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Erschienen in: BMC Cardiovascular Disorders 1/2020

Open Access 01.12.2020 | Research article

Is frequency of potato and white rice consumption associated with cardiometabolic risk factors in children and adolescents: the CASPIAN-V study

verfasst von: Fereshteh Baygi, Mostafa Qorbani, Mohammad Esmaeil Motlagh, Gita Shafiee, Kourosh Nouri, Zeinab Ahadi, Armita Mahdavi-Gorab, Ramin Heshmat, Roya Kelishadi

Erschienen in: BMC Cardiovascular Disorders | Ausgabe 1/2020

Abstract

Background

This study evaluated the association of frequency of potato and rice consumption with cardiometabolic risk factors in children and adolescents.

Methods

This nationwide cross-sectional survey was conducted on 14,400 children and adolescents. Fasting blood was obtained from a sub-sample of 4200 randomly selected students. Physical examination and laboratory tests were conducted under standard protocols. Metabolic Syndrome (Mets) was defined based on the Adult Treatment Panel III criteria modified for the pediatric age group. The self-reported frequency consumption of white rice and potato was reported on a daily or non-daily basis.

Results

The participation rate for the whole study and for blood sampling were 99 and 91.5%, respectively. Overall, 49.4% of the participants were girls while 50.6% were boys. The frequency of daily consumption of white rice and potato was 84.4 and 21.3%, respectively. In the multivariable linear regression model, daily consumption of potato increased body mass index (β: 0.05, SE: 0.20, p = 0.010), waist (β: 0.63, SE: 0.24, p = 0.008), and hip circumferences (β: 0.62, SE: 0.26, p = 0.019). Moreover, in the multivariable logistic regression, daily consumption of potato was significantly associated with an increased risk of overweight (OR: 1.21, 95% CI: 1.04–1.39, P = 0.012). The potato and rice consumption had no statistically significant association with other cardiometabolic risk factors.

Conclusions

Daily consumption of potato was significantly associated with higher anthropometric measures, whereas rice consumption had no statistically significant association with cardiometabolic risk factors. Future research to examine the possible obesogenic effects of intake of potato on children and adolescents is recommended.
Hinweise

Supplementary information

Supplementary information accompanies this paper at https://​doi.​org/​10.​1186/​s12872-020-01524-y.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Abkürzungen
Mets
Metabolic syndrome
CVD
Cardiovascular disease
CASPIAN-V
Childhood and adolescence surveillance and PreventIon of adult non- communicable disease
PA
Physical activity
SES
Family socio-economic status
ST
Screen time
PIRLS
Progress in the international Reading literacy study
PCA
Principle components analysis
BMI
Body mass index
WrC
Wrist circumference
WC
Waist circumference
NC
Neck circumference
HC
Hip circumferences
BP
Blood pressure
SBP
Systolic blood pressure
DBP
Diastolic blood pressure
FFQ
Food frequency questionnaire
LNDF
Low nutrient-dense foods
FBS
Fasting blood glucose
TG
Triglycerides
TC
Total cholesterol
LDL-C
Low-density lipoprotein cholesterol
HDL-C
High-density lipoprotein cholesterol
SE
Standard error
OR
Odds ratio
CI
Confidence interval
TPB
Theory of planed behavior

Background

Nutrition -related non-communicable diseases like overweight and obesity are increasing in Iran [13]. The prevalence of overweight and obesity in children of America, Europe, Western Pacific, and Southeast Asia is 31, 38, 27, and 22%, respectively [4]. The development of cardiovascular diseases- as one of the main causes of death- is related to numerous early life risk factors such as overweight and obesity [5, 6]. Childhood excess weight increases the risk of obesity or overweight in the later years [7]. Shifts in dietary pattern can have significant effects on weight changes in terms of excess weight in children and adolescents [8, 9]. Longitudinal studies have shown that there is an association between dietary patterns and cardiovascular diseases [10, 11]. Numerous studies have been published showing an inverse association between the consumption of whole-grain foods and body weight so that consumption of whole grains can reduce hunger and increase satiety [12, 13]. Based on the results of a national household consumption survey, major part of the Iranian diet is devoted to plant foods [12]. Also, bread and rice are recognized as a major source of carbohydrates in Persian diets [14]. In an Asian population like Japan, because of high consumption of rice, the risk of metabolic syndrome and other non-communicable diseases is increasing [15]. Type and quantity of carbohydrates can have some effects on increased risk of cardiovascular disease (CVD) and type 2 diabetes [1618]. Since the prevalence of obesity and associated co-morbidities in children and adolescents of developing countries is increasing, studies should be conducted regarding dietary pattern and their association with cardio-metabolic risk factors. Accordingly, the current study aimed to evaluate the association of frequency of potato and rice consumption with cardio-metabolic risk factors in Iranian children and adolescents.

Methods

This multi-centric cross-sectional study was conducted in 2015 as the fifth survey of a surveillance program entitled “Childhood and Adolescence Surveillance and PreventIon of Adult Non- communicable disease” (CASPIAN-V) study. Overall, 14,400 students aged 7–18 years were recruited. They were selected by multistage, stratified cluster sampling from urban and rural areas of 30 provinces of Iran. Overall, 480 students were selected from each province according to the living area (urban/rural) and school grade (primary/ secondary), proportional to size with equal sex ratio. Blood sample was obtained from a sub-sample of 4200 randomly selected students. The study protocol has been described in detail previously [19]. It is summarized here.

Demographic data

In the current study, two sets of questionnaires were used to collect data from the all students and their parents. Questionnaire from WHO-GSHS was translated into Persian, and then its validity and reliability were assessed [20]. Demographic data including age, sex, residence area, physical activity (PA), and family socio-economic status (SES) were collected by trained health care providers. At least one of the parents was required to be present for answering the questions.
PA was assessed using a valid questionnaire [20]. One week prior to the study, the subjects answered the following two questions: 1) how many days were you physically active for 30 min per day during last week? (responses ranged from 0 to 7 days) 2) How much time per week do you spend in exercise classes at school? (answers ranged from 0 to 3 or more hours).
Screen time (ST) behavior was assessed by asking students questions about how long they spent on watching TV, working with computers, and playing video games. Mean ST of more than 2 h per day was considered high, as sedentary lifestyle [20].
SES was assessed using an approved method provided for the Progress in the International Reading Literacy Study (PIRLS) [19]. Variables like parents’ education and job, type of home (private, rented), type of school (private, governmental), and family asset (e.g., personal computer and private car) were summarized under one main component. Then, SES score was estimated using the principle components analysis (PCA) method [21]. The main component was categorized into three levels. The first, second, and third levels were considered as low, moderate, and high SES, respectively.

Physical measurements

Anthropometric indices such as body mass index (BMI), wrist circumference (WrC), waist circumference (WC), neck circumference (NC), and hip circumferences (HC) were measured for all students. All measurements were done using a non-elastic tape with standard protocol. Blood pressure (BP) was measured with the students in the arm position using a mercury sphygmanometer with an appropriate cuff size. It was measured twice at 15 min intervals. Systolic and diastolic blood pressure (SBP, DBP) was recorded and the average was recorded [22].
Rice and potato consumption were recorded using non-quantitative food frequency questionnaire (FFQ). In this questionnaire, the students reported the frequency of each food item as daily, weekly, seldom or never. For statistical analysis, the frequency consumption of rice and potato (daily or non-daily) was considered as weekly, seldom or never) consumption. Foods with a high content of sugar, salt, saturated fats and trans fats, and sugar sweetened beverages were considered as low nutrient-dense foods (LNDF).

Blood sampling

Selected sub-sample students (4200 students out of 14,400 students) accompanying one of their parents were referred to the laboratory for blood sampling. Venous blood samples were collected after 12 h overnight fasting. Centrifugation was done at 2500 to 3000 g for 10 min. Serum samples were stored at − 70 °C and transferred to Isfahan Mahdieh Laboratory by cold chain. Fasting blood glucose (FBS), triglycerides (TG), total cholesterol (TC), low-density lipoprotein cholesterol (LDL-C), and high-density lipoprotein cholesterol (HDL-C) were measured enzymatically using Hita-chi auto- analyzer (Tokyo, Japan) [23, 24].
Metabolic syndrome was defined according to the Adult Treatment Panel III definition as having at least three of the following abnormalities. 1) abdominal obesity (WC < 90th percentile), 2) low HDL-C (HDL < 40 mg/dL except in 15–19-year-old boys, in whom the cut-off was < 45 mg/dL), 3) high TG (TG > 100 mg/ dL), 4) high FBG (FBG > 100 mg/dL), and 5) high BP (SBP or DBP > 90th percentile adjusted by age, sex, and height) [25]. High LDL-C and high TC were defined as LDL-C > 110 mg/dL and TC > 200 mg/dL, respectively [26]. Overweight and obesity were considered as age-sex specific BMI 85th–95th percentile and BMI greater than 95th percentile, respectively [27].

Statistical analysis

The current study was conducted using a secondary analysis of the CASPIAN-V study. Quantitative variables were expressed as mean (standard deviation) and categorical variables were presented as number (percentage). The Student’s t-test was applied to compare mean difference between the means of quantitative variables. Qualitative variables were assessed using Chi-square test. Association of potato and rice consumption with cardiometabolic risk factors was assessed using linear and logistic regression analysis in different models, consisting of Model I: crude model (without adjustment); Model II: adjusted for age, sex, residence area, SES, PA, ST, LNDF (including sweetened beverages and fast foods consumption), and family history of chronic diseases; Model III: additionally adjusted for BMI only for all cardiometabolic risk factors except anthropometric measures. For all models, in the linear and logistic regression analysis, cardiometabolic risk factors were included as continuous and categorical dependent variable in the model respectively. Results of linear and logistic regression model were reported as beta coefficient with standard error (SE) and odds ratio (OR) with the 95% confidence interval (CI), respectively. The results of the questionnaires were analyzed using clustering analysis to investigate the cluster and design effects. To extrapolate the results to the Iranian children and adolescents, data were weighted directly to the Iranian students according to ministry of education list in 2014, to match the grade (primary/secondary), sex, and living area (rural/urban). All statistical analyses were performed using STATA package version 11.0 (Stata Statistical Software: Release 11. Stata Corp LP. Package. College Station, TX, USA) and a P-value< 0.05 was considered statistically significant.

Results

The participation rates for the whole study and for the blood sampling were 99 and 91.5%, respectively. A total of 14,400 children and adolescents (49.9% girls and 50.4% boys) with mean age of 12.3 ± 3.2 years participated in this study. The frequency of daily consumption of white rice and potato was 84.4 and 21.3%, respectively. Distribution of general characteristics of subjects according to consumption of rice and potato is presented in Supplementary Table 1. Distribution of rice consumption according to living area, level of PA and SES was statistically different (P < 0.050). Moreover, association of potato consumption with ST and SES was statistically significant (P < 0.050). Table 1 shows the prevalence of cardiometabolic risk factors according to rice and potato consumption. No significant differences were observed between daily and non-daily rice consumers according to prevalence of all cardiometabolic risk factors except high SBP. The prevalence of high SBP in daily potato consumers was significantly higher than non-daily consumers (3.8% vs. 2.9%) (P: 0.01).
Table 1
Prevalence of cardio-metabolic risk factors according to rice and potato consumption in Iranian children and adolescents: the CASPIAN-V study
 
Rice Consumption
Potato Consumption
Total
Daily (%)
Nondaily (%)
P-value
Daily (%)
Nondaily (%)
P-value
Abdominal obesity
2506 (21.0)
460 (21.4)
.677
658 (22.0)
2296 (20.8)
.151
2972 (21.1)
Over weight
1131 (9.5)
197 (9.1)
0.630
308 (10.3)
1007 (9.1)
0.053
1330 (9.4)
Obesity
1373 (11.5)
240 (11.1)
0.629
342 (11.4)
1268 (11.5)
0.917
1615 (11.4)
High FBS
143 (4.3)
18 (3.4)
0.299
41 (4.6)
120 (4.1)
0.467
161 (4.2)
High TG
913 (27.6)
151 (28.2)
0.793
237 (26.8)
824 (28.0)
0.489
1065 (27.7)
High TC
168 (5.1)
21 (3.9)
0.247
49 (5.5)
140 (4.8)
0.344
189 (4.9)
Low HDL
976 (29.5)
157 (29.3)
0.910
261 (29.5)
867 (29.5)
0.970
1134 (29.5)
High LDL
569 (17.2)
105 (19.6)
0.180
167 (18.9)
506 (17.2)
0.245
674 (17.5)
High SBP
365 (3.1)
71 (3.3)
0.606
114 (3.8)
318 (2.9)
0.010
438 (3.1)
High DBP
1214 (10.3)
231 (10.7)
0.521
321 (10.8)
1125 (10.3)
0.435
1450 (10.4)
High BP
1350 (11.4)
249 (11.6)
0.848
357 (12.0)
1240 (11.3)
0.324
1604 (11.5)
MetS
164 (5.1)
24 (4.6)
0.626
45 (5.2)
143 (5.0)
0.811
188 (5.0)
MetS metabolic syndrome, FBS fasting blood sugar, TC total cholesterol, TG triglycerides, LDL-C low-density lipoprotein cholesterol, HDL-C high-density lipoprotein cholesterol, BP blood pressure;
Defined as above the 85th percentile. Overweight: BMI 85th–95th; obesity: BMI >95th; low HDL: 110 mg/dL; high TG: 100 mg/dL; high TC: > 200 mg/dL; high FBS: > 100 mg/dL; high blood pressure: >90th (adjusted by age, sex, height); Abdominal obesity: WHtR> 0.5; MetS, ATP-III criteria;
Table 2 demonstrates the mean (±SD) of anthropometric and cardiometabolic indices according to the rice and potato consumption. The mean values of hip (79.2 ± 14.5) were significantly higher in subjects with daily rice consumption compared to other participants (78.5 ± 14.8) (P < 0.050). Diastolic BP was significantly lower in participants with daily rice consumption than non-daily consumption (63.7 ± 10.4 vs. 64.2 ± 10.2), (P < 0.001). There was a significant difference in waist to height ratio between participants with daily potato consumption and non-daily potato consumption (0.450 ± 0.06 vs. 0.458 ± 0.06) (P < 0.001).
Table 2
Mean (±SD) of anthropometric and cardio-metabolic indices according to rice and potato consumption
 
Rice Consumption
Potato Consumption
Daily Mean (SD)
Nondaily Mean (SD)
P-value
Daily Mean (SD)
Nondaily Mean (SD)
P-value
FBS
91.7 (12.2)
91.0 (11.4)
0.231
91.6 (12.5)
91.6 (12.0)
0.889
TG
88.1 (45.9)
87.2 (40.4)
0.663
87.7 (44.9)
88.1 (45.3)
0.827
TC
153.6 (27.7)
155.1 (25.1)
0.240
153.9 (28.8)
153.8 (27.0)
0.973
HDL
46.2 (9.9)
46.0 (9.9)
0.805
46.4 (10.0)
46.1 (9.9)
0.459
LDL
89.9 (22.4)
91.6 (20.5)
0.108
90.2 (23.2)
90.1 (21.8)
0.944
SBP
99.0 (13.1)
99.5 (12.8)
0.156
98.9 (13.8)
99.2 (12.8)
0.335
DBP
63.7 (10.4)
64.2 (10.2)
0.023
63.6 (10.8)
63.8 (10.3)
0.175
BMI z- score
0.01 (0.99)
0.00 (1.03)
0.832
0.02 (1.09)
0.00(0.97)
0.155
Waist
66.7 (12.1)
66.4 (12.1)
0.239
67.0 (12.8)
66.6 (11.9)
0.119
Hip
79.2 (14.5)
78.5 (14.8)
0.030
79.4 (14.9)
79.0 (14.5)
0.155
Wrist
14.7 (1.8)
14.7 (1.9)
0.313
14.7 (2.0)
14.7 (1.8)
0.487
Neck
29.8 (3.9)
29.8 (4.1)
0.648
29.8 (4.1)
29.8 (3.9)
0.649
WHtR
0.45 (0.06)
0.45 (0.06)
0.121
0.450 (0.06)
0.459 (0.06)
0.011
WHR
0.86 (0.19)
0.85 (0.16)
0.09
0.86 (0.17)
0.85 (0.15)
0.42
FBS fasting blood sugar, TC total cholesterol, TG triglycerides, LDL-C low-density lipoprotein cholesterol, HDL-C high-density lipoprotein cholesterol, SBP systolic blood pressure, DBP diastolic blood pressure, WC Waist circumference, HC hip circumference, NC neck circumference, BMI body mass index, WHtR waist to height ratio, WHR waist to hip ratio
Association of rice and potato consumption with anthropometric and cardiometabolic indices (as continuous variable) in linear regression analysis is presented in Table 3. Although, in the crude model, daily rice consumer had statistically lower diastolic BP (β: -0.56, SE: 0.24) and HC (β: 0.74, SE: 0.34) compare to nondaily consumers, in the multivariable model theses associations were not statistically significant. In the multivariable linear regression model, daily consumption of potato increased significantly BMI (β: 0.05, SE: 0.2, p = 0.010), WC (β: 0.63, SE: 0.24, p = 0.008), and HC (β: 0.62, SE: 0.26, P = 0.019).
Table 3
Association of rice and potato consumption with anthropometric and cardiometabolic indices in linear regression analysis
 
Rice (Daily/Nondaily)
Potato (Daily/Nondaily)
β
SE
P-value
β
SE
P-value
FBS
Model 1
0.676
0.564
0.231
−.065
.465
.889
Model 2
0.515
0.642
0.422
.021
.525
.967
Model 3
0.534
0.646
0.409
.000
.529
.999
TG
Model 1
0.918
2.104
0.663
−.380
1.735
.827
Model 2
0.699
2.308
0.762
−.030
1.887
.987
Model 3
0.430
2.319
0.853
−.258
1.897
.892
TC
Model 1
−1.501
1.277
0.240
.035
1.053
.973
Model 2
−0.564
1.432
0.694
−.094
1.170
.936
Model 3
−0.650
1.441
0.652
−.205
1.179
.862
HDL-C
Model 1
0.115
0.465
0.805
.283
.382
.459
Model 2
0.058
0.517
0.911
.449
.422
.288
Model 3
0.082
0.520
0.875
.432
.425
.309
LDL-C
Model 1
−1.661
1.034
0.108
.060
.852
.944
Model 2
−0.673
1.161
0.562
−.305
.948
.748
Model 3
−0.731
1.169
0.532
−.353
.955
.712
SBP
Model 1
−0.435
0.307
0.156
−.261
.270
.335
Model 2
−0.295
0.322
0.360
−.182
.279
.515
Model 3
−0.236
0.317
0.456
−.339
.275
.217
DBP
Model 1
−0.557
0.244
0.023
−.293
.216
.175
Model 2
−0.442
0.266
0.096
−.303
.231
.191
Model 3
−0.405
0.264
0.125
−.387
.229
.091
BMI z-score
Model 1
−0.005
0.023
0.832
.029
.021
.155
Model 2
−0.016
0.024
0.502
.053
.020
.010
WC
Model 1
0.334
0.284
0.239
.390
.250
.119
Model 2
0.218
0.272
0.423
.628
.236
.008
HC
Model 1
0.740
0.341
0.030
.428
.301
.155
Model 2
0.503
0.305
0.099
.621
.265
.019
Wrist
Model 1
−0.045
0.044
0.313
.027
.039
.487
Model 2
−0.033
0.041
0.419
.031
.036
.385
NC
Model 1
0.038
0.093
0.684
.037
.082
.649
Model 2
−0.035
0.085
0.681
.085
.074
.250
WHtR
Model 1
0.002
0.002
0.121
.003
.001
.011
Model 2
0.001
0.002
0.572
.005
.001
.001
WHR
Model 1
−0.008
0.004
0.061
−.003
.004
.455
Model 2
−0.002
0.004
0.579
−.001
.004
.718
FBS fasting blood sugar, TC total cholesterol, TG triglycerides, LDL-C low-density lipoprotein cholesterol, HDL-C high-density lipoprotein cholesterol, SBP systolic blood pressure, DBP diastolic blood pressure, WC Waist circumference, HC hip circumference, NC neck circumference, BMI body mass index, WHtR waist to height ratio, WHR waist to hip ratio
Model 1: Crude Model
Model 2:Adjusted for age, sex, region, SES, PA, ST, family history of chronic diseases, and LNDF (fast foods and sweetened beverages)
Model 3Additionally adjusted for BMI
Association of rice and potato consumption with overweight, obesity and cardiometabolic risk factors in logestic regression analysis is presented in Table 4. In the multivariable model, daily consumption of potato significantly increased odds of overweight (OR: 1.21, 95% CI: 1.04–1.39, P = 0.012). Association of potato and rice consumption with other cardiometabolic risk factors was not statistically significant in the multivariable model (p-value> 0.05).
Table 4
Association between rice and potato consumption with cardio-metabolic risk factors in logistic regression analysis
 
Rice Consumption
Potato Consumption
OR
95% CI
p-Value
OR
95% CI
p-Value
High FBS
Model 1
1.301
.790–2.143
.301
1.144
.796–1.645
.467
Model 2
1.123
.665–1.898
.664
1.332
.906–1.958
.144
Model 3
1.110
.657–1.877
.697
1.308
.888–1.927
.174
High TG
Model 1
.973
.794–1.192
.793
.942
.795–1.116
.489
Model 2
.947
.756–1.185
.633
.935
.775–1.127
.479
Model 3
.942
. 752–1.181
.607
.922
.764–1.113
.398
High TC
Model 1
1.313
.827–2.087
.249
1.175
.841–1.641
.345
Model 2
1.433
.841–2.440
.185
1.206
.835–1.741
.318
Model 3
1.418
.832–2.417
.199
1.187
.820–1.720
.364
Low HDL
Model 1
1.012
.828–1.236
.910
1.003
.851–1.183
.970
Model 2
1.053
.840–1.321
.653
.955
.794–1.150
.630
Model 3
1.055
.840–1.325
.645
.948
.786–1.142
.571
High LDL
Model 1
.854
.677–1.076
.181
1.122
.924–1.362
.245
Model 2
.896
.689–1.164
.409
1.152
.930–1.426
.195
Model 3
.890
.685–1.157
.383
1.152
.930–1.427
.196
High BP
Model 1
.986
.854–1.138
.848
1.065
.940–1.207
.324
Model 2
1.019
.865–1.201
.820
1.063
.925–1.223
.389
Model 3
1.034
.875–1.221
.697
1.048
.910–1.206
.518
Mets
Model 1
1.115
.719–1.730
.626
1.043
.739–1.471
.811
Model 2
1.087
.668–1.768
.738
1.079
.738–1.577
.694
Model 3
1.104
.667–1.829
.700
1.014
.685–1.501
.944
Abdominal obesity
Model 1
.976
.873–1.092
.677
1.074
.974–1.185
.151
Model 2
.942
.830–1.069
.357
1.114
.999–1.242
.052
Overweight
Model 1
1.040
.89–1.22
.631
1.142
.99–1.30
.053
Model 2
1.029
.860–1.230
.757
1.207
1.042–1.399
.012
Obesity
Model 1
1.037
.896–1.199
.629
.993
.875–1.128
.917
Model 2
.981
.831–1.158
.820
1.098
.956–1.262
.186
MetS metabolic syndrome, FBS fasting blood sugar, TC total cholesterol, TG triglycerides, LDL-C low-density lipoprotein cholesterol, HDL-C high-density lipoprotein cholesterol, BP blood pressure;
Defined as above the 85th percentile. Overweight: BMI 85th–95th; obesity: BMI >95th; low HDL: 110 mg/dL; high TG: 100 mg/dL; high TC: > 200 mg/dL; high FBS: > 100 mg/dL; high blood pressure: >90th (adjusted by age, sex, height); Abdominal obesity: WHtR> 0.5; MetS, ATP-III criteria;
Model 1: Crude Model
Model 2: Adjusted for age, sex, region, SES, PA, ST, family history of chronic diseases, and food habits (fast foods and sweetened beverages)
Model 3: Additionally adjusted for BMI

Discussion

In this national-wide study, we found significant associations of potato consumption with some cardio-metabolic risk factors. In potato consumers and after adjustment for potential confounders, some risk factors such as BMI, WC, and HC remained significant. The results also revealed that in the multivariable model, daily rice consumption was not associated with cardiometabolic risk factors. Our inability to identity positive associations between rice consumption and alteration of other cardio-metabolic risk factors may be related to change in eating habits of the studied population when body composition such as overweight and obesity is altered. Also, some specific difficulties in evaluating food consumption of children and adolescents such as limitation of the selected dietary survey, underreporting, etc. should be considered as the possible reasons for the mentioned issue.
Numerous studies have revealed that diet composition may play an essential role in development of obesity and its risk factors in adults [28, 29]. Data regarding the effects of dietary components on development of childhood obesity and related risk factors have so far been inconclusive.
There are some inconsistencies in the studies assessing the relationship between refined grains and CVD risk factors. Some of them found no association [30] and others demonstrated even an increment [31]. Some studies have reported positive associations between white rice consumption and CVD risk factors. According to some reports, higher intake of refined grains is associated with higher risk of type II diabetes [32], stroke [33], and hypertriglyceridemia [34]. However, other studies have found little association [16], with the potential exception of an association between white rice and type 2 diabetes [17]. Indian researchers found that rice, as a major source of carbohydrate, in comparison with other sources of carbohydrates, had a weaker effect on rising TG level [35]. The results of a clinical trial conducted on patients with coronary artery disease showed that after replacing refined rice with legume powder and whole grain products, as a source of carbohydrates, glucose and insulin concentrations changed significantly [36]. Other studies showed that refined grains had no effects on risk of hypertension [37], heart diseases, and diabetes type II [31, 38]. Also, no significant association was observed between refined grains’ intake and concentration of fasting insulin in Framingham Cohort Study [39].
The current study revealed that in subjects who consumed potato on a daily basis, the possibility of overweight increased. Inducing a faster rise in glucose level and insulin response maybe one of the possible mechanisms involved in the observed association. Since energy density is considered as a major factor contributing to overconsumption, explaining the relationship between specific foods consumption and excess weight gain is complex.
To enhance flavor in potatoes, they are mostly prepared by oils and fats. So, nutritional value of potatoes and potato products might be overlooked [30]. Due to confounders such as cooking method and storage, the association between dietary potato intake and health is complex [40]. Despite recent recommendations to consume starchy foods, we should consider the above-mentioned points for daily consumers of potato even in local foods [41].
Mozaffarian et al. evaluated the intake of 13 groups of foods and beverages among adults for 4 years. They found that weight gain was significantly higher in subjects who increased their daily intake of potato chips, potato, sugar-sweetened beverages, and processed meat, as compared with those who increased daily intake of vegetables, whole grains, fruit, yogurt, and nuts [42].
In a study conducted by Dong et al. on 7–13-year-old children, they found that high protein and fiber foods (dietary components that increase satiety and induce lower glycemic index) are negatively associated with excess weight gain [43].
In the present study, subjects with daily consumption of rice had lower DBP compared to non-daily consumers. The results from recent randomized controlled trials are inconsistent with our findings. They demonstrated that low-carbohydrate diets can decrease systolic and diastolic blood pressure [44, 45]. Weight loss would be the driving factor in decreasing blood pressure levels [46]. The observed association in the current study might be related to cross-sectional design of the study. Also, BP results were averages from only two consequent measurements. This method is not a precise methodology for measuring BP; it might be useful to recognize hypertensive subjects [47].
Our study revealed that daily fast foods and daily rice consumers had higher SES levels which are basically because of the higher price of such food items in Iran. While, daily potato consumers had lower SES because potato is very cheap food item in all parts of Iran. Also, current behavior regarding consumption of sweetened beverages and the possible predictors should be examined by using theory of planed behavior (TPB) in the future.
This study has some specific limitations. First, as a result of cross-sectional nature of the study, the obtained associations should be considered with caution. Second, data of portion size, quantification information, and type of consumed potato and rice were not collected in our study. Third, we were not able to estimate energy intake in the current study. Fourth, measurement errors are inevitable due to difficulties in evaluating food consumption of children and adolescents. Also, recall bias might be happen because of using self-reported physical activity questioner. The strengths of this study are its large sample size and novelty in the pediatric age group.

Conclusions

Daily consumption of potato was significantly associated with higher anthropometric measures whereas rice consumption had no statistically significant association with cardiometabolic risk factors. The prevalence of SBP was significantly higher in daily potato consumers compared to others. Therefore, it is recommended that future research examines the possible obesogenic effects of intake of potato on children and adolescents and also, we should consider this point that the evidence of single foods needs to be considered in the context of the total diet.
Despite numerous difficulties in assessing dietary habits of children and adolescents, such studies should be considered a main basis for devising interventions at an early age.

Supplementary information

Supplementary information accompanies this paper at https://​doi.​org/​10.​1186/​s12872-020-01524-y.

Acknowledgments

The authors are thankful of all participants and large team working on this project in different provinces.
The protocol of the study was approved by ethical committee of Isfahan University of Medical Sciences. Also, written informed consent and verbal consent were obtained from parents and students, respectively.
Not applicable.

Competing interests

All authors declare that they have no competing interests.
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Metadaten
Titel
Is frequency of potato and white rice consumption associated with cardiometabolic risk factors in children and adolescents: the CASPIAN-V study
verfasst von
Fereshteh Baygi
Mostafa Qorbani
Mohammad Esmaeil Motlagh
Gita Shafiee
Kourosh Nouri
Zeinab Ahadi
Armita Mahdavi-Gorab
Ramin Heshmat
Roya Kelishadi
Publikationsdatum
01.12.2020
Verlag
BioMed Central
Erschienen in
BMC Cardiovascular Disorders / Ausgabe 1/2020
Elektronische ISSN: 1471-2261
DOI
https://doi.org/10.1186/s12872-020-01524-y

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