Long-term effect of radioactive iodine on thyroid function and size in patients with solitary autonomously functioning toxic thyroid nodules

OBJECTIVE: To investigate the long-term effects of radioiodine (131I) on thyroid function and size in patients with a solitary toxic thyroid nodule. DESIGN: Prospective study of patients treated for a solitary autonomous toxic nodule, followed by evaluation of thyroid volume and function. PATIENTS: Sixty-two consecutive patients followed for a minimum of 12 months (range 12-168, median 60). Seventeen patients received antithyroid drug treatment before 131I. MEASUREMENTS: Standard thyroid function variables and ultrasonically determined thyroid volume before as well as 0.75, 1.5, 3, 6 and 12 months after treatment, and then once a year were investigated. RESULTS: 131I treatment (3.7 MBq/g thyroid tissue corrected to a 100% 24-h 131I uptake) was given as a single dose in 53 patients; six needed two doses and another three were given 3-5 131I treatments. The median initial dose was 310 MBq (140-666) and the median total dose was 332 MBq (148-1576). In patients receiving one 131I treatment (n = 53) the total thyroid volume decreased significantly from a median of 40 ml (range 19-77) to 24 ml (8-50) within 3 months. This represented a median reduction of 35%. A further significant decrease was seen after 24 months to a total reduction of 45%. In patients given more than one dose the thyroid volume was reduced from a median of 45 ml (19-104) before treatment to 30 ml (14-50) after a follow-up of 60 months (9-132) after the last 131I treatment. Patients without antithyroid pretreatment, receiving one 131I treatment (n = 39) became euthyroid after a median of 1.5 months (0.75-9) after treatment. Seventy-five per cent were euthyroid within 3 months. In patients pretreated with antithyroid drugs and treated with one dose of 131I (n = 14) euthyroidism was achieved after a median of 12 months (0.75-24) after 131I treatment. Hypothyroidism developed in five patients (8%) after a median of 36 months (6-60) after 131I treatment. CONCLUSION: A cure-rate of 75% within 3 months is seen when treating autonomous solitary toxic thyroid nodules with 131I. The thyroid volume is reduced by 35% within 3 months and 45% after 2 years. Side-effects are few and consist of hypothyroidism in less than 10% with a median follow-up of 5 years. This treatment should be regarded as the standard treatment for this condition until prospective comparisons with surgery and ethanol injection therapy have been performed.     

Autoimmunization and multinodular large toxic goiter therapy using repeated doses of 131I

The radioiodine therapy can favour and induces of autommunological reaction in thyroid gland. The aim of the study was evaluation of antithyroid autoantibodies in patients with multinodular large toxic goiter treated with repeated doses of 131I before and after therapy. Studies were conducted in 24 women (age range: 65-84 yrs) with multinodular large toxic goiters--goiter volume assessed by USG over 100 ml. Serum TSH, fT4, antithyroid antibodies (anti-TPO, anti-Tg, TSHR-Ab) levels were estimated in all patients parallel with radioiodine uptake test (after 5 and 24 hours), 131I thyroid scintigraphy and fine needle biopsy. These studies and therapy with 22 mCi 131I were repeated every 3 months. Before therapy median of thyroid volume was approximately 195 ml and during therapy gradually decreased to 110 ml after 12 months. After 12 months we found 11% of patients with hyperthyrodism, 62% of patients with euthyroidism and 27% of patients with hypothyroidism. Before radioiodine treatment aTg and aTPO presence were detected in the most of patients, but only in 5 cases above normal value. TSHRAb were detected (normal, very low values) in 16 patients. During therapy statistically significance increase of TSHRAb levels (median: from 0,27 to 0,65 after 6 months and to 0,71 IU/l after 9 months) was observed; aTPO and aTg antibodies levels showed marked tendency to rise, but without significant differences (aTPO median: from 40 IU/ml to 48 IU/ml; aTg - median: from 27 IU/ml to 46 IU/ml). During these observations we didn't find evident correlation between the levels of antithyroid antibodies, radioiodine uptake, proved reduction of goiter volume and TSH, FT4, FT3 values.     

Clinical and biochemical changes following 131I therapy for hyperthyroidism in patients not pretreated with antithyroid drugs

BACKGROUND: Radioiodine therapy (131I) for the treatment of hyperthyroidism has been shown to be effective and safe. Despite the extensive experience with radioiodine therapy, the necessity for pretreatment with antithyroid drugs is controversial. Pretreatment is partly based on the concept that antithyroid drugs deplete the thyroidal hormonal stores, thereby reducing the risk of a radioiodine-induced aggravation of hyperthyroidism or thyroid storm. Few data are available on the frequency of clinically significant exacerbations of hyperthyroidism following 131I therapy without prior treatment with antithyroid drugs. The aim of the present study was to determine prospectively the early clinical and biochemical changes after 131I therapy in patients who were not pretreated with antithyroid drugs. METHODS: Patients with Graves' disease (n = 21), toxic multinodular goiter (n = 11) or toxic adenoma (n = 2) were studied before and after 131I therapy. Clinical and biochemical parameters of thyroid function were investigated before and 1, 2, 8, 11, 18 and 25 days after 131I treatment. Patients were given no antithyroid drugs prior to 131I therapy, all patients received beta-blocking agents for symptomatic relief. RESULTS: In 19 of 34 patients, a transient increase in thyroid hormone levels was observed, predominantly in the first week following 131I therapy. None of these patients experienced worsening of thyrotoxic symptoms. This transient increase in thyroid hormone levels was demonstrated in all patients with toxic multinodular goiter, whereas it was found in only six of 21 patients with Graves' disease. This difference could not readily be explained by differences in pretreatment thyroid hormone levels, administered dose or effectively absorbed dose of 131I. CONCLUSIONS: 131I treatment of hyperthyroidism without pretreatment with antithyroid drugs may cause a transient increase in thyroid hormone levels. Clinically significant exacerbations of hyperthyroidism were, however, not observed in our study population. Increased hormone levels following 131I therapy were more often seen in patients with toxic multinodular goiter than in patients with Graves' disease.     

Transition of nodular toxic goiter to autoimmune hyperthyroidism triggered by 131I therapy.

The use of 131I treatment in nodular toxic goiter is widely accepted. In this article, we describe transition of nodular toxic goiter into an autoimmune toxic goiter with development of thyrotropin receptor antibodies (TRAb) as a side effect of 131I treatment. In this retrospective study, 149 patients with nodular toxic goiter (100 with multinodular goiter, 49 with a solitary autonomously functioning toxic nodule) were studied. Of these 149 patients 100 became permanently euthryoid after 1 dose of 131I, and due to persistent hyperthyroidism, 32 patients needed 2-5 doses to became euthyroid. After becoming euthyroid, none of these 132 patients had relapse of hyperthyroidism in the follow-up period. Based on evaluation of the thyroid hormone variables, 17 of 149 patients had a distinctly different pattern in the changes in thyroid hormones. They developed an increase in FT4I 3-6 months posttreatment after an initial fall in FT4I. Twelve of these 17 patients were treated with antithyroid drugs before the initial 131I dose. On samples of frozen sera (-20 degrees C) anti-thyroid peroxidase (TPO) and TRAb were followed for 6 months after 131I treatment in these 17 patients. A similar follow-up was done in 20 patients (10 with and 10 without antithyroid drug pretreatment), randomly selected from the patients who did not relapse. In the remaining 112 patients, anti-TPO and TRAb levels were measured only before the 131I treatment. Of the 17 patients with relapse, 6 developed TRAb concomitant with recurrence of hyperthyroidism (4% of the study group). In 5 of the 17 patients TRAb values remained absent throughout the follow-up period. The remaining 6 patients had elevated TRAb values before 131I treatment. Among the 132 patients who did not relapse, an additional 7 cases with presence of TRAb were found. A total of 9% of the study group was found to have TRAb before 131I pretreatment. Anti-TPO was found in 20 of 149 patients (13%) before 131I treatment. Complications, either hypothyroidism or TRAb-associated hyperthyroidism, were seen in 8 of 20 patients (40%) with anti-TPO before 131I treatment, compared to 9 of 129 (7%) without (p<0.005). In conclusion, TRAb and a Graves' like hyperthyroidism can be triggered by 131I treatment in patients with nodular toxic goiter. The presence of anti-TPO seem to be a marker of an increased risk of development of TRAb-associated hyperthyroidism as well as hypothyroidism, but both side effects can be seen despite the absence of anti-TPO autoantibodies.     

Does radioiodine therapy have an equal effect on substernal and cervical goiter volumes? Evaluation by magnetic resonance imaging.

Most often thyroidectomy is recommended in patients with large goiters. However, high-dose (131)I therapy may be used in case of contraindications to surgery. Large goiters are often partially located in the mediastinum. The aim of this study was to evaluate the impact of (131)I therapy on the cervical and the substernal goiter volume, separately. Fourteen patients (median age, 69 years; range, 52-86 years) with a large multinodular goiter (three hyperthyroid) and with a substernal extension greater than 15 mL were included. T1-weighted magnetic resonance (MR) estimates of the thyroid volume in the cervical and substernal compartments were obtained before and 1 year after high-dose (131)I therapy. The total goiter volumes ranged from 182 to 685 mL. The median substernal volume was 66 mL (fraction of total volume, 17.6%; range, 8.0%-78.9%). One year after treatment, the median substernal goiter volume was reduced by 29.2% (range, -6.1%-59.4%, mean: 26.1% +/- 6.0%), and the cervical goiter volume by 30.3% (range, 6.0%-75.4%, mean, 35.6 +/- 5.6%) compared to baseline values; p = 0.25 for difference in a regional effect. The volume reduction was unrelated to initial substernal goiter size. Likewise, deterioration of the inspiratory capacity did not correlate with the magnitude of the substernal goiter extension. In conclusion, high-dose (131)I therapy seems as effective in reducing the substernal as the cervical goiter volume. However, because the overall effect is modest, this therapy should primarily be considered for the patient with a high surgical risk.     

Influence of compensated radioiodine therapy on thyroid volume and incidence of hypothyroidism in Graves' disease

Abstract. Objectives . To investigate the long-term effect of radioactive iodine (¹³¹I) on thyroid function and size in patients with Graves' disease. Setting . Out-patient clinic in Herlev Hospital. Subjects . One hundred and seventeen consecutive patients (104 women) with Graves' disease selected for ¹³¹I treatment and followed for a minimum of 12 months (range 1–10 years, median 5 years). Interventions . ¹³¹I dose was calculated based on thyroid volume and 24-h ¹³¹I uptake. Main outcome measures . Standard thyroid function variables and ultrasonically determined thyroid volume before treatment as well as 0.75, 1.5, 3, 6 and 12 months after treatment, and then once a year were investigated. Results . Seventy-eight patients were cured by one ¹³¹I dose and 30 by two doses, while the remaining nine patients received additional doses (range one to five doses, median one dose). Within one year, 25% developed hypothyroidism, and hereafter, hypothyroidism developed at a constant rate of 3% per year independent of antithyroid pretreatment. The cumulative 10-year risk of hypothyroidism was 60%. Initial median thyroid volume was 33 mL (range 9–106 mL). At 12 months after the last ¹³¹I dose, median thyroid volume was reduced to 14 mL (range 6–36 mL) (P < 0.00001). The median reduction being 58% (range 0–80%,), hereafter no further reduction occurred. A significant reduction in thyroid volume was also noted in patients needing subsequent ¹³¹I doses and in those developing hypothyroidism within the first year. Conclusions . ¹³¹I normalizes thyroid volume in patients with Graves' disease. Hypothyroidism seems an inevitable end result of this treatment. The present study suggests that it will be impossible to modify ¹³¹I therapy in a way to achieve both early control of hyperthyroidism and a low incidence of hypothyroidism.     

Stimulation with 0.3-mg recombinant human thyrotropin prior to iodine 131 therapy to improve the size reduction of benign nontoxic nodular goiter: a prospective randomized double-blind trial

BACKGROUND: Use of recombinant human thyrotropin increases the thyroid radioiodine (iodine 131 [(131)I]) uptake and may have a role in the context of (131)I therapy of benign goiter. METHODS: In a double-blind, placebo-controlled trial, 57 patients with nodular nontoxic goiter (51 women and 6 men) were randomized to receive either 0.3 mg of recombinant human thyrotropin (n = 28) or placebo (n = 29) 24 hours before (131)I therapy. The (131)I dose was calculated based on thyroid size (measured by ultrasound), thyroid (131)I uptake, and (131)I half-life. The follow-up period was 1 year and included measurements of thyroid size and function and patient satisfaction. RESULTS: Baseline median goiter volume was 51 mL (range, 20-99 mL) in the placebo group and 59 mL (range, 25-92 mL) in the thyrotropin group (P = .75). At 12 months, the mean +/- SEM relative goiter reduction was 46.1% +/- 4.0% in the placebo group and 62.1% +/- 3.0% in the thyrotropin group (P = .002 between groups). The difference was most pronounced among patients with large goiters. Within each group, there was no significant correlation between retained thyroid (131)I dose and goiter reduction. Adverse effects were significantly more frequent in the thyrotropin group (34 vs 12 events; P<.001). Permanent hypothyroidism developed in 3 patients (11%) in the placebo group compared with 16 patients (62%) in the thyrotropin group (P<.001). Patient satisfaction was high and uninfluenced by the use of recombinant human thyrotropin. CONCLUSIONS: Stimulation with recombinant human thyrotropin prior to (131)I therapy improves thyroid size reduction by 35%, with a 5-fold higher rate of hypothyroidism. These effects are, at least partially, mediated through mechanisms other than an increase in retained (131)I thyroid dose. Further recombinant human thyrotropin dose-finding studies are warranted before routine use.     

Improvement of goiter volume reduction after 0.3 mg recombinant human thyrotropin-stimulated radioiodine therapy in patients with a very large goiter: a double-blinded, randomized trial

INTRODUCTION: The effect of (131)I therapy amplification by recombinant human (rh) TSH prestimulation in very large goiters has not been evaluated in a double-blinded, placebo-controlled study. METHODS: Twenty-nine patients (22 females; age range 37-87 yr) with a large multinodular goiter (median 160 ml, range 99-440 ml) were randomized to receive placebo (n = 15) or 0.3 mg rhTSH (n = 14) 24 h before (131)I administration. Goiter volume was monitored by magnetic resonance imaging. RESULTS: On average, the goiter volume was unchanged 1 wk after therapy in both groups, but the largest deviations from baseline were observed in the rhTSH group. After 12 months the median goiter volume was reduced from 170 to 121 ml in the placebo group and from 151 to 72 ml in the rhTSH group, respectively (within group: P = 0.001; between group: P = 0.019). This corresponds to reductions of 34.1 +/- 3.2 and 53.3 +/- 3.3%, respectively (between group: P < 0.001). In the placebo group, the goiter reduction correlated positively with the retained thyroid (131)I dose, whereas such a relationship was absent in the rhTSH group. Adverse effects, mainly related to thyroid pain and cervical compression, were more frequent in the rhTSH group. At 12 months, goiter-related complaints were significantly reduced in both groups without any between-group difference. One and three patients in the placebo and the rhTSH group, respectively, developed hypothyroidism. CONCLUSION: rhTSH-stimulated (131)I therapy improves the reduction of very large goiters by more than 50%, compared with (131)I therapy alone, but at the expense of more adverse effects after therapy. Our data suggest that rhTSH stimulation may work through mechanisms that go beyond the increase in thyroid (131)I uptake.     

High dose of (131)I therapy for the treatment of hyperthyroidism caused by Graves' disease

Radioactive iodine ((131)I) has become the most widely used therapy for patients with hyperthyroidism caused by Graves' disease in the United States. There remains, however, significant variability among (131)I dosing regimens, and it is clear that most patients ultimately develop hypothyroidism after therapy. To avoid persistent hyperthyroidism, we adopted a high dose (131)I therapy protocol based on measurement of 24-h thyroid (123)I uptake designed to deliver 8 mCi (296 MBq) to the thyroid gland 24 h after (131)I administration. To evaluate the efficacy of this protocol, we reviewed our clinical experience over a 7-yr period. We treated 261 patients (219 women and 42 men) with hyperthyroidism caused by Graves' disease with (131)I [mean dose, 14.6 mCi (540 MBq)] between 1993 and 1999. Before treatment, 207 (79%) had received an antithyroid drug (109 propylthiouracil and 98 methimazole). We determined their thyroid status 1 yr after treatment in relation to age, pretreatment with an antithyroid drug, pretreatment thyroid size, and dose of (131)I retained in the thyroid 24 h after treatment. Among the 261 patients, 225 (86%) were euthyroid or hypothyroid 1 yr after treatment, and 36 patients (14%) had persistent hyperthyroidism and required a second treatment. The patients who had persistent hyperthyroidism were younger (P < 0.01), had larger thyroid glands (P < 0.01), higher pretreatment thyroid (123)I uptake values (P < 0.01), and higher serum T(4) concentrations (P < 0.01) and were more likely to have taken antithyroid medication before administration of (131)I (P = 0.01). Five of these patients developed transient hypothyroidism, followed by thyrotoxicosis. There was an asymptotic, inverse relationship between the retained dose of (131)I at 24 h and persistent hyperthyroidism, revealing a 5-10% failure rate despite delivery of up to 400 microCi (14.8 MBq)/g. A dose of (131)I that results in accumulation of 8 mCi (296 MBq) in the thyroid gland 24 h after administration is an effective treatment for the majority of patients with Graves' hyperthyroidism. Young patients with larger thyroid glands, higher serum T(4) concentrations, and higher 24-h thyroid (123)I uptake values, and those pretreated with antithyroid medication for greater than 4 months are at higher risk for treatment failure. A higher dose of (131)I may be advisable in such patients.     

An outline concerning the potential use of recombinant human thyrotropin for improving radioiodine therapy of multinodular goiter

Radioiodine ((131)I) treatment for nontoxic and toxic multinodular goiter (MNG) is an alternative therapeutic procedure used especially for patients with contraindication for surgery. Several studies have been conducted in recent years assessing the use of recombinant human TSH (rhTSH) in increasing (131)I uptake in MNGs. This procedure also decreases the activity level of the administered (131)I, changes the distribution of (131)I in the thyroid, lowers the absorption dose, and dramatically reduces the volume of the goiter (50-75% of the baseline volume). A major disadvantage, however, is the induction of hypothyroidism in a relatively large number of patients. A transient increase in thyroid volume and tenderness was noted in the first week of treatment. Also a short period (2-4 weeks) of hyperthyroidism was observed in most patients with potential consequences particularly for the elderly. Still, there has been no evidence to date that the adverse effects outweigh the positive results of using rhTSH. The use of rhTSH in benign goiter disease has not yet been approved worldwide, but its positive activity in MNG is remarkable and promising.     

Recombinant human thyrotropin markedly changes the 131I kinetics during 131I therapy of patients with nodular goiter: an evaluation by a randomized double-blinded trial

The present study compares, in a randomized double-blinded design, the expected and the actual absorbed thyroid radioactive dose in response to 0.3 mg recombinant human (rh)TSH (n = 35) or placebo (n = 28) given 24 h before (131)I therapy in patients with nodular goiter (median volume, 69 ml; range, 20-440 ml). The (131)I activity calculation was based on thyroid (131)I uptake (RAIU) at 24 and 96 h after a tracer dose of 0.5 MBq (131)I. After (131)I therapy, 24- and 96-h RAIU were repeated allowing a more exact assessment of the actual absorbed thyroid dose. The median (131)I activity was 617 and 632 MBq, respectively, in the rhTSH and the placebo group. At baseline, the 24- and 96-h RAIU and the expected thyroid dose were 32.8 +/- 9.1%, 32.1 +/- 8.2%, and 96.3 +/- 16.3 Gy, respectively, in the rhTSH group and 35.7 +/- 11.8%, 35.2 +/- 11.3%, and 94.1 +/- 18.5 Gy, respectively, in the placebo group (P value not significant between groups). After (131)I therapy, the 24- and 96-h RAIU and the actual absorbed thyroid dose were 46.9 +/- 11.7%, 45.0 +/- 12.1%, and 136.7 +/- 47.9 Gy, respectively, in the rhTSH group and 33.0 +/- 11.4%, 31.0 +/- 11.3%, and 76.9 +/- 27.5 Gy, respectively, in the placebo group (P < 0.001 between groups). Comparing the expected with the actual absorbed thyroid dose, this corresponds to a mean increase of 36.4% (95% confidence interval, 21.3-53.4) in the rhTSH group and a decrease of 21.5% (95% confidence interval, -33.9 to -6.6) in the placebo group (P < 0.001), equivalent to an increase of 73.8% in the absorbed thyroid dose in the rhTSH-treated group. We have thus for the first time shown that stimulation with rhTSH before (131)I therapy not only hinders the decrease in the thyroid RAIU observed with conventional (131)I therapy but in fact also significantly enhances the absorbed thyroid dose. Whether this also leads to a significant increase in goiter size reduction needs additional study.     

Is calculation of the dose in radioiodine therapy of hyperthyroidism worth while?

OBJECTIVE The persistent controversy as to the best approach to radioiodine dose selection in the treatment of hyperthyroldism led us to perform a study in order to compare a fixed dose regime comprising doses of 185, 370 or 555 MBq based on gland size assessment by palpation only, with a calculated ¹³¹I dose based on type of thyroid gland (diffuse, multinodular, solitary adenoma), an accurate thyroid volume measurement, and a 24-hour ¹³¹I uptake determination. DESIGN Prospective randomized study. PATIENTS Two hundred and twenty-one consecutive hyperthyroid patients referred for ¹³¹I treatment. Four patlents who dled for reasons unrelated to hyperthyroidism, 7 lost to follow-up and 47 who did not receive antithyroid drugs after treatment, were excluded. The remalnlng 163 patlents (143 women) were studied, dlvlded into subgroups accordlng to the type of gland. They all recelved antithyroid drugs prior to ¹³¹I treatment and this was resumed 7 days after treatment for a period of 3 weeks. MEASUREMENTS Thyroid function variables were determined approximately 2 weeks before ¹³¹I treatment, and again 1, 2, 3, 6, 9 and 12 months after treatment. Prior to ¹³¹I therapy the size of the thyroid gland was determined by ultrasound and a 24-hour uptake of ¹³¹I was carried out. Thyroid in 78 of the 163 patients. Twelve months after the initial ¹³¹I dose patients could be classified as euthyroid, hyperthyrold or hypothyroid. RESULT Neither in the group of 163 patients nor within the three subgroups of hyperthyroidism could any significant difference in outcome between the two treatment regimes be demonstrated. Thirty-two of 78 patients (41%) in the calculated dose group and 30 of 85 patients (35%, NS) in the fixed group were classified as hyperthroid. Seven of 78(9%) in the calculated dose group were classified as permanently hypothyroid. Finally, 39 of 78(50%) In the calculated dose group and 49 of 85(58%, NS) in the fixed group were enthyroid at 12 months after ¹³¹I treatment. One year after ¹³¹I therapy thyroid volume was deduced from 59.3 ± 9.2 (mean ± SEM) to 36.2 ± 6.6 ml (average reduction 39%) In the calculated dose group (P < 0.001). This reduction did not differ significantly from the fixed dose group where thyroid volume declined from 61.6 ± 6.1 to 41.17 ± 4.7 ml (average reduction 32%) (P < 0.001). CONCLUSIONS A semiquantitative approach is probably as good as the more elaborately calculated radiolodine dose for treatment of hyperthyroidism. It is clearly more cost effective and allows the use of predetermined standard doses.     

Determinants of longterm outcome of radioiodine therapy of sporadic non-toxic goitre

OBJECTIVE: Radioiodine treatment is effective in reducing the size of sporadic nontoxic goitre, albeit at the expense of a high incidence of postradiation hypothyroidism. The decrease in goitre size, however, is not observed in all subjects, and little is known about recurrent goitre growth after 131I therapy. The aim of the present study was to evaluate which factors determine the longterm outcome of 131I treatment in patients with sporadic nontoxic nodular goitre, in terms of changes in both thyroid size and thyroid function. STUDY DESIGN: Retrospective follow-up study. PATIENTS: Fifty patients with sporadic nontoxic nodular goitre were evaluated who had been treated in our institution with 131I (mean dose 4.4 MBq/g thyroid) in the period 1988-95. Nine patients received a second dose of 131I and one a third. Median follow-up time was 41 months (range 24-115). MEASUREMENTS: Thyroid function was assesed by TSH and FT4 index, and thyroid volume by ultrasound in 46 patients, by scintiscan using the Himanka formula in three and by CT-scan in one. The response to treatment was defined as a decrease in thyroid volume of greater than 13% (i.e. the mean + 2SD of the coefficient of variation of volume measurements), and recurrent goitre as an increase in thyroid volume greater than 13% after an initial response. RESULTS: Goitre size decreased from a median value of 82 ml (range 17-325) to 37 ml (range 6-204) two years after 131I treatment, a median reduction of 49%. The decrease in goitre size was directly related to the dose of 131I (r = 0.50, P = 0.0003) and indirectly to baseline goitre size (r = - 0.35, P = 0.006). Seven patients (14%) were nonresponders, and four (8%) experienced recurrent goitre growth after 3-5 years. These 11 patients (22%) when compared to the remaining 39 responders (78%) had larger goitres with more often a dominant nodule, and had received a lower 131I dose. The efficacy of a second dose of 131I (median reduction in goitre size 37%) was comparable to the first dose. Hypothyroidism occurred in 24 patients (48%), mostly in the first two years after treatment; 11 had overt and 13 subclinical hypothyroidism. Kaplan Meier statistics indicated a probability of 58% for developing hypothyroidism after 8 years. Hypothyroid patients had a smaller initial goitre size and a higher prevalence of TPO antibodies and a family history of thyroid disease than the patients who remained euthyroid; the 131I dose did not differ between the two groups. CONCLUSIONS: The size of sporadic nontoxic goitres is reduced on average by 50% after a single dose of 4.77 MBq 131I/g thyroid. Independent determinants of the relative decrease in thyroid volume are administered 131I dose and initial goitre size. Nonresponders (14%) and those with late recurrence of goitre growth (8%) have larger goitres and more often dominant nodules than responders. Determinants of postradioiodine hypothyroidism (cumulative risk 58% after 8 years) are the presence of TPO antibodies, a family history of thyroid disease and a relatively small goitre.The implications of these findings are that the efficacy of a given 131I dose can be enhanced when administered at an earlier stage when the goitre is still smaller, albeit at the expense of an increased risk for developing hypothyroidism.     

Acute changes in thyroid volume and function following 131I therapy of multinodular goitre

OBJECTIVE Many textbooks claim that radioIodine (¹³¹I) treatment should be given with care to a goitre with substernal extension, for fear of acute swelling of the gland and thus respiratory problems. Since ¹³¹I Is used increasingly in the treatment of non-toxic as well as toxic goitre we have evaluated the acute changes in thyroid volume following ¹³¹I therapy. DESIGN Evaluation of potential acute changes in thyroid volume and function after ¹³¹I treatment in patients with non-toxic goitre treated because of compression symptoms or for cosmetic reasons, as well as In patients with toxic goitre. PATIENTS Out-patients with multinodular goitre, either non-toxic (n= 20) or toxic (n= 10). Excluded were patients with a substernal goitre. MEASUREMENTS Ultrasonically determined thyroid volume and standard thyroid function variables were Investigated before and 2, 7, 14, 21, 28 and 35 days after treatment. RESULTS In non-toxic goitres the thyroid volume did not increase significantly, the maximum increase in the median volume being 4% on day 7. Serum levels of free T3 and free T4 Indices increased by 20% (day 7) and 13% (day 14) (P= 0·002), respectively. Likewise thyroid volume in toxic nodular goitre did not change significantly after ¹³¹I treatment (maximum median increase was 2%). None of the patients presented symptoms of tracheal compression. CONCLUSIONS ¹³¹I treatment of non-toxic as well as toxic multinodular goitre does not seem to increase thyroid volume.     

Is routine thyroxine treatment to hinder postoperative recurrence of nontoxic goiter justified?

Previous reports regarding the efficacy of levo-T4 (L-T4) in preventing postoperative recurrence of nontoxic goiter have been controversial. This study was designed to evaluate the influence of long-term L-T4 treatment on thyroid volume after thyroidectomy for nontoxic goiter. We studied 202 consecutive patients operated on for benign nontoxic goiter and followed them for a minimum of 12 months (median, 10 yr; range, 1-14 yr). Three months after thyroidectomy, patients were randomized to L-T4 treatment (group A, n = 100) with an initial dose of 150 microg daily and to no treatment (group B, n = 102). All were clinically and biochemically euthyroid, and preoperatively none were taking any thyroid and/or antithyroid medication. Standard thyroid function variables and ultrasonically determined thyroid volume (normal range, 9-28 mL) were determined before and 3 and 12 months after randomization and yearly thereafter. Recurrence was defined as an ultrasonically enlarged thyroid gland. Clinical data were similar between the two groups. Incidence of recurrence in group A was 19/100 (21%; 95% CL 0-42%; life-table analysis) and in group B 27/102 (35%; CL 7-64%) (P = 0.16) and was related to removed amount, remnant size, and pathoanatomical diagnosis but not type of operation or postoperative level of serum TSH and T4. L-T4 dose had to be reduced in 36 of 100 patients because of side effects of the treatment. In conclusion, the possible benefits of L-T4 treatment should be weighed against the possible side effects. Our study does not support the routine postoperative use of L-T4.     

Outcome of treatment of hyperthyroidism.

This is a retrospective study designed to evaluate the initial response to carbimazole in patients with Graves' disease (GD), possible determinants of that response, the frequency of occurrence of adverse effects during treatment with carbimazole and the frequency of transient and permanent hypothyroidism after treatment with 131I in patients with GD and multinodular goiter (MNG). Data were collected from patients who first presented with GD or MNG at the Department of Endocrinology of the Royal Infirmary of Edinburgh between 1 January 1993 and 31 August 1996. Patients were divided into three groups: patients with GD treated with a daily dose of 40 mg carbimazole, patients with GD treated with a single dose of 400 MBq 1311, and patients with MNG treated with the same dose of 131I. Of the patients younger than 30 years, 50% remained biochemically hyperthyroid after 4-6 weeks of treatment with carbimazole, compared to 14% of patients over 30. Other determinants of the response to carbimazole expressed as the fall in thyroid hormone levels after 4-6 weeks were: pretreatment levels of FT4, T3, TRAb and the 4 h 131I uptake, patients with the higher levels responding significantly better to carbimazole. Adverse effects were reported in 11.5% of patients. Of the patients with GD treated with 1311, 62.6% became hypothyroid, transient hypothyroidism occurred in only 2.4% of these cases. The main predictors of development of hypothyroidism were positive titres of antithyroid peroxidase antibodies (AbTPO) and antithyroglobulin antibodies (AbTg), with positive predictive values of 79.5 and 91.6 respectively. None of the patients with MNG became hypothyroid after treatment with 131I, a response significantly different from patients with GD. In conclusion, GD younger patients might benefit from higher initial doses of carbimazole. In patients with positive titres of AbTPO and AbTg, lower doses of 1311 might prevent hypothyroidism. Transient hypothyroidism was underestimated in this study. No permanent thyroxin replacement therapy should be started within the first six months after 131I treatment.     

OUTCOME FOLLOWING STANDARDIZED 185 MBq DOSE 131I THERAPY FOR GRAVES'' DISEASE

The clinical outcome of 199 patients with Graves' disease treated with standardized 185MBq 131I therapy doses has been analysed. Most patients were controlled with antithyroid drugs prior to the 131I therapy, and also received antithyroid drugs for several months following 131I. The median follow-up period was 5.5 years. The single 185MBq 131I dose successfully treated 72.4% of patients. The 1, 2 and 5 year hypothyroid figures were 15.5%, 19.3% and 27.3%, respectively. Previous thyroidectomy was associated with an increased hypothyroid rate. Retreatment was required by 25.6%, with 3.5% requiring more than two 131I doses. Discriminant analysis of pretreatment variables suggests that patients with large goitres or severe disease (serum T3 greater than 10nmol/l) should be treated with higher doses of 131I.     

Thyroid autoimmunity is associated with higher urinary iodine concentrations in an iodine-deficient area of Northwestern Greece.

Northwestern Greece was identified in the 1960s for its high prevalence of endemic goiter and iodine deficiency. Although iodized salt has been commercially available since then, a recent epidemiological survey of 3916 schoolchildren found that low-grade goiter is still prevalent in endemic proportions (21%). The aim of this study was to further assess the cause of goiter and the severity of iodine deficiency in children from this endemic area of Greece. Of the 800 children with clinically detectable goiter, 97 children (60 girls and 37 boys, 8-15 years) were recruited for determination of urinary iodine excretion, as well as assessment of thyroid volume and function and detection of antithyroid antibodies. The median urinary iodine concentration was 8.4 microg/dL, indicative of a mild iodine deficiency. Thyroid function was normal in all but 11 children who had subclinical hypothyroidism. Sixteen children (16.5%), including all those with subclinical hypothyroidism, were positive for antithyroid antibodies. Their median urinary iodine concentration (20.6 microg/dL) was higher compared to children who were negative for antibodies (7.4 microg/dL; p<0.001). The mean thyroid volume by ultrasonography (12.2+/-4.1 mL) was above the upper limit of normal for this age group. Thyroid volume was inversely related to the urinary iodine content in the children with negative antithyroid antibodies. Iodine deficiency is still prevalent in northwestern Greece although of mild severity and constitutes the primary cause of goiter among schoolchildren. However, it appears that autoimmune thyroiditis is emerging as a frequent cause of goiter in those children with sufficient iodine intake.     

Toxic multinodular goiter: a variant of autoimmune hyperthyroidism

The aim of this study was to examine whether at least a subgroup of patients with toxic multinodular goiter may have autoimmune thyroid disease. Thyroid-stimulating immunoglobulin (TSI) activity, measured by a sensitive bioassay employing cultured human thyroid cells, was determined in patients with toxic multinodular goiter and other thyroid disorders. All patients with active Graves' disease (n = 47) had detectable serum TSI activity, whereas TSI was undetectable in patients with thyroid disease not believed to be of autoimmune origin: toxic adenoma (n = 13), cold nodule (n = 5), and nontoxic goiter (n = 19), with a single exception in the latter group. Toxic multinodular goiter (n = 26) was diagnosed based on clinical and laboratory evidence of hyperthyroidism associated with a multinodular goiter on palpation and scintiscan. The toxic multinodular goiter group was then subclassified according to scintiscan pattern (type A, diffuse but uneven distribution of technetium uptake; type B, multiple discrete nodules of varying size and function). All but 1 of the 11 TSI-positive toxic multinodular goiter patients had a type A scintiscan pattern. The patients with the type A scintiscan pattern were younger and more often had elevated antithyroid antibody titers, ophthalmopathy, and concurrent development of goiter and hyperthyroidism (rather than long-standing goiter preceding hyperthyroidism) compared to the type B patients. Thus, a subgroup of patients with clinically defined toxic multinodular goiter (type A) probably have autoimmune hyperthyroidism (a variant of Graves' disease), while in another subgroup (type B) hyperthyroidism is not related to an autoimmune etiology (a variant of toxic adenoma).     

Clinical characteristics of amiodarone-induced thyrotoxicosis and hypothyroidism in Japan.

Since amiodarone was introduced in Japan in 1992, the incidence of the drug-induced thyroid dysfunction has been increasing. We studied the thyroid function of 13 patients with amiodarone-induced thyrotoxicosis (AIT) and 11 patients with amiodarone-associated hypothyroidism (AAH) who had been referred to our Institute in the last 6 years. AIT and AAH developed after 39+/-21 and 20+/-16 months of amiodarone treatment, respectively. One patient developed AAH followed by AIT. The AIT ranged from subclinical to overt thyrotoxicosis. Four patients with moderate to marked AIT were treated with methimazole. Their thyrotoxicosis persisted for 3 to 9 months, despite administration of antithyroid agents. One patient with mild thyrotoxicosis was treated with prednisolone, resulting in a euthyroid state in a few months. Eight patients with asymptomatic to moderate thyrotoxicosis resolved spontaneously without any treatment. In four asymptomatic patients with AIT, serum levels of T3 and T4 were in the upper normal range or slightly high (< 12 microg/dl), accompanied by suppressed TSH (<0.1 microU/ml) and high thyroglobulin levels, suggesting destruction-induced thyrotoxicosis. Such a subclinical thyrotoxicosis developed repeatedly in one patient. Ultrasonographic studies revealed no nodular lesion in the thyroid, and color flow Doppler sonography demonstrated no hypervascularity in the thyroid gland in any AIT patient. Although it is postulated in Europe that there are two types of AIT, namely type I, which develops in patients with latent Graves' disease or toxic multinodular goiter, and type II, which develops in an apparently normal thyroid as destructive thyroiditis, all AIT patients we have seen so far had developed destructive type AIT. Sufficient intake of iodide and a very low incidence of toxic multinodular goiter may account for the rare incidence of type I AIT in our country. Mild to moderate AIT resolved spontaneously without discontinuing amiodarone, but it was discontinued in two of 13 AIT patients because of extrathyroidal adverse reactions.