Hostname: page-component-76fb5796d-skm99 Total loading time: 0 Render date: 2024-04-28T07:24:56.693Z Has data issue: false hasContentIssue false
  • English
  • Français

Sociodemographic differences in dietary trends among Iranian adults: findings from the 2005–2016 Iran-WHO STEPS survey

Published online by Cambridge University Press:  20 October 2023

Sara Ebrahimi ,
Rebecca M Leech ,
Sarah A McNaughton ,
Farshad Farzadfar ,
Erfan Ghasemi ,
Sahar Saeedi Moghaddam  and
Katherine M Livingstone Open the ORCID record for Katherine M Livingstone [Opens in a new window]
Sara Ebrahimi*
Affiliation:
Deakin University, Institute for Physical Activity and Nutrition, School of Exercise and Nutrition Sciences, Geelong, VIC 3220, Australia
Rebecca M Leech
Affiliation:
Deakin University, Institute for Physical Activity and Nutrition, School of Exercise and Nutrition Sciences, Geelong, VIC 3220, Australia
Sarah A McNaughton
Affiliation:
Deakin University, Institute for Physical Activity and Nutrition, School of Exercise and Nutrition Sciences, Geelong, VIC 3220, Australia
Farshad Farzadfar
Affiliation:
Non-Communicable Diseases Research Center, Endocrinology and Metabolism Population Sciences Institute, Tehran University of Medical Sciences, Tehran, Iran Endocrinology and Metabolism Research Centre, Endocrinology and Metabolism Clinical Sciences Institute, Tehran University of Medical Sciences, Tehran, Iran
Erfan Ghasemi
Affiliation:
Non-Communicable Diseases Research Center, Endocrinology and Metabolism Population Sciences Institute, Tehran University of Medical Sciences, Tehran, Iran Endocrinology and Metabolism Research Centre, Endocrinology and Metabolism Clinical Sciences Institute, Tehran University of Medical Sciences, Tehran, Iran
Sahar Saeedi Moghaddam
Affiliation:
Non-Communicable Diseases Research Center, Endocrinology and Metabolism Population Sciences Institute, Tehran University of Medical Sciences, Tehran, Iran Endocrinology and Metabolism Research Centre, Endocrinology and Metabolism Clinical Sciences Institute, Tehran University of Medical Sciences, Tehran, Iran
Katherine M Livingstone
Affiliation:
Deakin University, Institute for Physical Activity and Nutrition, School of Exercise and Nutrition Sciences, Geelong, VIC 3220, Australia
*
*Corresponding author: Email s.ebrahimi@deakin.edu.au
Rights & Permissions [Opens in a new window]

Abstract

Objective:

To examine trends in the intake of key food groups among Iranian adults between 2005 and 2016, overall, and according to sociodemographic characteristics.

Design:

Repeat cross-sectional data from the Iran-STEPwise approach to risk factor surveillance (Iran-WHO STEPS) 2005–2016 were analysed. Regression analyses were used to evaluate trends in the frequency of fruits, vegetables and fish intake and type of oil used over time. Interactions by sex, age and area of residence were examined.

Setting:

Iran.

Participants:

225 221 Iranian adults.

Results:

The frequency of vegetables (β: −0·03; 95 % CI (−0·06, −0·00); P-trend = 0·030) and fish (β: −0·09; 95 % CI (−0·10, −0·08); P-trend < 0·001) intake and use of solid fat (OR: 0·70; 95 % CI (0·70, 0·72); P-trend < 0·001) declined, whilst the frequency of fruit intake (β-Coeff: 0·03, 95 % CI (0·01, 0·05); P-trend = 0·014) and liquid oil use (OR: 1·40; 95 % CI (1·3, 1·4); P-trend<0·001) rose. Rising trends in fruit intake were larger in mid-aged (40–60 years) and older (>60 years) adults (P-interaction < 0·001), whilst declines in vegetable (P-interaction < 0·001) and fish intake (P-interaction = 0·001) were larger in older adults. The declining use of solid fat was strongest in middle-aged and older adults (P-interaction = 0·035), while the increasing use of liquid oil was strongest in rural areas (P-interaction = 0·011).

Conclusions:

During the nutrition transition, liquid oil use and the frequency of fruit intake rose, while the frequency of vegetables and fish intake declined. Nonetheless, the fatty acid composition and cooking methods are important considerations. The changes observed are concerning from a public health perspective and demonstrate the need for interventions and possible targets for tailored strategies.

Keywords

Dietary trendsIranian adultsNutrition transitionWHO STEPS surveyRepeat-cross-sectionalSociodemographic characteristics
Type
Research Paper
Information
Public Health Nutrition , Volume 26 , Issue 12 , December 2023 , pp. 2963 - 2972
Check for updates
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Nutrition Society

A nutrition transition is a situation in which urbanisation, social development and the advent of modern technology result in changing quality and quantity of foods consumed. Specifically, high-quality foods such as fruits, vegetables and legumes are replaced by foods high in added sugars, fat and salt, animal-source foods and refined grains(Reference Popkin1,Reference Popkin, Adair and Ng2) . While a nutrition transition has been identified in developed countries including the United States and European countries over the past few decades, developing countries such as Indonesia and Myanmar are also experiencing changes in dietary intake(Reference Popkin, Adair and Ng2,Reference Popkin and Ng3) . The Eastern Mediterranean Region (EMR), which includes most Middle Eastern countries, has also experienced a nutrition transition as a result of urbanisation and technological development that has led to higher prevalence of chronic disease(4).

The World Health Organization (WHO) has identified that Iran and neighbouring Arab countries located in the Middle East region, including Kuwait, Bahrain, Emirate, Qatar and Oman, have experienced a nutrition transition, in which dietary intake has changed towards increasing intake of foods high in saturated fat, added sugars and salt and lower intake of fruits and vegetables(4Reference Popkin6). Iran is the second most highly populated country in the Middle East region with a population of over 80 million. It consists of a broad range of different ethnic groups, which are found in other Middle East countries such as Turks, Kurds and Arabs(4,Reference Ghassemi, Harrison and Mohammad7,Reference Rashidvash8) . Since the 1970s, Iran has experienced economic development and rapid urbanisation, resulting in a reduction in infectious diseases and the advent of new challenges in rising rates of obesity and chronic diseases(Reference Ghassemi, Harrison and Mohammad7,Reference Naghavi, Shahraz and Sepanlou9) . This economic and social development has played a significant role in changing dietary behaviours(Reference Golzarand, Mirmiran and Jessri10). While limited studies investigated the type of oil used in this region, evidence shows that Iran and Arab countries have high intake of animal fat and saturated fat. This led the WHO to recommend that these countries apply a policy to reduce the intake of saturated fat in the region(Reference Musaiger, Hassan and Obeid11,12) . Findings report that Iranians use hydrogenated vegetable oils and solid fats for cooking and frying, baking breads and sweets due to their popular taste and aroma(Reference Salehzadeh, Soori and Sadeghi13). Moreover, although Iranian households have traditionally used animal fats for cooking(Reference Salehzadeh, Soori and Sadeghi13), government subsidisation of liquid oils is likely to have led to higher consumption of hydrogenated vegetable oils. Given the role of total fat and SFA in developing obesity and chronic diseases, it is essential to examine the use of different types of oils in the Iranian population(14). It will also help to determine policy impacts on dietary trends(Reference Asgary, Nazari and Sarrafzadegan15). Moreover, data from a national WHO study in 2011 suggest that up to 88 % of Iranian adults aged 15–64 years are consuming less than five servings of fruits and vegetables per day(Reference Kousha, Etemad and Kouhpayezadeh16).

Currently, only one study by Kimiagar et al.(Reference Kimiagar, Ghaffarpour and Houshiar Rad17) has examined trends in dietary intake in Iranian adults at the population level. In this repeat cross-sectional study of 5591 households, changes in the food intake of Iranian households were examined between 1963–1976 and 1991–1995. Results show that bread consumption declined, rice intake rose and trends in the consumption of dairy products did not change during these years. Conversely, there was a rise in the intake of fruits and vegetables, legumes, meats, eggs and total fats(Reference Kimiagar, Ghaffarpour and Houshiar Rad17). Evidence suggests that Iran has experienced a nutrition transition over the past five decades, however, no study has examined trends in food group intakes or use of specific oil types in the Iranian adult population after the year 2000(4,Reference Ghassemi, Harrison and Mohammad7) .

It is unclear whether the nutrition transition is disproportionately affecting different population groups in Iran. A repeat cross-sectional study conducted by Ghassemi et al. compared dietary intake trends between areas of residence (rural and urban areas) from 1985 to 1995(Reference Ghassemi, Harrison and Mohammad7). This study showed that consumption of fruits and vegetables, dairy products and meats rose in rural areas, whilst they declined in urban areas(Reference Ghassemi, Harrison and Mohammad7). Cross-sectional studies of Iranian adults suggest that dietary intakes vary by age(Reference Mirmiran, Hosseini-Esfahanil and Jessri18Reference Esteghamati, Noshad and Nazeri20) and sex(Reference Mirmiran, Hosseini-Esfahanil and Jessri18Reference Mohammadifard, Omidvar and Rad21), with higher intake of fruits in younger adults(Reference Kiadaliri19,Reference Esteghamati, Noshad and Nazeri20) and in women(Reference Mirmiran, Hosseini-Esfahanil and Jessri18). However, no studies have examined differences in dietary trends according to age and sex and no studies have looked at overall trends and differences by population groups in the same study. Thus this study aimed to examine overall trends in dietary intake among adults between the years 2005 and 2016 and to investigate variations in these trends according to sociodemographic characteristics using data from the Iran-WHO STEPS 2005–2016(22,23) . This information will help identify which Iranian population groups, and in which regions, have shown worsening or improvements in dietary intake over the nutrition transition. Furthermore, most countries in the Middle East have experienced a nutrition transition and these countries have culturally specific diets that are characterised by high intake of hydrogenated fats(Reference Esmaillzadeh and Azadbakht24,Reference Ebrahimi, Leech and McNaughton25) . Therefore, an understanding of trends in key food group intakes in the Middle East region, particularly Iran, is needed.

Methods

Subjects and study design

The Iran-WHO STEPS 2005–2016 is a repeat cross-sectional study that was conducted annually in Iran between 2005 and 2009, and then additionally in 2011 and 2016(22,23) . The WHO STEPS surveillance programmes aim to develop continuous evidence to inform the global prevention and control of non-communicable diseases(22,23) . The interviewers were trained on how to complete the questionnaire, and how to store and send the information(26). Participants were included in the present analysis if they were aged 18 years or older. Participants were excluded if they had missing data for any sociodemographic characteristics (age, sex and area of residence) or food group intakes (fruit, vegetables, fish and type of oil)(22,23) . A cluster sampling method was used to recruit participants from all provinces of Iran between 2006 and 2009. In total, 50 clusters and 1000 individuals in each cluster were randomly selected from each province of Iran, while each cluster included 20 individuals, 10 male and 10 females(22,23) . A multistage cluster sampling method was used in 2005 and 2011. A total of 50 distinct counties were selected as the primary sampling units. Urban and rural areas were selected as secondary sampling units. The households were randomly selected using postal codes and one individual was recruited from each household(Reference Malekzadeh, Lotfaliany and Ostovar27). A proportional-to-size cluster sampling method was used in 2016(22,23) . A total of 3105 clusters were selected from all provinces of Iran and 10 participants were recruited from each cluster(Reference Malekzadeh, Lotfaliany and Ostovar27). Trained staff of universities of medical sciences in Iran collected self-reported information on dietary intake, sociodemographic characteristics, lifestyle behaviours and health characteristics. The range of response rate of the surveys was high throughout and ranged between 89·5 % in 2005 and 98·4 % in 2016(22,23) .

Participants were excluded from the present study if they were aged <18 years and had missing data for sociodemographic characteristics or food group intakes. A signed consent form was obtained from all participants. The Iran-WHO STEPS 2005 to 2011 was approved by the Iran Centre for Control of Diseases, and Iran-WHO STEPS 2016 was approved by the National Institute for Medical Research Development. The present analysis was granted an Ethics Exemption by Deakin University (reference number 2019-288). This manuscript is reported according to the Strengthening the Reporting of Observational Studies in Epidemiology—Nutritional Epidemiology reporting checklist (see online Supplemental Table 1)(Reference Lachat, Hawwash and Ocké28).

Study measures

Dietary intakes

Information on the intake of fruits, vegetables, fish and the use of type of oil was collected using a previously tested brief dietary questionnaire(22,23) . Data collected from open-ended questions included: the frequency of intake of fruits (d/week), vegetables (d/week) and fish (times/week). Participants were asked to select the type of oil that was usually used from the following options: solid fat, liquid oil, animal fat (ghee), margarine, no specific type of oil, never-use oil, any other oil, unknown and butter. Due to small numbers of responses (between 0·1 % and 0·3 %), butter was combined with animal fat (ghee) and unknown oil and other oils were combined with no specific type of oil. As a result, solid fat, liquid oil, animal fat, margarine, no specific oil and never-use oil were included in this analysis. There were some minor differences in the dietary questionnaires used between the years. For example, in 2005, fruit intake was assessed by asking participants how many days fruit was consumed in the last week, while in other years it asked how many days fruit was consumed in a typical week. A summary of the brief dietary questions is provided in Supplemental Table 2.

Sociodemographic characteristics

A self-report questionnaire was administered face-to-face by a trained interviewer to collect sociodemographic data including age, sex and area of residence. Participants were asked about their date of birth and selected their sex and area of residence from males and females and urban and rural areas, respectively. For the purpose of this study, age was categorised into three age groups including 18–≤40 years (young adults), 40–≤60 years (mid-aged adults), >60 years (older adults) based on previous research using the Iran-WHO STEPS(Reference Bakhshi, Koohpayehzadeh and Seifi29).

Data analysis

Data analyses were performed using weighted counts using the svy suite of commands for survey weighting (version 16.0; StataCorp.). A P-value of <0·05 was considered statistically significant. To address the differences between the Iran-WHO STEPS sample and the Iranian population, weights were calculated using sex and province according to the 2006 Iranian National Population and Housing Census(30). The weighted mean and linearised standard errors were reported for continuous variables (fruit, vegetable and fish) and the weighted proportion of participants was reported for all categorical and binary variables (sociodemographic characteristics and type of oil). Linear regression analysis was used to evaluate the slopes (β-Coeff and 95 % CI) of frequency of fruit, vegetable and fish intake (d/week, times/week, dependent variables) over time (independent variable). The analysis was adjusted for age (continuous) and area of residence (binary). Each type of oil was treated as a binary outcome variable, and logistic regression analysis was used to evaluate the slopes (odds ratios (OR) and 95 % CI) in the type of oil used (dependent variable) over time (independent variable). Time was treated as an ordinal variable when reporting the mean and percentage of food groups in each year, and treated as a continuous variable when examining the P for trend for slopes across years. Interaction terms were added to the models to examine how trends in diet varied according to the following sociodemographic characteristics: age (categorical), sex (binary) and area of residence (binary). The overall significance of the interaction was determined using the testparm command. Interaction analyses were adjusted for age (continuous), sex (binary) and area of residence (binary), except when the given variable was used in the interaction term. For frequencies of fruit, vegetable and fish intake, the margins post hoc command was used to derive the marginal effect for each category of the sociodemographic characteristic over time using the dydx option. This command helps with identifying coefficients and P values for each sociodemographic category over time (e.g. females and males). For oil use, the lincom post hoc command was used to estimate the effect for each category of the sociodemographic characteristic over time.

Results

Of the 239 713 individuals included in the WHO-STEP surveys, 13 776 individuals were excluded in the present analysis for being <18 years of age (n 13 704; 5·7 % participants excluded) and for missing data for sex (n 69; 0·03 % participants excluded) and area of residence (n 3; 0·001 % participants excluded). A total of 225 937 adults were included in the descriptive analysis of demographic characteristics. To minimise loss from missing data on food group intakes, three samples were used to examine trends in food groups between 2005 and 2016: fruit and vegetables (n 214 597; 5·02 % participants excluded), fish (n 131 799; 41·67 % participants excluded) and oil (n 225 221; 0·32 % participants excluded) (Fig. 1).

Fig. 1 Participants flow diagram from the Iran-WHO STEPS surveys 2005–2016

The weighted proportion of sociodemographic characteristics of Iranian adults between the years 2005 and 2016 is shown in Table 1. In all years, the majority of participants were younger aged males, and living in urban areas.

Table 1 Sociodemographic characteristics in Iranian adults from the Iran-WHO STEPS surveys 2005–2016 (n 225 937)

* Weighting proportions were estimated using sex and province weighting.

Younger aged (18–≤40 years old), mid-aged (40–≤60 years old), older aged (>60 years old).

Trends in the intake of key food groups are presented in Table 2. Between 2005 and 2016, the frequency of intake of fruits (d/week) rose (β: 0·03; 95 % CI (0·01, 0·05); P-trend = 0·014), while there was a decline in the frequency of vegetables (d/week) consumed (β: −0·03; 95 % CI (−0·06, −0·00); P trend = 0·030), and the frequency of consumption of fish (times/week) (β: −0·09; 95 % CI (−0·10, −0·08); P-trend < 0·001) declined. Between 2005 and 2016, the proportion of participants who usually used solid fat declined from 79 % to 29 % (OR: 0·70; 95 % CI (0·70, 0·72); P-trend < 0·001), while the proportion of participants who used liquid oil, animal fat and no specific oil rose from 18 % to 64 % (OR: 1·40; 95 % CI (1·3, 1·4); P-trend < 0·001), 1·3 % to 3 % (OR: 1·13; 95 % CI (1·1, 1·2); P-trend < 0·001) and 0·7 % to 2 % (OR: 1·18; 95 % CI (1·1, 1·3); P-trend < 0·001), respectively. No significant trends were observed for margarine intake and never using oil.

Table 2 Trends in food group intakes and use of oils in Iranian adults from the Iran-WHO STEPS surveys 2005–2016

* Unadjusted mean and SE.

Unadjusted percentage.

Slopes reflect β-Coeff and 95 % CI for fruits, vegetables and fish intake and odds-ratio and 95 % CI for use of oils.

§ Unadjusted P trend. Trends in fruits and vegetables (n pooled = 214 597; 2005 n 74 961; 2006 n 27 966; 2007 n 24 922; 2008 n 23 882; 2009 n 23 867; 2011 n 9844; 2016 n 29 155), and fish intake (n pooled = 131 799; 2005 n 34 152; 2006 n 27 964; 2007 n 12 638; 2008 n 9585; 2009 n 9034; 2011 n 8434; 2016 n 29 992), over time were examined by using Wald tests of associations for linear regression weighted for sex and province.

P trend adjusted for age (continuous) and area of residence (binary). Trends in types of oil over time were examined by using Wald tests of associations for logistic regression (n pooled = 225 222; 2005 n 75 100; 2006 n 27 959; 2007 n 27 473; 2008 n 27 196; 2009 n 27 441; 2011 n 10 087; 2016 n 29 966), weighted for sex and province.

Trends in key food group intake by sociodemographic characteristics are presented in Supplemental Tables 35. Significant interactions were observed for trends in fruit, vegetables and fish intake by age only. While younger adults had non-significant trends in fruit intake between 2005 and 2016 (β: −0·02; P-trend = 0·157), mid-aged (β: 0·06; P-trend < 0·001) and older adults (β: 0·08; P-trend < 0·001) had an increase in fruit intake over time (P-interaction < 0·001). For vegetable intake, the younger (β: −0·05; P-trend = 0·006) and older aged (β: −0·07; P-trend = 0·001) adults had a decline in intake between 2005 and 2016, while trends were non-significant in the mid-aged adults (β: 0·00; P-trend = 0·926) (P-interaction < 0·001). Between 2005 and 2016, younger (β: −0·09; P-trend < 0·001), mid-aged (β: −0·08; P-trend < 0·001) and older adults (β: −0·11; P-trend < 0·001) had a decline in the frequency of fish intake (P-interaction = 0·001).

Trends in solid fat, no specific oils and never-use oil were significantly different between age groups and the trends in liquid oil, animal fat and never-use oil were significantly different between areas of residence (see online Supplemental Table 6). Between 2005 and 2016, younger (OR: 0·71; P-trend < 0·001), mid-aged (OR: 0·70; P-trend < 0·001) and older adults (OR: 0·70; P-trend < 0·001) had a decline in the use of solid fat (P-interaction = 0·035). Adults living in urban (OR: 1·38; P-trend < 0·001) and rural (OR: 1·45; P-trend < 0·001) areas had a rise in the use of liquid oil intake (P-interaction = 0·011). Furthermore, adults in urban (OR: 1·17; P-trend < 0·001) and rural (OR: 1·09; P-trend =0·002) areas had an increase in the use of animal fat (P-interaction = 0·042). Between 2005 and 2016, younger (OR: 1·16; P-trend = 0·001), mid-aged (OR: 1·18; P-trend < 0·001) and older adults (OR: 1·28; P-trend < 0·001) had a rise in the use of no specific oil (P-interaction = 0·012). Adults who lived in rural areas only (OR: 0·83; P-trend = 0·001) had a decline in never using oil (P-interaction = 0·026).

Discussion

Many developed and developing countries have experienced a nutrition transition. Changes in dietary intake towards higher intake of sugars, saturated fat and lower intake of fruits and vegetables have taken place in Middle Eastern countries including Iran. This repeated analysis of the Iran-WHO STEPS cross-sectional surveys examined the 11-year trends in intake of key food groups, overall and by sociodemographic characteristics, in a nationally representative sample of 225 221 Iranian adults. To our knowledge, this is the first study that has evaluated trends in key food groups intakes in this population in the last two decades. The main findings were that the use of solid fat has declined considerably over time, while the use of liquid oil and animal fat has risen. These trends may reflect the impact of Iranian food policy approaches that have been implemented over the past two decades to reduce solid fat intake. Furthermore, although the frequency of fruit intake may have risen, the frequency of vegetable and fish intake declined. With the largest declines observed in older adults, these findings highlight the need for targeted interventions to improve dietary patterns in these age groups. While the frequency of fruit and vegetable intake was higher in females than males between 2005 and 2016, no significant differences were found in fruit and vegetable trends between females and males, which was in line with a previous study on Iran-WHO STEPS(Reference Kiadaliri19).

This study showed that the trend in solid fat use has declined and almost halved between the years 2005 and 2016 while the use of liquid oil rose nearly three-fold. Based on the existing evidence, the average consumption of SFA and trans fatty acids in the EMR countries is over 10 % and 1 % of energy, respectively, which is above WHO recommended intakes. Regarding trans fatty acids intake, the EMR is among the highest intake regions with the highest SFA and trans fatty acids intake in Kuwait, Saudi Arabia, Egypt and Pakistan. As a result, the WHO issued a recommendation for the EMR to adopt initiatives to reduce intake of these fatty acids(Reference Al Jawaldeh and Al-Jawaldeh31). In addition, hydrogenated vegetable oils are also commonly used for cooking and frying in the EMR(32). Findings report that Iranians use hydrogenated vegetable oils and solid fats for cooking and frying, baking breads and sweets(Reference Salehzadeh, Soori and Sadeghi13). Although the present study did not include data on different types of solid fat, previous research found that 12 % of calories consumed by Iranians in 2004 came from hydrogenated vegetable oil(33). The observed trends in solid fat and liquid oil use are likely attributable to policy that was adopted in Iran in 2005 to shift solid fat intake towards the consumption of liquid oil(33). Policy action has included increasing public awareness of the harmful effects of trans fatty acids via mass media campaigns, and collaboration with industry to limit the amount of trans fatty acids in edible oils to less than 10 % of calories, with the ultimate goal of trans fats less than 1 %(33,Reference Peymani, Joulaei and Zamiri34) . Specifically, new industry regulation was introduced on oil fractioning technology to reduce trans fatty acid content, on palm oil imports to reduce palm oil use in the food industry and on food product labelling to show the trans fatty acid content and nutritional traffic light signposting(33,Reference Moslemi, Kheirandish and Mazaheri35,Reference Al-Jawaldeh, Taktouk and Chatila36) . Similar policies have been adopted in other Middle Eastern countries, where Saudi Arabia, Kuwait, Bahrain and Israel launched nutrition labelling on products. In addition, Saudi Arabia has implemented a regulation to reduce the trans fatty acids content of hydrogenated vegetable oil to 2 % of total fat(Reference Kandhro, Sherazi and Mahesar37). However, it is worth mentioning that the benefits of liquid oil use vary depending on fatty acid composition and cooking methods. Frying liquid oils to high temperatures could result in the production of compounds with adverse effects on health(Reference Dobarganes and Márquez-Ruiz38). Furthermore, animal fats consist of vitamins and essential fatty acids, which could be nutritionally beneficial(Reference Barendse39). Future research should investigate the fatty acid composition of liquid oil and cooking methods in the Iranian population.

Despite observed fluctuations in the trends in fruit and vegetable intake over the past two decades, the frequency of vegetable intake declined and the frequency of fruit intake slightly increased overall from 2005 to 2016. This provides supporting evidence for a nutrition transition in Iranian adults, although it conflicts with what studies found prior to the year 2000, when vegetable intake was increasing(Reference Kimiagar, Ghaffarpour and Houshiar Rad17). In line with our findings for differences by population groups, a previous study using Iran-WHO STEP data from 2007 to 2009 reported that daily consumption of fruits and vegetables was lower in older aged groups(Reference Kiadaliri19). The reports identified low intake of fruits and vegetables (below 5 servings/d) in Middle Eastern countries, including Egypt, Kuwait and Saudi Arabia(Reference Aboul-Enein, Bernstein and Neary40,Reference Musaiger41) .

The declining trend in vegetable intake observed in this study suggests that culturally appropriate dietary policies and interventions are needed to address any worsening of diets as a result of the nutrition transition in Iran. Improvements in modifiable risk factors, such as diet, are particularly critical to combat rising rates of obesity and chronic disease in Iran observed during the nutrition transition(Reference Ghassemi, Harrison and Mohammad7). To address these challenges, pragmatic policies and interventions that aim to improve nutrition education and food literacy are needed, as well as programmes to support a healthy food environment.

This study found that the frequency of fish intake has declined in Iranian adults overall, while intake was slightly higher in mid-aged adults. Fish is not considered a common component of Iranian cuisine compared to other protein sources(Reference Aberoumand and Abouali42), where chicken, mutton and beef are more commonly consumed(Reference Adeli, Hasangholipour and Hossaini43). Fish consumption varies between Middle Eastern countries, where countries such as the United Arab Emirates and Oman have the highest intake of seafood, and Syria and Iraq have the lowest intake of seafood(44). The FAO reported that fish consumption has increased from 1 kg/capita in 1980 to 7·3 kg/capita in 2008 in Iran, however, it is still less than the world average (18·9 kg/capita in 2010)(45). While reports from the FAO show an increase in fish consumption/capita in Iranians after 1980, the current findings show a decline in the trend of fish intake. As with any food groups examined in this study, any discrepancies with the wider literature may be explained by fluctuations in intake observed over a shorter period of time in the present study. Longer durations of follow-up may help determine whether the declining trends observed in this study persist. While fish intake is recommended by the Iranian Dietary Guidelines(Reference Safavi, Omidvar and Djazayery46), a long-term plan and reformed policy that includes nutrition education and public awareness campaigns, as well as strategies to improve the food supply system, may be needed to increase Iranian fish consumption(Reference Adeli, Hasangholipour and Hossaini43,Reference Rimm, Appel and Chiuve47) .

This study has several strengths. The repeated cross-sectional design facilitated the first examination of trends in key food group intake over the last two decades in Iran. The questionnaire used in this study has been used in the STEP survey in other countries, which enables comparison of results from Iran with other populations(22). Furthermore, information on different types of oil was available in this study, enabling investigation of the impact of the Iranian policy to reduce the intake of solid fat. This study also included a large nationally representative sample of Iranian adults from all provinces of Iran, including both urban and rural areas. This enabled the examination of interactions by sociodemographic characteristics, which helped identify the characteristics of group of Iranians with suboptimal dietary intake. Furthermore, findings from this study are somewhat comparable to the Iranian Dietary Guidelines. For example, the Iranian Dietary Guidelines recommend consuming fruits three times every day, however, the results from this study showed that the frequency of consumption of fruits in Iranian adults is 4 d in a week, which is much less than the Iranian Dietary Guidelines.

Several limitations should be acknowledged. Firstly, the use of a brief dietary questionnaire meant that this questionnaire did not provide sufficient details to derive nutrient intakes. Furthermore, the questionnaire collected information on fats and oils via one summary question, which may have limited the understanding of how Iranians use fats for different purposes. Also, participants might have considered butter as a solid fat, resulting in fewer responses for butter. Secondly, the study design was repeated cross-sectional, which meant that different samples of individuals were included at each time point. This prohibited our ability to determine changes in individual intakes over time but allowed for population-level estimates and examination of trends. Thirdly, the questionnaire items used between 2005 and 2016 were not all framed in the same way, which might have introduced measurement differences and impacted the accuracy of the identified trends. Also, the dietary questionnaire has not been validated in this population and the proportion of missing data varied between food groups. Furthermore, the sampling method was different between the years 2005 and 2016, which might have impacted the results between different time points. For example, participants aged 15–64 years old were included between the years 2005 and 2011, while participants over 18 years old (with no upper age limit) were recruited in 2016. Thus, the representativeness of the sample in terms of age is likely to be lower in the previous years, which may also have impacted the examination of differences in terms of age groups. However, this study applied weighted counts to compare the study samples and the Iranian population. Fourthly, since Iran has experienced a nutrition transition, examining the trends in intakes of unfavourable food groups, such as fast food and soft drinks, might reveal additional important aspects of the nutrition transition in Iran, which were not available in this study. Fifthly, it should be considered that the Iranian Dietary Guidelines recommend consuming food groups such as legumes and lean meats and fish, which were not collected in the Iran-WHO STEP and thus not available for analysis in this study. Therefore, future research may benefit from examining the intake of food groups that are specifically recommended in the Iranian Dietary Guidelines. Future research should also quantify intakes to confirm that any trends in the frequency of intake also correspond to trends in amounts consumed. Sixthly, dietary intakes according to different ethnicities were not examined due to lack of data. Given Iran is an ethnically diverse country, providing information on changes in dietary intakes in different ethnicities would be helpful for furthering understanding of associations between diet and health outcomes in the Iranian population. Lastly, it is important to note that a comprehensive sanction has been imposed in Iran over the last two decades. This impacted a variety of financial sectors, including banking networks and oil sectors. Thus, this political climate has influenced the country’s economy. Future research is needed to investigate any possible effects of political and financial changes on Iranian dietary intake(Reference Nakhli, Rafat and Bakhshi Dastjerdi48).

Conclusions

In this large repeated cross-sectional study of Iranian adults, we observed that solid fat use declined over time, while liquid oil and animal fat use increased. Furthermore, the intake of fruits rose slightly over time, particularly in mid-aged and older adults. In contrast, vegetables and fish intake declined, with the strongest declines in older adults. These findings provide supporting evidence for the impact of Iranian food policy approaches for decreasing solid fat use and the need for targeted dietary intervention to increase vegetable and fish intake among Iranian adults. Nonetheless, the fatty acid composition and cooking methods are important considerations when choosing and preparing vegetable oils. Future research is needed to examine trends in unfavourable food groups to understand the full impact of the nutrition transition in Iran.

Acknowledgements

The Non-Communicable Diseases Research Center, Endocrinology and Metabolism Population Sciences Institute, Tehran University of Medical Sciences, is the custodian of the original data set of this study.

Financial support

KML is supported by a National Health and Medical Research Council Emerging Leadership Fellowship (APP1173803). RML was supported by a National Heart Foundation Postdoctoral Research Fellowship (ID102109) and is currently supported by a National Health and Medical Research Council Emerging Leadership Fellowship (APP1175250).

Conflicts of interest

All authors have nothing to disclose.

Authorship

F.F., E.G.H. and S.S.M. designed and carried out the Iran-WHO STEP and provided the data set. S.E., R.M.L., S.A.M. and K.M.L. designed the analysis. SE conducted the statistical analysis and drafted the manuscript. All authors contributed to the critical review of the manuscript and approved the final version of the manuscript.

Ethics of human subject participation

The Iran-WHO STEPS 2005 to 2011 was approved by the Iran Centre for Control of Diseases, and Iran-WHO STEPS 2016 was approved by the National Institute for Medical Research Development. The present analysis was granted an Ethics Exemption by Deakin University (reference number 2019-288).

Supplementary material

For supplementary material accompanying this paper visit https://doi.org/10.1017/S1368980023002203

References

Popkin, BM (2015) Nutrition transition and the global diabetes epidemic. Curr Diab Rep 15, 64.Google Scholar
Popkin, BM, Adair, LS & Ng, SW (2012) Global nutrition transition and the pandemic of obesity in developing countries. Nutr Rev 70, 321.Google Scholar
Popkin, BM & Ng, SW (2022) The nutrition transition to a stage of high obesity and noncommunicable disease prevalence dominated by ultra-processed foods is not inevitable. Obes Rev 23, e13366.Google Scholar
World Health Organization (2021) Regional Strategy on Nutrition 2010–2019 and Plan of Action. Geneva: WHO; available at https://applications.emro.who.int/dsaf/dsa1230.pdf?ua=1 (accessed July 2021).Google Scholar
World Health Organization (2020) Noncommunicable Disease Surveillance in the WHO Eastern Mediterranean Region; available at https://applications.emro.who.int/docs/9789290223139-eng.pdf (accessed July 2021).Google Scholar
Popkin, BM (2015) Nutrition transition and the global diabetes epidemic. Curr Diab Rep 15, 64.CrossRefGoogle ScholarPubMed
Ghassemi, H, Harrison, G & Mohammad, K (2002) An accelerated nutrition transition in Iran. Public Health Nutr 5, 149155.Google Scholar
Rashidvash, V (2013) Iranian people: Iranian ethnic groups. IJHSS 3, 216226.Google Scholar
Naghavi, M, Shahraz, S, Sepanlou, SG et al. (2014) Health transition in Iran toward chronic diseases based on results of global burden of disease 2010. Arch Iran Med 17, 321335.Google Scholar
Golzarand, M, Mirmiran, P, Jessri, M et al. (2012) Dietary trends in the Middle East and North Africa: an ecological study (1961 to 2007). Public Health Nutr 15, 18351844.Google Scholar
Musaiger, AO, Hassan, AS & Obeid, O (2011) The paradox of nutrition-related diseases in the Arab countries: the need for action. Int J Environ Res Public Health 8, 36373671.Google Scholar
World Health Organization & Regional Office for the Eastern Mediterranean (2014) Policy Statement and Recommended Actions for Reducing Fat Intake and Lowering Heart Attack Rates in the Eastern Mediterranean Region. Cairo: World Health Organization, Regional Office for the Eastern Mediterranean.Google Scholar
Salehzadeh, H, Soori, MM, Sadeghi, S et al. (2019) The type and amount of household oil consumption and the influential factors in Sanandaj city, Iran. J Adv Environ Health Res 7, 17.Google Scholar
World Health Organization (2023) Healthy Diet. Geneva: WHO; available at https://www.who.int/news-room/fact-sheets/detail/healthy-diet (accessed July 2023).Google Scholar
Asgary, S, Nazari, B, Sarrafzadegan, N et al. (2009) Fatty acid composition of commercially available Iranian edible oils. J Res Med Sci 14, 211215.Google Scholar
Kousha, A, Etemad, K, Kouhpayezadeh, J et al. (2011) Non–Communicable Diseases Risk Factors Surveillance National Report Selected Results. Geneva: WHO; available at http://www.who.int/ncds/surveillance/steps/Iran_2011_STEPS_Report.pdf (accessed July 2021).Google Scholar
Kimiagar, S, Ghaffarpour, M, Houshiar Rad, A et al. (1998) Food consumption pattern in the Islamic Republic of Iran and its relation to coronary heart disease. EMHJ 4, 539547.Google Scholar
Mirmiran, P, Hosseini-Esfahanil, F, Jessri, M et al. (2011) Does dietary intake by Tehranian adults align with the 2005 dietary guidelines for Americans? Observations from the Tehran lipid and glucose study. J Health Popul Nutr 29, 3952.Google Scholar
Kiadaliri, AA (2013) Demographic and socioeconomic differences in fruit and vegetables consumption, 2007–2009: a province-level study in Iran. Int J Prev Med 4, 831840.Google Scholar
Esteghamati, A, Noshad, S, Nazeri, A et al. (2012) Patterns of fruit and vegetable consumption among Iranian adults: a SuRFNCD-2007 study. Br J Nutr 108, 177181.Google Scholar
Mohammadifard, N, Omidvar, N, Rad, AH et al. (2005) Does fruit and vegetables intake differ in adult females and males in Isfahan? ARYA J 1, 193201.Google Scholar
World Health Organization (2021) STEPwise Approach to NCD Risk Factor Surveillance (STEPS). Geneva: WHO; available at https://www.who.int/teams/noncommunicable-diseases/surveillance/systems-tools/steps (accessed July 2021).Google Scholar
World Health Organization (2021) STEPwise Approach to NCD Risk Factor Surveillance (STEPS), Iran (Islamic Republic of). Geneva: WHO; available at https://www.who.int/teams/noncommunicable-diseases/surveillance/data/iran-(islamic-republic-of) (accessed July 2021).Google Scholar
Esmaillzadeh, A & Azadbakht, L (2008) Major dietary patterns in relation to general obesity and central adiposity among Iranian women. J Nutr 138, 358363.Google Scholar
Ebrahimi, S, Leech, RM, McNaughton, SA et al. (2023) Dietary patterns derived using principal component analysis and associations with sociodemographic characteristics and overweight and obesity: a cross-sectional analysis of Iranian adults. Front Nutr 10, 1091555.Google Scholar
World Health Organization (2023) 2016 STEPS Country Report Iran (Islamic Republic of). Geneva: WHO; available at https://www.who.int/publications/m/item/2016-steps-country-report-iran-islamic-republic-of (accessed July 2023).Google Scholar
Malekzadeh, H, Lotfaliany, M, Ostovar, A et al. (2020) Trends in cardiovascular risk factors in diabetic patients in comparison to general population in Iran: findings from national surveys 2007–2016. Sci Rep 10, 11724.CrossRefGoogle ScholarPubMed
Lachat, C, Hawwash, D, Ocké, MC et al. (2016) Strengthening the reporting of observational studies in epidemiology–nutritional epidemiology (STROBE-nut): an extension of the STROBE statement. Nutr Bull 41, 240251.Google Scholar
Bakhshi, E, Koohpayehzadeh, J, Seifi, B et al. (2015) Obesity and related factors in Iran: the STEPS Survey, 2011. Iran Red Crescent Med J 17, e22479.Google Scholar
Statistical Center of Iran (2021) Population and Housing Censuses. Tehran: Statistical Center of Iran; available at https://amar.org.ir/english/Population-and-Housing-Censuses (accessed May 2021).Google Scholar
Al Jawaldeh, A & Al-Jawaldeh, H (2018) Scaling Up Obesity and NCD Prevention in the Eastern Mediterranean Region through Fat Reduction Intake Strategies at Population Levels. Preprints (accessed July 2021).Google Scholar
World Health Organization (2002) Intercountry Workshop on Oil Fortification: A Simple and Effective Measure to Eradicate Vitamin A and D Deficiency in the Eastern Mediterranean Region. Geneva: WHO; available at https://apps.who.int/iris/bitstream/handle/10665/254948/RD_MESSAGE_19.pdf?sequence=1&isAllowed=y (accessed August 2021).Google Scholar
World Health Organization (2021) Cutting into Trans Fat Consumption in Iran. Geneva: WHO; available at https://www.who.int/news-room/feature-stories/detail/cutting-into-trans-fat-consumption-in-iran (accessed March 2021).Google Scholar
Peymani, P, Joulaei, H, Zamiri, N et al. (2012) Iran’s experience on reduction of trans-fatty acid content in edible oils. Middle East J Sci Res 11, 12071211.Google Scholar
Moslemi, M, Kheirandish, M, Mazaheri, RNF et al. (2020) National food policies in the Islamic Republic of Iran aimed at control and prevention of noncommunicable diseases. East Mediterr Health J 26, 15561564.Google Scholar
Al-Jawaldeh, A, Taktouk, M, Chatila, A et al. (2021) A systematic review of trans fat reduction initiatives in the eastern Mediterranean region. Front Nutr 8, 771492.CrossRefGoogle ScholarPubMed
Kandhro, A, Sherazi, ST, Mahesar, SA et al. (2008) GC-MS quantification of fatty acid profile including trans FA in the locally manufactured margarines of Pakistan. Food Chem 109, 207211.Google Scholar
Dobarganes, C & Márquez-Ruiz, G (2015) Possible adverse effects of frying with vegetable oils. Br J Nutr 2, S49S57.Google Scholar
Barendse, W (2014) Should animal fats be back on the table? A critical review of the human health effects of animal fat. Animal Prod Sci 54, 831855.Google Scholar
Aboul-Enein, BH, Bernstein, J & Neary, AC (2017) Dietary transition and obesity in selected Arabicspeaking countries: a review of the current evidence. East Mediterr Health J 22, 763770.CrossRefGoogle ScholarPubMed
Musaiger, AO (2012) The Food Dome: dietary guidelines for Arab countries. Nutr Hosp 27, 109115.Google ScholarPubMed
Aberoumand, A & Abouali, S (2018) Studies on consumption of fish and seafood and its relation with the health of people in the city of Hendijan, in Iran. J Bioenergy Food Sci 4, 127134.Google Scholar
Adeli, A, Hasangholipour, T, Hossaini, A et al. (2011) Status of fish consumption per capita of Tehran citizens. Iran J Fish Sci 10, 546556.Google Scholar
Food and Agriculture Organization of the United Nations (2023) Markets in the Middle East: Market, Trade and Consumption. Rome: FAO; available at https://www.fao.org/in-action/globefish/market-reports/resource-detail/en/c/338542/#:∼:text=In%20the%20United%20Arab%20Emirates,20.8%20kg%20per%20year%20respectively (accessed August 2023).Google Scholar
Food and Agriculture Organization of the United Nations (2021) Fishery and Aquaculture Country Profiles, the Islamic Republic of Iran. Rome: FAO; available at http://www.fao.org/fishery/facp/IRN/en#CountrySector-PostHarvest (accessed March 2021).Google Scholar
Safavi, SM, Omidvar, N, Djazayery, A et al. (2007) Development of food-based dietary guidelines for Iran: a preliminary report. Ann Nutr Metab 51, Suppl. 2, 3235.Google Scholar
Rimm, EB, Appel, LJ, Chiuve, SE et al. (2018) Seafood long-chain n-3 polyunsaturated fatty acids and cardiovascular disease: a science advisory from the American Heart Association. Circulation 138, e35e47.Google Scholar
Nakhli, SR, Rafat, M, Bakhshi Dastjerdi, R et al. (2021) How do the financial and oil sanctions affect the Iran’s economy: a DSGE framework. J Econ Stud 48, 761785.Google Scholar
Figure 0

Fig. 1 Participants flow diagram from the Iran-WHO STEPS surveys 2005–2016

Figure 1

Table 1 Sociodemographic characteristics in Iranian adults from the Iran-WHO STEPS surveys 2005–2016 (n 225 937)

Figure 2

Table 2 Trends in food group intakes and use of oils in Iranian adults from the Iran-WHO STEPS surveys 2005–2016

Supplementary material: File

Ebrahimi et al. supplementary material 1
Download undefined(File)
File 18 KB
Supplementary material: File

Ebrahimi et al. supplementary material 2
Download undefined(File)
File 44.2 KB