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Effectiveness of a redesigned iron supplementation delivery system for pregnant women in Negros Occidental, Philippines

Published online by Cambridge University Press:  01 July 2009

Maria Grace D Risonar*
Affiliation:
Nutrition Center of the Philippines, Social Science Research Division, Villamor Interchange, South Superhighway, Western Bicutan, Taguig City 1630, Philippines
Pura Rayco-Solon
Affiliation:
Nutrition Center of the Philippines, Social Science Research Division, Villamor Interchange, South Superhighway, Western Bicutan, Taguig City 1630, Philippines
Lorena W Tengco
Affiliation:
Nutrition Center of the Philippines, Social Science Research Division, Villamor Interchange, South Superhighway, Western Bicutan, Taguig City 1630, Philippines
Jesus N Sarol Jr
Affiliation:
College of Public Health, University of the Philippines, Manila, Philippines
Lourdes S Paulino
Affiliation:
National Center for Disease Prevention and Control, Department of Health, Manila, Philippines
Florentino S Solon
Affiliation:
Nutrition Center of the Philippines, Social Science Research Division, Villamor Interchange, South Superhighway, Western Bicutan, Taguig City 1630, Philippines
*
*Corresponding author: Email [email protected]
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Abstract

Objective

To determine the effectiveness of a redesigned Fe supplementation delivery system (ISDS) in improving Hb concentrations and compliance among pregnant women.

Design

A controlled before and after study design was used. Interviews and Hb measurements of randomly selected pregnant women in both treatment areas were conducted at baseline and after 6 months. The redesigned ISDS, reached by consensus based on the surveys and focus group discussions, involved the health workers in spot mapping and clustering; Fe tablets’ distribution, monitoring and promotion; and counselling of pregnant women.

Setting

Negros Occidental and Negros Oriental, Philippines.

Subjects

In total, 1180 pregnant women given Fe/folic acid tablets daily through the redesigned ISDS in the experimental areas and the existing ISDS in the control areas.

Results

There were significantly more anaemic pregnant women in the experimental than in the control area at baseline (50·7 v. 37·3 %; P = 0·001). However, at endline, the anaemia prevalence rate in the experimental area was comparable to that of the control (35·6 v. 33·1 %; P = 0·530). Also, the mean Hb concentration increased significantly in the experimental area by 0·5 g/dl (P = 0·002). An increase in the actual number of prenatal visits/trimester in the experimental area was observed (from 0·99 to 1·66; P < 0·0001). Pregnant women in the experimental area were four times more likely to take Fe tablets (OR = 3·79; P < 0·001) and sixteen times more likely to being monitored for Fe intake (OR = 16·86; P < 0·001) compared to the control.

Conclusions

The redesigned ISDS was effective in improving the Hb concentration and health-related behaviour of pregnant women.

Type
Research Paper
Copyright
Copyright © The Authors 2008

Globally, Fe deficiency and anaemia remain major public health problems. The global prevalence of anaemia among pregnant women is 41·8 %, more prevalent in the developing regions of Africa (55·8 %) and Asia (41·6 %)(Reference McLean, Cogswell, Egli, Wojdyla and de Benoist1). In the Philippines, anaemia prevalence among pregnant women remains high as shown in the National Nutrition Surveys in 1993 (43·6 %), 1998 (50·7 %) and 2003 (43·9 %)(24). The risk of developing Fe deficiency anaemia (IDA) is highest during pregnancy because the amount of dietary Fe absorbed cannot meet the increased demand for Fe. During pregnancy, Fe requirements increase by the second trimester, and by up to 5–6 mg per day during the last trimester(Reference Casanueva and Viteri5). A varied array of interventions that include dietary improvement, fortification of food with Fe, Fe supplementation and other public health measures, such as helminth control, have been designed to prevent and correct IDA(Reference Beard6Reference Mannar9). Fe supplementation remains the most widely used approach to meet the elevated physiological Fe demands of pregnant women(Reference Mannar9). However, the effectiveness of this approach has been limited due to inefficient health services, which includes inadequate supply and sub-standard Fe supplements resulting in low compliance of pregnant women(Reference Galloway and McGuire10Reference Yip and Ramakrishnan13).

The effectiveness of an Fe supplementation programme depends to a large extent on the delivery system and the recipients’ compliance. The availability of Fe tablets in the health centres relies in turn on the government’s policy, funds from the local government units and the available infrastructure. Community communication to encourage programme participation and partnership is essential when tackling the Fe supply and demand problems and to ensure programme sustainability and success(Reference Mannar9). In addition to ensuring the adequacy of Fe supply, health workers must be trained on anaemia and on the importance of Fe during pregnancy, and motivated to comply with the set protocol to ensure that pregnant women receive the required Fe tablets.

The receipt of sufficient Fe tablets, however, will not ensure that pregnant women will actually take them as required(Reference DeMaeyer, Dallman, Gurney, Hallberg, Sood and Srikantia14). Compliance is influenced by the undesirable side effects brought about by the ingestion of Fe tablets, which are related to the amount(Reference Charoenlarp, Dhanamitta and Kaewvichit15) and form of the tablets(Reference Bonnar, Goldberg and Smith8) and possibly to the frequency and duration of its ingestion. Further, the knowledge, attitudes and practices of the pregnant women regarding the use of Fe tablets are important factors to consider(Reference Schultink16, Reference Galloway, Dusch and Elder17). At present, prenatal Fe supplementation programmes in developing countries have been unable to achieve good coverage and have been ineffective in reducing anaemia among pregnant women(Reference Yip18) Efforts are needed to determine innovative solutions to the problems in the supply and distribution of Fe tablets, adherence of pregnant women to Fe supplementation and reduction of concurrent infections (malarial and parasitic). A successful Fe supplementation programme for pregnant women would eventually benefit the mother and the child through increased productivity, improved quality of life and increased physical and mental performance.

The present study was conducted to determine the effectiveness of the redesigned Fe supplementation delivery system (ISDS) for pregnant women in improving Fe status, reducing anaemia prevalence, increasing compliance of pregnant women and in upgrading coverage by the health workers.

Methods

Study area and participants

The present study was carried out in the two provinces of the island of Negros in Southern Philippines. The province of Negros Occidental was the experimental area with 63·4 % anaemia prevalence among pregnant women prior to the study(3). The province of Negros Oriental was selected as the control area because of its similarity with the experimental area in terms of socio-economic status and geographical features. Schistosomiasis and malaria are not endemic in both provinces. From each province, three areas were chosen to represent different socio-developmental standings as set by the Philippine Department of Finance, namely one upper class city, one middle class city and one lower class municipality. Three villages were selected from each area based on geography (one coastal and two hinterland) and population size. The study sample was representative of the two provinces in Negros island and its coastal and hinterland cities and barangays in terms of sociodemographic parameters.

Approximately 288 pregnant women at baseline and at post-six months were required for each treatment group based on the following assumptions: 60 % baseline anaemia prevalence, 20 % reduction in anaemia prevalence with 80 % statistical power and an alpha of 0·05. The sample size was increased by 5 % to account for possible dropouts; hence, 300 pregnant women per treatment group per survey period were needed or a total of 1200 pregnant women. The EpiInfo software was used in generating the required sample size.

Before the baseline and endline surveys, pregnant women were identified using the Target Client List (TCL) in the government health units and the prenatal record books in private clinics. Those who were confirmed pregnant during house-to-house listing by the health workers were considered eligible for inclusion in the study. Pregnant women were randomly selected from the list at baseline and then again after 6 months. Thus, the pregnant women who participated at baseline were not the same pregnant women examined after 6 months. The number of pregnant women selected from each area was proportional to the population size of the village.

The age of gestation of each pregnant woman was determined based on the date of her last menstrual period (LMP). Of the 2·9 % pregnant women whose LMP was unknown, a professional health worker measured the height of the uterine fundus to provide a rough estimate of the age of gestation. However, only gestational ages from LMPs were used in the analyses.

Study design

The first phase of the study was the evaluation and redesigning of the existing ISDS. The redesigned ISDS strategy was reached by consensus based on the results of a survey on the existing ISDS followed by focus group discussions among experts with inputs from village health workers (VHW) and traditional birth attendants (TBA). The second phase of the study focused on determining the effectiveness of the redesigned ISDS through a controlled trial.

A controlled before and after study design was chosen for the present study since the management of health programmes in the Philippines including Fe supplementation delivery was devolved to the local government units(19). In addition, inter-local health zones composed of provincial and municipal governments together with non-government organisations meet monthly aiming to improve health services delivery. Thus, individual or cluster (by village or municipality) randomisation within a province would not have been possible without contamination of interventions.

Interviews and Hb measurements of randomly selected pregnant women in both treatment areas were conducted at baseline and after 6 months of the installation of the redesigned ISDS in the experimental area. The health workers in both treatment areas were not blinded on the Fe status of the pregnant women. The participants were informed of their Fe status by the VHW.

Intervention

The intervention consisted of providing UNICEF tablets (Lomapharm, Germany) containing 60 mg elemental Fe and 0·40 mg folic acid to all pregnant women to be taken once daily in both treatment areas. The Department of Health (DOH) provided the UNICEF tablets that were used in the study. Adequate and regular Fe supply is an important component of success of any Fe supplementation programme. This problem had been cited during the preliminary survey on the existing ISDS and during the focus group discussions among health workers and experts. To eliminate the Fe supply as a confounding factor in the present study, a 2-year supply of Fe/folic acid tablets was delivered by the Philippine DOH to the Provincial Health Offices of both treatment areas following their routine supply and delivery procedures, prior to the training of the health workers. The one-week training of health workers on the features of the redesigned ISDS was conducted only in the experimental area.

The redesigned ISDS was installed and implemented in the experimental villages by the trained health workers while the existing ISDS was continued in the control villages. No incentive in cash or in kind was provided by the research team to the health workers in both treatment areas for their participation in the study.

The features of the redesigned ISDS included involvement of the VHW and the TBA in spot mapping and clustering to identify and register the pregnant women for antenatal care early; in the distribution of Fe supplements and monitoring of compliance using the monitoring notebooks; and in using information, education and communications (IEC) materials such as posters and flyers for promoting Fe supplementation in the community and for counselling pregnant women. All of these features were absent in the existing ISDS. The comparison of the existing ISDS and the redesigned ISDS is shown in Table 1.

Table 1 Comparison of the existing ISDS and the redesigned ISDS

ISDS, Fe supplementation delivery system; IEC, information, education and communication.

A yearly household survey in each village was conducted by the VHW and TBA, the output of which was a village spot map wherein demographic information of the surveyed households was pictorially illustrated in a map of the community (usually drawn on the wall of the health centre) to give the local authorities the complete picture or profile of a locality in terms of age group, sex, physiologic status (pregnant, non-pregnant, child, father, etc.), socio-economic status, health and nutritional status at a glance. Clusters composed of twenty to thirty households were created, each managed by a VHW or TBA.

The pregnant women in the control area were given the UNICEF Fe/folic acid tablets using the existing ISDS while those in the experimental area were given the same tablets and dose using the redesigned ISDS. The Fe tablet distributors in the redesigned ISDS were the rural health midwife (RHM), VHW and the TBA. The first thirty Fe/folic acid tablets were given by the RHM during the pregnant woman’s first prenatal visit. The VHW and the TBA conducted home visits 15d later and every 15d thereafter to counsel, check the participants’ compliance to Fe tablet intake and replenish their Fe supply. The fifteen extra Fe tablets given by the VHW and TBA served as a buffer supply until the pregnant woman’s next prenatal visit. Compliance monitoring was conducted also by the RHM during the pregnant woman’s prenatal visit in the health units. The remaining Fe tablets were counted and the intake was recorded in the TCL by the RHM and in the monitoring notebooks by the VHW and the TBA. During the distribution, counselling on the importance of Fe supplements during pregnancy and on dealing with the side effects after Fe tablet intake were also carried out by the RHM during mother’s class and by the VHW and TBA during home visits using the IEC materials. Instructions on the dosage and frequency of intake (written in the label of the Fe packs) were also imparted to the pregnant women.

Data collection

Blood sample collection and interviews of pregnant women were conducted simultaneously in both treatment areas at baseline (June 2002) and at endline (January 2003). Blood samples were collected by trained medical technologists through finger-prick to determine Hb concentration on-site using a HemoCue hemoglobinometer (HemoCue, Sweden) following standard procedures. Anaemia was defined as Hb < 11 g/dl. Anaemia was further classified as mild (Hb ≥ 10 to <11 g/dl), moderate (Hb ≥ 7 to <10 g/dl) or severe (Hb ≥ 4 to <7 g/dl)(Reference Mathers, Bernard and Iburg20).

House-to-house interviews of pregnant women were carried out by trained nurses and nutritionists to gather information on socio-economic-demographic status; age of gestation; place and frequency of prenatal visits; quantity, quality, source and receipt of Fe supplements; dose and frequency of intake of Fe tablets; and side effects experienced after Fe tablet intake.

Statistical analysis

Descriptive statistics of baseline characteristics were computed to determine the comparability of the groups using Pearson’s χ 2 test for categorical variables and two-tailed Student’s t-test for continuous variables. Adequate prenatal visit was defined as 1 visit/month for the first 32 weeks of pregnancy, 1 visit/2 weeks from the 33rd to 36th weeks of pregnancy and weekly visits from the 37th week up to the time of delivery.

In the present study, two provinces were purposively selected, and from these provinces, two cities and one municipality were chosen based on socio-developmental standing. From each area, three villages were chosen based on geography. Thus, there were both (i) a two-level nesting (villages were nested within the cities, and cities were nested within the provinces) and (ii) a village-type and city-type structure.

Because selection of the study sites was not random, multilevel mixed-effects linear regression was used in the analysis, where village and city were random parameters. Village- and city-types were fixed parameters. This was done to determine the effects of the experimental v. the control interventions while accounting for possible differences in variances and covariances by area.

Statistical analysis was performed using EpiInfo version 6·04d (Centers for Disease Control and Prevention, Atlanta, GA, USA and WHO, Geneva, Switzerland) and Stata (Stata Corporation, College Station, TX, USA) statistical software packages. Significance was tested at the 5·0 % level.

Ethical approval and informed consent

The study was reviewed and approved for implementation in Negros Island by the Health Research Division of the Health Policy Development and Planning Bureau of the DOH through the National Center for Disease Prevention and Control and the Regional Health Offices. The purpose of the study and the procedures to be undertaken were explained to the local government and health executives in the provinces of Negros Occidental and Negros Oriental by an NCP staff during courtesy calls and to the pregnant women by trained field assistants during house-to-house visits. Signed informed consent was obtained from each pregnant woman and her husband (if married) or from one of her parents (if unmarried and <18 years old).

Results

There were 596 pregnant women from the experimental area and 584 pregnant women from the control area (or a total of 1180 pregnant women) who agreed to participate in the study (Fig. 1). The participants’ mean age was 27 years and 48·1 % were in the second trimester of their pregnancy (Table 2). There was no difference in gestational age between treatment groups at baseline (P = 0·276) and at post-intervention (P = 0·497) and in the number of pregnant women in each trimester at baseline (P = 0·418) and 6 months after (P = 0·786). The results were similar even when we limited the analysis to the women in the first half of their pregnancy (data not shown). Nearly all of the pregnant women (97·1 %) remembered their date of the LMP. There were significantly more multiparous women in the experimental area than in the control area both at baseline (76·5 v. 68·7 %; χ 2 = 4·621, P = 0·031) and at endline (71·5 v 60·9 %; χ 2 = 7·261, P = 0·007). Filipino women’s fertility rate is at 3·5 births per woman(21). The 2002 Field Health Service Information Service System report completed by field health workers also showed that there were 18 721 recorded number of pregnancies in the experimental areas, higher than the 14 905 recorded pregnancies in the control areas(22).

Fig. 1 Study design (ISDS, Fe supplementation delivery system)

Table 2 Characteristics of the participants at baseline and after 6 months by treatment group

*Comparison between groups at baseline.

†Comparison between groups at endline.

The mean number of prenatal visits per trimester (0·99 v. 1·08) and the probability of taking Fe tablets (68·5 v. 74·3 %) were not significantly different between the control and experimental areas at baseline (all P > 0·05). There were significantly fewer pregnant women in the experimental area with adequate prenatal visits (13·5 v. 23·3 %; P = 0·002), who were monitored for compliance (43·0 v. 52·3 %; χ 2 = 5·2733, P = 0·022) and who reported having experienced side effects after Fe intake (20·1 v. 40·0 %; χ 2 = 28·0415, P < 0·001) than in the control area at baseline.

Before the implementation of the redesigned ISDS, there were significantly more anaemic pregnant women in the experimental area than in the control area (50·7 v. 37·3 %; χ 2 = 10·795, P = 0·001). However, at endline, the proportion of anaemic pregnant women in the experimental area was comparable to that of the control area (35·6 v. 33·1 %; χ 2 = 0·394, P = 0·530). Although logistic regression showed that the pregnant women in the experimental group were significantly less likely to be anaemic at endline compared with baseline, and whereas the prevalence rates of anaemia did not change in the control group (Table 3), multiple logistic regression taking baseline characteristics, village- and city-type structure, and random effects of nesting into account did not show a significant impact on anaemia prevalence in the intervention area as compared to the control one (Table 4).

Table 3 Odds ratios of outcomes between baseline and 6 months post-intervention shown separately for the control and intervention areas

Table 4 Odds ratios for the impact of the intervention on the experimental group in comparison to the control group at endline as compared to baseline

When we analysed Hb concentration as a continuous variable, we saw a significant difference between the control and intervention areas. The mean Hb concentration of the pregnant women at baseline in the experimental group (10·87 g/dl) was lower than in the control group (11·45 g/dl; P = 0·001) but not at endline (P > 0·05). After controlling for baseline characteristics, village- and city-type structure, and random effects of nesting, an increase in the mean Hb among pregnant women in the experimental group by 0·49 g/dl (95 % CI 0·16, 0·78; P = 0·002) more than in the control group was observed. There were significantly more pregnant women in the experimental group than in the control group who were taking Fe tablets at endline (79·2 v. 57·4 %; χ 2 = 32·060; P < 0·001).

Overall, only one-fifth of the pregnant women had an adequate number of prenatal visits at baseline (18·1 %) and at post-intervention (19·4 %). At baseline, the proportion of pregnant women in the experimental area with adequate prenatal visits was significantly less than in the control area (13·2 v. 23·0 %; P = 0·002). However, the proportion of pregnant women with adequate prenatal visits increased in the experimental group and was comparable to the control group at post-intervention (17·8 v. 21·2 %; P = 0·311). Although the proportion of pregnant women with adequate prenatal visits was generally very low, the actual number of prenatal visits/trimester of gestation increased almost twofold (by 0·69; P < 0·001) in the experimental group (0·99 to 1·66 visits/trimester of gestation at baseline to endline; P < 0·001) while it remained at baseline level in the control group (1·08 to 1·04 visits/trimester; P = 0·617). Pregnant women from the experimental group were also four times more likely to be taking Fe tablets, five times more likely to report side effects from Fe intake and sixteen times more likely to be monitored for compliance to Fe supplementation compared to those from the control area. An increase in the reporting of side effects in the experimental group at endline (as shown in Table 2) manifests the increase in the client–health provider contact, concurrent with an increase in the proportion of pregnant women who were monitored by the health workers.

Discussion

For the past decades, prenatal Fe supplementation has been the standard recommendation for reducing maternal anaemia in developing countries including the Philippines. This strategy has long been documented as efficacious in improving Fe status. A meta-analysis of data on the relative change in maternal Hb associated with Fe supplementation from pooled randomised controlled trials published between 1966 and 1998 showed that Fe supplementation increased the Hb concentration of pregnant women(Reference Sloan, Jordan and Winikoff23). A review of forty randomised or quasi-controlled trials involving 12 706 pregnant women showed that daily Fe supplement increases Hb levels in both antenatal and postnatal maternal blood(24). Reduction in anaemia prevalence after supplementing with Fe was also seen among pregnant women in India(Reference Abel, Rajaratnam, Kalaimani and Kirubakaran25), in rural Bangladesh(Reference Ekstrom, Hyder and Chowdhury26) and in adolescent pregnant women in their first pregnancy in Wisconsin, USA(Reference Meier, Nickerson, Olson, Berg and Meyer27).

The problem, then, was not in the efficacy of the Fe tablets but in the effectiveness of the public health intervention. The redesigned ISDS was developed to answer the identified problems and constraints in the existing ISDS. An innovative approach to addressing some of the constraints was empowering and elevating the status of the local VHW as partners of the professional health workers in the delivery of health services. Responsibilities that would normally go to the overworked professional health workers were given to the local health workers such as identification and registration of pregnant women, counselling with the use of the IEC materials, distribution of the Fe supplements and monitoring compliance of the pregnant women in their assigned clusters with the use of the monitoring notebooks. With appropriate training and motivation, indigenous health workers became effective channels for the Fe supplementation scheme for pregnant women as was similarly seen in Indonesia(Reference Galloway, Dusch and Elder17, Reference Robinson28, Reference Utomo, Riono and Budiono29).

Compliance is a key factor to the success of an ISDS. Side effects experienced by the pregnant women after Fe tablet intake might be a deterrent to compliance, resulting in the inability of the pregnant women to complete the minimum required number of Fe supplements to be taken during pregnancy. An increase in compliance was noted despite the increase in the proportion of pregnant women in the experimental group who reported minor gastrointestinal side effects. This could be attributed to the increase in the proportion of pregnant women who were visited, counselled and monitored by the health workers, which led to an increase in the reporting of side effects concomitant with an increase in the awareness of the need of Fe supplements during pregnancy, leading to persistence in daily Fe tablet intake(Reference Galloway, Dusch and Elder17, Reference Elder30). Although the giving of Fe supplements to pregnant women in the redesigned ISDS was not directly observed by the supplementers due to logistical constraints, the attendant increase in Hb concentration makes the present study result a reliable measure of compliance to Fe tablet intake.

An increase in the actual number of prenatal visits of pregnant women in the group supplemented with Fe through the redesigned ISDS was also noted. Early detection of pregnancy by the indigenous health workers through clustering of households and listing of pregnant women led to early counselling and referral of the pregnant women for prenatal check-up and start of Fe supplementation. However, because the proportion of women with adequate number of prenatal visits remained low, improvements on this system could be iteratively added and evaluated.

In summary, we recommend the use of an ISDS that empowers the local VHW to become partners of the professional health care workers in registration, counselling, Fe supplement distribution and monitoring compliance of pregnant women with appropriate training. We have shown this to be an effective system in increasing maternal Hb concentration and in improving prenatal health-seeking behaviour. A summary of suggested changes and ways to improve Fe supplementation programmes is provided in Table 5.

Table 5 Suggested changes and ways to improve iron supplementation programmes

Acknowledgements

Sources of funding: The study was funded by the National Center for Disease Prevention and Control of the Philippine Department of Health.

Conflict of interest: None of the authors had any conflict of interest.

Authorship responsibilities: M.G.D.R. was responsible for the management of the project and wrote the manuscript. P.R.-S. performed the statistical analyses, interpreted the data and reviewed the manuscript. L.W.T. reviewed the manuscript. J.N.S. was involved in the design of the study; performed the statistical analyses and reviewed the manuscript. L.S.P. was involved in the design of the study and reviewed the manuscript. F.S.S. was responsible for the overall conception and design of the study and reviewed the manuscript.

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Figure 0

Table 1 Comparison of the existing ISDS and the redesigned ISDS

Figure 1

Fig. 1 Study design (ISDS, Fe supplementation delivery system)

Figure 2

Table 2 Characteristics of the participants at baseline and after 6 months by treatment group

Figure 3

Table 3 Odds ratios of outcomes between baseline and 6 months post-intervention shown separately for the control and intervention areas

Figure 4

Table 4 Odds ratios for the impact of the intervention on the experimental group in comparison to the control group at endline as compared to baseline

Figure 5

Table 5 Suggested changes and ways to improve iron supplementation programmes