Front. Pediatr.Frontiers in PediatricsFront. Pediatr.2296-2360Frontiers Media S.A.10.3389/fped.2018.00134PediatricsOriginal ResearchDoes Eating Vegetables at Start of Meal Prevent Childhood Overweight in Japan? A-CHILD StudyTaniYukako12FujiwaraTakeo1*OchiManami3IsumiAya1KatoTsuguhiko41Department of Global Health Promotion, Tokyo Medical and Dental University (TMDU), Tokyo, Japan2Japan Society for the Promotion of Science, Tokyo, Japan3Japan Support Center for Suicide Countermeasures, National Institute of Mental Health, National Center of Neurology and Psychiatry, Tokyo, Japan4Department of Social Medicine, National Center for Child Health and Development, Tokyo, Japan
Reviewed by: Ameer Ahmad, Quaid-i-Azam Medical College, Bahawalpur, Pakistan; E. Lisako J. McKyer, School of Public Health, Texas A&M University College Station, United States
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Background: Because eating behaviors are established early in life, it is important to instill healthy eating habits in children. However, no published studies have examined the effects of what is habitually consumed first at a meal on children's body weight in real settings. The aim of this study was to examine the associations between what was consumed (vegetables, rice/bread, meat/fish, or soup) at the start of a meal and childhood overweight in Japan.
Methods: We used cross-sectional data from the Adachi Child Health Impact of Living Difficulty (A-CHILD) study, a population-based study comprising all first-grade students in Adachi City, Tokyo, Japan, performed in 2015. Through a questionnaire, we identified what types of food children ate first at meals. The questionnaire was completed by 4,040 caregivers. We used corresponding school health check-up data (height and weight) to assess overweight in each child.
Results: The proportions of what was consumed first at a meal were 11.6, 23.3, 25.4, 9.8, and 29.9% for vegetables, meat/fish, rice/bread, soup, and undetermined (variable), respectively. Multivariate logistic regression showed the odds ratio of being overweight was 1.83 in children who ate meat/fish first (95% CI: 1.27–2.64, p < 0.01) compared with children who ate vegetables first. In contrast, the odds ratios in children who consumed rice/bread or soup first compared with children who ate vegetables first were 1.11 (95% CI: 0.76–1.61, p = 0.59) and 1.29 (95% CI: 0.83–2.01, p = 0.26), respectively.
Conclusion: Children who eat meat/fish at the start of a meal are more likely to be overweight than those who eat vegetables at the start of a meal. Future studies are needed to investigate the mechanisms of how the order in which food is consumed at a meal affects weight status in children.
eating behaviororder of food consumedfood sequencingbehavioral economicschildhood obesityMinistry of Health, Labour and Welfare10.13039/501100003478Japan Society for the Promotion of Science10.13039/501100001691Introduction
The prevalence of childhood overweight and obesity has increased worldwide in recent decades and it has become a major public health epidemic (1–3). Between 1980 and 2013, the prevalence of overweight and obesity in developed countries has increased from 16.9 to 23.8% in boys and from 16.2 to 22.6% in girls (3). Overweight and obese children are likely to stay obese into adulthood (4–6), and have greater risk of heart disease, type 2 diabetes, stroke, and premature death and disability in adulthood (7, 8). Furthermore, children nowadays are more likely to become overweight at a younger age (9). Therefore, prevention of overweight in young children is important.
Although several risk factors for childhood overweight have been identified (10), the effectiveness of intervention programs has been minor and short-term (11). There is a need to establish a feasible and effective strategy against childhood overweight using an alternative approach. A notable example is the “CAN Approach,” which is based on the practice of making healthy foods more convenient, attractive, and normative. This method nudges healthy food choices through behavioral economic theories of decision-making (12). For example, placing the healthiest food first and the least healthy food last at a buffet spread nudged people to select healthier meals, due to a high percentage of people taking the first available food (13). Similarly, the order of food consumption at meals can be habitual in conjunction with mealtime socialization (14), and this seems to be a normative choice for children. Therefore, we hypothesized that eating vegetables first at meals may increase vegetable intake, which aids in the prevention of overweight.
The order of food consumption may have an effect on overweight by changing the amount of food consumed during the rest of the meal. Some controlled studies in adults have shown that eating low energy density food first (vegetables, soup, or fruit) reduces total meal energy intake (15–17). Furthermore, Roe et al. reported that consuming low energy density salad before, rather than with, the main course increases total vegetable consumption (18).
The order of food consumption may also affect overweight and obesity by changing postprandial digestibility and metabolic effects. Glycemic excursions and incremental glucose peaks are reportedly significantly smaller when vegetables are consumed before carbohydrate foods compared with the reverse sequence (19). This may be due to the fiber in vegetables, which affects the speed of digestion and the amount of insulin needed for subsequent metabolic disposal (20).
Eating patterns established in early life tend to persist into adolescence and adulthood (21–23). Therefore, it is important to instill healthy eating habits in children. To date, however, no published studies have examined the effects of order of food consumption at meals on children's body weight in real settings.
In Japan, a typical meal—known as “ichi-ju san-sai”—consists of a staple food (such as rice), a soup (usually miso), and three dishes (one main side dish and two side dishes). The food is served all at once (24). Therefore, the order of food consumption at a meal can vary significantly among individuals.
To that end, a health promotion strategy known as “Eat Vegetables First at Meals” was launched in Adachi City in Tokyo, Japan, in 2013 to address various health problems. Specifically, the municipality focused on children in public daycare centers. To assess the impact of this health promotion policy, a questionnaire survey concerning eating habits of children in Grade 1 in Adachi City was implemented. The responses to the questionnaire was linked with school health checks data, including objective assessments of height and weight.
The purpose of the present study was to use this population-based sample to examine the associations between the order of food consumption at a meal in Grade 1 elementary school children and their overweight status in Japan.
Materials and methodsStudy design and subjects
We used data from the Adachi Child Health Impact of Living Difficulty (A-CHILD) study performed in Adachi City, Tokyo, Japan, in 2015 (25). The survey covered all 69 public elementary schools in Adachi City. Between July 2015 and November 2015, self-reported questionnaires with anonymous unique ID were distributed to 5,355 children in the first grade of elementary school (aged 6 to 7 years). Children were asked to pass on the questionnaires to their caregivers at home to fill out. The children then returned the completed questionnaires to their school. A total of 4,467 questionnaires were returned (response rate: 83.4%) and 4,291 of the responding caregivers provided informed consent to include their child in the study (25). Questionnaire responses were linked to each participating child's school health check-up data from the same year (linkage rate: 100%) to determine their body mass indexes (BMI). The analyses were carried out using the data of 4,040 participants after excluding the following: (i) potential participants whose sex, date of birth, or body weight status were missing (n = 189); and (ii) potential participants whose caregivers had not answered the questions about what was consumed first (n = 62). The A-CHILD protocol was approved by the Ethics Committee of the National Center for Child Health and Development (No. 1187). All participants gave written informed consent in accordance with the Declaration of Helsinki.
Child body weight status
School teachers assessed elementary school children's height and weight during health check-ups according to a standardized protocol (26). Height was measured to the nearest 0.1 cm using a portable stadiometer, and weight to the nearest 0.1 kg on a digital scale without shoes and wearing light clothing. BMI was calculated from weight (in kilograms) over square of height (in meters). BMI was expressed as z-score representing the deviation in standard deviation units from the mean of a standard normal distribution of BMI specific to age and sex according to the standard of the WHO Child Growth Standards. Children were categorized as non-overweight or overweight using +1 standard deviation cut-off points (27).
Order of food consumption
What was consumed first at meals over the past month was assessed using the following question: “What does your child eat first at mealtimes? Circle the answer that best applies for the past month.” The responses to this question were “vegetables,” “meat/fish,” “rice/bread (staple),” “soup,” or “not determined (variable).”
Covariates
Because the “Eat Vegetables First at Meals” campaign was launched prior to our study, adjustments were made for the preschool status (public nursery, private nursery, or private kindergarten) of each child. Potential confounders of the association between what is consumed first at meals and overweight were assessed by questionnaires completed by caregivers.
The children's physical activity was assessed according to the frequency of being physically active for half an hour or more, and was categorized into four groups (never/rarely, 1–2, 3–4, or ≥5 times/week). The status of the responder to the questionnaire was categorized into two groups (mother or father).
Marital status of caregivers was categorized into two groups (married/common-law marriage or unmarried/divorced/bereavement). Annual normalized household income was determined from the household income and the number of household members and divided into three categories (<2.50, 2.50–3.49, or ≥3.50 million yen).
Family meal status during dinner (children eating with family or only with other children/alone) was included in the analysis because family meals are related to children's eating patterns and body weight status (28). Because children are largely cared for by their mothers and only 10% of fathers take care of children's meals in Japan (29), mother's characteristics were included: age (<30, 30–39, or ≥40 years), educational status (low: junior high school/high school; middle: technical/junior college/college dropout; or high: college/graduate school), and employment status (full-time, part-time, self-employed, side job, or unemployed). Participating children's BMI at age 3 years was calculated using the height and weight reported by their caregivers. BMI was expressed as z-score representing the deviation in standard deviation units from the mean of a standard normal distribution of BMI specific to age and sex according to the standard of the WHO Child Growth Standards. Children were categorized as non-overweight or overweight using +1 standard deviation cut points (30). Mothers' and fathers' BMI were calculated using their self-reported heights and weights. Standard categories of BMI (31) were used to characterize parents as obese (BMI ≥ 30.0 kg/m2), overweight (BMI = 25.0–29.9 kg/m2), normal (BMI = 18.5–24.9 kg/m2), and underweight (BMI < 18.5 kg/m2).
Statistical analysis
First, χ2-tests were used to assess participants' characteristics and differences in what is consumed first at meals. Second, the association between what is consumed first at meals and the overweight status of each child was evaluated using logistic regression analysis to calculate the adjusted odds ratios (OR) with 95% confidence intervals (CI). The following sequence of models was constructed: Model 1 was adjusted for the sex of each child; Model 2 was additionally adjusted for each child's physical activity and preschool status, each respondent's (parent's) status and marital status, annual normalized household income, family meal, mother's age, mother's education and mother's employment; and Model 3 was further adjusted for each child's BMI at 3 years, and mother's and father's BMI. All analyses were conducted using STATA version 13 (Stata Statistical Software: Release 13. College Station, TX: StataCorp LP).
Results
Overall, the proportions of what was consumed first at meals were 11.6, 23.3, 25.4, 9.8, and 29.9% for vegetables, meat/fish, rice/bread, soup, and not determined, respectively (Table 1). Of the participating children, 13.5% were overweight. Most respondents were mothers (90.7%). The proportions of preschool status were 14.0%, 25.9%, and 55.8% for private nursery, public nursery, and private kindergarten, respectively. Of the children who ate vegetables first at meals, 30.2% previously attended public nurseries, whereas 22.9% of children who ate meat/fish first at meals previously attended public nurseries.
Characteristics of participating Japanese school children and their caregivers (n = 4040).
Total
Food consumed first
χ2
p-value
Vegetables
Meat/Fish
Rice/Bread
Soup
Not determined
n
%
n
%
n
%
n
%
n
%
n
%
CHILD-RELATED CHARACTERISTICS
Food consumed first
Vegetables
470
11.6
470
100
Meat/Fish
943
23.3
943
100
Rice/Bread
1,024
25.4
1024
100
Soup
396
9.8
396
100
Not determined
1,207
29.9
1207
100
Sex
Boy
2,089
51.7
213
45.3
571
60.6
540
52.7
192
48.5
573
47.5
48.0
<0.001
Girl
1,951
48.3
257
54.7
372
39.4
484
47.3
204
51.5
634
52.5
Body weight status (BMI for age z score)
Normal (<1SD)
3,495
86.5
419
89.1
772
81.9
895
87.4
342
86.4
1,067
88.4
24.6
<0.001
Overweight (≥1SD)
545
13.5
51
10.9
171
18.1
129
12.6
54
13.6
140
11.6
Physical activity
Never/rarely
410
10.1
34
7.2
91
9.7
116
11.3
44
11.1
125
10.4
18.8
0.28
1–2 times/weeks
1,832
45.3
216
46
408
43.3
494
48.2
177
44.7
537
44.5
3–4 times/weeks
1,068
26.4
135
28.7
266
28.2
241
23.5
96
24.2
330
27.3
≥5 times/weeks
718
17.8
83
17.7
175
18.6
169
16.5
78
19.7
213
17.6
Missing
12
0.3
2
0.4
3
0.3
4
0.4
1
0.3
2
0.2
Preschool status
Public nursery
1,045
25.9
142
30.2
216
22.9
267
26.1
122
30.8
298
24.7
27.4
0.01
Private nursery
566
14
65
13.8
122
12.9
155
15.1
57
14.4
167
13.8
Private kindergarten
2,253
55.8
241
51.3
560
59.4
558
54.5
193
48.7
701
58.1
Other/none/missing
176
4.4
22
4.7
45
4.8
44
4.3
24
6.1
41
3.4
Body weight status at 3 age years (BMI for age z score)
Normal (<1SD)
2,804
69.4
327
69.6
656
69.6
707
69
269
67.9
845
70
4.8
0.78
Overweight (≥1SD)
691
17.1
80
17
171
18.1
168
16.4
65
16.4
207
17.1
Missing
545
13.5
63
13.4
116
12.3
149
14.6
62
15.7
155
12.8
RESPONDENT'S STATUS
Mother
3,664
90.7
445
94.7
846
89.7
922
90
366
92.4
1,085
89.9
14.8
0.06
Father
308
7.6
20
4.3
84
8.9
82
8
24
6.1
98
8.1
Other/missing
68
1.7
5
1.1
13
1.4
20
2
6
1.5
24
2
HOUSEHOLD-RELATED CHARACTERISTICS
Marital status of caregiver
Married/common-law marriage
3,581
88.6
423
90
842
89.3
909
88.8
345
87.1
1,062
88
3.7
0.89
Unmarried/divorced/bereavement
338
8.4
35
7.4
76
8.1
86
8.4
35
8.8
106
8.8
Other/missing
121
3
12
2.6
25
2.7
29
2.8
16
4
39
3.2
Annual normalized household income (million yen)
Low (<2.50)
1,557
38.5
164
34.9
352
37.3
388
37.9
150
37.9
503
41.7
17.2
0.14
Middle (2.50–3.49)
1,056
26.1
130
27.7
245
26
264
25.8
97
24.5
320
26.5
High (≥3.50)
1,028
25.4
137
29.1
254
26.9
264
25.8
106
26.8
267
22.1
Missing
399
9.9
39
8.3
92
9.8
108
10.5
43
10.9
117
9.7
Family meal
Children eat with family
3,890
96.3
454
96.6
903
95.8
981
95.8
386
97.5
1166
96.6
6.7
0.57
Children eat separately
145
3.6
15
3.2
40
4.2
41
4
9
2.3
40
3.3
Missing
5
0.1
1
0.2
0
0
2
0.2
1
0.3
1
0.1
CAREGIVER-RELATED CHARACTERISTICS
Mother's age (years)
<30
212
5.2
20
4.3
47
5
55
5.4
23
5.8
67
5.6
13.5
0.34
30–39
2,086
51.6
243
51.7
478
50.7
509
49.7
201
50.8
655
54.3
≥40
1,639
40.6
193
41.1
402
42.6
429
41.9
158
39.9
457
37.9
Missing
103
2.5
14
3
16
1.7
31
3
14
3.5
28
2.3
Mother's education
Junior high school/high school
1,447
35.8
145
30.9
334
35.4
364
35.5
149
37.6
455
37.7
16.3
0.18
Technical/Junior college/college dropout
1,663
41.2
191
40.6
402
42.6
424
41.4
167
42.2
479
39.7
Collage/graduate school
819
20.3
118
25.1
181
19.2
203
19.8
71
17.9
246
20.4
Other/missing
111
2.7
16
3.4
26
2.8
33
3.2
9
2.3
27
2.2
Mother's employment
Full-time
775
19.2
99
21.1
176
18.7
205
20
93
23.5
202
16.7
25.3
0.19
Part-time
1,498
37.1
167
35.5
351
37.2
385
37.6
159
40.2
436
36.1
Self-employed
198
4.9
25
5.3
43
4.6
45
4.4
13
3.3
72
6
Side work
77
1.9
5
1.1
18
1.9
23
2.2
6
1.5
25
2.1
Not employed
1,388
34.4
163
34.7
332
35.2
337
32.9
117
29.5
439
36.4
Other/missing
104
2.6
11
2.3
23
2.4
29
2.8
8
2
33
2.7
Mother's BMI
Underweight (BMI<18.5)
525
13
73
15.5
107
11.3
130
12.7
61
15.4
154
12.8
26.1
0.05
Normal (18.5≤BMI<25.0)
2,831
70.1
323
68.7
688
73
707
69
274
69.2
839
69.5
Overweight (25.0≤BMI<30.0)
351
8.7
45
9.6
79
8.4
99
9.7
34
8.6
94
7.8
Obesity(BMI≥30.0)
72
1.8
5
1.1
19
2
15
1.5
2
0.5
31
2.6
Missing
261
6.5
24
5.1
50
5.3
73
7.1
25
6.3
89
7.4
Father's BMI
Underweight (BMI<18.5)
83
2.1
12
2.6
19
2
24
2.3
6
1.5
22
1.8
14.8
0.54
Normal (18.5≤BMI<25.0)
2,330
57.7
282
60
542
57.5
590
57.6
234
59.1
682
56.5
Overweight (25.0≤BMI<30.0)
856
21.2
96
20.4
210
22.3
217
21.2
80
20.2
253
21
Obesity (BMI≥30.0)
144
3.6
7
1.5
36
3.8
31
3
18
4.5
52
4.3
Missing
627
15.5
73
15.5
136
14.4
162
15.8
58
14.6
198
16.4
BMI, body mass index; SD, standard deviation.
After adjusting for each child's sex, children who ate meat/fish first at meals were 1.82 times (95% CI: 1.30–2.54, p < 0.001) more likely to be overweight than those who ate vegetables first at meals (Model 1, Table 2). In contrast, the OR in children who ate rice/bread or soup first at first compared with children who ate vegetables first at meals were 1.18 (95% CI: 0.84–1.67, p = 0.34) and 1.30 (95% CI: 0.86-1.95, p = 0.21), respectively (Model 1, Table 2). Adjusting for each child's physical activity, preschool status, each respondent's (parent's) status and marital status, annual normalized household income, mother's age, mother's education, mother's employment and family meal, the OR in children who ate meat/fish first was slightly lower, but remained significant (1.80; 95% CI: 1.28–2.54, p < 0.01) (Model 2). Subsequent adjustment for each child's BMI at age 3 years and mother's and father's BMI did not weaken the association (1.83; 95% CI: 1.27–2.64, p < 0.01) (Model 3).
Adjusted odds ratios for overweight status according to the food consumed first by Japanese school children (n = 4040).
Model 1
Model 2
Model 3
Overweight
Overweight
Overweight
OR (95%CI)
p-value
OR (95%CI)
p-value
OR (95%CI)
p-value
FOOD CONSUMED FIRST
Vegetables
Reference
Reference
Reference
Meat/Fish
1.82 (1.30–2.54)
<0.001
1.80 (1.28–2.54)
<0.01
1.83 (1.27–2.64)
<0.01
Rice/Bread
1.18 (0.84–1.67)
0.34
1.14 (0.80–1.61)
0.46
1.11 (0.76–1.61)
0.59
Soup
1.30 (0.86–1.95)
0.21
1.23 (0.81–1.85)
0.33
1.29 (0.83–2.01)
0.26
Not determined
1.08 (0.77–1.51)
0.67
1.06 (0.75–1.50)
0.74
0.99 (0.68–1.43)
0.95
OR, odds ratio; CI, confidence interval. Model 1: Adjusted for child's sex. Model 2: Model 1 + adjusted for child's physical activity, preschool status, respondent status, marital status, annual normalized household income, family meal, mother's age, mother's education and mother's employment. Model 3: Model 2 + adjusted for child's body weight status at age 3 years, mother's and father's BMI.
Discussion
In this study, we found that children who habitually eat meat/fish first at meals are more likely to be overweight than those who eat vegetables first. In contrast, the effects of eating rice/bread or soup first on overweight did not differ significantly from that of eating vegetables first. To our knowledge, this is the first study to examine the effect of what is consumed first at meals on body weight status in children in a real setting.
There are several possible explanations for our findings. One possibility is that eating low energy density food (vegetables) first at meals may better promote satiety and reduce energy intake over the course of the meal compared with eating high energy density food (meat/fish) first. Indeed, a suggested strategy for enhancing satiety and reducing energy intake is to consume a filling portion of low energy density food, such as vegetables or salad, as a first course (32). Furthermore, in a single-meal study, serving children a low energy density, vegetable-based soup as a first course was associated with less energy intake from the more energy dense main course (33). In adults, consuming low energy density salads is associated with less energy intake over a meal than having no first course (15).
These findings are consistent with our present study, which found that the effect on overweight of eating soup, a low energy-density food, first did not differ significantly from that of eating vegetables first. In addition to vegetables, eating other low energy density foods (such as soup or fruit) as a first course is also associated with eating less of a higher energy density main course and less energy intake over the course of the meal (16, 17). In several multiple-meal studies of both adults and children, reducing the energy density of multiple meals over 2 days resulted in decreased cumulative energy intake (34, 35), suggesting that reducing the energy density of multiple meals leads to persistent and habitual decreases in energy intake from meals. This may in turn contribute to the prevention of overweight. Future studies are needed to investigate energy intake over a meal to clarify the mechanisms of the effect of food sequencing on overweight.
Another possibility is that eating vegetables first provides greater opportunity to eat more vegetables. In a crossover design, serving vegetables or vegetable-based-soup as a first course was associated with increased total vegetable consumption over the meal by children (33, 36). Children typically like fatty and sugary foods and dislike vegetables (37) because they innately prefer sweet and salty foods and reject sour and bitter foods (38). One Japanese study showed that vegetables were the most disliked of all foods in school lunches and that dislike was the main reason for leftovers among primary school children (39). Therefore, children who eat meat/fish first may leave more vegetables than those who eat vegetables first.
Furthermore, our measure of what was consumed first at meals may act as a proxy for the habitual quality of family meals. For example, the frequency of vegetables being served as part of family meals may be higher among children who eat vegetables first, and may in fact result in these children acquiring the habit of eating vegetables first. We found the prevalence of eating vegetables at both breakfast and dinner (over a month) was higher in children who ate vegetables first than in those who ate meat/fish first (48 vs. 31%, respectively; p < 0.001). Additionally, the consumption of obesity-related foods (juice, dessert, etc.) may be higher in children who eat meat/fish first. Further studies on the habitual quality of meals are needed to explore this possibility.
Eating rice/bread first at meals did not differ significantly from eating vegetables first in terms of the impact on overweight. Because eating vegetables before carbohydrates is associated with smaller glycemic excursions and glucose peaks than the reverse sequence (19), we hypothesized that eating vegetables first at meals would better protect against overweight than eating carbohydrates (rice/bread) first. However, the effects of eating vegetables first may not have depended on digestibility and metabolic effects in the present setting. The mechanisms underlying the differences in effects of what is consumed first still require further investigation.
This study has several limitations. First, we did not explore the validity or reliability of the question assessing what is consumed first at meals. We collected information on what children ate first from their caregivers. Therefore, the responses may have been biased due to the caregivers' perception. Social desirability bias may also have skewed the caregivers' responses. Nonetheless, we confirmed what was consumed first did not differ according to the caregiver's social status (marital status, income, mother's age, education, and employment), and the prevalence of eating vegetables first was higher in children from public nurseries, where a habituation policy of eating vegetables first had been implemented. Second, we lacked information on the amount of food that was consumed first. Therefore, we included children who ate both large and small amounts of vegetables first in the same category. For example, the “vegetables first” category may include children who had a bite of vegetables at the beginning of meals but ate the rest of the vegetables later. However, our hypothesis is not about the effectiveness of the amount of vegetables consumed first, but rather the habit of eating vegetables first, which leads to a higher frequency of eating vegetables. Future studies should aim to elucidate the mechanism by which habitually eating vegetables first increases the frequency or amount of vegetables consumed, which eventually prevents overweight among children. Third, because we lacked information on factors such as children's food preferences and caregivers' knowledge about nutrition, we may not have taken all confounding factors into account. For example, caregivers who know a lot about nutrition may not only pay attention to what their children eat, but may also teach them to eat vegetables first. Fourth, despite the difference in the nutritional value of fish and meat (chicken, red meat, etc.), we grouped these food categories together. Future study should divide these categories to clarify the mechanism of the effect of eating meat and fish first on overweight. Finally, we did not assess energy intake or physical exercise, and the study design was cross-sectional. Hence, the mechanism by which the habit of eating vegetables first prevents overweight among children is yet to be uncovered.
In conclusion, what was consumed first at meals was associated with children's body weight status. Based on the theories of behavioral economics, the habitual behavior of avoiding meat/fish first may nudge children to eat better. This strategy may be useful for “non-course-meal” culture in which all dishes are served at one time, such as the meals typically served in Japan. Further studies measuring total daily and mealtime energy intake, energy per food category, energy expenditure, food preferences, glucose metabolism, and satiety responsiveness based on food group order are warranted to determine whether and how eating vegetables first actually prevents childhood overweight.
Author contributions
YT and TF conceived the design. TF, MO, AI, and TK collected data. YT reviewed literature and analyzed data. YT wrote first draft of paper. TF revised the first draft. MO, AI, and TK edited the manuscript. All authors approved the final version of the manuscript.
Conflict of interest statement
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
We are particularly grateful to the staff members and central office of Adachi City Hall for conducting the survey. We would like to thank everyone who participated in the surveys. In particular, we would also like to thank Mayor Yayoi Kondo, Mr. Syuichiro Akiu, Mr. Hideaki Otaka, and Ms. Yuko Baba of Adachi City Hall, all of whom contributed significantly to completion of this study.
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Funding. This study was supported by a Health Labour Sciences Research Grant, Comprehensive Research on Lifestyle Disease from the Japanese Ministry of Health, Labour and Welfare (H27-Jyunkankito-ippan-002), and Grants-in-Aid for Scientific Research from the Japan Society for the Promotion of Science (JSPS KAKENHI Grant Number 16H03276, 16K16295, and 16J11423), St. Luke's Life Science Institute Grants, and the Japan Health Foundation Grants.