Individual and community level factors associated with use of iodized salt in sub-Saharan Africa: A multilevel analysis of demographic health surveys

Yigizie Yeshaw; Alemneh Mekuriaw Liyew; Achamyeleh Birhanu Teshale; Tesfa Sewunet Alamneh; Misganaw Gebrie Worku; Zemenu Tadesse Tessema; Adugnaw Zeleke Alem; Getayeneh Antehunegn Tesema

doi:10.1371/journal.pone.0251854

Abstract

Introduction

Iodine deficiency disorder a common problem in sub-Saharan Africa (SSA). It affects not only the health of the affected individual but also the economic development of the country. However, to the best of our knowledge, there is a scarcity in literature about the associated factors of iodized salt utilization in sub-Saharan Africa. Therefore, this study aimed to identify both individual and community level determinants of iodized salt utilization in sub-Saharan Africa.

Methods

This study used the appended datasets of the most recent demographic and health survey from 31 sub-Saharan countries. A total weighted sample of 391,463 households was included in the study. Both bivariable and multivariable multilevel logistic regression were done to determine the associated factors of iodized salt utilization in SSA. P value ≤ 0.05 was used to declare statistically significant variables.

Results

Those households with primary (AOR = 1.53, 95% CI = 1.50–1.57), secondary (AOR = 1.81, 95% CI = 1.76–1.86) and higher education level (AOR = 2.28, 95% CI = 2.17–2.40) had higher odds of iodized salt utilization. Households with middle (AOR = 1.05, 95% CI = 1.02–1.08), richer (AOR = 1.13, 95% CI = 1.09–1.17) and richest wealth index (AOR = 1.23, 95% CI = 1.18–1.28) also had an increased chance of using iodized salt. Households from high community media exposure (AOR = 2.07, 95% CI = 1.71–2.51), high community education level (AOR = 3.78, 95% CI = 3.14–4.56), and low community poverty level (AOR = 1.29, CI = 1.07–1.56) had higher odds of using salt containing iodine.

Conclusion

Both individual and community level factors were found to be associated with use of salt containing iodine in sub-Saharan Africa. Education level, media exposure, community poverty level, wealth index, community education, and community media exposure were found to be associated with use of salt containing iodine in SSA. Therefore, to improve the use of iodized salt in the region, there is a need to increase access to media sources and develop the socioeconomic status of the community.

Citation: Yeshaw Y, Liyew AM, Teshale AB, Alamneh TS, Worku MG, Tessema ZT, et al. (2021) Individual and community level factors associated with use of iodized salt in sub-Saharan Africa: A multilevel analysis of demographic health surveys. PLoS ONE 16(5): e0251854. https://doi.org/10.1371/journal.pone.0251854

Editor: Sun Young Lee, Boston University School of Medicine, UNITED STATES

Received: December 9, 2020; Accepted: May 4, 2021; Published: May 17, 2021

Copyright: © 2021 Yeshaw et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: All relevant data are within the manuscript. The full dataset of each country can be obtained from DHS Program at https://dhsprogram.com/data/dataset_admin/login_main.cfm after reasonable request of the program.

Funding: The author(s) received no specific funding for this work.

Competing interests: The authors have declared that no competing interests exist.

Abbreviations: AOR, Adjusted Odds Ratio; CI, Confidence Interval; COR, Crude odds ratio; DHS, Demographic and Health Survey; ICC, Intraclass Correlation Coefficient; IDD, Iodine Deficiency Disorder; MOR, Median Odds Ratio; PCV, Proportional Change in Variance; SSA, Sub Saharan Africa; USI, Universal Salt Iodization

Introduction

Iodine is an essential trace mineral that is needed for the synthesis of thyroid hormones from the thyroid gland that aid in the development, growth and control of metabolic processes [1, 2]. When the intake of iodine is inadequate due to different reasons, the thyroid gland fails to synthesize sufficient amounts of thyroid hormones which in turn lead to the development of iodine deficiency disorders [3]. Iodine deficiency disorder (IDD) is associated with stillbirth, spontaneous abortion, congenital anomalies. perinatal mortality, cretinism, short stature, infant mortality, impaired mental functioning, delayed physical and psychomotor development [4–10]. It also affects quality of life the affected individual and economic productivity [11, 12].

Though the use of iodized salt can prevent iodine deficiency disorder, many parts of the world do not have enough iodine available through their diet and hence, iodine deficiency continues to be an important public health problem globally, making 30% of the world’s population at risk of iodine deficiency disorder [2]. This problem is more pronounced in sub-Saharan Africa [9]. To minimize the impact of IDD, the adoption of universal salt iodization (USI) program is recommend in all countries and there has been major global progress to the elimination of IDDs [13]. For instance, the global prevalence of clinical IDDs fell from 13.1% in 1993 to 3.2% in 2019, and 720 million cases of clinical IDDs have been prevented by USI (a reduction of 75.9%) [14] and the proportion of households consuming iodized salt increased from 70% in 2000 to 88% in 2019 low-income countries [13]. Although this substantial progress has been made over the last several decades towards iodized salt consumption, still it is under the recommendation of the World Health Organization(at least 90% of households should consume iodized salt) [8] and hence, iodine deficiency remains a significant health problem in developing countries [15].

Some previous research works conducted revealed that the use of iodized salt is associated with wealth index [16–19], age [16, 17], education status [16–20], community media exposure [18], knowledge of respondents on IDD and the importance of using iodized salt [20, 21]. Despite the use of iodized salt is a cost-effective universal strategy to combat IDD [22], IDD is still a problem in SSA [23]. However, to the best of our knowledge, there is no study that identifies the individual and community level determinants of iodized salt utilization in SSA. Identifying these factors that are associated with iodized salt utilization will be crucial for policy makers and other concerned bodies to take intervention measures and minimize the burden of IDD in the region.

Methods

Data source

The appended most recent demographic and health survey (DHS) datasets of 31 sub-Saharan countries (conducted from 2010 to 2018) were used for this study. The DHS is a nationally representative survey, collected every five years, to provide population and health indicators at the national and regional levels. A pretested standard Demographic and Health Survey questionnaires were used for data collection of the DHS surveys. The questionnaire was conceptualized to the different countries context and the data were collected by trained data collectors. The datasets of each sub Saharan country were obtained at https://dhsprogram.com/data/dataset_admin/index.cfm. Only those countries with data on iodized salt utilization were included for the analysis. Hence, a total weighted sample of 391,463 households were included in the analysis (Table 1).

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Table 1. List of countries sub-Saharan countries, their demographic and health survey year and sample size included in the analysis.

https://doi.org/10.1371/journal.pone.0251854.t001

Variables of the study

Dependent variable.

Iodized salt utilization was the dependent variable. To ascertain the use of iodized salt, households were asked by the interviewers to bring a salt used for cooking purpose and they tested it using the iodine rapid test kits (RTKs) for presence or absence of iodine. So in this study, we only determined how much percentages of households were using salt that contains iodine irrespective of the amount of iodine content. And hence we dichotomized our dependent variable household iodized salt utilization into yes (households are using salt that has iodine) and no (households were not using salt that has iodine).

Independent variables.

In this study, both individual and community level variables were included. The individual level factors included in this study were marital status, wealth index, education level, age of household head, and media exposure (a composite variable of having radio and television, in which households were said to have media exposure “if they have exposed to either of radio or television” and no “if did not have exposure to all of the above media sources”). The community level variables included in this study were residence, community poverty level (a composite variable generated from wealth index and defined as the proportion of households in the community with low wealth status (lowest and second quantiles), community education level and community media exposure(the proportion of households who had at least one of the medias sources (television or radio) and dichotomized as low(< 50% of households had one of these media sources) and high (≥ 50% of households had one of these media sources) based on median value)). With the exception of residence, the above mentioned community level variables were not directly found in the DHS data and hence they were created by aggregating their corresponding individual level variables at the cluster level. Then after, these generated community level variables were categorized as high and low based on their median value (their value were skewed).

Data analysis procedure. We used STATA 14 software to extract, recode and analyze the data. The data were weighted before doing any statistical analysis to restore the representativeness of the sample and get a reliable estimate and standard error. The procedure of weighting and its rationale is found on the guide of DHS statistics [24].

Due to the correlated nature of DHS data, measures of community variation/random-effects such as Intraclass Correlation Coefficient (ICC), Median Odds Ratio (MOR) and Proportional Change in Variance (PCV) were calculated. Accordingly, the values of these measures were found to be significant, and hence the use of multilevel logistic regression model is more appropriate than using ordinary logistic regression. To choose the best fitted model, first we developed four models and compared them with Deviance. These were: the null-model; a model with no independent variable, model I; a model that have individual-level factors only, model II; a model with community-level factors only and model III; a model that contain both individual and community level independent variables. Of the four models fitted, model III was the best fitted model, had the lowest Deviance.

After selecting the best fitted model, bivariable and multivariable multilevel logistic regression was done to determine the associated factors of iodized salt utilization in SSA. All variables with a p value < 0.25 at bi-variable analysis were entered into the multivariable multilevel logistic regression model. In the final model, we used p value ≤ 0.05 to declare statistically significant variables.

Ethics consideration

We used a secondary analysis of DHS data. Therefore, obtaining ethical approval was not needed. However, we have received a permission letter to download and use the data files from DHS Program.

Results

Individual and community level characteristics of study participants

A total weighted samples of 391,463 households were included in this study. Of these, majority, 248,265 (63.42%) and 292,145 (74.63%) of them were living rural area and currently married, respectively. Regarding educational level, 133,352(34.06%) of the participants had not received formal education. Most of the study participants, 241,677(71. 74%) had media exposure. More than half of the study participants were from high community education (50.82%), and high community media exposure (51.14%) (Table 2).

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Table 2. Socio demographic characteristics of respondents.

https://doi.org/10.1371/journal.pone.0251854.t002

Random effect analysis

According to the result of the random-effects model, there is significant clustering of iodized salt utilization across the communities (OR of community level variance = 2.75, 95% CI = 2.43–3.11). The value of ICC in the null model revealed that 45.49% of the overall variation of iodized salt utilization was attributed to cluster variability. The 4.83 MOR value of the null model also indicates the presence of variation in iodized salt utilization between clusters. It means if we randomly select households from different clusters, those households at the cluster with higher household iodized salt utilization had 4.83 times higher chance of using iodized salt use compared to their counterparts.

As you can see in the Table 3 below, the PCV increases from 12.64% (model I) to 31.97% (model III), indicating that model III best explains the variability of iodized salt utilization. Moreover, model III has the lowest Deviance value. Hence, it was selected as best fitted model (Table 3).

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Table 3. Model comparison and random effect analysis result.

https://doi.org/10.1371/journal.pone.0251854.t003

Associated factors of iodized salt utilization in sub-Saharan Africa.

To identify associated factors of iodized salt utilization, both bivariable and multivariable multilevel logistic regression analyses were performed. Accordingly, on bivariable analysis, education level, marital status, media exposure, community media exposure, wealth index, community poverty and community education level were associated with iodized salt use in SSA (p < 0.25). In the final model, community poverty level, wealth index, community education, education level, and community media exposure were found to be significantly associated with iodized salt utilization (p ≤ 0.05).

Households who were from high community media exposure had 2.1 times higher odds of iodized salt utilization compared to those households of low community media exposure (AOR = 2.07, 95% CI = 1.71–2.51). Household heads with primary, secondary and higher education level had 1.5 (AOR = 1.53, 95% CI = 1.50–1.57), 1.8 (AOR = 1.81, 95% CI = 1.76–1.86) and 2.3 (AOR = 2.28, 95% CI = 2.17–2.40) times higher chance of using iodized salt compared to those with no education. Those households from high community education level had 3.8(AOR = 3.78, 95% CI = 3.14–4.56) times higher chance of iodized salt utilization compared to those households came from low community education level. Household with middle, richer and richest wealth status had 1.05 (AOR = 1.05, 95% CI = 1.02–1.08), 1.1 (AOR = 1.13, 95% CI = 1.09–1.17) and 1.2 (AOR = 1.23, 95% CI = 1.18–1.28) times higher odds of iodized salt utilization compared to households with poorest wealth index. Those households from low community poverty level had 1.3 (AOR = 1.29, CI = 1.07–1.56) times higher odds of using salt containing iodine compared to their counterparts (Table 4).

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Table 4. Multilevel logistic regression analysis of use of salt containing iodine in SSA, 2020.

https://doi.org/10.1371/journal.pone.0251854.t004

Discussion

Though salt iodization is the preferred affordable strategy for prevention of iodine deficiency disorders [25], iodine deficiency disorders still continue to be a serious public health problem in low income countries [23, 26]. Therefore, this study was conducted to identify the associated factors of iodized salt utilization in SSA. This study found that education level, media exposure, residence, community poverty level, wealth index, community education, and community media exposure were associated with iodized salt utilization in SSA.

Similar to a study done in Ethiopia [18], in this study, those households from high community media exposure had an increased chance of using iodized salt compared to their counterparts. This is because media exposure is one effective way of increasing people’s level of awareness and use of iodized salt [27, 28]. This finding highlighted that the need to continual and effective use of media to improve the utilization of iodized salt in the region.

Another factor which is significantly associated with use of iodized salt is level of education. Those household with primary, secondary and higher education level had higher odds of using iodized salt compared to uneducated once. Similarly, households from high community education level had higher chance of using iodized salt compared to those households came from low community education level. The finding of this study is consistent with other studies conducted elsewhere [16–19]. This higher chance of using iodized salt among educated participants might be due an increased knowledge and awareness about the importance of using iodized salt [27, 29].

Consistent with previous studies conducted in low income countries [16–19, 30], in this study, wealth index is associated with use of iodized salt. Those households with middle, richer and richest wealth status had an increased chance of iodized salt utilization compared to households with poorest wealth status. Moreover, households who were from low community poverty level had higher odds of using iodized salt compared to their counterparts. This is because households’ access to use iodized salt is commonly dependent on awareness, availability and price [31]. Households with high economic status can afford to purchase salt from appropriate sources which contains iodine compared to poor households [32, 33].

This study has two major strengths. The first one is the use of very huge and representative datasets of 31 sub-Saharan countries, which are collected by well-trained data collectors using standard and validated questioner that makes the finding of this study to be generalizable for the region. The second strength of this study is the use of multilevel modeling, a model that accounts the nested/hierarchical nature the demographic and health survey to get reliable estimates. However, our study is not free from limitations. This study uses rapid test kits (RTKs) to identify weather the households are using salt that contains any levels of iodine or not. Therefore, we are unable to quantify the amount of iodine in the salt and hence, we failed to categorize the use of iodized salt as adequate or inadequate. Due to the secondary nature of the study, we are also unable to assess knowledge of individuals and some food sources of iodine with the use of iodized salt.

Conclusion

Both individual and community level factors were found to be associated with use of salt containing iodine in sub-Saharan Africa. Education level, media exposure, community poverty level, wealth index, community education, and community media exposure were found to be associated with use of salt containing iodine in SSA. Therefore, to improve the use of iodized salt in the region, there is a need to increase access to media sources and develop the socioeconomic status of the community.

Acknowledgments

We authors would like to thank the MEAUSRE DHS Program for giving the permission to access and use the dataset for the study.

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Figures

Abstract

Introduction

Methods

Results

Conclusion

Introduction

Methods

Data source

Variables of the study

Dependent variable.

Independent variables.

Ethics consideration

Results

Individual and community level characteristics of study participants

Random effect analysis

Associated factors of iodized salt utilization in sub-Saharan Africa.

Discussion

Conclusion

Acknowledgments

References