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.     

Serum thyrotropin-receptor autoantibodies levels after I therapy in Graves' patients: effect of pretreatment with methimazole evaluated by a prospective, randomized study

OBJECTIVE: Radioiodine therapy (131I) in hyperthyroid Graves' disease is generally followed by a transitory increase in levels of thyrotropin receptors antibodies (TRAb). Immunosuppressive effects of antithyroid drugs are still a matter of debate. In this study we evaluated the effect of methimazole pretreatment on the TRAb boost induced by 131I. DESIGN: A randomized, prospective clinical trial. METHODS: 61 patients were randomly assigned to receive 131I alone (32 patients) or 131I plus pretreatment with methimazole (30 mg/day; 29 patients). Serum TRAb levels were measured on the day of 131I dosing (D0), and at 1, 3, 6 and 12 months after 131I administration. RESULTS: The mean serum TRAb levels decreased significantly from baseline to D0 in patients treated with methimazole (80.8 vs 48.8 U/l; P<0.05). After 131I treatment, TRAb levels increased at 3 months (48.8 to 60 U/l; 19%) and they were still elevated at 6 months compared with D0 values (99.9 U/l; 105%). Thereafter, TRAb levels decreased to baseline values (47.8 U/l) at 12 months. In hyperthyroid patients, TRAb levels increased significantly from D0 to 1 month (45.0 to 78 U/l; 73%) reaching their highest levels at 3 months (225 U/l; 400%). After this, we observed a progressive decrease to the baseline levels at 12 months (40.0 U/l). The course of TRAb levels after 131I treatment was significantly different between the two groups (P<0.05). Multiple regression analysis identified serum TRAb levels on D0 as independent predictors of TRAb increment after 131I therapy (r2=0.34; P=0.001). A higher increment in serum TRAb levels was associated with hypothyroidism after 1 year of follow-up. CONCLUSION: Methimazole pretreatment attenuates the 131I-induced rise in serum TRAb levels. The effects of methimazole could be attributed to a direct immunomodulatory action or may be due to its effects on the control of hyperthyroidism, which is a known cause of immune dysregulation.     

The effect of combination therapy with propylthiouracil and cholestyramine in the treatment of Graves' hyperthyroidism

OBJECTIVE: The study aims to evaluate the efficacy of combination therapy with propylthiouracil (PTU) and cholestyramine in the treatment of Graves' hyperthyroidism. BACKGROUND: Thyroxine (T4) is metabolized mainly in the liver by conjugation to glucuronides and sulphates that enter the enterohepatic circulation. Thyrotoxic patients have an abnormal increase in thyroid hormone in their enterohepatic circulation. Previous studies on combination therapy with methimazole and cholestyramine for Graves' hyperthyroidism have shown it to be an effective adjunctive treatment. In this study, we examined the efficacy of combination therapy with PTU and cholestyramine in the treatment of Graves' hyperthyroidism. METHODS: Thirty patients with newly diagnosed Graves' hyperthyroidism were randomly divided into two groups: group I (n = 15) received PTU 100 mg twice a day, propranolol 40 mg twice a day and cholestyramine 4 g twice a day for 4 weeks; group II (n = 15) received PTU 100 mg twice a day and propranolol 40 mg twice a day for 4 weeks. The therapeutic efficacy was determined by serum total triiodothyronine (TT3), free thyroxine (FT4) and TRAb levels at baseline, and at the end of 2 and 4 weeks during the study period. RESULTS: There was no significant difference in baseline thyroid function parameters. At the end of 2 and 4 weeks of the study period, serum TT3 and FT4 levels of group I were significantly lower than those of group II. No significant differences in the TRAb level were found between the two groups. CONCLUSION: Cholestyramine contributed to a more rapid and complete decline in thyroid hormone levels in patients with Graves' hyperthyroidism. It was thus proved to be an effective and well-tolerated adjunctive therapy.     

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.     

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.     

Therapy of Graves' disease with sodium ipodate is associated with a high recurrence rate of hyperthyroidism.

To evaluate the long-term efficacy of sodium ipodate (IPO) in the treatment of hyperthyroid Graves' disease, we studied 12 consecutive patients with Graves' hyperthyroidism treated only with 500 mg IPO po daily for several weeks to 22 months. Serum thyroid hormone concentrations markedly decreased and serum free T3 values normalized in all patients within 7 days of therapy. Five patients (42%, Group 1) were euthyroid after 6 weeks of IPO treatment and remained so until IPO was discontinued after 22 months. Recurrence of hyperthyroidism after drug withdrawal occurred in only one of these Group 1 patients, who was promptly responsive to a second course of IPO. In contrast, seven of 12 patients (58%, Group 2) relapsed with recurrent hyperthyroidism between 14 and 42 days of IPO therapy. After IPO was withdrawn, these Group 2 patients were treated with methimazole (20-30 mg/day, initial dose), but the therapeutic response was poor and delayed. Two patients were still hyperthyroid after 6 months of methimazole treatment. Elevated serum FT3 concentrations were observed in the Group 2 patients at 21 days following the early normalization of serum FT3 concentrations. No changes in serum thyroglobulin and thyroid microsomal and TSH-receptor autoantibody titers were observed in either groups during IPO therapy. In conclusion, the results of the present study demonstrate that IPO rapidly restores euthyroidism, but its prolonged administration is associated with a high rate of relapse of hyperthyroidism and a poor response to subsequent methimazole treatment and that long-term IPO administration does not affect humoral markers of thyroid autoimmunity.     

Studies of thyroid function and immune parameters in patients with hyperthyroid Graves' disease in remission

The natural course of hyperthyroidism due to Graves' disease after discontinuation of antithyroid drug therapy was studied in 184 patients who had been treated with methimazole and whose thyroid function was suppressible with T3 when methimazole was discontinued. The patients were followed after discontinuation of therapy for up to 60 months. Serum T4, free T4 (FT4) and T3 levels, TSH receptor antibody (TRab) and anti-DNA antibody titers, and the percentage of HLA-DR positive lymphocytes in peripheral blood were measured serially. TRab and anti-DNA antibody tests were positive in the majority of patients before treatment and were negative in most at the end of treatment. Twenty-three (12.5%) patients had a recurrence of their hyperthyroidism, which occurred a mean of 20 months after withdrawal of methimazole; they are designated as having overt recurrent hyperthyroidism (group A). In these patients, serum T4, FT4 and T3 concentrations increased rather abruptly to markedly elevated levels in a several-month period and the TRab and anti-DNA antibody titers increased markedly at or shortly after recurrence in the majority. In 9 patients (4.1%), TRH-induced TSH secretion became totally suppressed, indicating the reappearance of thyroidal autonomy; however, the patients did not have any hyperthyroid signs and symptoms (subclinical hyperthyroidism; group B). Their serum T4 and FT4 concentrations fluctuated in the upper normal to slightly supra-normal range, and their serum T3 concentrations remained within the normal range throughout the follow-up period, but their TRab and anti-DNA antibody titers did not appreciably increase. Thus, the time of recurrence could not be precisely determined in group B. In the remainder (152 patients; 83.4%), serum thyroid hormone levels and TRH-induced TSH secretion remained normal, TRab and anti-DNA antibody titers remained negative, and hyperthyroidism did not recur (euthyroid remission; group C). At the time of final examination (in groups B and C) or at the time of recurrence (in group A), the percentage of HLA-DR positive peripheral lymphocytes was 17.9% in group A, 15.9% in group B, and 12.1% in group C. Retrospective analysis of the data indicated that the mean pretreatment TRab titer (percent inhibition of TSH binding) was slightly but not significantly lower in group C (37.8%) compared to those in group A (53.9%) and group B (54.8%). The 3 groups were indistinguishable by all other laboratory data both before treatment and at the time of the T3 suppression test. These data strongly indicate heterogeneity among patients with hyperthyroidism due to Graves' disease.(ABSTRACT TRUNCATED AT 400 WORDS)     

The effect of methimazole on cure rates after radioiodine treatment for Graves' hyperthyroidism: a randomized clinical trial.

Forty-two newly diagnosed patients with Graves' hyperthyroidism were randomly assigned to receive 131I therapy after pretreatment with methimazole (21) or beta-blocker alone (21) and prospectively evaluated, to determine possible effects of methimazole on 131I treatment outcome. After randomization, 8 patients were excluded from the study (5 from pretreatment group and 3 from nonpretreatment group). Radioactive iodine (baseline dose 15 mCi, adjusted for goiter size and/or 131I uptake) was administered after pretreatment with methimazole (30 mg initial dose for at least 2 months and stopped 6 days before treatment) and beta-blocker or pretreatment with beta-blocker alone (atenolol 50-100 mg/d). All but one patient in each group became hypothyroid. A similar length of time was required by both groups to achieve hypothyroidism (112 days, [95% confidence interval [CI] = 28 to 196 days) in the pretreated group and 106 days, [95% CI = 45 to 167 days] in nonpretreated patients). Free thyroxine (T4) normalized 44 +/- 39 days after therapy in the nonpretreated group and 35 +/- 30 days in the pretreated group (p = 0.57) and decreased to subnormal levels 80 +/- 70 days in nonpretreated and 65 +/- 32 days in pretreated patients (p = 0.46). We conclude that pretreating patients with methimazole before radioactive iodine therapy does not interfere with the final outcome. Similar cure rates and time required to achieve hypothyroidism after radioiodine were observed when patients were pretreated with methimazole compared to nonpretreated patients.     

Propylthiouracil reduces the effectiveness of radioiodine treatment in hyperthyroid patients with Graves' disease.

In order to assess the effect of propylthiouracil (PTU) or methimazole (MMI) pretreatment on patient outcome after radioiodine therapy, we examined 100 patients with Graves' disease 3, 6, 9, and 12 months after administration of a 10-mCi standard single dose of 131I. They were assigned to one of three groups: no drug (ND) treatment (30 cases); MMI (45 cases); and PTU (25 cases). Antithyroid drugs (ATD) were withdrawn 15 days before radioiodine administration. The groups were similar concerning age, gender, ATD pretreatment duration, goiter size, and initial serum triiodothyronine (T3), thyroxine (T4), free thyroxine (FT4), antithyroid autoantibody levels, 24-hour radioiodine uptake and 131I dose administered per gram of thyroid tissue. ND and MMI groups presented a similar rate of cure of 73.3% and 77.8% respectively (p = NS). In contrast, the PTU group showed a rate of cure of only 32% (p < 0.05). Logistic regression analysis indicated that PTU administration (p = 0.003) and thyroid size (p = 0.02) were the variables related to radioiodine therapy failure. Our data demonstrate that the chance of 131I treatment failure is higher in individuals using PTU than in patients using MMI or not using any ATD before radioiodine (odds ratio [OR] 5.84; 95% confidence interval [CI] 1.82-18.76) suggesting that PTU should be avoided in the treatment of patients with Graves' disease.     

Efficacy of single daily dosage of methimazole vs. propylthiouracil in the induction of euthyroidism

OBJECTIVE: Previous studies of the treatment of hyperthyroidism with a single daily dose of antithyroid drugs have demonstrated a favourable result with methimazole (MMI). However, the efficacy of a single daily dose of propylthiouracil (PTU) was inconsistent. The present prospective randomized study was conducted to compare the efficacy of a single daily dose of MMI and PTU in the induction of euthyroidism in patients with Graves' disease. SUBJECTS: Seventy-one patients with newly diagnosed Graves' disease were studied. METHODS AND MEASUREMENTS: Patients were randomized to two groups to receive once daily dose of either 15 mg MMI or 150 mg PTU for 12 weeks. The therapeutic efficacy was determined biochemically by serum total T3, total T4 and TSH levels at baseline and at 4, 8 and 12 weeks during the study period. RESULTS: There was no significant difference in baseline characteristics. Serum total T3 levels of the MMI group were significantly lower than those of the PTU group after four weeks of the treatment (3.54 +/- 0.72 vs. 5.49 +/- 2.74 nmol/l, P < 0.05) through the end of the study (2.22 +/- 1.42 vs. 4.30 +/- 1.78 nmol/l, P < 0.05). The changes in serum total T4 levels occurred in the same direction as serum total T3 levels but a significant difference was observed only after eight weeks of the treatment (MMI vs. PTU; 101.67 +/- 54.05 vs. 176.32 +/- 66.92 nmol/l, P < 0.05). At the end of the study, more patients in the MMI group had both serum total T3 and T4 levels less than the upper limit of the normal range compared to the PTU group (77.1% vs. 19.4%). Hypothyroidism was observed in 31.4% of the patients in the MMI group but not in the PTU group. CONCLUSIONS: During 12-weeks' treatment of Graves' hyperthyroidism, a single daily dose of 15 mg of MMI was much more effective in the induction of euthyroidism than a single daily dose of 150 mg of PTU. Once daily regimen of MMI not only decreased serum T3 and T4 levels more rapidly but also induced euthyroidism four times more effectively than did the once daily regimen of PTU. In the doses used in this study, MMI is preferable to PTU when a once-daily regimen of antithyroid drug is considered for the treatment of hyperthyroidism.     

Is excessive weight gain after ablative treatment of hyperthyroidism due to inadequate thyroid hormone therapy?

There is controversy about the correct dose and form of thyroid hormone therapy for patients with hypothyroidism. Despite restoration of serum thyrotropin (TSH) concentrations to normal, many patients complain of excessive weight gain. We have compared weight at diagnosis of hyperthyroidism with that when euthyroid, evidenced by a stable, normal serum TSH concentration, with or without thyroxine (T4) replacement therapy, in patients treated with an 18-month course of antithyroid drugs (43 patients), surgery (56 patients), or 13I (34 patients) for Graves' disease. In addition, weights were recorded before and after treatment of 25 patients with differentiated thyroid carcinoma by total thyroidectomy, 131I, and long-term T4 suppressive therapy, resulting in undetectable serum TSH concentrations. Mean weight gain in patients with Graves' disease who required T4 replacement therapy following surgery was significantly greater than in those of the same age, sex, and severity of hyperthyroidism rendered euthyroid by surgery (3.9 kg) (p < 0.001) or at the end of a course of antithyroid drugs (4.1 kg) (p < 0.001). Weight gain was similar in those requiring T4 replacement following surgery or 131T therapy (10.4 versus 10.1 kg). In contrast, ablative therapy combined with suppression of TSH secretion by T4 in patients with differentiated thyroid carcinoma did not result in weight gain. The excessive weight gain in patients becoming hypothyroid after destructive therapy for Graves' disease suggests that restoration of serum TSH to the reference range by T4 alone may constitute inadequate hormone replacement.     

Comparison of single daily dose of methimazole and propylthiouracil in the treatment of Graves' hyperthyroidism

OBJECTIVE: The present study was to compare the efficacy of a single daily dose of methimazole (MMI) and propylthiouracil (PTU) in the treatment of Graves' hyperthyroidism. BACKGROUND: Antithyroid drugs, MMI and PTU, are widely used in the treatment of hyperthyroidism. Previous studies in the treatment of hyperthyroidism with a single daily dose of antithyroid drugs have demonstrated a more favourable result with MMI. However, the efficacy of a single daily dose of PTU was inconsistent. In this study, we examined the therapeutic efficacy of single daily doses of MMI and PTU on the change of thyroid hormones and thyrotropin receptor antibodies (TRAb) levels. METHODS: Thirty patients with newly diagnosed Graves' hyperthyroidism were randomly divided into two groups, each receiving a single dose of either 15 mg MMI or 150 mg PTU daily for 12 weeks. The therapeutic efficacy was determined by serum total triiodothyronine (TT3), total thyroxine (TT4), thyrotropin (TSH), free thyroxine (FT4), and TRAb levels at baseline and at the end of 4, 8 and 12 weeks during the study period. RESULTS: There was no significant difference in baseline thyroid function parameters. Serum TT3, TT4 and FT4 levels in the MMI-treated group were significantly lower than those of the PTU-treated group after 4 weeks and through the end of the study. MMI also has superior effect on reducing serum TRAb levels than PTU after 8 weeks and at the end of the study. CONCLUSION: During the 12-week treatment of Graves' hyperthyroidism, a single daily dose of 15 mg MMI was much more effective in the induction of euthyroidism than a single daily dose of 150 mg PTU. In the doses used in this study, MMI is preferable to PTU when a once-daily regimen of antithyroid drug is considered for the treatment of Graves' hyperthyroidism.     

Continued suppression of serum TSH level may be attributed to TSH receptor antibody activity as well as the severity of thyrotoxicosis and the time to recovery of thyroid hormone in treated euthyroid Graves' patients.

The cause of continued suppression of serum thyroid-stimulating hormone (TSH) levels during antithyroid drug therapy in some Graves' patients is unclear. Recently, there has been a notable explanation involving the direct inhibition of TSH receptor antibody (TRAb) on TSH secretion in the pituitary gland. The purpose of this study is to verify the relation between TRAb or other clinical parameters and the continued suppression of serum TSH level during antithyroid drug therapy in patients with Graves' disease. We reviewed the medical records of patients with Graves' disease between 1995 and 2002 at Samsung Medical Center. We selected 167 Graves' patients who had been euthyroid for at least 12 months after recovery of serum T3 and T4 levels during the antithyroid drug therapy. We analyzed the correlation of the interval until recovery of serum TSH with the pretreatment clinical parameters. We compared the recovery rates of suppressed TSH levels between pretreatment thyrotrophin-binding inhibitory immunoglobulin (TBII)-positive (>15%) and TBII-negative patients. We also compared the clinical parameters between two groups at the time of diagnosis and after recovery of thyroid hormone. Pretreatment serum T3 level, (131)I uptake, TBII activity, and the time to recovery of T3 or T4/free T4 level showed significant positive correlations with the interval until recovery of serum TSH level ( p < 0.05). Recovery rates of serum TSH levels at 3 months after recovery of thyroid hormone were significantly lower in pretreatment TBII-positive patients than those in TBII-negative patients ( p < 0.01). Serum TSH levels were significantly lower in TBII-positive patients at 3 months after recovery of thyroid hormone ( p < 0.05). TBII activities inversely correlated only with serum TSH levels at 3months after recovery of thyroid hormone ( p < 0.001). In conclusion, continued suppression of serum TSH level may be attributed to TRAb activity as well as the pretreatment severity of thyrotoxicosis and the time to recovery of thyroid hormone in patients with Graves' disease during antithyroid drug therapy.     

乳头状甲状腺癌术后131I治疗后短期内TSH和甲状腺激素水平变化及临床意义

目的 探讨乳头状甲状腺癌(PTC)患者首次131I治疗清除残余甲状腺组织(清甲治疗)后第5天血清甲状腺功能指标的变化及临床意义.方法 PTC术后患者74例,首次131I清甲治疗剂量3.7 GBq,分别于131I治疗前1 d及治疗后第5天监测PTC患者血清FT3、FT4、TSH.以治疗前TSH水平分A、B两组:A组TSH＜30 mIU/L 22例,B组TSH≥30 mIU/L 52例.统计分析采用配对资料的符号秩和检验及相关性分析.结果 A组在131I治疗后第5天TSH下降87%,FT4升高88%,FT3升高87%,3项指标前后变化均有统计学意义(均P＜0.05),其中45%(10/22)患者达一过性甲状腺毒症水平.B组治疗后第5天三指标变化个体差异大,TSH小幅上升6%(P＞0.05);而FT4下降13%,FT3下降14%,前后变化有统计学差异(均P＜0.05).结论 针对PTC患者首次清甲治疗后短期内,部分患者甲状腺功能指标会升高甚至出现一过性甲状腺毒症,而另一些患者甲状腺激素只轻微下降,个体变化差异大.所以针对清甲治疗后的甲状腺激素替代和抑制治疗宜根据血清甲状腺功能指标监测结果制定个性化治疗计划.     

Comparison of effects of high and low dosage regimens of antithyroid drugs in the management of Graves' hyperthyroidism

We compared the effects of high and low dosages of antithyroid drugs in 113 patients with Graves' hyperthyroidism. The patients were randomly divided into 2 groups. In group A, 65 patients received either methimazole (MMI): 60 +/- 14.5 mg/day (mean +/- SD); range 40-100 mg/day, or propylthiouracil (PTU): 693 +/- 173 mg/day; range 500-1200 mg/day. These high doses were maintained throughout treatment with later addition of 50-75 micrograms T3 daily. Forty eight patients (group B) were treated with lower doses of MMI or PTU without thyroid hormone addition. The maintenance dose of MMI was 13.6 +/- 7 mg/day (range 5-25 mg/day) and that of PTU was 180 +/- 58 mg/day (range 100-300 mg/day). The treatment period was 15.1 +/- 4.2 (range 10-30) months for group A and 13.5 +/- 2.2 (range 12-20) months for group B. Remission occurred in 75.4% patients from group A and in 41.6% patients from group B (P less than 0.001). The mean follow-up was 42 +/- 14 months (17-81 months). The free T4 index (FT4I) in group A remained below the normal range during treatment. The mean FT4I, obtained during the course of treatment, of patients who went into remission from group A was significantly (P less than 0.001) lower than in relapsed patients (4.8 vs. 6.5). Moreover, there was an inverse correlation between mean FT4I and maintenance daily dose of either MMI (r = -0.567; P less than 0.001), or PTU (r = -0.379; P less than 0.01). A fall in microsomal antibody (MCHA) titer occurred mainly in remission patients, and was more significant (P less than 0.05) in group A patients. In contrast, 11 (7 from group B) of the 16 patients with an increase of microsomal antibody levels relapsed. The frequency of negative tests of thyroid-stimulating antibody was higher in group A patients (71%) than in group B (29%) at the end of therapy (P less than 0.01). No correlation was found between thyroid T3 suppressibility and either mean FT4I or thyroid-stimulatory antibody activity during treatment. Our findings show that patients treated with high doses of PTU or MMI throughout treatment have a higher remission rate when compared to those treated with a more conventional regimen. These results support the hypothesis that large antithyroid drug doses may have greater immunosuppressive effects than low dosage regimens. Furthermore, a high dosage regimen could permit the restoration of the immune surveillance mechanisms and, thus, lasting remission of Graves' disease.     

Antithyroid drugs inhibit radioiodine-induced increases in thyroid autoantibodies in hyperthyroid Graves' disease.

Methimazole (MMI) has been reported to affect prognosis in hyperthyroid Graves' disease patients treated with radioiodine (131I). In the present study, serum concentrations of thyroxine (T4), triiodothyronine (T3), thyroglobulin (Tg), thyrotropin-binding inhibitory immunoglobulin (TBII), thyroglobulin antibody (TgAb), and thyroid-peroxidase antibody (TPOAb) were measured serially for 1 year in patients with Graves' disease after 131I treatment either given alone (group 1, 41 patients) or followed by an antithyroid drug (group 2, 19 patients). The effect of antithyroid drugs on these parameters was analyzed retrospectively. Mean serum concentrations of T4 and T3 both decreased to normal within 3 months after 131I treatment in both groups. Serum Tg concentrations in group 1 showed significant transient increases (about four times the basal value) 1 month after 131I administration. Titers of TBII, TgAb, and TPOAb in group 1 also increased transiently after 131I treatment, with the maximum increase at 3 months. Antithyroid drugs significantly lessened 131I-induced increases in serum concentrations of Tg and all thyroid autoantibodies tested. One year after 131I treatment, 33 of 41 patients (80%) were euthyroid or hypothyroid in group 1; this was true for only 4 of 19 group II patients (22%). The results indicate that administering antithyroid drugs after 131I treatment reduced 131I-induced damage to the thyroid and reduced therapeutic efficacy of 131I in hyperthyroidism. Drug treatment also inhibited release of Tg and blunted 131I-induced increases in titers of thyroid autoantibodies.     

Serum concentrations of osteocalcin in patients with hyperthyroidism, hypothyroidism and subacute thyroiditis.

Serum concentration of osteocalcin (OC) was measured in sera from untreated patients with Graves' disease, hypothyroidism due to Hashimoto's thyroiditis, and subacute thyroiditis. Serum concentration of OC in Graves' disease and hypothyroidism were 14.1 +/- 5.6 micrograms/L and 3.8 +/- 2.7 micrograms/L, respectively which were significantly different from that of healthy subjects (Graves' disease, p less than 0.001, hypothyroidism, p less than 0.01). Serum concentration of OC in patients with subacute thyroiditis was 8.0 +/- 3.5 micrograms/L which was not statistically different from age-matched normal controls. Serial measurement of serum OC for 24 mo in 15 patients with Graves' disease after initiation of antithyroid drugs disclosed that the decline of serum OC was obtained only 24 mo after antithyroid drug therapy. On the other hand, in hypothyroid patients, increased serum OC was observed after 1-2 months treatment of L-T4. Correlation coefficients between serum concentrations of OC and T3, T4, FT3 or FT4 in all the patients with thyroid disorders were 0.66, 0.51, 0.50 and 0.54, respectively, which were statistically significant (all, p less than 0.001). These results suggest that osteoblastic activity is enhanced in hyperthyroidism and suppressed in hypothyroidism. In hyperthyroid patients, despite of normalization of FT4 concentration in relatively short period (within 3-4 mo), it took 24 mo after initiation of antithyroid drugs for OC to normalize, suggesting not only thyroid hormone per se but also some unknown factor(s) participates in serum OC secretion. In contrast to thyrotoxic patients, rapid increase in serum OC after initiation of supplemental L-T4 treatment in hypothyroidism was observed, suggesting a direct effect of thyroid hormone on the osteoblasts in patients with hypothyroidism.     

Discordant hypothyroxinemia and hypertriiodothyroninemia in treated patients with hyperthyroid Graves' disease

Hypothyroxinemia and hypertriiodothyroninemia may occur in the course of antithyroid drug or 131I treatment for hyperthyroid Graves' disease. To determine the frequency of combined high serum T3 and low serum T4 concentrations during such treatment and to assess the clinical significance of its recognition, we reviewed 60 patients treated for hyperthyroid Graves' disease with antithyroid drugs (n = 43) or radioactive iodine (n = 17). Six of these patients (10%) were found to have high serum T3 and low serum T4 concentrations during therapy. Four were receiving antithyroid drugs, and 2 had received radioactive iodine. At the time this abnormality occurred, 4 patients were euthyroid, 1 was hypothyroid, and 1 was hyperthyroid. The serum TSH concentration was increased in 2, at the upper limit of normal in 1, and undetectable in 3 patients. In 2 clinically euthyroid patients, these biochemical findings resolved spontaneously. After discontinuation or reduction in the dose of antithyroid drug, clinical and chemical euthyroidism was restored in 2 additional patients with previously elevated TSH levels. In 2 patients, both of whom previously had undetectable serum TSH levels, clinical hyperthyroidism persisted or recurred, and additional therapy was required. No patient developed permanent hypothyroidism during the period of follow-up (1-22 months). An additional 19 of the 60 patients (32%) had an elevated serum T3 level with a normal serum T4 concentration during the course of follow-up. Among these 19 patients, the magnitude of serum T3 elevation was not different between clinically euthyroid (n = 13) and hyperthyroid (n = 6) patients. We conclude that discordance of serum T4 and T3 concentrations is frequently encountered in patients with hyperthyroid Graves' disease during or after therapy. In such patients, the low serum T4 level does not predict hypothyroidism, nor does a high serum T3 level predict hyperthyroidism. Furthermore, the serum T3 concentration in these patients correlates poorly with their clinical thyroid status.     

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.     

Radioiodine treatment of hyperthyroidism-prognostic factors for outcome

There is little consensus regarding the most appropriate dose regimen for radioiodine (131I) in the treatment of hyperthyroidism. We audited 813 consecutive hyperthyroid patients treated with radioiodine to compare the efficacy of 2 fixed-dose regimens used within our center (185 megabequerels, 370 megabequerels) and to explore factors that may predict outcome. Patients were categorized into 3 diagnostic groups: Graves' disease, toxic nodular goiter, and hyperthyroidism of indeterminate etiology. Cure after a single dose of 131I was investigated and defined as euthyroid off all treatment for 6 months or T4 replacement for biochemical hypothyroidism in all groups. As expected, patients given a single dose of 370 megabequerels had a higher cure rate than those given 185 megabequerels, (84.6% vs. 66.6%, P < 0.0001) but an increase in hypothyroidism incidence at 1 yr (60.8% vs. 41.3%, P < 0.0001). There was no difference in cure rate between the groups with Graves' disease and those with toxic nodular goiter (69.5% vs. 71.4%; P, not significant), but Graves' patients had a higher incidence of hypothyroidism (54.5% vs. 31.7%, P < 0.0001). Males had a lower cure rate than females (67.6% vs. 76.7%, P = 0.02), whereas younger patients (<40 yr) had a lower cure rate than patients over 40 yr old (68.9% vs. 79.3%, P < 0.001). Patients with more severe hyperthyroidism (P < 0.0001) and with goiters of medium or large size (P < 0.0001) were less likely to be cured after a single dose of 131I. The use of antithyroid drugs, during a period 2 wk before or after 131I, resulted in a significant reduction in cure rate in patients given 185 megabequerels 131I (P < 0.01) but not 370 megabequerels. Logistic regression analysis showed dose, gender, goiters of medium or large size, and severity of hyperthyroidism to be significant independent prognostic factors for cure after a single dose of 131I. We have demonstrated that a single fixed dose of 370 megabequerels 131I is highly effective in curing toxic nodular hyperthyroidism as well as Graves' hyperthyroidism. Because male patients and those with more severe hyperthyroidism and medium or large-sized goiters are less likely to respond to a single dose of radioiodine, we suggest that the value of higher fixed initial doses of radioiodine should be evaluated in these patient categories with lower cure rates.