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Invited commentary in response to the paper entitled ‘Iodine concentration of milk-alternative drinks available in the UK in comparison with cows’ milk’ by Sarah Bath and colleagues

Published online by Cambridge University Press:  28 November 2017

André F. Brito*
Affiliation:
Department of Agriculture, Nutrition, and Food Systems, University of New Hampshire, Durham, NH 03824, USA
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Abstract

Type
Invited Commentary
Copyright
Copyright © The Author 2017 

It is well recognised that iodine deficiency may increase the risks for goiter, hypothyroidism, decreased fertility, obesity, psychiatric disorders, fibromyalgia and a variety of cancers due to impaired functions of triiodothyronine and thyroxine( Reference Verheesen and Schweitzer 1 Reference Ma, He and Braverman 4 ). Adequate iodine intake is particularly important for pregnant and nursing women, as iodine is essential for neural development in the growing fetus and newborn( Reference Zimmermann 2 , Reference Zimmermann 3 ). Globally, it is estimated that approximately 2 billion people have inadequate iodine intake( Reference de Benoist, McLean and Andersson 5 ). Despite noticeable progress in controlling iodine deficiency worldwide since 2003( Reference de Benoist, McLean and Andersson 5 ), decline in milk consumption, a major iodine source in the UK, combined with changes in dietary choices and consumer behaviour may negatively affect the iodine status of the British population. For instance, the rapid growth of milk-alternative drinks consumption in the UK( 6 ) is raising concerns about whether these products are suitable substitutes for dairy cows’ milk regarding iodine provision. Emerging British research have begun to unravel this question and how milk-alternative drinks may impact consumers’ health( Reference Bath, Hill and Infante 7 ).

Recently in the British Journal of Nutrition, a group of researchers from the University of Surrey led by Dr Margaret Rayman reported a comparison between the iodine concentration of retail milk-alternative drinks and that of dairy cows’ milk, the first study of its kind in the UK( Reference Bath, Hill and Infante 7 ). Specifically, the iodine concentration of seven types of milk-alternative drinks (soya, almond, coconut, oat, rice, hazelnut and hemp) or forty-seven products was determined via inductively coupled plasma-MS. Their results revealed that the median iodine concentration of forty-four non-iodine-fortified milk-alternative drinks was quite low (7·3 μg/kg) or only 2·1 and 3·1 % of that detected in all-season conventional (median 344 μg/kg) and organic (median 234 μg/kg) milk, respectively. However, the concentration of iodine in three iodine-fortified soya, oat and rice products, all from the same brand, averaged 278 μg/kg and was equivalent to 81 and 119 % of the median iodine content reported for all-season conventional and organic milk, respectively. Authors pointed out that the amount of iodine (range from 0·9 to 4·3 μg) provided by a glass (200 ml) of unfortified milk-alternative drinks is negligible relative to the adult iodine recommendation of 150 μg/d( 8 , 9 ), thereby indicating that these products are not suitable substitutes for cows’ milk. Thus, consumers of unfortified milk-alternative beverages should be aware of the potential health implications of insufficient iodine intake, especially those with greater risks for iodine deficiency such as pregnant and lactating women, school-age children and vegans( Reference Ma, He and Braverman 4 , Reference Bath, Steer and Golding 10 , Reference Bath and Rayman 11 ). On the other hand, a glass of iodine-fortified soya, oat and rice drinks would provide, on average, 55 μg of iodine or approximately 37 % of adults’ iodine recommended intake of 150 μg/d( 8 , 9 ). Authors concluded that fortified milk-alternative drinks could be considered reasonable replacements for cows’ milk in terms of iodine provision.

Rayman and co-authors also presented results about the differences in iodine concentration between organic and conventional milk. They stated that the lower iodine concentration in organic v. conventional milk is likely caused by restrictions on mineral-fortified concentrates in organic farming and reliance on white clover (Trifolium repens L.) to ‘fix’ N in place of prohibited chemical and synthetic fertilisers. Cyanogenic glucosides present in white clover can be converted to thiocyanate, which compete for transportation sites on the sodium-iodide symporter( Reference De La Vieja, Dohan and Levy 12 Reference Flachowsky, Franke and Meyer 14 ), ultimately reducing the transfer of iodine into milk. In addition to differences in iodine concentration between milk sources, authors discussed the potential health implications, including iodine-induced thyroid dysfunction( Reference Crawford, Cowell and Emder 15 ), in response to supplementation of milk-alternative drinks with extract from the brown seaweed kombu (Saccharina japonica). In fact, Food Standards Australia New Zealand( 16 ) recalled batches of a kombu-fortified soya drink containing extremely high iodine concentration (25 000 μg/l)( Reference Crawford, Cowell and Emder 15 ). Feeding the brown seaweed Ascophyllum nodosum meal to cows, a supplement very popular in the organic dairy sector in the USA( Reference Antaya, Soder and Kraft 17 Reference Sorge, Moon and Wolff 19 ), also raises health concerns. For instance, a glass of milk from organic-certified Jersey cows fed 57, 113 or 170 g/d of A. nodosum meal( Reference Antaya, Soder and Kraft 17 ) would result in 121, 203 and 274 μg/d of iodine intake, respectively, or 81, 135 and 183 % of the adult iodine recommendation of 150 μg/d( 8 , 9 ).

Rayman and colleagues’ study is the largest systematic evaluation of milk-alternative drinks in the UK and the first to report the iodine concentration of oat and hazelnut beverages. Their research is timely needed as the consumption of milk-alternative drinks is growing in a fast pace not only in the UK( 6 ) but also in the USA( Reference Copeland and Dharmasena 20 ), and similar growth patterns may be underway in other industrialised or developing societies worldwide. Authors demonstrated using state-of-art analytical approach (inductively coupled plasma-MS) that the iodine concentration of non-iodine-fortified milk-alternative drinks is extremely low, indicating that companies commercialising these beverages should consider fortification measures to mitigate potential iodine deficiency in certain groups of people. At the time of Rayman-led study, only one manufacturer (not the market leader) was fortifying some of their products. Overall, iodine nutrition is very complex as iodine deficiency or excess can lead to serious implications to human health. Therefore, emerging food sources and industries should be scrutinised through scientific and legislative approaches so consumers’ health are not put at risk.

Acknowledgements

The author reports no conflict of interest.

References

1. Verheesen, RH & Schweitzer, CM (2008) Iodine deficiency, more than cretinism and goiter. Med Hypot 71, 645648.CrossRefGoogle ScholarPubMed
2. Zimmermann, MB (2009) Iodine deficiency. Endocr Rev 30, 376408.CrossRefGoogle ScholarPubMed
3. Zimmermann, MB (2009) Iodine deficiency in pregnancy and the effects of maternal iodine supplementation on the offspring: a review. Am J Clin Nutr 89, Suppl., 668S672S.CrossRefGoogle ScholarPubMed
4. Ma, WS, He, X & Braverman, LE (2016) Iodine content in milk alternatives. Thyroid 26, 13081310.CrossRefGoogle ScholarPubMed
5. de Benoist, B, McLean, E, Andersson, M, et al. (2008) Iodine deficiency in 2007: global progress since 2003. Food Nutr Bull 29, 195202.CrossRefGoogle ScholarPubMed
6. Kantar Worldpanel (2017) GB liquid milk expenditure and volume sales. Comparing the 52 w/e 03 Jan 2016 and the 52 w/e 01 Jan 2017. https://dairy.ahdb.org.uk/market-information/dairy-sales-consumption/liquid-milk-market/#.WKxQW2_yhaQ (accessed September 2017).Google Scholar
7. Bath, SC, Hill, S, Infante, HG, et al. (2017) Iodine concentration of milk-alternative drinks available in the UK in comparison with cows’ milk. Br J Nutr 118, 525532.CrossRefGoogle ScholarPubMed
8. World Health Organization, United Nations International Children’s Emergency Fund & International Council for the Control of Iodine Deficiency Disorders (2007) Assessment of Iodine Deficiency Disorders and Monitoring Their Elimination. Geneva: WHO.Google Scholar
9. European Food Safety Authority (2014) Scientific opinion on dietary reference values for iodine. EFSA J 12, 3660.Google Scholar
10. Bath, SC, Steer, CD, Golding, J, et al. (2013) Effect of inadequate iodine status in UK pregnant women on cognitive outcomes in their children: results from the Avon Longitudinal Study of Parents and Children (ALSPAC). Lancet 382, 331337.CrossRefGoogle ScholarPubMed
11. Bath, SC & Rayman, MP (2015) A review of the iodine status of UK pregnant women and its implications for the offspring. Environ Geochem Health 37, 619629.CrossRefGoogle ScholarPubMed
12. De La Vieja, A, Dohan, O, Levy, O, et al. (2000) Molecular analysis of the sodium/iodide symporter: impact on thyroid and extrathyroid pathophysiology. Physiol Rev 80, 10831105.CrossRefGoogle ScholarPubMed
13. Laurberg, P, Andersen, PH, Knudsend, N, et al. (2002) Thiocyanate in food and iodine in milk: from domestic animal feeding to improved understanding of cretinism. Thyroid 12, 897902.CrossRefGoogle ScholarPubMed
14. Flachowsky, G, Franke, K, Meyer, U, et al. (2014) Influencing factors on iodine content of cow milk. Eur J Nutr 53, 351365.CrossRefGoogle ScholarPubMed
15. Crawford, BA, Cowell, CT, Emder, PJ, et al. (2010) Iodine toxicity from soy milk and seaweed ingestion is associated with serious thyroid dysfunction. Med J Aust 193, 413415.CrossRefGoogle ScholarPubMed
16. Food Standards Australia New Zealand (2009) National product recall – Bonsoy soy milk with very high levels of iodine. 24 December. http://www.foodstandards.gov.au/media/Pages/mediareleases/mediareleases2009/nationalproductrecal4651.aspx (accessed October 2017).Google Scholar
17. Antaya, NT, Soder, KJ, Kraft, J, et al. (2015) Incremental amounts of Ascophyllum nodosum meal do not improve animal performance but do increase milk iodine output in early lactation dairy cows fed high-forage diets. J Dairy Sci 98, 19912004.CrossRefGoogle Scholar
18. Hardie, CA, Wattiaux, M, Dutreuil, M, et al. (2014) Feeding strategies on certified organic dairy farms in Wisconsin and their effect on milk production and income over feed costs. J Dairy Sci 97, 46124623.CrossRefGoogle ScholarPubMed
19. Sorge, US, Moon, R, Wolff, LJ, et al. (2016) Management practices on organic and conventional dairy herds in Minnesota. J Dairy Sci 99, 31833192.CrossRefGoogle ScholarPubMed
20. Copeland, A & Dharmasena, S (2015) Consumer demand for dairy alternative beverages in the United States and its implications to U.S. dairy industry. In 2015 Agricultural and Applied Economics Association and Western Agricultural Economics Association Joint Annual Meeting, San Francisco, CA, 26–28 July 2015. http://ageconsearch.umn.edu/record/205334/files/Dharmasena_Copeland%20Dairy%20Alternatives%20AAEA%202015%20May%2027.pdf (accessed September 2017).Google Scholar