Thu, Apr 25, 2024
[Archive]
Volume 7, Issue 3 (Aug 2022)
JNFS 2022, 7(3): 362-373 |
Back to browse issues page
Download citation:
BibTeX | RIS | EndNote | Medlars | ProCite | Reference Manager | RefWorks
Send citation to:
BibTeX | RIS | EndNote | Medlars | ProCite | Reference Manager | RefWorks
Send citation to:
Moghtaderi F, Sarebanhassanabadi M, Hosseini S, Pakseresht M, Beiki O, Seyed Hosseini S M, et al . Incidence of Overweight and Its Predictors in Adults after 10 Years of Follow-up: Yazd Healthy Heart Project. JNFS 2022; 7 (3) :362-373
URL: http://jnfs.ssu.ac.ir/article-1-487-en.html
URL: http://jnfs.ssu.ac.ir/article-1-487-en.html
Fatemeh Moghtaderi 
, Mohammadtaghi Sarebanhassanabadi * , Shabnam Hosseini , Mohammadreza Pakseresht , Omid Beiki , Seyed Mostafa Seyed Hosseini , Seyedeh Mahdieh Namayandeh , Mahmood Emami , Amin Salehi-Abargouei
, Mohammadtaghi Sarebanhassanabadi * , Shabnam Hosseini , Mohammadreza Pakseresht , Omid Beiki , Seyed Mostafa Seyed Hosseini , Seyedeh Mahdieh Namayandeh , Mahmood Emami , Amin Salehi-Abargouei
YaYazd Cardiovascular Research Center, Non-communicable Diseases Research Institute, Shahid Sadoughi University of Medical Sciences, Yazd, Iranardiovascular Research Center, Shahid Sadoughi University of Medical Sciences, Yazd, Iran.
Full-Text [PDF 810 kb]
(275 Downloads)
| Abstract (HTML) (1167 Views)
Introduction
.PNG)
Full-Text: (212 Views)
Incidence of Overweight and Its Predictors in Adults after 10 Years of Follow-up: Yazd Healthy Heart Project
Fatemeh Moghtaderi; MSc1, Mohammadtaghi Sarebanhassanabadi; PhD*1, Shabnam Hosseini; BSc2, Mohammadreza Pakseresht; PhD3, Omid Beiki; PhD4, Seyed Mostafa Seyed Hosseini; MD1,Seyedeh Mahdieh Namayandeh; PhD1, Mahmood Emami; MD1 & Amin Salehi-Abargouei; PhD5
Fatemeh Moghtaderi; MSc1, Mohammadtaghi Sarebanhassanabadi; PhD*1, Shabnam Hosseini; BSc2, Mohammadreza Pakseresht; PhD3, Omid Beiki; PhD4, Seyed Mostafa Seyed Hosseini; MD1,Seyedeh Mahdieh Namayandeh; PhD1, Mahmood Emami; MD1 & Amin Salehi-Abargouei; PhD5
1 Yazd Cardiovascular Research Center, Non-communicable Diseases Research Institute, Shahid Sadoughi University of Medical Sciences, Yazd, Iran
2 Nutrition and Endocrine Research Center, Research Institute for Endocrin Science, Shahid Beheshti University of Medical Sciences, Tehran, Iran
3Department of Agricultural, Food and Nutritional Sciences, University of Alberta, Edmonton, Alberta, Canada
4 Cognizant Technology Solutions, Stockholm, Sweden
5Nutrition and Food Security Research Center, Shahid Sadoughi University of Medical Sciences, Yazd, Iran
2 Nutrition and Endocrine Research Center, Research Institute for Endocrin Science, Shahid Beheshti University of Medical Sciences, Tehran, Iran
3Department of Agricultural, Food and Nutritional Sciences, University of Alberta, Edmonton, Alberta, Canada
4 Cognizant Technology Solutions, Stockholm, Sweden
5Nutrition and Food Security Research Center, Shahid Sadoughi University of Medical Sciences, Yazd, Iran
6Department of Nutrition, School of Public Health, Shahid Sadoughi University of Medical Sciences, Yazd, Iran
| ARTICLE INFO | ABSTRACT | |
| ORIGINAL ARTICLE | Background: Obesity and overweight are important public health problems which are rapidly growing throughout the world. This study aims to provide 10-year incidence estimates of obesity and overweight in adults along with their risk factors in an Iranian adult population. Methods: This cohort study was conducted within the framework of the Yazd Healthy Heart Project (YHHP) throughout phases from 2005-2006 to 2015-2016 among urban adult population. The participants comprised of 1000 males and 1000 females aged 20-74 years from urban areas of Yazd. Cox proportional hazards model was used to examine the potential risk factors for obesity and overweight. Results: A total of 2000 participants aged 47.09 ± 16.97 years and body mass index (BMI) of 21.99 ± 2.21 kg/m2 were entered in this study at baseline. After 10 years of follow-up, the cumulative incidence of overweight for the entire population was 38.6% (41.6% in women and 36.8% in men). Furthermore, the 10-year cumulative incidence of obesity was 14.8% in the population (20.8% for women and 10.5% for men). Female participants showed a significantly higher incidence rate compared to males either for obesity or overweight. Regarding risk factors, there was a significant association between non-smoking (HR= 1.54, 95% CI: 1.06-2.25), socio-economic status (HR= 1.82, 95% CI: 1.13-2.94), and education (HR= 1.56, 95% CI: 1.14-2.13) with overweight (P < 0.05). Conclusion: This study revealed the incidence rate of obesity and overweight is significantly high in adult population of Yazd, Iran especially in women. The most important predictors of overweight seem to be smoking, lower socio-economic status, and education. Keywords: Overweight; Obesity; Incidence; Cohort; Risk factors |
|
| Article history: Received: 25 Sep 2021 Revised: 30 Nov 2021 Accepted: 15 Dec 2021 |
||
| *Corresponding author: mtsareban@gmail.com Yazd Cardiovascular Research Center, Afshar hospital, Jomhouri Blvd., Yazd, Iran. Postal code: 8917945556 Tel: +983535231421 |
Introduction
xcessive weight gain as a global epidemic is one of the major health threats in the world (Lim et al., 2020), which is rising more rapidly in developing countries, such as Iran (Prentice, 2005, Rahmani et al., 2015 ). Although under-nutrition had been a major nutrition-related concern to most of countries around the world for many years, recently a rapid increase in the mean weight of populations has caught the professionals’ attention. It is due to the fact that obesity and overweight have shown to be associated with major chronic diseases, such as cardiovascular diseases (Dwivedi et al., 2020), diabetes, and cancer (Lega and Lipscombe, 2020) which are the most common leading causes of death.
According to the WHO, the worldwide prevalence of obesity was tripled between 1975 and 2016; ended in 39% of adults being overweight and 13% being obese in 2016 (World Health Organization, 2017). In addition, the prevalence of Iranian adults with overweight and obesity has been shown to be 36.6% and 22.7% in 2016, respectively (Djalalinia et al., 2020). In a 20-year cohort study conducted in Tehran, the prevalence of overweight and obese adults was reported 20.8% and 63.6%, respectively (Barzin et al., 2018b). In a 5-year follow-up study in Yazd, the prevalence of obesity and overweight was reported 27.1% and 38.5% in 2014, respectively (Ghadiri-Anari et al., 2013). Although many of the Iranian studies have reported the prevalence of adulthood obesity and overweight, a few studies have been conducted on their incidence rates, most of which were conducted on populations other than Yazd (Barzin et al., 2018a, Erfanifar et al., 2021, Hosseinpanah et al., 2016, Nemesure et al., 2008, Sarebanhassanabadi et al., 2017). Further incidence studies are required to determine the potential predictors for developing excessive weight in adults of Yazd province. In spite of the importance of excessive weight gain, there is limited knowledge regarding the factors related to the increasing levels of overweight and obesity to develop appropriate prevention strategies. This longitudinal population-based cohort study was conducted to establish obesity and overweight incidence in adults living in urban areas of Yazd and to assess the potential predictors of these two common public health problems in the same population.
Materials and Methods
Study population: This cohort study was carried out within the framework of the Yazd Healthy Heart Project (YHHP), a population based cohort study. The selection process of participants was described in detail elsewhere (Sarebanhassanabadi et al., 2017). In total 2000 participants (50% males) aged 20-74 years were recruited to the YHHP using a cluster random sampling method over 2005-2006 from the urban population of Yazd. Every individual was contacted, invited to the Yazd cardiovascular research center (YCRC) and recruited to participate in the study for further measurements and next follow-ups. Twenty two participants were excluded from the study due to missing data. In the latest phase of the project in 2015-2016, individuals were invited to YCRC again for follow-up. The data were collected by a researcher made questionnaire validated using content validity during 2005–2006. The details of the questionnaire included demographic information, anthropometric parameters, and lipid profiles, smoking status, educational levels, socioeconomic status, and physical activity.
In the current study, all the 2000 participants were participated to determine the incidence of obesity and overweight separately and their predictors. After excluding those who were obese at the baseline and those who had consumed glucocorticoids or other hormonal drugs (total number of excluded participants N = 376); 1602 participants remained. Of these participants, 534 had no further follow-ups. Final analysis was performed on 1068 participants (taking into account a drop-out rate of 33.3%, Figure 1). For those who were recognized as overweight participants, after excluding those who were overweight or those who had consumed glucocorticoids or other hormonal drugs at the baseline; 810 participants remained. Of these, 294 participants refused to follow the study. The final analysis was done on 516 participants (Figure 2).
Measurements and definitions: To reduce subjective errors, trained staff were responsible for collecting data, measurements, and demographic information.
Weight was assessed regarding standard protocols when patients were minimally clothed by an electronic scale (Omron Karada Body Scan and Scale, Model BF511, Omron Co. Osaka, Japan) with an accuracy of up to 0.1 kg. Height was strictly measured without footwear using wall-mounted stadiometer, to the nearest 0.1 cm. To measure waist circumference (WC), the narrowest level over light clothing was selected using an un-stretched tape, without any pressure to body surface, and measurements were recorded to the nearest 0.1 cm. In addition, cut-off point of WC was determined as ≥102 cm for men and ≥88 cm for women (National Cholesterol Education Program Adult Treatment Panel III, 2002). Body mass index (BMI) was calculated as weight in kilograms divided by the height in squared meters (kg/m2). Obesity and overweight were defined according to the World Health Organization (WHO): BMI≥25 as being overweight and BMI ≥30 kg/m2 as being obese (World Health Organization, 2017).
A qualified physician, using an automatic digital blood pressure monitor (model M6 Comfort; Omron Co.), measured systolic and diastolic blood pressure two times on the right arm, with the participant in a seated position, asked to rest for 15 min period between measurements. The mean of the two measurements was considered to be the participant’s blood pressure. Blood samples were drawn from all the study participants after an overnight fasting of 12–14 h. All blood analyses were performed at the research laboratory on the day of blood collection. Fasting blood sugar (FBS) was measured by the enzymatic colorimetric method using glucose oxidase. Plasma triglyceride (TG) levels were measured by enzymatic colorimetric kits using cholesterol esterase/cholesterol oxidase and glycerol phosphate oxidase, respectively. High-density lipoprotein cholesterol (HDL-C) was measured after precipitation of the apolipoprotein B–containing lipoproteins with phosphotungstic acid.
Economic status was classified in to three groups (low, moderate, and high) based on scoring variables, including home area (square meters), household income, and owning a private car. In addition, based on educational level (primary school, high school, diploma, academic degree), participants were divided into three categories of low, moderate, and high. International physical activity scoring system was utilized for dividing participants in to three groups of low, moderate, and vigorous physical activity levels. Moreover, smoking habit was recorded for each participant and they were classified in to two categories of smokers and non-smokers. The details were reported in a previous study (Sarebanhassanabadi et al., 2018).
Ethical consideration: Ethical approval of the current study was obtained from the Ethics Committee of Shahid Sadoughi University of Medical Sciences in Yazd, Iran (ethical code: IR.SSU.MEDICINE.REC. 1395.287). Also, informed consent was obtained from all participants at the first and second phases of the study.
Data analysis: Statistical Package for Social Sciences (SPSS 19, IBM Corporation, New York, USA) was used to analyze of the data. Student t-test was used for comparison of continuous variables, including age, weight, BMI, systolic and diastolic blood pressure, TG, HDL-cholesterol, and WC between two groups of completed and lost to follow-up. Chi-square test was used for the comparison of categorical data, including gender, smoking, economic status, physical activity, and educational levels. In this study, P-value of less than 0.05 was considered as significant level. Cox proportional hazards model was used to estimate the risk of overweight and obesity after a 10-year follow-up considering age, gender, smoking, economic status, physical activity, and educational levels.
Results
The baseline characteristics of the participants without overweight who were lost to follow-up and those completing the study are shown in Table 1. As indicated, there were significant differences in age, weight, systolic blood pressure, socioeconomic status, and education. The participants in the follow-up group were significantly younger, had higher body weight, and lower systolic blood pressure compared to another group. Table 4 reveals that the participants without obesity in the follow-up group were significantly younger, had higher body weight, BMI, and waist circumference and they had lower fasting blood glucose and systolic blood pressure compared to those who lost to follow-up. Moreover, education (P = 0.001) and socioeconomic status (P = 0.001) were significantly different between the follow-up and lost to follow-up groups. There was no significant difference in diastolic blood pressure, TG, HDL-C, physical activity, and smoking between the two groups.
The annual incidence rate of overweight in men, women, and total population was 3.7%, 4.2%, and 3.9%, respectively. The annual incidence rate of obesity in men, women, and total population was 1.06%, 2.1%, and 1.49%, respectively (Table 5).
Table 2 indicates that the overall incidence of overweight during 9.8-year follow-up was 38.37/1000 person-year. Indeed, the incidence of overweight in women was greater than men, 41.43/1000 person-year in women and 37.22/1000 person-year in men, but there was no significant difference between the two groups. However, the incidence of obesity in women was significantly higher than men (Table 6).
According to the WHO, the worldwide prevalence of obesity was tripled between 1975 and 2016; ended in 39% of adults being overweight and 13% being obese in 2016 (World Health Organization, 2017). In addition, the prevalence of Iranian adults with overweight and obesity has been shown to be 36.6% and 22.7% in 2016, respectively (Djalalinia et al., 2020). In a 20-year cohort study conducted in Tehran, the prevalence of overweight and obese adults was reported 20.8% and 63.6%, respectively (Barzin et al., 2018b). In a 5-year follow-up study in Yazd, the prevalence of obesity and overweight was reported 27.1% and 38.5% in 2014, respectively (Ghadiri-Anari et al., 2013). Although many of the Iranian studies have reported the prevalence of adulthood obesity and overweight, a few studies have been conducted on their incidence rates, most of which were conducted on populations other than Yazd (Barzin et al., 2018a, Erfanifar et al., 2021, Hosseinpanah et al., 2016, Nemesure et al., 2008, Sarebanhassanabadi et al., 2017). Further incidence studies are required to determine the potential predictors for developing excessive weight in adults of Yazd province. In spite of the importance of excessive weight gain, there is limited knowledge regarding the factors related to the increasing levels of overweight and obesity to develop appropriate prevention strategies. This longitudinal population-based cohort study was conducted to establish obesity and overweight incidence in adults living in urban areas of Yazd and to assess the potential predictors of these two common public health problems in the same population.
Materials and Methods
Study population: This cohort study was carried out within the framework of the Yazd Healthy Heart Project (YHHP), a population based cohort study. The selection process of participants was described in detail elsewhere (Sarebanhassanabadi et al., 2017). In total 2000 participants (50% males) aged 20-74 years were recruited to the YHHP using a cluster random sampling method over 2005-2006 from the urban population of Yazd. Every individual was contacted, invited to the Yazd cardiovascular research center (YCRC) and recruited to participate in the study for further measurements and next follow-ups. Twenty two participants were excluded from the study due to missing data. In the latest phase of the project in 2015-2016, individuals were invited to YCRC again for follow-up. The data were collected by a researcher made questionnaire validated using content validity during 2005–2006. The details of the questionnaire included demographic information, anthropometric parameters, and lipid profiles, smoking status, educational levels, socioeconomic status, and physical activity.
In the current study, all the 2000 participants were participated to determine the incidence of obesity and overweight separately and their predictors. After excluding those who were obese at the baseline and those who had consumed glucocorticoids or other hormonal drugs (total number of excluded participants N = 376); 1602 participants remained. Of these participants, 534 had no further follow-ups. Final analysis was performed on 1068 participants (taking into account a drop-out rate of 33.3%, Figure 1). For those who were recognized as overweight participants, after excluding those who were overweight or those who had consumed glucocorticoids or other hormonal drugs at the baseline; 810 participants remained. Of these, 294 participants refused to follow the study. The final analysis was done on 516 participants (Figure 2).
Measurements and definitions: To reduce subjective errors, trained staff were responsible for collecting data, measurements, and demographic information.
Weight was assessed regarding standard protocols when patients were minimally clothed by an electronic scale (Omron Karada Body Scan and Scale, Model BF511, Omron Co. Osaka, Japan) with an accuracy of up to 0.1 kg. Height was strictly measured without footwear using wall-mounted stadiometer, to the nearest 0.1 cm. To measure waist circumference (WC), the narrowest level over light clothing was selected using an un-stretched tape, without any pressure to body surface, and measurements were recorded to the nearest 0.1 cm. In addition, cut-off point of WC was determined as ≥102 cm for men and ≥88 cm for women (National Cholesterol Education Program Adult Treatment Panel III, 2002). Body mass index (BMI) was calculated as weight in kilograms divided by the height in squared meters (kg/m2). Obesity and overweight were defined according to the World Health Organization (WHO): BMI≥25 as being overweight and BMI ≥30 kg/m2 as being obese (World Health Organization, 2017).
A qualified physician, using an automatic digital blood pressure monitor (model M6 Comfort; Omron Co.), measured systolic and diastolic blood pressure two times on the right arm, with the participant in a seated position, asked to rest for 15 min period between measurements. The mean of the two measurements was considered to be the participant’s blood pressure. Blood samples were drawn from all the study participants after an overnight fasting of 12–14 h. All blood analyses were performed at the research laboratory on the day of blood collection. Fasting blood sugar (FBS) was measured by the enzymatic colorimetric method using glucose oxidase. Plasma triglyceride (TG) levels were measured by enzymatic colorimetric kits using cholesterol esterase/cholesterol oxidase and glycerol phosphate oxidase, respectively. High-density lipoprotein cholesterol (HDL-C) was measured after precipitation of the apolipoprotein B–containing lipoproteins with phosphotungstic acid.
Economic status was classified in to three groups (low, moderate, and high) based on scoring variables, including home area (square meters), household income, and owning a private car. In addition, based on educational level (primary school, high school, diploma, academic degree), participants were divided into three categories of low, moderate, and high. International physical activity scoring system was utilized for dividing participants in to three groups of low, moderate, and vigorous physical activity levels. Moreover, smoking habit was recorded for each participant and they were classified in to two categories of smokers and non-smokers. The details were reported in a previous study (Sarebanhassanabadi et al., 2018).
Ethical consideration: Ethical approval of the current study was obtained from the Ethics Committee of Shahid Sadoughi University of Medical Sciences in Yazd, Iran (ethical code: IR.SSU.MEDICINE.REC. 1395.287). Also, informed consent was obtained from all participants at the first and second phases of the study.
Data analysis: Statistical Package for Social Sciences (SPSS 19, IBM Corporation, New York, USA) was used to analyze of the data. Student t-test was used for comparison of continuous variables, including age, weight, BMI, systolic and diastolic blood pressure, TG, HDL-cholesterol, and WC between two groups of completed and lost to follow-up. Chi-square test was used for the comparison of categorical data, including gender, smoking, economic status, physical activity, and educational levels. In this study, P-value of less than 0.05 was considered as significant level. Cox proportional hazards model was used to estimate the risk of overweight and obesity after a 10-year follow-up considering age, gender, smoking, economic status, physical activity, and educational levels.
Results
The baseline characteristics of the participants without overweight who were lost to follow-up and those completing the study are shown in Table 1. As indicated, there were significant differences in age, weight, systolic blood pressure, socioeconomic status, and education. The participants in the follow-up group were significantly younger, had higher body weight, and lower systolic blood pressure compared to another group. Table 4 reveals that the participants without obesity in the follow-up group were significantly younger, had higher body weight, BMI, and waist circumference and they had lower fasting blood glucose and systolic blood pressure compared to those who lost to follow-up. Moreover, education (P = 0.001) and socioeconomic status (P = 0.001) were significantly different between the follow-up and lost to follow-up groups. There was no significant difference in diastolic blood pressure, TG, HDL-C, physical activity, and smoking between the two groups.
The annual incidence rate of overweight in men, women, and total population was 3.7%, 4.2%, and 3.9%, respectively. The annual incidence rate of obesity in men, women, and total population was 1.06%, 2.1%, and 1.49%, respectively (Table 5).
Table 2 indicates that the overall incidence of overweight during 9.8-year follow-up was 38.37/1000 person-year. Indeed, the incidence of overweight in women was greater than men, 41.43/1000 person-year in women and 37.22/1000 person-year in men, but there was no significant difference between the two groups. However, the incidence of obesity in women was significantly higher than men (Table 6).
|
Missing data
n= 22 |
|
Overweight [n= 199(38.6%)]
Obese n= 158(14.8%) |
|
Non-overweight [n= 317(61.4%)]
Non-obese [n= 910(85.5%)] |
|
Overweight [n= 1168 (59%)]
Obese [n= 376(19%)] |
|
Non-overweight [n= 810 (41%)]
Non-obese [n= 1602(81%)] |
|
Baseline (2005-2006)
n= 1978 |
|
Repeated measurement (2015-2016)
|
|
Loss to follow-up for overweight [n= 294(36.3%)]
Loss to follow-up for obesity [n= 534(33.3%)] |
|
Follow-up for overweight [n= 516(63.7%)]
Follow-up for obesity [n= 1068(66.7%)] |
Elderly participants aged 65-74 years had a lower risk of developing overweight compared to the participants aged 20-30 years (Table 2). Older participants had a greater risk of obesity which was not significant in different age groups except for the
participants aged 30-39 years (Table 6). Among remaining predictive variables, moderate level of education and economic status showed significant association with developing the risk of overweight (Table 2). Furthermore, non-smoking was significantly associated with higher risk of obesity and overweight. There was no significant difference between the variables of physical activity, education, and economic status with the risk of obesity (Table 6).
Table 3 represents the association between predictive variables and hazard ratio for overweight based on gender. The lowest rate of incident overweight was observed in men aged 65-74 years (HR = 0.44, 95% CI: 0.20 – 0.97) compared to the participants aged 20-30 years. Non-smoking was also significantly associated with higher risk of overweight in men (HR = 1.57, 95%CI: 1.05-2.36) and total population (HR = 1.54, 95%CI: 1.06-2.25). There was no significant difference between the risk of overweight and other variables, including physical activity, education, and economic status in males. In females, only moderate educational level was significantly associated with higher risk of overweight (HR = 2.03, 95%CI: 1.23 – 3.35).
The risk of obesity in men and women is reported in Table 7. There was no significant difference between the risk of obesity and all categorized variables except for age in women.
participants aged 30-39 years (Table 6). Among remaining predictive variables, moderate level of education and economic status showed significant association with developing the risk of overweight (Table 2). Furthermore, non-smoking was significantly associated with higher risk of obesity and overweight. There was no significant difference between the variables of physical activity, education, and economic status with the risk of obesity (Table 6).
Table 3 represents the association between predictive variables and hazard ratio for overweight based on gender. The lowest rate of incident overweight was observed in men aged 65-74 years (HR = 0.44, 95% CI: 0.20 – 0.97) compared to the participants aged 20-30 years. Non-smoking was also significantly associated with higher risk of overweight in men (HR = 1.57, 95%CI: 1.05-2.36) and total population (HR = 1.54, 95%CI: 1.06-2.25). There was no significant difference between the risk of overweight and other variables, including physical activity, education, and economic status in males. In females, only moderate educational level was significantly associated with higher risk of overweight (HR = 2.03, 95%CI: 1.23 – 3.35).
The risk of obesity in men and women is reported in Table 7. There was no significant difference between the risk of obesity and all categorized variables except for age in women.
| Table 1. Characteristics of the follow-up and lost to follow-up in non-overweight participants at the baseline. | ||||
| Variables | Follow-up | Lost to follow-up | Total | P-valuea |
| Age (year) | 44.09 ± 15.47b | 52.35 ± 18.20 | 47.09 ± 16.97 | <0.001 |
| Weight (kg) | 62.80 ± 9.34 | 59.43 ± 9.31 | 61.57 ± 9.46 | <0.001 |
| BMI (kg/m2) | 22.14 ± 2.17 | 21.73 ± 2.26 | 21.99 ± 2.21 | 0.11 |
| Systolic blood pressure (mmHg) | 123.58 ± 14.66 | 127.23 ± 16.58 | 124.90 ± 15.47 | 0.002 |
| Diastolic blood pressure (mmHg) | 80.37 ± 8.54 | 81.15 ± 8.85 | 80.65 ± 8.66 | 0.218 |
| Fasting blood glucose (mg/dl) | 95.45 ± 40.36 | 99.50 ± 46.69 | 96.92 ± 42.77 | 0.214 |
| Triglyceride (mg/dl) | 150.27 ± 96.15 | 149.00 ± 86.82 | 149.81 ± 92.83 | 0.851 |
| HDL-cholesterol(mg/dl) | 53.62 ± 14.60 | 55.38 ± 14.66 | 54.26 ± 14.64 | 0.100 |
| Waist circumference (cm) | 84.76 ± 9.60 | 84.26 ± 9.37 | 84.58 ± 9.51 | 0.476 |
| Gender | ||||
| Male | 326 (63.2) c | 166(56.5) | 492(60.7) | 0.062 |
| Female | 190 (36.8) | 128(43.5) | 318(39.3) | |
| Current smokers | 110 (21.3) | 78(26.5) | 188(23.2) | 0.100 |
| Socioeconomic status | ||||
| Low | 70 (28.7) | 52(42.3) | 122(33.2) | 0.006 |
| Moderate | 106 (43.4) | 52(42.3) | 158(43.1) | |
| High | 68 (27.9) | 19(15.4) | 87(23.7) | |
| Physical activity | ||||
| Low | 225 (62.3) | 146 (70.5) | 371 (65.3) | 0.095 |
| Moderate | 118 (32.7) | 50 (24.2) | 168 (29.6) | |
| Vigorous | 18 (5.0) | 11 (5.3) | 29 (5.1) | |
| Education | ||||
| Low | 249 (51.2) | 198 (68.5) | 447 (57.7) | <0.0001 |
| Moderate | 173 (35.6) | 70 (24.2) | 243 (31.4) | |
| High | 64 (13.2) | 21 (7.3) | 85 (11.0) | |
| a:Chi-square used for categorical variables and ANOVA test used for quantitative variables ; b: mean ± SD; c: n (%) | ||||
| Table 2. Hazard ratio of overweight after a 10-year follow-up. | ||||||
| Variables | At risk (n) | Person year | Cases (n) |
Incidence/1000 person-year | Hazard ratio HR(95%CI) | |
| Age groups (y) |
20-30 | 126 | 1260.60 | 50 | 39.66 | 1 |
| 30-39 | 90 | 898.66 | 44 | 48.96 | 0.99(0.65-1.49) | |
| 40-49 | 102 | 1005.86 | 46 | 45.73 | 1.35(0.90-2.03) | |
| 50-65 | 135 | 1327.71 | 43 | 32.38 | 0.77(0.51-1.17) | |
| ≥65 | 63 | 637.51 | 16 | 25.09 | 0.50(0.28-0.88) | |
| Gender |
Male | 326 | 3223.54 | 120 | 37.22 | 1 |
| Female | 190 | 1906.80 | 79 | 41.43 | 1.03(0.78-1.37) | |
| Smoking |
Smoker | 110 | 1097.32 | 33 | 30.07 | 1 |
| Non-smoker | 406 | 4033.02 | 166 | 41.16 | 1.54(1.06-2.25) | |
| Socioeconomic status |
Low | 70 | 721.02 | 28 | 38.83 | 1 |
| Moderate | 106 | 1067.30 | 48 | 44.97 | 1.82(1.13-2.94) | |
| High | 68 | 682.46 | 20 | 29.30 | 0.98(0.55-1.74) | |
| Physical activity |
Low | 225 | 2235.13 | 81 | 36.23 | 1 |
| Moderate | 118 | 1169.35 | 44 | 37.62 | 1(0.69-1.44) | |
| Vigorous | 18 | 180.34 | 9 | 49.90 | 1.36(0.68-2.73) | |
| Education |
Low | 249 | 2490.48 | 93 | 37.34 | 1 |
| Moderate | 173 | 1694.08 | 74 | 43.68 | 1.56(1.14-2.13) | |
| High | 64 | 644.62 | 20 | 31.02 | 0.79(0.48-1.29) | |
| Total | 516 | 5130.34 | 199 | 38.37 | - | |
| Table 3. Hazard ratio of overweight based on gender after a 10-year follow-up. | ||||||||||
| Variables | Men | Women | ||||||||
| At risk (n) |
Person year |
Cases (n) |
Incidence/1000 person-year | Hazard ratio HR(95%CI) | At risk (n) | Person year | Cases (n) |
Incidence/1000 person-year | Hazard ratio HR(95%CI) | |
| Age groups (y) | ||||||||||
| 20-30 | 78 | 778.47 | 32 | 41.10 | 1 | 48 | 482.13 | 18 | 37.33 | 1 |
| 30-39 | 56 | 561.50 | 26 | 46.30 | 0.88(0.52-1.49) | 34 | 337.17 | 18 | 53.38 | 1.23(0.64-2.39) |
| 40-49 | 66 | 652.68 | 26 | 39.83 | 1.12(0.66-1.89) | 36 | 353.17 | 20 | 56.62 | 1.80(0.95-3.42) |
| 50-65 | 86 | 828.77 | 28 | 33.78 | 0.91(0.54-1.51) | 49 | 498.94 | 15 | 30.06 | 0.58(0.29-1.16) |
| ≥65 | 40 | 402.12 | 8 | 19.89 | 0.44(0.20-0.97) | 23 | 235.39 | 8 | 33.98 | 0.52(0.22-1.22) |
| Smoking | ||||||||||
| Yes | 108 | 1075.78 | 33 | 30.67 | 1 | - | - | - | - | - |
| No | 218 | 2147.75 | 87 | 40.50 | 1.57(1.05-2.36) | - | - | - | - | - |
| Socioeconomic status | ||||||||||
| Low | 46 | 466.23 | 17 | 36.46 | 1 | 24 | 254.79 | 11 | 43.17 | 1 |
| Moderate | 78 | 782.18 | 36 | 46.02 | 1.68(0.93-3.01) | 28 | 285.12 | 12 | 42.08 | 2.22(0.91-5.39) |
| High | 49 | 490.60 | 13 | 26.49 | 0.80(0.38-1.65) | 19 | 191.87 | 7 | 36.48 | 1.61(0.60-4.29) |
| Physical activity | ||||||||||
| Low | 159 | 1564.40 | 60 | 38.35 | 1 | 66 | 670.73 | 21 | 31.30 | 1 |
| Moderate | 79 | 781.38 | 28 | 35.83 | 0.91(0.58-1.43) | 39 | 387.97 | 16 | 41.24 | 1.23(0.64-2.37) |
| Vigorous | 16 | 159.40 | 7 | 43.91 | 1.06(0.48-2.34) | 2 | 20.94 | 2 | 95.51 | 4.03(0.92-17.61) |
| Education | ||||||||||
| Low | 134 | 1331.64 | 50 | 37.54 | 1 | 115 | 1158.84 | 43 | 37.10 | 1 |
| Moderate | 118 | 1147.14 | 46 | 40.09 | 1.38(0.92-2.07) | 55 | 546.94 | 28 | 51.19 | 2.03(1.23-3.35) |
| High | 51 | 517.05 | 16 | 30.94 | 0.67(0.38-1.18) | 13 | 127.58 | 4 | 31.35 | 1.74(0.61-4.94) |
| Total | 326 | 3223.54 | 120 | 37.23 | - | 190 | 1906.8 | 79 | 41.43 | - |
| Table 4. Baseline characteristics of the follow-up and lost to follow-up participants in obese and non-obese participants. | ||||
| Variables | Follow-up | Lost to follow-up | Total | P-valuea |
| Age (year) | 46.5 ± 14.4b | 51.9 ± 17.1 | 43.8 ± 15.4 | 0.001 |
| Weight (kg) | 68.9 ± 11.0 | 65.1 ± 11.3 | 48.3 ± 15.5 | 0.001 |
| Body mass index (kg/m2) | 24.8 ± 3.1 | 24.2 ± 3.3 | 24.6 ± 3.2 | 0.004 |
| Systolic blood pressure (mmHg) | 126.7 ± 15.3 | 129.1 ± 6.9 | 127.5 ± 15.9 | 0.007 |
| Diastolic blood pressure (mmHg) | 82.0 ± 8.8 | 82.2 ± 9.1 | 82.1 ± 88.9 | 0.569 |
| Fasting blood glucose (mg/dl) | 99.1 ± 40.5 | 106.7 ± 54.1 | 101.6 ± 45.6 | 0.004 |
| Triglyceride (mg/dl) | 171.1 ± 106.1 | 171.3 ± 114.7 | 171.2 ± 109.0 | 0.983 |
| HDL-cholesterol(mg/dl) | 53.5 ± 13.6 | 54.3 ± 13.8 | 53.8 ± 13.6 | 0.267 |
| Waist circumference (cm) | 90.9 ± 10.6 | 89.6 ± 10.8 | 90.5 ± 10.7 | 0.020 |
| Gender | ||||
| Male | 621 (58.1)c | 260 (48.7) | 881 | 0.001 |
| Female | 447 (41.9) | 274 (51.3) | 721 | |
| Current smokers | 205 (19.2) | 110 (20.6) | 315 | 0.627 |
| Socioeconomic status | ||||
| Low | 134 (26.5) | 84 (40.2) | 218 | 0.001 |
| Moderate | 207 (41.0) | 81 (38.8) | 288 | |
| High | 164 (32.5) | 44 (21.1) | 208 | |
| Physical activity | ||||
| Low | 498 (66.0) | 267 (73.0) | 765 | 0.062 |
| Moderate | 219 (29.0) | 84 (23.0) | 303 | |
| Vigorous | 38 (5.0) | 15 (4.1) | 53 | |
| Education | ||||
| Low | 561 (54.4) | 355 (67.5) | 916 | 0.001 |
| Moderate | 353 (34.2) | 132 (25.1) | 458 | |
| High | 118 (11.4) | 39 (7.4) | 157 | |
| a:Chi-square used for categorical variables and ANOVA test used for quantitative variables ; b: mean ± SD; c: n (%) | ||||
| Table 5. Cumulative and annual risk of overweight and obesity based on gender and total population. | |||||
| Variables | At risk (n) |
Loss to follow-up (n) |
Cases (n) |
9.9-yr cumulative incidence rate (%) | Annual incidence rate (%) |
| Overweight | |||||
| Men | 492 | 166 | 120 | 36.8 | 3.7 |
| Women | 318 | 128 | 79 | 41.6 | 4.2 |
| Total | 810 | 294 | 299 | 38.6 | 3.9 |
| Obesity | |||||
| Men | 621 | 260 | 65 | 10.5 | 1.06 |
| Women | 447 | 274 | 93 | 20.8 | 2.1 |
| Total | 1068 | 534 | 158 | 14.8 | 1.49 |
| Table 6. Hazard ratio of obesity after a 10-year follow-up. | |||||
| Variables | At risk (n) |
Person year | Cases (n) |
Incidence/1000 person-year | Hazard ratio HR(95%CI) |
| Age groups (year) | |||||
| 20-30 | 177 | 1778.81 | 20 | 11.24 | 1 |
| 30-39 | 190 | 1884.75 | 42 | 22.28 | 2.07(1.21-3.54) |
| 40-49 | 243 | 2407.73 | 34 | 14.12 | 1.44(0.83-2.51) |
| 50-59 | 219 | 2148.87 | 35 | 16.28 | 1.62(0.93-2.81) |
| ≥60 | 239 | 2392.73 | 27 | 11.28 | 1.03(0.57-1.84) |
| Gender | |||||
| Male | 621 | 6142.5 | 65 | 10.58 | 1 |
| Female | 447 | 4470.38 | 93 | 20.80 | 1.77(1.28-2.44) |
| Smoking | |||||
| Yes | 205 | 2049.26 | 20 | 9.75 | 1 |
| No | 862 | 8554.48 | 138 | 16.13 | 1.74(1.09-2.79) |
| Socioeconomic status | |||||
| Low | 134 | 1361.8 | 21 | 15.42 | 1 |
| Moderate | 207 | 2068.01 | 29 | 14.02 | 1.01(0.57-1.78) |
| High | 164 | 1644.38 | 29 | 17.63 | 1.39(0.79-2.44) |
| Physical activity | |||||
| Low | 498 | 4951.97 | 78 | 15.75 | 1 |
| Moderate | 219 | 2192.03 | 28 | 12.77 | 0.82(0.53-1.26) |
| Vigorous | 38 | 381.76 | 5 | 13.09 | 0.82(0.33-2.02) |
| Education | |||||
| Low | 561 | 5592.9 | 90 | 16.09 | 1 |
| Moderate | 353 | 3479.83 | 52 | 14.94 | 1.004(0.71-1.41) |
| High | 118 | 1176.07 | 12 | 10.20 | 0.6(0.33-1.1) |
| Total | 1068 | 10612.88 | 158 | 14.88 | |
| Table 7. Hazard ratio of obesity based on gender after a 10-year follow-up. | |||||||||||
| Variables | Men | Women | |||||||||
| At risk (n) | Person year | Cases (n) |
Incidence/1000 person-year | Hazard ratio HR(95%CI) | At risk (n) |
Person year | Cases (n) |
Incidence/1000 person-year |
Hazard ratio HR(95%CI) | ||
| Age groups (year) 20-30 |
|||||||||||
| 101 | 1013.29 | 20 | 19.73 | 1 | 76 | 765.52 | 8 | 10.45 | 1 | ||
| 30-39 | 104 | 1036.03 | 19 | 18.33 | 1.55(0.75-3.3.19) | 86 | 848.71 | 23 | 27.09 | 3.02(1.34-6.79) | |
| 40-49 | 144 | 1426.31 | 12 | 8.41 | 0.91(0.40-2.05) | 99 | 981.42 | 22 | 22.41 | 2.33(1.03-5.24) | |
| 50-59 | 127 | 1242.23 | 12 | 9.66 | 0.89(0.39-2.02) | 92 | 906.64 | 23 | 25.36 | 2.78(1.24-6.26) | |
| ≥60 | 145 | 1426.64 | 10 | 7 | 0.72(0.31-1.69) | 94 | 968.09 | 17 | 17.56 | 1.45(0.62-3.37) | |
| Smoking | |||||||||||
| Yes | 199 | 1987.26 | 17 | 8.55 | 1 | 6 | 62 | 3 | 48.38 | 1 | |
| No | 422 | 4155.24 | 48 | 11.55 | 1.47(0.84-2.57) | 441 | 4408.38 | 90 | 20.41 | 0.53(0.16-1.68) | |
| Socioeconomic status | |||||||||||
| Low | 79 | 797.08 | 9 | 11.29 | 1 | 55 | 564.71 | 12 | 21.24 | 1 | |
| Moderate | 147 | 1453.91 | 18 | 12.38 | 1.59(0.68-3.68) | 60 | 614.10 | 11 | 17.91 | 0.71(0.30-1.68) | |
| High | 112 | 1114.29 | 14 | 12.56 | 1.39(0.58-3.32) | 52 | 530.09 | 15 | 28.29 | 1.59(0.74-3.43) | |
| Physical activity | |||||||||||
| Low | 324 | 3181.72 | 34 | 10.68 | 1 | 174 | 1770.25 | 44 | 24.85 | 1 | |
| Moderate | 133 | 1327.75 | 12 | 9.03 | 0.66(0.33-1.31) | 86 | 864.27 | 16 | 18.51 | 0.89(0.49-1.59) | |
| Vigorous | 30 | 302.97 | 2 | 6.60 | 0.45(0.10-1.91) | 8 | 78.79 | 3 | 38.07 | 2.27(0.69-7.42) | |
| Education | |||||||||||
| Low | 268 | 2661.81 | 26 | 9.76 | 1 | 293 | 2931.09 | 64 | 21.83 | 1 | |
| Moderate | 228 | 2235.04 | 25 | 11.18 | 1.12(0.64-1.96) | 125 | 1244.80 | 27 | 21.69 | 1.05(0.67-1.65) | |
| High | 98 | 975.90 | 12 | 12.29 | 0.95(0.47-1.91) | 20 | 200.16 | 0 | - | - | |
| Total | 621 | 6142.50 | 65 | 10.58 | 447 | 4470.38 | 93 | 20.80 | |||
Discussion
This present study provided the incidence estimates for obesity and overweight after 9.8-year follow-up in Yazd. The findings indicated a high incidence of obesity and overweight in a 9.8 year follow-up of. It is revealed that the incidence of obesity was higher in women than men. Nevertheless, the incidence of overweight in women was greater than men, but there was no significant difference between two groups. Among predictive variables, moderate economic status and moderate education were considerably associated with higher risk of overweight. However, non-smoking was significantly associated with higher risk of overweight and obesity. Limited studies are conducted on the incidence of obesity and overweight. Indeed, most published reports are based on cross-sectional studies which are useful to provide the prevalence estimates (Ayatollahi and Ghoreshizadeh, 2010, Ghadiri-Anari et al., 2013, Kiadaliri et al., 2015). Due to discrepancies in culture, socio-behavioral habits, ethnicity and socioeconomic status, the incidence rate may be different in various populations. In a study conducting by Pan et al. on 432,607 participants in the United States, the overall crude incidence of obesity was reported 4% per year which was higher than the incidence of obesity in the current study (1.49%) (Pan et al., 2011). Furthermore, a study indicated that the incidence of obesity significantly decreased by increasing the level of education. However, this association was not significant in the current study. A study also reported that the incidence of obesity was higher in the current and former smokers, which is not in line with the present study. However, findings from other studies examining the association between smoking and BMI or prevalence of obesity were similar to the current study. However, there was no conclusive evidence between smoking and increasing or decreasing incidence rate of weight gain (Lahti-Koski et al., 2002, Tavani et al., 1994). Higher incidence rate of obesity in women was reported by Nemesure et al. They reported that the incidence of obesity was 6.9% in men and 13.1% in women, which is in agreement with the present study. They have also revealed that the incidence rate of overweight was 22.6% and 24.1% for men and women, respectively (Nemesure et al., 2008). However, the greater incidence of overweight in women compared to men was not significant in the current study. Ortiz-Moncada have reported higher incidence of obesity in women compared to men (29.9% vs. 13.1%, respectively) by following 1008 participants after 8-year follow-up (Ortiz-Moncada et al., 2010). In this study, there was no significant difference between economic and smoking status and changes in BMI over the time. However, the findings of the current study indicated that the incidence rate of obesity and overweight was significant in some variables, such as smoking. Furthermore, in the present study, moderate economic status significantly increased the incidence of overweight. On the other hand, Vasan et al. have reported that the incidence of obesity was higher in men according to data from Framingham Heart Study (Vasan et al., 2005). The higher incidence of obesity in women may be justified with high level of unemployment in women in Iran (Hasani, 2013), contributing to obesity (Laitinen et al., 2002). In a study by Hosseinpanah in Tehran, the capital of Iran, during a median of 8-year follow-up, the cumulative incidence of obesity was reported 31.3% (CI: 29.9%–32.7%), 38.1% (CI: 36.2%–40.1%), and 23.4% (CI: 21.6%–25.3%) for total population, women, and men, respectively (Hosseinpanah et al., 2016). However, the cumulative incidence of obesity in the present study was 12.9% in women and 7.4% in men. Similar to the current study, they reported that participants with lower educational level were at higher risk of obesity.
This study was the first cohort study in Yazd to ascertain the incidence of obesity and overweight. The current study had some limitations. First, given that the study was conducted on Yazd population, it cannot be generalized to the general population. Second, due to unavoidable factors, such as migration and death, 33% and 36% of obese and overweight participants were lost to follow-up. Third, in the current study, repeated measurements were done after 10 years; therefore, the real time of occurrence of overweight and obesity were lost. Fourth, changes of lifestyle could not be checked during the past 10 years. However, the current study had numerous strengths. It is a population-based study with long-term follow-up which assessed the incidence rate of obesity and overweight and its risk factors.
Conclusion
In conclusion, this population-based study reported that the incidence of obesity was higher in women compared to men. The most important predictors of overweight seem to be smoking, lower socio-economic status, and education. Increasing trend of obesity prevalence in Iran as a developing country has heightened concerns about risk of various diseases and medical conditions imposing public health burdens. Therefore, it is necessary to develop health-care plans to decrease incidence of obesity and overweight, especially in women.
Funding
The study was supported by Shahid Sadoughi University of Medical Sciences, Yazd, Iran and Iran National Science Foundation (INSF).
Acknowledgement
Thanks are owed to all the participants because of their patience during the cohort study, as well as the authors’ colleagues in Afshar Hospital in Yazd, Iran, for their cooperation in this study.
Conflict of interest statement
The authors declare that there is no conflict of interest in the study.
Authors’ contributions
1) Sarebanhassanabadi M, Namayandeh SM and Salehi-Abargouei A conceived and designed the experiments;
2) Sarebanhassanabadi M and Namayandeh SM performed the experiments;
3) Sarebanhassanabadi M, Pakseresht MR, Beiki O, and Salehi-Abargouei A analyzed and interpreted the data;
4) Sarebanhassanabadi M, Namayandeh SM and Salehi-Abargouei A contributed reagents, materials, analysis tools or data;
5) Moghtaderi F, Sarebanhassanabadi M and Hosseini S wrote the paper;
6) Pakseresht MR, Beiki O, Seyed Hosseini SM, Namayandeh SM, Emami M, and Salehi-Abargouei A revised the paper.
References
Ayatollahi S & Ghoreshizadeh Z 2010. Prevalence of obesity and overweight among adults in Iran. Obesity reviews. 11 (5):
335-337.
Barzin M, et al. 2018a. Incidence of obesity and its predictors in children and adolescents in 10 years of follow up: Tehran lipid and glucose study (TLGS). BMC Pediatrics. 18 (1):
245.
Barzin M, et al. 2018b. Overweight and Obesity: Findings from 20 Years of the Tehran Lipid and Glucose Study. International journal of endocrinology and metabolism. 16 (4 Suppl): e84778.
Djalalinia S, et al. 2020. Patterns of Obesity and Overweight in the Iranian Population: Findings of STEPs 2016. Frontiers in endocrinology. 11: 42.
Dwivedi AK, Dubey P, Cistola DP & Reddy SY 2020. Association Between Obesity and Cardiovascular Outcomes: Updated Evidence from Meta-analysis Studies. Current cardiology reports. 22 (4): 25.
Erfanifar A, Latifi SM, Shahbazian H & Moravej Aleali A 2021. Prevalence and Incidence of Obesity, Overweight & Abdominal Obesity in Adults: A 5-year Longitudinal Study in Ahvaz (2009-2014). Iranian journal of diabetes and obesity.
Ghadiri-Anari A, et al. 2013. Prevalence of obesity and overweight among adults in Iranian population (Yazd Province). Iranian journal of diabetes and obesity. 5 (2): 67-70.
Hasani Z 2013. Factors Affecting the Level of Female Employment in Iran. Technical journal of engineering and applied sciences. 3 (14): 1424-1431.
Hosseinpanah F, et al. 2016. Incidence and potential risk factors of obesity among Tehranian adults. Preventive medicine. 82: 99-104.
Kiadaliri AA, et al. 2015. The prevalence of adulthood overweight and obesity in Tehran: findings from Urban HEART-2 study. Medical journal of the Islamic Republic of Iran. 29: 178.
Lahti-Koski M, Pietinen P, Heliövaara M & Vartiainen E 2002. Associations of body mass index and obesity with physical activity, food choices, alcohol intake, and smoking in the 1982–1997 FINRISK Studies. American journal of clinical nutrition. 75 (5): 809-817.
Laitinen J, Power C, Ek E, Sovio U & Järvelin M-R 2002. Unemployment and obesity among young adults in a northern Finland 1966 birth cohort. International journal of obesity. 26 (10): 1329.
Lega IC & Lipscombe LL 2020. Review: Diabetes, Obesity, and Cancer-Pathophysiology and Clinical Implications. Endocrine reviews. 41 (1).
Lim HJ, Xue H & Wang Y 2020. Global Trends in Obesity. In Handbook of Eating and Drinking: Interdisciplinary Perspectives (ed. H. L. Meiselman), pp. 1217-1235. Springer International Publishing: Cham.
National Cholesterol Education Program Adult Treatment Panel III 2002. Third report of the National Cholesterol Education Program (NCEP) expert panel on detection, evaluation, and treatment of high blood cholesterol in adults (Adult Treatment Panel III) final report. Circulation. 106: 3143-3421.
Nemesure B, Wu S, Hennis A & Leske M 2008. Nine-year incidence of obesity and overweight in an African-origin population. International journal of obesity. 32 (2): 329.Ortiz-Moncada R, García M, González-Zapata LI, Fernandez E & Álvarez-Dardet C 2010.
ncidence of overweight and obesity in a Mediterranean population-based cohort: the CornHealth Interview Survey Follow-up Study (CHIS. FU). Preventive medicine. 50 (1-2): 45-49.
Pan L, Freedman DS, Gillespie C, Park S & Sherry B 2011. Incidences of obesity and extreme obesity among US adults: findings from the 200 Behavioral Risk Factor Surveillance System. Population health metrics. 9 (1): 56.
Prentice AM 2005. The emerging epidemic of obesity in developing countries. International journal of epidemiology. 35 (1): 93-99.
Rahmani A, et al. 2015 Investigation of the Prevalence of Obesity in Iran: a Systematic Review and Meta-Analysis Study. Acta Medica Iranica. 53 (10): 596-607.
Sarebanhassanabadi M, et al. 2017. The Incidence of Metabolic Syndrome and the Most Powerful Components as Predictors of Metabolic Syndrome in Central Iran: A 10-Year Follow-Up in a Cohort Study. Iranian red crescent medical journal. 19 (7): e14934.
Sarebanhassanabadi M, et al. 2018. Effect of dietary habits on the risk of metabolic syndrome: Yazd Healthy Heart Project. Public health nutrition. 21 (6): 1139-1146.
Tavani A, Negri E & La CV 1994. Determinants of body mass index: a study from northern Italy. International journal of obesity and related metabolic disorders. 18 (7): 497-502.
Vasan RS, Pencina MJ, Cobain M, Freiberg MS & D'Agostino RB 2005. Estimated risks for developing obesity in the Framingham Heart Study. Annals of internal medicine. 143 (7): 473-480.
World Health Organization 2017. Obesity and Overweight, http://www.who.int/mediacentre/ factsheets/ fs311/en/.
This present study provided the incidence estimates for obesity and overweight after 9.8-year follow-up in Yazd. The findings indicated a high incidence of obesity and overweight in a 9.8 year follow-up of. It is revealed that the incidence of obesity was higher in women than men. Nevertheless, the incidence of overweight in women was greater than men, but there was no significant difference between two groups. Among predictive variables, moderate economic status and moderate education were considerably associated with higher risk of overweight. However, non-smoking was significantly associated with higher risk of overweight and obesity. Limited studies are conducted on the incidence of obesity and overweight. Indeed, most published reports are based on cross-sectional studies which are useful to provide the prevalence estimates (Ayatollahi and Ghoreshizadeh, 2010, Ghadiri-Anari et al., 2013, Kiadaliri et al., 2015). Due to discrepancies in culture, socio-behavioral habits, ethnicity and socioeconomic status, the incidence rate may be different in various populations. In a study conducting by Pan et al. on 432,607 participants in the United States, the overall crude incidence of obesity was reported 4% per year which was higher than the incidence of obesity in the current study (1.49%) (Pan et al., 2011). Furthermore, a study indicated that the incidence of obesity significantly decreased by increasing the level of education. However, this association was not significant in the current study. A study also reported that the incidence of obesity was higher in the current and former smokers, which is not in line with the present study. However, findings from other studies examining the association between smoking and BMI or prevalence of obesity were similar to the current study. However, there was no conclusive evidence between smoking and increasing or decreasing incidence rate of weight gain (Lahti-Koski et al., 2002, Tavani et al., 1994). Higher incidence rate of obesity in women was reported by Nemesure et al. They reported that the incidence of obesity was 6.9% in men and 13.1% in women, which is in agreement with the present study. They have also revealed that the incidence rate of overweight was 22.6% and 24.1% for men and women, respectively (Nemesure et al., 2008). However, the greater incidence of overweight in women compared to men was not significant in the current study. Ortiz-Moncada have reported higher incidence of obesity in women compared to men (29.9% vs. 13.1%, respectively) by following 1008 participants after 8-year follow-up (Ortiz-Moncada et al., 2010). In this study, there was no significant difference between economic and smoking status and changes in BMI over the time. However, the findings of the current study indicated that the incidence rate of obesity and overweight was significant in some variables, such as smoking. Furthermore, in the present study, moderate economic status significantly increased the incidence of overweight. On the other hand, Vasan et al. have reported that the incidence of obesity was higher in men according to data from Framingham Heart Study (Vasan et al., 2005). The higher incidence of obesity in women may be justified with high level of unemployment in women in Iran (Hasani, 2013), contributing to obesity (Laitinen et al., 2002). In a study by Hosseinpanah in Tehran, the capital of Iran, during a median of 8-year follow-up, the cumulative incidence of obesity was reported 31.3% (CI: 29.9%–32.7%), 38.1% (CI: 36.2%–40.1%), and 23.4% (CI: 21.6%–25.3%) for total population, women, and men, respectively (Hosseinpanah et al., 2016). However, the cumulative incidence of obesity in the present study was 12.9% in women and 7.4% in men. Similar to the current study, they reported that participants with lower educational level were at higher risk of obesity.
This study was the first cohort study in Yazd to ascertain the incidence of obesity and overweight. The current study had some limitations. First, given that the study was conducted on Yazd population, it cannot be generalized to the general population. Second, due to unavoidable factors, such as migration and death, 33% and 36% of obese and overweight participants were lost to follow-up. Third, in the current study, repeated measurements were done after 10 years; therefore, the real time of occurrence of overweight and obesity were lost. Fourth, changes of lifestyle could not be checked during the past 10 years. However, the current study had numerous strengths. It is a population-based study with long-term follow-up which assessed the incidence rate of obesity and overweight and its risk factors.
Conclusion
In conclusion, this population-based study reported that the incidence of obesity was higher in women compared to men. The most important predictors of overweight seem to be smoking, lower socio-economic status, and education. Increasing trend of obesity prevalence in Iran as a developing country has heightened concerns about risk of various diseases and medical conditions imposing public health burdens. Therefore, it is necessary to develop health-care plans to decrease incidence of obesity and overweight, especially in women.
Funding
The study was supported by Shahid Sadoughi University of Medical Sciences, Yazd, Iran and Iran National Science Foundation (INSF).
Acknowledgement
Thanks are owed to all the participants because of their patience during the cohort study, as well as the authors’ colleagues in Afshar Hospital in Yazd, Iran, for their cooperation in this study.
Conflict of interest statement
The authors declare that there is no conflict of interest in the study.
Authors’ contributions
1) Sarebanhassanabadi M, Namayandeh SM and Salehi-Abargouei A conceived and designed the experiments;
2) Sarebanhassanabadi M and Namayandeh SM performed the experiments;
3) Sarebanhassanabadi M, Pakseresht MR, Beiki O, and Salehi-Abargouei A analyzed and interpreted the data;
4) Sarebanhassanabadi M, Namayandeh SM and Salehi-Abargouei A contributed reagents, materials, analysis tools or data;
5) Moghtaderi F, Sarebanhassanabadi M and Hosseini S wrote the paper;
6) Pakseresht MR, Beiki O, Seyed Hosseini SM, Namayandeh SM, Emami M, and Salehi-Abargouei A revised the paper.
References
Ayatollahi S & Ghoreshizadeh Z 2010. Prevalence of obesity and overweight among adults in Iran. Obesity reviews. 11 (5):
335-337.
Barzin M, et al. 2018a. Incidence of obesity and its predictors in children and adolescents in 10 years of follow up: Tehran lipid and glucose study (TLGS). BMC Pediatrics. 18 (1):
245.
Barzin M, et al. 2018b. Overweight and Obesity: Findings from 20 Years of the Tehran Lipid and Glucose Study. International journal of endocrinology and metabolism. 16 (4 Suppl): e84778.
Djalalinia S, et al. 2020. Patterns of Obesity and Overweight in the Iranian Population: Findings of STEPs 2016. Frontiers in endocrinology. 11: 42.
Dwivedi AK, Dubey P, Cistola DP & Reddy SY 2020. Association Between Obesity and Cardiovascular Outcomes: Updated Evidence from Meta-analysis Studies. Current cardiology reports. 22 (4): 25.
Erfanifar A, Latifi SM, Shahbazian H & Moravej Aleali A 2021. Prevalence and Incidence of Obesity, Overweight & Abdominal Obesity in Adults: A 5-year Longitudinal Study in Ahvaz (2009-2014). Iranian journal of diabetes and obesity.
Ghadiri-Anari A, et al. 2013. Prevalence of obesity and overweight among adults in Iranian population (Yazd Province). Iranian journal of diabetes and obesity. 5 (2): 67-70.
Hasani Z 2013. Factors Affecting the Level of Female Employment in Iran. Technical journal of engineering and applied sciences. 3 (14): 1424-1431.
Hosseinpanah F, et al. 2016. Incidence and potential risk factors of obesity among Tehranian adults. Preventive medicine. 82: 99-104.
Kiadaliri AA, et al. 2015. The prevalence of adulthood overweight and obesity in Tehran: findings from Urban HEART-2 study. Medical journal of the Islamic Republic of Iran. 29: 178.
Lahti-Koski M, Pietinen P, Heliövaara M & Vartiainen E 2002. Associations of body mass index and obesity with physical activity, food choices, alcohol intake, and smoking in the 1982–1997 FINRISK Studies. American journal of clinical nutrition. 75 (5): 809-817.
Laitinen J, Power C, Ek E, Sovio U & Järvelin M-R 2002. Unemployment and obesity among young adults in a northern Finland 1966 birth cohort. International journal of obesity. 26 (10): 1329.
Lega IC & Lipscombe LL 2020. Review: Diabetes, Obesity, and Cancer-Pathophysiology and Clinical Implications. Endocrine reviews. 41 (1).
Lim HJ, Xue H & Wang Y 2020. Global Trends in Obesity. In Handbook of Eating and Drinking: Interdisciplinary Perspectives (ed. H. L. Meiselman), pp. 1217-1235. Springer International Publishing: Cham.
National Cholesterol Education Program Adult Treatment Panel III 2002. Third report of the National Cholesterol Education Program (NCEP) expert panel on detection, evaluation, and treatment of high blood cholesterol in adults (Adult Treatment Panel III) final report. Circulation. 106: 3143-3421.
Nemesure B, Wu S, Hennis A & Leske M 2008. Nine-year incidence of obesity and overweight in an African-origin population. International journal of obesity. 32 (2): 329.Ortiz-Moncada R, García M, González-Zapata LI, Fernandez E & Álvarez-Dardet C 2010.
ncidence of overweight and obesity in a Mediterranean population-based cohort: the CornHealth Interview Survey Follow-up Study (CHIS. FU). Preventive medicine. 50 (1-2): 45-49.
Pan L, Freedman DS, Gillespie C, Park S & Sherry B 2011. Incidences of obesity and extreme obesity among US adults: findings from the 200 Behavioral Risk Factor Surveillance System. Population health metrics. 9 (1): 56.
Prentice AM 2005. The emerging epidemic of obesity in developing countries. International journal of epidemiology. 35 (1): 93-99.
Rahmani A, et al. 2015 Investigation of the Prevalence of Obesity in Iran: a Systematic Review and Meta-Analysis Study. Acta Medica Iranica. 53 (10): 596-607.
Sarebanhassanabadi M, et al. 2017. The Incidence of Metabolic Syndrome and the Most Powerful Components as Predictors of Metabolic Syndrome in Central Iran: A 10-Year Follow-Up in a Cohort Study. Iranian red crescent medical journal. 19 (7): e14934.
Sarebanhassanabadi M, et al. 2018. Effect of dietary habits on the risk of metabolic syndrome: Yazd Healthy Heart Project. Public health nutrition. 21 (6): 1139-1146.
Tavani A, Negri E & La CV 1994. Determinants of body mass index: a study from northern Italy. International journal of obesity and related metabolic disorders. 18 (7): 497-502.
Vasan RS, Pencina MJ, Cobain M, Freiberg MS & D'Agostino RB 2005. Estimated risks for developing obesity in the Framingham Heart Study. Annals of internal medicine. 143 (7): 473-480.
World Health Organization 2017. Obesity and Overweight, http://www.who.int/mediacentre/ factsheets/ fs311/en/.
Type of article: orginal article |
Subject:
public specific
Received: 2021/09/25 | Published: 2022/08/19 | ePublished: 2022/08/19
Received: 2021/09/25 | Published: 2022/08/19 | ePublished: 2022/08/19
References
1. Ayatollahi S & Ghoreshizadeh Z 2010. Prevalence of obesity and overweight among adults in Iran. Obesity reviews. 11 (5):
2. 335-337.
3. Barzin M, et al. 2018a. Incidence of obesity and its predictors in children and adolescents in 10 years of follow up: Tehran lipid and glucose study (TLGS). BMC Pediatrics. 18 (1):
5. Barzin M, et al. 2018b. Overweight and Obesity: Findings from 20 Years of the Tehran Lipid and Glucose Study. International journal of endocrinology and metabolism. 16 (4 Suppl): e84778.
6. Djalalinia S, et al. 2020. Patterns of Obesity and Overweight in the Iranian Population: Findings of STEPs 2016. Frontiers in endocrinology. 11: 42.
7. Dwivedi AK, Dubey P, Cistola DP & Reddy SY 2020. Association Between Obesity and Cardiovascular Outcomes: Updated Evidence from Meta-analysis Studies. Current cardiology reports. 22 (4): 25.
8. Erfanifar A, Latifi SM, Shahbazian H & Moravej Aleali A 2021. Prevalence and Incidence of Obesity, Overweight & Abdominal Obesity in Adults: A 5-year Longitudinal Study in Ahvaz (2009-2014). Iranian journal of diabetes and obesity.
9. Ghadiri-Anari A, et al. 2013. Prevalence of obesity and overweight among adults in Iranian population (Yazd Province). Iranian journal of diabetes and obesity. 5 (2): 67-70.
10. Hasani Z 2013. Factors Affecting the Level of Female Employment in Iran. Technical journal of engineering and applied sciences. 3 (14): 1424-1431.
11. Hosseinpanah F, et al. 2016. Incidence and potential risk factors of obesity among Tehranian adults. Preventive medicine. 82: 99-104.
12. Kiadaliri AA, et al. 2015. The prevalence of adulthood overweight and obesity in Tehran: findings from Urban HEART-2 study. Medical journal of the Islamic Republic of Iran. 29: 178.
13. Lahti-Koski M, Pietinen P, Heliövaara M & Vartiainen E 2002. Associations of body mass index and obesity with physical activity, food choices, alcohol intake, and smoking in the 1982–1997 FINRISK Studies. American journal of clinical nutrition. 75 (5): 809-817.
14. Laitinen J, Power C, Ek E, Sovio U & Järvelin M-R 2002. Unemployment and obesity among young adults in a northern Finland 1966 birth cohort. International journal of obesity. 26 (10): 1329.
15. Lega IC & Lipscombe LL 2020. Review: Diabetes, Obesity, and Cancer-Pathophysiology and Clinical Implications. Endocrine reviews. 41 (1).
16. Lim HJ, Xue H & Wang Y 2020. Global Trends in Obesity. In Handbook of Eating and Drinking: Interdisciplinary Perspectives (ed. H. L. Meiselman), pp. 1217-1235. Springer International Publishing: Cham.
17. National Cholesterol Education Program Adult Treatment Panel III 2002. Third report of the National Cholesterol Education Program (NCEP) expert panel on detection, evaluation, and treatment of high blood cholesterol in adults (Adult Treatment Panel III) final report. Circulation. 106: 3143-3421.
18. Nemesure B, Wu S, Hennis A & Leske M 2008. Nine-year incidence of obesity and overweight in an African-origin population. International journal of obesity. 32 (2): 329.
19. Ortiz-Moncada R, García M, González-Zapata LI, Fernandez E & Álvarez-Dardet C 2010.
20. Incidence of overweight and obesity in a Mediterranean population-based cohort: the Cornellà Health Interview Survey Follow-up Study (CHIS. FU). Preventive medicine. 50 (1-2): 45-49.
21. Pan L, Freedman DS, Gillespie C, Park S & Sherry B 2011. Incidences of obesity and extreme obesity among US adults: findings from the 2009 Behavioral Risk Factor Surveillance System. Population health metrics. 9 (1): 56.
22. Prentice AM 2005. The emerging epidemic of obesity in developing countries. International journal of epidemiology. 35 (1): 93-99.
23. Rahmani A, et al. 2015 Investigation of the Prevalence of Obesity in Iran: a Systematic Review and Meta-Analysis Study. Acta Medica Iranica. 53 (10): 596-607.
24. Sarebanhassanabadi M, et al. 2017. The Incidence of Metabolic Syndrome and the Most Powerful Components as Predictors of Metabolic Syndrome in Central Iran: A 10-Year Follow-Up in a Cohort Study. Iranian red crescent medical journal. 19 (7): e14934.
25. Sarebanhassanabadi M, et al. 2018. Effect of dietary habits on the risk of metabolic syndrome: Yazd Healthy Heart Project. Public health nutrition. 21 (6): 1139-1146.
26. Tavani A, Negri E & La CV 1994. Determinants of body mass index: a study from northern Italy. International journal of obesity and related metabolic disorders. 18 (7): 497-502.
27. Vasan RS, Pencina MJ, Cobain M, Freiberg MS & D'Agostino RB 2005. Estimated risks for developing obesity in the Framingham Heart Study. Annals of internal medicine. 143 (7): 473-480.
28. World Health Organization 2017. Obesity and Overweight, http://www.who.int/mediacentre/ factsheets/ fs311/en/.
Send email to the article author
| Rights and permissions | |
 |
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License. |
