the association between fruit intake and availability and 0·5 for the association between vegetable availability and intake. These associations were maintained in the regression models, which accounted for 28 % of the overall variance in the vegetable model and 46 % of the variance in the fruit model. The variance in fruit accounted for by these models is considerably greater than the 30 % that has traditionally been reported as the maximum amount of variance in fruit and vegetable consumption among children after accounting for demographics, availability and other psychosocial variables such as self-efficacyReference Bere and Klepp(17, Reference Wind, De Bourdeaudhuij, te Velde, Sandvik, Due, Klepp and Brug31Reference Baranowski, Cullen and Baranowski33). The variance accounted for in the vegetable model is less than the 39 % that was recently reported among Icelandic youth with low vegetable consumption (less than 1 serving/d)Reference Kristjansdottir, Thorsdottir, De Bourdeaudhuij, Due, Wind and Klepp(34). The associations between fruit availability and intake are likely a by-product of the Greek lifestyle whereby the home is the main place where children have most of their meals, including access to fruits and vegetables. Less fruit and vegetable consumption outside the home may aid the formation of desirable dietary patterns without distractions from other environments. The implication of this finding is that Greek children who live in homes that have high availability of fruits and vegetables are likely to consume more of these foods. Promoting home availability is therefore likely to be an important intervention mechanism.

Our finding that high availability of fruit and vegetables is associated with high consumption appears consistent with US literature in which lower levels of consumption have been reported and consumption has been linked to availability. At first glance this finding would appear to suggest that a consistent relationship exists between these variables. However, data from the Pro-Children study have shown that 11-year-olds’ fruit and vegetable consumption in Spain is lower than that of similar aged children in countries such as Norway and Sweden that have lower levels of availabilityReference Yngve, Wolf and Poortvliet(9, Reference Naska, Vasdekis and Trichopoulou21). While these inconsistencies could be a product of the methods used to assess both availability and intake, it seems likely that national, culturally specific factors are also important. This would imply that we need to understand the association between availability and intake in different countries, and what the cultural influences on this association might be. Potentially important factors could be family meal times and parenting style, as well as more general social trends within the countryReference Kremers, Brug, de Vries and Engels(35, Reference Nicklas, Baranowski, Baranowski, Cullen, Rittenberry and Olvera36). Once associations and influences have been established more work is needed to ascertain if the cultural influences from one country can be translated to another as a means of increasing consumption.

There was no significant association between fruit consumption and BMI or between vegetable consumption and BMI. This is contrary to previous studies in the USAReference Cullen, Baranowski, Klesges, Watson, Sherwood, Story, Zakeri, Leachman-Slawson and Pratt(29) and SpainReference Perez-Rodrigo, Aranceta Bartrina, Serra Majem, Moreno and Delgado Rubio(30), which found that increased consumption of fruit and vegetables was associated with a lower BMI. The lack of an association of either food group with BMI might suggest that associations between BMI and fruit and vegetable consumption differ by country. Understanding the possible reasons for these country differences could provide insights into the possible utility of increasing fruit and vegetable consumption as a means of preventing childhood obesity. More work is therefore needed to tease out the possible causes of these different associations.

Consumption of vegetables differed according to father’s education level, with participants who lived in higher educated households consuming fewer vegetables than the least educated group. Our finding is therefore different from the associations that have previously been reported in studies from the UKReference Wardle, Jarvis, Steggles, Sutton, Williamson, Farrimond, Cartwright and Simon(7) and The NetherlandsReference Hulshof, Brussaard, Kruizinga, Telman and Lowik(37), where vegetable consumption was found to be higher among more affluent socio-economic groups. The difference between these studies suggests that there is likely something unique about the fruit and vegetable consumption of Greek adolescents. More work is therefore needed to elucidate the dietary patterns of this group, associations with home availability and the reasons for these associations. Such information could then be used to develop more effective intervention approaches.

Strengths and limitations

The present study enhances previous work by reporting the association between fruit and vegetable consumption and home availability of fruits and vegetables among children who reside in a country where fruits and vegetables are routinely available in large quantities within the home. Its data therefore provide information that supports the promotion of home availability of fruits and vegetables in populations that currently have low levels of home availability.

The study is limited by the relatively small sample drawn from a single city in south-west Greece and the absence of parental educational data for forty-nine participants. The consent rate achieved in the present work was considerably lower than the rates reported in similar studies such as the multi-national Pro-Children studyReference Yngve, Wolf and Poortvliet(9). The low consent rate limits our ability to generalise our findings beyond our sample. Furthermore, although we used a previously validated FFQ the scale was modified for the local population and we do not have test–retest data in this population. FFQ are reliant on the participants’ perception of frequency and portion sizeReference Willett(38) and the tool we used assessed consumption of multiple, individual fruits and vegetables which may lead to an overestimation of intakeReference Krebs-Smith, Heimendinger, Subar, Patterson and Pivonka(39).

It is also important to acknowledge that we assessed the potential importance of only one variable on the fruit and vegetable consumption of Greek children. As a number of psychosocial variables such as self-efficacy and taste preferencesReference Sandvik, De Bourdeaudhuij and Due(20, Reference Baranowski, Cullen and Baranowski33) have been associated with consumption, it could be that these variables accounted for part of the variance in the models and therefore the importance of availability was inflated in our analyses. However, the correlations between intake variables and home availability are higher than those reported in many other studiesReference Jago, Baranowski and Baranowski(19), suggesting that home availability is a stronger predictor of intake among Greek children than in many other groups. More work is therefore needed to determine what the causes of such differences might be.

Conclusions

The data presented herein indicate that home availability of fruit and vegetables is associated with intake among Greek children. Importantly, the data indicate that the association between fruit intake and consumption is substantially higher than the associations reported among Northern European and American populations. We have also shown that participants who resided in homes that did not have many fruits and vegetables were likely to consume less fruit and vegetables than their counterparts who had a high home availability of fruits and vegetables. These findings therefore provide support for an association between availability and intake, and suggest that promoting home availability of fruit and vegetables could be an important means of increasing consumption.

Acknowledgements

The data reported in the present article were collected as part of the first author’s MSc dissertation that was supervised by R.J. Both authors participated in the conception and writing of the paper. R.J. performed the analysis. We have no conflicts of interest.

References

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Figure 0

Table 1 Descriptive statistics for participant characteristics, fruit and vegetable intake, and fruit and vegetable availability: Greek primary-school children

Figure 1

Table 2 Correlations among diet, availability and demographic variables: Greek primary-school children

Figure 2

Table 3 Cross-tabulation of high and low fruit and vegetable consumption and availability: Greek primary-school children

Figure 3

Table 4 Regression model predicting mean daily vegetable consumption: Greek primary-school children

Figure 4

Table 5 Regression model predicting mean daily fruit and juice consumption: Greek primary-school children