This article has Open Peer Review reports available.
Coverage, compliance and factors associated with utilization of iron supplementation during pregnancy in eight rural districts of Ethiopia: a cross-sectional study
© Gebremedhin et al.; licensee BioMed Central Ltd. 2014
Received: 12 December 2013
Accepted: 9 June 2014
Published: 14 June 2014
Despite the efforts to reduce iron deficiency during pregnancy, information on the coverage and factors associated with utilization of iron supplements is lacking. The study is intended to assess the coverage, compliance and factors associated with the use of prenatal iron supplements in eight rural districts of Ethiopia.
The study comprised two independent surveys conducted among pregnant women (n = 414) and women who gave birth in the preceding year of the survey (n = 1573). In both cases, respondents were selected using multistage sampling technique and data were collected via structured questionnaire. Predictors of iron supplement utilization (ranked categories of number of prenatal supplements taken) were identified using ordinal logistic regression. The outputs of the analysis are given using adjusted Odds Ratio (OR) with 95% Confidence Interval (CI).
Among women who gave birth in the preceding year, 35.4% (95% CI: 31.3-39.5) were given/prescribed prenatal iron supplement during the index pregnancy and only 3.5% were supplemented for the recommended 91 or more days. Compared to women who had 4 or more ANC visits, those with 0, 1, 2 and 3 visits had 0.04, 0.33, 0.50 and 0.60 times less odds of iron supplement utilization, respectively. Women lacking comprehensive knowledge of anemia (OR = 0. 75 (95% CI: 0.57-0.97)) and those who weren’t informed about the importance of iron supplementation during the pregnancy (OR = 0. 05 (95% CI: 0.04-0.07)) had significantly lower utilization. On the other hand, in pregnant women the prevalence of anemia was 33.2%. Among pregnant women who were given/prescribed supplements, the average level of compliance was 74.9% and about 25.1% had less than 70% adherence. The leading reported reasons for non-adherence were side-effects (63.3%) and forgetfulness (16.7%).
Promoting early and frequent ANC, enhancing the quality of ANC counseling and promoting the knowledge of women on anemia are essential strategies for improving the utilization of iron supplements.
Anemia is a global public health problem affecting two billion people worldwide . Particularly pregnant women and preschool-age children take its disproportionate burden. Globally, almost half of all preschool children (47.4%) and pregnant women (41.8%) and close to one-third of non-pregnant women (30.2%) are anemic [1, 2]. Though anemia has multifaceted causes, half of its burden is attributed to Iron Deficiency (ID) .
Several studies documented the consequences of maternal anemia including increased risk of maternal death, low birth weight and preterm birth . According to the World Health Organization (WHO), 3.7% of maternal mortality in Africa is directly attributed to anemia . Besides ID is an underlying cause for 22% of maternal deaths worldwide . A meta-analysis indicated that the risk of maternal death can be reduced by 20% for each 1 g/dl increase in population mean hemoglobin level .
In Ethiopia many studies witnessed the public health significance of maternal anemia [6–10]. Accordingly, in confirmation of the WHO recommendation , the national guideline for control and prevention of micronutrient deficiencies highlights the need of daily iron supplementation for at least 6 months during pregnancy and 3 months postpartum . The National Nutrition Strategy (NNS) also set a key target of increasing the proportion of mothers who get iron supplementation for more than 90 days during pregnancy and the postpartum period to 50% by 2015 .
According to Ethiopia Demographic Health Survey (EDHS) 2011, the coverage of iron supplementation is disappointingly low as only 17.3% of women took the supplement during their recent pregnancy in the preceding 5 years and only 0.4% were supplemented for 90 or more days . Despite the assumption that iron supplementation is an integral part of Antenatal Care (ANC), only 37% of women who had ANC received iron supplements .
Thus the purpose of the current study is to assess the coverage, compliance and factors associated with utilization of iron supplementation during pregnancy in eight selected rural districts of Ethiopia. The study also appraised prevalence of anemia during pregnancy and the association between duration of iron supplementation and maternal hemoglobin concentration. The study is focused on iron supplementation – rather than iron-folate supplementation – as the availability of the latter was limited throughout the health institutions of the districts in the reference period of the study.
The study was conducted from February to March 2012 in eight rural woredas of the four major regions of Ethiopia (Tigray, Amhara, Oromya and Southern Nations Nationalities and Peoples (SNNP) regions). A woreda –hereafter referred to as district – is an administrative division typically composed of 20–40 kebeles. Kebele is the smallest administrative unit with an average population of 5000. The districts included in the study were: Almata and Enderta from Tigray region, Menze Mama and Menze Gera from Amhara region, Ada Berga and Meta Robi from Oromya region, Sankura and Meskan from SNNP region. The districs were selected from their respective regions due to their relative accessability to the center of the country. In Ethiopia prenatal iron supplementation is the integral part of ANC and its provided free of charge; nevertheless, the program suffers from supply and logistic challenges.
The study embraced two distinct community based surveys carried out simultaneously in the eight districts. The first survey – conducted among women who gave birth in the preceding one year – was designed to assess the level and factors associated with the utilization of iron supplements during pregnancy. The other survey – conducted among pregnant women – was intended to appraise pregnant women’s compliance with iron supplementation and its association with hemoglobin concentration.
The sample size for the study conducted among non-pregnant women was calculated as 1573 using single proportion formula. The inputs of the computation were: 95% confidence level, 2% margin of error, expected iron supplementation coverage of 17% , design effect of 1.5 and non-response rate of 10%. Further, based on the power calculation formula  designed for ordinal logistic regression analysis, the available sample size is judged to be optimal for identifying the factors associated with utilization of iron supplementation with 95% confidence level and 90% power and small effect size (Odds Ratio (OR) of 1.5) to be detected.
The sample size for the survey among pregnant women was computed as 445 using single mean formula. The computation was made with 95% confidence level, 0.20 Standard Deviation (SD) for mean adherence , 0.05 margin of error, design effect of 1.5 and 10% non-response rate. Further, corrections were made for finite population size and expected coverage of iron supplementation. In both of the surveys, the sample sizes were equally distributed to the eight districts and the 24 kebeles included in the study.
In both of the surveys multistage sampling technique was applied to select the study participants. Initially from each district 3 rural kebeles were selected using simple random sampling technique. The sampling frames for the secondary sampling units (pregnant women and women who gave birth in the preceding 12 months) were developed by mobilizing local Community Health Promoters (CHPs) working at sub-kebele level. Ultimately, participants were selected using simple random sampling technique.
Data collection method
In the surveys, information was gathered using pre-tested structured questionnaires. The tools were finalized in Amharic and administered in the local languages. The data were gathered by 24 trained female data collectors. For the non-pregnant women, interviews were made at home; however, the pregnant women were invited to the nearby health posts so that blood samples can easily be collected. Nearly the entire (93%) pregnant women invited to the health post took part in the study.
In order to assess the knowledge of pregnant women on anemia, different local names of anemia in the five local languages spoken in the study districts were used. The local names were identified ahead through conducting group discussions with local mothers and in-depth interviews with Health Extension Workers (HEWs) in each of the eight districts.
Among pregnant women, hemoglobin concentration was determined using a drop of capillary blood via HemoCue Hb 301 following standard procedures. Hemoglobin values were adjusted for altitude according to the standard of the Centers for Disease Prevention and Control (CDC) . Based on hemoglobin concentration, anemia status was classified as normal, mild, moderate and severe using trimester specific cutoff points.
Data management and analyses
The data were entered into SPSS 20.0 and exported to STATA/SE 11.0 for analysis. Considering the complex sampling technique used in the study, descriptive analyses were made using the survey (svy) command after specifying the appropriate sampling design, probability weights and sampling fractions.
Wealth index was computed as a composite indicator of living standard using Principal Component Analysis (PCA). The data reduction was made based on 25 input variables related to ownership of selected household assets, size of agricultural land, quantity of livestock and materials used for housing construction. Ultimately, a principal component was generated and it was divided into 5 equal wealth quintiles (poorest, poorer, middle, richer, and richest).
Factors associated with the utilization of iron supplementation were identified using ordinal logistic regression. The response variable (duration of iron supplementation) was categorized into five ranks: no supplementation, 1–30, 31–60, 61–90 and more than 90 days of supplementation. Categorical ranks, rather than actual days of supplementation, were preferred as the latter is more liable to recall errors.
For the logistic model, eleven independent variables were selected based on review of relevant literatures. The variables were: household wealth index, maternal literacy, husband’s literacy, birth order, maternal age, distance from the nearest health facility, frequency of ANC, receiving information about the importance of iron supplementation during the pregnancy, comprehensive knowledge of anemia, previous experience of life threatening pregnancy complication and whether the pregnancy was wanted or not.
At the outset, the association of every independent variable with the response variable was evaluated using bivariate analysis. Subsequently, statistically significant variables (P < 0.05) were considered in the multivariate model. The major assumption of ordinal logistic regression – homogeneity of OR – was checked using the test of parallel lines. The fitness of the mode was assessed via Pearson and Deviance chi-square tests. The association between duration of iron supplementation and hemoglobin concentration was evaluated using linear regression analysis.
The study was conducted in confirmation of ethical guidelines for research involving human subjects. Ethical clearance was obtained from the scientific and ethical review office of Ethiopian Public Health Institute (EPHI). The data were collected after taking informed verbal consent form the study participants. All pregnant women who were not on ANC were linked with the health post so that they can start the service. The transportation costs of the pregnant women who traveled to the nearby health posts for the study were covered by the project.
Survey among women who gave birth in the last 12 months
Socio-demographic characteristics of the study participants, eight selected rural districts of Ethiopia, March 2012
Maternal age in years (n = 1559)
Children ever born (n = 1552)
Educational status (n = 1563)
Can't read or write
Secondary or tertiary education
Marital status (n = 1561)
Occupation (n = 1563)
Awareness about maternal anemia
Near to three-fourth (72.0%) of the respondents had ever heard of anemia. About 67.9% and 57.6% managed to tell at least one of the major symptoms and causes of anemia, respectively. Failure to take iron supplements during pregnancy and inadequate dietary iron intake were recognized as causes by 42.3% and 25.9% of the respondents. Two-third (62.5%) mentioned at least one of the consequences of maternal anemia. Increased risks of maternal death (42.1%), serious maternal illness (40.5%) and fetal death (16.2%) were the frequently mentioned ones.
Comprehensive knowledge of anemia was measured using a composite index constructed based on multiple indicators. Respondents who were aware of anemia and know at least one of its major causes, symptoms and consequences during pregnancy were considered to have comprehensive knowledge. Nearly half (51.4%) of the respondents had comprehensive knowledge of anemia.
About 38.4% claimed that during the recent pregnancy, they had been informed about the significance of iron supplementation. The principal sources of information were HEWs (19.9%) and health professionals (19.8%). Family/neighbors (2.1%) and CHPs (1.5%) were seldom mentioned. Very few of the respondents were aware that the supplement has to be taken on a daily basis (37.1%) and it should be taken throughout the pregnancy (13.0%).
Coverage of iron supplementation during pregnancy
About 35.4% (95% CI: 31.3-39.5) of the women were given/prescribed iron supplements during the pregnancy they had in the last 12 months. Amongst women who had at least one ANC visit, less than half (46.8%) received iron supplements. Proportions who were given/prescribed iron among those who had 1, 2, 3 and 4 or more ANC visits were 35.5, 39.8, 49.3 and 59.2%, respectively.
Factors affecting utilization of prenatal iron supplementation
As discussed in the methods section, the level of iron supplementation utilization was subdivided into five ordinal categories and modeled using ordinal logistic regression. Eleven factors were considered as explanatory variables. In the univariate analysis, maternal age and birth order were not significant predictors thus the multivariate model was built on the remaining nine variables. Ultimately, maternal literacy, wealth index, frequency of ANC, comprehensive knowledge of anemia and receiving information about the importance of iron supplementation during pregnancy were the significant predictors.
Factors associated with utilization of iron supplementation during pregnancy, eight selected rural districts of Ethiopia, March 2012
Maternal age in years
Household wealth index
5 or more
Two-way distance from the nearest health facility
Less than 30 minutes
30 minutes to one hour
More than one hour
Frequency of ANC visits during pregnancy
4 or more
Experience of serious pregnancy complication before
Comprehensive knowledge of anemia
Information about importance iron supplementation during the pregnancy
Survey among currently pregnant women
Prevalence of anemia in pregnancy
Association between iron supplementation and hemoglobin
Compliance to prenatal iron supplementation
Level of compliance with iron supplementation in the preceding 15 days of the survey, selected eight rural districts of Ethiopia, March 2012
Number of iron supplements taken in the preceding 15 days
Corresponding level of compliance
According to EDHS 2011, only 17.3% of women took iron supplements during the recent pregnancy they had within 5 years . However, our study reported relatively higher level of utilization (34.7%) probably due to the reason that it was conducted in comparatively accessible districts of the four better off regions of the country. Furthermore, the longer reference period used in the DHS might have made it less sensitive to the very recent national level interventions targeted to move up iron supplementation coverage.
The NNS of Ethiopia envisages increasing the proportion of mothers who get iron supplementation for more than 90 days during pregnancy and the postpartum period to 50% . Yet in the study districts, only 3.5% of the women had such level of utilization during pregnancy and the practice was non-existent in the postpartum period. Besides, most women started the supplement in the late second or third trimester. Taking into account the relative accessibility of the study districts, a gloomier national level figure can be anticipated. This can be taken as strong evidence that extraordinary interventions are needed to materialize the target.
Existing studies applied assorted criteria to define compliance with iron supplementation; hence, comparison among them is not viable. Nonetheless, the reported level of compliance (75%) might have been overestimated as it is measured based on the self-reporting method. A reasonable number of studies witnessed that self-reporting overestimates compliance as compared with pill count or biochemical method. According to a study in Indonesia , in 43% of the pregnant women who have claimed to have taken all iron tablets, the same can’t be confirmed using stool tests. Studies in Egypt  and Philippines  also found significantly higher level of compliance as compared with the pill count method.
ANC is the vital route for delivery of iron supplementation and reinforcement of adherence. Consequently, the association observed between the frequency of ANC and level of iron utilization is an expected one. Several studies have also documented the same [18–20]. In contrast, we found nearly half of the women who had ANC were not given iron supplements. This can be due to shortage of iron supply and lack of effective logistic system to distribute the supply. A study in Tanzania also reported, among women who had 2 or more ANC visits, the coverage of iron supplementation was only 15 to 21% .
Several studies found better iron supplement utilization among socio-economically empowered women [19, 21–23]. Yet in the current study the opposite is reported. The unexpected finding can be due to a couple of reasons. The well-off mothers might consider themselves less susceptible to anemia as a result they might have poor compliance. Or the expected higher prevalence of anemia among economically disadvantaged women might have compelled them to adhere better. According to a study in Saudi Arabia, 10% of the women with low compliance miss the supplements believing that they had adequate diet .
WHO had recommended a criterion to evaluate the public health significance of anemia based on its prevalence in pregnant women . The prevalence reported in the current study (33%) falls within the category of 20-40% indicative of moderate public health significance. Other large scale surveys in Ethiopia concluded the same. The recent two DHS surveys conducted in 2011  and 2005  and another large-scale survey carried out in 2005  reported 22%, 27% and 31% prevalences among pregnant women, respectively.
Limited proportion of the women (51.4%) had comprehensive knowledge of anemia and only 38.4% were informed about the significance of iron supplementation during the pregnancy. However, both of the variables turned out to be strong predictors of iron supplement utilization. The finding indicates that enhancing the awareness of mothers can substantially improve the utilization of iron supplementation. Previous studies conducted in Cambodia  and Sweden  also came up with parallel findings.
Side-effect is frequently considered as a major obstacle to compliance. According to studies in Saudi Arabia , Senegal  and India , it was reported as a reason for missing doses by 40.2%, 27.0% and 25.4% of the pregnant women with low adherence, respectively. Studies conducted in Philippines , Bangladesh  and Vietnam  also concluded likewise. In the current study, a relatively higher proportion of women with low compliance (63.3%) reported side-effect as the reason for non-adherence. One possible explanation for the elevated figure can be the fact that nearly all (94%) of the pregnant women were not informed about potential side-effects of iron supplements in advance. Appropriate orientation is known to raise psychological tolerance to side-effects .
The study is the first attempt in Ethiopia to understand factors influencing the utilization of prenatal iron supplement. The study sampled respondents from eight districts across the four major regions of the country and included reasonably large sample size. Besides, it complemented two different surveys. However, the following limitations need to be considered while interpreting the findings of the study. Recall error regarding the number of supplements taken in the prior year is possible and it might have affected the precision of the study. Further, as relatively accessible districts are selected, selection bias is likely and the supplementation coverage might have been over estimated; consequently, the findings cannot be generalized beyond the study districts. In addition, pregnant women in the first trimester were largely under represented (1.5%) due to various reasons (the study only used presumptive symptoms of pregnancy to recruit the study subjects and there is common culture of not revealing pregnancy status in public until it becomes obvious). This might have overestimated the prevalence of anemia and utilization of iron supplements.
The coverage of prenatal iron supplementation is unsatisfactory as only 35.4% of the women who gave birth in the preceding year were given/prescribed iron tablets. Factors adversely associated with the utilization of the supplements were having no or too few ANC visits, lack of comprehensive knowledge of anemia and unable to get advice about the importance of the supplement during the pregnancy. Of pregnant women on iron supplementation, the average level of compliance was 74.9%. Amongst women with low adherence, the leading underlying reasons were side-effects and forgetfulness.
Promoting the benefits of early and frequent ANC, enhancing the quality of ANC counseling including guidance on management of side-effects; and promoting the knowledge of women on anemia are essential elements for improving the utilization of the service. Local CHPs should also be strongly involved in the promotion of prenatal iron supplementation.
SG: Assistant professor of public health, Hawassa University, Ethiopia.
AS: Associate researcher of food science and nutrition, EPHI, Ethiopia.
GM: Senior program officer of maternal neonatal health and nutrition, Micronutrient Initiative (MI), Ethiopia.
TM: Assistant researcher of food Science and nutrition, EPHI, Ethiopia.
TA: Associate researcher of food Science and nutrition, EPHI, Ethiopia.
The authors acknowledge Micronutrient Initiative (MI) and World Bank for funding the study and EPHI for arranging logistics for the study.
- Worldwide prevalence of anemia 1993–2005: WHO global database on anemia. Edited by: Benoist B De, McLean E, Egli I, Cogswell M. 2008, Geneva: WHO, CDCGoogle Scholar
- Badham J, Zimmermann MB, Kraemer K: (Ed): The guidebook nutritional anemia. 2007, Basel: Sight and LifeGoogle Scholar
- Allen LH: Anemia and iron deficiency: effects on pregnancy outcome. Am J Clin Nutr. 2000, 71 (suppl): 1280-1284.Google Scholar
- Khan KS, Wojdyla D, Say L, Gülmezoglu AM, Van Look P: WHO analysis of causes of maternal death: a systematic review. Lancet. 2006, 367: 1066-1074. 10.1016/S0140-6736(06)68397-9.View ArticlePubMedGoogle Scholar
- Stoltzfus RJ, Mullany L, Black RE: Iron deficiency anemia. comparative quantification of health risks. Edited by: Ezzati M, Lopez AD, Rodgers A, Murray C. 2004, Geneva: WHO Press, Volume 1: 163-209.Google Scholar
- Central Statistical Agency of Ethiopia, Measure DHS: Ethiopia demographic and health survey 2011. 2011, Addis Ababa and Calverton: CSA Ethiopia and MEASURE DHS-ICF MacroGoogle Scholar
- ORC Macro, Central Statistical Agency of Ethiopia: Ethiopia demographic and health survey 2005. 2006, Central Statistical Agency and ORC Macro: Addis Ababa and CalvertonGoogle Scholar
- Haidar J, Pobocik R: Iron deficiency anemia is not a rare problem among women of reproductive ages in Ethiopia: a community based cross-sectional study. BMC Blood Disord. 2009, 9: 7-10.1186/1471-2326-9-7. doi:10.1186/1471-2326-9-7PubMedPubMed CentralGoogle Scholar
- Haidar J: Prevalence of anemia, deficiencies of iron and folic acid and their determinants in Ethiopian women. J Health Popul Nutr. 2010, 28 (4): 359-368.View ArticlePubMedPubMed CentralGoogle Scholar
- Haidar J, Nekatibeb H, Urga K: Iron deficiency anemia in pregnant and lactating mothers in rural Ethiopia. East Afr Med J. 1999, 76 (11): 618-622.PubMedGoogle Scholar
- WHO: Weekly iron–folic acid supplementation (WIFS) in women of reproductive age: its role in promoting optimal maternal and child health. Position statement. 2009, Geneva: WHO PressGoogle Scholar
- Federal Ministry of Health (FMOH) of Ethiopia: National guideline for control and prevention of micronutrient deficiencies. 2004, Addis Ababa: FMOHGoogle Scholar
- International Food Policy Research Institute: Framework document for a national nutrition strategy for Ethiopia. 2005, Addis Ababa: IFPRIGoogle Scholar
- Campbell MJ, Julious SA, Altman DG: Estimating sample sizes for binary, ordered categorical and continuous outcomes in two group comparisons. BMJ. 1995, 311: 1145-1148. 10.1136/bmj.311.7013.1145.View ArticlePubMedPubMed CentralGoogle Scholar
- Lutsey PL, Dawe D, Villate E, Valencia S, Lopez O: Iron supplementation compliance among pregnant women in Bicol, Philippines. Public Health Nutr. 2007, 11 (1): 76-82. doi:10.1017/S1368980007000237PubMedGoogle Scholar
- The International Nutritional Anemia Consultative Group: Adjusting hemoglobin values in program surveys. [http://pdf.usaid.gov/pdf_docs/PNACQ927.pdf]
- Schultink W, Van der Ree M, Matulessi P, Gross R: Low compliance with an iron-supplementation program: a study among pregnant women in Jakarta, Indonesia. Am J Clin Nutr. 1993, 57: 135-139.PubMedGoogle Scholar
- Ibrahim ZM, El-hamid SA, Mikhail H, Khattab MS: Assessment of adherence to iron and folic acid Ssupplementation and prevalence of anemia in pregnant women. Med J Cairo Univ. 2011, 79 (2): 115-121.Google Scholar
- Ogundipe O, Hoyo1 C, Ostbye T, Oneko O, Manongi R, Lie RT, Daltveit AK: Iron supplementation among 21,889 pregnant women in Northern Tanzania: a cross-sectional hospital-based study. BMC Public Health. 2012, 12: 481-10.1186/1471-2458-12-481.View ArticlePubMedPubMed CentralGoogle Scholar
- Lacerte P, Pradipasen M, Temcharoen P, Imamee N, Vorapongsathorn T: Determinants of adherence to Iron/Folate supplementation during pregnancy in two provinces in Cambodia. Asia Pac J Public Health. 2011, 23 (3): 315-323. 10.1177/1010539511403133.View ArticlePubMedGoogle Scholar
- Knudsen VK, Hansen HS, Ovesen L, Mikkelsen TB, Olsen SF: Iron supplement use among Danish pregnant women. Public Health Nutr. 2007, 10 (10): 1104-1110. doi:10.1017/S136898000769956XView ArticlePubMedGoogle Scholar
- Habib F, Alabdin EH, Alenazy M, Nooh R: Compliance to iron supplementation during pregnancy. J Obstet Gynecol. 2009, 29 (6): 487-492. 10.1080/01443610902984961.View ArticleGoogle Scholar
- Jasti S, Siega-Riz AM, Cogswell ME, Hartzema AG, Bentley ME: Pill count adherence to prenatal multivitamin/mineral supplement use among low-income women. J Nutr. 2005, 135: 1093-1101.PubMedGoogle Scholar
- World Health Organization (WHO: Iron deficiency anemia: assessment, prevention, and control. 2001, Geneva: WHO pressGoogle Scholar
- Wulff M, Ekstrom E: Iron supplementation during pregnancy in Sweden: to what extent is the national recommendation followed?. Acta Obstet Gynecol Scand. 2003, 82 (7): 628-635. 10.1034/j.1600-0412.2003.00186.x.View ArticlePubMedGoogle Scholar
- Seck BC, Jackson RT: Determinants of compliance with iron supplementation among pregnant women in Senegal. Public Health Nutr. 2007, 11 (6): 596-605. doi:10.1017/S1368980007000924PubMedGoogle Scholar
- Bilimale A, Anjum J, Sangolli HN, Mallapur M, Nehru J: Improving adherence to oral iron supplementation during pregnancy. AMJ. 2010, 3 (5): 281-290.View ArticleGoogle Scholar
- Hyder SMZ, Persson L, Chowdhury AMR, Ekstrom EC: Do side-effects reduce compliance to iron supplementation? A study of daily- and weekly- dose regimens in pregnancy. J Health Popul Nutr. 2002, 20 (2): 175-179.PubMedGoogle Scholar
- Aikawal R, Jimba M, Nguen KC, Zhao Y, Binns CW, Lee MK: Why do adult women in Vietnam take iron tablets?. BMC Public Health. 2006, 6: 144-10.1186/1471-2458-6-144. doi:10.1186/1471-2458-6-144View ArticleGoogle Scholar
- Galloway R, Mcguire J: Determinants of compliance with iron supplementation: Supplies, side-effects or psychology?. Soc Sci Med. 1994, 39 (3): 381-390. 10.1016/0277-9536(94)90135-X.View ArticlePubMedGoogle Scholar
- The pre-publication history for this paper can be accessed here:http://0-www.biomedcentral.com.brum.beds.ac.uk/1471-2458/14/607/prepub
This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly credited. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.