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Impact of targeted food supplementation on pregnancy weight gain and birth weight in rural Bangladesh: an assessment of the Bangladesh Integrated Nutrition Program (BINP)

Published online by Cambridge University Press:  01 August 2009

Shamsun Nahar ,
CG Nicholas Mascie-Taylor  and
Housne Ara Begum
Shamsun Nahar
Affiliation:
Department of Biological Anthropology, University of Cambridge, Pembroke Street, Cambridge CB2 3RA, UK
CG Nicholas Mascie-Taylor*
Affiliation:
Department of Biological Anthropology, University of Cambridge, Pembroke Street, Cambridge CB2 3RA, UK
Housne Ara Begum
Affiliation:
Department of Biological Anthropology, University of Cambridge, Pembroke Street, Cambridge CB2 3RA, UK
*
*Corresponding author: Email nmt1@cam.ac.uk
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Abstract

Objectives

To assess whether the Bangladesh Integrated Nutrition Programme (BINP) correctly identified which pregnant women should be enrolled in the food supplementation programme, whether supplementation commenced on time and was taken on a regular basis. A second objective was to determine whether food supplementation led to enhanced pregnancy weight gain and reduction in the prevalence of low birth weight.

Design

A one-year community-based longitudinal study.

Setting

A rural union of Bhaluka Upazila, Mymensingh, located 110 km north-west of Dhaka City, the capital of Bangladesh.

Participants

A total of 1104 normotensive, non-smoking pregnant women who attended Community Nutrition Centres were studied from first presentation at the centre until child delivery.

Results

Pregnant women who had a BMI of <18·5 kg/m2 on first presentation should have been selected for supplementary feeding (2512 kJ (600 kcal)/d for six days per week) starting at month 4 (16 weeks) of pregnancy. However, of the 526 women who had BMI < 18·5 kg/m2, only 335 received supplementation; so the failure rate was 36·3 %. In addition, of those receiving supplementation, only 193 women (36·7 % of 526 women) commenced supplementation at the correct time, of whom thirty-two (9·6 % of 335 women) received supplementation for the correct number of days (100 % days). There were no significant differences in mean weight gain between BMI < 18·5 kg/m2 supplemented or non-supplemented groups or between the equivalent groups with BMI ≥ 18·5 kg/m2. Weight gain was inversely related to initial weight, so lighter women gained relatively more weight during their pregnancy than heavier women. The mean birth weight in the supplemented and non-supplemented groups was 2·63 kg and 2·72 kg, respectively. Mothers with BMI < 18·5 kg/m2 who were or were not supplemented had almost equal percentages of low-birth-weight babies (21 % and 22 %, respectively).

Conclusion

The study raises doubt about the efficiency of the BINP to correctly target food supplementation to pregnant women. It also shows that food supplementation does not lead to enhanced pregnancy weight gain nor does it provide any evidence of a reduction in prevalence of low birth weight.

Keywords

Pregnancy weight gainFood supplementationLow birth weight
Type
Research Paper
Information
Public Health Nutrition , Volume 12 , Issue 8 , August 2009 , pp. 1205 - 1212
Copyright
Copyright © The Authors 2008

Intra-uterine growth and development is one of the most vulnerable periods in the human life cycle. The weight of an infant at birth is an important indicator of maternal health and nutrition prior to, and during, pregnancy, and a powerful predictor of infant growth and survival(Reference Gülmezoglu, de Onis and Villar1). Approximately 25 million babies are born each year weighing less than 2500 g, the WHO cut-off for low birth weight (LBW), of which 90 % are born in developing countries(2). Bangladesh is one such country, where 50 % of childbearing women are suffering from malnutrition defined by BMI < 18·5 kg/m2 and more than 20 % are severely stunted(Reference Mitra, Al-Sabir and Cross3). Bangladesh has the highest worldwide prevalence of LBW with rates estimated at between 20 % and 60 %(4, Reference Nahar, Afroza and Hossain5).

The high prevalence of LBW in Bangladesh has enormous implications for its future population. The World Bank estimates that the rate of 40 % LBW and the corresponding level of stunting alone will cost Bangladesh $US 10 billion in lost productivity over a 10-year period(Reference McLachlan6). The Government of Bangladesh, with financial support from The World Bank, initiated a supplementation programme known as the Bangladesh Integrated Nutrition Programme (BINP) in 1995 with the aim of increasing weight gain in pregnancy up to 7 kg in 50 % of pregnant women and reducing LBW by half from its then-current rate.

The BINP was implemented in forty out of a total of 460 thanas (administrative areas) in the country. The aim of the programme was to reduce malnutrition, particularly among women and children, by ensuring household food security and through behavioural changes related to food intake, infant feeding, growth monitoring and caring practice. All children below 2 years of age were targeted for monthly growth monitoring and for determination of nutritional status. Pregnant women were also identified primarily within the first trimester for regular monthly weighing. All severely malnourished children or growth-faltering children as well as malnourished pregnant mothers (defined by BMI < 18·5 kg/m2) received daily supplementary feeding for six days per week. The malnourished pregnant women received a ration of 2512 kJ (600 kcal)/d for six days per week for up to 6 months during pregnancy and weekly Fe supplementation and vitamin A within 14 d of delivery(7). The services were provided through Community Nutrition Centres (CNC) located in villages.

The BINP Mid Term Evaluation(8) reported that, since its inception, the programme has had notable success in reducing the prevalence of malnutrition among young children. Its effect on pregnant women, a second key target group, has however been less clear to date. The present study was designed to evaluate two main aspects of the BINP: (i) the efficiency of the BINP in identifying which women should be supplemented, whether supplementation commenced on time and whether mothers were compliant; and (ii) whether supplementation led to greater maternal weight gain and fetal weight gain, thereby reducing LBW prevalence.

Participants and methods

A one-year, longitudinal, rural community-based study was conducted on all pregnant women who registered between their second and sixth month of gestation as part of the routine BINP assessment. The data were collected from a rural union of Bhaluka Thana, Mymensingh, located 110 km north-west of Dhaka City, the capital of Bangladesh. A total of 1104 pregnant women were studied from first presentation until child delivery. At first registration women were weighed and had their height measured. Thereafter weight was measured at approximately monthly intervals until delivery.

Pregnant women who have BMI < 18·5 kg/m2 on first presentation should receive supplementary feeding starting at 4 months (16 weeks). Women who register later in pregnancy with BMI < 18·5 kg/m2 should start supplementation immediately. The 2512 kJ (600 kcal)/d food supplement consisted primarily of a cereal–pulse mixture containing raw sugar (jaggery) and oil, which comprises 80 % carbohydrate, 12 % protein and 8 % fat. The food was prepared at the village level. Pregnant mothers had to consume the supplement at a local CNC.

All anthropometric measurements were carried out using standard methodology as described by Lohman et al.(Reference Lohman, Roche and Martorell9). The measurements were made with the subjects wearing a minimum amount of clothing. Height was measured by using a locally made stadiometer. The woman was asked to maintain an upright and erect posture with her feet together and the back of her heels touching the pole of the anthropometer. The horizontal headpiece was lowered onto the woman’s head (maintained in the Frankfurt plane) and the measurement was taken to the nearest 0·1 cm. The UNICEF UNI-Scale was used to measure the weight of the pregnant women and newborn babies. Newborn babies were weighed within 24 h of delivery at the birth place. The weighing machine was calibrated with known weights up to 70 kg at the beginning of each weighing session. The women’s BMI was calculated using the formula: weight (kg)/[height (m)]2.

The inter-observer error for height and weight were computed at four different times during the study: before starting the study, at months 5 and 9, and at the end of the study. Ten subjects were used each time and the technical error of measurement (TEM) and reliability were determined. The TEM was obtained by measuring the same subject by each research assistant. Reliabilities for all measurements were all above 0·98 and higher than the 0·95 threshold given by Ulijaszek and Kerr(Reference Ulijaszek and Kerr10). Thus the TEM was acceptable and was not incorporated in the statistical analysis.

One of the problems with longitudinal data is that, in order to examine incremental weight changes over time, the numbers of days between visits need to be very similar. Although this is potentially achievable in strictly research projects, in operational programmes this is much less likely to occur. Brush et al.(Reference Brush, Harrison, Barber and Zumrawi11) overcame the monthly variation in days between measurements by computing the curvilinear relationship between the anthropometric variable, e.g. weight, and the actual days between measurements. As the polynomial fits (adjusted R 2) were very good, they calculated the weight at fixed intervals. The same procedure was used here because the ‘monthly’ variation between measurements was between 22 and 35 d. Consequently an individual polynomial regression curve was computed for each woman, and like Brush et al. we found that the fit was very good, with adjusted R 2 ranging from over 95 % to nearly 100 %. As a result, the predicted weight at 28 d intervals was computed and these predicted weights were used in all subsequent analyses.

Gestational age was assessed by the Parkin method(Reference Ceesay, Prentice, Cole, Ford, Weaver, Poskitt and Whitehead12), which scores four external characteristics: skin colour, skin texture, ear firmness and breast development. The scheme is simple, easy to use, less time-consuming and appropriate for field workers.

A power test showed that these sample sizes were sufficient to detect about a 10 % difference in the percentage of supplemented and non-supplemented women gaining >1 kg per month during pregnancy or gaining >7 kg at the end of pregnancy. A variety of statistical tests was used, including univariate ANOVA and repeated-measures ANOVA.

Results

BINP programmatic issues

Four indicators were used to measure the efficacy of the BINP supplementation programme: (i) receiving supplementation if BMI < 18·5 kg/m2; (ii) commencing supplementation at the correct time; (iii) receiving daily supplementation six days a week until the birth of the child; and (iv) achieving targeted weight gain set by BINP of >1 kg per month or >7 kg at the end of pregnancy.

As the women registered in different months the amount of time they received supplementation varied. In order to make comparisons, the extent of supplementation was computed (the number of days a women received supplementation/the total number of possible days of supplementation). The mean percentage compliance was 91·0 (sd 9·9) % (range 54–100 %).

Table 1 presents a breakdown of supplementation status by BMI cut-off. As can be seen, of the 526 women with BMI < 18·5 kg/m2 only 63·7 % were supplemented while 4 % of women with BMI ≥ 18·5 kg/m2 were incorrectly supplemented. Even so, of the 63·7 % who received supplementation, only 193 (36·7 % of 526 women) commenced supplementation at the correct time, of whom thirty-two women (9·6 % of 335 women) received the full supplementation. Women with BMI < 18·5 kg/m2 who registered in months 3 and 4 were more likely to receive supplementation than those registering later.

Table 1 BMI cut-offs and supplementation status: rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery

Sociodemographic and nutritional status of the pregnant women at registration and outcome of pregnancy

The primarily Muslim pregnant women and their families living in this rural area of Bangladesh were mainly poor with three-quarters of families spending £10–20/month, mostly on food. About 20–25 % of husbands and wives had received no education and the majority of husbands were working as either day labourers or farmers. Most of the pregnant mothers were between 20 and 34 years of age. Over one-third of the women were nulliparous while 12·8 % were multiparous (≥4 births). Most (93 %) mothers registered between the third and fifth month of pregnancy and only 7 % registered in the sixth month. The average birth interval, based on the last child, was about 2·5 years. About 47 % of women had BMI < 18·5 kg/m2 on first registration, of whom 6 % were in the chronic energy deficiency group (CED) III (BMI < 16·0 kg/m2), 11 % in CED II (BMI = 16·0–16·9 kg/m2) and 30 % in CED I (BMI = 17·0–18·5 kg/m2). There were no significant associations between BMI status and any of these sociodemographic variables. Women with BMI < 18·5 kg/m2 had significantly (P < 0·001) lower mean weight (on average 6·8 kg), but their height was just significantly greater (+1·1 cm) than that of women with BMI ≥ 18·5 kg/m2. There was no significant difference between the supplemented and non-supplemented groups with BMI < 18·5 kg/m2 in initial weight or stature nor was there any difference between the two groups in weight gain during pregnancy or birth outcome.

About 97 % of the 1104 deliveries occurred at home, of which 95 % were live born, 3·3 % stillborn and 1·5 % were perinatal deaths. Of the newborn babies 50·6 % were male. No significant association was found between any of the sociodemographic variables and birth outcome and supplementation status.

Weight gain during pregnancy by BMI and supplementation status groups

The existence of the four groups of women (see Table 1) allowed more detailed comparisons between women with BMI < 18·5 kg/m2 and either correctly supplemented (<18·5 sf) or incorrectly not supplemented (<18·5 nsf), as well as between women with BMI ≥ 18·5 kg/m2 correctly not supplemented (≥18·5 nsf) and those incorrectly supplemented (≥18·5 sf). Table 2 presents the overall mean weight gain of these four groups by month of registration. As expected, the weight gain declined with later registration month and was consistent across all four BMI/supplementation status groups. ANOVA revealed that only for mothers who registered in month 3 were there significant differences between the four means, with women with BMI < 18·5 kg/m2 showing higher mean weight gains than women with BMI ≥ 18·5 kg/m2 whether supplemented or not. Post hoc tests showed that the overall difference in means was mainly accounted for by the greater weight gain of women in the BMI < 18·5 kg/m2 and supplemented group compared with women in the BMI ≥ 18.5 kg/m2 and non-supplemented group (P = 0·002). There were no significant differences in mean weight gain between supplemented and non-supplemented women with BMI < 18·5 kg/m2 or between the equivalent groups with BMI ≥ 18·5 kg/m2. After correction for initial weight, the difference in weight gain between BMI < 18·5 kg/m2 supplemented and BMI ≥ 18·5 kg/m2 non-supplemented groups fell further to only 100 g and was not significant.

Table 2 Total (absolute) weight gain (kg) by registration month according to BMI and supplementation status group: rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery

sf, supplemented; nsf, non-supplemented.

The BINP sets weight gain targets of >1 kg per month and overall weight gain of >7 kg at the end of pregnancy in 50 % of pregnant women. However, as Table 3 shows, these women failed to meet these targets especially for >7 kg weight gain in pregnancy.

Table 3 Pregnancy weight gain in relation to the programmatic targets (% of women achieving the target) by BMI and supplementation status group: rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery

sf, supplemented; nsf, non-supplemented.

Repeated-measures ANOVA were used to examine the change in monthly weights of the four BMI/supplementation status groups and, as can be seen from Fig. 1, the mean weights of the four groups tracked each other and were more or less parallel. Thus there was no evidence of any significant catch-up or catch-down, which indicates that the food supplement was not impacting on pregnancy weight gain.

Fig. 1 Monthly weight according to BMI (kg/m2) and supplementation status group (- - ●- -, <18·5 supplemented (sf); —▵—, <18·5 non-supplemented (nsf); — -□— -, ≥18·5 nsf; − −+− −, ≥18·5 sf) in month 3: rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery

The relationship between initial weight and weight gain was examined for each registration month separately and negative regression coefficients were found in all analyses, i.e. women who had a higher initial weight tended to show a lower weight gain. The magnitude of the coefficients declined from registration months 3 to 6 as would be expected (−0·41, −0·38, −0·22 and −0·18, respectively). There were no significant differences in regression coefficients between supplemented and non-supplemented women at each registration month.

Birth weight and relationship with sociodemographic variables and supplementation status of the mother

The overall mean birth weight of both boys and girls was 2·69 kg (sd 0·36 kg and 0·37 kg, respectively). Analysis of the birth weight of the newborn babies using the four BMI/supplementation status groups revealed significant heterogeneity in mean birth weights between them (P < 0·001). One-way ANOVA showed that the overall difference in means was mainly accounted for by the lower birth weight of the babies whose mothers were in the BMI < 18·5 kg/m2 groups irrespective of supplementation status (Table 4). However, there was no significant difference in mean birth weights of babies born to mothers with BMI < 18·5 kg/m2 whether supplemented or non-supplemented, or between the means of the equivalent BMI ≥ 18·5 kg/m2 supplemented and non-supplemented groups.

Table 4 Birth weight (kg) by sex of the newborn according to BMI and supplementation status group: rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery

sf, supplemented; nsf, non-supplemented.

The pattern of birth weight in the four BMI/supplementation status groups was consistent (insignificant interaction between sex of the baby and BMI groups, P = 0·43). When the analyses were repeated for each sex separately, the significant heterogeneity remained, more so in females than males. In both sexes the main difference was the higher mean in mothers with BMI ≥ 18·5 kg/m2v. those with BMI < 18·5 kg/m2.

Low birth weight, supplementation status and sociodemographic variables

Overall 17 % of babies were born with LBW (defined by WHO as <2·5 kg), and there were almost equal numbers of LBW male and female (17·0 % v. 16·3 %) babies. Gestational age calculated using the Parkin score revealed that 96·4 % were born after 37 weeks of gestation, and so intra-uterine growth retardation appears to be the major contributor to LBW. No significant association was found between LBW and any of the sociodemographic variables. Women who had BMI < 18·5 kg/m2, irrespective of supplementation status, had a significantly higher rate of LBW babies than women who had BMI ≥ 18·5 kg/m2 and were not supplemented (Table 5, P < 0·001). A sequential logistic regression analysis which adjusted for the effect of BMI (<18·5 and ≥18·5 kg/m2) first of all, and then tested for the effect of supplementation status, confirmed the insignificant effect of food supplementation on birth weight.

Table 5 Birth weight by BMI and supplementation status group: rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery

sf, supplemented; nsf, non-supplemented.

In addition, malnourished women gained significantly more weight during pregnancy (6·3 kg, 6·2 kg and 5·9 kg, CED grades III, II and I respectively; Table 6) than non-malnourished women (5·4 kg). When the birth weight and proportion of LBW in these groups were compared, malnourished women in all three CED categories had a lower mean birth weight and a higher proportion of LBW babies than non-malnourished women.

Table 6 Weight gain, birth weight and percentage of low birth weight (LBW) by level of chronic energy deficiency (CED): rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery

Discussion

The present study, in keeping with a recent World Bank report(13), highlights serious deficiencies in the implementation of the BINP in this rural area with over 40 % of women either not receiving supplementation or receiving it incorrectly. In addition, of those receiving food supplementation, nearly half started late and only about one in ten women received the full supplementation. In the BINP Monthly Monitoring Report(14) (June 2000), the seven non-governmental organizations working for the BINP had examined 107 845 pregnant women of whom 53 922 had BMI < 18·5 kg/m2. If the results of the present study are extrapolated to the whole BINP, then over 50 000 women would either not have been supplemented or, if so, would not start supplementation on time or would not receive the full supplementation.

In this group of rural women, irrespective of supplementation status, the total weight gain was 5·6 kg, which is higher than the 4·8 kg weight gain recorded by Krasovec(Reference Krasovec15) for Bangladeshi rural women but lower than values reported in other south Asian countries (Taiwan, 7·6 kg; India, 6·5 kg; East Java, 6·0 kg).

A recent study in Bangladesh(Reference Ortolano, Mahmud, Kabir and Levinson16) using monitoring data from the BINP found that the absolute (total) weight gain and monthly weight gain were higher in supplemented (BMI < 18·5 kg/m2) than non-supplemented women (7·5 kg v. 6·3 kg and 1·4 kg v. 1·3 kg, respectively). However, the weight gains and the monthly weight gains in the present study were lower than those observed by Ortolano et al.(Reference Ortolano, Mahmud, Kabir and Levinson16). This may be because the latter study(Reference Ortolano, Mahmud, Kabir and Levinson16) did not take into account when mothers first registered at the CNC and so its two groups are not strictly comparable. More crucially, as noted by Kramer(Reference Kramer17), the comparison of these two groups does not indicate success of the programme since Ortolano et al.’s study did not control for women with BMI < 18·5 kg/m2 and not supplemented or women with BMI ≥ 18·5 kg/m2 and supplemented. As the present study has demonstrated, comparison of all four groups of women was able to show that women with BMI < 18·5 kg/m2 whether supplemented or not gained more weight than women with BMI ≥ 18·5 kg/m2.

The targets set by the BINP of a weight gain >1 kg per month and >7 kg at the end of pregnancy in 50 % of women were also used by Ortolano et al.(Reference Ortolano, Mahmud, Kabir and Levinson16) to monitor the success of the BINP. They reported that, overall, 74·9 % of women in the supplemented group gained >1 kg per month and 61·8 % of the women in the non-supplemented group gained >1 kg per month. They also reported that 69·5 % of the women in the supplemented group gained >7 kg at the end of pregnancy while 49·0 % of the non-supplemented group gained >7 kg, and was more likely to be observed in primigravids. The present study, in keeping with the Monthly Monitoring Report(14), observed much lower percentages: only 45·0 % of the women in the supplemented group gained >7 kg at the end of pregnancy while in the non-supplemented only 34·7 % gained >7 kg at the end of pregnancy in the present study.

The effect of supplementation on pregnancy weight gain using BMI as an indicator for undernutrition needs to be interpreted with caution, keeping in mind that pre-pregnancy BMI or even early-pregnancy BMI is often inversely associated with gestational weight gain(Reference Schieve, Cogswell, Scanlon, Perry and Ferre18), presumably as a physiological compensatory mechanism for pre-pregnancy undernutrition. In the present study weight gain was inversely correlated with BMI and initial weight. Lighter women gained relatively more weight during their pregnancy than heavier women, a result in keeping with other studies in East Java, Indonesia(Reference Kusin and Kardjati19), Pakistan(Reference Winkvist, Habicht and Rasmussen20) and Taipei, Republic of China(Reference SiegaRiz, Adair and Hobel21).

The present study showed that supplementation had an insignificant effect on birth weight and LBW, in keeping with some studies(Reference Kardjati, Kusin and de With22Reference Agarwal, Agarwal, Agarwal, Rai, Prasad, Agarwal and Singh27), while other studies have reported a significant impact of supplementation on birth weight(Reference Ceesay, Prentice, Cole, Ford, Weaver, Poskitt and Whitehead12, Reference Lechtig28Reference Begum, Hussain, Afrid and Hamid32). The most recent food supplementation trial on undernourished women from the Gambia(Reference Ceesay, Prentice, Cole, Ford, Weaver, Poskitt and Whitehead12) reported considerably larger effects on birth weight. The present study, however, was unable to show significant improvement in birth weight and reduction in LBW prevalence. The difference may be explained by the much higher energy (4258 kJ (1017 kcal)) and protein content (22 g) of the Gambian supplement compared with that used in Bangladesh (2512 kJ (600 kcal) and 8·0–9·4 g, respectively). The second explanation may be that the food supplementation in the BINP may be a replacement not a supplement, which is supported by the findings of BINP operational research(Reference Abdullah, Karim and Samad33) that 30 % of the women substituted at least part of their domestic food intake by BINP food supplements. A WHO collaborative study(34) showed that weight gain of 1·5 kg/month during the last two trimesters is consistent with good pregnancy outcomes. However, the average monthly weight gain in the present study was considerably lower, averaging only 0·92 kg/month in the second and third trimesters.

In his meta-analysis Kramer(Reference Kramer35) showed no evidence that supplementation had a larger effect in undernourished women and concluded that the increment in birth weight due to supplementation was no larger in those women who were undernourished prior to or during pregnancy. Several researchers have argued that the degree of maternal undernutrition may affect the response to supplementation(Reference Winkvist, Habicht and Rasmussen20, Reference Pelto, Dickin and Engle36, Reference Olson37). They suggest that supplementation of moderately malnourished women produces an increase in birth weight but has little impact on maternal weight gain. However, when seriously malnourished women are supplemented they cannot ‘afford’ to direct the energy to the fetus and therefore such supplementation improves maternal weight gain more than birth weight. The results of the present study also show that although malnourished women gained significantly more weight in pregnancy, they had a higher proportion of LBW babies compared with non-malnourished women.

In conclusion, the present study found that the food supplementation programme in Bangladesh is inefficient in targeting eligible women, failed to start on time and did not achieve full compliance. Regular monitoring and supervision of field staff is essential, as is motivating the community to participate. There was a small but positive impact of food supplementation on maternal weight gain, but supplementation did not lead to improvement in birth weight and there was no indication of a reduction in prevalence of LBW babies. Further research is needed to determine the appropriate quality and quantity of food and micronutrient supplementation needed to reduce LBW prevalence.

Acknowledgements

Financial support for the study was provided by the Department for International Development administered by The British Council and University of Cambridge. We are very grateful to PROSHIKA (national non-governmental organization in Bangladesh) who gave us permission to work in their field centres, the officers who worked in Bhaluka for the Bangladesh Integrated Nutrition Programme and the field workers involved in the study. We also thank the women who participated in the study. There are no conflicts of interest. All three authors designed the study. The fieldwork was carried out by S.N. and H.A.B. The analyses were carried out primarily by S.N. and C.G.N.M.-T. and the writing up of the results was a joint effort by all three authors.

References

1.Gülmezoglu, M, de Onis, M & Villar, J (1997) Effectiveness of interventions to prevent or treat impaired fetal growth. Obstet Gynecol Surv 52, 139149.CrossRefGoogle ScholarPubMed
2.World Health Organization (1994) Multicentre Study on Low Birth Weight and Infant Mortality in India, Nepal and Sri Lanka. New Delhi: WHO, 1994.Google Scholar
3.Mitra, S, Al-Sabir, A & Cross, A (1997) Bangladesh Demographic and Health Survey. Dhaka: NIPORT.Google Scholar
4.UNICEF (2002) Evaluation database. http://www.unicef.org/evaldatabase/index_19000.html (accessed August 2008).Google Scholar
5.Nahar, N, Afroza, S & Hossain, M (1998) Incidence of low birth weight in three communities in Bangladesh. Bangladesh Med Res Counc Bull 18, 157164.Google Scholar
6.McLachlan, M (1999) National Nutrition Project. Washington, DC: The World Bank.Google Scholar
7.Government of Bangladesh (1996) Bangladesh Integrated Nutrition Program. Project Implementation Volume (PIV). Bangladesh: Ministry of Health and Family Welfare.Google Scholar
8.Institute of Nutrition and Food Science (1998) Bangladesh Integrated Nutrition Program (BINP). Mid-Term Evaluation Report. Bangladesh: INFS.Google Scholar
9.Lohman, TG, Roche, AF & Martorell, R (1988) Anthropometric Standardization Reference Manual. Champaign, IL: Human Kinetics Books.Google Scholar
10.Ulijaszek, SJ & Kerr, DA (1999) Anthropometric measurement error and the assessment of nutritional status. Br J Nutr 82, 165177.CrossRefGoogle ScholarPubMed
11.Brush, G, Harrison, GA, Barber, FM & Zumrawi, FY (1992) Comparative variability and interval correlation in linear growth of Hong Kong and Sudanese infants. Am J Hum Biol 17, 291299.CrossRefGoogle Scholar
12.Ceesay, SM, Prentice, AM, Cole, TJ, Ford, F, Weaver, LT, Poskitt, EM & Whitehead, RG (1997) Effects on birth weight and perinatal mortality of maternal dietary supplements in rural Gambia: 5 year randomised controlled trial. BMJ 315, 786790.CrossRefGoogle ScholarPubMed
13.The World Bank (2005) Maintaining Momentum to 2015? An Impact Evaluation of Interventions to Improve Maternal and Child Health and Nutrition in Bangladesh. Washington, DC: World Bank.Google Scholar
14.Government of Bangladesh (2000) Bangladesh Integrated Nutrition Project (BINP). Monthly Monitoring Report. Bangladesh: Ministry of Health and Family Welfare.Google Scholar
15.Krasovec, K (1989) An investigation into the use of maternal arm circumference for nutritional monitoring of pregnant women. ScD Dissertation, Johns Hopkins University School of Hygiene and Public Health.Google Scholar
16.Ortolano, SE, Mahmud, Z, Kabir, IAF & Levinson, FJ (2003) Effect of targeted food supplementation and services in the Bangladesh Integrated Nutrition Program on women and their pregnancy outcomes. J Health Popul Nutr 21, 8389.Google Scholar
17.Kramer, MS (2003) Food supplementation during pregnancy and functional outcomes. J Health Popul Nutr 21, 13.Google ScholarPubMed
18.Schieve, LA, Cogswell, ME, Scanlon, KS, Perry, G & Ferre, C (2000) Prepregnancy body mass index and pregnancy weight gain: associations with preterm delivery. Obstet Gynecol 96, 194200.Google ScholarPubMed
19.Kusin, JA & Kardjati, S (1994) Maternal and Child Nutrition in Madura, Indonesia. Amsterdam: Royal Tropical Institute.Google Scholar
20.Winkvist, A, Habicht, J-P & Rasmussen, K (1998) Linking maternal and infant benefits of a nutritional supplement during pregnancy and lactation. Am J Clin Nutr 68, 656661.CrossRefGoogle ScholarPubMed
21.SiegaRiz, A, Adair, L & Hobel, C (1996) Maternal undernutrition and inadequate rate of weight gain during third trimester of pregnancy increases the risk of preterm delivery. J Nutr 126, 146153.CrossRefGoogle Scholar
22.Kardjati, S, Kusin, JA & de With, C (1988) Energy supplementation in the last trimester of pregnancy in East Java: I. Effect on birthweight. Br J Obstet Gynaecol 95, 783794.CrossRefGoogle Scholar
23.Adair, L & Popkin, BM (1988) Birth weight, maturity and proportionality in Filipino infants. Hum Biol 60, 319339.Google ScholarPubMed
24.Alam, DS, Yunus, M, Axix, KMA & Francisco, A (1998) Birth weight and its association with maternal nutrition and socioeconomic variables in rural Bangladesh. Glimpse 20, 3–4.Google Scholar
25.Rush, D (1980) A randomized controlled trial of perinatal nutrition supplementation. Pediatrics 65, 683697.CrossRefGoogle Scholar
26.Viegas, OA, Scott, PH, Cole, TJ, Eaton, P, Needham, PG & Wharton, BA (1982) Dietary protein energy supplementation of pregnant Asian mothers at Sorrento, Birmingham. II: selective during third trimester only. Br Med J 285, 592595.CrossRefGoogle ScholarPubMed
27.Agarwal, KN, Agarwal, DK, Agarwal, A, Rai, S, Prasad, R, Agarwal, S & Singh, TB (2000) Impact of the integrated child development services (ICDS) on maternal nutrition and birth weight in rural Varanasi. Indian Pediatr 37, 13211327.Google ScholarPubMed
28.Lechtig, A (1975) Effect of food supplementation during pregnancy on birth weight. Pediatrics 56, 508520.CrossRefGoogle Scholar
29.Prentice, AM, Cole, T, Ford, F, Lamb, W & Whitehead, R (1987) Increased birth weight after prenatal dietary supplementation of rural African women. Am J Clin Nutr 46, 912925.CrossRefGoogle ScholarPubMed
30.Tontisirin, K, Booranasubkajorn, U, Hongsumarn, A & Thewtong, D (1986) Formulation and evaluation of supplementary foods for Thai pregnant women. Am J Clin Nutr 43, 931939.CrossRefGoogle ScholarPubMed
31.Kaseb, F, Kimiagar, M, Ghafarpoor, M & Valaii, N (2002) Effect of traditional food supplementation during pregnancy on maternal weight gain and birthweight. Int J Vitam Nutr Res 72, 389393.CrossRefGoogle ScholarPubMed
32.Begum, N, Hussain, T, Afrid, B & Hamid, A (1991) Effect of supplementary feeding of pregnant women on birth weight of the newborn. Plant Foods Hum Nutr 41, 329336.CrossRefGoogle Scholar
33.Abdullah, M, Karim, R & Samad, QA (2000) Is the supplement a substitute or true supplementation to the usual diet?. In Results from the BINP Operations Research Project, vol. 2, p. 9. Dhaka: International Centre for Diarrhoeal Disease Research, Bangladesh.Google Scholar
34.World Health Organization (1995) Maternal anthropometry and pregnancy outcome: a collaborative project. Bull World Health Organ 73, Suppl., 198.Google Scholar
35.Kramer, MS (1993) Determinants of low birth weight: methodological assessment and meta-analysis. Bull World Health Organ 65, 663737.Google Scholar
36.Pelto, G, Dickin, K & Engle, P (1999) A Critical Link: Interventions for Physical Growth and Psychological Development: A Review. WHO/CHS/CAH/99.3. Geneva: Department of Child and Adolescent Health and Development, WHO.Google Scholar
37.Olson, R (1994) Developing Indicators that Predict Benefit from Prenatal Energy Supplementation. New York: Cornell University Press.Google Scholar
Figure 0

Table 1 BMI cut-offs and supplementation status: rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery

Figure 1

Table 2 Total (absolute) weight gain (kg) by registration month according to BMI and supplementation status group: rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery

Figure 2

Table 3 Pregnancy weight gain in relation to the programmatic targets (% of women achieving the target) by BMI and supplementation status group: rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery

Figure 3

Fig. 1 Monthly weight according to BMI (kg/m2) and supplementation status group (- - ●- -, <18·5 supplemented (sf); —▵—, <18·5 non-supplemented (nsf); — -□— -, ≥18·5 nsf; − −+− −, ≥18·5 sf) in month 3: rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery

Figure 4

Table 4 Birth weight (kg) by sex of the newborn according to BMI and supplementation status group: rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery

Figure 5

Table 5 Birth weight by BMI and supplementation status group: rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery

Figure 6

Table 6 Weight gain, birth weight and percentage of low birth weight (LBW) by level of chronic energy deficiency (CED): rural, non-smoking, pregnant women enrolled in the Bangladesh Integrated Nutrition Programme, studied from first presentation at the community nutrition centre until child delivery