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Measures of self-efficacy and norms for low-fat milk consumption are reliable and related to beverage consumption among 5th graders at school lunch

Published online by Cambridge University Press:  01 April 2008

Victoria J Thompson*
Affiliation:
The University of Texas, M.D. Anderson Cancer Center, Unit 182, 1515 Holcombe Boulevard, Houston, TX 77030, USA
Christine Bachman
Affiliation:
University of Houston, – Downtown, Houston, TX, USA
Kathy Watson
Affiliation:
Baylor College of Medicine, USDA/ARS Children’s Nutrition Research Center, Houston, TX, USA
Tom Baranowski
Affiliation:
Baylor College of Medicine, USDA/ARS Children’s Nutrition Research Center, Houston, TX, USA
Karen W Cullen
Affiliation:
Baylor College of Medicine, USDA/ARS Children’s Nutrition Research Center, Houston, TX, USA
*
Corresponding author: Email vthompso@mdanderson.org
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Abstract

Objective

To determine the reliability and validity of scales measuring low-fat milk consumption self-efficacy and norms during school lunch among a cohort of 5th graders.

Design

Two hundred and seventy-five students completed lunch food records and a psychosocial questionnaire measuring self-efficacy and norms for school lunch low-fat milk consumption during the fall and spring semesters of the 1998–1999 academic year. Test–retest reliability was assessed in participants who also completed the questionnaire in the spring semester (n = 262). Principal component analyses identified and confirmatory factor analyses confirmed latent variables. Bivariate correlations measured construct validity.

Setting

Houston-area middle school.

Subjects

Fifth graders (n = 275) from one middle school in southeast Texas.

Results

Two scales measuring psychosocial influences of low-fat milk consumption were identified and proved reliable in this population: milk self-efficacy and milk norms. Milk self-efficacy and norms were positively correlated with milk consumption and negatively correlated with consumption of sweetened beverages.

Conclusions

These questionnaires can be used in similar interventions to measure the impact of self-efficacy and norms for drinking low-fat milk during school lunch.

Type
Research Paper
Copyright
Copyright © The Authors 2007

Milk is a major dietary source of calcium in the USA and its consumption throughout childhood and adolescence is important to support growth and the development of optimal bone massReference Black, Williams, Jones and Goulding1Reference Volek, Gomez, Scheett, Sharman, French and Rubin3. Milk consumption has been associated with weight managementReference Zemel4, Reference Zemel and Miller5 and inversely associated with the consumption of sweetened beveragesReference Blum, Jacobsen and Donnelly6. Children with dental caries had lower intakes of milk as toddlers and young children than their counterparts without cariesReference Marshall, Levy, Broffitt, Warren, Eichenberger-Gilmore and Burns7. Inadequate milk consumption was related to inadequate intakes of vitamin A, folate, calcium, phosphorus and magnesiumReference Bowman8.

Despite the need for milk and calcium in development, milk intake declines from childhood to adolescenceReference Nielsen and Popkin9Reference Cullen and Zakeri12. Despite one serving of milk included in the National School Lunch Program (NSLP) meal, adolescent milk consumption declines even in the school environmentReference Cullen and Zakeri12, Reference Cullen, Eagan, Baranowski, Owens and de Moor13. This decline may be partly attributed to the competing alternatives available in à la carte bars and vending machines that students encounter in middle schoolReference Cullen and Zakeri12, Reference Cullen, Eagan, Baranowski, Owens and de Moor13.

Understanding the salient motivators and barriers to milk consumption among children and adolescents informs intervention design. Previous research has identified factors related to calcium and dairy consumption. These include age, gender, socio-economic status, body weight, taste preferencesReference Larson, Story, Wall and Neumark-Sztainer14, lactose intoleranceReference Auld, Boushey, Bock, Bruhn, Gabel and Gustafson15, soft drink intakeReference Harnack, Stang and Story16 and self-efficacyReference Larson, Story, Wall and Neumark-Sztainer14. One’s sense of self-efficacy (or confidence) may play a role in both drinking milk and overcoming barriers to drinking milkReference Bandura17. Self-efficacy motivates effort and persistenceReference Bandura18, Reference Garcia and Mann19. In addition, subjective norms – i.e. one’s judgement about whether or not others will approve of one’s behaviour – and social norms – i.e. one’s beliefs regarding the expected level of behaviour in a particular social contextReference Ajzen20 – may also influence milk consumption.

There has been some concern about the low predictiveness of dietary intake by psychosocial variables among children, since children do not always control the selection of what they eatReference Baranowski, Cullen and Baranowski21. In school, however, children exercise control over their beverage selection, particularly when students are transitioning from NSLP-only meals in elementary school to middle schools where snack bars are available. In the present study students were introduced to NSLP alternatives in the first semester of the 5th grade. The present observational study examined the reliability and validity of new scales of self-efficacy and norms regarding low-fat milk consumption during school lunch among 5th grade youth.

Methods

This observational study was approved by the Institutional Review Board of the University of Texas M.D. Anderson Cancer Center. It was part of a larger study, the objective of which was to examine the influence of school snack bars on fruit and vegetable and beverage intakes of middle-school studentsReference Cullen and Zakeri12, Reference Cullen, Eagan, Baranowski, Owens and de Moor13, Reference Thompson, Bachman, Baranowski and Cullen22.

Population

All 5th grade students (n = 422) from one 5th and 6th grade middle school in southeast Texas were invited to participate. Written parental consent and youth assent were obtained. Students attending this middle school had access to a snack bar/à la carte line and the NSLP meal. No school store was available. In 1998–1999, the district included 18% African-American, 24% Mexican-American, 57% Euro-American and 1% Asian/Other students. Approximately 24% of the students within the district were eligible for free/reduced-price meals. Study participants were 42% male; 13% were African-Americans, 27% Mexican-Americans, 49% Euro-Americans and 11% Asian/Other. Data were not collected on NSLP eligibility of participants.

Instruments and data collection

Food records

Students completed lunch food records for five consecutive days during the fall and spring semesters, for a total of 10 days of food records for the school year. These records were completed in the cafeteria or in the classroom after each lunch period, thereby minimising error of report due to time-related memoryReference Domel, Baranowski, Leonard, Davis, Riley and Baranowski23. Trained data collectors instructed students on how to properly and accurately complete the food records. Students listed each food item consumed during school lunch on separate blank lines, and indicated the number of servings consumed and the source (NSLP, snack bar, home). Immediately after students completed the food records and before the lunch period was over, data collectors checked the food records for missing data and ensured that all food items were described properly. Dietary data collection via food records has been shown to be validReference Domel, Baranowski, Leonard, Davis, Riley and Baranowski23. In accordance with the serving sizes (i.e. one serving = 8 oz milk; one serving = 12 oz sweetened beverages) of the 1998 Food Guide Pyramid, the food records were coded for milk (high-fat, i.e. whole flavoured or plain milk; or low-fat, i.e. 2% fat or less in flavoured or plain milk) and sweetened beverages (i.e. water-based beverages that contain sugar) by trained dietitians.

Psychosocial questionnaire

On the first day of each spring and fall data collection week and immediately following lunch, consented students also completed an 11-item questionnaire which asked questions related to influences on low-fat milk intake during school lunch. Specifically, the items were chosen to reflect self-efficacy for selecting and drinking milk during school lunch. The norms items reflect peer influence on drinking milk during school lunch. The overall Flesch/Kincaid readability score was at a 5.0 grade level. Self-efficacy was measured using a three-point response scale. Norms were measured with four-point scale items (Table 1).

Table 1 Scale indicators and factor loadings for the two-factor solution using principal component analysis (PCA) and confirmatory factor analyses (CFA)

† Responses for self-efficacy scale: ‘I cannot’ = 0; ‘a little sure I can’ = 1; ‘very sure I can’ = 2.

‡ The following item did not load on either scale: ‘Most kids my age think that drinking low-fat milk at school is…’ (responses: ‘a very good thing’, ‘a good thing’, ‘they don’t care’, ‘I don’t know’).

§Responses for norms scale: ‘never’ = 0; ‘sometimes’ = 1; ‘often’ = 2; ‘always’ = 3.

¶ Responses for norms scale: ‘they tell me not to’ = 0; ‘not at all’ = 1; ‘a little’ = 2; ‘a lot’ = 3.

∥ Cronbach’s α for CFA (spring 1999): milk self-efficacy = 0.92; milk norms = 0.60.

Data analyses

Data preparation

Analyses were conducted on data from the fall 1998 (n = 275) and spring 1999 (n = 262) semesters. Survey items were normalised to minimise the effects of using three- and four-category response scales. Items within scales were averaged for fall and spring, separately. All variables were normally distributed. Less than 5% of the data were missing and no obvious patterns existed among missing data.

Servings of milk and sweetened beverages (i.e. water-based beverages that contain sugar) were summed for each day and the mean across the five days of collection was calculated for each child at each of the two time intervals.

Reliability

The psychosocial questionnaire from fall 1998 (n = 275) was subject to principal component analysis (PCA) with Varimax rotation using SPSS 11.0. The number of factors to be retained was determined from the scree plot, factor loadings and the interpretability of resulting factors. Only items loading on a factor with a minimum factor loading of 0.40 were retained. Ten of the 11 items loaded on one of two factors: milk norms and milk self-efficacy (Table 1). Internal consistency and test–retest reliability of the two factors were analysed using Cronbach’s α and Pearson correlation, respectively. To assess whether the factor solutions were stable, factor patterns were examined using both measurement periods of the study (i.e. 1998 and 1999).

To measure the stability of beverage consumption, the intra-class correlation (ICC) of reliability was calculated for each of the dietary intake variables (i.e. sweetened beverages, total milk, high-fat milk, low-fat milk) for a single day and for the average over the five days of intake during the spring and the fall semesters, giving a total of two measures for each intake variable.

Measurement model

The 1999 dataset was used for confirmatory factor analyses (CFA) (i.e. to test the reliability of the 1998 PCA data) using AMOS 5.0Reference Arbuckle and Wothke24. CFA were conducted using the measurement model to determine how well the indicators loaded on the appropriate latent variable using the normalised 1999 datasetReference Hoyle, Panter and Hoyle25Reference Browne, Cudeck, Bollen and Long29. Interpretation of the association between the measured and latent variables, and the internal consistency of the scales, were used to determine inclusion of variables in the measurement models.

Construct validity

Using the fall 1998 data, bivariate Pearson correlations were performed to measure construct validity between the psychosocial factors and the consumption of sweetened beverages and low-fat milk.

Results

Consumption

Average student consumption of total milk and sweetened beverages at school lunch was less than half a serving per day (Table 2). Most milk consumed (80%) was low-fat. Using a single measure, the ICC reliabilities were low (range 0.46–0.57); however, when calculating ICC as an average across the five days of intake during each semester, the values ranged from 0.78 to 0.84 (Table 2).

Table 2 Mean (standard deviation) and intra-class correlation (ICC) for consumption of milk and sweetened beverages at school lunch

*ICC single and average values are the reliabilities associated with using a single measure and the average measure across the five days of assessment, respectively.

Reliability

Two factors were obtained. Internal reliabilities for the self-efficacy and norms scales were consistent for both datasets (i.e. 1998 and 1999) (Table 1). Test–retest for the self-efficacy and norms scales was 0.75 and 0.54, respectively (Table 1).

Using the 1999 normalised data, CFA confirmed a two-factor model of influences on milk consumption. The fit of the 10-item model was adequate and yielded , P < 0.001, comparative fit index = 0.98, root-mean-square error of approximation = 0.07. Three items loaded on norms, range 0.44 to 0.56. Seven items loaded on self-efficacy, range 0.66 to 0.86.

Construct validity

Milk self-efficacy was negatively correlated to the consumption of sweetened beverages (r = −0.34, P < 0.01) and positively correlated to total milk (r = 0.35, P < 0.01), low-fat milk (r = 0.30, P < 0.01) and high-fat milk (r = 0.15, P < 0.05) consumption. The milk norms scale was also negatively correlated with sweetened beverage consumption (r = −0.19, P < 0.01) and positively correlated to total milk (r = 0.20, P < 0.01) and low-fat milk consumption (r = 0.18, P < 0.01).

Discussion

This study examined the reliability and validity of questionnaires measuring school lunch self-efficacy and norms for low-fat milk consumption among 5th graders. CFA confirmed that the two factors emerging from the 1998 PCA loaded on the respective latent variables using the spring 1999 data. Since α is primarily a function of the number of items included in a scale, a higher value for internal reliability was expected for the self-efficacy scale than for the norms scale.

Although the reliability of a single day’s beverage intake was low, the reliability using the average across the five days was acceptable, indicating an acceptable level of stability in beverage consumption among the students. Because test–retest reliability values have declined within a few weeks in childrenReference Resnicow, Davis-Hearn, Smith, Baranowski, Lin and Baranowski30, the adequate values herein are somewhat surprising as the questionnaires were administered several months apart. While similar values have been noted in pre-school childrenReference Jaramillo, Yang, Hughes, Fisher, Morales and Nicklas31, the pre-school values represent food preferences which are relatively stable, even in childrenReference Skinner, Carruth, Wendy and Ziegler32. We found no test–retest values that examined school lunch self-efficacy and norms among students as they transitioned from NSLP-only school lunch to school lunch with NSLP-competing alternatives. Hence, the test–retest values reported in this study are of particular interest because these middle-school students were faced with making beverage choices each day. Equally noteworthy is that less than 5% of meals were brought from homeReference Cullen, Eagan, Baranowski, Owens and de Moor13, suggesting that students self-selected low-fat milk from the school cafeteria although whole milk was also available.

A more general understanding of the psychosocial factors influencing milk consumption among children and adolescents is derived from previous studies which measured influences and intake using food-frequency questionnairesReference Larson, Story, Wall and Neumark-Sztainer14, Reference Barr33. No study, however, was found that specifically examined consumption of low-fat milk during lunch at school, particularly when student norms may be changing to reflect a more competitive cafeteria environment. This more specific assessment provides insight into school-based intervention designs.

Self-efficacy assessed students’ confidence that they could consume low-fat milk during school lunch. Not surprisingly, students’ self-efficacy for low-fat milk consumption was negatively correlated to sweetened beverage consumption and positively correlated to total, high-fat and low-fat milk consumption. These findings underscore those of Larson et al.Reference Larson, Story, Wall and Neumark-Sztainer14 in which students’ self-efficacy to make healthy choices was related to dairy and calcium intakes. While the questionnaire referred to low-fat milk, perhaps students who selected whole milk ignored the distinction and completed the questions indicating their self-efficacy to choose milk.

Consistent with previous workReference Barr33, student norms regarding low-fat milk consumption during school lunch also predicted healthier eating habits. The results indicate that specific norms such as modelling, subjective norms and peer encouragement are positively related to healthy eating habits, particularly total milk consumption, during school lunch among 5th graders. The correlation between milk consumption and the three-item norms scale mirrors previousReference Barr33 findings that behavioural modelling, perceptions of others’ recommendations and use of milk influence milk consumption. In the present investigation these norms items were not predictive of high-fat milk consumption, possibly because high-fat milk consumption was so low, or suggesting that high-fat milk consumption at school is not influenced by social pressure or behavioural expectations as is low-fat milk consumption.

Several limitations should be noted. All data were from self-report, with potential errors from memory and estimation of portion sizes. The participants were from one school in southeast Texas, potentially limiting generalisability. Further, self-assessment of psychosocial influences, particularly norms, at this age and during this critical time of transition may be rather tenuous. Testing whether preferences mediated any of these relations may further elucidate the psychosocial influences. Future research should test these questionnaires with middle-school students in other areas of the country. Whether these constructs are important for youth in high school is also an important question for further study, given that sweetened beverage intake increases throughout the teen yearsReference Forshee and Storey10.

Of middle-school students who have to make beverage choices each day at school, to our knowledge this is the first study to simultaneously measure self-efficacy and norms with beverage intake. The potential roles for low-fat milk self-efficacy and norms for consuming low-fat milk are important in designing more effective interventions to increase low-fat milk and decrease sweetened beverage consumption. For example, schools could be encouraged to sponsor tasting of various types of low-fat milks, and provide posters and point-of-service advertisements to promote the low-fat choices. Students would have the opportunity to observe classmates consuming the low-fat milk. This would potentially reset the norm for low-fat milk consumption in middle schools. These questionnaires are available for use to measure the impact of these interventions on self-efficacy and norms.

Acknowledgements

Sources of funding: This work is a publication of the US Department of Agriculture (USDA)/Agricultural Research Service (ARS) Children’s Nutrition Research Center, Department of Pediatrics, Baylor College of Medicine and Texas Children’s Hospital, Houston, Texas. This project has been funded in part by federal funds from the USDA/ARS under Cooperative Agreement No. 58-6250-6001. The contents of this publication do not necessarily reflect the views or policies of the USDA, nor does mention of trade names, commercial products, or organisations imply endorsement by the US Government. This work was also supported by grants CA88511 and CA88511-01S1 from the National Cancer Institute.

Conflict of interest declaration: There are no conflicts of interest.

Authorship responsibilities: V.J.T. conducted data analyses and wrote the manuscript. C.B. participated in data analyses, particularly SEM, as well as manuscript developments. T.B. contributed to data analyses and interpretation, K.W.C., the principal investigator, conceived the study hypothesis and authored the grant. All co-authors made substantial contributions to data analysis, data interpretation and the writing of the manuscript.

Acknowledgements: The authors wish to thank Drs Virginia Kennedy, Asha Kapadia and Jeanne Martin of the University of Texas Health Science Center at Houston for their editorial comments.

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Figure 0

Table 1 Scale indicators and factor loadings for the two-factor solution using principal component analysis (PCA) and confirmatory factor analyses (CFA)

Figure 1

Table 2 Mean (standard deviation) and intra-class correlation (ICC) for consumption of milk and sweetened beverages at school lunch