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Nutrition composition of children’s meals in twenty-six large US chain restaurants

Published online by Cambridge University Press:  27 May 2020

Caroline G Dunn*
Affiliation:
Department of Health Policy and Management, Harvard T.H. Chan School of Public Health, Boston, MA, USA
Kelsey A Vercammen
Affiliation:
Department of Epidemiology, Harvard T.H. Chan School of Public Health, Boston, MA, USA
Johannah M Frelier
Affiliation:
Department of Health Policy and Management, Harvard T.H. Chan School of Public Health, Boston, MA, USA
Alyssa J Moran
Affiliation:
Department of Health Policy and Management, Johns Hopkins Bloomberg School of Public Health, Baltimore, MD, USA
Sara N Bleich
Affiliation:
Department of Health Policy and Management, Harvard T.H. Chan School of Public Health, Boston, MA, USA
*
*Corresponding author: Email cdunn@hsph.harvard.edu
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Abstract

Objective:

To compare the nutritional quality of children’s combination meals offered at large US chain restaurants characterised by three versions – default (advertised), minimum (lower-energy) and maximum (higher-energy).

Design:

We identified default children’s meals (n 92) from online restaurant menus, then constructed minimum and maximum versions using realistic additions, substitutions and/or portion size changes for existing menu items. Nutrition data were obtained from the MenuStat database. Bootstrapped linear models assessed nutrition differences between meal versions and the extent to which meal components (main dish, side dish, beverage) drove differences across versions. For each version, we examined the proportion of meals meeting the Guidelines for Responsible Food Marketing to Children.

Setting:

Twenty-six fast-food and fast-casual restaurants, in 2017.

Participants:

None.

Results:

Nutrient values differed significantly across meal versions for energy content (default 2443 kJ (584 kcal), minimum 1674 kJ (400 kcal), maximum 3314 kJ (792 kcal)), total fat (23, 17, 33 g), saturated fat (8, 6, 11 g), Na (1046, 915, 1287 mg) and sugar (35, 14, 51 g). The substitution of lower-energy beverages resulted in the greatest reduction in energy content (default to minimum, −418 kJ (−100 kcal)) and sugar (−20 g); choosing lower-energy side dishes resulted in the greatest reduction in total fat (default to minimum, −4 g), saturated fat (−1·1 g) and Na (−69 mg). Only 3 % of meals met guidelines for all nutrients.

Conclusions:

Realistic modifications to children’s combination meals using existing menu options can significantly alter a meal’s nutrient composition. Promoting lower-energy items as the default option, especially for beverages and side dishes, has a potential to reduce fat, saturated fat and/or sugar in children’s meals.

Type
Research paper
Copyright
© The Authors 2020

Children consume more energy content and have worse diet quality on days they eat at restaurants than on days they do not(Reference Powell and Nguyen1,Reference Schmidt, Affenito and Striegel-Moore2) . This is problematic given that more than one-third (36 %) of American children aged 2–19 years eat at fast-food restaurants on a typical day(3), and restaurant meals account for approximately 12 % of daily energy content and 35 % of added sugars and solid fats consumed by children(Reference Poti, Slining and Popkin4,Reference Vikraman, Fryar and Ogden5) . A growing body of work has examined trends in the nutritional quality of foods and beverages offered on children’s menus of large chain restaurants both within the United States(Reference Moran, Block and Goshev6Reference Mueller, Wilde and Folta12) and internationally(Reference Uechi13Reference Mazariegos, Chacon and Cole15). Research suggests that, despite public health recommendations and voluntary industry pledges(16), children’s menu items often exceed nutrition guidelines for energy content, total fat, saturated fat, Na and sugar, with little progress towards meeting recommendations or offering a substantially larger number of healthy options(Reference Moran, Block and Goshev6,Reference Deierlein, Peat and Claudio10Reference Mueller, Wilde and Folta12) . In addition to unhealthy individual menu items, children’s combination meals (i.e. bundled main dish, side dish and beverage at a discounted price) generally do not meet nutrition guidelines(Reference Sliwa, Anzman-Frasca and Lynskey7Reference Batada, Bruening and Marchlewicz9). Furthermore, despite recent increases in the proportion of healthy side or beverage items in advertised (default) children’s meals, these options still remain relatively uncommon (<20 % of meals)(Reference Mueller, Wilde and Folta12).

The restaurant industry may consider several approaches to provide healthier options for young customers, including reformulating existing recipes, introducing new healthier meals or including existing healthy menu items as defaults. Because it would likely require lesser resources (e.g. time, labour, money), replacing meal components with healthier default options from the existing menu may be the most desirable strategy. To ensure healthier default options, recent legislative action includes policies in California(17), Baltimore, MD(18), New York City(Reference Wootan19), Lafayette, CO(20), Wilmington, DE(Reference Tucker21), Louisville, KY(Reference Louisville22) and Hawaii(23) requiring restaurants to provide healthy default beverages in children’s meals. Given the strong status quo bias in restaurant ordering (i.e. customers are likely to select the default)(Reference Samuelson and Zeckhauser24,Reference Downs, Loewenstein and Wisdom25) , such legislation has a potential to improve public health without relying on individual behaviour change. However, legislative actions have almost exclusively applied to beverages, and little information is available to quantify the potential nutritional impacts of policies on other components of children’s meals.

Specifically, we lack an understanding of how simple modifications, such as substitutions, additions and portion size changes to existing offerings, can influence the nutrition composition of children’s combination meals; how meal components (main dish, side dish, beverage) might drive those changes; and how this knowledge could be operationalised to create children’s healthier default combination meals that meet nutrition guidelines. This is a key area of inquiry given that, while parents report they are more likely to purchase fast-food for their children based on a healthy kids meal policy(26), little progress has been made towards improving the nutrition composition of foods or meals(Reference Moran, Block and Goshev6Reference Kirkpatrick, Reedy and Kahle11).

The primary aims of the current study were to: (i) characterise the nutrition composition of three versions of children’s combination meals – default (as advertised on the menu), minimum (lower-energy) and maximum (higher-energy) – offered at large chain restaurants; (ii) examine the relative contribution of each meal component (main dish, side dish, beverage) to differences in nutrients across meal versions; and (iii) examine the proportion of children’s meal versions meeting the Guidelines for Responsible Food Marketing to Children recommendations on energy content, fat, saturated fat, Na and sugar(27).

Methods

Data

Restaurants eligible for inclusion were those included in MenuStat (n 94 in 2017), a database containing nutrition information on menu items offered at top-grossing restaurant chains (www.menustat.org)(28,29) . Restaurants were excluded if they (i) did not offer children’s combination meals (i.e. a bundled meal with ‘kid’, ‘children’ or ‘child’ in the description, containing a main dish, at least one side dish and a beverage; n 57); (ii) did not advertise a default version of the children’s combination meals (e.g. only offered ‘make your own’ options; n 9); or (iii) were missing children’s combination meals in MenuStat (n 2) (see online supplementary material; Appendix Fig. 1). The final restaurant sample included twenty-six restaurants (twenty-three fast-food, three fast-casual) (see online supplementary material; Appendix Table 1).

For each restaurant, we used online menus from the restaurant’s website to construct default (as advertised), minimum (lower-energy) and maximum (higher-energy) versions of each children’s combination meal (see online supplementary material; Appendix A for details on the creation of combination meals) in 2017. In summary, each default meal included a main dish, side dish and beverage; some meals included an additional side dish if those were part of the advertised meal. The minimum and maximum meal versions reflected realistic energy adjustments to the default meal, such as changing portion sizes (e.g. including a four-piece chicken instead of a six-piece one), substituting side dishes or beverages (e.g. replacing a sugary drink with a non-energetic alternative) or adding/removing toppings or dipping sauces to main dish or side dishes (e.g. adding mayonnaise to a sandwich; see online supplementary material; Appendix Tables 2 and 3). A codebook of rules described by Vercammen et al. (Reference Vercammen, Frelier and Moran30) was created to ensure consistency in identifying default meals and developing minimum and maximum combinations across all meals and restaurants (see online supplementary material; Appendix Table 4 for an example of a default, a minimum and a maximum version of a children’s meal).

At the item level (main dish, side dish, beverage and toppings/condiments), the components of each version were matched to nutrition information in the MenuStat database by restaurant and item description. Nutrition information for toppings/condiments was attributed to the meal component that they complemented (e.g. ketchup with fries was attributed to the side dish). Total nutrient values for each meal were calculated by summing across all components of the meal. If nutrition data were unavailable for an item in 2017, 2016 MenuStat values were used. If data were not available in 2016, missing values were manually entered using nutrition information from restaurant websites in 2018. After this step, complete data were available for a final sample of 276 distinct meals (ninety-two default, ninety-two minimum and ninety-two maximum versions). For a portion of the final sample (n 24, 9 % of total sample), nutrition data were only available for the full meal but not for the components.

Statistical analyses

Data were analysed using Stata, version 15 (StataCorp LLC)(31). Bootstrapped linear models (using fifty replications) with fixed effects for restaurant chain and meal version (default, minimum, maximum) were used to test for differences in nutrients of interest (i.e. energy content, grams of fat, grams of saturated fat, milligrams of Na and grams of sugar) between the default v. minimum and maximum meal versions. The unit of observation in these models was the combination meal; the primary outcome was the nutrient value of interest; and the primary predictor was the meal version. Fixed effects for restaurant chain were included to account for clustering of menu items within restaurants, and bootstrapping was used to account for the non-normality of residuals(Reference Efron, Kotz and Johnson32). The margins command was used to estimate predicted mean nutrient values for each meal version post-regression.

Next, bootstrapped linear models (using fifty replications) with fixed effects for restaurant and meal component type (main dish, side dish, beverage) were used to test the extent to which meal components contributed to differences in nutrients across meal versions. The unit of observation in these models was the meal component (i.e. main dish, beverage or side dish); the primary outcome was the difference between the default and minimum or maximum for each nutrient; and the primary predictor was an indicator for whether the meal component was a main dish, beverage or side dish. The margins command was used to estimate predicted mean differences in nutrients between the default and minimum or maximum for each meal component. Nutrition information was available for all individual meal components in 252 children’s combination meals (91 % of the final sample); meals without nutrient profiles for all individual components (n 24; 9 % of the total sample) were excluded from the analysis.

We also estimated the proportion of each meal version that met the Guidelines for Responsible Food Marketing to Children, developed by the Center for Science in the Public Interest (CSPI)(27). The guidelines provide nutritional criteria for food manufacturers, restaurants and organisations marketing foods to children, and state that children’s meals should include no more than 35 % of energy content from fat, 10 % of energy content from saturated fat, 770 mg of Na, 35 % of total energy content from added sugar and one-third of the daily recommended energy content for the average age of children targeted for the meal. For this analysis and consistent with a previous evaluation of children’s restaurant meals(8), we based our energetic standards on the recommendations for a moderately active child aged 4–8 years from the 2015–2020 Dietary Guidelines for Americans(Reference Zhong, Auchincloss and Lee33) of approximately 6276 kJ (1500 kcal) per day, which translates to 2092 kJ (500 kcals) per meal.

Results

Table 1 shows the predicted mean nutrient values for default, minimum and maximum combination meal versions. Nutrient values differed significantly (P < 0·05 for all) between default to minimum combination meal versions, and default to maximum versions for energy content (default 2443 kJ (584 kcal); minimum 1674 kJ (400 kcal); maximum 3314 kJ (792 kcal)), total fat (23, 17, 33 g), saturated fat (8, 6, 11 g), Na (1046, 915, 1287 mg) and sugar (35, 14, 51 g).

Table 1 Mean, standard deviation and range of nutrients in default, minimum and maximum combination meals

* Indicates significant difference in nutrient value of minimum compared to default nutrient value in bootstrapped linear model with fixed effects for each restaurant and combination meal type (P < 0·05).

Indicates significant difference in nutrient value of maximum compared to default nutrient value in bootstrapped linear model with fixed effects for each restaurant and combination meal type (P < 0·05).

Figure 1 depicts the mean contribution of each meal component to differences in energy content, total fat (g), saturated fat (g), Na (mg) and sugar (g) between the default v. minimum and default v. maximum meal versions (point estimates and 95 % CI included in the online supplementary material; Appendix Table 5). Beverages were the greatest driver of total energy reduction from default to minimum versions (−418 kJ (−100 kcal), 56 % of difference), followed by side dishes (−247 kJ (−59 kcal), 33 %) and main dishes (−84 kJ (−20 kcal), 11 %). Side dishes were the greatest driver of increased energy content from default to maximum versions (+536 kJ (+128 kcal), 59 %), followed by beverages (+243 kJ (+58 kcal), 27 %) and main dishes (+126 kJ (+30 kcal), 14 %). Side dishes contributed the most to changes in total fat (default to minimum: −3·5 g, 56 %; default to maximum: +7·5 g, 70 %), saturated fat (default to minimum: −1·1 g, 55 %; default to maximum: +2·3 g, 77 %) and Na (default to minimum: −69 mg, 54 %; default to maximum: +202 mg, 78 %). Finally, beverages were the largest contributor to changes in sugar (default to minimum: −20 g, 95 %; default to maximum: +16 g, 91 %).

aTwenty-four meals (9 % of the sample: eight default, eight minimum and eight maximum) were excluded from this analysis because nutrition information was only available for the entire meal in MenuStat, precluding our ability to examine how individual meal components drove differences in nutrient values across meal versions. bCalories (i.e. kilocalories; 1 kcal = 4·184 kJ). , beverage; , entrée; , side. *Significant difference at P < 0·05.

Fig. 1 Differences in predicted mean nutrient values for default v. maximum and minimum, by meal components (n 252 meals)a

Figure 2 includes the number and proportion of each type of meal meeting the CSPI Guidelines for Responsible Food Marketing to Children, using energetic recommendations for a moderately active child aged 4–8 years from the 2015–2020 Dietary Guidelines for Americans(Reference Zhong, Auchincloss and Lee33). Only eleven (12 %) minimum and three (3 %) default meal versions met all guidelines. No maximum versions of the meals met all of the guidelines. Notably, the majority of meals (default 86 %; minimum 98 %; maximum 87 %) met the guidelines for sugar; fewer met the guidelines for energy content (41, 75, 12 %), total fat (48, 47, 39 %), saturated fat (41, 42, 42 %) and Na (28, 41, 12 %).

aBased on the Dietary Guidelines for Americans (2015); approximately one-third of the daily requirement for a moderately active 4–8-year-old child. bCalories (i.e. kilocalories; 1 kcal = 4·184 kJ). Although recommendations are provided for added sugar, total sugar was used because added sugars were not available from MenuStat database. , default; , minimum; , maximum.

Fig. 2 Proportions of default, minimum and maximum meal versions meeting the Guidelines for Responsible Food Marketing to Children (n 276)

Discussion

Children’s default combination meals at large US chain restaurants were generally high in energy content, total fat, saturated fat and Na, and only 3 % of advertised meals met nutrition guidelines. We also found that nutrient values differed significantly across default, minimum and maximum meal versions, which suggests that changes to children’s combination meals using existing menu items could substantially alter nutrition composition. A closer look at the sources of variation indicated that considerable nutritional improvement could be realised by selecting a healthier side dish to reduce total fat, saturated fat or Na, and by substituting the default beverage to reduce energy content and sugar.

To our knowledge, three previous studies examined the extent to which children’s combination meals at US chain restaurants meet nutritional recommendations(Reference Sliwa, Anzman-Frasca and Lynskey7Reference Batada, Bruening and Marchlewicz9). Results from our study are most comparable to the 2013 CSPI report that also used the Guidelines for Responsible Food Marketing to Children(8) to evaluate 3494 meals from thirty-four chain restaurants. CSPI researchers also found that only 3 % of children’s combination meals met nutritional guidelines. However, our findings for individual nutrients diverge from CSPI’s findings. Most notably, the CSPI report found that only 14 % of meals met the standard for energy content, while our findings indicate that 41 % of default, 75 % of minimum and 12 % of maximum meals met this standard.

Our findings are similar to those of Batada et al. (Reference Batada, Bruening and Marchlewicz9), who reported that among 1662 possible children’s combination meals at twenty-two US chain restaurants, 1 % of meals met a set of nutritional standards based on the 2010 Dietary Guidelines for Americans(34). Contrary to our findings, Sliwa et al. (Reference Sliwa, Anzman-Frasca and Lynskey7) found that 32 % of 1363 children’s meals from ten quick-service restaurants met nutrition standards. However, the guidelines used by both Batada et al. (Reference Batada, Bruening and Marchlewicz9) and Sliwa et al. (Reference Sliwa, Anzman-Frasca and Lynskey7) were specified for a moderately active child aged 9–13, with higher thresholds for energy content, fat (measured as per cent energy content from fat) and saturated fat (measured as per cent energy content from saturated fat). Discrepancies between these two studies are likely due to the inclusion of additional nutrition standards (e.g. micronutrients) by Batada et al. (Reference Batada, Bruening and Marchlewicz9). Of note, had we selected a higher energetic threshold (such as the 2720 kJ (650 kcal) per meal maximum for children in kindergarten to grade 5 participating in the National School Lunch Program(35)), more combination meals would have met the guidelines for energy content. This means that our estimate of the proportion of meals meeting the energetic guideline is conservative.

In addition to differences in the standards used to assess nutritional quality, there are several reasons why our findings may diverge from previous studies. Differences may be due to the timeframe the data were collected (2012(8,Reference Batada, Bruening and Marchlewicz9) and 2014(Reference Sliwa, Anzman-Frasca and Lynskey7)v. our data collected in 2017), or to differences in the restaurants sampled (n 26 in our study, n 34 in the CSPI report(8), n 22 in Batada, et al. (Reference Batada, Bruening and Marchlewicz9), and n 10 fast-food services in Sliwa et al. (Reference Sliwa, Anzman-Frasca and Lynskey7)). Methodological differences in constructing meal versions may also account for divergent findings. Specifically, previous studies examined all possible children’s meal combinations, while our approach included constructing and assessing three distinct versions (default, minimum and maximum).

The construction of three meal versions using a detailed set of rules for reasonable alterations allowed us to examine how changes such as substitutions or portion size modifications account for variations in nutrition composition. Therefore, results provide specific examples of how realistic modifications to meal components can improve the default option and provide an estimate of the magnitude of those differences. The menu labelling provision of the Affordable Care Act, which was implemented in May 2018, requires that restaurants (among other retail establishments) with twenty or more locations disclose energetic information on the menu. For ‘variable items’ like combination meals, energy content may be listed as ranges (e.g. 1966–2469 kJ (470–590 kcals)), but guidance on how to construct ranges is vague, and restaurants are not required to disclose the compositions of meals they used to create the ranges(36). Therefore, it is not immediately apparent where a default meal would fall in the posted range, and restaurants are not required to post information on other nutrients of public health concern (e.g. Na, saturated fat), which, as we showed, can vary greatly with changes to the default. It is also unclear how meaningful energy ranges are when customers are making decisions about what to order(Reference Bleich, Economos and Spiker37). Because a tendency towards the status quo in restaurant ordering has been documented(Reference Samuelson and Zeckhauser24,Reference Downs, Loewenstein and Wisdom25) and evidence on the impact of energetic menu labelling remains inconclusive(Reference Bleich, Economos and Spiker37), changing healthy default options has the potential to improve diets without requiring individual behaviour change for the one-third of children who consume restaurant food daily(3).

While the federal guidance has suggested reformulation of existing items or the introduction of new items to meet health goals(Reference Zhong, Auchincloss and Lee33), our findings highlight that simple changes to default meals using existing menu options can substantially improve the nutrition of children’s meals. This approach would likely require lesser resources and, thus, may be favourable to the restaurant industry, but previous work has documented that restaurants participating in voluntary industry initiatives (e.g. the Kids LiveWell initiative from the National Restaurant Association, which was not active at the time of data collection and analysis; oral communication, March 2019) continue to serve meals and food items outside of industry-suggested standards(Reference Moran, Block and Goshev6,Reference Sliwa, Anzman-Frasca and Lynskey7,Reference Batada, Bruening and Marchlewicz9) .

If voluntary action is either ineffective or discontinued, legislative options may be needed to create meaningful changes. The current legislation focusing on improving default beverage options(1723) could substantially improve the nutritional profile of meals offered on children’s menus by reducing sugar and energy content. However, no legislation has focused on requiring a healthy side dish as the default, which could significantly reduce energy content, fat, saturated fat and Na – all of which are overconsumed by children(Reference Zhong, Auchincloss and Lee33). The substitution of healthy default beverages in place of sugary drinks may be preferable by the industry because it may require lesser resources than adjustments made to sides. Restaurants might comply with healthy default beverage laws by simply offering tap water as the default beverage, which requires no change to beverage contracts or supply chains, while the inclusion of fresh fruits or vegetables as side items may necessitate additional employee training, changes to procurement, increased food preparation time and increased storage capacity(Reference Ozdemir and Caliskan38,Reference Anzman-Frasca, Folta and Glenn39) . Moreover, restaurant executives may have concerns about low consumer demand for healthier items and subsequent decreases in revenue(Reference Anzman-Frasca, Folta and Glenn39), which may reduce voluntary compliance with such initiatives. Because children are viewed as vulnerable populations, policies regarding the inclusion or availability of children’s menu items may be met with less opposition than those targeting adult customers. However, any legislative action taken to alter options at restaurants is likely to be met with industry opposition and should be accompanied by clear guidance on acceptable items and meal combinations (e.g. agreement on nutrient limits or ranges; clear definitions of ‘healthy’) to facilitate compliance among industry leaders.

These findings should be interpreted with respect to several limitations. First, data were limited to twenty-six US chain restaurants with nutrition information available in the MenuStat database, and were confined by children’s combination meals listed on restaurant websites. This may limit the generalisability of results by not accounting for regional or seasonal combination meals and local or state policies that influence meal compositions (e.g. healthy beverage ordinances)(1723), or include independent, small chain or local establishments. Second, this analysis focused on creating meal versions that maximised and minimised energy content, but did not account for alterations that could maximise or minimise other nutrients such as Na or sugar. Third, the CSPI guidelines for fat and sugar are based on the overall energetic content of meals (i.e. per cent of energy content from fat and sugar), meaning higher-energy meals may have a greater likelihood of meeting recommendations while actually having higher absolute values of fat and sugar. For example, a 4184-kJ (1000-calorie) meal with 1423 kJ (340 calories) from sugar (34 %) would meet the sugar guideline of including <35 % energy content from sugar, while a 2092-kJ (500-calorie) meal with only 795 kJ (190 calories) from sugar (38 %) would not. Next, our analysis did not include purchase or consumption data, which limited our ability to infer population health impacts of our findings. Finally, the CSPI guidelines include a standard for added sugar – a nutrient of greater public health interest than total sugar. However, data on added sugar is not available in MenuStat; therefore, we reported findings on total sugar and may have underestimated the proportion of meals meeting this recommendation.

The current study also has several strengths, notably examining children’s combination meals across twenty-six large restaurant chains and the use of high-quality, publicly available nutrition data. Additionally, detailed rules for reasonable alterations to children’s meals to create minimum and maximum versions allowed for an in-depth analysis of how modifications may impact the nutritional profile of combination meals and facilitate an estimate for the effect of swapping current default items for healthier menu options.

This research suggests important areas for future inquiry. In particular, better data are needed to understand how often children order combination meal versions and the types of customisations they make. Further, more empirical evaluations (e.g. from natural experiments) are needed to assess the effects of changes to the default children’s combination meals on purchasing and consumption. For example, adjustments to children’s menus may have unintended consequences if young consumers react to healthy changes by ordering items from the adult menu, or may be less effective if children already do so. Some evidence suggests that parents are more likely to purchase fast-food if they believe it is healthier; thus, creating and publicising healthier meals could have an unintended consequence of increasing overall fast-food consumption(26). Future research should assess the cost-effectiveness of implementing changes to children’s menus from the perspectives of restaurants (who may incur higher food preparation and menu printing costs), consumers (who may face a burden if healthier offerings are more expensive) and the government (who would be responsible for monitoring and enforcement if menu changes are the result of a legislative process). Fast-food consumption remains high among minority, low-income populations(3) that are more likely to be overweight(Reference Ogden, Carroll and Lawman40); as such, future research should evaluate whether voluntary or legislative actions to improve children’s meals also address health equity.

Conclusion

Children’s default combination meals at large US chain restaurants are high in energy content, total fat, saturated fat and Na, and few default meals meet comprehensive nutrition guidelines. Realistic modifications – such as substituting default side dishes and beverages – could significantly alter the nutrition composition. Promoting existing healthier items as the default option, especially side dishes and beverages, holds promise for improving the nutrition composition of children’s meals. However, more research is needed to determine the impact of these changes on children’s meal orders and dietary intake.

Acknowledgements

Acknowledgements: None. Financial support: This research received no specific grant from any funding agency, commercial or not-for-profit sectors. Conflict of interest: The authors have no conflicts of interest relevant to this article. Authorship: C.G.D. contributed to the conceptualisation and data analysis of the article, and drafted the manuscript; K.A.V. contributed to design, data collection and data analysis; J.M.F. oversaw data collection and contributed to data analysis; A.J.M. participated in study design and data analysis; S.N.B. contributed to study conceptualisation and data collection; all authors reviewed and approved the final manuscript as submitted and agree to be accountable for all aspects of the work. Ethics of human subject participation: The current study did not involve human subjects.

Supplementary material

For supplementary material accompanying this article visit https://doi.org/10.1017/S1368980019004907

References

Powell, LM & Nguyen, BT (2013) Fast-food and full-service restaurant consumption among children and adolescents: effect on energy, beverage, and nutrient intake. JAMA Pediatr 167, 1420.10.1001/jamapediatrics.2013.417CrossRefGoogle ScholarPubMed
Schmidt, M, Affenito, SG, Striegel-Moore, Ret al. (2005) Fast-food intake and diet quality in black and white girls: the national heart, lung, and blood institute growth and health study. Arch Pediatr Adolesc Med 159, 626631.10.1001/archpedi.159.7.626CrossRefGoogle ScholarPubMed
(2018) Percentage of youths aged 2–19 years consuming any fast food on a given day, by race and Hispanic origin – National Health and Nutrition Examination Survey, 2013–2016. MMWR Morb Mortal Wkly Rep 67, 1134.10.15585/mmwr.mm6740a8CrossRefGoogle Scholar
Poti, JM, Slining, MM & Popkin, BM (2014) Where are kids getting their empty calories? Stores, schools, and fast-food restaurants each played an important role in empty calorie intake among US children during 2009–2010. J Acad Nutr Diet 114, 908917.CrossRefGoogle ScholarPubMed
Vikraman, S, Fryar, CD & Ogden, CL (2015) Caloric intake from fast food among children and adolescents in the United States, 2011–2012. NCHS Data Brief (213).Google Scholar
Moran, AJ, Block, JP, Goshev, SGet al. (2017) Trends in nutrient content of children’s menu items in U.S. chain restaurants. Am J Prev Med 52, 284291.10.1016/j.amepre.2016.11.007CrossRefGoogle ScholarPubMed
Sliwa, S, Anzman-Frasca, S, Lynskey, Vet al. (2016) Assessing the availability of healthier children’s meals at leading quick-service and full-service restaurants. J Nutr Educ Behav 48, 242–9.e1.CrossRefGoogle ScholarPubMed
Center for Science in the Public Interest (2013) Kids’ Meals II: Obesity and Poor Nutrition on the Menu. https://cspinet.org/sites/default/files/attachment/cspi-kids-meals-2013.pdf (accessed October 2019).Google Scholar
Batada, A, Bruening, M, Marchlewicz, EHet al. (2012) Poor nutrition on the menu: children’s meals at America’s top chain restaurants. Child Obes 8, 251254.CrossRefGoogle ScholarPubMed
Deierlein, AL, Peat, K & Claudio, L (2015) Comparison of the nutrient content of children’s menu items at US restaurant chains, 2010–2014. Nutr J 14, 80.10.1186/s12937-015-0066-4CrossRefGoogle ScholarPubMed
Kirkpatrick, SI, Reedy, J, Kahle, LLet al. (2014) Fast-food menu offerings vary in dietary quality, but are consistently poor. Public Health Nutr 17, 924931.CrossRefGoogle ScholarPubMed
Mueller, MP, Wilde, P, Folta, SCet al. (2019) Availability of healthier children’s menu items in the top selling quick service restaurant chains (2004–2015). Am J Public Health 109, 267269.10.2105/AJPH.2018.304800CrossRefGoogle Scholar
Uechi, K (2018) Nutritional quality of meals offered to children (kids’ meals) at chain restaurants in Japan. Public Health Nutr 21, 31013110.10.1017/S1368980018001891CrossRefGoogle ScholarPubMed
Young, M, Coppinger, T & Reeves, S (2019) The nutritional value of children’s menus in chain restaurants in the United Kingdom and Ireland. J Nutr Educ Behav 51, 817825.10.1016/j.jneb.2019.04.018CrossRefGoogle ScholarPubMed
Mazariegos, S, Chacon, V, Cole, Aet al. (2016) Nutritional quality and marketing strategies of fast food children’s combo meals in Guatemala. BMC Obes 3, 52.10.1186/s40608-016-0136-yCrossRefGoogle ScholarPubMed
National Restaurant Association (2017) Kids Live Well Program. http://kidslivewell.com/ (accessed October 2019).Google Scholar
California Senate Bill No. 1192 (2019) Healthy by Default Kid’s Meal Drinks. https://leginfo.legislature.ca.gov/faces/billTextClient.xhtml?bill_id=201720180SB1192 (accessed October 2019).Google Scholar
Baltimore Code 17-0152 (2019) Healthy Beverages for Children’s Meals. https://health.baltimorecity.gov/news/press-releases/2018–07–18-baltimore-city-healthy-kids-meals-bill-becomes-law (accessed October 2019).Google Scholar
Wootan, MG (2019) Healthy Kids’ Meal Movement Grows with Passage of New York City Bill 2019. https://cspinet.org/news/healthy-kids%E2%80%99-meal-movement-grows-passage-new-york-city-bill-20190328–0 (accessed October 2019).Google Scholar
Lafayette Colorado Ordinance No. 40 (2017) Enacting Article IX of Chapter 55 of the Municipal Code Establishing the Default Beverages Offered with Children’s Meals. https://www.cityoflafayette.com/DocumentCenter/View/24389/O-17–40 (accessed October 2019).Google Scholar
Tucker, L (2018) Council Approves Ordinance Requiring City Eateries to Offer Healthy Beverages as Default Drink for Kids’ Meals Wilmington, DE. https://www.wilmingtoncitycouncil.com/council-approves-ordinance-requiring-city-eateries-to-offer-healthy-beverages-as-default-drink-for-kids-meals/ (accessed October 2019).Google Scholar
Center for Science in the Public Interest (2019) Hawaii Governor Signs Kids’ Meal Bill; Delaware Measure Passes Legislature. https://cspinet.org/news/delaware-hawaii-kids-meal-bills-awaiting-governors-signatures-20190627 (accessed October 2019).Google Scholar
Samuelson, W & Zeckhauser, R (1988) Status quo bias in decision making. J Risk Uncertain 1, 759.10.1007/BF00055564CrossRefGoogle Scholar
Downs, JS, Loewenstein, G & Wisdom, J (2009) Strategies for promoting healthier food choices. Am Econ Rev 99, 159164.10.1257/aer.99.2.159CrossRefGoogle ScholarPubMed
UConn Rudd Center for Food Policy and Obesity. Parents’ Report of Fast-Food Purchases for Their Children: Have They Improved? http://uconnruddcenter.org/files/Fast%20food%20parents%20survey%20two%20pager_.pdf (accessed October 2019).Google Scholar
Center for Science in the Public Interest. Guidelines for Responsible Food Marketing to Children. https://cspinet.org/sites/default/files/attachment/marketingguidelines.pdf (accessed October 2019).Google Scholar
National Restaurant News (2017) 2017 Top 100: Data & Rankings Nation’s Restaurant News. https://www.nrn.com/data-research/top-100-restaurants (accessed October 2019).Google Scholar
NY City Department of Health and Mental Hygiene (2019) MenuStat Methods. http://menustat.org/Content/assets/pdfFile/MenuStat%20Data%20Completeness%20Documentation.pdf (accessed October 2019).Google Scholar
Vercammen, KA, Frelier, JM, Moran, AJet al. (2019) Calorie and nutrient profile of combination meals at U.S. fast food and fast casual restaurants. Am J Prev Med 57, e77e85. doi: 10.1016/j.amepre.2019.04.008.CrossRefGoogle ScholarPubMed
StataCorp (2017) Stata Statistical Software: Release 15. College Station, TX: StataCorp LLC.Google Scholar
Efron, B (1992) Bootstrap methods: another look at the jackknife. In Breakthroughs in Statistics, pp. 569593 [Kotz, S & Johnson, NL, editors]. New York, NY: Springer.CrossRefGoogle Scholar
Zhong, Y, Auchincloss, AH, Lee, BKet al. (2018) The short-term impacts of the Philadelphia beverage tax on beverage consumption. Am J Prev Med 55, 2634.CrossRefGoogle ScholarPubMed
USDA (2015) 2015–2020 Dietary Guidelines for Americans. Washington, DC: USDA.Google Scholar
USDA (2019) Lunch Meal Pattern 2019. Washington, DC: USDA.Google Scholar
U.S. Department of Health and Human Services (2016) A Labeling Guide for Restaurants and Retail Establishments Selling Away-from-Home Foods – Part II (Menu Labeling Requirements in Accordance with 21 CFR 101.11): Guidance for Industry. Washington, DC: DHHS.Google Scholar
Bleich, SN, Economos, CD, Spiker, MLet al. (2017) A systematic review of calorie labeling and modified calorie labeling interventions: impact on consumer and restaurant behavior. Obesity (Silver Spring) 25, 20182044.CrossRefGoogle ScholarPubMed
Ozdemir, B & Caliskan, O (2014) A review of literature on restaurant menus: specifying the managerial issues. Int J Gastron Food Sci 2, 313.CrossRefGoogle Scholar
Anzman-Frasca, S, Folta, SC, Glenn, MEet al. (2017) Healthier children’s meals in restaurants: an exploratory study to inform approaches that are acceptable across stakeholders. J Nutr Educ Behav 49, 285295.e1.10.1016/j.jneb.2016.11.009CrossRefGoogle ScholarPubMed
Ogden, CL, Carroll, MD, Lawman, HGet al. (2016) Trends in obesity prevalence among children and adolescents in the United States, 1988–1994 through 2013–2014. JAMA 315, 22922299.10.1001/jama.2016.6361CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Mean, standard deviation and range of nutrients in default, minimum and maximum combination meals

Figure 1

Fig. 1 Differences in predicted mean nutrient values for default v. maximum and minimum, by meal components (n 252 meals)a

aTwenty-four meals (9 % of the sample: eight default, eight minimum and eight maximum) were excluded from this analysis because nutrition information was only available for the entire meal in MenuStat, precluding our ability to examine how individual meal components drove differences in nutrient values across meal versions. bCalories (i.e. kilocalories; 1 kcal = 4·184 kJ). , beverage; , entrée; , side. *Significant difference at P
Figure 2

Fig. 2 Proportions of default, minimum and maximum meal versions meeting the Guidelines for Responsible Food Marketing to Children (n 276)

aBased on the Dietary Guidelines for Americans (2015); approximately one-third of the daily requirement for a moderately active 4–8-year-old child. bCalories (i.e. kilocalories; 1 kcal = 4·184 kJ). Although recommendations are provided for added sugar, total sugar was used because added sugars were not available from MenuStat database. , default; , minimum; , maximum.
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