Hostname: page-component-8448b6f56d-t5pn6 Total loading time: 0 Render date: 2024-04-17T08:04:48.365Z Has data issue: false hasContentIssue false
  • English
  • Français

Iodine status of postpartum women and their infants in Australia after the introduction of mandatory iodine fortification

Published online by Cambridge University Press:  09 August 2017

Dao Huynh ,
Dominique Condo ,
Robert Gibson ,
Beverly Muhlhausler ,
Philip Ryan ,
Sheila Skeaff ,
Maria Makrides  and
Shao J. Zhou
Dao Huynh
Affiliation:
School of Agriculture, Food and Wine, Foodplus Research Centre, University of Adelaide, PMB 1, Glen Osmond, SA 5064, Australia
Dominique Condo
Affiliation:
Women’s and Children’s Health Research Institute, 72 King William Road, North Adelaide, SA 5006, Australia
Robert Gibson
Affiliation:
School of Agriculture, Food and Wine, Foodplus Research Centre, University of Adelaide, PMB 1, Glen Osmond, SA 5064, Australia Women’s and Children’s Health Research Institute, 72 King William Road, North Adelaide, SA 5006, Australia
Beverly Muhlhausler
Affiliation:
School of Agriculture, Food and Wine, Foodplus Research Centre, University of Adelaide, PMB 1, Glen Osmond, SA 5064, Australia Women’s and Children’s Health Research Institute, 72 King William Road, North Adelaide, SA 5006, Australia
Philip Ryan
Affiliation:
School of Population Health, University of Adelaide, Adelaide, SA 5005, Australia
Sheila Skeaff
Affiliation:
Department of Human Nutrition, University of Otago, PO Box 56, Dunedin 9094, New Zealand
Maria Makrides
Affiliation:
School of Agriculture, Food and Wine, Foodplus Research Centre, University of Adelaide, PMB 1, Glen Osmond, SA 5064, Australia Women’s and Children’s Health Research Institute, 72 King William Road, North Adelaide, SA 5006, Australia South Australia Health and Medical Research Institute, PO Box 11060, Adelaide, SA 5001, Australia
Shao J. Zhou*
Affiliation:
School of Agriculture, Food and Wine, Foodplus Research Centre, University of Adelaide, PMB 1, Glen Osmond, SA 5064, Australia Women’s and Children’s Health Research Institute, 72 King William Road, North Adelaide, SA 5006, Australia
*
*Corresponding author: Dr S. J. Zhou, fax +61 8 8303 7135, email jo.zhou@adelaide.edu.au
Rights & Permissions [Opens in a new window]

Abstract

Mandatory I fortification in bread was introduced in Australia in 2009 in response to the re-emergence of biochemical I deficiency based on median urinary I concentration (UIC)<100 µg/l. Data on the I status of lactating mothers and their infants in Australia are scarce. The primary aim of this study was to assess the I status, determined by UIC and breast milk I concentration (BMIC), of breast-feeding mothers in South Australia and UIC of their infants. The secondary aim was to assess the relationship between the I status of mothers and their infants. The median UIC of the mothers (n 686) was 125 (interquartile range (IQR) 76–200) µg/l and median BMIC (n 538) was 127 (IQR 84–184) µg/l. In all, 38 and 36 % of the mothers had a UIC and BMIC below 100 µg/l, respectively. The median UIC of infants (n 628) was 198 (IQR 121–296) µg/l, and 17 % had UIC<100 µg/l. Infant UIC was positively associated with maternal UIC (β 0·26; 95 % CI 0·14, 0·37, P<0·001) and BMIC (β 0·85; 95 % CI 0·66, 1·04, P<0·001) at 3 months postpartum after adjustment for gestational age, parity, maternal secondary and further education, BMI category and infant feeding mode. The adjusted OR for infant UIC<100 µg/l was 6·49 (95 % CI 3·80, 11·08, P<0·001) in mothers with BMIC<100 µg/l compared with those with BMIC≥100 µg/l. The I status of mothers and breast-fed infants in South Australia, following mandatory I fortification, is indicative of I sufficiency. BMIC<100 µg/l increased the risk of biochemical I deficiency in breast-fed infants.

Keywords

IodineUrinary iodine concentrationBreast milkMothers: Infants
Type
Full Papers
Information
British Journal of Nutrition , Volume 117 , Issue 12 , 28 June 2017 , pp. 1656 - 1662
Copyright
Copyright © The Authors 2017 

I is essential for the synthesis of thyroid hormones, which play a critical role in growth and development( Reference Mullur, Liu and Brent 1 ). I deficiency is a common nutritional deficiency in both developed and developing countries. It is estimated that approximately 2 billion individuals world-wide are I deficient( Reference Stagnaro-Green and Pearce 2 ). Furthermore, approximately 38 million newborns in developing countries( 3 ) and over 24 million school-age children in Europe are classified as I deficient( Reference Zimmermann, Gizak and Abbott 4 ). Severe I deficiency (defined as median urinary I concentration (UIC)<20 µg/l in a population) before birth and in early infancy can result in irreversible cognitive and physical deficits( Reference Eastman and Zimmermann 5 ). It is therefore important to ensure adequate I nutrition during this critical developmental period.

I deficiency has become a public health issue in Australia and mandatory I fortification was implemented in Australia in 2009 to address the re-emergence of I deficiency( 6 ). This strategy has led to improvement in the I status of the general population( 7 ) but data on the I status of lactating mothers and their infants in Australia are scarce. Before the mandatory fortification, two small studies (n≤50) conducted in tertiary referral hospitals in Sydney reported I deficiency in lactating mothers in the early postpartum period( Reference Chan, Hams and Wiley 8 , Reference Gunton, Hams and Fiegert 9 ), as indicated by a median UIC<100 µg/l( Reference Andersson, de Benoist and Delange 10 ). There has been only one small study (n 60) assessing I status of lactating mothers following the introduction of mandatory I fortification in Australia. This study reported a median UIC of 123 µg/l (interquartile range (IQR) 71–236 µg/l)( Reference Axford, Charlton and Yeatman 11 ), indicating an improvement in I status of lactating women in Sydney, compared with the pre-fortification period. However, it did not meet the minimum sample size required to assess I status of populations (n 300) as suggested by the World Health Organization( 12 ). There are currently no studies with an adequate sample size that have determined the I status of lactating women and/or infants in Australia after mandatory I fortification.

Although UIC is the recommended biomarker for assessing the I status of populations it is not appropriate to use it as a marker of I status of individuals due to large day to day variation( 12 ), breast milk I concentration (BMIC) may be a suitable marker of I status of exclusively breast-fed infants as breast milk is the sole source of dietary I for these infants. Previous studies in Iran have demonstrated a positive relationship between maternal BMIC and the UIC of their infants( Reference Bazrafshan, Mohammadian and Ordookhani 13 , Reference Hashemipour, Nasri and Hovsepian 14 ). It has been suggested that a BMIC of at least 80–100 µg/l is required to ensure that full-term breast-fed infants received a sufficient supply of I to meet their I requirements( Reference Dold, Zimmermann and Baumgartner 15 , Reference Semba and Delange 16 ). Data on BMIC of lactating women in Australia are limited, with only one small study (n 50) reporting a median BMIC of 84 µg/l in mothers between 3 and 9 d postpartum, indicative of an inadequate I supply to meet the requirements of term infants( Reference Chan, Hams and Wiley 8 ). This study was conducted before mandatory I fortification and collected from a convenience sample in a tertiary referral hospital in Sydney, Australia. Thus, the average BMIC of Australian women following the introduction of mandatory I fortification is unknown.

The primary aim of this study was to assess the I status of mothers and infants post-I fortification in Australia. The secondary aim was to examine the relationship between maternal UIC, BMIC and infant UIC.

Methods

Study design

This study was undertaken as part of a larger prospective cohort study which aimed to examine the relationship between maternal I intake in pregnancy and neurodevelopmental outcomes in the children at 18 months of age (Pregnancy I and Neurodevelopment in Kids)( Reference Condo, Skeaff and Ryan 17 , Reference Huynh, Condo and Gibson 18 ). This study was conducted according to the guidelines laid down in the Declaration of Helsinki and all procedures involving human subjects were approved by the Women’s & Children’s Health Network Human Research Ethics Committee (Ref: REC 1657/2/11 & REC 2230/12/15). Written informed consent was obtained from all participants.

Participants and recruitment

Healthy pregnant women (<20 weeks of gestation) were recruited from the antenatal clinics at the Women’s and Children’s Hospital and Flinders Medical Centre in Adelaide, South Australia between August 2011 and December 2012 and were followed up until 3 months after birth. Women with a history of thyroid disease, drug or alcohol abuse, who had a known fetal abnormality in their current pregnancy, or families in which English was not the primary language spoken at home were excluded.

Assessment of iodine status

UIC was assessed as a biomarker of I status of mothers and infants. A spot urine sample (10–20 ml) was collected from mothers and their infants at 3 months after birth (between September 2012 and October 2013) using a 70-ml sterilised pot (Southern Cross Scientific Ltd). The urine samples were stored at −20°C for subsequent batch analysis of UIC. UIC was measured using the WHO Method Two( 12 ) in an Ensuring the Quality of Urinary Iodine Procedures program accredited laboratory at the University of Adelaide. The principle of this method is the colorimetric Sandell-Kolthoff reaction following ammonium persulfate digestion. The SeronormTM Trace Elements Urine (SERO) was used as external standard and the results (mean) obtained by using this method was 285 (sd 12) µg/l compared with the certified value of 304 (sd 44) µg/l. The detection limit and reporting limit of the assay were 5·5 and 18·3 µg/l, respectively. Intra-assay and inter-assay CV were both <5 %.

BMIC was also determined as an additional biomarker of I status. A breast milk sample was collected from all breast-feeding mothers at the same time of the urine sample collection and using the same type of the container used for collecting urine. Mothers were instructed to collect 10–20 ml of the breast milk in the morning between 05.00 and 09.00 hours before the first feed. Breast milk samples were collected in either the study clinic or in the mother’s home. If the sample was collected at home, mothers were instructed to freeze the samples in their home freezer until collection by study staff, whereas breast milk samples collected in the clinic were kept in the clinic freezer after collection. The samples were transported from the participant’s home or the clinic to the laboratory within 4 d. The samples were kept frozen during transport using an insulated container with a freeze brick. All breast milk samples were then stored at −80°C until analysis. No I contamination was detected in any components used for urine and breast milk samples collection and analysis. I concentration in breast milk was determined using a modified method of the determination of I in food samples by Inductively Coupled Plasma MS after tetramethylammonium hydroxide extraction as described in detail previously( Reference Huynh, Zhou and Gibson 19 ). Using this method, the results obtained for the external standard NIST 1549 milk powder (National Institute of Standard and Technology) was 3·38 (sd 0·02) mg/kg, which is the same as the certified value of 3·38 (sd 0·02) mg/kg. The method quantitative limit for human breast milk was 1·6 µg/l. The intra-assay and inter-assay CV were <1 and 3·5 %, respectively.

Other assessments

Socio-demographic characteristics of the mothers including age, gestational age, weight and height, parity, education level, employment, smoking and alcohol consumption status, were collected at study entry. Information on feeding mode (exclusively breast-feeding, partially breast-feeding or non-breast-feeding) at 3 months postpartum was collected by maternal report at the 3 month follow-up appointment. Women are recommended to take I supplements of 150 μg/d when planning pregnancy, during pregnancy and breast-feeding in Australia( 20 ). The information on I supplementation in lactation was not collected in the current study as the exposure variables in our study were maternal UIC and BMIC, not maternal I intake.

Statistical analysis

Normally distributed data are reported as means and standard deviations and non-normally distributed data are expressed as medians and IQR. The I status of the mothers and their infants was classified according to the WHO criteria: a median UIC<100 µg/l was considered indicative of I deficiency, whereas a median UIC≥500 µg/l in mothers and a median UIC≥300 µg/l in infants was considered indicative of excessive I intake( 12 ). A BMIC<100 µg/l was taken as indicative of an inadequate I supply to the infants( Reference Semba and Delange 21 ).

The percentage of mothers and infants with UIC below (<100 µg/l) or above (≥500 µg/l in mothers or ≥300 µg/l in infants) the WHO population thresholds were calculated as these thresholds are often reported in the literature. These thresholds should not be used to classify the I status of individuals as a single spot UIC is not an appropriate marker of individuals’ I status due to the large day to day variation in UIC( 12 ). UIC was not normally distributed, thus quantile regression models, estimating the 50th centile (the median), were used to investigate the differences in UIC and BMIC between groups categorised by infant and maternal characteristics, that is infant sex, feeding mode and maternal BMI category. A quantile regression model was used to assess the relationships between maternal UIC (as the predictor) and infant UIC (as the outcome) with and without adjustment for covariates. Subgroup analysis was also performed in breast-feeding mothers and their children to assess the relationship between BMIC (as the predictor) and infant UIC (as the outcome). When UIC and BMIC were separated into two groups: <100 v. ≥100 µg/l, quantile regression models were also used to assess the differences in infant/maternal UIC and BMIC between these groups. Logistic regression models were used to estimate the OR of infants having a UIC<100 µg/l when their mothers had a UIC<100 µg/l or BMIC<100 µg/l. The OR of having a BMIC<100 µg/l when maternal UIC were <100 µg/l. Both unadjusted and adjusted analyses were performed. Covariates adjusted in all regression models including gestational age at study entry, parity, maternal completed secondary and further education, BMI category and feeding mode. Results from all models are reported as standardised regression coefficient (β) or OR as appropriate with 95 % CI.

Results

A total of 696 mothers and their infants who provided either maternal urine, breast milk and/or infant urine samples at 3 months postpartum were included in the study. Of these, urine samples were obtained from 686 (99 %) mothers and 628 (90 %) infants; and breast milk samples from 538 (95 %) of the 573 mothers who were still breast-feeding at 3 months postpartum. The socio-demographic characteristics of the mothers at enrolment are shown in Table 1. The percentages of infants who were exclusively breast-fed, partially breast-fed or exclusively formula fed at 3 months of age were 61, 18 and 21 %, respectively.

Table 1 Demographic characteristics of women at study entry (n 696) (Medians and interquartile ranges (IQR); numbers and percentages)

Iodine status of mothers at 3 months postpartum

The median UIC of mothers was 125 (IQR 76–200) µg/l; 38 % of mothers had UIC<100 µg/l, whereas 2 % had UIC≥500 µg/l. The median BMIC was 127 (IQR 84–184) µg/l, with 36 % mothers having BMIC<100 µg/l. The median BMIC and percentage of mothers with BMIC<100 μg/l in the groups of mothers categorised by UIC<100 v. UIC≥100 μg/l are shown in Table 2.

Table 2 Median breast milk iodine concentration (BMIC) and infant urinary iodine concentration (UIC) according to maternal UIC and BMIC category(Medians and interquartile ranges (IQR); numbers and percentages)

* Adjusted for gestational age at study entry, parity, maternal completed secondary and further education, BMI category and feeding mode.

P value derived from quantile regression.

P value derived from logistic regression.

The median BMIC was higher in mothers with UIC≥100 μg/l compared with those with UIC<100 μg/l, by 33 (95 % CI 18, 48) μg/l (P<0·001) before adjustment and by 39 (95 % CI 22, 55) μg/l (P<0·001) after the adjustment. Mothers with a UIC<100 µg/l were also more likely to have a BMIC<100 µg/l, compared with mothers with a UIC≥100 µg/l, in both unadjusted and adjusted analysis (Table 2).

The median UIC of mothers according to feeding mode are shown in Fig. 1. Median UIC of non-breast-feeding mothers was significantly higher than that of exclusively breast-feeding mothers after the adjustment for gestational age, parity, maternal secondary and further education, BMI categories and feeding mode (P<0·01). No difference in the median UIC was found between partially and exclusively breast-feeding mothers (P>0·05). There was no difference in the median BMIC between women with baseline BMI<25 kg/m2 (123 (IQR 68, 188) μg/l) and those with BMI≥25 kg/m2 (126 (IQR 85, 222) μg/l). Unadjusted and adjusted estimates β and 95 % CI are shown in Table 3. Maternal UIC was positively associated with BMIC in both unadjusted (β 0·21 (95 % CI 0·17, 0·26), P<0·001) and adjusted analysis (β 0·27 (95 % CI 0·18, 0·35), P<0·001).

Fig. 1 Urinary iodine concentration of mothers () and infants () according to feeding mode.

Table 3 Infant urinary iodine concentrations (UIC), maternal UIC and breast milk iodine concentration (BMIC) according to infant sex, feeding mode and BMI category (Standardised regression coefficients (β) and 95 % confidence intervals; odds ratios and 95 % confidence intervals)

* Adjusted for gestational age at study entry, parity, maternal completed secondary and further education, BMI category and feeding mode.

Iodine status of infants at 3 months of age

The median UIC of infants at 3 months was 198 (IQR 121–296) µg/l; 17 % of infants had UIC <100 µg/l, whereas 24 % had UIC≥300 µg/l. Table 2 showed median UIC of infants and percentage of infants with UIC<100 μg/l according to maternal UIC and BMIC categories (<100 v. ≥100 μg/l).

The median UIC of male (n 347) and female infants (n 281) were 196 (IQR 120–293) and 201 (IQR 122–299) μg/l, respectively. Median UIC and IQR of infants according to feeding mode are shown in Fig. 1. No difference in the median UIC was found between male and female infants and between infants with different feeding modes, including exclusively breast-fed, partially breast-fed and exclusively formula fed in both adjusted and unadjusted analysis (Table 3).

The relationship between iodine status of mothers and their infants

Infant UIC were positively associated with maternal UIC with or without adjustment for gestational age, parity, maternal education, baseline BMI category and infant feeding mode (unadjusted β 0·22; 95 % CI 0·08, 0·36, P=0·002 and adjusted β 0·26; 95 % CI 0·14, 0·37, P<0·001). A similar relationship was also observed between infant UIC and BMIC in the subgroup of breast-fed infants in both unadjusted analysis (β 0·86; 95 % CI 0·65, 1·08, P<0·001) and adjusted analysis (adjusted for gestational age, parity, maternal completed secondary and further education, BMI category and feeding mode) (β 0·85; 95 % CI 0·66, 1·04, P<0·001).

The median UIC of infants whose mothers had UIC≥100 μg/l was 32 (95 % CI 7, 57) μg/l (P=0·013) higher than infants whose mothers had UIC<100 μg/l. A similar finding was observed (32 (95 % CI 9, 56) μg/l (P=0·007) higher) after adjustment for gestational age, parity, maternal secondary and further education, baseline BMI category, and infant feeding mode. When the data of breast-fed infants were analysed separately, the median UIC of infants whose mothers had a BMIC≥100 µg/l was 93 (95 % CI 61, 125) μg/l (P<0·001) higher than infants whose mothers with BMIC<100 µg/l in unadjusted analysis, and 87 (95 % CI 61, 114) μg/l (P<0·001) higher in adjusted analysis.

Infants of mothers with UIC<100 µg/l were more likely to have UIC<100 µg/l compared with infants born to mothers with UIC≥100 µg/l before and after the adjustment for gestational age, parity, mothers completed secondary and further education, baseline BMI category and feeding mode (Table 3). Infants of mothers with BMIC<100 µg/l were more likely to have a UIC<100 µg/l than infants of mothers with BMIC≥100 µg/l in both unadjusted and adjusted analysis (Table 3).

Discussion

Our study is the first prospective cohort study to simultaneously assess I status of both mothers and their infants in Australia after the introduction of mandatory I fortification. The median UIC of both mothers and infants were indicative of I sufficiency in this study population, which should not be interpreted to indicate that all participants are I sufficient as a single spot UIC cannot be used to define I status of individuals( 12 ). The present study also provides the first data on BMIC of lactating women in South Australia post-fortification, and suggests that, on average, their breast milk provides an adequate I supply to meet the requirement of full term breast-fed infants at 3 months of age.

The median UIC of lactating women in our study, the largest Australian study conducted to date, is consistent with a small study (n 60) conducted in Illawarra region of Australia post-fortification( Reference Axford, Charlton and Yeatman 11 ) indicating an I sufficient status of lactating women. Our study is the first to report I status of Australian infants following the introduction of mandatory I fortification. Our finding of adequate I status in both mothers and infants are in agreement with a national I survey conducted in 2011–2012, which showed that child-bearing aged women and school-age children in South Australia were I sufficient post-fortification( 7 ). We found, however, that mothers with UIC<100 µg/l were more likely to produce breast milk containing I <100 µg/l and their infants had a higher risk of I deficiency. Although the median UIC of breast-fed infants whose mothers had BMIC<100 µg/l was considered I sufficient, the risk of these infants having a UIC<100 µg/l were six times higher compared with breast-fed infants whose mothers had a BMIC≥100 µg/l. This suggests that I intake of breast-fed infants may be suboptimal if maternal BMIC is <100 µg/l. These findings highlight the importance of achieving and maintaining an I sufficient status during lactation in order to ensure sufficient I supply to their breast-fed infants.

The positive association between maternal and infant UIC in our study is consistent with previous reports( Reference Liu, Wang and Liu 22 , Reference Wang, Zhang and Ge 23 ), but there is little evidence on the relationship between maternal BMIC and UIC. The only study in Australia that examined this relationship( Reference Chan, Hams and Wiley 8 ) was conducted before the mandatory I fortification, and showed no correlation between maternal BMIC and UIC. However, the study was only conducted on a small sample (n 50) and may not have adequate power to detect the association. The current study is the first to investigate the relationship between maternal UIC/BMIC and infant UIC in Australia, and has demonstrated that both maternal UIC and BMIC measured at 3 months postpartum were positively associated with infant UIC at this same time point. Furthermore, our results suggest that BMIC is a better predictor of infant UIC compared with maternal UIC as reflected by a stronger association between BMIC and infant UIC and a larger effect size of BMIC on infants UIC from the regression analysis.

Although large studies in adults in a number of countries, including Germany (n 6978) and China (n 26 773) have reported lower UIC in females compared with males( Reference Johner, Thamm and Schmitz 24 , Reference Zou, Ding and Lou 25 ), whether this is the case in infants is less clear. We found no difference in median UIC at 3 months of age between male and female infants, similar to studies in Iran (n 147)( Reference Nazeri, Mirmiran and Hedayati 26 ) and France (n 95)( Reference Pouessel, Damie and Soudan 27 ) in infants under 12 months of age. Another large study of 16 481 Chinese infants, however, reported that the median UIC of female infants was significantly lower than males( Reference Yang, Zheng and Li 28 ), but the magnitude of difference was small, at 6 µg/l. Whether there are differences in I metabolism, I status and I requirement between male and female infants remains unclear, but if they do exist, they are probably small and unlikely to be clinically important.

Maternal overweight and obesity have been associated with an increased risk of a number of micronutrient deficiencies( Reference Asfaw 29 ). I is a key component of thyroid hormone which regulates metabolic rate. There is limited evidence suggesting an association between thyroid hormone concentrations and markers of metabolic health including BMI and insulin sensitivity in adults( Reference Boron and Boulpaep 30 ). In the current study, we saw no differences in BMIC at 3 months postpartum between overweight/obese mothers and normal weight mothers categorised based on BMI at study entry, and the median BMIC in both groups were higher than the cut-off of 100 µg/l, indicative of adequate I level to meet the I requirements of their infants. It is important to note that the BMI of the women in this study was determined from weight and height collected at study entry (<20 weeks of gestation), and subsequent weight changes during pregnancy/lactation may also have the potential to impact on BMIC. Thus, further studies in which I status/BMIC and maternal weight are assessed at multiple time-points before and after pregnancy are required to more clearly delineate if overweight or obese may have a negative impact on maternal/infant I status and BMIC.

The current study provides the first data regarding I nutrition status of infants in Australia with different feeding modes. Our finding is consistent with the results of a previous study conducted in USA, which also showed no difference in median UIC between exclusively breast-fed, partially breast-fed and exclusively formula fed infants <3 months of age( Reference Gordon, Leung and Hale 31 ). Although there appeared to be no impact of feeding mode on infant UIC in this population with adequate I status, we found that mothers who were exclusively breast-feeding had a lower median UIC than women who were not breast-feeding reflecting the higher I requirements in breast-feeding women. In addition, mothers who breast-fed their infants were more likely to have a UIC<100 μg/l than non-breast-feeding mothers. Whether breast-feeding has a short-term impact on UIC or long-term impact on thyroid function of the mother is still unclear, and it will be important to assess whether there are differences in maternal thyroid function between breast-feeding and non-breast-feeding women in future studies.

Recently it was reported that the BMIC of lactating women increased and reached the peak levels at 6 h after the administration of 600 μg KI( Reference Leung, Braverman and He 32 ). BMIC was reported to be higher in the foremilk and the mid-feed milk compared with the hindmilk( Reference Dold, Baumgartner and Zeder 33 ) and declined as lactation progressed in the first 6 months( Reference Mulrine, Skeaff and Ferguson 34 ). However, for practical and logistical reasons, only foremilk samples were collected from the participants in the early morning. Therefore, further studies in which multiple samples are collected at different stages of lactation and from different breast milk fractions will be important. Furthermore, we did not collect data on I intake or use of I supplements at 3 months’ postpartum in the present study. Therefore, whether I fortification alone or coupled with I supplements improved I status and BMIC of lactating mothers in Australia is unclear. Women in our study were recruited from two major maternal hospitals in Adelaide, South Australia, however, families where English was not spoken at home were not eligible to take part in the study. Consequently, our results may not be generalisable to mothers and children from a non-English-speaking background.

In conclusion, our findings indicate that the I status of lactating mothers and their infants in South Australia is sufficient post mandatory I fortification. However, I intake of breast-fed infants may be suboptimal if maternal BMIC is <100 µg/l.

Acknowledgements

The authors are grateful to Waite Analytical Service, School of Agriculture, Food and Wine, University of Adelaide for assistance with method development and validation. The authors thank Dr Jennie Louise for assistance with statistical analysis.

B. M. is supported by a Career Development Fellowship, R. G. is supported by a Senior Research Fellowships and M. M. is supported by a Principal Research Fellowship from the National Health and Medical Research Council of Australia (NHMRC). D. H. is sponsored by the Vietnamese Ministry of Education and Training (project 322), the University of Adelaide and FOODplus Research Centre. D. C. is supported by the University of Adelaide, Women’s and Children’s Health Research Institute and Women’s and Children’s Hospital Foundation. This work was supported by the National Health and Medical Research Council (NHMRC, grant no. 626800). This funding body had no role in the design, analysis or writing of this article.

The author contributions are as follows: S. J. Z and M. M. designed and managed the study with input from S. S. and P. R.; D. C. recruited the participants, collected the breast milk and urine samples, D. H. performed breast milk and urine analysis and drafted the manuscript with contributions from all authors. R. G. and B. M. supervised the analysis of breast milk and urine samples. All authors reviewed and approved the manuscript submitted.

R. G. and M. M. received honoraria for scientific advisory board contributions to Fonterra (Auckland, New Zealand). M. M. also received honoraria for scientific advisory board contributions to the Nestle Nutrition Institute (Vevey, Switzerland) and Nutricia. All honoraria are paid to their institutes to support continuing education activities for students and postgraduates. B. M. received honoraria for presentations for ASPEN Nutritionals Australia Pty and Danone Nutrition. The other authors has no conflicts of interest to declare.

Supplementary material

For supplementary material/s referred to in this article, please visit https://doi.org/10.1017/S0007114517001775

References

1. Mullur, R, Liu, YY & Brent, GA (2014) Thyroid hormone regulation of metabolism. Physiol Rev 94, 355382.CrossRefGoogle ScholarPubMed
2. Stagnaro-Green, A & Pearce, EN (2013) Iodine and pregnancy: a call to action. Lancet 382, 292293.Google Scholar
3. United Nations International Children’s Emergency Fund (2008) Sustainable elimination of iodine deficiency. https://www.unicef.org/publications/files/Sustainable_Elimination_of_Iodine_Deficiency.pdf (accessed December 2014).Google Scholar
4. Zimmermann, MB, Gizak, M, Abbott, K, et al. (2015) Iodine deficiency in pregnant women in Europe. Lancet Diabetes Endocrinol 3, 672674.Google Scholar
5. Eastman, CJ & Zimmermann, MB (2009) Iodine deficiency disorders. http://www.thyroidmanager.org/Chapter20/20-frame.htm (accessed February 2011).Google Scholar
6. Food Standards Australia and New Zealand (2008) Proposal P1003 – mandatory iodine fortification for Australia, approved report, Food Standards Australia and New Zealand, Canberra. http://www.foodstandards.gov.au/code/proposals/Pages/proposalp1003mandato3882.aspx (accessed December 2014).Google Scholar
7. Australian Bureau of Statistics (2013) Australian Health Survey: biomedical results for Nutrients 2011–12. http://www.abs.gov.au/ausstats/abs@.nsf/Lookup/4364.0.55.006Chapter1202011-12 (accessed December 2014).Google Scholar
8. Chan, SS, Hams, G, Wiley, V, et al. (2003) Postpartum maternal iodine status and the relationship to neonatal thyroid function. Thyroid 13, 873876.Google Scholar
9. Gunton, JE, Hams, G, Fiegert, M, et al. (1999) Iodine deficiency in ambulatory participants at a Sydney teaching hospital: is Australia truly iodine replete? Med J Aust 171, 467470.Google Scholar
10. Andersson, M, de Benoist, B, Delange, F, et al. (2007) Prevention and control of iodine deficiency in pregnant and lactating women and in children less than 2-years-old: conclusions and recommendations of the Technical Consultation. Public Health Nutr 10, 16061611.Google Scholar
11. Axford, S, Charlton, K, Yeatman, H, et al. (2011) Improved iodine status in breastfeeding women following mandatory fortification. Aust N Z J Public Health 35, 579580.Google Scholar
12. World Health Organization (2007) Assessment of iodine deficiency disorders and monitoring their elimination. http://apps.who.int/iris/bitstream/10665/43781/1/9789241595827_eng.pdf (accessed December 2014).Google Scholar
13. Bazrafshan, HR, Mohammadian, S, Ordookhani, A, et al. (2005) An assessment of urinary and breast milk iodine concentrations in lactating mothers from Gorgan, Iran, 2003. Thyroid 15, 11651168.Google Scholar
14. Hashemipour, M, Nasri, P, Hovsepian, S, et al. (2010) Urine and milk iodine concentrations in healthy and congenitally hypothyroid neonates and their mothers. Endokrynol Pol 61, 371376.Google ScholarPubMed
15. Dold, S, Zimmermann, MB, Baumgartner, J, et al. (2016) A dose-response crossover iodine balance study to determine iodine requirements in early infancy. Am J Clin Nutr 104, 620628.CrossRefGoogle ScholarPubMed
16. Semba, RD & Delange, F (2001) Iodine in human milk: perspectives for infant health. Nutr Rev 59, 269278.Google Scholar
17. Condo, D, Skeaff, S, Ryan, P, et al. (2015) Relationship between maternal and infant thyroid function: a large prospective cohort study. J Paediatr Child Health 51, 59.Google Scholar
18. Huynh, D, Condo, D, Gibson, R, et al. (2017) Comparison of breast-milk iodine concentration of lactating women in Australia pre and post mandatory iodine fortification. Public Health Nutr 20, 1217.Google Scholar
19. Huynh, D, Zhou, SJ, Gibson, R, et al. (2015) Validation of an optimized method for the determination of iodine in human breast milk by inductively coupled plasma mass spectrometry (ICPMS) after tetramethylammonium hydroxide extraction. J Trace Elem Med Biol 29, 7582.Google Scholar
20. National Health & Medical Research Council (2010) NHMRC public statement: iodine supplementation for pregnant and breastfeeding women. http://www.nhmrc.gov.au/guidelines/publications/new45 (accessed July 2012).Google Scholar
21. Semba, RD & Delange, F (2002) Iodine in human milk: perspectives for infant health. Nutr Rev 59, 269278.Google Scholar
22. Liu, L, Wang, D, Liu, P, et al. (2015) The relationship between iodine nutrition and thyroid disease in lactating women with different iodine intakes. Br J Nutr 114, 14871495.Google Scholar
23. Wang, Y, Zhang, Z, Ge, P, et al. (2009) Iodine status and thyroid function of pregnant, lactating women and infants (0-1 yr) residing in areas with an effective Universal Salt Iodization program. Asia Pac J Clin Nutr 18, 3440.Google Scholar
24. Johner, SA, Thamm, M, Schmitz, R, et al. (2016) Examination of iodine status in the German population: an example for methodological pitfalls of the current approach of iodine status assessment. Eur J Nutr 55, 12751282.Google Scholar
25. Zou, Y, Ding, G, Lou, X, et al. (2015) A study on the influencing factors of urinary iodine concentration and the relationship between iodised salt concentration and urinary iodine concentration. Br J Nutr 113, 142146.CrossRefGoogle Scholar
26. Nazeri, P, Mirmiran, P, Hedayati, M, et al. (2016) Can postpartum maternal urinary iodine be used to estimate iodine nutrition status of newborns? Br J Nutr 115, 12261231.CrossRefGoogle ScholarPubMed
27. Pouessel, G, Damie, R, Soudan, B, et al. (2008) Status of iodine nutrition of children until 1 year: consequences on the thyroid function. Arch Pediatr 15, 12761282.CrossRefGoogle ScholarPubMed
28. Yang, J, Zheng, H, Li, X, et al. (2014) Assessment of iodine status and associated factors in vulnerable populations in Henan Province, China, in 2012. Asia Pac J Clin Nutr 23, 626633.Google Scholar
29. Asfaw, A (2007) Micronutrient deficiency and the prevalence of mothers’ overweight/obesity in Egypt. Econ Hum Biol 5, 471483.Google Scholar
30. Boron, WF & Boulpaep, EL (2009) Thyroid hormone synthesis. In Medical Physiology: A Cellular and Molecular Approach, 2nd ed., pp. 10441056 [WF Boron and EL Boulpaep, editors]. Philadelphia, PA: Saunders/Elsevier.Google Scholar
31. Gordon, JH, Leung, AM, Hale, AR, et al. (2014) No difference in urinary iodine concentrations between Boston-area breastfed and formula-fed infants. Thyroid 24, 13091313.Google Scholar
32. Leung, AM, Braverman, LE, He, X, et al. (2012) Breastmilk iodine concentrations following acute dietary iodine intake. Thyroid 22, 11761180.CrossRefGoogle ScholarPubMed
33. Dold, S, Baumgartner, J, Zeder, C, et al. (2016) Optimization of a new mass spectrometry Method for measurement of breast milk iodine concentrations and an assessment of the effect of analytic method and timing of within-feed sample collection on breast milk iodine concentrations. Thyroid 26, 287295.Google Scholar
34. Mulrine, HM, Skeaff, SA, Ferguson, EL, et al. (2010) Breast-milk iodine concentration declines over the first 6 mo postpartum in iodine-deficient women. Am J Clin Nutr 92, 849856.Google Scholar
Figure 0

Table 1 Demographic characteristics of women at study entry (n 696) (Medians and interquartile ranges (IQR); numbers and percentages)

Figure 1

Table 2 Median breast milk iodine concentration (BMIC) and infant urinary iodine concentration (UIC) according to maternal UIC and BMIC category(Medians and interquartile ranges (IQR); numbers and percentages)

Figure 2

Fig. 1 Urinary iodine concentration of mothers () and infants () according to feeding mode.

Figure 3

Table 3 Infant urinary iodine concentrations (UIC), maternal UIC and breast milk iodine concentration (BMIC) according to infant sex, feeding mode and BMI category (Standardised regression coefficients (β) and 95 % confidence intervals; odds ratios and 95 % confidence intervals)

Supplementary material: File

Huynh supplementary material

Tables S1 and S2

Download Huynh supplementary material(File)
File 16.9 KB