Hostname: page-component-586b7cd67f-t7czq Total loading time: 0 Render date: 2024-11-22T17:50:47.880Z Has data issue: false hasContentIssue false

Iron status in late pregnancy is inversely associated with birth weight in Colombia

Published online by Cambridge University Press:  16 April 2021

Alejandra Puerto
Affiliation:
ALZAK Foundation, Cartagena, Colombia Universidad de Cartagena, Carrera 5 #67-135, Edificio el Velero Apto 402, Barrio Crespo, Cartagena, Colombia
Annabelle Trojan
Affiliation:
Universidad de Cartagena, Carrera 5 #67-135, Edificio el Velero Apto 402, Barrio Crespo, Cartagena, Colombia
Nelson R Alvis-Zakzuk
Affiliation:
ALZAK Foundation, Cartagena, Colombia
Rossana López-Saleme
Affiliation:
Universidad de Cartagena, Carrera 5 #67-135, Edificio el Velero Apto 402, Barrio Crespo, Cartagena, Colombia
Francisco Edna-Estrada
Affiliation:
Centro de Investigación Para la Salud Materna Perinatal y de la Mujer, Clínica Maternidad Rafael Calvo C, Barranquilla, Colombia
Alvaro Alvarez
Affiliation:
Universidad de Cartagena, Carrera 5 #67-135, Edificio el Velero Apto 402, Barrio Crespo, Cartagena, Colombia
Nelson Alvis-Guzman
Affiliation:
ALZAK Foundation, Cartagena, Colombia Universidad de Cartagena, Carrera 5 #67-135, Edificio el Velero Apto 402, Barrio Crespo, Cartagena, Colombia Universidad de la Costa, Barranquilla, Colombia
Josefina Zakzuk*
Affiliation:
ALZAK Foundation, Cartagena, Colombia Universidad de Cartagena, Carrera 5 #67-135, Edificio el Velero Apto 402, Barrio Crespo, Cartagena, Colombia
*
*Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective:

Gestational anaemia (GA) is common in developing countries. This study assessed the relationship of late GA and negative perinatal outcomes in participants recruited in a reference maternity unit of the Caribbean region of Colombia.

Design:

Prospective analytical birth cohort study. Maternal Hb and serum ferritin (SF) levels were measured. GA was defined as Hb levels <6·82 mmol/l (<11 g/dl), SF depletion as SF levels <12 µg/l. Birth outcomes such as low birth weight (LBW), preterm birth (PB) and small for gestational age (SGA) were examined.

Setting:

Mothers in the first stage of labour, living in urban or rural areas of Bolívar, were enrolled in an obstetrical centre located in Cartagena, Colombia. Blood and stool samples were taken prior delivery. Maternal blood count, SF levels and infant anthropometric data were recorded for analysis.

Participants:

1218 pregnant women aged 18–42 years and their newborns.

Results:

Prevalence of GA and SF depletion was 41·6 % and 41·1 %, respectively. GA was positively associated with poverty-related sociodemographic conditions. Prenatal care attendance lowered the risk of PB, LBW and SGA. Birth weight was inversely associated with Hb levels, observing a −36·8 g decrease in newborn weight per 0·62 mmol/l (or 1 g/dl) of maternal Hb. SF depletion, but not anaemia, was associated with PB. SGA outcome showed a significant association with anaemia, but not a significant relationship with SF depletion.

Conclusions:

Birth weight and other-related perinatal outcomes are negatively associated with Hb and SF depletion. Prenatal care attendance reduced the risk of negative birth outcomes.

Type
Research paper
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of The Nutrition Society

Gestational anaemia (GA) can be defined as Hb levels <6·82 mmol/l (or <11·0 g/dl). Anaemia affects approximately 29 % of women worldwide and 38 % of pregnant women(1). Fe-deficiency anaemia is the most common type of anaemia, accounting for approximately 50 % of cases. Serum ferritin (SF), an Fe-binding protein, can be used to assess the body’s Fe storage and support diagnosis; normal ferritin levels in women can range from 15 to 150 µg/l, although literature indicates cut-off values at <12 µg/l when speaking of Fe deficiency(2). Previous studies have reported a relationship between anaemia and low birth weight (LBW)(Reference Figueiredo, Gomes-Filho and Batista3Reference Col Madendag, Eraslan Sahin and Madendag6), and children born to anaemic and/or Fe-deficient mothers are at risk for anaemia; anaemia and more specifically Fe-deficiency anaemia may lead to multiple health issues including cognitive impairment, pregnancy complications and reduced immunity, amongst others(Reference Suitor7,Reference Friedrisch and Friedrisch8) .

During pregnancy, Fe need increases to supply the growing fetus and placenta. Several physiological adaptive changes during pregnancy, such as increase in Fe absorption, also help to maintain Fe homoeostasis(Reference Suitor7). In fact, a decrease in the concentration of erythrocytes does not necessarily imply a real anaemic state, much less Fe-deficiency anaemia(Reference Fisher and Nemeth9). Recent studies have raised questions about the value of Fe supplementation in women who are Fe-replete and non-anaemic and suggested that excess Fe intake may paradoxically increase the risk of reproductive disorders(Reference Brannon and Taylor10,Reference Ng, Norwitz and Norwitz11) and also rather appears to be associated with significantly more adverse pregnancy events(Reference Ziaei, Norrozi and Faghihzadeh12,Reference Shastri, Mishra and Dwarkanath13) and that a high Fe status in late pregnancy is associated with a significantly smaller birth weight(Reference Dewey and Oaks14). The WHO recommends routine Fe supplementation of 30–60 mg/d throughout pregnancy to prevent Fe deficiency(15), but these policies could lead to prescription of Fe supplementation in pregnant women who, without deficiencies and assured intake, receive an excess of this nutrient, in view of the fact that physiologically, pregnant women undergo a haemodilution process due to expansion of blood volume(Reference Friedrisch and Friedrisch8,Reference Gonzales, Olavegoya and Gonzales16) . The nutritional status of women, before and during pregnancy, is a fundamental factor for the health of herself and her product. This situation could be affected because Latina women are a vulnerable group from a nutritional point of view(Reference Taipe-Ruiz17). Colombia, a middle-income country of high social inequality, presents moderate rates of GA (26·2 %) and Fe deficiency (44·5 %), being geographic location, wealth index and ethnicity its main determining factors(Reference Forero, Galindo and Hernández18). According to WHO guidelines(19), national public health policies and clinical guidelines include mandatory Fe supplementation (60 mg/d) to all pregnant women(20). However, studies from low-income African and Asian countries have also raised the concern of Fe excess even when the risk of developing anaemia is much higher(Reference Oaks, Jorgensen and Baldiviez21,Reference Hwang, Lee and Kim22) . There is an unmet need of evidence in Latin American countries, where many of them are improving socio-economic conditions, but social inequality persists. This study aimed to evaluate the relationship between GA and perinatal outcomes in a sample of women representative of low socio-economic level population in Cartagena, Colombia.

Materials and methods

Study design/population

Participants of this prospective analytical cohort study were recruited from ‘E.S.E. Clínica Maternidad Rafael Calvo C’, a reference hospital in Cartagena, Colombia, which provides obstetric care for the entire department of Bolívar. A total of 1218 women and their infants born between 1 December 2018 and 28 February 2019 were enrolled in this study. The study was designed to create a community-based birth cohort for a prospective follow-up and collection of epidemiological data and biological samples to evaluate the influence of sociodemographic and biological factors on LBW and stunting. The current data result from a cross-sectional analysis at the baseline of mothers and their infants.

Study location

Cartagena is located at sea level in the North Coast of Colombia (10° 23′ 59″ North, 75° 30′ 52″ West). Most inhabitants are poor according to a governmental index that classifies households by assessing type of housing, overcrowding (three or more people per bedroom), water and sanitation conditions, income, level of urbanisation of each home and school attendance. This stratification is carried out mainly to assign subsidies and collect contributions differentially by strata(23). This socio-economic stratification (SES) ranges from 1 to 6, and 90 % of the population is grouped in the lowest strata, 1–3.

Eligibility criteria and enrolment procedures

Pregnant women attending this medical institution for parturition were screened for eligibility by nurses of the research staff. Inclusion criteria incorporated women in their last trimester of pregnancy who were in the first stage of labour before expulsive, residing in the Department of Bolivar, aged between 18 and 45 years. Exclusion criteria were extended to mothers diagnosed with HIV, mothers suffering from autoimmune diseases, diabetes mellitus and/or chronic kidney disease. Newborns with congenital defects and/or TORCH syndrome and children born with chromosomal abnormalities were not included in this study.

Mothers were interrogated during admission to the delivery room, and informed consent was obtained. A questionnaire was conducted on sociodemographic characteristics and medical conditions of interest during pregnancy and consumption of nutritional supplements (ferrous sulphate, folic acid and Ca). Blood samples for haemogram were collected from participants before delivery. SF determination was an additional exam included in the research protocol.

Collection of baseline data and follow-up

This study was based on multidimensional surveys, blood work, stool sample collection and anthropometric data documentation.

Surveys

A risk factor identification questionnaire was conducted during the last trimester of pregnancy based on medical history, prior to and during pregnancy. Infant anthropometric data at birth were provided by official registration documents from the National Administrative Department of Statistics (DANE).

Blood samples

Two blood samples in different collector tubes were obtained and processed. Total IV generation blood count (Mindray Bc 3000) was performed in the Clinical laboratory of the hospital. Quantitative determination of circulating ferritin concentrations in human serum was established by immunoenzymometric sequential assay (AccuBind Elisa Microwells; Monobind Inc.).

Stool samples and parasitological examination

Soil-transmitted helminthiases are frequent in tropical and vulnerable communities and are also known to be associated with anaemia. A faecal sample was obtained during delivery or up to 2 d postpartum. Parasitological analysis was carried out using 0·85 % saline solution and Lugol staining; helminth eggs were counted using the Kato Katz technique (Copro Kit; C&M Medical). The presence of eggs from geohelminths or parasite visualisation was considered diagnosis of active infection.

Definition of exposure and outcomes

Exposures

Maternal anaemia

Participants were diagnosed with anaemia when the Hb level was below 6·82 mmol/l (11 g/dl)(1).

Serum ferritin depletion

Subjects with SF levels were below <12 µg/l(2).

Iron deficiency anaemia

Participants with GA and SF depletion(25).

Birth outcomes

Low birth weight

Children born with weights below 2500 g(26,27) .

Preterm birth

An infant is considered preterm when born alive before 37 weeks of pregnancy are complete(28).

Small for gestational age

Neonate born with a birth weight below the 10th percentile according to INTERGROWTH-21st project definitions(Reference Villar, Ismail and Victora29).

Data analysis

Frequency rates and their 95 % CI were obtained with Epidat 3.1 (Xunta de Galicia, PAO/WHO). Most variables were not normally distributed, and they were therefore reported as the median value and its interquartile range.

Inferential analyses were done with Statistical Package for Social Sciences (SPSS ver. 25.0; IBM). Multivariate generalised linear models were applied to evaluate the relationship between Hb or SF levels and birth weight as a continuous outcome. An exploratory analysis was first performed to select covariates and factors to be included in the model. Continuous variables were identified by Spearman correlation test. Results are shown in correlograms generated in ‘corrplot’ R package(Reference Wei, Simko and Levy31). In addition, potential associated factors (binary predictors) were explored by comparing birth weight between groups by using the non-parametric Mann–Whitney U test. Predictors with a P-value <0·1 entered the multivariate model. Living in the urban or rural area was selected a priori as a confounding factor irrespective of its crude association with the outcome.

To assess the association between binary birth-related outcomes and predictors, univariate analysis was first performed by calculating crude OR with 95 % CI. The following factors were considered as independent variables: maternal age, socio-economic status, place of residency (urban/rural), health care scheme (contributive, subsidised or another(28)), number of prenatal care visits, previous pregnancies, method of delivery and infant sex. Multivariate binary logistic regression models were built for each outcome by including as covariates, predictors that showed a P-value <0·10 in the univariate analysis and potential confounders determined a priori (maternal age, SES and neonate sex). GA was also explored as an outcome using a similar approach to birth outcomes, except for including neonate sex as a predictor. Adjusted OR with 95 % CI were estimated. P-value < 0·05 was considered significant for all tests.

Results

Anaemia is associated with poverty-related sociodemographic conditions

A total of 1218 women in labour were recruited and fulfilled the eligibility criteria for inclusion in the study; however, Hb assessment could be performed in 930 mothers (Table 1). Prevalence of GA was 41·6 % (95 % CI 38·4, 44·8). SF levels were evaluated in 701 mothers, observing SF depletion in 41·1 % (95 % CI 37·4, 44·8) women. SF depletion was more common among pregnant women with anaemia than in the non-anaemic group (Fe-deficiency anaemia: 55·6 % v. 27·6 %, P < 0·0001). Median ferritin level was 14·7 µg/l (IQR: 8·5–24·9), and median Hb level was 11·2 g/dl (IQR 10·3–12·0). Cases of soil-transmitted helminthiases were scarce. Six women out of 424 with stool exam tested positive for helminths: four with Trichuris trichiura, four with Ascaris lumbricoides and one with Strongyloides stercoralis. No cases of hookworm infections were found. Due to the low prevalence of soil-transmitted helminthiases, its relationship with anaemia was not determined.

Table 1 Descriptive of mothers and newborns

SES, socio-economic stratification; SF, serum ferritin; SGA, small for gestational age.

The effect of several sociodemographic conditions on GA was assessed by logistic regression. Crude OR indicate that sociodemographic factors such as affiliation to the contributive health care scheme (OR: 0·59, 95 % CI 0·36, 0·97, P = 0·04), belonging to the lowest social class (OR: 1·94, 95 % CI 0·11, 3·40, P = 0·02) and living in the urban area (OR: 1·59, 95 % CI 1·13, 2·22, P = 0·01) were associated with this outcome (see online Supplemental Table 1). However, in the multivariate analysis, only living in the urban area remained associated with anaemia presentation. Maternal age was included as a potential confounder without a significant association in the univariate analysis, but its relationship with GA became significant after adjustment (Table 2). History of previous pregnancies was also a significant predictor for GA (Table 2). Due to the strong association of low SES with health care scheme affiliation and prenatal care access, to avoid the effect of collinearity, in an independent multivariate model, healthcare-related variables were excluded, observing that belonging to the lowest SES was directly associated with this outcome (aOR: 1·83, 95 % CI 1·03, 3·25, P = 0·04).

Table 2 Predictors of gestational anaemia

REF = reference; SES, socio-economic stratification.

* Living in the urban area (Cartagena) v. rural municipalities.

Affiliation to the contributive health care (mother or partner affiliated to health care due to employment) v. subsidiary or no affiliation.

Mothers belonging to the strata 1 v. others (range: 2–4).

Adjusted model included maternal age and all covariates if significantly associated with the outcome in the former univariate analysis.

The number of prenatal care visits correlated positively with Hb (rho: 0·25, P < 0·0001) and SF levels (rho: 0·21, P < 0·0001) (Fig. 1). Higher attendance to prenatal care was associated with lower risk of anaemia (Fig. 2) independent of age and SES, with observable significant risk reduction from 4 to 5 visits (aOR: 0·62, 95 % CI 0·40, 0·95, P = 0·028) and lowest risk when attending six or more (aOR: 0·40, 95 % CI 0·27, 0·60, P < 0·0001).

Fig. 1 Correlogram of maternal variables and birth outcomes. The scale indicates the Spearman coefficient (Rho) from −1 to 1. Positive correlations are indicated in the blue scale, and inverse correlations are indicated in the orange scale. *Significant correlations (P < 0·05)

Fig. 2 Forest plot for prenatal care attendance and the risk of gestational anaemia

Birth weight is associated with Hb and serum ferritin

The effects of Hb and SF on birth weight were explored by generalised linear models. Other variables that correlated with birth weight (Fig. 2) and potential confounders were included in the multivariate model. Birth weight was associated with Hb independent of gestational age. There was a −36·8 g decrease (P < 0·0001) in the weight of the infant per 1 g/dl (0·62 mmol/l) of maternal Hb (Fig. 3 and Table 3). SF levels and birth weight did not show a linear relationship. However, compared with mothers with SF levels in the highest quartile (Quartile 4), those in lower quartiles gave birth to higher weight babies (see online Supplemental Table 2).

Fig. 3 Relationship between birth weight and Hb. Dots and regression lines are coloured to discriminate between term (black) and preterm (grey) neonates

Table 3 Multivariate generalised linear regression model: maternal Hb and birth weight

REF, reference value; SES, socio-economical strata.

* After evaluation the goodness of fit, gestational age was included as a binary variable in the final model.

A linear model with identity link function was run. It included all predictors specified in this table.

Anaemia is inversely associated with adverse birth outcomes

The rate of LBW in the whole sample study was 5·8 % (n 71) and 2·7 % among term neonates (n 31). By multivariate logistic regression, it was observed that GA and SF depletion behaved as protective factors for LBW (Tables 4 and 5). SF depletion (OR: 0·45, 95 % CI 0·24, 0·87, P = 0·02), but not anaemia (OR: 0·90, 95 % CI 0·54, 1·47, P = 0·89), was associated with preterm birth (PB) in the univariate analysis. Association of SF depletion with this outcome remained significant after adjustment for several covariates. Small for gestational age (SGA) outcome showed a significant association with GA (aOR: 0·52, 95 % CI 0·33, 0·80) but no significant association with SF depletion (aOR: 0·66, 95 % CI 0·42, 1·05, P = 0·08). The number of prenatal care visits during pregnancy was negatively associated with PB and LBW, but not with SGA outcome. Living in the urban area was inversely associated with LBW and SGA presentation in multivariate models assessing the effects of GA or SF depletion.

Table 4 Effect of gestational anaemia on adverse birth outcomes: logistic regression

aOR, adjusted OR; LBW, low birth weight; SES, socio-economic stratification; SGA, small for gestational age.

* All models included potential confounders as covariates (maternal age, SES and neonate sex), except for SGA because INTERGROWTH21 calculates sex-adjusted centiles.

Table 5 Effect of maternal serum ferritin (SF) depletion on adverse birth outcomes: logistic regression analysis

cOR, crude OR; aOR, adjusted OR; LBW, low birth weight; SES, socio-economic stratification; PB, preterm birth; SGA, small for gestational age.

* All models included potential confounders as covariates (maternal age, SES and neonate sex), except for SGA because INTERGROWTH21 calculates sex-adjusted centiles.

Discussion

In this study, we have found that GA and SF depletion are prevalent conditions, associated with poor prenatal care attendance in a study sample representative of a deprived community from a low-to-middle-income Latin American country. However, anaemia or SF depletion was inversely associated with different birth-related outcomes such as LBW and PB.

Our results agree with the national findings of frequency rate of GA (26·2 %) presented in 2015 by the Demographic and Health Survey and National Nutritional Survey (ENSIN)(Reference Forero, Galindo and Hernández18). The overall prevalence of low SF was 44·5 %(Reference Forero, Galindo and Hernández18). As expected from previous studies, the presence of GA tended to be associated with sociodemographic conditions associated with poverty(Reference Mahamoud, Mwambi and Oyet33,Reference Okia, Aine and Kiiza34) . Mothers with other children also had a higher risk of GA, probably due to a higher risk of food insecurity. Although poor socio-economic conditions may also increase the risk of LBW, it was found that GA showed an inverse relationship with LBW and other poor birth outcomes, which raises different concerns on the impact of Fe supplementation and medical decisions based on this nutritional variable.

There is strong evidence supporting that in early pregnancy, Fe deficiency or anaemia increases the risk of PB and LBW(Reference Rahman, Abe and Rahman35); however, their relationship in late pregnancy with poor birth outcomes is still controversial. As reviewed by Dewey et al. (Reference Dewey and Oaks14), in the third trimester, few studies demonstrated a link between a low Hb concentration and a higher risk of LBW(Reference Mohamed, Ahmad and MacRi36) and PB(Reference Zhang, Ananth and Rhoads37,Reference Meng Lu, Goldenberg and Cliver38) ; meanwhile, others have found greater occurrence of adverse birth outcomes in mother with high Hb levels(Reference Zhang, Ananth and Rhoads37,Reference Chang, O’Brien and Nathanson39,Reference Maghsoudlou, Cnattingius and Stephansson40) . Our results are similar to other reports supporting that anaemia or SF depletion during the third trimester is inversely associated with poor birth outcomes(Reference Xiong, Buekens and Alexander41Reference Symington, Baumgartner and Malan43). In a prospective study of 250 pregnant women in South Africa, Symington et al. found that anaemia and SF depletion at 22 and 36 weeks were associated with higher birth weight. Women in the lowest ferritin quartile gave birth to babies weighing more than those in the highest quartile(Reference Symington, Baumgartner and Malan43). Also, in a cohort of pregnant women in Papua New Guinea (n 279), lower ferritin concentrations at enrolment were associated with higher mean birth weights and Fe deficiency women gave birth to heavier newborns when compared with Fe-replete women(Reference Fowkes, Moore and Opi42). In a recent publication based on a large retrospective study of Chinese women, SF depletion was inversely associated with LBW, PB and SGA birth. Others have also found that maternal SF was negatively associated with neonatal birth weight and length in the third trimester and at delivery(Reference Yuan, Hu and Zhang44,Reference Hsu, Wu and Hsieh45) . Furthermore, in a Taiwanese population, severe anaemia was found to be protective against SGA products(Reference Chu, Shaw and Lo46). In contrast, Mohamed et al. found that, in US, anaemia – defined by Hb measurement at delivery – was associated with LBW and PB, especially in African Americans(Reference Mohamed, Ahmad and MacRi36). Reasons for these disparities are unknown, but it is important to highlight that differences in genetic and sociodemographic conditions of population as well as in the Fe supplementary programmes may influence results and reinforce the importance of studying locally these relationships(Reference Oaks, Jorgensen and Baldiviez21). Few studies have been published in Latin American countries about Fe-related nutritional status and birth outcomes. A recent study by Figueiredo et al. reported that maternal anaemia at any time during pregnancy was associated with low/insufficient birth weight in a Brazilian population. However, since this study involved pregnant women from 8 to 32 weeks of gestational age, its results are not comparable to ours(Reference Figueiredo, Gomes-Filho and Batista3). A Chinese cohort study (n 511) of non-anaemic pregnant women receiving Fe supplements as part of routine antenatal care also found a significantly higher birth weight in the lowest compared with the highest ferritin quartile(Reference Lao47). Also, in a South Korean cohort (n 337), Hwang et al. found that excessive maternal Fe intake at mid-pregnancy was associated with reduced fetal growth(Reference Hwang, Lee and Kim22).

The biological plausibility of the inverse association between LBW and anaemia/low Fe status may take into consideration several factors. First, there is a physiological reduction of Hb levels throughout pregnancy, possibly related to plasmatic volume expansion(Reference Gonzales, Olavegoya and Gonzales16). This implies that a low Hb or SF concentration may not be equivalent to depleted Fe stores(Reference De Haas, Ghossein-Doha and Van Kuijk48). Since volume expansion may also be affected or determined by pathological situations such as undernutrition and hypertensive disorder, we cannot conclude that anaemia and SF depletion had a real protective effect on these birth outcomes(Reference Gernand, Christian and Schulze49). However, studies analysing other markers such as soluble transferrin receptor concentration, which increases with Fe deficiency and thus is less biased by volume expansion, also support the direction of our results(Reference Dewey and Oaks14,Reference Oaks, Jorgensen and Baldiviez21) . Hypothesis explaining the inverse link between Hb or Fe levels and adverse birth outcomes have been postulated by several authors(Reference Dewey and Oaks14,Reference Ng, Norwitz and Norwitz50) . Higher Hb concentrations may increase blood viscosity, ultimately compromising placental blood flow(Reference Ziaei, Norrozi and Faghihzadeh51). Excessive non-transferrin bound Fe may contribute to oxidative stress, lipid peroxidation and DNA damage in placental cells(Reference Casanueva and Viteri52). It has also been found that SF levels correlate with higher superoxide concentration in placenta, which in turn affects microvascular endothelial function and promote conditions leading to PB(Reference Mannaerts, Faes and Cos53). It is also possible that Hb levels may be related to birth weight independently of gestational age, as we and others have found by determining its relationship with SGA outcome. Stangret et al. also reported that maternal Hb may affect fetus development by influencing placental angiogenesis, finding that it was inversely correlated with placental expression of the flt-1 receptor (placental growth factor receptor) which, at the same time, was positively correlated with birth weight(Reference Stangret, Wnuk and Szewczyk54).

It is also important to highlight that elevated Fe levels during pregnancy could have an impact on maternal and neonatal outcomes, as it may lead to a potentially harmful inflammatory state, and is associated with: premature rupture of membranes(Reference Valappil, Varkey and Areeckal55), pregnancy-induced hypertension, pre-eclampsia(Reference Rayman, Barlis and Evans56) and gestational diabetes(Reference Rawal, Hinkle and Bao57,Reference Soheilykhah, Mojibian and Moghadam58) . Also, an Fe overload may impair the systemic response to inflammation and infection, which could be associated with adverse birth outcomes(Reference Martins, Maier and Gorki59Reference Drakesmith and Prentice61). Finally, there is also the potential for excess Fe to alter the maternal gut microbiome(Reference Jaeggi, Kortman and Moretti62) as well as increase the risk of Cu and Zn deficiency(Reference Ziaei, Janghorban and Shariatdoust63), which may have implications for birth outcomes(Reference Pathak and Kapil64).

This study also found that poor prenatal care may increase the risk of GA and LBW. Similar results have been reported in studies conducted in other developing countries. A 2015 study carried out in South Nigeria suggested that good-quality prenatal care appears to be a valuable preventive intervention against anaemia(Reference Ikeanyi and Ibrahim65). In another study published in 2019, Zhou et al. assessed LBW and its relationship with prenatal care in the poor counties of Western China and reported that LBW was associated with poor attendance to prenatal care (<5 visits), not receiving any prenatal care during the first trimester, and not having access to assess certain prenatal care content (i.e. weight, blood pressure, blood tests, urine test, B-scan ultrasound and folic acid supplement)(Reference Zhou, Wang and Huang66). In Colombia, Pinzón-Rondón et al. have also found this inverse relationship between prenatal care and LBW, independent of the health care insurance system providing this service(Reference Pinzón-Rondón, Gutiérrez-Pinzon and Madriñan-Navia67). Since GA and LBW are inversely associated in our study, we propose that the relationship of prenatal care with lower presentation of adverse birth outcomes is mediated by several factors in addition to promote a healthy Fe status on pregnancy.

As mentioned previously, soil-transmitted helminthiasis is frequent in tropical and poor communities and is also known to be associated with anaemia(Reference Gyorkos and Gilbert68,Reference Gopalakrishnan, Eashwar and Muthulakshmi69) . According to the Centers for Disease Control and Prevention, as of 2013, a large part of the world’s population was infected with one or more soil-transmitted helminths (i.e. ascaris, whipworm and hookworm). A meta-analysis published in 2008 showed that even light intensity (1–1999 eggs per gram) hookworm infection is associated with a significant decrease in blood Hb(Reference Brooker, Hotez and Bundy70). The low frequency of intestinal parasitosis in our population is most likely a reflection of adequate sanitation strategies and better access to potable water. In fact, 90 % of people living in urban Cartagena have access to drinking water and 60 % to a sewage system(Reference Acevedo, Sánchez and Zakzuk71). Furthermore, the Colombian Ministry of Health recommends preventive deworming every 6 months in people living in rural areas or where sufficient sanitary and hygienic standards are not met, and every year for people living in cities(72), a series of measures which have helped keep this health hazard under control and which are mirrored in our results.

This study is the first report on the relationship between late GA and perinatal outcomes in a prospective cohort of pregnant women in Colombia. Its results have implications on the evaluation of national public health policies related to nutritional supplementation during pregnancy, motivating further studies. Stored biological samples may also led to analyse other nutritional markers that led to have a better understanding of this relationship. Of note, monitoring of child growth and development will also continue up to 2 years in this study, and this will permit to evaluate the association of Fe status during pregnancy with nutritional parameters at early infancy. Limitations of this study include that women who participated in this cohort came from the most vulnerable socio-economic background and did not recruit teenage women; thus, our results may not reflect the general population. Other underlying genetic factors, nutrient and/or mineral deficiency that may be related to LBW were not assessed. Also, C-reactive protein levels were not determined, which would have been useful to identify inflammatory states in women with elevated SF levels. However, most samples have SF values lower than 30 ng/ml which suggest that bias of including mothers with active infection/inflammation is low. Haematocrit, red cell distribution width and mean corpuscular volume were not taken into consideration in this particular context; thus, classification of anaemia and its underlying causes and possible outcomes could not be evaluated and correlated during data analysis. Nevertheless, these data are accessible thanks to sample storage and could be analysed a posteriori.

Conclusions

GA and SF depletion were inversely associated with LBW in a Colombian population. Prenatal care attendance lowered the risk of GA and LBW. Our results are representative of women from vulnerable socio-economic background and provide initial information to question the real benefit of indiscriminate Fe supplementation during pregnancy.

Acknowledgements

Acknowledgements: We thank all women who voluntarily participated in this study and the staff of the ‘ESE Clínica Maternidad Rafael Calvo C’ for their administrative support to obtain the study population and get the necessary data from the participants. We also express deep gratitude to Alejandra Castilla, Bacteriologist of Clinibac Ltda, who collaborated with the preparation of necessary laboratory exams and important information to carry out this manuscript and Leung Hon for helping to insert information into the database. Financial support: This study was funded by the Instituto de Nutrición y Salud Kellogg’s® award 2018 – Agreement INSK-ALZAK 02-10-2018 lead by ALZAK Foundation and Universidad de Cartagena grant 112-2018. Conflict of interest: There are no conflicts of interest. Authorship: Conceived of the presented idea (J.Z. and N.A.Z.), consecution of the grant (J.Z., N.A.Z., N.A.G. and F.E.), collected the data (A.P., A.T. and A.A.), sample processing and analysis (A.A.), Data analysis (J.Z., A.P. and A.T.), coordination of fieldwork (A.P.) data interpretation (A.P., A.T. and J.Z.), writing (A.P., J.Z. and A.T.), study design (J.Z., N.A.Z. and R.L.S.) or critical revision (N.A.G., N.A.Z., F.E. and R.L.S.). All authors read and approved the final manuscript. Ethics of human subject participation: This study was conducted according to the guidelines laid down in the Declaration of Helsinki, and all procedures involving research participants were approved by the Ethics Committee of the ‘E.S.E. Clinica Maternidad Rafael Calvo C.’ (Authorisation number: Acta 001-18). Written informed consent was obtained from all subjects.

Supplementary material

For supplementary material accompanying this paper visit https://doi.org/10.1017/S136898002100166X

References

World Health Organization (2011) Haemoglobin Concentrations for the Diagnosis of Anaemia and Assessment of Severity. Geneva, Switzerland: World Health Organization.Google Scholar
World Health Organization (2020) WHO Guideline on Use of Ferritin Concentrations to Assess Iron Status in Individuals and Populations. Geneva: World Health Organization.Google Scholar
Figueiredo, ACMG, Gomes-Filho, IS, Batista, JET et al. (2019) Maternal anemia and birth weight: a prospective cohort study. PLoS One 14, e0212817.CrossRefGoogle ScholarPubMed
Yi, SW, Han, YJ & Ohrr, H (2013) Anemia before pregnancy and risk of preterm birth, low birth weight and small-for-gestational-age birth in Korean women. Eur J Clin Nutr 67, 337342.CrossRefGoogle ScholarPubMed
Malhotra, M, Sharma, JB, Batra, S et al. (2002) Maternal and perinatal outcome in varying degrees of anemia. Int J Gynecol Obstet 79, 93100.CrossRefGoogle ScholarPubMed
Col Madendag, I, Eraslan Sahin, M, Madendag, Y et al. (2019) The effect of iron deficiency anemia early in the third trimester on small for gestational age and birth weight: a retrospective cohort study on iron deficiency anemia and fetal weight. Biomed Res Int 2019, 7613868.CrossRefGoogle ScholarPubMed
Suitor, CW (1991) Perspectives on nutrition during pregnancy: part I, weight gain; part II, nutrient supplements. J Am Diet Assoc 91, 9698.CrossRefGoogle ScholarPubMed
Friedrisch, JR & Friedrisch, BK (2017) Prophylactic iron supplementation in pregnancy: a controversial issue. Biochem Insights 10, 117862641773773.CrossRefGoogle ScholarPubMed
Fisher, AL & Nemeth, E (2017) Iron homeostasis during pregnancy. Am J Clin Nutr 106, 1567S1574S.CrossRefGoogle ScholarPubMed
Brannon, PM & Taylor, CL (2017) Iron supplementation during pregnancy and infancy: uncertainties and implications for research and policy. Nutrients 9, 117.CrossRefGoogle ScholarPubMed
Ng, SW, Norwitz, SG & Norwitz, ER (2019) The impact of iron overload and ferroptosis on reproductive disorders in humans: implications for preeclampsia. Int J Mol Sci 20, 3283.CrossRefGoogle ScholarPubMed
Ziaei, S, Norrozi, M, Faghihzadeh, S et al. (2007) A randomised placebo-controlled trial to determine the effect of iron supplementation on pregnancy outcome in pregnant women with haemoglobin ≥ 13.2 g/dl. BJOG 114, 684688.CrossRefGoogle ScholarPubMed
Shastri, L, Mishra, PE, Dwarkanath, P et al. (2015) Association of oral iron supplementation with birth outcomes in non-anaemic South Indian pregnant women. Eur J Clin Nutr 69, 609613.CrossRefGoogle ScholarPubMed
Dewey, KG & Oaks, BM (2017) U-shaped curve for risk associated with maternal hemoglobin, iron status, or iron supplementation. Am J Clin Nutr 106, 1694S1702S.CrossRefGoogle ScholarPubMed
World Health Organization (2012) Guideline: Daily Iron and Folic Acid Supplementation in Pregnant Women. Geneva, Switzerland: World Health Organization.Google Scholar
Gonzales, GF, Olavegoya, P, Gonzales, GF et al. (2019) Pathophysiology of anemia in pregnancy: anemia or hemodilution ? Rev Peru Ginecol Obstet 65, 489502.CrossRefGoogle Scholar
Taipe-Ruiz, BR (2019) Anemia en el primer control de gestantes en un centro de salud de Lima, Perú y su relación con el estado nutricional pregestacional (Anemia at the first prenatal visit in a health center in Lima, Peru, and its relationship with the pregestational nutrit). Horiz Med (Barcelona) 19, 611.Google Scholar
Forero, Y, Galindo, M, Hernández, J et al. (2015) National Survey of Nutritional Situation ENSIN 2015. Politic note [Internet]. General document of analysis National Survey of the Nutritional Situation in Colombia – ENSIN 2015. ENSIN 2015. https://www.icbf.gov.co/bienestar/nutricion/encuesta-nacional-situacion-nutricional#ensin3 (accessed January 2021).Google Scholar
World Health Organization (2020) WHO guideline on use of ferritin concentrations to assess iron status in individuals and populations. https://apps.who.int/iris/handle/10665/331505 (accessed January 2021).Google Scholar
Ministerio de Salud y Protección Social (2015) Lines of action for the prevention and control of micronutrient deficiencies. National Strategy for the Prevention and Control of Micronutrient Deficiencies in Colombia 2014–2021. https://www.minsalud.gov.co/sites/rid/Lists/BibliotecaDigital/RIDE/VS/PP/SNA/Estrategia-nacional-prevencion-control-deficiencia-micronutrientes.pdf (accessed January 2021).Google Scholar
Oaks, BM, Jorgensen, JM, Baldiviez, LM et al. (2019) Prenatal iron deficiency and replete iron status are associated with adverse birth outcomes, but associations differ in Ghana and Malawi. J Nutr 149, 513521.CrossRefGoogle ScholarPubMed
Hwang, JY, Lee, JY, Kim, KN et al. (2013) Maternal iron intake at mid-pregnancy is associated with reduced fetal growth: results from Mothers and Children’s Environmental Health (MOCEH) study. Nutr J 12, 17.CrossRefGoogle ScholarPubMed
DANE (2015) Urban socioeconomic stratification methodology for home public services. Conceptual approach. https://www.dane.gov.co/files/geoestadistica/estratificacion/EnfoqueConceptual.pdf (accessed January 2021).Google Scholar
Cunningham, GF, Leveno, KJ, Bloom, SL et al. (editors) (2018) Labor. In Williams Obstetrics, 25e, p. 424. New York, USA: McGraw-Hill Education/Medical.Google Scholar
World Health Organization (2001) Iron deficiency anaemia. Assessment, prevention and control. WHO/NHD/01.3. https://doi.org/10.7748/ns2013.02.27.23.59.p10441.CrossRefGoogle Scholar
WHO (2009) WHO Child Growth Standards: Head Circumference-for-age, Arm Circumference-for-age, Triceps Skin Fold-for-age and Sub Scapular Skin Fold-for-age. Geneva, Switzerland: WHO.Google Scholar
WHO (2014) Global Nutrition Targets 2025: Low Birth Weight Policy Brief (No. WHO/NMH/NHD/14.5). Geneve, Switzerland: World Health Organization.Google Scholar
World Health Organization (2012) Born Too Soon. The Global Action Report on Preterm Birth. Geneva, Switzerland: World Health Organization.Google Scholar
Villar, J, Ismail, LC, Victora, CG et al. (2014) International standards for newborn weight, length, and head circumference by gestational age and sex: the Newborn Cross-Sectional Study of the INTERGROWTH-21st Project. Lancet 384, 857868.CrossRefGoogle ScholarPubMed
Mikolajczyk, RT, Zhang, J, Betran, AP et al. (2011) A global reference for fetal-weight and birthweight percentiles. Lancet 377, 18551861.CrossRefGoogle ScholarPubMed
Wei, T, Simko, V, Levy, M et al. (2017) Package ‘corrplot’. Statistician 56, 316324.Google Scholar
Flórez-Tanus, Á, Alvis-Guzmán, N, Caraballo, L et al. (2018) Health care costs and resource utilization for different asthma severity stages in Colombia: a claims data analysis. World Allergy Organ J 11, D26.CrossRefGoogle ScholarPubMed
Mahamoud, NK, Mwambi, B, Oyet, C et al. (2020) Prevalence of anemia and its associated socio-demographic factors among pregnant women attending an antenatal care clinic at Kisugu Health Center IV, Makindye Division, Kampala, Uganda. J Blood Med 11, 1318.CrossRefGoogle Scholar
Okia, CC, Aine, B, Kiiza, R et al. (2019) Prevalence, morphological classification, and factors associated with anemia among pregnant women accessing antenatal clinic at Itojo Hospital, South Western Uganda. J Blood Med 10, 351357.CrossRefGoogle ScholarPubMed
Rahman, MM, Abe, SK, Rahman, MS et al. (2016) Maternal anemia and risk of adverse birth and health outcomes in low-and middle-income countries: systematic review and meta-analysis, 2. Am J Clin Nutr 103, 495504.CrossRefGoogle Scholar
Mohamed, MA, Ahmad, T, MacRi, C et al. (2012) Racial disparities in maternal hemoglobin concentrations and pregnancy outcomes. J Perinat Med 40, 141149.CrossRefGoogle ScholarPubMed
Zhang, Q, Ananth, CV, Rhoads, GG et al. (2009) The impact of maternal anemia on perinatal mortality: a population-based, prospective cohort study in China. Ann Epidemiol 19, 793799.CrossRefGoogle ScholarPubMed
Meng Lu, Z, Goldenberg, RL, Cliver, S et al. (1991) The relationship between maternal hematocrit and pregnancy outcomes. Obstet Gynecol 77, 190194.CrossRefGoogle Scholar
Chang, S-C, O’Brien, KO, Nathanson, MS et al. (2003) Hemoglobin concentrations influence birth outcomes in pregnant African-American adolescents. J Nutr 133, 23482355.CrossRefGoogle ScholarPubMed
Maghsoudlou, S, Cnattingius, S, Stephansson, O et al. (2016) Maternal haemoglobin concentrations before and during pregnancy and stillbirth risk: a population-based case-control study. BMC Pregnancy Childbirth 16, 18.CrossRefGoogle Scholar
Xiong, X, Buekens, P, Alexander, S et al. (2000) Anemia during pregnancy and birth outcome: a meta-analysis. Am J Perinatol 17, 137146.CrossRefGoogle ScholarPubMed
Fowkes, FJI, Moore, KA, Opi, DH et al. (2018) Iron deficiency during pregnancy is associated with a reduced risk of adverse birth outcomes in a malaria-endemic area in a longitudinal cohort study. BMC Med 16, 156.CrossRefGoogle Scholar
Symington, EA, Baumgartner, J, Malan, L et al. (2019) Maternal iron-deficiency is associated with premature birth and higher birth weight despite routine antenatal iron supplementation in an urban South African setting: the NuPED prospective study. PLoS One 14, e0221299.CrossRefGoogle Scholar
Yuan, X, Hu, H, Zhang, M et al. (2019) Iron deficiency in late pregnancy and its associations with birth outcomes in Chinese pregnant women: a retrospective cohort study. Nutr Metab 16, 111.CrossRefGoogle ScholarPubMed
Hsu, WY, Wu, CH, Hsieh, CTC et al. (2013) Low body weight gain, low white blood cell count and high serum ferritin as markers of poor nutrition and increased risk for preterm delivery. Asia Pac J Clin Nutr 22, 9099.Google ScholarPubMed
Chu, FC, Shaw, SW, Lo, LM et al. (2020) Association between maternal anemia at admission for delivery and adverse perinatal outcomes. J Chin Med Assoc 83, 402407.CrossRefGoogle ScholarPubMed
Lao, TT (2000) Third trimester iron status and pregnancy outcome in non-anaemic women; pregnancy unfavourably affected by maternal iron excess. Hum Reprod 15, 18431848.CrossRefGoogle ScholarPubMed
De Haas, S, Ghossein-Doha, C, Van Kuijk, SMJ et al. (2017) Physiological adaptation of maternal plasma volume during pregnancy: a systematic review and meta-analysis. Ultrasound Obstet Gynecol 49, 177187.CrossRefGoogle ScholarPubMed
Gernand, AD, Christian, P, Schulze, KJ et al. (2012) Maternal nutritional status in early pregnancy is associated with body water and plasma volume changes in a pregnancy cohort in rural Bangladesh. J Nutr 142, 11091115.CrossRefGoogle Scholar
Ng, S-W, Norwitz, SG & Norwitz, ER (2019) The impact of iron overload and ferroptosis on reproductive disorders in humans: implications for preeclampsia. Int J Mol Sci 20, 3283.CrossRefGoogle ScholarPubMed
Ziaei, S, Norrozi, M, Faghihzadeh, S et al. (2007) A randomised placebo-controlled trial to determine the effect of iron supplementation on pregnancy outcome in pregnant women with haemoglobin ≥ 13.2 g/dl. BJOG 114, 684688.CrossRefGoogle ScholarPubMed
Casanueva, E & Viteri, FE (2003) Iron and oxidative stress in pregnancy. J Nutr 133, 1700S1708S.CrossRefGoogle ScholarPubMed
Mannaerts, D, Faes, E, Cos, P et al. (2018) Oxidative stress in healthy pregnancy and preeclampsia is linked to chronic inflammation, iron status and vascular function. PLoS One 13, 114.CrossRefGoogle ScholarPubMed
Stangret, A, Wnuk, A, Szewczyk, G et al. (2017) Maternal hemoglobin concentration and hematocrit values may affect fetus development by influencing placental angiogenesis. J Matern Neonatal Med 30, 199204.CrossRefGoogle ScholarPubMed
Valappil, SA, Varkey, M, Areeckal, B et al. (2015) Serum ferritin as a marker for preterm premature rupture of membranes – a study from a tertiary centre in central Kerala. J Clin Diagn Res 9, BC09BC12.Google ScholarPubMed
Rayman, MP, Barlis, J, Evans, RW et al. (2002) Abnormal iron parameters in the pregnancy syndrome preeclampsia. Am J Obstet Gynecol 187, 412418.CrossRefGoogle ScholarPubMed
Rawal, S, Hinkle, SN, Bao, W et al. (2017) A longitudinal study of iron status during pregnancy and the risk of gestational diabetes: findings from a prospective, multiracial cohort. Diabetologia 60, 249257.CrossRefGoogle ScholarPubMed
Soheilykhah, S, Mojibian, M & Moghadam, MJ (2017) Serum ferritin concentration in early pregnancy and risk of subsequent development of gestational diabetes: a prospective study. Int J Reprod Biomed 15, 155160.Google ScholarPubMed
Martins, R, Maier, J, Gorki, AD et al. (2016) Heme drives hemolysis-induced susceptibility to infection via disruption of phagocyte functions. Nat Immunol 17, 13611372.CrossRefGoogle ScholarPubMed
Arezes, J, Foy, N, McHugh, K et al. (2018) Erythroferrone inhibits the induction of hepcidin by BMP6. Blood 132, 14731477.CrossRefGoogle ScholarPubMed
Drakesmith, H & Prentice, AM (2012) Hepcidin and the iron-infection axis. Science 338, 768772.CrossRefGoogle ScholarPubMed
Jaeggi, T, Kortman, GAM, Moretti, D et al. (2015) Iron fortification adversely affects the gut microbiome, increases pathogen abundance and induces intestinal inflammation in Kenyan infants. Gut 64, 731742.CrossRefGoogle ScholarPubMed
Ziaei, S, Janghorban, R, Shariatdoust, S et al. (2008) The effects of iron supplementation on serum copper and zinc levels in pregnant women with high-normal hemoglobin. Int J Gynecol Obstet 100, 133135.CrossRefGoogle ScholarPubMed
Pathak, P & Kapil, U (2004) Role of trace elements zinc, copper and magnesium during pregnancy and its outcome. Indian J Pediatr 71, 10031005.CrossRefGoogle ScholarPubMed
Ikeanyi, EM & Ibrahim, AI (2015) Does antenatal care attendance prevent anemia in pregnancy at term? Niger J Clin Pract 18, 323327.CrossRefGoogle ScholarPubMed
Zhou, H, Wang, A, Huang, X et al. (2019) Quality antenatal care protects against low birth weight in 42 poor counties of Western China. PLoS One 14, 114.Google ScholarPubMed
Pinzón-Rondón, ÁM, Gutiérrez-Pinzon, V, Madriñan-Navia, H et al. (2015) Low birth weight and prenatal care in Colombia: a cross-sectional study. BMC Pregnancy Childbirth 15, 118.CrossRefGoogle ScholarPubMed
Gyorkos, TW & Gilbert, NL (2014) Blood drain: soil-transmitted helminths and anemia in pregnant women. PLoS Negl Trop Dis 8, 78.CrossRefGoogle ScholarPubMed
Gopalakrishnan, S, Eashwar, VA, Muthulakshmi, M et al. (2018) Intestinal parasitic infestations and anemia among urban female school children in Kancheepuram district, Tamil Nadu. J Fam Med Prim Care 7, 1395.CrossRefGoogle ScholarPubMed
Brooker, S, Hotez, PJ & Bundy, DAP (2008) Hookworm-related anaemia among pregnant women: a systematic review. PLoS Negl Trop Dis 2, e291.CrossRefGoogle ScholarPubMed
Acevedo, N, Sánchez, J, Zakzuk, J et al. (2012) Particular characteristics of allergic symptoms in tropical environments: follow up to 24 months in the FRAAT birth cohort study. BMC Pulm Med 12, 13.CrossRefGoogle ScholarPubMed
Ministry of Health and Social Protection (2013) Deworming Guideline “WHO Preventive Anthelmintic Chemotherapy”. https://www.minsalud.gov.co/sites/rid/Lists/BibliotecaDigital/RIDE/VS/PP/ET/LINEAMIENTODESPARASITANTIHELMÍNTICA080122014.pdf (accessed January 2021).Google Scholar
Figure 0

Table 1 Descriptive of mothers and newborns

Figure 1

Table 2 Predictors of gestational anaemia

Figure 2

Fig. 1 Correlogram of maternal variables and birth outcomes. The scale indicates the Spearman coefficient (Rho) from −1 to 1. Positive correlations are indicated in the blue scale, and inverse correlations are indicated in the orange scale. *Significant correlations (P < 0·05)

Figure 3

Fig. 2 Forest plot for prenatal care attendance and the risk of gestational anaemia

Figure 4

Fig. 3 Relationship between birth weight and Hb. Dots and regression lines are coloured to discriminate between term (black) and preterm (grey) neonates

Figure 5

Table 3 Multivariate generalised linear regression model: maternal Hb and birth weight

Figure 6

Table 4 Effect of gestational anaemia on adverse birth outcomes: logistic regression

Figure 7

Table 5 Effect of maternal serum ferritin (SF) depletion on adverse birth outcomes: logistic regression analysis

Supplementary material: File

Puerto et al. supplementary material

Tables S1-S2

Download Puerto et al. supplementary material(File)
File 21.6 KB