Obesity is a major public health problem in many countries throughout the world, especially for the young population and for the poor(Reference Basset and Perl1). In Brazil, obesity and overweight have been increasingly common in adults(Reference Monteiro, Conde and Popkin2), as well as in adolescents(Reference Veiga, da Cunha and Sichieri3). Dietary interventions that could prevent excessive weight gain in adolescents are fundamental to curb this epidemic.
School is considered a suitable setting for the promotion of healthy lifestyles in children(Reference Warren, Henry, Lightowler, Bradshaw and Perwaiz4, Reference Atkinson and Nitzke5). For obesity prevention many programmes have been tested among schoolchildren. Usually, these programmes have multiple focuses, including physical activity and nutritional behaviours, and most of them have attained good results in educating children on these issues(Reference Gortmaker, Peterson, Wiecha, Sobol, Dixit, Fox and Laird6, Reference Stice, Shaw and Marti7), but with little or no effect on weight change(Reference Stice, Shaw and Marti7, Reference Katz, O’Connell, Njike, Yeh and Nawaz8). On the other hand, a randomised trial with British schoolchildren with a focus on reduction of carbonated sodas showed a statistically significant and clinically relevant reduction in the weight gain in the experimental group compared with controls(Reference James, Thomas, Cavan and Kerr9). The strategy for the study was to reduce overall energy intake by the substitution of sugar-sweetened beverages for non-caloric drinks. Several educational activities were employed in order to incorporate this message. Two other longitudinal studies conducted in the USA observed increased BMI and prevalence of overweight associated with sugar-sweetened beverages(Reference Ludwig, Peterson and Gortmaker10–Reference Striegel-Moore, Thompson and Affenito12), and a review of sugar-sweetened carbonated beverages linked their intake to weight gain in both children and adults(Reference Malik, Schulze and Hu13).
Although some educators think that schools already have too much to do, and that prevention of obesity should not be expected to be an added responsibility(Reference Sutton14), school is considered an important part in the effort to prevent childhood obesity(Reference Story, Kaphingst and French15). Also, in countries such as Brazil, public schools are one of the few public institutions that reach the majority in the low socio-economic groups. The result of the British study(Reference James, Thomas, Cavan and Kerr9) is particularly important for developing countries, since it was based only on sugar-sweetened carbonated beverages. The result of this intervention can be more appealing for public health programmes compared with the usually more successful school interventions, which are comprehensive in nature(Reference Katz, O’Connell, Njike, Yeh and Nawaz8) and harder to be implemented in most countries.
The aim of the present study was to determine whether a school-based intervention addressing the issue of a healthy lifestyle aimed at discouraging adolescents from drinking sugar-sweetened carbonated beverages could prevent excessive weight gain.
Methods
A cluster randomised controlled trial of fourth graders from twenty-two public schools in the metropolitan city of Niterói, Rio de Janeiro, Brazil, was conducted from March to December 2005. Most students in the public schools are from families of low socio-economic level. Children go to school either in the morning (08.00–12.00 hours) or in the afternoon (13.00–17.00 hours). Only morning classes were included in the study. Families of fourth grade children (most of them 10 and 11 years old) were informed of the study and only those children with informed consent given by the parents were included in the study, but all of them received information as well as baseball caps and water bottles with the campaign logo.
Sample size
Sample size was estimated based on data from a previous study conducted in the same geographical area, for which the standard deviation of sugar-sweetened beverages consumption was 1·49 cups per day. In order to detect a difference of 0·5 glass of sugar-sweetened beverages between the two groups with a power of 80 % and a 5 % significance level, the sample size needed to be of 140 children in each arm of the trial. This sample size would also allow the detection of a difference of about 1 unit in BMI. Due to the cluster design (classes) and anticipating a rate of parental agreement of around 80 %, the sample size was set at 600 students. Since the school principals did not agree to select only one class of fourth graders, all classes were included, increasing the sample size to 1166 children, in forty-seven classes from twenty-two schools (Fig. 1). Schools, instead of classes, were randomised to reduce contamination of the intervention. We began the study by ranking schools based on the prevalence of overweight and of obesity, and randomisation was generated by blocking of four schools. The last two in the list were randomly assigned to intervention or control groups, balancing the groups by BMI.
Intervention
The intervention evaluated in the present study focused on the reduction in consumption of sugar-sweetened carbonated beverages by students. During seven months of one school year, a healthy lifestyle education programme was implemented using simple messages encouraging water consumption instead of sugar-sweetened carbonated beverages. The messages were previously tested for understanding in two small groups of children of the same age and socio-economic background as the study participants. Also, beliefs and behaviours of children in these focus groups were recorded in order to orient activities and the production of printed materials to be given to participants. Education was delivered via classroom activities; banners were hung promoting water consumption, and water bottles with the logo of the campaign were given to children and schoolteachers.
All children in the intervention classes were taught the importance of drinking water and asked to make drawings and songs about water and how much the body needs it. The main strategy was to convey the message that drinking water is positive. The body needs water and water should be drunk frequently. A ‘pyramid of drinking’ was created to communicate the message that water (the basis of the pyramid) should take prevalence over sugar-sweetened beverages (at the top of the pyramid). The centre of the campaign was to encourage the exchange of sugar-sweetened beverages for water. Ten one-hour sessions of activities facilitated by four trained research assistants were assigned for each class. The activities required 20–30 min and teachers were encouraged to reiterate the message during their lesson. Classroom quizzes and games using water v. sugar-sweetened carbonated beverages as the theme, as well as song and drawing competitions, were promoted. In addition, a musician using a tambourine helped each class to collectively develop songs related to drinking water and reducing the consumption of sugar-sweetened carbonated beverages. This musical activity was conducted during three one-hour sessions. The four research assistants and the musician received printed instructions and orientation on how to facilitate the activities.
The control group received only two one-hour general sessions on health issues and printed general advices regarding healthy diets.
Beverage intake measurement
Beverage intake was measured through one 24 h recall at baseline and another at the end of the trial. At baseline, following the 24 h recall, children were also asked about usual frequency of intake of beverages using a short questionnaire with the previous month as the time frame. The questionnaire included sugar-sweetened carbonated beverages (regular and diet), other sugar-sweetened beverages (regular and diet), milk, 100 % fruit juices (referred from now on simply as fruit juice) and powdered flavoured beverages containing sugar. Only five children reported the consumption of diet drinks.
The 24 h recall and answers to the short questionnaire were obtained by nutritionists during in-person interviews with the children at school.
Main outcome
Weight variation was measured by change in mean BMI (BMI = weight (kg)/height (m2)). Anthropometric measurements were taken at the beginning and at the end of the school year. Height (without shoes) was measured to the nearest 0·1 cm using a portable anthropometer. Weight (in light clothing) was measured to the nearest 0·1 kg on portable scales.
Secondary outcomes
Overweight and obesity, defined using the BMI cutoffs proposed by Cole et al. (2000)(Reference Cole, Bellizzi, Flegal and Dietz16), was also examined, since some studies have found changes in body mass following intervention only among those overweight at baseline, and mainly among girls(Reference Gortmaker, Peterson, Wiecha, Sobol, Dixit, Fox and Laird6, Reference Katz, O’Connell, Njike, Yeh and Nawaz8). Underweight was defined based on WHO (1995) criteria(17).
Data analysis
Data from 24 h recall were computed for all beverages and total added sugar. Schools serve two meals daily for free: breakfast and lunch. The meals are the same for every student, which makes it easy for recording purposes, since children need to only report the portions they consumed. Following the interview by the nutritionist, the reports of items eaten at or out of school were reviewed for adequate description, preparation and their portions. A software containing usual portion sizes developed for analysing Brazilian dietary intake data was used, Programa de Apoio a Nutriçao – NutWin version 2·0 (Departamento de Informática em Saúde, Universidade Federal de Sao Paulo, Brazil).
Regarding the short-frequency questionnaire, the total frequency of intake was estimated using frequency values that ranged from ‘zero’ to ‘three per day.’ The questionnaire includes seven exclusive categories, raging from ‘3 or more per day’ to ‘never or almost never.’
Statistical analysis
Baseline characteristics of the two groups were compared using either the Student’s t test or the χ 2 test. Data on those students who completed the study were compared (baseline v. after intervention) using paired t-tests. Intention-to-treat analysis was also performed using longitudinal analysis taking into account the cluster (classes) effect through mixed models(Reference Singer and Willett18). Data were analysed using SAS, version 8·2 (SAS Institute Inc., Cary, NC, USA). Two analyses were conducted: (i) change in BMI, therefore only data on completers were included; and (ii) modelling the change of BMI using all data. BMI was log-transformed because BMI distribution was skewed to the right. Correlation between the intake of juices and beverages and the intake of added sugars based on 24 h recall was calculated through the Spearman correlation coefficient.
Individuals were the unit of analysis for anthropometric variables. However, for changes in beverage consumption, the mean beverage intake of classes was used instead of individual data since 24 h is a good estimate for a group but not for individuals.
Results
Consent was given by most of the parents. Only twenty-six students refused or did not return the informed consent. Loss to follow-up added up to 18 %. Children out of the age range of between 9 and 12 years were allowed to participate but they did not contribute data. The mean follow-up time was slightly greater in the control group (8·24 months v. 7·96 months; P value = 0·02) and the percentage of students followed was slightly greater in the intervention group (82·5 % v. 81·1 % in the control group) (Fig. 1). A large number of children participated in the trial, but some of them did not agree to be interviewed for the 24 h recall at baseline and at the end of the study, with 85 % answering the 24 h recall at baseline, and 86 % of those followed also answered the 24 h recall at the end of the study. Anthropometric indices between those students with follow-up data on intake compared with those who refused to participate were similar for BMI (18·1 v. 18·3 kg/m2; t test P value = 0·43).
Groups were similar at baseline for age, sex, race, anthropometric measurements and beverage intake (Table 1a). The intracluster correlation coefficient for BMI was 0·024. At baseline, the intake of sugar-sweetened beverages was reported by 53 % of participants in the 24 h recall. The mean amount of carbonated beverages reported was 547 ml, which was greater than the amount of juices reported, which varied from 388 ml for powdered juice to 404 ml for fresh or concentrated juice (Table 1b).
*WHO (1995)(17).†Cole et al. (2000)(Reference Cole, Bellizzi, Flegal and Dietz16). ‡Only five students reported consumption of diet or light beverages.
Twenty-five students reported drinking juices and powdered flavoured beverages only, and 224 reported in the 24 h recall drinking both sugar-sweetened beverages and juices. The correlation coefficient between added sugar, for those 651 students reporting sugar intake in the previous day, was 0·34 (P < 0·0001) with the amount of juice/powdered flavoured beverages intake, and −0·15 (P < 0·0001) with amount of carbonated beverages intake.
The questionnaire regarding the usual intake of beverages in the previous month indicated that 98·8 % drink sugar-sweetened beverages with a daily intake frequency of 0·62.
At the end of the study, BMI and weight had increased in both groups and the mean intake of sodas per class was reduced in both groups, with reduction being about four times greater in the intervention compared with the control group (−69 ml v.−13 ml) (Table 2). The overall change in the BMI was not statistically significant between the two groups even after adjusting for age and time of follow-up. However, among those students overweight at baseline, the intervention group showed greater BMI reduction, and this difference was statistically significant among girls (P = 0·009; Table 3).
*Proc mixed models taking into account the cluster effect.
For both groups, obesity changed from about 4 to 4·5 % (Table 4). Carbonated beverage intake was significantly reduced in the intervention group compared with the control group, but fruit juice consumption was slightly increased in the intervention group (P = 0·08); for those who had not reported intake it was assumed to be zero (Table 4).
*Cole et al. (2000)(Reference Cole, Bellizzi, Flegal and Dietz16).
†χ 2 or t test at the end of the study.
‡For those not reporting intake, value was set 0.
Discussion
Soda intake has grown more than 400 % in the last three decades in Brazil(Reference Levy-Costa, Sichieri, Pontes and Monteiro19), and now there are many low-cost brands of soda available for the low-income population. We anticipated that this scenario would be adequate to test the hypothesis that the discouragement of intake of carbonated beverages would prevent excessive weight gain, but this single message was not effective in reducing excessive weight gain. However, we found a statistically significant decrease in BMI among overweight or obese girls at baseline, even though their sample size was small. Other studies have shown that gender and baseline BMI may explain better the changes in body weight associated with sugar-sweetened beverages(Reference Gibson and Neate20).
Overall baseline intake of carbonated drinks in the English study was slightly greater (approximately two glasses per day), whereas the mean baseline daily intake in our study was one and a half glasses, and 50 % of the students at baseline in our trial did not drink carbonated beverages.
We anticipated a reduction of consumption of half a glass of sodas per student per day, but our results showed a statistically significant reduction in soda intake of 66 ml in the intervention group compared with the control group (0·25 glasses). However, because of the large sample size in our study, this small change may have contributed to the overall negative findings. Also, the small self-reported change, representing about a 10 % reduction of baseline intake, was associated with compensation due to an increase in juices. The changes in consumption indicate that future interventions should allow exchanges to low sugar products, instead of a too big switch such as, in this case, to plain water.
A limitation in the study was the use of one 24 h recall, which is not the best method to measure intake. During the pre-test, a 3 d diary was used, but most children did not return them or brought them with highly incomplete data. Nevertheless, one 24 h recall provides a good estimation of group intake (classes)(Reference Buzzard21). Also, at baseline, the usual frequency of beverage intake measured by a frequency questionnaire indicated that 98 % of students drink sodas with a daily frequency of 0·62, a value that is close to the 53 % reported use in the previous day, measured by the 24 h recall.
The negative finding of the study may also be due to slight family involvement. Meeting with the parents was attempted at the beginning of the study without success, so we only sent them fliers and a fridge magnet to remind them of cutting down on carbonated beverages. Also, the intervention may not have been sufficiently intense or long enough to change behaviour. In addition, the reduction in drinking sugar-sweetened carbonated beverages as reported by students was combined with an increase in juice intake, which suggests that juices may have blurred the effects of soda reduction. A trend of substitution of sodas by juices or flavoured beverages has been observed in the USA(Reference Cavadini, Siega-Riz and Popkin22). Powdered fruit-flavoured drinks are very inexpensive in Brazil, and our data showed that the amount of sugar added per day in these beverages is greater than the amount of sugar in one glass of soda. The mean of sugar added was 34·5 g/d, whereas 250 ml of soda has 26 g of sugar.
Although the results from a systematic review indicate that regular sugar-sweetened beverage consumption is associated with weight gain(Reference Malik, Schulze and Hu13), in a large national survey – UK National Dietary and Nutritional Survey of Young People – using weighed 7 d food records, the risk associated with caloric soft drinks was non-linear with an increased risk only for very high consumers(Reference Gibson and Neate20), not frequent in our population.
Strategies of primary prevention of obesity that may prove effective, mainly among low socio-economic groups, are desperately needed and may be mandatory in developing countries given the burden associated with chronic diseases related to obesity. Unfortunately, the single message of cutting down on sodas was effective only among overweight girls, suggesting that efforts to reduce energy intake though liquids should also emphasise overall sweetened beverages, including the addition of sugar to juices.
Acknowledgements
Funding support: The study was supported by the Brazilian National Research Council – CNPq. Grant number: 500404/2003-8 – CNPq.
Conflict of interest: None.
Authors’ contributions: R.S. was the principal investigator, led the research project and participated in all phases of the study. G.V.V. was a co-investigator of the project and participated in conceptualisation of the intervention and collaborated in the manuscript. A.P.T. and R.A.S. conducted the analysis and collaborated in the manuscript.
Acknowledgements: We thank Walter Willett for helpful comments in the project and manuscript, and Fernanda Albuquerque Melo Nogueira, Flavia de Andrade Borges and Maria Eliza Mattos T. Mastrangelo for helping in the intervention and data collection.