health report

C ardiologists encounter thyroid disor- ders frequently. Hyperthyroidism causes and may present with atrial

fibrillation, while hypothyroidism is a risk factor for coronary artery disease. Moreover, the use of amiodarone may precipitate a variety of thyroid disorders, and severe heart disease, such as left ventricular failure or acute myocar- dial infarction, can cause confusing distur- bances in thyroid function tests.

Hyperthyroidism

Hyperthyroidism is a common condition with a prevalence of approximately 1%; it aVects pre- dominantly women aged 30–50 years and is usually (70%) caused by Graves’ disease which is characterised by diVuse goitre, orbitopathy, pretibial myxoedema, and the presence of stimulating thyrotrophin (TSH) receptor anti- body in the serum. Most of the remaining cases (20%) are caused by autonomous production of thyroid hormones by a nodular goitre.

Effects of thyroid hormones on the cardiovascular system The thyroid secretes two active hormones: thy- roxine (T4) which is a prohormone and tri-iodothyronine (T3) which acts as the final mediator. In hyperthyroidism there is excessive

production of T3, owing to hypersecretion by the thyroid gland, and an increase in the peripheral monodeiodination of T4, which leads to profound changes in the cardiovas- cular system through both nuclear and non- nuclear actions at the cellular level.1

The interrelation between the direct and indirect actions of T3 on the peripheral circu- lation and the heart is shown in fig 1.2 Myocar- dial contractility is increased as a result of a change in the synthesis of myosin heavy chain protein from the â to the á form, increased transcription of the calcium ATPase gene, and enhanced calcium and glucose uptake. These changes make contraction less eYcient and increase heat production. Afterload is reduced, with a reduction of as much as 50–70% in sys- temic vascular resistance, caused by the direct eVects of T3 and the indirect eVects of excess lactate production (increased tissue thermo- genesis) on vascular smooth muscle. Blood flow, particularly to skin, muscle, and heart, is therefore greatly increased. The preload of the heart rises because blood volume is expanded owing to increases in the serum concentrations of angiotensin converting enzyme and erythro- poietin, with resultant increases in renal sodium absorption and red cell mass.

Hyperthyroidism is characterised by a high left ventricular ejection fraction (LVEF) at rest but, paradoxically, by a significant fall during exercise. Restoration of euthyroidism is accom- panied by the anticipated rise in LVEF on exercise at the same workload and heart rate.3

This reversible “cardiomyopathy” could ex- plain the reduced exercise tolerance of patients with hyperthyroidism. Rather than being an intermediate state between normal left ven- tricular function and left ventricular dysfunc- tion at rest, the failure of LVEF to increase on exercise is perhaps better viewed as a conse- quence of the additional burden of exercise induced increase in afterload on a heart performing near its maximum capacity.

The characteristic tachycardia is caused by a combination of more rapid diastolic depolari- sation and shortening of the action potential of the sinoatrial cells. The refractory period of the atrial cells is also shortened which may explain the well known propensity to atrial fibrillation.

There is a complex interaction between thy- roid hormones and the adrenergic system, and many of the clinical features of hyperthy- roidism such as tachycardia, increased pulse pressure, and tremor resemble the heightened â adrenergic state of phaeochromocytoma. However, serum and urinary catecholamine concentrations are normal or even low in hyperthyroidism, and there is no good evidence of greater sensitivity to catecholamines despite an increased density of â1 adrenoceptors in cardiac muscle. It may well be that thyroid hormones and catecholamines act independ- ently at the cellular level but share a signalling pathway. This would explain why non-selective â adrenoceptor antagonists, such as pro- pranolol or nadolol, improve but do not abolish many of the symptoms of hyperthyroidism.

GENERAL CARDIOLOGY

Thyroid disease and the heart

A D Toft, N A Boon Endocrine Clinic, and Department of Cardiology, Royal Infirmary,

Edinburgh, UK

Figure 1. Effects of hyperthyroidism on the cardiovascular system and the possible outcomes. TBV, total blood volume; LVEDV, left ventricular end diastolic volume; LVESV, left ventricular end systolic volume; SV stroke volume; SVR systemic vascular resistance; CO, cardiac output; ↑ increased; ↓ decreased. Solid arrows indicate direct effects, and dashed arrows potential outcomes. *Features for which T3 is directly responsible.

Heart 2000;84:455–460

455

Correspondence to: Dr A D Toft, Endocrine Clinic, Royal Infirmary, Edinburgh EH3 9YW, UK

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Clinical features Most patients with hyperthyroidism complain of palpitations and breathlessness on exertion, although symptoms such as weight loss in the presence of a normal or increased appetite, heat intolerance, and irritability tend to pre- dominate. Established angina may become worse and may, exceptionally, be a new development. Myocardial ischaemia is presum- ably caused by the increased demands of the thyrotoxic myocardium. However, coronary spasm may be an additional factor and myocardial infarction can occur in the absence of significant atheroma.4 The ECG is usually normal but in severe hyperthyroidism there may be impressive ST-T wave changes in the absence of ischaemic chest pain (fig 2).

Characteristically there is a sinus tachycardia of approximately 100 per minute with a good volume, often collapsing pulse, and a wide pulse pressure. The apex beat is forceful, flow murmurs are common, and there may be a bruit over the enlarged thyroid gland. Mild ankle oedema is common but is rarely caused by cardiac failure and is, in part, a manifesta- tion of the reduced day:night ratio of urinary sodium excretion by the kidneys.

Overt cardiac failure is uncommon in hyper- thyroidism and usually occurs in the context of rapid atrial fibrillation in an elderly patient with pre-existing ischaemic or valvar heart disease. Nevertheless, high output failure is a rare but recognised complication of severe thyrotoxico- sis.

Atrial fibrillation A variety of atrial and ventricular tachycardias have been described in hyperthyroidism, but the most common arrhythmia is atrial fibrilla- tion. In unselected series 10–15% of patients with thyrotoxicosis were in atrial fibrillation at presentation; however, the prevalence is prob- ably falling because the widespread availability of accurate tests of thyroid function means that hyperthyroidism is now diagnosed at an earlier stage in its natural history. Atrial fibrillation is rare in patients under 40 years of age unless there is longstanding severe thyrotoxicosis or coexistent structural heart disease. The preva- lence increases with age and is higher in men such that in the authors’ experience 50% of hyperthyroid males over the age of 60 are in atrial fibrillation at presentation.

In one series, 13% of patients with “idio- pathic” or “lone” atrial fibrillation attending a cardiology clinic were found to have overt or subclinical hyperthyroidism; the discovery of atrial fibrillation, in the absence of an obvious cause, should therefore prompt a request for thyroid function testing.5

Atrial fibrillation may be the dominant feature of hyperthyroidism in older patients and is not necessarily accompanied by pro- nounced elevation of the serum concentrations of T3 and T4. Increases of thyroid hormones within their respective reference ranges associ- ated with a suppressed serum TSH concentra- tion (subclinical hyperthyroidism) may be suf- ficient to trigger atrial fibrillation in susceptible individuals.6 In the Framingham study, for

example, a low serum TSH was associated with a threefold increase in the incidence of atrial fibrillation among clinically euthyroid elderly subjects, 28% of whom developed atrial fibril- lation during 10 years of follow up.7

Sixty per cent of patients with hyperthyroid atrial fibrillation will revert spontaneously to sinus rhythm within a few weeks of restoration of normal tests of thyroid function; approxi- mately half of the remainder will respond to DC cardioversion if serum TSH concentra- tions are normal or raised at the time of the procedure. Failure to achieve stable sinus rhythm is most likely in those in whom the diagnosis of hyperthyroidism has been delayed. These are usually patients with mild hyperthy- roidism caused by a small multinodular goitre in whom only serum T3 may be elevated (T3 toxicosis) and in whom other useful diagnostic features, such as ophthalmopathy or major weight loss, are missing.

Hyperthyroid atrial fibrillation is typically resistant to digoxin, caused in part by an increase in the renal clearance and the apparent volume of distribution of the drug. It is often necessary to add a non-selective â adrenocep- tor antagonist to achieve adequate rate control.

Figure 2. (A) ECG in a 48 year old woman in whom there was an exacerbation of hyperthyroidism 72 hours after treatment with iodine131. (B) The pronounced ST changes slowly resolved and the tracing was normal three months after the patient became euthyroid.

LOC 00000–0000 Speed: 25 mm/sec Limb: mm/mV Chest: 10 mm/mV F 50~ 0.5 – 100 Hz W 05744

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Anticoagulation Systemic embolisation is increased in hyper- thyroid atrial fibrillation, but the risk is diYcult to quantify with estimates in cross sectional studies ranging from 2–20%. Patients over 50 years of age with valvar or hypertensive heart disease would appear to be at greatest risk. Whether younger patients with structurally normal hearts benefit from anticoagulation is not known, but a decision to withhold warfarin would be more secure if there was no evidence of atrial thrombus at transoesophageal echo- cardiography. As the development of a dense hemiplegia complicating a readily reversible metabolic disorder is a clinical disaster, it is our policy to consider anticoagulation with warfa- rin (target international normalised ratio (INR) 2–3:1) in all patients with hyperthyroid atrial fibrillation. Anticoagulant control may be diYcult because hyperthyroidism is associated with an increased sensitivity to warfarin.8

Treatment of hyperthyroidism Radioiodine (iodine131) is the treatment of choice in patients over 40 years of age, but in younger patients most centres adopt the empirical approach of prescribing a 12–18 month course of carbimazole and recommend- ing surgery if relapse occurs. There should be a noticeable clinical improvement within 10–14 days, and most patients will be biochemically euthyroid within 4–6 weeks of starting carbi- mazole 40 mg daily. Patients with Graves’ disease are likely to become hypothyroid within a year of treatment with radioiodine, but this is an unusual occurrence in patients with nodular goitre. There may be an exacerbation of hyper- thyroidism a few days after treatment with radioiodine, owing to a transient increase in serum thyroid hormone concentrations; in patients with atrial fibrillation and cardiac fail- ure it is therefore good practice to render the patient euthyroid with an antithyroid drug before giving radioiodine.

Hyperthyroidism is associated with an in- crease in cardiovascular and cerebrovascular mortality, which is most evident in the first year following treatment with radioiodine. For exam- ple, a large series from a single centre, based on more than 100 000 patient years of follow up, showed that the standardised mortality ratio, in the year after ablative radioiodine, was 1.8:1 (95% confidence interval (CI) 1.6 to 2:1).9 At least some of this excess mortality could probably be avoided by earlier diagnosis and more aggressive treatment of the hyperthy- roidism and its cardiovascular complications.

Hypothyroidism

Symptomatic thyroid failure is present in 1–2% of the population and tends to aVect women. In the absence of previous radioiodine or surgical treatment of Graves’ disease, the condition is usually caused by autoimmune mediated atro- phy of the gland, or Hashimoto’s thyroiditis which is characterised by diVuse firm thyroid enlargement. In contrast to hyperthyroidism,

the low serum concentrations of thyroid hormones are associated with a decrease in cardiac output, heart rate, stroke volume, and myocardial contractility, and an increase in systemic vascular resistance. The clinical fea- tures are not as dramatic as those of thyrotoxi- cosis and are usually only evident in patients with profound longstanding thyroid failure in whom there may be a characteristic facies. The cardiac manifestations of hypothyroidism in- clude sinus bradycardia, pericardial eVusion, heart failure (fig 3), and coronary atheroma.

Ischaemic heart disease Overt hypothyroidism is associated with hyper- lipidaemia and coronary artery disease. Ap- proximately 3% of patients with longstanding hypothyroidism report angina, and a similar proportion report it during treatment with thy- roxine. In most patients the angina does not change, diminishes or disappears when thyrox- ine is introduced; however, it may worsen and up to 40% of those patients who present with hypothyroidism and angina cannot tolerate full replacement treatment. Moreover, myocardial infarction and sudden death are well recog- nised complications of starting treatment, even in patients receiving as little as 25 µg of thyrox- ine daily. For these reasons it is customary to begin treatment with thyroxine in patients with symptomatic ischaemic heart disease in a dose of 25 µg daily, increasing by 25 µg increments every three weeks until a dose of 100 µg daily is reached. After a further six weeks, serum free T4 and TSH should be measured and the dose of thyroxine adjusted to ensure that free T4 and TSH concentrations are in the upper and lower parts respectively of the reference range. It should be exceptional not to achieve full replacement treatment.

Subclinical hypothyroidism Subclinical hypothyroidism (normal serum T4, raised TSH) is usually caused by autoimmune (lymphocytic) thyroiditis, characterised by the presence of antiperoxidase antibodies in the serum, and may be associated with coronary artery disease. For example, in one postmortem study there was histological evidence of lym- phocytic thyroiditis in 20% of men and 50% of women with fatal myocardial infarction and only 10% of men and women who died from other causes.10 Although hyperlipidaemia is common in overt hypothyroidism this may not explain the putative link between subclinical autoimmune thyroid disease and ischaemic heart disease. A meta-analysis of the many studies published between 1976 and 1996 on the eVect of thyrox- ine replacement on lipids in subclinical hypo- thyroidism showed that restoration of serum TSH to normal reduced total cholesterol by only 0.4 mmol/l, and had little eVect on high density lipoprotein (HDL) cholesterol.11

Over replacement with thyroxine? There is some concern that administering thy- roxine in a dose which suppresses serum TSH may provoke significant cardiovascular prob- lems, including abnormal ventricular diastolic relaxation, a reduced exercise capacity, an

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increase in mean basal heart rate, and atrial premature contractions.12 Apart from an in- crease in left ventricular mass index within the normal range, these observations have not been verified.13 Moreover, there is no evidence, despite the findings of the Framingham study,

that a suppressed serum TSH concentration in a patient taking thyroxine in whom serum T3 is unequivocally normal is a risk factor for atrial fibrillation.

Influence of heart disease on thyroid function tests

The interpretation of thyroid function test results may be diYcult in the presence of acute or chronic non-thyroidal illness such as myocar- dial infarction or congestive cardiac failure for a variety of metabolic and technical reasons. In these situations there is a reduction in the peripheral monodeiodination of T4 to T3, resulting in the so called “low T3 syndrome” and, depending upon the assay employed, a low, normal or raised serum concentration of free T4. Secretion of TSH is inhibited centrally and may also be influenced by drugs such as dopamine, so that concentrations of less than 0.05 mU/l are not uncommon. Conversely, serum TSH may rise into the hypothyroid range during recovery from illness. Moreover, certain inhibitors in the serum, and possibly also the tis- sues, of some patients with non-thyroidal illness may interfere with binding of thyroid hormones to their carrier proteins, prevent transport of T3 and T4 into cells, and block the attachment of T3 to intracellular nuclear and cytoplasmic receptors. Many of these problems are amplified by the refusal of some commercial kit manufac- turers to disclose the exact nature of their prod- ucts, and by the manipulation of some assay sys- tems in order to provide a result thought to be consistent with thyroid status. As a result low, normal or raised concentrations of free T3 and T4 may be recorded in the same patient using diVerent assays.

The diYculty of relying upon serum TSH measurements to assess thyroid function in ill patients is highlighted by the finding that in a large series of hospitalised patients a low serum TSH concentration was three times as likely to be caused by non-thyroidal illness as hyperthy- roidism, and a raised TSH of greater than 20 mU/l was as commonly due to illness as to primary hypothyroidism.14 The combination of low serum TSH and high free T4 is, therefore, not uncommon in euthyroid patients with significant cardiovascular disease, and some would take the view that thyroid function testing should not be requested unless there is good evidence of thyroid disease, such as goitre, oph- thalmopathy or unexplained atrial fibrillation. Even adopting such a counsel of perfection, there will be occasional patients in whom it is not possible to make an unequivocal diagnosis of euthyroidism or hyperthyroidism using the whole panoply of thyroid function testing. In this situation there is little choice but to recommend a trial of antithyroid drugs for three months.

The biochemical changes (that is, low TSH and low T3) associated with illness or starva- tion are often considered teleologically as an adaptive response to spare calories and protein; however, it is not clear whether chronic disease can, in some circumstances, cause the poten-

Figure 3. Sequential chest x rays from a patient with longstanding hypothyroidism that was complicated by congestive cardiac failure. (A) Before treatment. Cardiomegaly was caused by a combination of dilatation of all the cardiac chambers and pericardial effusion. (B) After treatment with thyroxine for nine months. (C) Seven years later, two years after the patient has stopped taking thyroxine, against medical advice, and had re-presented to the same physician with the symptoms and signs of heart failure. Reproduced from Davidson’s principles and practice of medicine, 18th ed, p 570, with permission of the publisher Churchill Livingstone.

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tially detrimental entity of “tissue hypothyroidism”.15 Although the present con- sensus is that thyroid hormone treatment is not indicated in patients with significant non- thyroidal illness, this has become a controver- sial issue. There are some studies which have shown improvements in cardiac output and systemic vascular resistance in patients with chronic cardiac failure following treatment with intravenous T3 or oral T4.16

Amiodarone induced thyroid disease

Amiodarone is a lipid soluble benzofuranic antiarrhythmic drug that has complex eVects on the thyroid and may interfere significantly with thyroid hormone metabolism.17 18 Owing to its high iodine content amiodarone may cause thyroid dysfunction in patients with pre- existing thyroid disease; it can also cause a destructive thyroiditis in patients with an inherently normal thyroid gland. The com- bined incidence of hyper- and hypothyroidism in patients taking amiodarone is 14–18% and, because of its extraordinarily long half life, either problem may occur several months after stopping the drug.

Effects on thyroid hormone metabolism Amiodarone administered chronically to eu- thyroid patients with no evidence of underlying thyroid disease results in raised serum T4 con- centrations (free T4 up to 80 pmol/l) with low normal T3. These changes are caused by the potent inhibition of 5’-deiodinase which con- verts T4 to T3. Serum TSH concentrations may increase initially then return to normal, but in some patients are suppressed at less than

0.05 mU/l. This may make it diYcult to decide whether a patient is euthyroid or hyperthyroid, particularly as the antiadrenergic eVects of amiodarone can mask the clinical features of hyperthyroidism.

Type I amiodarone induced hyperthyroidism Each 200 mg tablet of amiodarone contains 25 mg of iodine of which approximately 9 mg is released during metabolism. A patient taking a maintenance dose of 400 mg of amiodarone daily will therefore receive approximately 18 mg of inorganic iodine which is 100 times the recommended daily allowance. Chronic exposure of patients with underlying thyroid autonomy, such as Graves’ disease in remission or nodular goitre, to these excessive quantities of iodine may induce hyperthyroidism (type I amiodarone induced hyperthyroidism). This is not necessarily an indication to stop amiodar- one because many patients can be managed satisfactorily by introducing concomitant anti- thyroid medication. However, this form of hyperthyroidism can be diYcult to treat, espe- cially in areas with relative iodine deficiency as is the case in much of mainland Europe. Standard doses of carbimazole, methimazole or propylthiouracil are often ineVective and it may be necessary to add potassium perchlorate in an attempt to reduce further the iodine uptake, and therefore hormone synthesis, by the thyroid. Treatment with iodine131 is not usually advisable because of the relatively poor ability of the already iodine rich gland to concentrate the radioisotope. Total thyroidectomy may be the only method of rapid reversal of the thyro- toxicosis and has been successfully performed in patients with significant heart disease.

Type II amiodarone induced hyperthyroidism Amiodarone per se may cause a drug induced destructive thyroiditis in patients with no pre-existing thyroid disease (type II amiodar- one induced hyperthyroidism). In most cases this will resolve within 3–4 months whether or not amiodarone is discontinued. The distur- bance of thyroid function is similar to that found in other forms of destructive thyroiditis, such as de Quervain’s (subacute) or postpar- tum thyroiditis, with a few weeks of hyperthy- roidism caused by the release of preformed thyroid hormones, followed by a brief spell of hypothyroidism, and then recovery.

Which type of hyperthyroidism? Although there are features which help to distinguish between the two types of hyperthy- roidism (table 1), the diVerentiation may be diYcult and in some patients both mechanisms may be operating. In such circumstances it is sensible to institute a trial of carbimazole and to withdraw the drug after 3–4 months. If the patient remains euthyroid or becomes hypothy- roid the diagnosis is likely to be type II hyper- thyroidism; evidence of persistent hyperthy- roidism suggests a diagnosis of type I hyperthyroidism and the need to maintain car- bimazole treatment for as long as the amiodar- one is necessary and beyond.

Key points

x Serious non-thyroidal illness, such as heart failure, can cause high T4 and low TSH concentrations, suggesting hyperthyroidism.

x Measurements of T3 may help to exclude thyrotoxicosis in this situation but can be inconclusive, and in some situations a trial of antithyroid drugs may be warranted.

x In view of these diYculties thyroid function tests should only be requested in patients with credible evidence of thyroid disease such as goitre or unexplained atrial fibrillation.

Table 1 Features which may help to distinguish between type I and type II amiodarone induced hyperthyroidism

Type I Type II

Pre-existing thyroid disease Yes No Goitre DiVuse or nodular Uncommon,

may be tender Radioiodine uptake by thyroid Low normal Negligible TSH receptor antibodies in serum May be present Absent Antiperoxidase (microsomal antibodies in serum) May be present May be present Serum IL-6 Normal or slightly elevated Very elevated Subsequent hypothyroidism No Possible

IL-6, interleukin 6.

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AMIODARONE INDUCED HYPOTHYROIDISM Amiodarone may cause hypothyroidism in patients with pre-existing Hashimoto’s thy- roiditis. However, the presence of a raised serum TSH concentration before or during treatment is not a contraindication to the use of amiodarone as the thyroid failure is readily treated with thyroxine.

ASSESSMENT OF THYROID FUNCTION BEFORE AND DURING TREATMENT

In an attempt to minimise the risk of type I hyperthyroidism we recommend that before initiating treatment with amiodarone patients should be examined for the presence of goitre or Graves’ ophthalmopathy and measurements made of serum T3, T4, TSH, antiperoxidase (microsomal) and, if possible, TSH receptor antibodies. Clinical evidence of thyroid disease and/or a suppressed serum TSH concentra- tion, particularly if associated with antithyroid antibodies, should prompt a reconsideration of the use of amiodarone, and discussion with an endocrinologist.

Measurement of serum concentrations of T3, T4, and TSH should be made three and six months after starting amiodarone treatment and every six months thereafter, including dur- ing the first year after the drug is stopped. Table 2 shows the diVerent patterns of abnormal thy- roid function test results which may occur. Serum T3 concentration is the best indicator of hyperthyroidism, but in some circumstances a trial of carbimazole for 6–8 weeks may be nec- essary to establish whether the patient is hyperthyroid or not.

1. Klein I, Levey GS. The cardiovascular system in thyrotoxicosis. In: Braverman LE, Utiger RD, eds. The thyroid, 8th ed. Philadelphia: Lippincott-Raven, 2000:596–604.

2. Woeber KA. Thyrotoxicosis and the heart. N Engl J Med 1992;327:94–8.

3. Forfar JC, Muir AL, Sawers SA, et al. Abnormal left ventricular function in hyperthyroidism. Evidence for possible reversible cardiomyopathy. N Engl J Med 1982;307:1165–70. • Left ventricular ejection fraction measured by radionuclide

ventriculography was increased at rest in hyperthyroidism but fell on exercise. This paradoxical response disappeared within a few weeks of the patients becoming euthyroid, raising the possibility of a reversible cardiomyopathy in hyperthyroidism.

4. Wei JY, Genecin A, Greene HL, et al. Coronary spasm with ventricular fibrillation during thyrotoxicosis: response to attaining euthyroid state. Am J Cardiol 1979;43:335–9.

5. Forfar JC, Miller HC, Toft AD. Occult thyrotoxicosis: a correctable cause of “idiopathic” atrial fibrillation. Am J Cardiol 1979;44:9–12.

6. Forfar JC, Feek CM, Miller HC, et al. Atrial fibrillation and isolated suppression of the pituitary-thyroid axis: response to specific antithyroid therapy. Int J Cardiol 1981;1:43–8. • The first demonstration that subclinical hyperthyroidism

could cause atrial fibrillation.

7. Sawin CT, Geller A, Wolf PA. Low serum thyrotropin levels as a risk factor for atrial fibrillation in older persons. N Engl J Med 1994;331:1249–52. • Large Framingham community study in which a

heterogeneous group of patients with a low serum TSH concentration were shown to be at a sixfold risk of developing atrial fibrillation.

8. Kellett HA, Sawers JSA, Boulton FE, et al. Problems of anticoagulation with warfarin in hyperthyroidism. QJM 1986;58:43–51.

9. Franklyn JA, Maisonneuve P, Sheppard MC, et al. Mortality after the treatment of hyperthyroidism with radioactive iodine. N Engl J Med 1998;338:712–8. • Cohort of 7209 patients with hyperthyroidism treated in one

centre with iodine131 between 1950 and 1989, with 105 028 person years of follow up. The risk of death from cardiovascular disease was increased throughout the period of study but most obvious in the first post-treatment year (standardised mortality ratio (SMR) 1.6; 95% CI 1.2 to 2.1).

10. Bastenie PA, Vanhaelst L, Neve P. Coronary artery disease in hypothyroidism. Observations in preclinical myxoedema. Lancet 1967;ii:1221–2.

11. Tanis BC, Westendorp RJ, Smelt AM. Effect of thyroid substitution on hypercholesterolaemia in patients with subclinical hypothyroidism: a re-analysis of intervention studies. Clin Endocrinol 1996;44:643–9.

12. Biondi B, Fazio S, Cuocolo A, et al. Impaired cardiac reserve and exercise capacity in patients receiving long-term thyrotropin suppressive therapy with levothyroxine. J Clin Endocrinol Metab 1996;81:4224–28.

13. Shapiro LE, Sievert R, Ong L, et al. Minimal cardiac effects in asymptomatic athyreotic patients chronically treated with thyrotropin-suppressive doses of L-thyroxine. J Clin Endocrinol Metab 1997;82:2592–5.

14. Spencer C, Eigen A, Shen D, et al. Specificity of sensitive assays of thyrotropin (TSH) used to screen for thyroid disease in hospitalised patients. Clin Chem 1987;33:1391–6. • Analysis of thyroid function tests measured in a large

number of patients with non-thyroidal illness demonstrates the lack of specificity of even the most sensitive assays of TSH in determining thyroid status.

15. De Groot LJ. Dangerous dogmas in medicine: the nonthyroidal illness syndrome. J Clin Endocrinol Metab 1999;84:151–64. • A comprehensive review of the changes in thyroid

hormone metabolism in acute and chronic non-thyroidal illness, the problems of measurement and of deciding thyroid status. The arguments in favour of treating selected patients with thyroid hormone are well developed, although as yet unproven.

16. Hamilton MA, Stevenson LW, Fonarow GC, et al. Safety and hemodynamic effects of intravenous triiodothyronine in advanced congestive heart failure. Am J Cardiol 1998;81:443–7.

17. Weirsinga WM. Amiodarone and the thyroid. In: Weetman AP, Grossman A. Pharmacotherapeutics of the thyroid gland. Berlin: Springer, 1997: 225–87.

18. Newman CM, Price A, Davies DW, et al. Amiodarone and the thyroid: a practical guide to the management of the thyroid dysfunction induced by amiodarone therapy. Heart 1998;79:121–7.

Table 2 Patterns of thyroid function tests which may occur during treatment with amiodarone

Euthyroid (eVect of amiodarone on thyroid hormone metabolism)

Type I or II hyperthyroidism Hypothyroid

T3 Normal or low normal Raised > 3.0 nmol/l

Low or low normal

T4 Raised, may be in excess of 60 pmol/l

Raised Low, normal

TSH Raised, normal or low Low Raised

Reference ranges: total T3 1.1 to 2.8 nmol/l; free T4 10 to 25 pmol/l; TSH 0.15 to 3.50 mU/l.

Key points

x Amiodarone will induce hyper- or hypothyroidism in up to 20% of subjects, and thyroid dysfunction may persist for several months or develop for the first time after the drug has been stopped.

x Thyroid status should be evaluated thoroughly before introducing the drug because patients with pre-existing (often occult) thyroid disease are at particularly high risk.

x T3 is the most valuable and sensitive measure of thyroid function in patients who have received amiodarone because, even among euthyroid patients, the inhibition of the peripheral conversion of T4 to T3 may produce a high T4 and low TSH.

Education in Heart

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