A randomized comparison of radioiodine doses in Graves' hyperthyroidism

The optimal method for determining iodine-131 treatment doses for Graves' hyperthyroidism is unknown, and techniques have varied from a fixed dose to more elaborate calculations based upon gland size, iodine uptake, and iodine turnover. Patients with Graves' hyperthyroidism (n = 88) who had not been previously treated with radioactive iodine were randomized to one of four dose calculation methods: low-fixed, 235 MBq; high-fixed, 350 MBq; low-adjusted, 2.96 MBq (80 micro Ci)/g thyroid adjusted for 24 h radioiodine uptake; and high-adjusted, 4.44 MBq (120 micro Ci)/g thyroid adjusted for 24 h radioiodine uptake. Subjects were followed for mean of 63 months (range, 10-94 months) for the following clinical outcomes: euthyroid without medication, hyperthyroid requiring further radioiodine, and hypothyroid requiring life-long L-T(4). Mean treatment doses were similar in the different outcome groups. We could not demonstrate any advantage to using an adjusted dose method. Survival analysis did not demonstrate any difference in the time to outcome between the fixed and adjusted dose methods. The use of a fixed dose method simplifies the approach to treatment with potential cost savings.     

Appearance of thyroid stimulating antibody and Graves' disease after radioiodine therapy for toxic nodular goitre

A patient with toxic nodular goitre is described in whom radioiodine (¹³¹I) therapy paradoxically induced typical Graves' disease. This patient had a goitre with two autonomously functioning nodules suppressing uptake by the remainder of the gland. Circulating thyroid peroxidase antibody indicated the coexistence of focal lymphocytic thyroiditis. Radioiodine therapy was followed by the development of severe and persistent Graves' hyperthyroidism associated with diffuse ¹³¹I uptake by the gland. A second administration of ¹³¹I produced a further worsening of hyperthyroidism, and the appearance of ophthalmopathy. TSH-receptor antibody and thyroid stimulating antibody were undetectable before ¹³¹I, appeared after the first administration of radioiodine, and showed a further increase after the second dose of ¹³¹I. We suggest that, in a patient genetically susceptible to thyroid autoimmunity, the release of TSH-receptor antigenic components from follicular cells damaged by radioiodine therapy triggered an autoimmune response to the TSH-receptor, thus turning a toxic nodular goitre into Graves' disease.     

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.     

Acute pre-tibial myxoedema following radioiodine therapy for thyrotoxic Graves' disease

A 54-year-old woman was treated with an oral dose of S55MBq of ¹³¹I radioiodine for thyrotoxicosis. She had no clinically detectable extrathyroidal manifestations of Graves' disease at the time, but within two months developed moderately severe ophthalmopathy and very extensive thyroid dermopathy affecting her face, arms, hands and feet, in addition to the classic pre-tlblal area. Although she developed mild post radioiodine hypothyroidism, this was detected at an early stage and its treatment had no effect on the extrathyroldal signs. Thyrotrophin receptor antibodies (TRAb) were positive before treatment (22% Inhibition of T S H binding in neat serum), rose to very high levels following radioiodine (97.6% Inhibition), and fell progressively over the following year during treatment with prednisolone. Thyroglobulln autoantibodies became detectable following radioiodine but thyroid peroxidase antibodies were undetectable throughout. Serum and purified IgG from blood samples obtained prior to steroid therapy and over the subsequent year were tested on a dermal fibroblast cell line in vitro for the stimulation of synthesis of glycosamlnoglycans, protein and DNA, but no increase in radiolabel incorporation was apparent for any sample when compared to controls. The temporal relation between the radioiodine and the acute onset of dermopathy and ophthalmopathy, together with the abrupt rise in TRAbs, indicates a probable causal association. However, the absence of In-vitro fibroblast stimulation would suggest that the pathogenesis of Graves' dermopathy is not dependent solely on any simple humoral factor.     

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.     

Optimized radioiodine therapy of Graves' disease: analysis of the delivered dose and of other possible factors affecting outcome.

The best approach to radioiodine dose selection in the treatment of Graves' hyperthyroidism remains highly controversial. The formula to calculate the individual dose of (131)I to be delivered has been used for half a century and takes into account the thyroid mass, the effective half-life and the maximum uptake of (131)I. The objective of the present study was to evaluate the accuracy of this formula by determining the relationship between the administered dose of (131)I calculated to deliver a target dose of 50Gy to the thyroid and the actual exact organ dose. We further analyzed if therapeutic success, defined by euthyroidism following the individually calculated dose, can be predicted by different pretreatment parameters and particularly by organ dose. One hundred patients with a first episode of Graves' disease and who had received optimal thyroid irradiation after precise dosimetry were retrospectively reviewed. The patients were categorized according to their thyroid function (plasma free thyroxine (T(4)) serum concentration) as eu-, hyper- or hypothyroid during and 1 year after treatment. The relationship between the administered dose and organ dose was assessed by simple regression. We compared free T(4), free tri-iodothyronine, thyroid weight, the number of patients with antithyroperoxidase antibodies and TSH receptor autoantibodies, 24h urinary iodine excretion, (131)I uptake, and the exact dose of (131)I delivered to the thyroid as pretreatment variables. Although we found a correlation between administered dose (mCi) and organ dose (Gy) (r=0.3, P=0.003), the mean coefficient of variation for organ dose was 45%. Individualized radioiodine therapy enabled euthyroidism in 26% of patients and failed in 74% of patients (33% had persistent or recurrent hyperthyroidism and 41% permanent hypothyroidism). (131)I uptake was significantly higher in the hyperthyroidism group in comparison with the euthyroid group. However, organ dose and other pretreatment variables did not differ among the three groups. In conclusion, these results confirm the low performance of individual dosimetry using what are established ratios, since the delivered dose to the gland, although correlated to the intended dose, is highly variable. The finding that other usual pretreatment variables are not different between groups, gives little hope for improving the way of calculating the ideal dose of radioiodine. We suggest to those not yet ready to give a standard or an ablative dose for Graves' hyperthyroidism that they abandon this way to calculate the (131)I dose.     

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.     

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.     

Treatment of Hyperthyroidism with Standard Doses of Radioiodine Aiming at Ablation

ABSTRACT Sixty patients with hyperthyroidism were treated with standard doses of ¹³¹I during 1969–83 in our department. The doses were 10–25 mCi (370–920 MBq), mostly 15 mCi (550 MBq). 38 of the patients have become hypothyroid, mostly within one year after treatment. There were 3 early relapses of hyperthyroidism; these patients became hypothyroid within one year after an additional dose of radioiodine. All hypothyroid patients had early substitution with l-thyroxine before overt clinical symptoms and signs had developed. There were no late relapses of hyperthyroidism. 15 patients had died during the follow-up; all were euthyroid or hypothyroid with adequate substitution. 28 of the 60 patients have been followed for 5–14 years, 14 for 2–5 years, 7 for 1–2 years and 10 for less than one year. Standard dose ¹³¹I treatment offers certain advantages compared with attempted individualized treatment. Late hypothyroidism after individualized dosage may be difficult to anticipate and detect, whereas early hypothyroidism after ablative standard dose treatment is easy to detect and control. Generally speaking, hypothyroidism is not to be regarded as a complication of radioiodine treatment for hyperthyroidism, but as its natural end result. The fixed dose schedule is especially well suited for regions where hyperthyroidism with no goitre or a small goitre is common.     

A reappraisal of the role of methimazole and other factors on the efficacy and outcome of radioiodine therapy of Graves' hyperthyroidism

The outcome of radioiodine therapy of Graves' hyperthyroidism was retrospectively evaluated in 274 consecutive patients treated from 1975 to 1984. At 1-yr follow-up, permanent hypothyroidism occurred in 36.9% of patients and the cumulative incidence of hypothyroidism progressively increased up to 79.3% after 7-10 yr. At the end of the follow-up period, 148 patients (54%) were hypothyroid, 115 (42%) euthyroid and 11 (4%) still hyperthyroid. The prevalence of hypothyroidism was significantly higher in patients with small goiters (less than or equal to 50 g) than in those with large goiters (greater than 90 g). Moreover, hypothyroidism was more frequent in patients with high thyroglobulin antibodies titers (greater than or equal to 1:25,600) than in those with low titers or negative tests, and occurred earlier in the former group than in the latter ones Correction of thyrotoxicosis was obtained after the administration of a single dose of 131I in 187 patients (63.6%); 69 patients required two doses and 11 three or more doses. Seven patients refused further treatment with 131I after the first dose. In an effort to identify possible factors affecting the efficacy of 131I therapy, we evaluated the results obtained after the administration of the first dose of radioiodine. We found that large goiters, rapid iodide turnover and adjunctive therapy with methimazole shortly after radioiodine were associated with a higher rate of persistence of thyrotoxicosis, whereas an increased prevalence of hypothyroidism was observed in patients with small goiters and in those not treated with methimazole up to one week after 131I.(ABSTRACT TRUNCATED AT 250 WORDS)     

Long-term follow-up study of radioiodine treatment of hyperthyroidism

OBJECTIVE: To determine the cumulative incidence of hypothyroidism during long-term follow-up in patients treated for hyperthyroidism by radioactive iodine (131)I (RAI) therapy, the significance of clinical factors in predicting the development of hypothyroidism, and the outcome after a fixed 7 mCi (259 MBq) dose of RAI. DESIGN: Prospective cohort study of patients treated for hyperthyroidism by RAI. PATIENTS AND MEASUREMENTS: Since 1965, details on 2043 patients treated by RAI therapy in Tampere University Hospital were entered into a computerized register. Following RAI treatment, thyroid status was monitored every 1-3 months during the first year, and subsequently at 1-3-year intervals until June 2002 or until the patient died or moved out of the Tampere University Hospital district. results The cumulative incidence of hypothyroidism in patients with Graves' disease and toxic multinodular goitre at 1, 10 and 25 years was 24%vs. 4%, 59%vs. 15% and 82%vs. 32%, respectively. In a Cox regression model, previous partial thyroidectomy [risk ratio (RR) = 1.63 in patients with Graves' disease and RR = 1.59 in those with toxic multinodular goitre] and age at the first RAI treatment (RR = 0.998 and RR = 0.996 per year) were statistically significantly associated with the development of hypothyroidism both in patients with Graves' disease and in those with toxic multinodular goitre. Antithyroid medication preceding RAI therapy (RR = 0.47) decreased and female gender (RR = 1.53) increased the risk of hypothyroidism only in patients with Graves' disease. Administration of a single dose of RAI resulted in the control of hyperthyroidism in 75% of patients, while two to six RAI treatments were needed in 25% of patients to achieve either a hypothyroid or a euthyroid state in both groups. None of the clinical factors studied was associated with the remission rate either in patients with Graves' disease or in those with toxic multinodular goitre. The remission rate did not differ between the patients who received a dose of RAI calculated according to the uptake of RAI and thyroid size and those who received an empirical dose of RAI. The fixed 7 mCi (259 MBq) dose of RAI cured 80% of patients. CONCLUSION: RAI treatment is effective in treating hyperthyroidism in patients with Graves' disease, but hypothyroidism will develop in 82% of patients in 25 years. Because the development of hypothyroidism seems to be inevitable and unpredictable by any clinical factors, the objective of RAI treatment should be to minimize the persistence of hyperthyroidism with the simplest possible form of treatment. We recommend a fixed 7 mCi dose of RAI to be used as the first empirical dose in the treatment of hyperthyroidism, at least in Graves' disease.     

Randomized prospective study comparing a single radioiodine dose and a single laser therapy session in autonomously functioning thyroid nodules

OBJECTIVE: To compare the efficacy of interstitial laser photocoagulation (ILP) with radioiodine in hot thyroid nodules. DESIGN: Thirty consecutive outpatients with subclinical or mild hyperthyroidism and a scintigraphically solitary hot nodule with extraglandular suppression were randomized to either one ILP session or one radioiodine ((131)I) dose. METHODS: ILP was performed under continuous ultrasound-guidance and with an output power of 2.5-3.5 W. (131)I was given as a single dose based on thyroid volume and a 24-h thyroid (131)I uptake. Thyroid function and nodule volume were evaluated at inclusion and at 1, 3 and 6 months after treatment. RESULTS: Normalization of serum TSH was achieved in 7 out of 14 patients in the ILP group and in all 15 patients in the (131)I group (P=0.0025). In the ILP group, mean thyroid nodule volume reduction was 44+/-5% (s.e.m.; P<0.001), and in the (131)I group 47+/-8% (P<0.001), within 6 months, without between-group difference (P=0.73). The mean reduction of total thyroid volume was 7+/-5% in the ILP group (P=0.20) and 26+/-8% (P=0.006) in the (131)I group (P=0.06 between-group). Two patients in the (131)I group developed hypothyroidism but no major side effects were seen. CONCLUSIONS: This first randomized study, comparing ILP with standard therapy, demonstrates that ILP and (131)I therapy approximately halves thyroid nodule volume within 6 months; but in contrast to (131)I, extranodular thyroid volume is unaffected by ILP and no patient developed hypothyroidism. Using the present design, ILP seems inferior to (131)I therapy in normalization of serum TSH. The potential value of ILP as a non-surgical alternative to (131)I needs further investigation.     

The efficacy of long term thyrostatic treatment in elderly patients with toxic nodular goitre compared to radioiodine therapy with different doses.

The objective of the study was to investigate the efficacy of long term thyrostatic versus radioiodine treatment of hyperthyroidism in old age. Our study is a retrospective analysis of the therapeutical outcome in 66 patients over 60 years of age with toxic nodular goitre. The patients were divided in two groups: Group A: 28 patients on methimazole treatment: starting dose 5-30, median (M) 10 mg, maintenance dose 2.5-15 (M = 5) mg, follow up 6 to 240 months (M = 23.5 months). Group B: 38 patients treated by either 100-300 MBq (N = 14, subgroup B1) or 325-1000 MBq (N = 24, subgroup B2) 131I, follow up: 18 to 156 months (M = 48 months). The efficacy of the different therapeutical approaches were compared by calculating the occurrence rate of persisting and relapsing thyroid dysfunctions and associated side effects. The 28 patients on methimazole treatment became euthyroid after 1-16 (M = 5) months but numerous relapses occurred in the follow up: hyperthyroidism, clinical: 5, subclinical 13, (relapse duration: M = 8 months; associated symptoms: hypertension in 4, cardiac arrhythmia in 3, cerebral embolism in 1, angina pectoris in 2, weight loss in 2 cases). Poor patient's compliance (9/28) or dose reduction by the physician (5/28) were the main causes of the relapses. Transient clinical (3 cases) or subclinical (6 cases) hypothyroidism also occurred (duration: 1-3 M = 2 months, no clinical symptoms). In 7 out of 14 (50%) patients receiving 100-300 MBq 131I (Group B1) hyperthyroidism persisted (versus 4/24 -16.7%- in Group B2 following 325-1000 MBq 131I; chi2(1) = 4.78 P = 0.028), methimazole treatment had to be continued in 9/14 patients (64.3%) (versus 5/24 -20.8%)- in Group B2., chi2(1) = 7.18 P = 0.0074) and in 5/14 (35.7%) the radiotherapy had to be repeated (versus 5/24 -020.8%- in Group B2, not sign.). Our conclusions are: 1) long term thyrostatic treatment is not safe in elderly patients with toxic nodular hyperthyroidism, mainly because of poor compliance or dose reduction by the physician; 2) radioiodine treatment as the first choice should be recommended for these patients and higher doses should be preferred.     

The effect of methimazole pretreatment on the efficacy of radioactive iodine therapy in Graves' hyperthyroidism: one-year follow-up of a prospective, randomized study

The effect of antithyroid drugs on the efficacy of radioiodine (131I) treatment is still controversial. This study evaluated the effect of methimazole pretreatment on the efficacy of 131I therapy in Graves' hyperthyroidism. Sixty-one untreated patients were randomly assigned to receive 131I alone (32 patients) or 131I plus pretreatment with methimazole (30 mg/d; 29 patients). 131I was administered 4 d after drug discontinuation. The calculated 131I dose was 200 microCi/g thyroid tissue as estimated by ultrasound, corrected by 24-h radioiodine uptake. Serum TSH, T4, and free T4 were measured 4 d before 131I therapy, on the day of treatment, and then monthly for 1 yr. Considering cure as euthyroidism or hypothyroidism, based on free T4 measurement, approximately 80% of patients from both groups were cured 3 months after beginning 131I treatment. After 1 yr the groups were similar in terms of persistent hyperthyroidism (15.6% vs. 13.8%), euthyroidism (28.1% vs. 31.0%), or hypothyroidism (56.3% vs. 55.2%). Relapsed patients presented larger thyroid volume (P = 0.002), higher 24-h radioiodine uptake (P = 0.022), and T3 levels (P = 0.002). Multiple logistic regression analysis identified T3 values as an independent predictor of therapy failure. In conclusion, pretreatment with methimazole had no effect on either the time required for cure or the 1-yr success rate of 131I therapy.     

The treatment of Graves' disease with antithyroid drugs and small doses of radioiodine (author's transl)

Three hundred and thirty Graves' disease patients (258 F. 72 M. ; mean age = 50 +/- 07 years) were treated by 131I from 1961 to 1979 ; 57 % had a goiter and 32 % had exophthalmos. One or several doses of radioiodine were given to each patient without dosimetry. The mean total dose (+/- SEM) was = 8,51 +/- 0,44 mCi and the mean for the first dose 4,34 +/- 4 ans 54,8 % of the patients received only one dose but 10,3 % of them had more than 3 doses. Data obtained by actuarial methods showed 66 % of the cases to be in remission in less than 2 years ; the frequency of hypothyroidism increased steadily by 3 % every year to give 15 % at 5 years and 30 % at 10 years. Remission was slower to occur in goitrous subjects and hypothyroidism was less frequent in this group despite doses significantly higher of radioiodine (p less than 0,001). Recovery was also slower among exophthalmos patients. Finally, the mean 3-hour radioiodine uptake and plasma T3 level were significantly lower six months after the first therapeutic dose among those who were cured of thier hyperthyroidism within two years.     

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.     

PRODUCTION OF NON-STIMULATORY IMMUNOGLOBULINS THAT INHIBIT TSH BINDING IN Graves'' DISEASE AFTER RADIOIODINE ADMINISTRATION

The effect of a single dose of ¹³¹I upon thyroid stimulating immunoglobulins has been studied in twenty-two patients with Graves' disease. The thyroid stimulating immunoglobulins were assessed by parallel measurements of thyrotrophin receptor binding inhibitory immunoglobulins (TBII) and of thyroid adenylate cyclase stimulating immunoglobulins (TACSI) in serum by radioreceptor assay and stimulation of adenylate cyclase respectively. Prior to ¹³¹I therapy TBII were present in fourteen and TACSI in sixteen patients; seventeen were positive in one of the assays and thirteen in both assays. After radioiodine the level of both TACSI and TBII increased in most patients, but in six patients ¹³¹I therapy appeared to lead to a dissociation between the TBII and TACSI. After 12 months, nine patients were still positive in both assays, and twenty-one in one of the assays. In total, five patients developed hypothyroidism within 1 year after radioiodine. The TBII levels were significantly higher both before and 3 months after therapy in these patients than in those who remained euthyroid. Two of the hypothyroid patients developed non-stimulatory TSH binding inhibitory antibodies. The present study thus confirms that radioiodine therapy is followed by an increase of TBII and TACSI in most patients with Graves' disease. The level of TBII can probably provide a marker for development of hypothyroidism following ¹³¹I therapy and might be involved in its pathogenesis.     

A novel mutation causing complete deficiency of thyroxine binding globulin

OBJECTIVE Recovery of thyroid function in patients following hypothyroidism induced by ¹³¹I therapy for Graves' disease has been described, but only a few detailed clinical and biochemical studies of this phenomenon (transient hypothyroidism) have been published. The prevalence, mechanism, and final outcome of transient hypothyroidism in 260 patients with Graves’ disease treated with ¹³¹I was studied. DESIGN A retrospective study. PATIENTS Two hundred sixty patients with Graves' disease, treated with ¹³¹I between 1 and 15 years previously, were categorized into 4 groups according to their thyroid function during and 1 year after therapy (Group 1: permanent hypothyroidism, 28 patients; Group 2: transient hypothyroidism, 39 patients; Group 3: euthyroidism without transient hypothyroidism, 83 patients; Group 4: hyperthyroidism, 110 patients). MEASUREMENTS We compared total T4, total T3, TSH, anti-thyroglobulin (TGHA) and anti-microsomal (MCHA) antibodies, the TSH-binding inhibitory immunoglobulin (TBII) index, thyroid weight, dose of ¹³¹I, and 24-hour ¹³¹I uptake as pretreatment variables. The mean time for permanent hypothyroidism to develop was estimated by the Kaplan–Meier product limit method. The TBII index and thyroid stimulating antibody (TSAb) activity were measured in seven patients from Group 1 and in nine patients from Group 2 at the time that they became hypothyroid. RESULTS Hypothyroidism developing within 12 months of therapy was transient in 58% (39/67) of patients. No pretreatment variables were found to differ between patients with and without transient hypothyroidism. The mean estimated time between therapy and the development of permanent hypothyroidism was 96 months in Group 2; this time interval was significantly shorter than 126 months in Group 3 and 129 months in Group 4 (P<0.05, P<0.01, respectively). TSAb activity was > 500% in 78% (7/9) of patients from Group 2, which was significantly higher than that found (14%, 1/7) in Group 1. CONCLUSIONS These results indicate that (1) more than half the patients who developed hypothyroidism within 6 months after ¹³¹I treatment for Graves' disease recovered spontaneously, (2) TSAb activity might play some role in the recovery of transient hypothyroidism, and (3) the development of transient hypothyroidism may influence long-term thyroid function.     

A randomized controlled trial to evaluate the adjuvant effect of lithium on radioiodine treatment of hyperthyroidism.

OBJECTIVE: To evaluate the role of lithium (Li) as an adjuvant in radioiodine therapy of hyperthyroidism. METHODS: A randomized controlled trial was carried out on 350 hyperthyroid patients with a mean follow-up period of 32.3 +/- 9.8 months (range, 12-60 months). The patients were randomized into two groups with 175 patients in each group: (1) radioiodine group (controls)-no lithium was given to these patients at any stage of their treatment and (2) radioiodine and lithium group (Li group)-lithium carbonate, 300 mg three times a day, for 3 weeks starting on the day of radioiodine administration. All patients were made euthyroid with antithyroid drugs prior to radioiodine therapy. RESULTS: Mean age was 41.8 +/- 11.5 years (range, 18-71) in the control group and 41.8 +/- 12.2 years (range, 19-73) in the Li group. Mean first dose and cumulative dose of (131)I were 229 +/- 85 MBq and 326 +/- 204 MBq in controls and 233 +/- 110 MBq and 344 +/- 281 MBq in the Li group. Average number of radioiodine therapy administered was the same (1.4) in both groups. The cure rate (euthyroid plus hypothyroid) after the first dose of radioiodine in the control and the lithium groups was 68.4% and 68.9%, respectively (p = ns). The overall cure rate at the end of the study was also the same in both groups (96.7% and 96.3%, respectively). Even in patients with a rapidly discharging gland or in patients with a large goiter, no significant statistical difference was observed in radioiodine therapy outcome between the two groups. Ten percent of the patients complained of mild to moderate side effects of lithium. CONCLUSION: The role of lithium as an adjuvant in radioiodine therapy of hyperthyroidism is insignificant.