untitled


Public Health Nutrition: 18(2), 361–371 doi:10.1017/S1368980014000305

Impact of a Smarter Lunchroom intervention on food selection
and consumption among adolescents and young adults with
intellectual and developmental disabilities in a residential
school setting

Kristie L Hubbard1,*, Linda G Bandini2,3, Sara C Folta1, Brian Wansink4, Misha
Eliasziw5 and Aviva Must5
1Friedman School of Nutrition Science and Policy, Tufts University, 150 Harrison Avenue, Boston, MA 02111,
USA: 2Eunice Kennedy Shriver Center, University of Massachusetts Medical School, Waltham, MA, USA:
3Department of Health Sciences, Boston University, Boston, MA, USA: 4Dyson School of Applied Economics and
Management, Cornell University, Ithaca, NY, USA: 5Department of Public Health and Community Medicine, Tufts
University School of Medicine, Boston, MA, USA

Submitted 19 April 2013: Final revision received 18 November 2013: Accepted 4 February 2014: First published online 17 March 2014

Abstract

Objective: To assess whether a Smarter Lunchroom intervention based on beha-
vioural economics and adapted for students with intellectual and developmental
disabilities would increase the selection and consumption of fruits, vegetables and
whole grains, and reduce the selection and consumption of refined grains.
Design: The 3-month intervention took place at a residential school between
March and June 2012. The evaluation employed a quasi-experimental, pre–post
design comparing five matched days of dietary data. Selection and plate waste of
foods at lunch were assessed using digital photography. Consumption was
estimated from plate waste.
Setting: Massachusetts, USA.
Subjects: Students (n 43) aged 11–22 years with intellectual and developmental
disabilities attending a residential school.
Results: Daily selection of whole grains increased by a mean of 0?44 servings
(baseline 1?62 servings, P 5 0?005) and refined grains decreased by a mean of
0?33 servings (baseline 0?82 servings, P 5 0?005). The daily consumption of fruits
increased by a mean of 0?18 servings (baseline 0?39 servings, P 5 0?008), whole
grains increased by 0?38 servings (baseline 1?44 servings, P 5 0?008) and refined
grains decreased by a mean of 0?31 servings (baseline 0?68 servings, P 5 0?004).
Total kilojoules and total gram weight of food selected and consumed were
unchanged. Fruit (P 5 0?04) and vegetable (P 5 0?03) plate waste decreased.
Conclusions: A Smarter Lunchroom intervention significantly increased whole
grain selection and consumption, reduced refined grain selection and con-
sumption, increased fruit consumption, and reduced fruit and vegetable plate
waste. Nudge approaches may be effective for improving the food selection and
consumption habits of adolescents and young adults with intellectual and
developmental disabilities.

Keywords
Adolescence

Health promotion
Intellectual disability

Developmental disability

Population-based data from the USA
(1–3)

and Australia
(4)

indicate that youth with intellectual and developmental

disabilities (I/DD) are at an increased risk of obesity. A

higher prevalence of obesity has been reported among

non-representative samples of youth with spina bifida(5),

cerebral palsy(6,7), Down’s syndrome(8) and intellectual

disability(9–12). Obesity among youth with I/DD may

undermine their ability to live independently, limit future

opportunities for employment, and may contribute to

health disparities in adulthood(13).

Youth with I/DD are more vulnerable to poor diet quality

compared with typically developing children due to their

complex medical, physical and behavioural challenges

(i.e. medication use, cognitive impairments, eating pro-

blems)(14–16). Compared with typically developing peers,

youth with I/DD, including children with autism spectrum

disorder, consume fewer daily servings of fruits and

vegetables
(17,18)

and these outcomes have a positive

association with lower family income
(18)

. Schools repre-

sent ideal environments for public health interventions to

*Corresponding author: Email usherkristie@gmail.com r The Authors 2014

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improve population-level dietary patterns of children and

adolescents(19). Little is known about the extent to which

youth with I/DD have been included in school-based

efforts to improve dietary intake(20).

Behavioural economics and principles of behavioural

science that guide recent efforts to ‘steer students to

better choices by making low or no-cost changes to the

cafeteria environment’ are termed the Smarter Lunchroom

Movement. When redesigning lunchrooms to be smarter,

how food is served and presented to students is modi-

fied rather than emphasizing extreme changes to what

foods are served(21). This approach preserves autonomous

choice – a central tenet of health promotion for youth with

I/DD(22). The six principles of Smarter Lunchroom design

include efforts to: (i) manage portion sizes; (ii) make

healthy choices more convenient; (iii) improve visibility

of healthier foods; (iv) enhance taste expectations;

(v) utilize suggestive selling (prompts); and (vi) use smart

pricing and bundling strategies(23). Smarter Lunchroom

interventions have improved fruit and vegetable selection

and consumption among typically developing high-school

students(24), but these strategies have not been tested

specifically among youth with I/DD. Furthermore, no pub-

lished research has addressed whether youth with I/DD in

residential education settings can benefit from adaptations

to evidenced-based health promotion strategies that have

proved successful among typically developing youth in

regular education settings.

The present study adapted these Smarter Lunchroom

principles to meet the needs of students with I/DD

enrolled in a residential school. Outcomes of interest,

established a priori, aligned with new federal nutrition

standards for school lunch(25), addressed dietary deficits

common among youth, and included improvements in

the selection and consumption of fruits, vegetables,

whole grains and refined grains based on the number of

servings. The evaluation employed a pre–post quasi-

experimental design in which five days of matched diet-

ary data were compared between baseline and follow-up

to assess changes at the individual level(26). We hypo-

thesized that the intervention would increase students’

selection and consumption of fruits, vegetables and

whole grains, and decrease their selection and con-

sumption of refined grains, over a 3-month period.

Methods

Setting

Of the 6?5 million students with disabilities served

through the Individuals with Disabilities Education Act

(IDEA) in the USA, 3?4 % are served in private specialized

day and/or residential programmes (2008 data)
(27)

. Under

IDEA, the right to a free and public education in the ‘least

restrictive environment’ provides that separate schooling

in private programmes occurs only when the nature or

severity of the disability is such that education in regular

classes cannot be achieved satisfactorily. The interven-

tion was implemented in Massachusetts at a private

specialized residential school for students with I/DD

between December 2011 and June 2012. The school

served 120 students aged 9–22 years with I/DD and a

range of secondary emotional, mental health and beha-

vioural conditions including autism spectrum disorder.

Eighty-eight students lived at the school (i.e. residential)

and thirty-two attended the day programme only. Eighty

per cent of students’ families were at or below the federal

poverty level. Students aged 9–18 years were enrolled in

the education programme and grouped into classrooms

by age and functional ability; students aged 18–22 were

enrolled in the vocation programme to focus on job

training and grouped according to job site. The student to

teacher ratio was 3 to 1.

Recruitment

The study was conducted according to the guidelines

established in the Declaration of Helsinki and all proce-

dures involving human subjects were approved by the

Tufts University Institutional Review Board. At the school

administrators’ request, all students participated in the

intervention to avoid disruptions in daily routines. The

research aspect was limited to the pre–post evaluation

of the selection and plate waste of foods at lunch using

digital photography. The licensing policy of the school

stipulated students classified as wards of the state (n 20)

were ineligible to participate in the research aspects of

the intervention. Recruitment letters were sent to the

families of the remaining eligible students (n 100). Written

parental permission to participate in the research aspect

(evaluation) was received for fifty-one students. Assent to

participate in the evaluation was obtained from partici-

pants via classroom visits. Participants were told that

pictures would be taken of their tray before and after they

ate lunch to help us learn more about students’ eating

habits. Participants were aware that they could stop

participating at any time and were free to decline having

the food photographs taken of their lunch tray on each

day of data collection.

Baseline conditions

Formative research was conducted between December

2011 and February 2012 and is described elsewhere(28).

Baseline data were collected in February 2012 prior to

any dining hall layout changes. The school participated

in the School Breakfast and National School Lunch

Programs, with breakfast and dinner provided in the

residential housing units. The intervention focused on the

lunch meal, served daily in the dining hall from 10.45 to

12.00 hours. School food service followed a seasonal

three-week cycle menu. Table 1 displays week 1 of the

baseline menu. The order of choices in the serving line at

baseline was as follows: (i) peanut butter and jelly

362 KL Hubbard et al.

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Table 1 Menu at baseline

Monday Tuesday Wednesday Thursday Friday

Entrée 1 with bundled side
Entrée Asian chicken salad Veggie burger on whole-wheat

bun
Steak and blue cheese salad

with whole-wheat roll
Sausage gumbo over brown

rice
Tuna caprese salad with

flatbread crackers
Bundled side dish Mediterranean mix (tomatoes,

cucumbers, feta cheese)
Entrée 2 with bundled side

Entrée Grilled mozzarella cheese
sandwich on whole-wheat
bread

Barbeque turkey tips with corn
bread

Popcorn chicken Roasted turkey wrap with
spinach and tomato

Pizza on whole-grain crust

Bundled side dish Baby carrots Baby spinach side salad with
cucumbers and grape
tomatoes

Cucumbers and carrots with
dip

Whole grain goldfish Garden greens side salad

Soup Turkey wild rice cranberry
soup

Vegetable soup Tuscan soup Chicken noodle Florentine
soup

Roasted garlic rosemary
chowder

Dessert Chocolate pudding with
whipped topping

Yellow cake with chocolate
frosting

Homemade trail-mix

Canned fruit Canned peaches Fruit cocktail
Whole fresh fruit Apples Apples Apples Apples Apples

Bananas Bananas Bananas Bananas Bananas
Oranges Oranges Oranges Oranges Oranges

Yoghurt 4 oz low-fat 4 oz low-fat 4 oz low-fat 4 oz low-fat 4 oz low-fat
Milk Skimmed, 1 %, Lactaid (white

only)
Skimmed, 1 %, Lactaid (white

only)
Skimmed, 1 %, Lactaid (white

only)
Skimmed, 1 %, Lactaid (white

only)
Skimmed, 1 %, Lactaid

(white only)
Alternative entrée with

bundled side dish
Peanut butter and jelly

sandwich on white bread
with side of pretzels

Peanut butter and jelly
sandwich on white bread
with side of pretzels

Peanut butter and jelly
sandwich on white bread
with side of pretzels

Peanut butter and jelly
sandwich on white bread
with side of pretzels

Peanut butter and jelly
sandwich on white bread
with side of pretzels

Condiments Saltine crackers Saltine crackers Saltine crackers Saltine crackers Saltine crackers
Ketchup Ketchup Ketchup Ketchup Ketchup
Mustard Mustard Mustard Mustard Mustard
Mayonnaise Mayonnaise Mayonnaise Mayonnaise Mayonnaise
Butter Butter Butter Butter Butter
Margarine Margarine Margarine Margarine Margarine

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sandwiches on white bread served with a corresponding

side of pretzels; (ii) soup; (iii) main entrée option 1 with a

corresponding side dish; (iv) main entrée option 2 with

corresponding side dish; (v) fresh fruit (apples, oranges,

bananas offered daily); (vi) yoghurt; (vii) dessert or

canned fruit; and (viii) milk (skimmed, 1 % and Lactaid –

white milk only). The main entrée was provided by

the head server to ensure standard portion sizes. The

remaining items were pre-portioned in separate dishes by

food-service staff in advance because vocational students

participated in the lunch service.

Prior to the intervention, the menu was communicated to

students through words and Picture Communication Sym-

bolsTM (Dynavox Mayer-Johnson LLC, Pittsburgh, PA, USA)

for foods. Picture Communication Symbols are visual

representations of concepts and ideas that reinforce

meaning. They are used as an alternative method of com-

munication for youth with cognitive impairments or com-

munication disorders(29). A placemat used as a tray liner

depicted the lunch elements and included a picture high-

lighting dessert. The peanut butter and jelly sandwiches

were available daily to accommodate students who had

very limited food repertoires. Side dishes (i.e. pretzels and

vegetable side dishes) were ‘bundled’ with the entrée.

Students were permitted to refuse the side dish that was

automatically plated with the entrée in accordance with

National School Lunch Program rules for offer v. serve, but

were not permitted to switch side dishes. A fruit bowl

containing apples, oranges and bananas was kept behind

the counter. Dessert was served on the eye-level counter by

a vocational student. Canned fruit was offered on Tuesday

and Friday, when dessert was not offered.

Students arrived to the dining hall by classroom,

including the primary teacher and teaching assistants.

Students had 30 min to choose and eat lunch. The lunch

periods assigned to classrooms were staggered to avoid

overcrowding. Teachers selected their own food from the

serving line and ate lunch with their students to provide

them with the support and supervision they required due

to their cognitive, behavioural and physical challenges.

No monetary transactions took place because student

meals were included in yearly tuition.

Intervention planning

Adaptations to classic Smarter Lunchroom strategies were

necessary due to physical and social factors within the

lunchroom environment and the unique characteristics

of the study population, including: cognitive disabilities (low

literacy and comprehension, impairments in reasoning and

decision making); sensory sensitivities (both auditory and

oral); communication disorders; oral-motor impairments (all

students are considered high risk for choking); and mobility

limitations. Youth with I/DD, particularly those with autism

spectrum disorder, may experience anxiety and exhibit

disruptive behaviour in response to change and transition.

Additionally, many students had communication challenges

and language-based disabilities. Students were prepared for

the impending changes through Social StoriesTM, videos,

student lunch advisory committee activities and a 2 d pilot

to practice data-collection procedures. Social Stories

describe situations, relevant social cues and common

responses in a specific format on the premise that an

improved understanding of the situation will lead to the

desired behavioural response(30).

Dining hall layout changes

The intervention capitalized on environmental changes to

enhance the students’ experience of making choices

in the serving line for all three weeks of the menu cycle

(Fig. 1). The goal was to induce improvements in students’

food choices through ‘nudging’ rather than menu changes.

Communication of the menu choices was enhanced by

supplementing the Picture Communication Symbols with

real food photos. In our formative work, teachers descri-

bed real food photos as the optimal visual aids because

they were more accurate and descriptive compared with

Picture Communication Symbols. For example, students

were confused if the entrée-sized salad on the lunch menu

was taco salad with multiple toppings but the Picture

Communication Symbol featured a plain lettuce salad. The

placemat was revised to present a non-directive (no foods

pictured) instruction for food placement on the tray.

Peanut butter and jelly sandwiches were moved to

the back counter and made available only by request to

encourage students to at least consider the two main

entrée options. Fruit was moved to the beginning of the

serving line. Apples, bananas and oranges were separated

into attractive and easy-to-reach baskets to improve

accessibility. An easy-to-eat fruit option (e.g. apple sauce)

was available by request daily near the fresh fruit. The

healthiest entrée (i.e. meeting the greatest amounts of the

dietary targets) was placed earlier in line, followed

by side dishes. A critical change was the unbundling of

side dishes and entrées, made in response to formative

research which indicated students were confused by the

inability to change side dishes and our desire to support

autonomous choice. Teachers were trained to support

autonomous student choices in the serving area. Desserts

were kept behind the counter, rather than serving them

at eye level. Milk and yoghurt were not targeted for

improvement because formative research suggested that

almost all students selected dairy daily. The menu was

altered in two instances. One menu change was to serve

peanut butter and jelly sandwiches on wheat bread rather

than white; a second change was to reduce the portion

sizes of desserts to 75 % of their original size. The two

menu changes were a result of our community-engaged

formative research; teachers unanimously asked for these

two changes during the planning stage.

Activities to support the intervention included: (i) pro-

mpting by ‘celebrity servers’; (ii) the creation of fruit

and vegetable-inspired artwork for the dining hall;

364 KL Hubbard et al.

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(iii) classroom-based taste-testing activities; and (iv) logo-

naming and branding activities. Fidelity to the layout

changes was monitored on three non-consecutive days

for the first four weeks of the intervention, followed by

weekly observations in months 2 and 3. Specifically,

vocational students who worked in the serving area

required support to adjust to their new roles. We moni-

tored the ability of students and staff to serve the food as

delineated in the layout plan.

Measures

The digital photography of foods method(31,32) was used

to measure food selection and plate waste at lunch

for five consecutive days (Monday through Friday) at

baseline in February 2012 and five consecutive days

(Monday through Friday) at follow-up in June 2012 on

the same week of the menu cycle to allow for direct

comparison. Digital photography methodology has been

validated in school cafeteria settings in comparison to

weighed and visual estimation of portion sizes(32). Two

camera stations were located near the exit of the serving

area to capture selection and at the waste disposal station

to capture plate waste. Trays were lined with a paper

placemat that contained a unique identification to link

selection and plate waste photos to the individual parti-

cipants each day. Two angle (418) and two aerial (40 cm

(16 in)) photographs were taken of each tray to assess

selection and plate waste, for a total of four photographs

per participant per day.

Portions of each available item were weighed in tripli-

cate at baseline and follow-up to ensure no changes in

serving sizes (with the exception of desserts) occurred.

Standardized recipes and nutrient content of each available

item were analysed by a registered dietitian (K.L.H.) using

the Nutrition Data System for Research (NDSR; University

of Minnesota, Minneapolis, MN, USA, 2011). NDSR was

used to calculate servings of fruits, vegetables, whole

grains and refined grains per each available item. NDSR

food group servings were derived from the Nutrition

Coordinating Center (NCC) Food Group Serving Count

System, defined per the Dietary Guidelines for Americans

2005. All items, including side dishes, had the potential to

contribute to the calculated servings. Each food was linked

to macronutrient and micronutrient information from

NDSR. Food selection and plate waste were estimated

using a triple-screen computer set-up that simultaneously

displayed photographs of the reference portion, food

selection and plate waste. A trained research assistant

coded selection as ‘yes/no’ of each available item fol-

lowed by quantity, because for certain items, such as

milk, participants were permitted to take more than one.

Selection was verified by a registered dietitian when plate

waste was coded.

Photographs of weighed standard reference portions

were captured for all available items. A registered dietitian

estimated consumption by comparing the plate waste

photograph with the standard reference photograph.

Consumption was coded on a five-point scale (0 %, 25 %,

50 %, 75 %, 100 %). Consumption estimates for fruits with

cores and peels included the edible portion only. Gram

weights were estimated from the plate waste photographs

as follows: consumption estimates were entered and

linked to the NDSR nutrient analyses based on gram

weights of the reference portion. Servings of fruits, vege-

tables, whole grains and refined grains of each available

item selected, wasted and consumed were calculated from

Fig. 1 (colour online) Intervention elements. From left to right: easy-to-reach fruit baskets, Picture Communication Symbol
TM

for
‘choose’, menu board featuring food photographs (top), baby spinach side dish, non-directive placemat, fruit salad side dish,
intervention logo (bottom). *The Picture Communication Symbols r1981–2011 by Mayer-Johnson LLC. All Rights Reserved
Worldwide. Used with permission

Smarter Lunchroom for youth with disabilities 365

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the standardized recipes in NDSR. In addition to servings,

counts of all available items selected and consumed were

generated.

Data analysis

Three different analyses of the data were conducted.

First, for the primary analysis, mixed linear regression

models were used to evaluate mean changes in servings

of fruits, vegetables, whole grains and refined grains

selected, wasted and consumed with the individual

participant as the unit of analysis. The models included

two fixed within-participant factors that were crossed:

visit (baseline v. follow-up) and day of the week. Random

participant intercepts were used to induce the within-

participant correlations. Day-to-day variability was assessed

using a likelihood ratio test comparing the log-likelihood of

full models that included the interaction terms with partial

models with no interaction terms.

Second, the percentage of selected foods that were

wasted was examined. Overall plate waste was assessed

by calculating the percentage of total kilojoules and total

gram weight of foods selected that were wasted. The

plate waste of fruits and vegetables was assessed by

calculating the percentage of the servings selected that

were wasted. The mean percentage of plate waste (for

total kilojoules, total gram weight and total fruit and

vegetable servings) was calculated for each participant

and averaged across all participants.

Third, Poisson regression was used to evaluate changes

in item count of foods selected and consumed. Counts

were used to examine the relative contribution of chan-

ges in selection of foods targeted in the intervention

(i.e. whole fruit, canned fruit, vegetable side dishes, soup

side dishes, entrée-sized salads, desserts, and peanut

butter and jelly sandwiches) to the changes in servings of

fruits, vegetables, whole grains and refined grains selec-

ted (expressed as a rate: per 100 student-trays). We used

the same approach to examine the relative contribution

of changes in consumption. Rates of milk and yoghurt

selection and consumption were examined for potential

unintended shifts away from these foods. All statistical

analyses were conducted using SAS statistical software

package version 9?2; P values less than 0?05 were con-

sidered statistically significant.

Results

Enrolment

Fifty-one participants were enrolled in the research study.

For each participant, a complete data record would

contain twenty observations, consisting of selection and

plate waste photos on each of five days at both baseline

and follow-up. Dietary data were excluded from six

participants with completely missing baseline or follow-

up data (due to hospitalizations), from one participant

who had no matching pre–post intervention days and

from one participant who followed a gluten-free diet sent

from home. These exclusions yielded a final sample size

of forty-three participants. Of the 860 possible observa-

tions for the forty-three participants, 196 were missing

(23 %) leaving a total of 664 observations (332 selection,

332 consumption) for the analyses. Reasons for missing

data consisted of classroom field trips, illness, off-campus

job locations and transient refusal to participate in data

collection. Each day, one to three participants refused

to participate in the pre or post photograph. The mean

age of the participants in the analyses was 18?3 (SD 2?5)

years (range 11–22 years); 51 % were female; 72 % were

residential students; and 53 % were enrolled in the edu-

cation programme.

Selection

Daily mean kilojoules and mean gram weight of foods

and beverages selected did not change over the study

period (Table 2). Significant benefits of the intervention

were observed for daily selection of whole grain and

refined grain servings (Fig. 2(a)). Daily selection of whole

grains increased by a mean of 0?44 servings (from 1?62 to

2?06 servings) and refined grains decreased by a mean of

0?33 servings (from 0?82 to 0?49 servings). Daily selection

of fruit and vegetable servings did not change. Significant

variability in daily mean serving changes was observed

for vegetable selection (likelihood ratio test, P , 0?001)

but was not significant for the selection of fruit (P 5 0?16),

whole grains (P 5 0?05) and refined grains (P 5 0?07).

Rates of selection of whole fruit, canned fruit, vegetable

side dishes, soup side dishes, entrée-sized salads, desserts,

and peanut butter and jelly sandwiches are shown in

Table 3. The rate of canned fruit selection more than

doubled. No significant changes were observed in rates of

whole fruit selection. Raw vegetable side dishes and soup

side dishes were grouped together to examine the changes

in rates of selection for all vegetable side dishes. The rate

of selection of all vegetable side dishes did not change

significantly from baseline to follow-up. Total vegetable

side dishes were divided into raw vegetable sides and soup

Table 2 Daily mean kilojoules and mean gram weight of food
selected and consumed, at baseline and follow-up, among stu-
dents (n 43) aged 11–22 years with intellectual and developmental
disabilities attending a residential school in Massachusetts, USA,
March–June 2012

Baseline Follow-up

Mean 95 % CI Mean 95 % CI

Selection
Kilojoules 3636 3381, 3895 3707 3448, 3962
Gram weight 784 696, 873 791 702, 878

Consumption
Kilojoules 3025 2757, 3288 3054 2787, 3322
Gram weight 610 532, 689 637 558, 716

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sides to determine whether the form of the vegetable

impacted the rate of selection. The rate of soup selection

increased significantly by 28 %, while the rate of selection

of raw vegetable sides decreased significantly by 46 %. The

rate of dessert selection did not change.

Consumption

Daily mean kilojoules and mean gram weight of foods and

beverages consumed did not change over the study period

(Table 2). Significant benefits of the intervention were

observed for daily consumption of fruit, whole grain and

refined grain servings (Fig. 2(b)). Daily consumption of

fruits increased by a mean of 0?18 servings (from 0?39 to

0?57 servings), whole grains increased by a mean of 0?38

servings (from 1?44 to 1?83 servings) and refined grains

decreased by a mean of 0?31 servings (from 0?68 to

0?37 servings). Daily vegetable servings consumed did not

change. Significant variability in daily mean serving changes

was observed for vegetable consumption (likelihood ratio

test, P 5 0?008), but not for fruit (P 5 0?27), whole grain

(P 5 0?05) and refined grain (P 5 0?28) consumption.

Plate waste

Participants at baseline wasted a mean of 17?5 % of the

total kilojoules selected and a mean of 21?4 % of the total

gram weight of foods and beverages selected. Overall

plate waste did not change significantly over the inter-

vention period (17?6 % of the total kilojoules post and

19?5 % of the total gram weight post). The change in the

percentage of total kilojoules wasted differed significantly

Fruits Vegetables Whole grains Refined grains

Fruits Vegetables Whole grains Refined grains

Monday

Tuesday

Wednesday

Thursday

Friday

Overall

Monday

Tuesday

Wednesday

Thursday

Friday

Overall

–1
·0

–1
·0

–1
·0

–0
·5

–0
·5

–0
·50·0 0·0 0·00·00·5 0·51·0 1·0 1·0 1·0–1

·0

–1
·0

–0
·5 0·0 0·5 1·0 –0

·5 0·0 0·5 1·0–1
·0

–0
·5 0·0 0·5 1·0–1

·0
–0

·5 0·0 0·5 1·0–1
·0

–0
·5 0·5 0·5

Change in servings
mean overall = 0·14
95 % Cl –0·02, 0·29

Change in servings
mean overall = 0·18
95 % Cl 0·05, 0·31

Change in servings
mean overall = 0·04
95 % Cl –0·11, 0·20

Change in servings
mean overall = 0·38
95 % Cl 0·11, 0·65

Change in servings
mean overall = –0·31
95 % Cl –0·51, –0·10

Change in servings
mean overall = –0·12
95 % Cl –0·31, 0·08

Change in servings
mean overall = 0·44
95 % Cl 0·14, 0·73

Change in servings
mean overall = –0·33
95 % Cl –0·56, –0·11

Fig. 2 Mean change (with 95 % confidence interval represented by horizontal bar) in daily servings of fruits, vegetables, whole
grains and refined grains (a) selected and (b) consumed, from baseline to follow-up, by day of the week and overall, among
students (n 43) aged 11–22 years with intellectual and developmental disabilities attending a residential school in Massachusetts,
USA, March–June 2012

Smarter Lunchroom for youth with disabilities 367

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across days (likelihood ratio P 5 0?02), but did not

differ significantly for percentage gram weight wasted

(P 5 0?15). Significant benefits of the intervention were

observed for fruit and vegetable plate waste. The mean

percentage of fruit servings wasted from those selected

decreased by 9?4 % (P 5 0?04) and the mean percentage

of vegetable servings wasted from those selected

decreased by 9?0 % (P 5 0?03; Fig. 3). The percentage of

fruit and vegetable servings wasted from those selected

did not differ across days (fruit P 5 0?97, vegetables

P 5 0?05).

Discussion

To our knowledge, the present study is the first to investi-

gate food-environment intervention approaches based on

behavioural economics and principles of behavioural

Table 3 Estimated differences in the rates of selection and consumption of menu items at baseline and follow-up among students (n 43)
aged 11–22 years with intellectual and developmental disabilities attending a residential school in Massachusetts, USA, March–June 2012

Measure Time point

Sample
observations

(student trays)*

Baseline
rate (per 100
student-trays)

Follow-up
rate (per 100
student-trays) Rate ratio 95 % CI P value

Canned fruit Selection 332 21?69 31?32 2?37 1?11, 5?08 0?03
Consumption 332 18?07 30?72 2?55 1?18, 5?54 0?02

Whole fruit Selection 332 28?91 34?93 1?18 0?81, 1?71 0?39
Consumption 332 25?90 30?72 1?20 0?80, 1?80 0?38

All vegetable side dishes Selection 332 97?59 92?77 1?00 0?85, 1?18 0?95
Consumption 332 77?11 84?33 1?16 0?95, 1?41 0?14

Raw vegetable side dishes Selection 332 53?61 36?74 0?54 0?41, 0?70 ,0?001
Consumption 332 38?55 33?13 0?68 0?49, 0?95 0?02

Soup side dishes Selection 332 43?98 56?02 1?28 1?02, 1?60 0?03
Consumption 332 38?55 51?20 1?37 1?06, 1?76 0?02

Entrée-sized salads Selection 204 7?83 5?42 0?75 0?31, 1?82 0?53
Consumption 204 7?22 5?42 0?95 0?35, 2?55 0?92

Desserts Selection 140 34?93 27?71 0?87 0?70, 1?08 0?20
Consumption 140 34?93 25?90 0?81 0?65, 1?02 0?07

Peanut butter and jelly sandwiches Selection 332 13?25 15?66 1?16 0?53, 2?51 0?70
Consumption 332 13?25 15?66 1?16 0?53, 2?51 0?70

Milk and yoghurt Selection 332 149?39 140?96 0?94 0?81, 1?10 0?44
Consumption 332 138?00 133?73 0?96 0?82, 1?13 0?64

*Entrée-sized salads and desserts not offered daily, resulting in differences in sample size.

Increase

10

0

–10

Decrease

–9·4 % –9·0 %

–4·4 %

+3·6 %

Fruits Vegetables Whole grains Refined grains

C
ha

ng
e 

in
 p

er
ce

nt
ag

e 
of

 p
la

te
 w

as
te

Fig. 3 Mean change (with 95 % confidence interval represented by vertical bar) in percentage of fruit, vegetable, whole grain and
refined grain servings wasted of those selected, from baseline to follow-up, among students (n 43) aged 11–22 years with
intellectual and developmental disabilities attending a residential school in Massachusetts, USA, March–June 2012

368 KL Hubbard et al.

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science in a population of students with I/DD. Our findings

are consistent with studies employing behavioural eco-

nomic approaches in lunchroom environments among

typically developing students. Verbal prompts from food-

service workers to encourage fruit selection resulted in

significant improvements in selection and consumption of

fruits at lunch among schoolchildren(33). Peeling and slicing

oranges to improve the accessibility of fruit increased the

percentage of children selecting and consuming oranges in

an elementary-school cafeteria(34). When offered a choice

between carrots or celery instead of a requirement to take

them, a greater proportion of junior high students con-

sumed their vegetable
(35)

. A Chef’s Initiative intervention to

improve the availability of healthy foods in Boston middle

schools resulted in significant improvements in the pro-

portion of students choosing whole grains and vegetables

and the total amount of these foods consumed(36).

The intervention resulted in shifts in the sources of

kilojoules selected and consumed, with an overall

improvement in diet composition, rather than a decrease

in overall energy intake. We observed no overall increase

in plate waste, nor did the intervention cause unintended

shifts away from selecting and consuming healthy foods.

These results suggest that the intervention was effective

for improving dietary intake, but may not directly affect

positive energy balance or obesity. The cumulative impact

of these relatively small changes at one eating occasion

translate to an increase of 1?0 fruit serving, an increase of

2?2 whole grain servings and a decrease of 1?7 refined grain

servings for one individual over a 5 d school week. The

observed improvement in whole grain consumption could

be achieved by substituting half a slice of whole grain

bread for half a bag of pretzels (refined grain) daily. The

intervention resulted in a decrease in fruit and vegetable

plate waste, supporting the hypothesis that students will

consume a greater percentage of the fruit and vegetable side

dishes when given the opportunity to make an autonomous

choice. A reduction in fruit and vegetable plate waste could

lead to significant cost savings for schools. The favourable

impact was achieved through subtle ‘nudge’ mechanisms

that preserve autonomous choice, were accepted by stu-

dents, and carry a high potential for long-term sustainability

due to the low implementation cost and potential for savings

related to lower food waste.

Changes in the rates of particular menu items selected

and consumed offer additional insights for the mechan-

isms by which changes in overall servings selected and

consumed were achieved. Decreased rates of dessert

selection and consumption, although non-significant,

accounted for approximately 12 % of the decrease in daily

mean refined grain servings selected. Changing peanut

butter and jelly sandwiches from white to wheat bread

accounted for 30 % of the increase in daily mean whole

grain servings selected.

Observed shifts in selection towards canned fruits

and soup suggest that processed forms of fruits and

vegetables may be preferred over raw forms by students

with I/DD. Although we observed a significant increase in

the percentage of fruit servings consumed and rates of

canned fruit selection and consumption, the magnitude of

the behaviour change was not adequate to observe an

overall increase in mean servings of fruit selected at the

individual level. The power to detect these changes may

have been limited by our small sample size.

Changes in vegetable servings selected should be inter-

preted with caution because the vegetable side dishes

were automatically placed on trays at baseline, making it

difficult to isolate true selection of these items at this time

point. The unbundling of raw vegetable side dishes caused

a shift towards soup side dishes. The soups contained 0?5

to 1 serving of vegetables per 6 ounce portion – less than

the vegetable servings provided by raw vegetable side

dishes. This may explain the increase in the percentage of

vegetable sides consumed from those selected, but no

significant increase in mean vegetable servings consumed.

The student population in the present study was hetero-

geneous with respect to primary and secondary diagnoses,

medication use, cognitive ability and severity of beha-

vioural and emotional challenges. The licensing policy of

the school, designed to protect this vulnerable population,

limited the ability to obtain additional information about

the students beyond age and sex. Although it may have

been beneficial to attempt to evaluate these and other

potential modifying factors, the small sample size did not

support the investigation of differential effects by student-

level characteristics, even had they been available.

Two important limitations of the study were its small

sample size and the lack of a control school to help rule

out the potential influence of secular trends or events

that may have occurred outside the study. To the best of

our knowledge, the school did not implement any other

changes in campus environments outside the dining

hall that could impact food selection and eating habits

at the lunch meal. None the less, findings should be

replicated in a larger population and a comparison school,

if possible.

Schools have been identified as the optimal venue to

deliver nutrition interventions and policies for children

and should support the inclusion of youth with I/DD.

Interventions to improve dietary intake need to address

barriers at the individual and environmental levels that

are perceived or experienced by youth with I/DD and

their caregivers(37). In our experience, the community-

engaged research process facilitated a broad and rich

discussion of health promotion opportunities for youth

with I/DD and led to an intervention that incorporated

values of foremost importance to the school community.

No students were excluded based on their disability

and because the intervention did not rely on reasoning,

those with significant cognitive impairments were not

disadvantaged. Students readily adapted to layout changes,

data collection procedures, and the switch of peanut butter

Smarter Lunchroom for youth with disabilities 369

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and jelly sandwiches from white bread to wheat. There

were no reports of behavioural problems.

Although the specific intervention elements may have

limited generalizability, we believe the approach to the

intervention design which focused on the process of

developing adaptations based on formative research and

engaging the school community is highly generalizable and

makes an important contribution to the growing literature

highlighting the need for the adaptation of evidence-based

health promotion strategies(38). Evidence from interventions

with adults with intellectual disability support the invol-

vement of caregivers in the research process as well as

the consideration for the context of the lived disability

experience(39). The time required for the formative

research and adaptation process was substantially greater

compared with similar studies designed for typically devel-

oping students. A major impetus for a careful approach was

to ensure student and teacher safety and to prevent unin-

tentional cognitive or emotional stress.

Conclusion

A Smarter Lunchroom intervention, based on behavioural

economics and adapted for students with I/DD, significantly

increased whole grain selection and consumption, reduced

refined grain selection and consumption, increased fruit

consumption, and reduced fruit and vegetable plate waste.

Results suggest that low-cost interventions that create

environments in which the healthiest choice is the easiest

choice hold great promise for improving the short-term

food choices and dietary intake of this vulnerable popula-

tion. Future studies are needed to evaluate whether dietary

changes are maintained in the long term and if the effects

are replicated in regular education settings.

Acknowledgements

Sources of funding: This study was funded by the Deborah

Munroe Noonan Memorial Research Foundation. The

Deborah Munroe Noonan Memorial Research Foundation

had no role in the design, analysis or writing of this article.

Conflict of interest: None. Ethics: This study was approved

by the Tufts University Institutional Review Board. Authors’

contributions: All authors contributed intellectually to the

research aims, drafting and revising of the article, and gave

final approval of the version to be published. K.L.H., L.G.B.,

S.C.F. and A.M. conducted the research. K.L.H. analysed

the data and wrote the manuscript. M.E. assisted with the

statistical analyses and interpretation of results. K.L.H. and

A.M. had primary responsibility for the final content.

Acknowledgements: The authors would like to thank the

students at the Cardinal Cushing School for participating in

the study. They gratefully acknowledge the contributions of

the school staff and the Project Advisory Board to the

design and implementation of the intervention.

References

1. Bandini L, Curtin C, Hamad C et al. (2005) Prevalence of
overweight in children with developmental disorders in the
continuous National Health and Nutrition Examination
Survey (NHANES) 1999–2002. J Pediatr 146, 738–743.

2. Chen AY, Kim SE, Houtrow AJ et al. (2010) Prevalence of
obesity among children with chronic conditions. Obesity
(Silver Spring) 18, 210–213.

3. Curtin C, Anderson SE, Must A et al. (2010) The prevalence
of obesity in children with autism: a secondary data
analysis using nationally representative data from the
National Survey of Children’s Health. BMC Pediatr 10, 11.

4. Emerson E & Robertson J (2010) Obesity in young children
with intellectual disabilities or borderline intellectual
functioning. Int J Pediatr Obes 5, 320–326.

5. Simeonsson RJ, McMillen JS & Huntington GS (2002)
Secondary conditions in children with disabilities: spina
bifida as a case example. Ment Retard Dev Disabil Res Rev
8, 198–205.

6. Bandini L, Schoeller DA, Fukagawa NK et al. (1990) Body
composition and energy expenditure in adolescents with
cerebral palsy or myelodysplasia. Pediatr Res 29, 70–77.

7. Hurvitz EA, Green LB, Hornyak JE et al. (2008) Body mass
index measures in children with cerebral palsy related to
gross motor function classification: a clinic-based study.
Am J Phys Med Rehabil 87, 395–403.

8. Luke A, Roizen NJ, Sutton M et al. (1994) Energy
expenditure in children with Down syndrome: correcting
metabolic rate for movement. J Pediatr 125, 829–838.

9. Bégarie J, Maı̈ano C, Leconte P et al. (2013) The prevalence
and determinants of overweight and obesity among French
youths and adults with intellectual disabilities attending
special education schools. Res Dev Disabil 34, 1417–1425.

10. Lin JD, Yen C, Li C et al. (2005) Patterns of obesity among
children and adolescents with intellectual disabilties in
Taiwan. J Appl Res Intellect Disabil 18, 123–129.

11. Stewart L, Van de Ven L, Katsarou V et al. (2009) High
prevalence of obesity in ambulatory children and adoles-
cents with intellectual disability. J Intellect Disabil Res 53,
882–886.

12. Takeuchi E (1994) Incidence of obesity among school
children with mental retardation in Japan. Am J Ment
Retard 99, 283–288.

13. Drum C, McClain MR, Horner-Johnson W et al. (2011)
Health Disparities Chart Book on Disability and Racial and
Ethnic Status in the United States. Concord, NH: University
of New Hampshire, Institute on Disability.

14. Gibson JC, Temple VA, Anholt JP et al. (2011) Nutrition
needs assessment of young Special Olympics participants.
J Intellect Dev Disabil 36, 264–268.

15. Sharp WG, Berry RC, McCracken C et al. (2013) Feeding
problems and nutrient intake in children with autism
spectrum disorders: a meta-analysis and comprehensive
review of the literature. J Autism Dev Disord 43,
2159–2173.

16. Twachtman-Reilly J, Amaral SC & Zebrowski PP (2008)
Addressing feeding disorders in children on the autism
spectrum in school-based settings: physiological and
behavioral issues. Lang Speech Hear Serv Sch 39, 261–272.

17. Evans EW, Must A, Anderson SE et al. (2012) Dietary
patterns and body mass index in children with autism and
typically developing children. Res Autism Spectr Disord 6,
399–405.

18. Yen C-F & Lin J-D (2010) Factors for healthy food or less-
healthy food intake among Taiwanese adolescents with
intellectual disabilities. Res Dev Disabil 31, 203–211.

19. Institute of Medicine (2004) Preventing Childhood
Obesity: Health in Balance. Washington, DC: The National
Academies Press.

370 KL Hubbard et al.

Downloaded from https://www.cambridge.org/core. 06 Apr 2021 at 01:16:47, subject to the Cambridge Core terms of use.

https://www.cambridge.org/core


20. Minihan P, Fitch S & Must A (2007) What does the epidemic
of childhood obesity mean for children with special health
care needs? J Law Med Ethics 35, 61–77.

21. Just DR & Wansink B (2009) Smarter lunchrooms: using
behavioral economics to improve meal selection. Choices
24, issue 3; available at http://www.choicesmagazine.org/
magazine/article.php?article 5 87

22. Rimmer JH (2002) Health promotion for individuals with
disabilities. Dis Manage Health Outcomes 10, 337–343.

23. Cornell Center for Behavior Econcomics in Child Nutri-
tion Programs (2012) Six guiding principles to improving
eating behaviors. http://smarterlunchrooms.org/sites/default/
files/introduction_to_smarter_lunchrooms_6_principles_
powerpoint.pdf (accessed April 2013).

24. Hanks AS, Just DR & Wansink B (2013) Smarter lunchrooms
can address new school lunchroom guidelines and child-
hood obesity. J Pediatr 162, 867–869.

25. US Department of Agriculture, Food and Nutrition Service
(2012) Nutrition Standards in the National School Lunch
and School Breakfast Programs. 7 CFR Parts 210 and 220.
Fed Reg 77, issue 17, 4088–4167.

26. Cook T & Campbell D (1979) Quasi-Experimentation:
Design and Analysis Issues for Field Studies. Boston, MA:
Houghton Mifflin Company.

27. Boyle CA, Boulet S, Schieve LA et al. (2011) Trends in the
prevalence of developmental disabilities in US children,
1997–2008. Pediatrics 127, 1034–1042.

28. Hubbard K, Bandini L, Folta SC, et al. (2012) Adaptation
of smarter lunchroom design to the specific needs of
children with intellectual and developmental disabilities:
formative research and community collaboration. Pre-
sented at the American Public Health Association 140th
Annual Meeting and Exposition, San Francisco, CA, USA,
27–31 October 2012.

29. Mayer-Johnson LLC (2013) Picture Communication Symbols.
http://www.mayer-johnson.com/category/symbols-and-
photos (accessed September 2013).

30. The Gray Center for Social Learning and Understanding
(2013) What are Social StoriesTM? http://www.thegraycen-
ter.org/social-stories/what-are-social-stories (accessed June
2013).

31. Williamson DA, Allen HR, Martin PD et al. (2004) Digital
photography: a new method for estimating food intake in
cafeteria settings. Eat Weight Disord 9, 24–28.

32. Williamson DA, Allen HR, Martin PD et al. (2003)
Comparison of digital photography to weighed and visual
estimation of portion sizes. J Acad Nutr Diet 103,
1139–1145.

33. Schwartz MB (2007) The influence of a verbal prompt on
school lunch fruit consumption: a pilot study. Int J Behav
Nutr Phys Act 4, 6.

34. Swanson M, Branscum A & Nakayima PJ (2009) Promoting
consumption of fruit in elementary school cafeterias.
The effects of slicing apples and oranges. Appetite 53,
264–267.

35. Price JP & Just DR (2009) Getting kids to eat their veggies.
Presented at the International Association of Agricultural
Economists 27th Triennial Conference, Beijing, China,
16–22 August 2009.

36. Cohen JF, Smit LA, Parker E et al. (2012) Long-term impact
of a chef on school lunch consumption: findings from a
2-year pilot study in Boston middle schools. J Acad Nutr
Diet 112, 927–933.

37. Humphries K, Traci M & Seekins T (2004) A preliminary
assessment of the nutrition and food-system environment
of adults with intellectual disabilitites living in supported
arrangements in the community. Ecol Food Nutr 43,
517–532.

38. Rimmer JH (2011) Promoting inclusive community-based
obesity prevention programs for children and adolescents
with disabilities: the why and how. Child Obes 7, 177–184.

39. Hamilton S, Hankey CA, Miller S et al. (2007) A review
of weight loss interventions for adults with intellectual
disabilities. Obes Rev 8, 339–345.

Smarter Lunchroom for youth with disabilities 371

Downloaded from https://www.cambridge.org/core. 06 Apr 2021 at 01:16:47, subject to the Cambridge Core terms of use.

https://www.cambridge.org/core