Iodine deficiency in ambulatory participants at a Sydney teaching hospital: is Australia truly iodine replete?

The recommended daily intake (RDI) of iodine is 100 µg daily for the general population and 150-200 µg daily for women who are pregnant or breastfeeding^6-8,10 (iodine demand increases during pregnancy because of increased renal clearance and fetal iodine transfer).

Approximately 90% of iodine is excreted in the urine,^1,11 and iodine status is usually assessed by measuring urinary iodine concentration.

The accepted minimum adequate level of urinary iodine is 100 µg/L, and levels above this are considered normal.^1,6-9,12 Urinary iodine concentrations below 25 µg/L are classified as severe deficiency, and are associated with an increased risk of cretinism; 26-50 µg/L is classified as moderate deficiency, and 51-100 µg/L is regarded as mild iodine deficiency.^1,6-9,12 The World Health Organization (WHO) recommends that the median urinary iodine concentration for populations as a whole should be more than 100 µg/L, that less than 20% of the population should have a urinary iodine concentration below 50 µg/L, and that no cretinism occurs.¹²

Having previously found low levels of free thyroxine in pregnant women,¹³ and in light of the adverse consequences of iodine deficiency during pregnancy, we initially set out to test the iodine status of a group of pregnant women. We subsequently included other groups to widen our investigation of iodine status.

Participants thus comprised 81 consecutive pregnant women who attended the obstetric clinic between 1 August 1998 and 1 April 1999, 26 of these same women who were reassessed at three months postpartum, 135 consecutive patients who attended the diabetes clinic for an annual complications screen between 1 November 1998 and 1 February 1999, and 19 volunteers recruited between 1 February and 1 July 1999. All participants provided a routine urine sample. There were no exclusion criteria.

One of the 81 pregnant women had thyrotoxicosis as a result of Graves' disease -- she particpated before commencing therapy. Twenty-two of the patients attending the diabetes clinic (16.1%) had type 1 diabetes, 103 (76.3%) had type 2 diabetes and 10 (7.5%) had impaired glucose tolerance.

One of the patients with diabetes had recently received iodine-containing intravenous contrast medium during a coronary angiogram, and one was taking amiodarone. No other participant was known to have received contrast medium, or to be taking amiodarone or iodine supplements.

Some investigators use the urinary iodine/creatinine ratio to determine iodine status.^1,14 We thus measured urinary creatinine by the Creatinine Jaffa method (Boehringer Mannheim Systems, Mannheim, Germany) and calculated iodine/creatinine ratios (µg iodine/g creatinine) for each participant. The correlation between urinary iodine and iodine/creatinine ratio was high for non-pregnant participants (r = 0.969; P < 0.001) and lower for the pregnant group (r = 0.419; P < 0.001).

Twenty-four-hour urinary iodine measurement may be used to assess iodine status,⁶ but this method can be unreliable because of incorrect or incomplete collection,¹⁵ and is less practical than spot samples for population surveys.^9,12 To compare this method with our spot sampling, we selected six pregnant women (on the basis of their spot urine concentrations to cover a range of values) who collected 24-hour urine samples for iodine content measurement. The correlation was highly significant (r² = 0.82), thus confirming that spot urine samples were a reliable way of measuring iodine status.

As part of routine care, 70 of the 81 pregnant women and 121 of the 135 patients with diabetes had thyroid function tests. Free thyroxine (FT₄) and thyroid-stimulating hormone (TSH) levels were measured by means of an automated chemiluminescence system (Chiron Diagnostics, Scoresby, Vic.).

We did not seek ethical approval for this study as it involved no deviation from usual care, except in the case of the 19 volunteers who agreed to provide a urine sample.

The median iodine concentration in the 26 postpartum women (79 µg/L) who provided repeat urine samples for iodine measurement three months after delivery was considerably lower than that in the 81 pregnant women (104 µg/L). However, this difference was not statistically significant (P = 0.249).

The patient with diabetes who had received iodine-containing intravenous contrast medium during a coronary angiogram in the month before the urinary spot test had a urinary iodine concentration of 2170 µg/L.

Box 5 shows TSH levels and FT₄ levels versus iodine status in pregnant and non-pregnant participants. There was no significant relationship between iodine status and FT₄ or TSH levels in either the pregnant group or non-pregnant group. Separate analysis of patients with diabetes and postpartum women did not significantly alter these results. However, there was a weak correlation between FT₄ and urinary iodine levels when examined as a continuous variable (Pearson correlation coefficient, 0.26; P = 0.016).

Our findings mirror recent reports from other countries.^9,11,20 A United States study showed that the median urinary iodine concentration in 1988-1994 had decreased by more than 50% from that in 1971-1974.^9,11 The 1988-1994 results showed 11.7% of the US population to be iodine deficient (a 4.5-fold increase since 1971-1974). The mean urinary iodine concentration in that population was 265 µg/L, and people from higher socioeconomic groups were more likely to be iodine deficient. Our data may also reflect this effect, as, although our patients were attending a public clinic, the hospital catchment area is a relatively high socioeconomic group. Our data suggest that Australia may be experiencing a similar trend to that seen in the US.

Iodine deficiency during pregnancy can affect the thyroid glands of both the mother and baby,^10,17-19 and may have many adverse health consequences (Box 1). Some, but not all, researchers have found an increase in urinary iodine levels during pregnancy.^10,17-19 Smyth et al studied urinary iodine concentration in a group of pregnant women in an area of Ireland with known borderline iodine deficiency.¹⁰ In the third trimester, they found a mean urinary iodine concentration of 132 µg/L (standard error of the mean, 6.8), and found that urinary iodine concentration increased during pregnancy. In a more iodine-deficient area, Glinoer et al found that urinary iodine concentration did not increase during pregnancy (median iodine concentration 45 µg/L after 20 weeks' gestation, no mean given).¹⁹ So, it is not clear whether the apparently higher levels in our pregnant women were pregnancy related or, in fact, masked iodine deficiency in pregnancy.

We found that a considerable percentage of pregnant women (4.9%) were severely iodine deficient, with spot urine results of < 25 µg/L. While this is the threshold below which cretinism may occur, other factors, such as selenium deficiency and the presence of dietary goitrogens, also play a part in determining cretinism,²¹ and these two factors are not usually seen in Sydney. Therefore, we would not expect to see an increased incidence of cretinism in Sydney on the basis of these results alone. However, more subtle adverse fetal outcomes may occur.

Our findings suggest that we should no longer automatically consider Australia an iodine-replete country. We found that iodine deficiency was common among 235 people attending a Sydney teaching hospital and speculate that these data are applicable to the general population, although this will require independent confirmation. The frequency of iodine deficiency in our pregnant population (18.8%) approaches the maximum acceptable level recommended by WHO (20%); this recommendation was exceeded in our group with diabetes (34.1%) and the normal volunteers (26.3%). The postpartum women had a median iodine concentration of 79 µg/L, which is lower than the WHO recommendation of 100 µg/L. This has important public health implications.

The weaknesses of this study include the small group of normal volunteers, and perhaps the use of a sample from a teaching hospital rather than the community. The normal volunteers had results which are equivalent to those seen in postpartum women and non-pregnant patients with diabetes. Our subjects were all ambulatory, not inpatients at the time of testing, and generally well. Although 24-hour urinary iodine excretion studies may be the ideal method of assessing iodine status, these are not generally performed in large numbers for a variety of technical and practical reasons.

A weak correlation between urinary iodine and free thyroxine was observed for all non-pregnant participants in total, and for the participants with diabetes mellitus. Because of the large number of other factors which influence thyroid function (including pregnancy),¹³ the relatively loose correlations are an expected finding.

Further studies are needed, and these include (i) population surveys in Sydney and elsewhere in Australia; (ii) assessment of thyroid size (eg, by ultrasound) in relation to iodine status; and (iii) detailed assessment of neonates, including thyroid size, neonatal TSH levels, and detailed neurological outcomes.

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Reprints: Dr J E Gunton, C/- Clinic 1, Royal North Shore Hospital, St Leonards, NSW 2065.
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