Effects of iron supplementation and anthelmintic treatment on motor and language development of preschool children in Zanzibar: double blind, placebo controlled study

doi:10.1136/bmj.323.7326.1389

BMJ 2001;323:1389 ( 15 December )

Papers

Effects of iron supplementation and anthelmintic treatment on motor and language development of preschool children in Zanzibar: double blind, placebo controlled study

Rebecca J Stoltzfus, associate professor ^a, Jane D Kvalsvig, director ^c, Hababu M Chwaya, director of preventive services ^d, Antonio Montresor, medical officer ^e, Marco Albonico, scientific secretary ^f, James M Tielsch, professor ^b, Lorenzo Savioli, coordinator ^e, Ernesto Pollitt, professor of human development and behaviour research ^g.

^a Center for Human Nutrition, Department of International Health, Bloomberg School of Public Health, Johns Hopkins University, Baltimore, MD 21205-2179, USA, ^b Department of International Health, Bloomberg School of Public Health, ^c Child Development Programme, University of Natal, Congella 4013, South Africa, ^d Ministry of Health, Zanzibar, Tanzania, ^e Parasitic Diseases and Vector Control, World Health Organization, 1211 Geneva 27, Switzerland, ^f Ivo de Carneri Foundation, 20129 Milan, Italy, ^g Department of Pediatrics, School of Medicine, University of California, Davis, CA 95616, USA

Correspondence to: R J Stoltzfus rstoltzf{at}jhsph.edu

Abstract

Top
Abstract
Introduction
Participants and methods
Results
Discussion
References

Objective: To measure the effects of iron supplementationand anthelmintic treatment on iron status, anaemia, growth, morbidity,and development of children aged 6-59months.
Design: Double blind, placebo controlled randomisedfactorial trial of iron supplementation and anthelmintictreatment.
Setting: Community in Pemba Island,Zanzibar.
Participants: 614 preschool children aged 6-59months.
Main outcome measures: Development of language and motor skills assessedby parental interview before and after treatment in age appropriatesubgroups.
Results: Before intervention, anaemia was prevalentand severe, and geohelminth infections were prevalent and light $---$ Plasmodiumfalciparum infection was nearly universal. Iron supplementationsignificantly improved iron status, but not haemoglobin status.Iron supplementation improved language development by 0.8 (95%confidence interval 0.2 to 1.4) points on the 20 point scale.Iron supplementation also improved motor development, but thiseffect was modified by baseline haemoglobin concentrations (P=0.015for interaction term) and was apparent only in children with baselinehaemoglobin concentrations <90 g/l. In children with a baselinehaemoglobin concentration of 68 g/l (one standard deviation belowthe mean value), iron treatment increased scores by 1.1 (0.1 to2.1) points on the 18 point motor scale. Mebendazole significantlyreduced the number and severity of infections caused by Ascarislumbricoides and Trichuris trichiura, but not by hookworms. Mebendazoleincreased development scores by 0.4 ( $-$ 0.3 to 1.1) points on themotor scale and 0.3 ( $-$ 0.3 to 0.9) points on the languagescale.
Conclusions: Iron supplementation improved motor and languagedevelopment of preschool children in rural Africa. The effectsof iron on motor development were limited to children with moresevere anaemia (baseline haemoglobin concentration <90 g/l). Mebendazolehad a positive effect on motor and language development, but thiswas not statisticallysignificant.

What is already known on this topic
Iron is needed for development and functioning of the human brain

Anaemic children show developmental delays, but it is not yet clear whether iron deficiency causes these deficits or whether iron supplementation can reverse them

Helminth infections in schoolchildren are associated with cognitive deficits, but few studies have been made of helminth infection and early child development

What this study adds
Low doses of oral iron supplementation given daily improved language development in children aged 1-4 years in Zanzibar

Iron supplementation improved motor development, but only in children with initial haemoglobin concentrations below 90 g/l

The effects of routine anthelmintic treatment on motor and language milestones were positive, but non-significant, with our sample size

	Introduction

Top Abstract Introduction Participants and methods Results Discussion References

Iron deficiency anaemia is associated with comparatively poor performance in tests of mental and motor development in infantsand toddlers and of intelligence and cognitive function in preschooland school children.^1-4 In young children aged 12-18 months,one randomised trial found that development improved in childrentreated for iron deficiency anaemia⁵; however, most quasi-experimentalstudies in children of a similar age have shown no such benefit.⁶Prospective trials have also produced discrepant findings. ⁷ ⁸

A causal link between iron deficiency anaemia and delays in child development may be mediated by a variety of direct or indirectpathways; the most obvious are associated decreases in haemoglobinconcentration and oxygen delivery to tissues. Alternative theoriesrelate to reductions in cerebral iron concentrations, includinghypomyelination and impaired dopaminergic function.^9-11

Kvalsvig et al found that geohelminth infections impair children's cognition and learning,¹² but the focus of their workwas in schoolchildren. Associations between geohelminth infectionand mental performance in schoolchildren have been reported,^12-16but results from randomised trials have been inconclusive.¹⁷We are not aware of published investigations of the relation betweengeohelminth infections and development in preschoolchildren.

We report measures of child development from a subsample of children of an appropriate age enrolled in a double blind placebocontrolled randomised factorial trial of iron supplementationand anthelmintic treatment. The trial was designed to measurethe effects of iron supplementation and anthelmintic treatmenton iron status, anaemia, growth, morbidity, and development ofchildren aged 6-59 months at the start of the trial. In studiesof the relation between iron concentrations and child development,our trial is unique because it included a considerable numberof children with moderate to severe anaemia, and it was carriedout in a population exposed to numerous health risks, includingyear round of Plasmodium falciparum malaria and geohelminths,and widespreadmalnutrition.

Participants and methods

Top
Abstract
Introduction
Participants and methods
Results
Discussion
References

Location
The study was conducted in Kengeja villageon the island of Pemba north of Zanzibar. The environment is rural,with fishing and farming as the main occupations. P falciparumis holoendemic and transmitted throughout the year, and P malariaeis also present. A number of helminths are highly endemic in thispopulation, including two hookworm species (Ancylostoma duodenaleand Necator americanus), Ascaris lumbricoides, Trichuris trichiura,and Schistoma haematobium.

Study sample and randomisation
Before the study, we estimated the samplesize that was needed to be recruited to show a 5 g/l differencein mean haemoglobin response in two age subgroups, with $alpha$ =0.05and $beta$ =0.10 as 640 children. Prior power calculations were notmade for developmental outcomes, as the rating scales were developedspecifically to be filled out by parents in thisstudy.

During June and July 1996, a census was conducted in Kengeja and a database of all children whose age was reported by theirparents as 3-56 months was created (the trial was planned to beginthree months later). The database contained 684 children from451 households, all of whose parents gave informed consent toparticipate in the census and the trial; these parents were invitedto enter their children in thetrial.

Households, rather than children, were randomly allocated to receive iron or placebo, so that mothers of siblings would haveto manage only one bottle of supplement. Households were groupedinto three strata $---$ those with children <36 months, those with children $>=$ 36 months, and those with one or more child in each age subgroups.Within these strata, households were randomly allocated to receiveiron or placebo in blocks of four. Random allocation to mebendazoleor mebendazole placebo was carried out by child, stratified byiron allocation and household, in blocks offour.

Of the 684 children identified in the census and randomised to treatment, 614 attended the baseline clinic at the local primaryhealthcare centre during September 1996. In total, 538 childrencompleted the follow up period of 12 months, including the finalclinical assessment during September1997.

Developmental data were collected in August 1996 and August 1997, one month before each clinical assessment. The languagedevelopment scale was appropriate for children from 12 to 48 months,and 417 children between these ages entered the trial. Of these,397 children were assessed in August 1996, and 359 children $---$ thelanguage scale cohort $---$ were assessed again in August 1997. Themotor development scale was appropriate only for children between12 and 36 months, and 293 children between these ages enteredthe trial. Of these, 267 were assessed in August 1996, and 255children $---$ the motor scale cohort $---$ were assessed again in August1997. The motor scale cohort is a younger subset of the languagescale cohort. The randomisation and retention of children in thetrial is shown in figure 1 .

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Fig 1. Randomisation of preschool children in Zanzibar to iron and mebendazole or placebo, and retention in trial

The 58 children eligible by age for inclusion in the language scale cohort who were not followed up were similar to the 359who completed the study in sex, age, and other characteristics.The children who were not followed up had slightly better baselinehaemoglobin values than those who were (88.6 (SD 14.7) g/l v 85.6(14.7) g/l, P=0.15).

Interventions

Iron treatment
Iron treatment consisted of a ginger flavouredliquid supplement containing 20 mg/ml ferrous sulphate, or anidentical placebo (both supplied by Alpharma USPD, Baltimore).The supplement was packaged in 50 ml bottles, with childproof1 ml dropper caps. Each bottle label included one of six batchnumbers, three of which corresponded to iron and three to placebo;these treatment codes were assigned by Alpharma USPD and werekept in sealed envelopes in Baltimore and Zanzibar. At the baselineclinic, each mother was trained on how to give a 0.5 ml dose (equivalentto 10 mg iron) to her children, and she was instructed to givethis dose daily for the next year. During the 12 month trial,study staff visited each mother weekly to ask how many days inthe past week she had given the supplement to her child and todeal with any compliance problems, using a problem solving algorithm.The study staff member also replenished the supplement as needed.The potency of the supplement was monitored by the manufacturer,and it was found to retain 80% of its potency after being storedfor 12 months at roomtemperature.

Despite the childproof packaging, two children each consumed a large portion of a bottle of iron supplement. These childrenwere monitored closely for toxic sequelae (none of which werefound), and they were included in the analyses. After these events,the amount of iron supplement in each bottle was reduced to 25ml so that the total amount of elemental iron in each bottle wasreduced from 1000 mg to 500mg.

Anthelmintic treatment
Anthelmintic treatment consisted of 500 mgmebendazole in an orange flavoured chewable tablet, or an identicalplacebo tablet (Pharmamed, Zejtun). The pills were packaged insix bottles with unique treatment codes, three corresponding tomebendazole and three to placebo. The treatment codes were assignedby one study investigator, and they were kept in sealed envelopesin Baltimore and Zanzibar. After the baseline clinic, study staffmade home visits to all children every three months to give theanthelmintictreatment.

Oral iron
Children with severe anaemia (haemoglobinconcentrations <70 g/l) at the baseline clinic were treated withoral iron 60 mg/day for 30 days, but they were also given theirrandomly allocated iron. The total iron dosage for these severelyanaemic children for the first month of the study, therefore,was 60 mg/day or 70 mg/day. These children were also given mebendazole(500 mg) in place of their randomly allocated anthelmintic treatment,but they subsequently received their randomly allocated treatmentat the baseline clinic. Parents of these children were informedthat their child was severely anaemic and the treatments givenwere explained. These children were included in the subsequentanalyses on an intention to treatbasis.

Clinical assessments
Parents were given a container in which totake a small sample of their child's faeces to the baseline clinic.Faecal samples were stained on the same day and examined withinone hour by the Kato-Katz method.¹⁸ The numbers of helmintheggs in faecal samples were counted for 591/614 (96%) of studychildren.

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Table 1. Mean item scores on language and motor scales for preschool children in Zanzibar

The children's weights were measured to the nearest 0.1 kg using a digital scale (Seca, Columbia, NY). Length was measuredin triplicate to the nearest 0.1 cm using a wooden length board(Shorr Productions, Olney). Age was ascertained from the birthcertificate or, in one case where the birth certificate was missing,by the parent's report. Anthropometric z scores were computedwith Anthro version 3.0 (CDC, Atlanta). Stunting was defined asheight for age z score < $-$ 2.0, wasting as weight for height z score< $-$ 2.0, and underweight as weight for age z score < $-$ 2.0. Motherswere asked to recall all foods and drinks, including breast milk,given to the child in the previous 24hours.

Blood samples (3 ml) were collected by venipuncture into a Vacutainer tube (BD, Franklin Lakes). Drops of whole blood weredispensed immediately to make a blood film that was used to determinehaemoglobin concentration (HemoCue haemoglobinometer; HemoCue,Angelhom) and erythrocyte protoporphyrin concentration (haematofluorometer;Aviv Biomedical, Lakewood, NJ). The remaining blood was centrifugedat 1000 × g for 20 minutes at room temperature and the serum wascollected. Thin blood films were fixed with ethanol and stainedwith Giemsa, and the numbers of malaria parasites were countedagainst leukocytes using standard methods.¹⁹ Serum samples werestored in Pemba at $-$ 10°C for up to three months, and they werethen transported in liquid nitrogen to Baltimore, where they werestored at $-$ 70°C until they were analysed. Ferritin was assayedusing a fluorescence-linked immunoassay (DELFIA system; Wallac,Gaithersburg). The average coefficient of variation for this assaywas 3% (range 0.2%-7.0%).

Developmental assessments
Motor and language development were assessedby the parents reporting gross motor and language milestones $---$ amethod known to have considerable accuracy and sensitivity foridentifying developmental delays.^20-23 Mothers were asked if theirchild could do each of the tasks listed in table 1 ; one pointwas scored for each item that the mother reported the child coulddo. When the scales were being constructed, a wide ranging collectionof items was taken from a variety of sources, including the Griffithsand McCarthy scales of motor and mental development. ²⁴ ²⁵ Toensure reliability of the scales, the number of items was reducedthrough a series of piloting procedures, initially in Zulu ina rural African community (Umbumbulu, KwaZulu-Natal, South Africa)and then in Kiswahili in a peri-urban community in Pemba(Mkoroshoni).

The data collection team consisted of Pemban men and women whose first language was Kiswahili. To forestall any tendency byparents to over-rate or underrate their child's ability, carewas taken to secure parental cooperation in providing accurateresponses and the child was asked to demonstrate the ability toperform some of the items. The procedures used to check the motoritems were similar to those used in the McCarthy scales.²⁵

A preliminary analysis established that the scales were appropriate to the age range and were sensitive to changes over timewithin the study environment. At the 12 month retest, the meanmotor score for the children in the group who were now aged 36-48months was nearing asymptote, and children older than 48 monthsat retest were excluded from further analysis on this measure.The language score neared asymptote at a later stage, and childrenwho were 60 months and over at retest were excluded from furtherlanguage development analysis. The scales were tested for internalconsistency using Cronbach's $alpha$ (table 1).²⁶

Analysis of treatment effects
We compared the characteristics of childrenin the motor and language cohorts by treatment group (table 2).Several characteristics (sex, breast feeding, stunting and developmentalscores), were unbalanced between the groups.

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Table 2. Characteristics of children in Zanzibar aged 12-48 months at baseline with complete developmental assessments at baseline and after treatment. Values are numbers (percentages) unless otherwise specified

Other general characteristics, baseline iron status, baseline developmental score, and baseline helminth infections were testedfor significance using P<0.10 as the criterion for inclusion inthe comparison $---$ only age, sex, and baseline developmental scoremet this criterion. When covariates were included, the resultschanged only slightly; however, we present the adjusted resultsbecause they provide the most accurate estimates of treatmenteffects. An iron with mebendazole (iron-mebendazole) treatmentinteraction term was tested in all models, but it did not approachstatistical significance in any model. To look at variables thatmight modify the effects of treatment on developmental outcomes,we tested the interaction term of treatment (iron or mebendazole)with each variable. Finally, we repeated the final models formotor and language scores, excluding those children who were severelyanaemic (and treated therapeutically) at baseline, to determinewhether inclusion of these children attenuated the randomisedtreatment effects. In final regressions, we used generalised estimationequations to account for the intrahousehold clustering inducedby randomising the iron treatment by household. ²⁷ ²⁸ Statisticalanalyses were conducted in SYSTAT 7.0 for Windows (SPSS,Chicago).

The study was approved by the ethical review boards of Johns Hopkins University School of Hygiene and Public Health, the WorldHealth Organization, and the Ministry of Health ofZanzibar.

	Results

Top Abstract Introduction Participants and methods Results Discussion References

The characteristics of children in the language scale cohort are shown in table 2. In total, 101/358 (28%) of participantsaged 12-48 months were breast fed at the time of the study. Breastfeeding was common in children aged 12-23 months (96/121, 79%)and rare in children $>=$ 2 years (5/237, 2%). Stunted growth wascommon, while wasting was relatively uncommon. P falciparum malarialinfection was nearly universal. Most characteristics were similaramong the treatment groups, but more children who received ironthan those who received the iron placebo had stunted growth atbaseline (76/179, 43% v 58/171, 34%).

At baseline, anaemia was prevalent and severe. In total, 347 of 359 (97%) children were anaemic by international standards(haemoglobin <110 g/l) and 54/305 (18%) were severely anaemic(haemoglobin <70 g/l). Haemoglobin concentration was stronglyand positively associated with age at baseline.²⁹ An overallincrease in haemoglobin was seen in all treatment groups; thiswas mostly attributable to the increased age of the children atfollow up. Erythrocyte protoporphyrin concentrations were high,and they were strongly associated with haemoglobin concentrations,²⁹suggesting that iron deficiency was prevalent. Serum ferritinvalues were higher than expected given the prevalence of anaemiaand the raised erythrocyte protoporphyrin concentrations; thisprobably reflects the prevalence of malaria and other subclinicalinfections.²⁹ Iron supplementation significantly increased serumferritin and erythrocyte protoporphyrin concentrations, but ithad little impact on haemoglobin concentrations (table 3). Theeffect of iron treatment on haemoglobin concentration was greater(but still not statistically significant) in children who weremore anaemic at the start: 0.2 ( $-$ 4.8 to 5.2) g/l in children withbaseline haemoglobin concentrations $>=$ 80 g/l compared with 5.4( $-$ 2.7 to 13.1) g/l in those with initial haemoglobin <80 g/l.Mebendazole had no impact on indicators of iron status, exceptto decrease the average concentrations of serum ferritin (perhapsby reducing the gut inflammatory response secondary to helminthinfection).

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Table 3. Anaemia and iron status before and after treatment in preschool children. Values are numbers (percentages) unless otherwise specified

Helminth infections were prevalent (table 2), but of light intensity (number of eggs/g faeces; table 4). Regular treatmentwith mebendazole was highly efficient in reducing the prevalenceand intensity of A lumbricoides infection (table 4). It was lessefficacious against T trichiura, although the intensity of thisinfection was still greatly reduced in the participants who receivedmebendazole. The effect of mebendazole on hookworm prevalenceand intensity three months after treatment was not statisticallysignificant.

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Table 4. Helminth infections before and after treatment in preschool children. Values are numbers (percentages) unless otherwise specified

Baseline scores on the motor and language scales were strongly associated with age (motor r=0.691, P<0.001; language r=0.741,P<0.001) and with each other. After age was controlled for, thepartial correlation of baseline motor score with language scorewas 0.563 (P<0.001). There was also a strong within-child correlationof baseline score to the score at the end of the trial (motorr=0.578, P<0.001; language r=0.642, P<0.001). After age was adjustedfor, haemoglobin was positively associated with motor scores (partialcorrelation=0.175, P=0.005) and language scores (partial correlation=0.158,P=0.003) (fig 2).

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Fig 2. Relation of pretreatment language and motor scores to haemoglobin concentration. Points are age adjusted least squares means with standard errors

When adjusted for age, the association of erythrocyte protoporphyrin concentration with motor score was weaker than that ofhaemoglobin concentration (partial correlation= $-$ 0.113, P=0.071),and it became non-significant when haemoglobin concentration wasalso included in the model. In contrast, when we adjusted forage, the association of protoporphyrin concentration with languagescore was nearly as strong as that of haemoglobin concentration(partial correlation= $-$ 0.134, P=0.01), and it remained marginallysignificant (P=0.065) when haemoglobin concentration was alsoincluded in the model. Each heme increment in protoporphyrin of100 µmol/mol was associated with a decrease in language scoreof 0.4 (95% confidence interval 0 to 0.8) points. Serum ferritinconcentration was not associated with motor or language scores.After we adjusted for age, the presence of helminth infectionsat baseline (prevalence of each worm, intensity of each worm,or the number of worm species present) was not associated withbaseline motor or languagescores.

The adjusted main effects of iron and mebendazole treatments on motor scores were positive, but they were not statisticallysignificant. However, there was a significant interaction betweenbaseline haemoglobin concentration and iron treatment (P=0.015).Iron treatment was associated with higher post-treatment motorscores only in children with low baseline haemoglobin. There wasa benefit from iron treatment in children with baseline haemoglobinconcentrations <90 g/l, and this was statistically significantat concentrations <80 g/l. In children with baseline haemoglobinof 68 g/l (one standard deviation below the mean value), the irontreatment effect was 1.1 (0.1 to 2.1) points on the 18 point motorscale. The adjusted effect of mebendazole treatment on motor scoresin this final model was 0.44 ( $-$ 0.22 to 1.10); this was not significantlymodified by the concentration of haemoglobin at baseline or byirontreatment.

Because baseline haemoglobin was strongly related to age and erythrocyte protoporphyrin, we compared multivariate models thatincluded iron with haemoglobin (iron-haemoglobin), iron-protoporphyrin,and iron-age interaction terms. Baseline protoporphyrin did notmodify the iron treatment effect. The iron-age interaction termwas statistically significant if the iron-haemoglobin interactionwas not included in the model; younger children benefited mostfrom iron supplementation. The iron-haemoglobin interaction wasstatistically stronger and produced a higher model R² value than the iron-ageinteraction.

The adjusted main effects of iron and mebendazole treatments on language scores were positive, and the effect of iron treatmentwas significant (P=0.011) (table 5). Although children who receivediron and mebendazole treatments had the highest final languagescores, the iron-mebendazole interaction term did not approachsignificance (P=0.48). There was no significant interaction betweeneither treatment and any characteristics of the children includedin table 2. The effect of iron treatment was similar for allchildren within the wide range of haemoglobin concentrations andother measured characteristics in the study sample.

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Table 5. Language scores in four treatment groups with differences in scores showing effects of treatment

We repeated the final multivariate regression models for motor and language scores, excluding those children with baselinehaemoglobin concentrations <70 g/l who were treated therapeuticallyfor the first month of the trial. In the motor cohort (204 childrenwithout severe anaemia), the iron-haemoglobin interaction termwas marginally significant (P=0.067), although its magnitude wassimilar to that of the full cohort. The weakening in statisticalsignificance can be attributed to the smaller sample size andthe fact that we censored the cohort in the range of haemoglobinconcentrations where the iron treatment effect wasgreatest.

In the language cohort (298 children without severe anaemia), exclusion of severely anaemic children resulted in an effectof iron treatment that was larger and more statistically significantdespite the smaller sample size (0.9 (0.2 to 1.5) scale units).This is consistent with the lack of haemoglobin-iron interactionin this model and suggests that including children who were therapeuticallytreated with iron at the start of the trial in the placebo groupdiluted our measurement of the effect of iron supplementationat low doses on a long termbasis.

Discussion

Top
Abstract
Introduction
Participants and methods
Results
Discussion
References

Several distinct features characterise this study of the effects of iron and anthelmintic treatments on child development.Anaemia in the study children was prevalent and more severe thanthat reported in any published study with similar objectives ofwhich we are aware. P falciparum malaria was endemic and contributedconsiderably to the degree of anaemia observed.²⁹ The randomised,placebo controlled, community based intervention design providesa strong basis for causalinference.

Effects of iron and anaemia on motor and language development
Our results shed partial light on the contributionsof anaemia and iron deficiency as causes of developmental delays.At baseline, motor scores were more strongly related to haemoglobinconcentrations than to erythrocyte protoporphyrin concentrations(an indicator quite specific to iron deficiency in this population).²⁹Iron supplementation improved motor development only in childrenwith very low baseline haemoglobin concentrations. A similar plateauin the association of haemoglobin with motor development was recentlyfound in children in the United Kingdom.³⁰ It is possible thatthe aetiology of anaemia changes with its severity, with moresevere anaemia being more strongly related to iron deficiency.There is some evidence for this in our data, as the effect ofiron treatment was lower in children with baseline haemoglobinconcentrations $>=$ 80 g/l than <80 g/l, suggesting that the effectof iron on motor development was mediated through improved haemoglobinconcentrations. The younger age of children with more severe anaemiamay have been an important determinant of their increased responsetoiron.

In contrast, language scores at baseline were strongly related to haemoglobin and erythrocyte protoporphyrin concentrations.Iron supplementation improved language development across a widerange of baseline haemoglobin concentrations, despite the smalleffect of iron treatment on haemoglobin in all but the most severelyanaemic children. This suggests that the effect of iron on languagedevelopment was mediated through mechanisms that are independentof haemoglobinconcentration.

Effects of anthelmintic treatment on motor and language development
We are not aware of previous reports on theeffect of anthelmintic treatment on motor and language developmentof children in this young age range. In this study, children whoreceived mebendazole had slightly better developmental scores,but the size of the effect was small and did not approach statisticalsignificance. The power of our study to detect a statisticallysignificant difference was <80% for effect sizes smaller than1 unit on our scales. During the 12 month study period, the mostrapid increases in motor and language development scores werein the children aged 12-24 months. This group had low prevalencesof the target parasite species, making it less likely that wewould detect the effects of mebendazole treatment. At baseline,only 6% of the children aged 12-24 months were infected with allthree helminth species compared with 39% of the children aged37-48months.

The lack of effect of mebendazole on motor and language development might be explained by the drug's relatively low cure ratesfor two of the species $---$ different species having different effectson development $---$ or by a causal relation too small to be detectedwith our methods or not present at all. The potential public healthbenefits of treating young children for worms include immunologicaland nutritional outcomes as well as motor and language development,and additional research isneeded.

Summary
Our results highlight that in African communitiesin which malaria is endemic there are severely anaemic childrenwho are not detected by the current healthcare system and whoseem to be at considerable risk of poor development. Identifyingthe optimal treatment and follow up regimen for severely anaemicchildren is a high priority and, although the best dose and durationneeds to be clarified, long term treatment with oral iron maybe an importantcomponent.

Acknowledgments

Contributors: All authors except EP were involved in the conception and design of the study. All authors were involved in the analysis and interpretation of data and drafting or revising the article. RS is the guarantor of the paper.

Footnotes

Funding: Thrasher Research Fund, Cooperative Agreement #HRN-A-00-97-00015-00 between the Johns Hopkins University and theUnited States Agency for International Development, and AlpharmaUSPD, Baltimore,MD.

Competing interests: Nonedeclared.

References

Top
Abstract
Introduction
Participants and methods
Results
Discussion
References

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19. Trape JF. Rapid evaluation of malaria parasite density and standardization of thick smear examination for epidemiological investigations. Trans R Soc Trop Med Hyg 1985; 79: 181-184[CrossRef][Medline].

20. Glascoe FP, Sandler H. Value of parents' estimates of children's developmental ages. J Pediatr 1995; 127: 831-835[CrossRef][Medline].

21. Ireton H, Glascoe FP. Assessing children's development using parents' reports. The Child Development Inventory. Clin Pediatr (Phila) 1995; 34: 248-255.

22. Cowen EL, Work WC, Wyman PA, Jarrell DD. Relationships between retrospective parent reports of developmental milestones and school adjustment at ages 10 to 12 years. J Am Acad Child Adolesc Psychiatry 1994; 33: 400-406[CrossRef][Medline].

23. Knobloch H, Stevens F, Malone A, Ellison P, Risemberg H. The validity of parental reporting of infant development. Pediatrics 1979; 63: 872-878[Abstract/Free Full Text].

24. Griffiths R. The abilities of young children: a comprehensive system of mental measurement for the first eight years of life. London: Child Development Research Centre, 1970.

25. McCarthy D. Manual for the McCarthy scales of children's abilities. New York: Psychological Corporation, 1972.

26. DeVellis R. Scale development. Theory and applications. California: Sage, 1991.

27. Zeger SL, Liang KY, Albert PS. Models for longitudinal data: a generalized estimating equation approach. Biometrics 1988; 44: 1049-1060[CrossRef][Medline].

28. Liang KY, Zeger SL. Longitudinal data analysis using generalized linear models. Biometrika 1986; 73: 13-22[Abstract/Free Full Text].

29. Stoltzfus RJ, Chwaya HM, Montresor A, Albonico M, Savioli L, Tielsch J. Malaria, hookworms and recent fever are related to anemia and iron status indicators in 0- to 5-y old Zanzibari children and these relationships change with age. J Nutr 2000; 130: 1724-1733[Abstract/Free Full Text].

30. Sherriff A, Emond A, Bell JC, Golding J. Should infants be screened for anaemia? A prospective study investigating the relation between haemoglobin at 8, 12, and 18 months and development at 18 months. Arch Dis Child 2001; 84: 480-485[Abstract/Free Full Text].

(Accepted 12 July 2001)

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Lost Causes and Side Effects: George Malcolm Morley
bmj.com, 17 Dec 2001 [Full text]
Allocation of placebo cannot be justified for iron deficiency anaemia.: Martin D Tobin
bmj.com, 21 Dec 2001 [Full text]
Anemia, Jaundiced, caused by inadequate training of birth medical persons.: Donna Young
bmj.com, 13 Jul 2003 [Full text]

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18.	Ash LR, Orihel TC, Savioli L. Bench aids for the diagnosis of intestinal parasites. Geneva: World Health Organization, 1994.
19.	Trape JF. Rapid evaluation of malaria parasite density and standardization of thick smear examination for epidemiological investigations. Trans R Soc Trop Med Hyg 1985; 79: 181-184[CrossRef][Medline].
20.	Glascoe FP, Sandler H. Value of parents' estimates of children's developmental ages. J Pediatr 1995; 127: 831-835[CrossRef][Medline].
21.	Ireton H, Glascoe FP. Assessing children's development using parents' reports. The Child Development Inventory. Clin Pediatr (Phila) 1995; 34: 248-255.
22.	Cowen EL, Work WC, Wyman PA, Jarrell DD. Relationships between retrospective parent reports of developmental milestones and school adjustment at ages 10 to 12 years. J Am Acad Child Adolesc Psychiatry 1994; 33: 400-406[CrossRef][Medline].
23.	Knobloch H, Stevens F, Malone A, Ellison P, Risemberg H. The validity of parental reporting of infant development. Pediatrics 1979; 63: 872-878[Abstract/Free Full Text].
24.	Griffiths R. The abilities of young children: a comprehensive system of mental measurement for the first eight years of life. London: Child Development Research Centre, 1970.
25.	McCarthy D. Manual for the McCarthy scales of children's abilities. New York: Psychological Corporation, 1972.
26.	DeVellis R. Scale development. Theory and applications. California: Sage, 1991.
27.	Zeger SL, Liang KY, Albert PS. Models for longitudinal data: a generalized estimating equation approach. Biometrics 1988; 44: 1049-1060[CrossRef][Medline].
28.	Liang KY, Zeger SL. Longitudinal data analysis using generalized linear models. Biometrika 1986; 73: 13-22[Abstract/Free Full Text].
29.	Stoltzfus RJ, Chwaya HM, Montresor A, Albonico M, Savioli L, Tielsch J. Malaria, hookworms and recent fever are related to anemia and iron status indicators in 0- to 5-y old Zanzibari children and these relationships change with age. J Nutr 2000; 130: 1724-1733[Abstract/Free Full Text].
30.	Sherriff A, Emond A, Bell JC, Golding J. Should infants be screened for anaemia? A prospective study investigating the relation between haemoglobin at 8, 12, and 18 months and development at 18 months. Arch Dis Child 2001; 84: 480-485[Abstract/Free Full Text].

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Effects of iron supplementation and anthelmintic treatment on motor and language development of preschool children in Zanzibar: double blind, placebo controlled study

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