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Trial of zinc supplements in relation to pregnancy outcomes, hematologic indicators, and T cell counts among HIV-1–infected women in Tanzania^1,2,3

¹ From the Departments of Nutrition (WWF, EV, GA, and DH) and Epidemiology (WWF and DH), Harvard School of Public Health, Boston, and the Departments of Community Health (GIM) and Microbiology and Immunology (SA and WU), Muhimbili University College of Health Sciences, Dar es Salaam, Tanzania

² Supported by the National Institute of Child Health and Human Development (NICHD R01 32257). Hermes Arzneimittel GmbH (Munich, Germany) donated the zinc and placebo tablets.

³ Address reprint requests to WW Fawzi, Department of Nutrition, Harvard School of Public Health, 665 Huntington Avenue, Boston, MA 02115. E-mail: mina{at}hsph.harvard.edu.

	ABSTRACT

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 
Background: In observational studies, the zinc status of HIV-infected persons has been associated with both positive and adverse clinical outcomes. Such endpoints may affect the risk of adverse birth outcomes among HIV-infected women.

Objective: We examined the effects of zinc supplements on birth outcomes, hematologic indicators, and counts of T lymphocyte subsets among 400 HIV-infected pregnant women.

Design: Eligible women between 12 and 27 wk of gestation were randomly assigned to daily oral supplementation with either 25 mg Zn or placebo between recruitment and 6 wk after delivery. All women received iron, folic acid, and multivitamin supplements irrespective of the experimental assignment.

Results: We observed no significant differences in birth weight, duration of gestation, or fetal and neonatal mortality between women in the zinc and placebo groups. Hemoglobin concentrations increased between baseline and 6 wk postpartum in both groups. However, the rise in hemoglobin over this period was significantly lower (P = 0.03) in the zinc group ( ± SD: 11.5 ± 17.9 g/L) than in the placebo group (15.2 ± 18.6 g/L). Similarly, the changes in red blood cell count and in packed cell volume over the same period were significantly lower in the zinc group (P < 0.01 and P = 0.01, respectively). Zinc had no effect on CD4⁺, CD8⁺, or CD3⁺ cell counts during the follow-up period.

Conclusion: Because of the lack of beneficial effects of zinc on adverse pregnancy outcomes and the likelihood of negative effects on hemoglobin concentrations, no compelling evidence exists to support the addition of zinc to prenatal supplements intended for pregnant HIV-infected women.

Key Words: Zinc • HIV infection • CD4⁺ cells • CD8⁺ cells • CD3⁺ cells • pregnancy • birth weight • preterm infants • small-for-gestational age infants • Tanzania

	INTRODUCTION

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 
Poor maternal zinc status is associated with adverse pregnancy outcomes in many observational studies and in early randomized trials with various methodologic limitations (1). In a well-designed placebo-controlled trial among African American women with low plasma zinc concentrations, prenatal zinc supplementation resulted in a significant increase in birth weight and in a longer duration of pregnancy (2). This result suggests that zinc supplementation may be beneficial in developing countries, where pregnant women may be more likely to have suboptimal zinc intakes. In a series of randomized trials in Asia and Latin America, however, supplementation had no beneficial effect on birth weight or the duration of pregnancy (3). It was noted that no trial has been carried out in African settings, where HIV infection is prevalent. Approximately 10–35% of pregnant women in southern Africa are HIV-infected; these women have a higher risk of adverse pregnancy outcomes, including fetal loss (4, 5), low birth weight, preterm birth, and intrauterine growth retardation (6). If zinc supplementation were beneficial for these outcomes, it would constitute a low-cost intervention.

Apart from its potential effects on pregnancy outcomes, the relations between zinc status and HIV-related outcomes are controversial. High zinc intakes were shown to be significantly associated with faster disease progression and higher risks of mortality among men in a prospective cohort study of asymptomatic HIV-infected men in the United States (7, 8). In another US study of HIV-positive men, however, plasma concentrations of zinc were inversely associated with mortality (9). Results from these observational studies are difficult to interpret; confounding of micronutrient status by other variables, such as stage of disease or access to health care, could provide alternative explanations for these observations.

We have shown that multivitamin supplements administered to HIV-infected women during pregnancy significantly decreased the risks of fetal death, preterm delivery, intrauterine growth retardation, and low birth weight and increased hemoglobin and CD4⁺ cell counts (10). It is important to examine the potential effects of additional inexpensive nutritional interventions, such as zinc supplementation, on these outcomes. We enrolled HIV-infected pregnant women in Dar es Salaam, Tanzania, to examine the efficacy of zinc supplements on birth outcomes, including fetal death, birth weight, and duration of pregnancy. We also examined the effect of the supplements on proxy indicators of HIV disease stage, namely hemoglobin concentrations and T lymphocyte subsets.

	SUBJECTS AND METHODS

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Recruitment and randomization
Pregnant women who were HIV-infected, who resided in Dar es Salaam at the time of the baseline interview, and who intended to stay in the city until delivery and for 1 y thereafter were eligible to enroll in this trial. Eligibility also required an estimated gestational age at randomization of between 12 and 27 wk. HIV-1 serostatus was ascertained from consenting women with the use of 2 enzyme-linked immunoassays (11), and discrepant results were resolved by Western Blot test (Genetic Systems, Redmond, WA). We used a two-stage informed consent procedure. Consent was initially sought for HIV testing as part of prenatal screening at antenatal clinics. HIV-positive women were not asked to enroll in the randomized trial immediately at the time of posttest counseling; instead, we sought their consent to be randomly assigned at a follow-up visit that was scheduled about 3 d later. In this manner, women were allowed time to cope with their positive HIV result and carefully consider participation in the trial, thereby decreasing the probability of dropout after enrollment. Randomization and all subsequent visits took place at a study clinic located at the Muhimbili National Hospital, Dar es Salaam, the main tertiary care hospital in Tanzania. Participants were recruited between September 2000 and October 2002, during which time the prevalence of HIV-1 among prenatal clinic attendees was 11.5%. The study protocol was approved by the Research and Publications Committee at Muhimbili University College of Health Sciences and the Institutional Review Board of the Harvard School of Public Health.

A randomization list was prepared in blocks of 20, and, at enrollment, each eligible woman was assigned to the next numbered bottle of regimen. Women received a daily oral dose of 1 of the 2 interventions from enrollment until the end of the study at 6 wk postpartum: 1) 25 mg Zn as zinc sulfate included in an effervescent citrus-flavored tablet or 2) a similarly constituted zinc-free placebo. All of the experimental tablets were identical in color, taste, and appearance. Women were instructed to dissolve one tablet in water every day. The resulting solutions were colorless and clear; the strong lemon-lime flavor of the solution effectively concealed the metallic taste of zinc and prevented the participants from determining which regimen they were assigned to. The doses used are safe during pregnancy (12). Both active and placebo regimens were prepared by Hermes Arzneimittel GmbH, Munich, Germany.

Standard of care
All women received ferrous sulfate (400 mg, equivalent to 120 mg ferrous Fe) and folate (5 mg) daily and prophylactic chloroquine phosphate (500 mg, equivalent to 300 mg chloroquine base) weekly as per the standard of prenatal care in Tanzania. Given our earlier findings on the benefits of multivitamin supplements among HIV-positive pregnant women (10), all women also received these supplements starting from the time of randomization until the time of delivery, irrespective of zinc treatment assignment. These supplements contained 20 mg thiamine, 20 mg riboflavin, 25 mg vitamin B-6, 100 mg niacin, 50 µg vitamin B-12, 0.8 mg folate, 500 mg vitamin C, and 30 mg vitamin E. As a measure against mother-to-child transmission of HIV, all women were offered a 200-mg dose of nevirapine to be taken at the onset of labor and 2 mg nevirapine/kg to their infant within 72 h of delivery (13).

Study procedures
At the first visit, information on the woman's age, education level, marital status, socioeconomic conditions, and obstetric history was collected. Also, at baseline and every month thereafter, a study physician conducted a full physical examination, and a research nurse gathered information on health problems during the prior month and obtained anthropometric measurements. Additional clinical assessment and continued counseling and support were provided as needed. The women who had psychosocial problems were referred to a full time research social worker, who had backup support from 2 psychiatrists. The women were asked to bring their regimen bottles at their monthly clinic visits. Nurses counted the remaining pills, and the women's supply was replenished. Compliance was evaluated on the basis of the number of tablets absent from the returned bottles divided by the total number of tablets the woman should have taken.

Laboratory results were available to the managing physicians, who prescribed treatment if indicated. Using specimens collected at the randomization visit, we carried out routine stool and urine examinations and obtained a complete blood count. Hemoglobin was measured with a CBC5 Coulter Counter (Coulter Corporation, Miami). The FACScount system (Becton-Dickinson, San Jose, CA) was used to obtain absolute counts of CD3⁺, CD4⁺, and CD8⁺ T lymphocyte subsets. Blood count and lymphocyte subsets analyses were repeated at 6 wk postpartum.

Women were encouraged to deliver at Muhimbili National Hospital, where research midwives were available 24 h a day. A research midwife weighed the infants to the nearest 10 g on a standard beam balance immediately after birth. She also measured birth length on an infant length board, measured head circumference with a nonstretchable tape (both to the nearest 0.1 cm), and weighed placentas after removal of blood clots. Gestational age was based on recall of the date of the last menstrual period at recruitment.

Women who did not come for their monthly appointments were visited at home when possible and were asked to come to the study clinic if their condition allowed. For women who traveled out of Dar es Salaam, we attempted to maintain contact with neighbors and relatives to collect information on the outcome of pregnancy, ie, whether the woman had a live birth or experienced a miscarriage or a stillbirth.

The primary endpoint of the trial was to examine the effect of zinc supplementation on hemoglobin concentrations between enrollment and 6 wk postpartum. A sample size of 150 subjects in each group was calculated to detect a difference in mean hemoglobin concentration based on a two-sample t test for the difference between 2 regimens. We enrolled an additional 100 women for a total of 400 women. An intent-to-treat analysis of treatment effects was used. Of the 400 women who were enrolled in the study, data on birth outcomes were not available for 3 women (2 in the zinc group and 1 in the placebo group) (Figure 1). Of the 397 women with known birth outcomes (miscarriage, still birth, or live birth), 366 had live births and were eligible for the analyses of birth weight and prematurity. We had a specific date of delivery for all 366 women; we did not have a birth weight for 8 of the infants because of delivery at home or at another medical facility. There were no differences in the availability of data on gestational age or birth weight between treatment groups. We examined the effects of the supplements on the continuous birth outcomes, namely gestational age and birth weight, length, head circumference, and placental weight. We also examined the effects of the supplements on the risk of miscarriage (defined as delivery before 28 wk of gestation), stillbirth (defined as delivery of a dead baby at or after 28 wk of gestation), and fetal death (all miscarriages and stillbirths). An infant born with any evidence of life, such as breathing or beating of the heart, was considered live born. Perinatal mortality included stillbirths and deaths in the first 7 d of life. Neonatal mortality was defined as deaths among live births in the first 28 d of life. Other categorical outcomes evaluated included a birth weight <2500 g (low birth weight; LBW), a birth weight <2000 g, preterm delivery (<37 wk of gestation), severe preterm delivery (<34 wk of gestation), and small-for-gestational age (SGA), which was defined as a birth weight less than the 10th percentile for gestational age on the basis of the reference of Brenner et al (14).

View larger version (27K): [in this window] [in a new window]   FIGURE 1. Trial profile. The numbers represent the number of subjects.

We examined the effect of the vitamin supplements on maternal T cells (absolute counts of CD4⁺, CD8⁺, and CD3⁺ cells), total white blood cells, total lymphocytes, and hematologic measurements (hemoglobin, red blood cell count, and packed cell volume). We observed no differences between treatment arms in the availability of data on these measurements. For each endpoint, we examined the difference between treatment groups at baseline and at 6 wk postpartum as well as the change between these visits.

We also assessed whether treatment effects on birth outcomes were modified by baseline CD4⁺ cell counts in 3 strata (<200, 200–499, and 500 cells/mm³) and within tertiles of baseline body mass index (BMI; defined as weight at baseline in kilograms divided by the square of height in meters). We used the Breslow-Day test for homogeneity (17) to examine whether treatment effects were significantly different between strata of potential modifiers. All P values reported are two-sided; statistical significance in this study was defined as P < 0.05. All statistical analyses were carried out using the SAS system (version 8.0; SAS Institute, Cary, NC).

	RESULTS

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We observed no significant differences at baseline between women in the zinc and placebo groups in sociodemographic characteristics (including age, parity, and marital status) or nutritional variables (including weight and midupper arm circumference) (Table 1). Women in the 2 regimen groups were also not significantly different with respect to baseline height, past history of adverse pregnancy outcomes, or malaria. The mean (±SD) duration of follow-up from the time of randomization was 8.6 ± 7.2 mo (median: 6.4 mo). Compliance with the study regimen was high between the time of randomization and delivery (94 ± 10%; median: 99%; interquartile range: 93–100%) and between the time of delivery and the end of follow-up at 6 wk postpartum (80 ± 27%; median: 92%; interquartile range: 69–100%). There were no significant differences in the duration of follow-up or compliance between the 2 experimental groups.

Table 2

Table 3

Table 4

Table 5

Table 6

	DISCUSSION

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Many other factors need to be considered when interpreting the results. There are no published data on plasma zinc status among adults in Tanzania; however, the women in the study were typical of other urban residents in Dar es Salaam with low intakes of animal products and are thus expected to suffer from zinc deficiency given the predominance of staple foods with a low bioavailability of zinc. Using national data on stunting rates and the adequacy of zinc in the national food supply, investigators of the International Zinc Nutrition Consultative Group estimate that 44% of Tanzanians are at risk of inadequate zinc intake (18). It is unlikely that the null effect noted on pregnancy outcomes was due to the concurrent existence of other micronutrient deficiencies given that we provided all women with a multivitamin supplement, including vitamin B complex and vitamins C and E. The latter supplement was provided given beneficial effects observed in an earlier trial among HIV-positive women in Dar es Salaam (10). The dose of zinc used was most likely adequate for having an effect, if such an effect existed. We chose a supplementation dose of 25 mg Zn/d because it was only slightly higher than the recommended dietary allowance for adult women in the United States of 15 mg (19, 20) and because studies using doses of zinc between 20 and 30 mg/d have not reported side effects (2, 12). It is possible that doses higher than those used in the above trials may have had a beneficial effect. However, the dose used is already within close range to the tolerable upper intake level for adults (40 mg). Women were enrolled in the study at their first prenatal visit, which was at 22 wk of gestation on average. Although it is possible that a longer duration of supplement use may have had a significant effect on pregnancy outcomes, the first antenatal visit in Dar es Salaam was relatively earlier than visits in other countries in sub-Saharan Africa (21), and we were interested in enrolling typical pregnant women in Dar es Salaam.

The lack of effect of zinc supplements on birth weight and duration of pregnancy does not agree with the results of a placebo-controlled trial conducted in pregnant African American women who were presumably mostly HIV-negative (2). In the latter group of women, who were apparently healthy but had plasma zinc concentrations below the median at enrollment, daily zinc supplements (25 mg, as used in the Tanzania trial) resulted in greater birth weights and head circumferences. This effect was observed predominantly in women with a BMI < 26. However, similar to our results, 6 of 7 trials in Asia and Latin America showed no effect of zinc supplementation on birth weight; a modest benefit was noted in the Chilean trial. None of the 7 trials indicated an effect on duration of gestation (3).

The effects of zinc (30 mg zinc sulfate) and iron (60 mg as ferrous fumarate) were examined in a recently completed large trial among pregnant women from Nepal; the women were randomly assigned to 1 of 5 groups: 1) folate; 2) folate and iron; 3) folate, iron, and zinc; 4) folate, iron, zinc, and multivitamins; and 5) placebo. All women received daily vitamin A supplements. None of the supplements had a significant effect on fetal loss or perinatal or neonatal deaths (22). Compared with the placebo group, the women who received iron and folate alone had a 14% reduction in LBW and a higher birth weight; however, the women who received zinc in addition to iron and folate had birth weights that were not significantly different from those of the placebo group. The authors attributed this apparent adverse effect of zinc to possible interference with iron absorption by zinc. Although the women who received zinc in our study in Tanzania had a nonsignificantly higher risk of fetal and early postpartum mortality, the study had limited statistical power to examine the efficacy of the supplements on these endpoints.

Concerns about the safety of zinc supplementation in HIV-infected persons were raised on the basis of findings from an observational study among asymptomatic HIV-infected men from the United States. Dietary zinc intake was associated with significantly higher risks of progression to AIDS (7) and mortality (8). In contrast, normalization of plasma zinc concentrations was associated with higher CD4⁺ cell counts among men who participated in another prospective cohort study (23). Low plasma zinc was also a significant predictor of AIDS mortality in a third study conducted in the United States (9). We found no effect of zinc supplementation on CD4⁺ or CD8⁺ cell counts among women in Tanzania. The effects of the supplements on viral load or clinical outcomes were not examined. We provided iron supplements to all of the women in our trial as per the standard of prenatal care in Tanzania. Iron deficiency anemia, a major public health problem among pregnant women in Tanzania and other developing countries, is a result of low prepregnancy stores, continued inadequate iron intake, malaria and hookworm infections, and increased iron requirements during pregnancy. Prenatal iron supplementation during pregnancy is routine practice given that it has been shown to raise hemoglobin concentrations (24, 25). Although all of the women in our trial, irrespective of experimental group, experienced an increase in hemoglobin and other hematologic indicators, this increase was significantly less among women who received zinc than in those who received placebo. It is possible that zinc supplementation resulted in a negative effect on iron absorption, as previously proposed (26). Women who participated in a randomized trial in Peru who received iron and folic acid alone or iron, folic acid, and zinc had similar hematologic responses (27). In 2 other trials, however, zinc supplementation was apparently associated with a reduced response to iron supplementation. In a trial in Mexico, pregnant women who received multimicronutrient supplements containing iron (60 mg as ferrous sulfate) and zinc (15 mg) experienced a slight decrease in hemoglobin concentrations compared with those who received iron only (28). In the perinatal trial from Nepal mentioned above, increases in hemoglobin concentrations were smaller in the group randomly assigned to receive folic acid plus iron and zinc than in the group who received folic acid and iron only (22). Concerns about a possible adverse effect of zinc supplements on iron absorption were also raised in 2 trials among children in Indonesia, in whom iron and zinc were less efficacious than was iron alone in improving hemoglobin concentrations and iron status (29, 30).

This was a community-based study of women receiving primary health care during pregnancy. The results are generalizable to HIV-infected women attending prenatal care clinics in Tanzania. In light of the lack of beneficial effects of zinc on adverse pregnancy outcomes and the potential for adverse effects of zinc supplementation on hematologic indicators, there is no compelling evidence to add zinc to prenatal supplements intended for pregnant women.

	ACKNOWLEDGMENTS

 
We thank the mothers and children and the field teams—including the nurses, midwives, supervisors, laboratory staff, and administrative staff—who made the study possible. We greatly appreciate the input of the following colleagues: Illuminata Ballonzi, Jenny Coley, Sylvia Kaaya, Roland Kupka, and Heavengton Mshiu. We also acknowledge the valuable encouragement and support of Ines Golly, previously at Hermes Arzneimittel GmbH, Munich, Germany. We thank the authorities at Muhimbili University College of Health Sciences, Muhimbili National Hospital, the City of Dar es Salaam Regional Health Authority, and the Tanzanian National AIDS Control Program for their institutional support.

WWF was the Harvard Principal Investigator of the project and contributed to the study design, study implementation, and data analyses and was primarily responsible for writing the draft of the manuscript. EV contributed to the data management in the field, data analyses, and writing of the paper. GIM contributed to the study design and the day-to-day running of the study in the field. GA supervised the data entry and management in the field. SA and WU oversaw the laboratory aspects of the study. DH contributed to the study design and provided advice on technical and practical issues during the implementation of the study. All authors contributed to the editing of the final version of the manuscript. None of the sponsors of the study had any role in the study design, data collection, data analysis, data interpretation, or writing of the report.

	REFERENCES

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1. Caulfield LE, Zavaleta N, Shankar AH, Merialdi M. Potential contribution of maternal zinc supplementation during pregnancy to maternal and child survival. Am J Clin Nutr 1998;68(suppl):499S-508S.[Abstract]
2. Goldenberg R, Tamura T, Neggers Y, et al. The effect of zinc supplementation on pregnancy outcome. JAMA 1995;274:463-8.[Abstract]
3. Osendarp SJ, West CE, Black RE. Maternal Zinc Supplementation Study Group. The need for maternal zinc supplementation in developing countries: an unresolved issue. J Nutr 2003;133(3):817S27S.
4. Gray RH, Wawer MJ, Serwadda D, et al. Population-based study of fertility in women with HIV-1 infection in Uganda. Lancet 1998;351:98-103.[Medline]
5. Urassa EJN, Kilewo C, Mtavangu SR, Mhalu FS, Mbena E, Biberfeld G. The role of HIV infection in pregnancy wastage in Dar es Salaam, Tanzania. J Obstet Gynaecol Cent Africa 1992;10:70-2.
6. Abrams EJ, Matheson PB, Thomas PA, et al. Neonatal predictors of infection status and early death among 332 infants at risk of HIV-1 infection monitored prospectively from birth. Pediatrics 1995;96:3:451-8.
7. Tang AM, Graham NM, Saah AJ. Effects of micronutrient intake on survival in human immunodeficiency virus type 1 infection. Am J Epidemiol 1996;143(12):1244-56.
8. Tang AM, Graham NM, Chandra RC, Saah AJ. Low serum vitamin B-12 concentrations are associated with faster human immunodeficiency virus type 1 (HIV-1) disease progression. J Nutr 1997;127:345-51.[Abstract/Free Full Text]
9. Lai H, Lai S, Shor-Posner G, Ma F, Trapido E, Baum MK. Plasma zinc, copper, copper:zinc ratio, and survival in a cohort of HIV-1-infected homosexual men. J Acquir Immune Defic Syndr 2001;27(1):56-62.
10. Fawzi WW, Msamanga GI, Spiegelman D, et al. Randomized trial of effects of vitamin supplements on pregnancy outcomes and T cell counts in HIV-1 infected women in Tanzania. Lancet 1998;351:1477-82.[Medline]
11. Urassa W, Matunda S, Bredberg Raden U, Mhalu F, Biberfeld G. Evaluation of the WHO human immune deficiency virus (HIV) antibody testing strategy for the diagnosis of HIV infection. Clin Diagn Virol 1994;2:1-6.[Medline]
12. Tsunenobu T, Goldenberg RL. Zinc nutriture and pregnancy outcome. Nutr Res 1996;16:139-81.
13. Guay LA, Musoke P, Fleming T, et al. Intrapartum and neonatal single-dose nevirapine compared with zidovudine for prevention of mother-to-child transmission of HIV-1 in Kampala, Uganda: HIVNET 012 randomised trial. Lancet 1999;354:795-802.[Medline]
14. Brenner WE, Edelman DA, Hendricks CH. A standard of fetal growth for the United States of America. Am J Obstet Gynecol 1976;126:555-64.[Medline]
15. Clopper CJ, Pearson ES. The use of confidence or fiducial limits illustrated in the case of the binomial. Biometrika 1934;26:404-13.[Free Full Text]
16. Wilcoxon F. Individual comparisons by ranking methods. Biometrics 1945;1:80-3.
17. Breslow NE, Day NE. Statistical methods in cancer research. Vol 1. The analysis of case-control studies. Lyon, France: International Research on Cancer, 1980:143.
18. International Zinc Nutrition Consultative Group (IZiNCG). Assessment of the risk of zinc deficiency in populations. In: Hotz C, Brown K, eds. Assessment of the risk of zinc deficiency in populations and options for its control. Food Nutr Bull 2004;25:S130-62.
19. Hathcock JN. Vitamins and minerals: efficacy and safety. Am J Clin Nutr 1997;66:427-37.[Abstract/Free Full Text]
20. National Research Council. Recommended dietary allowance. Washington, DC: National Academy Press, 1989.
21. Demographic and Health Surveys. 2003. Internet: http://www.measuredhs.com (accessed 18 May 2004).
22. Christian P, West KP, Khatry SK, et al. Effects of maternal micronutrient supplementation on fetal loss and infant mortality: a cluster-randomized trial in Nepal. Am J Clin Nutr 2003;78(6):1194-202.[Abstract/Free Full Text]
23. Baum MK, Shor-Posner G, Lu Y, et al. Micronutrients and HIV-1 disease progression. AIDS 1995;9:1051-6.[Medline]
24. Sloan NL, Jordan E, Winikoff B. Effects of iron supplementation on maternal hematologic status in pregnancy. Am J Public Health 2002;92:288-93.[Abstract/Free Full Text]
25. Mungen E. Iron supplementation in pregnancy. J Perinat Med 2003;31(5):420-6.
26. Solomons NW, Ruz M. Zinc and iron interaction: concepts and perspectives in the developing world. World Nutr Res 1997;17:177-85.
27. Zavaleta N, Caulfield LE, Garcia T. Changes in iron status during pregnancy in Peruvian women receiving prenatal iron and folic acid supplements with or without zinc. Am J Clin Nutr 2000;71(4):956-61.
28. Ramakrishnan U, Neufeld LM, Gonzalez-Cossio T, et al. Multiple micronutrient supplements during pregnancy do not reduce anemia or improve iron status compared to iron-only supplements in semirural Mexico. J Nutr 2004;134(4):898-903.
29. Dijkhuizen MA, Wieringa FT, West CE, Martuti S, Muhilal. Effects of iron and zinc supplementation in Indonesian infants on micronutrient status and growth. J Nutr 2001;131(11):2860-5.
30. Lind T, Lonnerdal B, Stenlund H, et al. A community-based randomized controlled trial of iron and zinc supplementation in Indonesian infants: interactions between iron and zinc. Am J Clin Nutr 2003;77(4):883-90.

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This Article Abstract Full Text (PDF) Purchase Article View Shopping Cart Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Fawzi, W. W Articles by Hunter, D. Search for Related Content PubMed PubMed Citation Articles by Fawzi, W. W Articles by Hunter, D. Agricola Articles by Fawzi, W. W Articles by Hunter, D.