Measuring Food Waste and Consumption by Children Using Photography


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Measuring food waste and consumption by children
using photography

Agnès Giboreau, Camille Schwartz, David Morizet, Herbert L. Meiselman

To cite this version:
Agnès Giboreau, Camille Schwartz, David Morizet, Herbert L. Meiselman. Measuring food waste
and consumption by children using photography. Nutrients, MDPI, 2019, 11 (10), pp.2410.
�10.3390/nu11102410�. �hal-02620997�

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nutrients

Article

Measuring Food Waste and Consumption by Children
Using Photography

Agnes Giboreau 1,*, Camille Schwartz 1,†, David Morizet 2 and Herbert L. Meiselman 3

1 Institute Paul Bocuse Research Center, 69130 Ecully, France; camille.schwartz@inra.fr
2 Bonduelle Corporate Research, 59650 Villeneuve-d’Ascq France; david.morizet@rd.loreal.com
3 Herb L. Meiselman Training and Consulting, Rockport, MA 01966, USA; herb@herbmeiselman.com
* Correspondence: agnes.giboreau@institutpaulbocuse.com; Tel.: +33-472-180-220
† Present address: Centre des Sciences du Goût et de l’Alimentation, AgroSup Dijon, CNRS, INRA, Université

Bourgogne Franche-Comté, 2100 Dijon, France.

Received: 31 August 2019; Accepted: 30 September 2019; Published: 9 October 2019
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Abstract: A photography method was used to measure waste on food trays in school lunch in France,
using the 5-point quarter-waste scale. While food waste has been studied extensively in US school
lunches, the structure of the French lunch meal is quite different, with multiple courses, and vegetables
(raw and cooked) in more than one course. Vegetables were the most wasted food category as usually
seen in school lunch research, especially cooked vegetables, which were wasted at rates of 66%–83%.
Raw vegetables were still wasted more than main dishes, starchy products, dairy, fruit, and desserts.
Vegetables were also the most disliked food category, with the classes of vegetables falling in the same
order as for waste. Waste and liking were highly correlated. Sensory characteristics of the food were
cited as a main reason for liking/disliking. There is a strong connection between food liking and food
consumption, and this connection should be the basis for future attempts to modify school lunch to
improve consumption. The photographic method of measuring food waste at an individual level
performed well.

Keywords: food waste; school lunch; photography; vegetables; liking; French meals

1. Introduction

The measurement of food consumption and food waste are important for the goals of healthy
eating and sustainability. Much of the research on measuring food intake and food waste has been
directed to children [1]. One of the major challenges with children’s eating is the consumption of
vegetables, which have received a large share of the attention in research [2–5].

The present study was designed to extend the research on school food waste to French school
canteens using the photographic method of estimating waste and study the reasons for non-consumption
with particular attention on the differences between the various foods served in the French meal
pattern. Much of the research on food consumption and food waste comes from studies of school
lunches in the USA, including served hot lunches, served cold lunches (sandwiches, etc.), packed
lunches from home, and possibly packed lunches purchased in shops. The children in the USA do not
typically eat a hot lunch when they are at home, where sandwiches prevail [6]. Sandwich lunches also
tend to be the norm in some Nordic countries [7,8]. Further, the meal content of the French mid-day
meal and of the school mid-day meal are different from meals in many other countries. The French
typically eat their main meal mid-day [9] and the meal usually includes multiple courses (usually
three), including cooked vegetables [10]. Similarly, French children usually have a hot lunch mid-day
at home or at school, though mainly at school as part of institutional practices. School lunches are
designed following dietary rules based on energy and balance of nutrients [11]. Lunches have multiple

Nutrients 2019, 11, 2410; doi:10.3390/nu11102410 www.mdpi.com/journal/nutrients

http://www.mdpi.com/journal/nutrients
http://www.mdpi.com
http://www.mdpi.com/2072-6643/11/10/2410?type=check_update&version=1
http://dx.doi.org/10.3390/nu11102410
http://www.mdpi.com/journal/nutrients


Nutrients 2019, 11, 2410 2 of 10

courses and always include vegetables as a either a starter and/or as a side dish. However, food waste
is observed in school restaurants: the official French agency for the environment estimates food waste
to be between 150 g and 200 g per person [12]. Detailed studies based on behavioral data are needed to
better understand reasons for non-consumption and identify the potential levers to select optimum
food offers.

1.1. Different Methods to Measure Waste

Most people probably view weighed food intake as the gold standard for measuring consumption
– with whole meals or individual meal components being weighed before and after the meal. This
method is time-consuming, labor-intensive, and requires space [13,14]. It is difficult to do weighed
assessments with large samples of people or with complex meals with many components.

Alternatives to weighing food are visual estimation, i.e., direct observation by an experimenter,
and photographic methods. Visual estimation has high reliability, requires less labor, less time, and
less space [13,15], but requires trained observers [14]. Another method is digital photography where
the estimation of amount consumed/amount wasted can be done at any time, and the photos can be
checked for inter-judge reliability [3,16].

Byker Shanks, Banna, and Serrano (2017) [17] review 53 articles measuring nutrient intake in the
United States National School Lunch Program. Different methods were used in the studies: visual
estimation (n = 11), photography (n = 11), weighing (n = 23), or a combination of these three (n = 8).
Most studies compared pre- and post-intervention in the school lunches. Fruits and vegetables were
the most researched food category and the most wasted. The authors recommend more consistency in
measuring food intake and food waste in school lunch assessments. For example, they note the wide
variability in how food waste is reported, including grams, ounces, percentages, or kilocalories, with
percentages being the most frequent. They also note the increasing popularity of visual estimation
methods, including photography. Various scales have been used to visually estimate the food left in
the plate as shown in Table 1.

Table 1. Diversity of scales used to measure food waste through visual estimation.

Scale Authors Food Left in the Plate

3-point scale Kandiah et al. 2006 [18] all; >50%; <50%
4-point scale Hiesmayr et al. 2009 [19] all; 1/2; 1/4; none

5-point scale
Graves et al. 1983 [20] all; 3/4; 1/2; 1/4 or less; none or almost none
Hanks et al. 2014 [13] all; 3/4; 1/2; 1/4; none

6-point scale
Comstock et al. 1981 [21] all; 1 bite eaten; 3/4; 1/2; 1/4; none
Navarro et al. 2016 [22] 100%; 90%; 75%; 50%; 25%; 0%

7-point scale Sherwin et al. 1998 [23] all; 1 mouthful eaten; 3/4; 1/2; 1/4; 1 mouthful left; none
11-point scale Williamson et al. 2003 [14] 100%; 90%; 80%; 70%; 60%; 50%; 40%; 30%; 20%; 10%; 0%

The 5-point scale—quarter-waste method – is recommended by Hanks et al. (2014) as the most reliable.

1.2. Photographic Methods

Martin et al. (2014) [24] provide an overview of the photographic method of food consumption and
waste estimation, noting its reliability and validity. Portion-size estimates using photography correlate
highly with weighed food intake, although research shows that the estimated intake does vary over
categories of nutrients but no information of potential link with food items is given. Additionally, the
photographic method does not appear to change significantly across different raters, making it suited
to large studies with multiple raters. The photographic method has been applied in a wide range of
food service settings including different levels of schools (including preschool and elementary school).

The photography method has been used in various contexts. Christoph et al. (2017) [25] applied
pre- and post-meal digital photography to measure dietary intake in a university self-serve dining-hall
in the USA. They report high degrees of inter-rater agreement on selection, servings, and consumption
of food groups, with the most challenge for consumption of mixed food items. Taylor et al. (2018) [26]



Nutrients 2019, 11, 2410 3 of 10

extend photo analysis to student packed lunches in the USA, concluding that there was satisfactory
reliability in assessment of quantities selected and consumed in eight food categories, with meat/meat
alternatives providing the biggest challenge. Pouyet et al. (2015) [27] used a photographic method to
study elderly patients’ meals in French nursing homes. A range of 11 reference images (0 to 100% food
with 10% increments) was provided to judges to help evaluate food waste. They observed reliability
of the method in that there was agreement between different untrained assessors and agreements
among various estimates made by the same assessor. They confirmed the accuracy and specificity of
this method by comparing food intake estimates for the four dishes with the food intakes determined
using the traditional weighed food method. The method worked equally well on different food types.
Hubbard et al. (2015) [28] used a photographic method to estimate waste and consumption in a nudge
intervention study with intellectually and developmentally disabled children in a school setting.

Smith and Cunningham-Sabo (2013) [3] used a photographic method to study food waste in the
US school lunch program. They estimated waste to the nearest 10% for the main dish, canned fruit,
fresh fruit, vegetable, grain and milk. One-third to one-half of fruits and vegetables were wasted.
Yoder, Foecke and Schoeller (2015) [4] studied waste following interventions in the US school lunch
program, measuring trays pre and post meal. The percentage remaining on the tray was estimated in
25% increments (0%, 25%, 50%, 75% and 100%) of the served portion. Amounts wasted were calculated
as the served portion multiplied by the percentage remaining. Results showed greater waste for raw
fruits (compared to cooked), cooked vegetables (compared to raw), locally sourced (as compared to
conventionally sourced, salad bar items (as compared to main menu items).

Byker Shanks et al. (2017) [2], as noted above, reported on 11 studies using digital photography
in their assessment of the National School Lunch Program in the USA The studies used a variety
of procedures, some studies using reference sizes of food components, and others using students’
selected food before consumption; in both cases, they reported percentage of the reference or the
pre-consumption amount. Different studies used different percentage amounts (actual percent,
increments of 10%, or 0%, 10%, 25%, 50%, 100%). Food waste was used to measure food waste and
food consumption, as well as a number of interventions and procedures.

1.3. Food Consumption and Waste in School Canteens

Several studies researched different methods for studying the low selection and intake of vegetables
in schools. Getts et al. (2015) [29] studied the quarter-waste method of visual estimation in a school
cafeteria and reported good validity and reliability. Comparing the estimated weight to the actual
weight, they found almost 90% of foods were in either “almost-perfect agreement (45%) or “substantial
agreement” (42%). Comparing inter-rater reliability, they found over 90% in perfect to substantial
agreement. Hanks et al. (2014) [13] also compared estimation methods (quarter-waste, half-waste,
photograph) with weighed food leftovers. They noted problems with photograph estimation when
foods are in containers, such as milk. The quarter-waste method reliability was slightly better than
the half waste. The authors recommend the photograph method for estimation of waste of selected,
unpackaged foods.

The goals of this research were to examine French children’s food waste in a school restaurant,
to analyze consumption across the range of diverse foods composing a complete meal and explore
reasons for non-consumption: the study analyzes actual waste in primary school and its link to taste
preference. In addition to extending the use of photographic measurement of waste to the school
setting in a natural environment, this research was designed to extend the study of school lunch to
France which has a specific lunch pattern of eating (starter, main and side dish, dessert). To this
end, a digital photography equipment was set-up in a typical French school to record leftovers at the
tray disposal point. Children’s interviews were conducted on a subsample of participants to explore
reasons of non-consumption.



Nutrients 2019, 11, 2410 4 of 10

2. Materials and Methods

2.1. General Procedure

The experiment took place in the natural setting of the school cafeteria. Observations were made
at lunchtime. The school cafeteria was self service. On most days, children could choose between two
cold-served vegetables served as a starter. Then they were served a main dish composed of meat/fish
and a side, a dairy product (that they could choose), and a dessert (that they choose).

The school was chosen in such a way that children were from a wide range of socio-economic
status. Participants were children aged 6 to 12 who usually had lunch in the school canteen. All
data were fully anonymous. Families pay for the meal according to their income. Tap water was the
only available beverage. Menus are conceived in accordance with the national regulation GEMRCN
ensuring dietary balance and hygiene standards. Food is prepared by a catering company in a central
kitchen and delivered to the canteen using a cold chain (chilled food) scheme. The employees preparing
and serving meals are city staff, trained to respect process and portion sizes. Children were given a
code at the entrance of the school canteen to display on their tray. Then they behaved as usual until the
disposal of their tray where a camera was set-up filming all trays during the service. At the entrance/exit
of the school canteen, an experimenter was available to children to discuss the meal (Figure 1).

Nutrients 2019, 11, x FOR PEER REVIEW 4 of 10 

 

2. Materials and Methods 

2.1. General Procedure 

The experiment took place in the natural setting of the school cafeteria. Observations were made 

at lunchtime. The school cafeteria was self service. On most days, children could choose between two 

cold-served vegetables served as a starter. Then they were served a main dish composed of meat/fish 

and a side, a dairy product (that they could choose), and a dessert (that they choose). 

The school was chosen in such a way that children were from a wide range of socio-economic 

status. Participants were children aged 6 to 12 who usually had lunch in the school canteen. All data 

were fully anonymous. Families pay for the meal according to their income. Tap water was the only 

available beverage. Menus are conceived in accordance with the national regulation GEMRCN 

ensuring dietary balance and hygiene standards. Food is prepared by a catering company in a central 

kitchen and delivered to the canteen using a cold chain (chilled food) scheme. The employees 

preparing and serving meals are city staff, trained to respect process and portion sizes. Children were 

given a code at the entrance of the school canteen to display on their tray. Then they behaved as usual 

until the disposal of their tray where a camera was set-up filming all trays during the service. At the 

entrance/exit of the school canteen, an experimenter was available to children to discuss the meal 

(Figure 1). 

 

Figure 1. General scheme of the protocol with children. 

2.2. Ethics 

The experiment received a favorable response from the ethics committee of the CHU of Lyon 

(Ref. Rech_FRCH_2013_005, Feb 6, 2013). Parents were informed about the study by the director of 

the school, who collected authorizations. None of the parents refused child participation in the study. 

2.3. Participants 

The data were collected through a 5-day longitudinal follow-up including a total of 215 children. 

Children of 4th and 5th grade classes were absent on one day because of a school trip. A total of 776 

trays were analyzed with a good balance of gender (50.6% girls) and age as shown in Table 2. 
  

Figure 1. General scheme of the protocol with children.

2.2. Ethics

The experiment received a favorable response from the ethics committee of the CHU of Lyon (Ref.
Rech_FRCH_2013_005, Feb 6, 2013). Parents were informed about the study by the director of the
school, who collected authorizations. None of the parents refused child participation in the study.

2.3. Participants

The data were collected through a 5-day longitudinal follow-up including a total of 215 children.
Children of 4th and 5th grade classes were absent on one day because of a school trip. A total of
776 trays were analyzed with a good balance of gender (50.6% girls) and age as shown in Table 2.



Nutrients 2019, 11, 2410 5 of 10

Table 2. Number of children by grade (boys/girls). * CLIS class (classe pour l’inclusion scolaire) is
composed of children of different ages with school difficulties and training assistance.

1st Grade 2nd Grade 3rd Grade 4th Grade 5th Grade CLIS* Total

Day 1 30 (14/16) 29 (13/16) 35 (20/15) 32 (13/19) 32 (18/14) 7 (4/3) 165

Day 2 30 (16/14) 37 (18/19) 29 (19/10) 17 (6/11) 35 (19/16) 0 (0/0) 148

Day 3 31 (12/19) 44 (19/25) 34 (20/14) 32 (14/18) 32 (18/14) 7 (5/2) 180

Day 4 35 (15/20) 47 (20/27) 32 (19/13) 35 (13/22) 28 (14/14) 8 (5/3) 185

Day 5 25 (11/14) 40 (16/24) 31 (21/10) n/a n/a 2 (1/1) 98

Total
151 (68/83)

19.4%
197 (86/111)

25.4%
161 (99/62)

20.7%
116 (46/70)

14.9%
127 (69/58)

16.4%
24 (15/9)

3.1%
776 (383/393)
(50.6% girls)

2.4. Part 1 Waste

Two days of pre-tests were used to set up the cameras in the school canteen at the disposal area
and to precisely define the process with the children: giving an individual label to be displayed on
the tray and visible when disposing the tray after the meal. Digital images of disposed trays were
automatically done with a camera set on a tripod with a distance of one meter at an angle of 45◦.
Pictures of foods were done after the meal (Figure 2). Extraction of a single image for each child was
manually done remotely at the office.

Nutrients 2019, 11, x FOR PEER REVIEW 5 of 10 

 

Table 2. Number of children by grade (boys/girls). * CLIS class (classe pour l'inclusion scolaire) is 

composed of children of different ages with school difficulties and training assistance. 

 1st Grade 2nd Grade 3rd Grade 4th Grade 5th Grade CLIS* Total 

Day 1 30 (14/16) 29 (13/16) 35 (20/15) 32 (13/19) 32 (18/14) 7 (4/3) 165 

Day 2 30 (16/14) 37 (18/19) 29 (19/10) 17 (6/11) 35 (19/16) 0 (0/0) 148 

Day 3 31 (12/19) 44 (19/25) 34 (20/14) 32 (14/18) 32 (18/14) 7 (5/2) 180 

Day 4 35 (15/20) 47 (20/27) 32 (19/13) 35 (13/22) 28 (14/14) 8 (5/3) 185 

Day 5 25 (11/14) 40 (16/24) 31 (21/10) n/a n/a 2 (1/1) 98 

Total 
151 (68/83) 

19.4% 

197 (86/111) 

25.4% 

161 (99/62) 

20.7% 

116 (46/70) 

14.9% 

127 (69/58) 

16.4% 

24 (15/9) 

3.1% 

776 (383/393) 

(50.6% girls) 

2.4. Part 1 Waste 

Two days of pre-tests were used to set up the cameras in the school canteen at the disposal area 

and to precisely define the process with the children: giving an individual label to be displayed on 

the tray and visible when disposing the tray after the meal. Digital images of disposed trays were 

automatically done with a camera set on a tripod with a distance of one meter at an angle of 45°. 

Pictures of foods were done after the meal (Figure 2). Extraction of a single image for each child was 

manually done remotely at the office. 

 

Figure 2. Example of the captured image of a disposed tray. 

For each child, each meal component was analyzed individually. The food remaining on the 

plate was evaluated as a percentage of the served quantity using a 5-point scale: 0, 1, 2, 3, or 4 

corresponding to 0%, 25%, 50%, 75% or 100% of the served portion. 

Waste was analyzed by food categories selected to be homogeneous in culinary terms: Raw 

vegetable (starter), Cooked vegetable served cold (starter), Starches (side dish), cooked vegetable 

served warm (side dish), main dish, dairy products, fruits, and desserts (Table 3). 

  

Figure 2. Example of the captured image of a disposed tray.

For each child, each meal component was analyzed individually. The food remaining on the plate
was evaluated as a percentage of the served quantity using a 5-point scale: 0, 1, 2, 3, or 4 corresponding
to 0%, 25%, 50%, 75% or 100% of the served portion.

Waste was analyzed by food categories selected to be homogeneous in culinary terms: Raw
vegetable (starter), Cooked vegetable served cold (starter), Starches (side dish), cooked vegetable
served warm (side dish), main dish, dairy products, fruits, and desserts (Table 3).



Nutrients 2019, 11, 2410 6 of 10

Table 3. Food items and food categories served during the 5 observation days.

Food Categories Food Items

1. Starter—Raw vegetable

Diced tomatoes
Grated carrots
Iceberg lettuce
Radishes with butter
Romaine Lettuce

2. Starter—Cooked vegetable served cold
Leeks
Zucchini with pesto

3. Starches
Chickpea salad
Creole Rice
Pasta Salad

4. Side dish—Cooked vegetable served warm
Eggplant gratin
Ratatouille
Swiss Chard gratin

5. Main dish

Breaded fish (hoki)
Fish filet (hoki) with cream sauce
Fish filet (lieu noir) with sauce
Plain Omelet
Shell Pasta with 5-cheese tomato sauce
Spaghetti Bolognaise

6. Dairy products

Blue cheese
Cheese specialty
Cottage cheese
Emmental cheese
Gouda
Mixed Fruit Yogurt

7. Fruits and desserts

Apple Sauce
Apple Tart
Apricot
Apricot Tart
Fruit Cocktail
Kiwi
Orange
Peach
Vanilla Muffins
Waffles

2.5. Part 2 Liking

The second part of the methodology consisted of exploring children’s reactions to the served dishes.
A subgroup of approximately 50 children per day, 10 children per grade, was interviewed after

meals to explore reasons for non-consumption and, more specifically, reasons for non-appreciation.
A total of 248 children (62% girls) were randomly selected from the children who left food on their tray.

The interview was a semi-structured one with two sections, one for the starter and one for the
main dish. The questions were: Which starter / main dish did you choose today? Did you enjoy it?
Had you had enough? too much? not enough? If not liked, why didn’t you like it?

The interviews allowed us to focus on dislikes through the forced categorization into two liking
categories (Liked or Disliked) and to develop reasons for dislikes.

A thematic analysis was conducted to interpret children discourses. Four categories were
determined after a first reading of collected verbatim interviews. Three categories are sensory ones:
appearance, taste and flavor, texture; one category concerns one food component often cited as rejection
cause: the sauce.



Nutrients 2019, 11, 2410 7 of 10

2.6. Statistics

A one-way ANOVA was performed to evaluate the difference of waste scores and a Chi Square
analysis to evaluate the proportion of likes and dislikes across the offered food range. A Pearson
coefficient was calculated to describe the correlation between waste and liking based on the 7 analyzed
food components (see Table 3). Statistical analyses were performed using XLSTAT 2015 (version
2015.4.01.22368, AddinsoftTM).

3. Results

3.1. Part 1. Waste

Vegetable dishes were significantly the most wasted food (F(ddl = 6) = 132,812, p < 0.0001)
especially cooked vegetables, either served warm as a side dish (66% wasted) or cold as a starter
(83% wasted). Vegetable dishes were less wasted when the vegetable was raw (42% wasted), e.g., salad
with dressing served as a starter. Other food components, main dish and starch or dairy product, fruit,
and dessert, were rather well consumed with wastage rates between 22% and 25% (see Figure 3).

Nutrients 2019, 11, x FOR PEER REVIEW 7 of 10 

 

2.6. Statistics 

A one-way ANOVA was performed to evaluate the difference of waste scores and a Chi Square 

analysis to evaluate the proportion of likes and dislikes across the offered food range. A Pearson 

coefficient was calculated to describe the correlation between waste and liking based on the 7 

analyzed food components (see Table 3). Statistical analyses were performed using XLSTAT 2015 

(version 2015.4.01.22368, Addinsoft™). 

3. Results 

3.1. Part 1 Waste 

Vegetable dishes were significantly the most wasted food (F(ddl = 6) = 132,812, p < 0.0001) 

especially cooked vegetables, either served warm as a side dish (66% wasted) or cold as a starter (83% 

wasted). Vegetable dishes were less wasted when the vegetable was raw (42% wasted), e.g., salad 

with dressing served as a starter. Other food components, main dish and starch or dairy product, 

fruit, and dessert, were rather well consumed with wastage rates between 22% and 25% (see Figure 

3). 

 

Figure 3. Mean rate of individual wastage of meal components (Error bars are standard deviations. 

Food with the same letter are not significantly different ANOVA 5% risk level). 

3.2. Part 2. Liking 

Interviewing children identified liked and disliked food components (Figure 4). The Chi Square 

statistics confirm observed differences (Chi²(6) = 317.16). Cooked vegetables served as starter or side 

dish were disliked whereas raw vegetables, main dishes, starches, dairy products, fruits and desserts 

were liked. 

Figure 3. Mean rate of individual wastage of meal components (Error bars are standard deviations.
Food with the same letter are not significantly different ANOVA 5% risk level).

3.2. Part 2. Liking

Interviewing children identified liked and disliked food components (Figure 4). The Chi Square
statistics confirm observed differences (Chi2(6) = 317.16). Cooked vegetables served as starter or side
dish were disliked whereas raw vegetables, main dishes, starches, dairy products, fruits and desserts
were liked.



Nutrients 2019, 11, 2410 8 of 10
Nutrients 2019, 11, x FOR PEER REVIEW 8 of 10 

 

 
Figure 4. Categories of likes/disliked food components. 

The thematic analysis of children’s discourse gave information on reasons for rejection. ‘Taste is 
the most-cited word, showing the importance of sensory characteristics in rejection. Two dishes were 
particularly disliked: the two recipes of cooked vegetable served as cold starters. For the leeks with 
dressing, taste mainly refers to texture of the slimy appearance. For the zucchini al pesto, it mainly 
refers to the unusual temperature (cold) and hardness. Moreover, both dishes are criticized regarding 
the sauce and the too-large quantity of sauce. Texture is often a major reason for food rejection [30]. 

Waste quantities are highly correlated with the liking status of foods. The Pearson coefficient of 
−0.997 (R2 = 0.994) is significant (n = 317, p < 0.0001). 

4. Discussion 

The present study was undertaken to study food selection and food waste in a typical French 
school lunch, with multiple courses of hot and cold foods, savory and sweet foods, using a 
photography method. Waste was measured using the 5-point quarter-waste scale [13]. As noted in 
previous research in the USA (see [2], for a review) and other countries [31], vegetables were the most 
wasted food category, especially cooked vegetables, which were wasted at rates of 66%–83%. Raw 
vegetables were still wasted more (42%) than main dishes, starch, dairy, fruit and desserts (22–25%). 

Similarly, vegetables were the most disliked food category, with the following classes of 
vegetables in the same order as for waste: cold cooked vegetable > side cooked vegetable > raw 
vegetable. Reasons for liking/disliking included sensory dimensions (e.g., “slimy”) and other reasons. 
There was a high correlation between waste and liking (p =< 0.0001). There is a strong connection 
between food liking and food consumption, but there is not yet strong research evidence identifying 
food disliking as the major reason for waste. However, numerous authors point to the importance of 
personal preferences in generating food waste and hopefully consumption, can be improved with 
design of school menus more in line with student preferences. 

This research supports the use of the 5-point quarter-waste method to measure food waste from 
photographs or online. Byker Shanks et al. (2017) [2] noted the problems arising from using a variety 
of scales to measure waste, and recommended more standardization of scales and methods. 

This research also supports the photographic method for measuring food waste. As noted above, 
weighed assessments of each food portion before and after a meal is time-consuming and labor-
intensive, while visual estimation of each food portion requires less time and labor, but requires 
trained observers. Both weighed assessments and visual estimation are difficult with large groups of 
people and with meals with many components. The photographic method is the only method where 
the meal images can be retained and checked later for validity and reliability. Further, the 

Figure 4. Categories of likes/disliked food components.

The thematic analysis of children’s discourse gave information on reasons for rejection. ‘Taste is
the most-cited word, showing the importance of sensory characteristics in rejection. Two dishes were
particularly disliked: the two recipes of cooked vegetable served as cold starters. For the leeks with
dressing, taste mainly refers to texture of the slimy appearance. For the zucchini al pesto, it mainly
refers to the unusual temperature (cold) and hardness. Moreover, both dishes are criticized regarding
the sauce and the too-large quantity of sauce. Texture is often a major reason for food rejection [30].

Waste quantities are highly correlated with the liking status of foods. The Pearson coefficient of
−0.997 (R2 = 0.994) is significant (n = 317, p < 0.0001).

4. Discussion

The present study was undertaken to study food selection and food waste in a typical French
school lunch, with multiple courses of hot and cold foods, savory and sweet foods, using a photography
method. Waste was measured using the 5-point quarter-waste scale [13]. As noted in previous research
in the USA (see [2], for a review) and other countries [31], vegetables were the most wasted food
category, especially cooked vegetables, which were wasted at rates of 66%–83%. Raw vegetables were
still wasted more (42%) than main dishes, starch, dairy, fruit and desserts (22–25%).

Similarly, vegetables were the most disliked food category, with the following classes of vegetables
in the same order as for waste: cold cooked vegetable > side cooked vegetable > raw vegetable. Reasons
for liking/disliking included sensory dimensions (e.g., “slimy”) and other reasons. There was a high
correlation between waste and liking (p =< 0.0001). There is a strong connection between food liking
and food consumption, but there is not yet strong research evidence identifying food disliking as the
major reason for waste. However, numerous authors point to the importance of personal preferences
in generating food waste and hopefully consumption, can be improved with design of school menus
more in line with student preferences.

This research supports the use of the 5-point quarter-waste method to measure food waste from
photographs or online. Byker Shanks et al. (2017) [2] noted the problems arising from using a variety
of scales to measure waste, and recommended more standardization of scales and methods.

This research also supports the photographic method for measuring food waste. As noted
above, weighed assessments of each food portion before and after a meal is time-consuming and
labor-intensive, while visual estimation of each food portion requires less time and labor, but requires
trained observers. Both weighed assessments and visual estimation are difficult with large groups of
people and with meals with many components. The photographic method is the only method where
the meal images can be retained and checked later for validity and reliability. Further, the photographic



Nutrients 2019, 11, 2410 9 of 10

method is not labor-intensive on the day of field testing; it is efficient in terms of space, personnel, and
required training.

5. Conclusions

The future of waste measurement in schools and in other eating contexts will probably utilize
automated analysis of food photographs. Future software will be able to automatically recognize food
items and measure food proportions remaining from standard serving sizes. However, the challenge
of measuring complex foods, complex food combinations, and foods in containers might continue.
This will help foodservice teams to adjust the offer to liked and consumed food and lower food waste
in the cafeteria. It also opens the path to build an educational program in school cafeterias to follow the
effect of actions such as exposure to foods in conjunction with adjustable portion sizes of less consumed
targeted food.

Author Contributions: A.G., D.M. and C.S. designed the study, C.S. supervised the study, A.G. and H.L.M. wrote
the article

Funding: This project was cofunded by the Institut Paul Bocuse Research Center, Bonduelle and Elior.

Acknowledgments: We would like to thank colleagues and students from the Institut Paul Bocuse: Stephen
Baldridge, Mélanie Ricci, Erica Pilgram, Remy Mondon, Fanny Jaillot as well as partners contributing to efficient
experiment setting and data collection in the school cafeterias: Laurence Depezay (Bonduelle), Christel Hanicotte
(Elior Restauration); Gratianne Dumas (City of Lyon) as well all other contributors on the field. We also thank
Bonduelle and Elior for the financial support of the study.

Conflicts of Interest: The authors declare no conflict of interest.

References

1. Appleton, K.; Hemingway, A.; Saulais, L.; Dinnella, C.; Monteleone, E.; Depezay, L.; Morizet, D.;
Perez-Cueto, F.J.A.; Bevan, A.; Hartwell, H. Increasing Vegetable Intakes: Rationale and Systematic
Review of Published Interventions. Eur. J. Nutr. 2016, 55, 869–896. [CrossRef] [PubMed]

2. Byker Shanks, C.; Banna, J.; Serrano, E.L. Food Waste in the National School Lunch Program 1978–2015:
A Systematic Review. J. Acad. Nutr. Diet. 2017, 17, 1792–1807. [CrossRef] [PubMed]

3. Smith, S.L.; Cunningham-Sabo, L. Food choice, plate waste and nutrient intake of elementary- and
middle-school students participating in the US National School Lunch Program. Public Health Nutr. 2013,
17, 1255–1263. [CrossRef] [PubMed]

4. Yoder, A.B.B.; Foecke, L.L.; Schoeller, D.A. Factors affecting fruit and vegetable school lunch waste in
Wisconsin elementary schools participating in Farm to School Programmes. Public Health Nutr. 2015, 18
(Suppl. 15), 2855–2863. [CrossRef] [PubMed]

5. Moreno-Black, G.; & Stockard, J. Salad bar selection patterns of elementary school children. Appetite 2018,
120, 136–144. [CrossRef] [PubMed]

6. McIntosh, W.A.; Dean, W.; Torres, C.C.; Anding, J.; Kubena, K.S.; Nayga, R. The American Family Meal.
In Meals in Science and Practice; Meiselman, H.L., Ed.; CRC Press: New York, NY, USA, 2009; pp. 190–218.

7. Makela, J.; Kjaernes, U.; Ekstrom, P. What did they eat. In Eating Patterns: A Day in the Lives of the Nordic
Peoples; Kjaernes, U., Ed.; National Institutes for Consumer Research: Lysaker, Norway, 2001; pp. 65–90.

8. Makela, J. The meal format. In Eating Patterns: A Day in the Lives of the Nordic Peoples; Kjaernes, U., Ed.;
National Institutes for Consumer Research: Lysaker, Norway, 2001; pp. 125–158.

9. de Saint Pol, T. Quand est-ce qu’on mange? Le temps des repas en France. Terrains et Travaux 2005, 9, 51–72.
10. Fischler, C.; Masson, E. Manger: Français, Européens et Américains face à L’alimentation; Odile Jacob: Paris,

France, 2008; p. 336.
11. Ministère de l’économie, de l’Industrie et du numérique. Recommandation Nutrition. Groupe d’Etude Des

Marchés de Restauration Collective et Nutrition GEM-RCN; Ministère de l’économie, de l’Industrie et du
numérique: Paris, France, 2015.

12. ADEME Réduire le gaspillage alimentaire en restauration collective. Guide Pratique de L’agence de et la Maîtrise
de L’énergie; Ademe éditions: Angers, France, 2018.

http://dx.doi.org/10.1007/s00394-015-1130-8
http://www.ncbi.nlm.nih.gov/pubmed/26754302
http://dx.doi.org/10.1016/j.jand.2017.06.008
http://www.ncbi.nlm.nih.gov/pubmed/28807638
http://dx.doi.org/10.1017/S1368980013001894
http://www.ncbi.nlm.nih.gov/pubmed/23866827
http://dx.doi.org/10.1017/S1368980015000385
http://www.ncbi.nlm.nih.gov/pubmed/25728060
http://dx.doi.org/10.1016/j.appet.2017.08.034
http://www.ncbi.nlm.nih.gov/pubmed/28864255


Nutrients 2019, 11, 2410 10 of 10

13. Hanks, A.S.; Wansink, B.; Just, D.R. Reliability and Accuracy of Real-Time Visualization Techniques for
Measuring School Cafeteria Tray Waste: Validating the Quarter-Waste Method. J. Acad. Nutr. Diet. 2014,
114, 470–474. [CrossRef]

14. Williamson, D.A.; Allen, H.R.; Martin, P.D.; Alfonso, A.J.; Gerald, B.; Hunt, A. Comparison of digital
photography to weighed and visual estimation of portion sizes. J. Am. Diet. Assoc. 2003, 103, 1139–1145.
[CrossRef]

15. Martins, L.M.; Cunha, L.M.; Rodrigues, S.P.; Rocha, A. Determination of plate waste in primary school
lunches by weighing and visual estimation methods: A validation study. Waste Manag. 2014, 34, 1362–1368.
[CrossRef]

16. Sabinsky, M.S.; Toft, U.; Andersen, K.K.; Tetens, I. Validation of a digital photographic method for assessment
of dietary quality of school lunch sandwiches brought from home. Food Nutr. Res. 2013, 57, 20243. [CrossRef]

17. Byker, C.J.; Farris, A.R.; Marcenelle, M.; Davis, G.C.; Serrano, E.L. Serrano Food Waste in a School Nutrition
Program After Implementation of New Lunch Program Guidelines. J. Nutr. Educ. Behav. 2014, 46, 406–411.
[CrossRef] [PubMed]

18. Kandiah, J.; Stinnett, L.; Lutton, D. Visual plate waste in hospitalized patients: Length of stay and diet order.
J. Am. Diet. Assoc. 2006, 106, 1663–1666. [CrossRef] [PubMed]

19. Hiesmayr, M.; Schindler, K.; Pernicka, E.; Schuh, C.; Schoeniger-Hekeler, A.; Bauer, P.; Laviano, A.; Lovell, A.;
Mouhieddine, M.; Schuetz, T.; et al. Decreased food intake is a risk factor for mortality in hospitalised
patients: The Nutrition Day survey 2006. Clin. Nutr. 2009, 28, 484–491. [CrossRef] [PubMed]

20. Graves, K.; Shannon, B. Using visual plate waste measurement to assess school lunch food behaviour. J. Am.
Diet. Assoc. 1983, 82, 163–165. [PubMed]

21. Comstock, E.M.; St Pierre, R.G.; Mackiernan, Y.D. Measuring individual plate waste in school lunches. Visual
estimation and children’s ratings vs. actual weighing of plate waste. J. Am. Diet. Assoc. 1981, 79, 290–296.
[PubMed]

22. Navarro, D.A.; Boaz, M.; Krause, I.; Eli, A.; Chernov, K.; Giabra, M.; Frishman, S.; Levy, M.; Giboreau, A.;
Kosak, S.; et al. Improved meal presentation increases food intake and decreases readmission rate in
hospitalized patients. Clin. Nutr. 2016, 35, 1153–1158. [CrossRef]

23. Sherwin, A.; Nowson, C.; McPhee, J.; Alexander, J.; Wark, J.; Flicke, L. Nutrient intake at meals in residential
care facilities for the aged: Validated visual estimation of plate waste. Aust. J. Nutr. Diet. 1998, 55, 188–193.

24. Martin, C.K.; Nicklas, T.; Gunturk, B.; Correa, J.B.; Allen, H.R.; Champagne, C. Measuring food intake with
digital photography. J. Hum. Nutr. Diet. 2014, 27, 72–81. [CrossRef]

25. Christoph, M.J.; Loman, B.R.; Ellison, B. Developing a digital photography-based method for dietary analysis
in self-serve dining settings. Appetite 2017, 114, 217–225. [CrossRef]

26. Taylor, J.C.; Sutter, C.; Ontai, L.L.; Nishina, A.; Zidenberg-Cherr, S. Feasibility and reliability of digital
imaging for estimating food selection and consumption from students’ packed lunches. Appetite 2018,
120, 196–204. [CrossRef]

27. Pouyet, V.; Cuvelier, G.; Benattar, L.; Giboreau, A. A photographic method to measure food item intake.
Validation in geriatric institutions. Appetite 2015, 84, 11–19. [CrossRef] [PubMed]

28. Hubbard, K.L.; Bandini, L.G.; Folta, S.C.; Wansink, B.; Eliasziw, M.; Must, A. Impact of a Smarter Lunch- room
intervention on food selection and consumption among adolescents and young adults with intellectual and
developmental disabilities in a residential school setting. Public Health Nutr. 2015, 18, 361–371. [CrossRef]
[PubMed]

29. Getts, K.M. Measuring Plate Waste: Validity and Inter-Rater Reliability of the Quarter-Waste Method.
Master’s Thesis, University of Washington, Washington, DC, USA, 2015.

30. Egolf, A.; Siegrist, M.; Hartmann, C. How people’s food disgust sensitivity shapes their eating and food
behaviour. Appetite 2018, 127, 28–36. [CrossRef] [PubMed]

31. Falasconi, L.; Vittuari, M.; Politano, A.; Segre, A. Food Waste in School Catering: An Italian Case Study.
Sustainability 2015, 7, 14745–14760. [CrossRef]

© 2019 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access
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(CC BY) license (http://creativecommons.org/licenses/by/4.0/).

http://dx.doi.org/10.1016/j.jand.2013.08.013
http://dx.doi.org/10.1016/S0002-8223(03)00974-X
http://dx.doi.org/10.1016/j.wasman.2014.03.020
http://dx.doi.org/10.3402/fnr.v57i0.20243
http://dx.doi.org/10.1016/j.jneb.2014.03.009
http://www.ncbi.nlm.nih.gov/pubmed/24857599
http://dx.doi.org/10.1016/j.jada.2006.07.015
http://www.ncbi.nlm.nih.gov/pubmed/17000200
http://dx.doi.org/10.1016/j.clnu.2009.05.013
http://www.ncbi.nlm.nih.gov/pubmed/19573957
http://www.ncbi.nlm.nih.gov/pubmed/6822701
http://www.ncbi.nlm.nih.gov/pubmed/7264115
http://dx.doi.org/10.1016/j.clnu.2015.09.012
http://dx.doi.org/10.1111/jhn.12014
http://dx.doi.org/10.1016/j.appet.2017.03.050
http://dx.doi.org/10.1016/j.appet.2017.08.037
http://dx.doi.org/10.1016/j.appet.2014.09.012
http://www.ncbi.nlm.nih.gov/pubmed/25261733
http://dx.doi.org/10.1017/S1368980014000305
http://www.ncbi.nlm.nih.gov/pubmed/24636533
http://dx.doi.org/10.1016/j.appet.2018.04.014
http://www.ncbi.nlm.nih.gov/pubmed/29680195
http://dx.doi.org/10.3390/su71114745
http://creativecommons.org/
http://creativecommons.org/licenses/by/4.0/.

	Introduction 
	Different Methods to Measure Waste 
	Photographic Methods 
	Food Consumption and Waste in School Canteens 

	Materials and Methods 
	General Procedure 
	Ethics 
	Participants 
	Part 1 Waste 
	Part 2 Liking 
	Statistics 

	Results 
	Part 1. Waste 
	Part 2. Liking 

	Discussion 
	Conclusions 
	References