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Role of dietary factors in thyroid disorders: A primary care perspective

MD Abu Bashar

MMIMSR, MM Deemed University, Mullana, India

E-mail : bhuvaneswari.bibleraaj@uhsm.nhs.uk

Nazia Begam

ECHS Hospital, Naraingarh, India

DOI: 10.15761/MRI.1000172

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Abstract

Thyroid disorders are one of the most common endocrine problems seen at primary care. Role of dietary factors in their management and prevention is largely unknown with inadequate scientific evidences. In this review, we examine the scientific evidence of the role of various dietary elements in causation, prevention and management of thyroid disorders.

Keywords

thyroid disorders, primary care, dietary factors

Introduction

Thyroid diseases including hypothyroidism, hyperthyroidism, and thyroid nodules are commonly seen in most primary care and endocrinology OPDs. In routine clinical practice, patients suffering from thyroid diseases often enquire about dietary changes they are required to make for treatment or reverse their disease from their healthcare providers. The evidence is strongest for adequate but not excessive iodine intake to benefit thyroid health in general, as well as selenium supplementation for patients with Graves’ disease. Aside from these, there is sparse scientific data showing that dietary changes can significantly benefit hypo- or hyperthyroidism. In this review, we discuss the common diet related factors influencing thyroid function based on the scientific evidences.

Common thyroid disorders

Hypothyroidism

Hypothyroidism affects up to 7% of the general population [1]. Although endemic iodine deficiency is the leading cause of hypothyroidism globally, the most common aetiology of hypothyroidism in developed countries like United States is Hashimoto thyroiditis, an autoimmune condition characterized by positive serum thyroid autoantibody titres and lymphocytic infiltration of the thyroid, which may lead to destruction of thyroid follicular cells, thereby increasing the risk for hypothyroidism.

Levothyroxine as thyroid hormone replacement remains one of the most commonly prescribed medications [2]. Many foods and substances interfere with the intestinal absorption of oral levothyroxine [3] and hence patients are advised to take the medication separately from mealtimes [4].

The majority of patients with hypothyroidism experience symptomatic improvement upon treatment with thyroid hormone replacement. However, some may continue to report hypothyroid symptoms despite the achievement of biochemical euthyroidism [5,6]. Others are dissatisfied with the current available options and seek alternative therapies [7,8]. As such, patients may seek dietary interventions to ameliorate symptoms or reverse their hypothyroidism.

Popular interventions include supplementation with various micronutrients, vitamins, or minerals, or restricted intake of certain foods or food groups. Given the role of Hashimoto thyroiditis in the development of hypothyroidism, possible intervention to specifically decrease serum thyroid autoantibody titers is a common inquiry.

Hyperthyroidism

Hyperthyroidism is present in up to 1.3% of the general population.1 Graves’ disease is the leading cause of hyperthyroidism globally, but other aetiologies include toxic nodular goitre and the hyperthyroid phase of thyroiditis. Conventional therapies for the treatment of hyperthyroidism are anti-thyroid medications, radioactive iodine treatment, and thyroid surgery, each with their respective potential risks and benefits [9].

Serum thyroid-stimulating antibodies drive the onset and course of Graves’ disease. Dietary iodine and selenium are micronutrients that can modify the thyroid antibody titers. Further, iodine status is an important consideration in individuals with thyroid nodules who are at risk for iodine-induced hyperthyroidism.

Thyroid nodules

Thyroid nodules are detected incidentally on radiologic imaging. Criteria based on a combination of nodule size and sonographic characteristics inform the decision to pursue a thyroid nodule fine-needle aspiration biopsy, as there is an overall risk for malignancy of only 7%-15% in all nodules [10]. Thyroid surgery is recommended if malignancy is highly suspected or confirmed, or if benign nodules are large enough to be associated with compressive symptoms to the anterior neck. Biopsy-benign or nonsuspicious nodules are monitored by ultrasound at regular intervals. Given the chronicity of monitoring needed for benign nodules, patients commonly seek dietary or other modalities to decrease the size of their thyroid nodules.

Specific dietary influences on thyroid functioning

Iodine

The production of thyroid hormone within the thyroid follicular cell requires adequate levels of circulating iodide taken in through the diet. The Recommended Dietary Allowance (RDA) for iodine is 150 µg/day in adults, and 220 µg/day and 290 µg/day in pregnant and lactating women, respectively [11]. Common dietary sources of iodine include iodized salt, seafood (including seaweed and fish), and some breads and grains.

Although eating a regular diet should meet nutritional iodine needs, some individuals may require supplementation in order to achieve RDA goals. Individuals with restricted diets, such as vegetarians and vegans, are at higher risk for inadequate iodine intake because vegetables are not a rich source of iodine [12].

Some "iodine for thyroid health" tablets, which are commonly available over the counter, may contain several hundred-fold the daily recommended amount of iodine in just a single dose. Other products labelled "for thyroid support" include tablets or liquid supplements containing spirulina (a superfood derived from blue-green algae) or kelp.

Taking supplements with high iodine content is unlikely to help the thyroid health, and in fact may even pose harm. In some individuals, excess iodine exposure or ingestion may induce hyperthyroidism or hypothyroidism [13], and chronic iodine excess may induce autoimmune thyroiditis, as highly iodinated thyroglobulin is immunogenic [14]. Iodine-induced thyroid dysfunction is found to be common in those who have a history of endemic iodine deficiency or pre-existing thyroid disease [15]. For this reason, the American Thyroid Association recommends avoiding supplements containing >500 µg/day of iodine [16].

Goitrogens

The term "goitrogen" refers to any substance that can produce goitre, the enlargement of the thyroid gland. This is usually accomplished through effects that decrease thyroidal iodine, but goitrogenic substances can also act by inhibiting any of the other components of normal thyroid hormone production. The most common examples of dietary goitrogens are cruciferous vegetables and soy products.

Cruciferous vegetables

Cruciferous vegetables are those in the Brassica genus and include broccoli, cabbage, Brussels sprouts, kale, turnips, cauliflower, collard greens, and bok choy. They are rich in glucosinolates, compounds that produce sulforaphane and the phenethyl and indolylic isothiocyanates associated with anticancerous properties [17]. However, glucosinolates also include the metabolite thiocyanate, which inhibits thyroid hormone production [17]. Thus, although eating cruciferous vegetables certainly has many health benefits, regular consumption of large quantities may induce or exacerbate hypothyroidism.

Data on the quantity of cruciferous vegetable consumption needed to adversely affect thyroid function are limited. In a study of five euthyroid volunteers who ingested 15.2 ozs of a commercial kale juice twice per day for 7 days, mean 6-hour thyroid radioiodine uptake decreased by 2.52% compared with baseline values, however serum thyroid function tests were unchanged [18]. It would be of much interest to see the results of a study with longer-term ingestion with larger amounts of kale consumed.

In a life-threatening example, one case report described the development of myxoedema coma in an 88-year-old Chinese woman who consumed 1.0-1.5 kg of raw bok choy daily for several months in an attempt to improve her diabetes control [19]. The data suggest that frequent intake of large amounts of cruciferous vegetables may decrease thyroid hormone production, however no rigorous clinical studies exist to support the need to stop eating them.

Soy

Dietary soy products—including soy milk, tofu, soy sauce, tempeh, and miso—contain isoflavones. As isoflavones can inhibit the action of thyroid peroxidase, an important enzyme required for thyroid hormone synthesis, it has been proposed that dietary soy intake may increase the risk for hypothyroidism in euthyroid individuals or that a higher dose of thyroid hormone replacement may be required in patients being treated for hypothyroidism.

The available literature shows that in euthyroid individuals living in iodine-replete areas, consumption of soy probably has no adverse effects on serum thyroid function [20]. An exception is when soy-based infant formula is used for neonates with congenital hypothyroidism; an increase in dose of levothyroxine may be required to adequately address thyroid hormone needs [21].

Other trace minerals

Data on other trace minerals apart from iodine and their effects on thyroid status are more inconsistent [22].

Selenium: Selenium is a micronutrient important for thyroid hormone metabolism. The US RDA of selenium in men and non-pregnant, non-lactating women is 55 µg [23]. The richest dietary sources of selenium are seafood and organ meats. Typical sources in the diet are breads, grains, meat, poultry, fish, and eggs.

The tolerable upper intake level for selenium is 400 µg/day [23]. Although selenium toxicity is not commonly encountered in routine clinical practice, symptoms include nausea; nail discoloration, brittleness, and loss; hair loss; fatigue; irritability; and foul breath (often described as "garlic breath").

Some studies have shown benefit from selenium supplementation in individuals with autoimmune thyroid disease, and low selenium levels have been associated with increased risk for goitre and thyroid nodules in European women [24]. In areas of severe selenium deficiency, supplementation up to 100 µg/day may be beneficial [25]. From the available evidence, however, routine selenium supplementation in individuals following unrestricted diets for the purpose of treating Graves’ disease [26,27], decreasing serum thyroid antibody titers, or maintaining normal thyroid function is mostly unsupported.

It is hence not routinely recommended selenium supplementation for the sole purpose of benefiting thyroid health. One exception is patients with mild Grave’s ophthalmopathy, in whom selenium supplementation may improve quality of life and the course of ocular disease [28]. Supplementation in these patients is recommended by the European Thyroid Association/European Group on Graves' Orbitopathy as a 6-month course [29].

Other trace elements: The roles of zinc, copper, and magnesium in thyroid hormone synthesis and metabolism are even less well defined. In the US National Health and Nutrition Examination Survey (2011-2012), levels of zinc, copper, and selenium were inconsistently associated with free or total serum thyroid hormone levels [30], whereas a meta-analysis of eight studies suggested a relationship between levels of selenium, copper, and magnesium with thyroid cancer [31]. Given the available scientific evidence, supplementation of these trace minerals solely for the purpose of promoting thyroid function is not generally supported.

Other dietary considerations for thyroid

Finally, a number of many other dietary factors, less rigorous—and in some cases with absent—scientific data, are proposed to affect thyroid health. Although coffee decreases the absorption of oral levothyroxine in individuals being treated for hypothyroidism, coffee, tea, and alcohol appear to have no effect on risk of thyroid cancer risk [32,33]. The potential role of vitamin D as a preventive or therapeutic agent for various thyroid diseases remains unclear [34].

Popular in the functional medicine community are interventions to treat leaky gut syndrome, the theory of increased intestinal permeability leading to various diseases. Gluten-free diets, sugar-free diets, and probiotics are advocated for promoting thyroid health. Although one small study demonstrated decreased serum thyroid antibody titers among 34 women who followed a gluten-free diet for 6 months [35], published data in the scientific literature on the effects of these interventions on thyroid health are lacking.

Conclusion

Apart from the definitive role of iodine and selenium deficiency in causation of hypothyroidism, the role of other dietary factors in affecting thyroid health remains inconclusive based on available scientific evidences. Much remains unknown about thyroid disease and that there are areas of uncertainty in modern medicine for which continued research is required.

References

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Editorial Information

Editor-in-Chief

Article Type

Review Article

Publication history

Received: February 07, 2020
Accepted: February 21, 2020
Published: February 23, 2020

Copyright

©2020 Abu Bashar MD. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Citation

MD Abu Bashar (2020) Role of dietary factors in thyroid disorders: A primary care perspective. Med Res Innov 4: DOI: 10.15761/MRI.1000172.

Corresponding author

Dr. MD Abu Bashar

Assistant Professor, MMIMSR, MM Deemed University, Mullana, Ambala, Haryana, India, Tel: 9501576052

E-mail : bhuvaneswari.bibleraaj@uhsm.nhs.uk

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