A diet rich in fruit and vegetables may decrease the risk of developing chronic diseases such as CVD, stroke, obesity and several forms of cancer in adult life(1, 2). For some cancer sites, the risk of developing cancer doubles with adult diets in the lowest quartile of intake of fruit and vegetables compared with the upper quartile of intake(Reference Block, Patterson and Sumar3). Good dietary habits developed in childhood may persist and lead to improved diet and health in adulthood(Reference Maynard, Gunnell and Emmett4, Reference Fisher, Mitchell and Smiciklas-Wright5).
The recommended intake of fruit and vegetables for adults and children in the UK and other Western countries is 400 g/d. This is equivalent to five 80 g portions of fruit and vegetables daily(2). In other countries recommendations are higher. In Australia the ‘Go for 2 & 5’ campaign recommends a daily intake of at least two pieces of fruit and five vegetables(6). Denmark recommends 600 g/d(Reference Eriksen, Haraldsdottir and Pederson7, Reference Appleton, Rogers and Blundell8). Surveys indicate that children living in Western countries are consuming considerably less than these recommendations(Reference Ransley, Greenwood and Cade9–Reference Krebs-Smith, Cook and Subar12). A UK survey reported children's intake to be 2·5 portions of fruit and vegetables daily. In Australia and the USA consumption is slightly higher(Reference Magarey, Daniels and Smith11, Reference Krebs-Smith, Cook and Subar12). The School Fruit and Vegetable Scheme (SFVS) was launched in 2004 as part of the UK's 5-A-Day strategy to improve children's consumption of fruit and vegetables(13). This scheme provides a free piece of fruit or vegetable each school day to children from the age of 4 years, for the first three years of school(14). The scheme distributes ∼440 million pieces of fruit and vegetables each year to over two million children in 18 000 schools across England(Reference Kitchen, Ransley and Greenwood15).
Studies evaluating the SFVS suggest that it increases children's fruit and vegetable intake in the short term, while children receive the free fruit or vegetable, but this falls when children are no longer eligible for the scheme. There appears to be no long-term impact of this scheme on fruit and vegetable intake of children(Reference Ransley, Greenwood and Cade9, Reference Wells, Nelson and Wells16, Reference Fogarty, Antoniak and Venn17).
A number of school-based multi-component intervention trials to improve fruit and vegetable intake in children have been carried out which include elements to improve the school curriculum as well as providing home-based projects(Reference Baranowski, Davis and Resnicow18–Reference Sahota, Rudolf and Dixey25). The majority of these studies are US-based and also include components to improve the school environment. Two trials reported in the literature are based in the UK; one in Dundee(Reference Anderson, Porteous and Foster24) and one in Leeds(Reference Sahota, Rudolf and Dixey25). The former included improvements to the curriculum and communications with parents and successfully improved fruit and vegetable consumption, while the latter focused on improving the curriculum and the school environment and reported little impact on fruit and vegetable intake.
There is a need for a school-based programme to maintain the increased intake of fruit following children's participation in the SFVS during the first three years of school. Project Tomato is a flexible, multi-component, theory-based intervention designed to do just this. The intervention is designed for children in school Years 3 and 4 (aged 7–9 years) who no longer receive free fruit and vegetables at school. It contains components which aim to both improve the school curriculum and engage parents and children at home using a variety of home-based projects.
The present study reports results from Project Tomato, the first-cluster randomised controlled trial in the UK to study the maintenance of fruit and vegetable intake post SFVS in a large number of schools across England.
Methods
Sampling method and study design
In 2006, a nationally representative sample of 130 primary schools across England formed a cross-sectional survey of children's fruit and vegetable intake. Schools were randomly sampled from the National Foundation of Educational Research (NFER) database of all schools. Schools were excluded if they had fewer than fifteen pupils per class, did not have pupils in Years 2–4, were independent or special schools, or were schools that had previously participated in SFVS projects. All schools were stratified on the following background criteria to ensure the sample was representative of English schools: Local Education Authority type (e.g. rural/metropolitan); school type (e.g. infant, primary); Key Stage One academic attainment (percentage of pupils achieving level two on Standard Assessment Tasks); percentage of pupils eligible for free school meals; percentage of pupils defined as having special educational needs; and percentage of pupils with English as an additional language. From the sample of 130 schools assessed at baseline, a subset of fifty-four schools was selected using a random allocation sequence generated by a computerised random number generator and recruited to the Project Tomato cluster-randomised controlled trial.
Eligible schools were sent a letter, additional information and a consent form inviting them to take part in the study. Parents received a letter with information about the study two weeks prior to the data collection date. The letter contained a self-completed reply slip providing the parents or guardians the opportunity for their child not to take part in the study (opt-out consent). Parents who did not wish their child to participate completed the reply slip, which was then returned to the school. Ethics approval was obtained through the University of Leeds Central Research Ethics Committee.
Fifty-four schools with 1031 children aged 7–8 years (Year 2) were randomised by school to either the intervention or control group. Block randomisation within strata was used (blocks of two) stratifying on ethnicity (percentage of pupils non-white British) and deprivation (percentage of pupils eligible for free school meals), both split at the median. Baseline data were collected between February and March 2007, and follow-up data were collected between September and October 2008 when these children were in Year 4.
The intervention
The intervention, Project Tomato, was designed using a framework of health maintenance behaviour which included the following components: familiarising children with fruit and vegetables through activities such as gardening and cooking; repeated exposure to eating fruit and vegetables through tasting sessions and school meals; engaging children in activities relating to these foods through science experiments and growing; encouraging adult and peer modelling of desirable behaviours such as eating fruit; and ensuring that the environment of the school promotes the eating of fruit and vegetables(Reference Kitchen, Ransley and Greenwood15, Reference Knai, Pomerleau and Lock26, Reference Conner and Sparks27). This approach was summarised by the acronym FRAME (Familiarisation, Repetition, Activities, Modelling and Environment).
The duration of the intervention was 10 months from July 2007 to April 2008. All schools received core intervention materials and activities consisting of a manual, twelve lesson plans, two newsletters, advice for parents, three take-home activity bags, and instructions for setting up a committee. In addition, schools received customised modules of materials and activities depending on their baseline level of activity in a number of key areas relating to promoting fruit and vegetable consumption, such as a cooking club or gardening club. For example, if a school did not have a gardening club, the head teacher was asked if they would like information to help them set up a club for Year 2 children in their school. The intervention participants – teachers, parents and children – were asked to complete questionnaires on the intervention materials to identify aspects relating to implementation and appreciation of the intervention. Baseline level of school activity to promote fruit and vegetable consumption was assessed by a questionnaire completed by a Year 3 teacher.
The control schools received a ‘5-A-DAY’ booklet and healthy eating leaflets to distribute to parents of Year 2 pupils(13).
Dietary assessment
Dietary intake was assessed using a validated 24 h dietary assessment tool, the Child and Diet Evaluation Tool (CADET) diary(Reference Cade, Frear and Greenwood28). The CADET diary comprises of a list of 105 separate food and drink types, divided into fifteen categories. The categories of foods are: (i) cereal (five items); (ii) sandwich/bread/cake/biscuit (ten items); (iii) spreads/sauces/soup (seven items); (iv) cheese/egg (six items); (v) chicken/turkey (three items); (vi) meat other (nine items); (vii) fish (five items); (viii) vegetarian (three items); (ix) pizza/pasta/rice (eight items); (x) desserts/puddings (three items); (xi) sweets/crisps (four items); (xii) vegetables and beans (eighteen items); (xiii) potato (two items); (xiv) fruit (thirteen items); and (xv) drinks (nine items). Each item in the diary has seven tick boxes related to different meal time options: ‘morning break’, ‘lunch time’, ‘afternoon break’, ‘before tea (after school)’, ‘evening meal/tea’, ‘after tea/during night’ and ‘breakfast/before school’. The diary is completed by a parent or guardian at home and by trained field workers at school; they are required to tick each item consumed by the child, under the appropriate meal time heading, within the 24 h period. For this analysis the NFER field workers completed the CADET diary during school hours. Parents were asked to record what their child ate in the evening and before school the next day. Gender- and age-specific portion sizes were applied to the data based on UK national survey results(Reference Gregory, Lowe and Bates10).
Statistical analysis
Twenty schools were required with 500 children per group to have 90 % power to detect a 0·5 portion difference in fruit or vegetable intake. Further details on the sampling methodology are reported elsewhere(Reference Kitchen, Ransley and Greenwood15).
Children who had no ticks in their diary for the home time periods were excluded from the analysis. Children were also excluded if they had more than forty ticks on their CADET diary as this indicated that they were using the CADET diary incorrectly.
To assess the impact of the intervention on changes in children's fruit and vegetable intake, an intention to treat analysis was undertaken. Multilevel regression modelling was conducted using MLwiN(Reference Rasbash, Steele and Browne29). This model takes into consideration the hierarchical structure of the data caused by cluster randomisation: school level and child level(Reference Kitchen, Ransley and Greenwood15). This type of analysis is appropriate as children within the same school are likely to be more similar to each other than to others in a different school in terms of fruit and vegetable intake. A random intercepts model was used with total weight of fruit and vegetables, weight of fruit only and weight of vegetables only used as the main outcomes. Weights were also converted to portions. To determine the intervention effects, baseline levels and age were included in the model as covariates (fixed effects), together with intervention status and gender as dummy variables (fixed effects). Results for school and home separately are reported as medians with interquartile range due to the data not being normally distributed. Vitamin C and vitamin A were log transformed as they are not normally distributed based on previous research(Reference Gregory, Lowe and Bates10).
Results
Fifty-four schools were randomised into the trial. Fifty schools (twenty-six control and twenty-four intervention) completed the trial. Trial materials were allocated to 1080 children and 1031 received the materials: fourteen children were opted out by their parents; thirty-one were absent on the baseline collection day; and four children had left the school before data collection. CADET diaries were returned from 781 (76 % of those receiving materials) children who completed it at both baseline and follow-up. Data from 658 children (64 % of those receiving materials: 347 control and 311 intervention) were used in the analysis. Poor completion of CADET resulted in 123 children being excluded from the analysis. Reasons for the loss of children randomised to the trial included: absence on the day of the survey; a move from the school between baseline and follow-up; and withdrawal of schools due to entering special measures (see Figs 1 and 2).
Table 1 shows baseline intakes of fruit, vegetables and key nutrients in the control and intervention groups. Intakes of food and key nutrients and energy were closely matched at baseline across intervention and control groups. The combined mean daily fruit and vegetable intake was similar in both groups (control: 305 g, 95 % CI 286, 324 g; intervention: 309 g, 95 % CI 287, 332 g). Comparison of the characteristics of children in the control and intervention group at baseline is shown in Table 1. There were also negligible differences in age, sex, height, weight and deprivation; however, there were slightly more children from different ethnic groups in the control compared with the intervention group (21·7 %, 95 % CI 14·2, 33·2 % v. 14·4 %, 95 % CI 8·3, 23·1 %, respectively). Slightly more children were eligible for free school meals in the control group compared with the intervention group.
IQR, interquartile range; IMD, Index of Multiple Deprivation; FSME, free school meal eligibility; N/A, not applicable.
*Median and IQR (single-level model).
†Natural log.
Project Tomato was evaluated by comparing fruit and vegetable intake between children in the intervention group and children in the control group at follow-up. Both groups were similar in terms of fruit and vegetable intake (mean difference: 2 g/d, 95 % CI −23, 26 g/d). This difference was not statistically significant. There was no effect of the intervention as delivered on the number of portions of fruit (0·0 portions, 95 % CI −0·3, 0·3) or vegetables (0·0 portions, 95 % CI −0·2, 0·3) consumed daily. Fruit intake was slightly higher than vegetable intake in both groups. There were no differences between the two groups of children in terms of intakes of key nutrients (Table 2). Intake of fruit and vegetables combined fell by ∼50 g/d between baseline and follow-up in both groups.
IQR, interquartile range; N/A, not applicable.
*Median and IQR (single-level model).
†Natural log.
Fruit and vegetable consumption dropped at home and at school between baseline and follow-up for both groups. In the control group, median daily fruit and vegetable intake fell from 184 g to 124 g at home and from 193 g to 91 g at school. In the intervention group, median daily fruit and vegetable intake fell from 190 g to 142 g at home and from 189 g to 90 g at school. This drop in school fruit and vegetable intake was most likely due to children not receiving free school fruit or vegetables and also to a reduction in intake at lunch time and break time.
All twenty-four schools which completed the intervention also completed the process measures questionnaires and 261 of the 311 children who completed the trial also completed the process measures evaluation. Implementation of the intervention was low overall, with 21 % of school items and 56 % of home items being used. Four schools implemented the additional materials to set up cooking and gardening clubs. Further details of the process evaluation are presented elsewhere(Reference Christian, Evans and Ransley30).
Discussion
Project Tomato is the first large, multi-component cluster-randomised controlled trial designed to improve fruit and vegetable intake involving primary schools across England. The intervention was designed to prevent the fall in consumption of fruit and vegetables in Year 3 children, aged 8–9 years, when they are no longer eligible for free school fruit.
Despite an intensive programme of activities, the intervention, as delivered, failed to have an impact on children's fruit and vegetable intake post SFVS. The decreased intake of fruit and vegetables in these children was particularly notable during the school day where it dropped by half. At baseline, children were receiving free school fruit and were eating more fruit than vegetables at school. When eligibility for free fruit ends, it coincides with a drop in fruit and vegetable intake. This is particularly marked at school and was not offset by the intervention. The availability of fruit during the school day, through schemes such as the SFVS, may be a key determinant of fruit intake in children. It appears difficult to make up for this loss of fruit provided either at school or home.
One reason for the lack of an intervention effect may be due to incomplete implementation. Process measure questionnaires were taken throughout the intervention from teachers, parents and children. The questionnaires measured implementation and appreciation of the intervention materials. Implementation of the intervention was low, with teachers implementing only 21 % of intervention materials even though they reported that they liked the materials and activities that had been provided. Children implemented 56 % of activities provided in the take-home activity kits. Parents implemented 35 % of the activities related to the intervention. Both child and parent appreciation of the intervention items was high(Reference Christian, Evans and Ransley30). The intervention was designed to be pragmatic, not relying on external agencies to deliver the activities; however, it appears that despite commitment from the schools and appreciation of the materials there was limited implementation.
The intervention was based on psychological constructs shown to promote behaviour change. Research in the field of health psychology suggests that the process of initiating health behaviour, such as eating more fruit, may be different from maintaining the behaviour. Each type of behaviour may need a separate and distinctive intervention strategy to support it(Reference Armitage and Conner31). The intervention was designed to address this hypothesis by mapping key psychological constructs involved with maintenance behaviour to intervention activities.
The intervention Project Tomato involved components aimed at teachers, parents and children over a period of 10 months. It is important to note this intervention was designed to be delivered by school staff and no additional personnel were deployed. Project Tomato was also designed to be sustainable and to enable the schools to continue its delivery beyond the evaluation stage. Multi-component interventions in this age group have been reported from the USA and shown improvements in fruit and vegetable intake of a third of a portion or more per day. A recent pooled analysis of seven studies in the USA showed an increase of 0·45 portions of fruit and vegetables consumed daily post intervention(Reference Howerton, Bell and Dodd32). However, not all of these studies were randomised controlled trials. The studies included in the analysis were more intensive, of longer duration and included additional personnel to deliver the interventions(Reference Reynolds, Franklin and Binkley23, Reference Perry, Bishop and Taylor33, Reference Cullen, Watson and Baranowski34). An Icelandic study showed a 46 % increase in fruit and vegetable intake in primary-school children following a school-based intervention. That study was, however, characterised by low intake of fruit and vegetables at baseline together with baseline imbalance between the intervention and control groups(Reference Kristjansdottir, Johannsson and Thorsdottir35). One recent intervention in the UK had some success in increasing fruit and vegetables in packed lunches at schools(Reference Evans, Greenwood and Thomas36).
The age-related decline in fruit and vegetables observed in the present study is a cause for concern, particularly as the intervention was designed to attenuate this. The School Meal Standards and the restriction on advertising of food high in fat, salt and sugar to children, which were introduced after this intervention, may help to increase children's intake of fruit and vegetables(37, 38). The introduction of food-based standards for school meals in 2006 has moderately improved the nutrient content of school meals, slightly widening the nutritional gap between children consuming school meals compared with packed lunches(Reference Evans, Cleghorn and Greenwood39). However, packed lunches fall behind with only 19 % of packed lunches containing vegetables and 54 % containing fruit for children in this age group(Reference Evans, Greenwood and Thomas40).
Powerful socio-cultural influences drive children's eating behaviour towards a more processed diet that is low in fruit and vegetables, with adolescents consuming less fruit and vegetables than younger children, particularly boys(Reference Gregory, Lowe and Bates10). This may be hard to offset without the continued availability of free fruit during the school day. The combined fruit and vegetable intake of about 300 g/d in the present study appears relatively high in comparison to other UK data. Findings of the National Diet and Nutrition Survey (NDNS) found the median intake of fruit for children aged 4–10 years was 88 g/d and intake of cooked and raw vegetables including salad was 74 g/d(Reference Ransley, Greenwood and Cade9, Reference Gregory, Lowe and Bates10), for a daily total of 162 g of fruit and vegetables combined. The fall in fruit intake at school in Year 3 shown in the present study may provide some evidence to support the continuation of the SFVS throughout primary school. However, more work is needed to confirm this. Some other studies have reported similar small or no improvements in fruit and vegetable intake following an intervention(Reference Bere, Veierod and Klepp41, Reference Te Velde, Brug and Wind42) although others have been successful(Reference Ciliska, Miles and O'Brien43, Reference Auld, Romaniello and Heimendinger44).
Strengths of the present study include the strong study design, the random sampling to include all primary schools in England, and the multilevel analysis using MLwiN which took into account the clustering of children within schools. A validated dietary assessment tool was used.
There were some limitations to the study. Four schools (∼120 pupils) were lost following randomisation. Reasons for school withdrawal included the school entering special measures or undergoing an inspection. This could have led to biased results if the schools that withdrew were different from schools that remained in the trial. In addition, the children in the intervention and control groups could have been unmatched in terms of social deprivation. Although attempts were made to match schools, measures of deprivation at the individual level were not included in the model. Parents were asked for their postcode to determine an IMD (Index of Multiple Deprivation) score for each child, but a large number of families did not provide this data. Therefore including IMD in the analysis would have greatly reduced the number of children included in the final model, leading to bias if there were inherent differences between families who provided this information and those who did not.
The dietary assessment tool could also be a limitation. The portion size of some of the different fruits and vegetables may have been overestimated using this method. Accurately assessing diet remains a difficult problem and the issue with 24 h recalls such as CADET is that participants may overestimate intake compared with weighed diaries, where participants are more likely to underestimate consumption. Although efforts were made to exclude children who used the assessment tool as an FFQ by ticking all the fruits and vegetables that they ever ate, it is possible that some pupils were included, contributing to an overestimation of fruit and vegetable consumption. The estimated daily amounts in the present study are higher than in the NDNS where weighed diaries were used, which may be due to overestimation of the CADET tool or underestimation of NDNS data. Moreover, the diary was only completed for 1 d, and fruit and vegetable consumption could vary considerably from day to day for each child. These issues are unlikely to have had an impact on the results of the trial as fruit and vegetable consumption would have been overestimated in both groups to the same degree.
Conclusions
The present large, cluster-randomised controlled trial provided a unique opportunity to explore whether a multi-component school-based intervention could increase children's consumption of fruit and vegetables. The results showed that the intervention as delivered had no positive effect on children's intake of these foods. Rather there was a marked decline following the end of the SFVS, particularly during the school day. However, the implementation of the intervention by teachers, pupils and parents was low. This raises important issues regarding how long national interventions such as the SFVS should be maintained in schools; what the effects of withdrawing an intervention may be; and the challenges facing the implementation of dietary interventions during the busy school day. These findings suggest that further work is required to improve the delivery and implementation of school-based interventions to improve fruit and vegetable consumption and to prevent the age-related decline in fruit and vegetable intake.
Acknowledgements
Sources of funding: This work was supported by the National Prevention Research Initiative of the UK Medical Research Council. Conflicts of interest: All authors declare that they have no conflicts of interest. Authors’ contributions: J.K.R. was responsible for managing the project, designing the intervention and writing the first draft of the paper. C.E.L.E. was responsible for analysing the data and updating the paper. M.S.C. was responsible for day-to-day running of the project, designing the intervention and updating the paper. D.C.G. was responsible for the overall statistical design of the trial and overseeing the analysis of the programme. J.D.T. was responsible for the database. J.E.C. was responsible for updating the paper and overall management of the project. Acknowledgements: The authors thank the children, parents and schools for their involvement in the study.