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Radioiodine plus recombinant human thyrotropin do not cause acute airway compression and are effective in reducing multinodular goiter

Abstract

Recombinant human thyrotropin (rhTSH) reduces the activity of radioiodine required to treat multinodular goiter (MNG), but acute airway compression can be a life-threatening complication. In this prospective, randomized, double-blind, placebo-controlled study, we assessed the efficacy and safety (including airway compression) of different doses of rhTSH associated with a fixed activity of 131I for treating MNG. Euthyroid patients with MNG (69.3 ± 62.0 mL, 20 females, 2 males, 64 ± 7 years) received 0.1 mg (group I, N = 8) or 0.01 mg (group II, N = 6) rhTSH or placebo (group III, N = 8), 24 h before 1.11 GBq 131I. Radioactive iodine uptake was determined at baseline and 24 h after rhTSH and thyroid volume (TV, baseline and 6 and 12 months after treatment) and tracheal cross-sectional area (TCA, baseline and 2, 7, 180, and 360 days after rhTSH) were determined by magnetic resonance; antithyroid antibodies and thyroid hormones were determined at frequent intervals. After 6 months, TV decreased significantly in groups I (28.5 ± 17.6%) and II (21.6 ± 17.8%), but not in group III (2.7 ± 15.3%). After 12 months, TV decreased significantly in groups I (36.7 ± 18.1%) and II (37.4 ± 27.1%), but not in group III (19.0 ± 24.3%). No significant changes in TCA were observed. T3 and free T4 increased transiently during the first month. After 12 months, 7 patients were hypothyroid (N = 3 in group I and N = 2 in groups II and III). rhTSH plus a 1.11-GBq fixed 131I activity did not cause acute or chronic changes in TCA. After 6 and 12 months, TV reduction was more pronounced among patients treated with rhTSH plus 131I.

Hyperthyroidism; Multinodular goiter; Tracheal airway; 131I; Thyrotropin alpha


Braz J Med Biol Res, March 2010, Volume 43(3) 303-309

Radioiodine plus recombinant human thyrotropin do not cause acute airway compression and are effective in reducing multinodular goiter

Correspondence and Footnotes C.C. Albino1,2, H. Graf3, G. Paz-Filho3,4, L.A. Diehl5, M. Olandoski6, A. Sabbag6 and C. Buchpiguel7

1Instituto de Diabetes e Endocrinologia de Maringá, Maringá, PR, Brasil

2Núcleo Diagnóstico de Maringá, Maringá, PR, Brasil

3SEMPR - Serviço de Endocrinologia e Metabologia, Universidade Federal do Paraná, Curitiba, PR, Brasil

4The John Curtin School of Medical Research, Australian National University, Canberra, Australia

5Universidade Estadual de Londrina, Londrina, PR, Brasil

6Núcleo de Bioestatística, Pontifícia Universidade Católica do Paraná, Curitiba, PR, Brasil

7Departamento de Radiologia, Universidade de São Paulo, São Paulo, SP, Brasil

Patients and Methods

Correspondence and Footnotes Correspondence and Footnotes Correspondence and Footnotes

Abstract

Recombinant human thyrotropin (rhTSH) reduces the activity of radioiodine required to treat multinodular goiter (MNG), but acute airway compression can be a life-threatening complication. In this prospective, randomized, double-blind, placebo-controlled study, we assessed the efficacy and safety (including airway compression) of different doses of rhTSH associated with a fixed activity of 131I for treating MNG. Euthyroid patients with MNG (69.3 ± 62.0 mL, 20 females, 2 males, 64 ± 7 years) received 0.1 mg (group I, N = 8) or 0.01 mg (group II, N = 6) rhTSH or placebo (group III, N = 8), 24 h before 1.11 GBq 131I. Radioactive iodine uptake was determined at baseline and 24 h after rhTSH and thyroid volume (TV, baseline and 6 and 12 months after treatment) and tracheal cross-sectional area (TCA, baseline and 2, 7, 180, and 360 days after rhTSH) were determined by magnetic resonance; antithyroid antibodies and thyroid hormones were determined at frequent intervals. After 6 months, TV decreased significantly in groups I (28.5 ± 17.6%) and II (21.6 ± 17.8%), but not in group III (2.7 ± 15.3%). After 12 months, TV decreased significantly in groups I (36.7 ± 18.1%) and II (37.4 ± 27.1%), but not in group III (19.0 ± 24.3%). No significant changes in TCA were observed. T3 and free T4 increased transiently during the first month. After 12 months, 7 patients were hypothyroid (N = 3 in group I and N = 2 in groups II and III). rhTSH plus a 1.11-GBq fixed 131I activity did not cause acute or chronic changes in TCA. After 6 and 12 months, TV reduction was more pronounced among patients treated with rhTSH plus 131I.

Key words: Hyperthyroidism; Multinodular goiter; Tracheal airway; 131I; Thyrotropin alpha

Introduction

Among many therapeutic options available for volume reduction of multinodular goiter (MNG), surgery is the treatment of choice. This approach leads to immediate reduction in thyroid volume (TV), as well as to prompt resolution of compressive symptoms. Additionally, surgery provides the opportunity for a complete histological evaluation (1). The radioactive isotope 131I can be used as an alternative when surgery is contraindicated or declined by the patient (2).

For the last two decades, radioiodine has been an effective therapy. One year after the administration of 131I, the reduction in TV ranges from 30 to 40% (2,3), with resolution of compressive symptoms in most patients (4). The activity of radioiodine required for a significant TV reduction is positively correlated with the initial TV and inversely correlated with the 24-h radioactive iodine uptake (RAIU). In many patients with MNG, low RAIU is observed. Since most patients with MNG have large goiters and low or normal RAIU, large activities of radioactive 131I are usually required. For this reason, patients treated with 131I are often subject to hospitalization, to greater exposure to radiation, and to higher treatment costs (5).

Recent studies have shown that low doses of recombinant human thyrotropin (rhTSH) not only increase RAIU (6), but also lead to a more homogenous pattern of uptake (7). Taken together, these properties reduce the 131I activity required for the treatment of MNG (8). We have demonstrated that rhTSH, at doses ranging from 0.005 to 0.2 mg, associated with 1.11 GBq 131I, increases RAIU and leads to significant decreases in TV, with mild and readily treatable adverse effects (9-12).

Acute airway compression causing goiter swelling after the administration of rhTSH (13-15) or 131I alone (16,17) can be a life-threatening complication within the first few days after treatment. Airway compression can be evaluated by measuring the tracheal cross-sectional area (TCA). However, there are no studies evaluating TCA within the first week of treatment with rhTSH plus 131I or 131I alone (18). Although treatment of MNG with rhTSH and 131I appears to be effective and safe, there are few prospective controlled studies reported in the literature.

In the present study, we determined the side effects, especially on the airways, of the treatment of euthyroid MNG with a fixed activity of 131I activity, 1.11 GBq, after the administration of placebo or low doses of rhTSH (0.01 or 0.1 mg). This is the first study to evaluate the early effects of combined rhTSH-131I therapy (before 1 week) on TCA. In addition, we evaluated the efficacy of the proposed treatment in terms of thyroid volume reduction.

Patients and Methods

Patients

We evaluated 22 patients with MNG (20 females and 2 males; age 64 ± 7 years). Patients were randomly and consecutively selected from the thyroid outpatient clinic of the Maringá University, Brazil. All patients had goiters larger than 40 mL, and either had a contraindication for surgery, or declined surgery. None of the patients had been previously submitted to surgery or to treatment with radioiodine. Prior to the treatment, malignancy was excluded by ultrasound-guided fine needle aspiration biopsy of the dominant and/or suspect nodules and by cytology studies. None of the participants had used amiodarone or iodinated contrast in the past 12 months. Patients with TSH levels below normal were excluded. Normal levels of creatinine, transaminases and fasting glucose, as well as normal electrocardiogram, excluded the presence of comorbidities.

Methods

This was a prospective, randomized, double-blind, placebo-controlled study. Patients underwent clinical examinations and blood was drawn before treatment and on days 0, 3, 10, 30, 90, 180, and 360. On those days, we determined total triiodothyronine (T3, chemiluminescence, reference range 1.23-3.30 nM, sensitivity 0.29 nM), free thyroxine (T4, chemiluminescence, reference range 10.43-23.81 pM, sensitivity 5.15 pM) and thyroid-stimulating hormone (TSH, chemiluminescence, reference range 0.4-4.0 mIU/L, sensitivity 0.004 mIU/L). TSH receptor antibody (radioimmunoassay, reference range <10 IU/L, sensitivity 0.4 U/L), antithyroperoxidase antibody (TPOAb, chemiluminescence, reference range <10 IU/mL, sensitivity 5 IU/mL) and antithyroglobulin antibody (enzyme immunoassay, reference range <20 IU/mL, sensitivity 2.0 IU/mL) were measured on days 0, 90, 180, and 360. All assays were performed with kits from DPC Diagnostics Products Corporation, USA.

Prior to the treatment, TV was measured by MRI using a 1.5-Telsa magnetic resonance system (Signa GE, 1.5 Tesla, USA), which is an accurate method for assessing TV (19). T1-weighted images were obtained from coronal, transverse and sagittal sections with 0.5 mm of thickness by using a neck coil. The thyroid limits were manually drawn, and the thyroid area was calculated by the built-in (dedicated) software. Thyroid volume was measured at baseline, and 2, 7, 180, and 365 days after treatment with 131I.

Tracheal compression was indirectly estimated by determining the tracheal cross-sectional area before treatment and on days 2, 7, 180, and 360. TCA was obtained by drawing the external border of the trachea, captured through T1-weigheted transverse images.

Basal 24-h RAIU (Pho/Dot scanner, Nuclear Chicago, USA) and 131I scintigraphies (dual-headed SPECT camera, Elscint-Helix, Israel) were obtained after the oral administration of 1.85 MBq 131I. Those evaluations were performed approximately 30 days before treatment and repeated 24 h after the administration of rhTSH or placebo. All patients were advised to follow a low-iodine diet, starting 2 weeks prior to the administration of the diagnostic and therapeutic activities of 131I.

For the treatment, a 1.1-mg vial of rhTSH (Thyrogen®, Genzyme Corp., USA) was diluted with 1.2 mL sterile water for injection, resulting in a 1-mL drawable solution of rhTSH concentrated at 0.9 ng/mL. A 1.0-mL aliquot of this solution was then diluted with 9 mL sterile water for injection, which resulted in a 0.1-mg/mL solution. In order to obtain the 0.01-mg/mL solution of rhTSH, 1 mL of the 0.1-mg solution was diluted with 9 mL sterile water.

Twenty-four hours prior to the administration of 131I (day 0), patients were assigned to a previously predefined treatment group by simple randomization (20). In that procedure, the patients were assigned directly to study and control groups, with no intermediate stages. Patients in group I received 1.0 mL of this solution (0.1 mg rhTSH) intramuscularly, and group II received 1.0 mL of the 0.01-mg/mL solution. Group III received 1.0 mL isotonic saline. On the same day, a tracer activity of 1.85 MBq 131I was given to all patients. On the following day (day 1), RAIU and scintigraphies were obtained, and 1.11 GBq 131I was administered to all participants as a fixed-dose therapeutic scheme.

Adverse effects were evaluated by clinical assessment and by frequent measures of thyroid hormone levels. Patients and investigators were blind to the treatment throughout the study, including the physicians responsible for the interpretation of the scintigraphies, RAIU and MRI.

Statistical analysis

The Shapiro-Wilks test was used to assess normality. One-way ANOVA with repeated measures was used to compare the responses within groups and within time, in normally distributed groups. In case of significant differences between groups by one-way ANOVA, we used the LSD test for multiple comparisons within two groups. For groups without normal distribution, within-group comparisons were made with the Kruskal-Wallis test. In case of significant differences between groups by the Kruskal-Wallis test, we used the Mann-Whitney test for multiple comparisons within two groups. The Wilcoxon test was used to compare the results after treatment with those obtained at baseline. The relative changes determined by the treatment were compared within the groups by covariance analysis, with the pretreatment variable fixed as a co-variable. For dichotomous variables, the groups were compared by a model of logistic regression. Results were considered to be significant when P < 0.05. For multiple comparisons by non-parametric tests, the P value was adjusted by the Bonferroni procedure.

This trial was reviewed and approved by the Ethics Committees of the Universities of Maringá and of São Paulo, Brazil, and written informed consent was obtained from all patients.

Results

Baseline

The baseline characteristics of the patients at the beginning of the study were not significantly different (Table 1).

Thyroid volume

No acute changes in TV were observed on days 2 or 7 in any of the three groups. After 7 days, TV significantly decreased by 4.0 ± 5.8% in group I (P = 0.034) and did not change in group II (4.2 ± 8.4%; P = 0.369). In group III, TV increased by 5.3 ± 4.6% (P = 0.023). The variations in TV were similar between groups II and III (P = 0.754), and both were different from group I (group I vs group II: P = 0.028; group I vs group III: P = 0.009).

After 6 months, TV decreased significantly by 28.5 ± 17.6% in group I (P = 0.001), and by 21.6 ± 17.8% in group II (P = 0.023), but not in group III (2.7 ± 15.3%; P = 0.631). The reductions in TV were similar between groups I and II (P = 0.437), and both were different from group III (group I vs group III: P = 0.005; group II vs group III: P = 0.041).

After 12 months, a significant decrease TV was observed in groups I and II, i.e., 36.7 ± 18.1% (P = 0.008) and 37.4 ± 27.1% (P = 0.004), respectively. In group III, the changes in TV were not significant compared to baseline (19.0 ± 24.3%; P = 0.087). These relative reductions were not statistically different among the groups (P = 0.237). The absolute values of TV are given in Table 2.

Tracheal cross-sectional area

No statistical differences between baseline and post-treatment TCA values were observed in groups I, II and III (ANOVA), and no significant differences in TCA were demonstrable on days 2, 7, 180, and 360 after treatment (Table 3).

RAIU

RAIU increased from a median of 15.5% (4.2-55.0%) to 40.2% (27.8-61.0%; P = 0.025) after 0.1 mg rhTSH in group I. In group II, RAIU increased from 27.0% (16.8-34.3%) to 34.2% (27.6-54.8; P = 0.028). The post-rhTSH RAIU were not different between both groups (P = 0.220). For group III (placebo), no changes in RAIU were observed, with values from 15.3% (3.9-30.6%) to 16.2% (9.9-31.9%), P = 0.889.

Before treatment, heterogeneous thyroid uptake was seen in most of the patients with MNG. After rhTSH, a more homogeneous pattern of 131I distribution was seen in groups I and II.

Thyroid hormones

At baseline, participants in all groups had similar levels of TSH, total T3 and free T4. Since the first post-treatment TSH was measured on day 3, we were unable to identify the peak levels of TSH.

After treatment, no statistically significant changes in free T4 were observed from day 0 to day 30 in group I (P = 0.387). For groups II and III, peak levels of free T4 were detected on day 30 (group II: 17.63 ± 21.9 pM, P = 0.037; group III: 20.72 ± 2.83 pM, P < 0.001), which were significantly higher than in group I (P = 0.001 for both comparisons; Figure 1A).

Levels of T3 increased in all groups after treatment. Group I reached peak levels of T3 on day 3 (2.92 ± 0.81 nM, P = 0.004). In group II, peak levels of T3 were reached on day 30 (2.70 ± -0.46 nM, P = 0.03). In group III, peak levels of T3 were observed on day 10 (2.79 ± 0.62 nM, P < 0.001; Figure 1B). On the first three days, levels of free T4 and total T3 were maintained within the normal range in all groups.

Adverse events

Starting on day 90, hypothyroidism was observed in 2 patients of 8 in group I, 3 of 6 in group II and 1 of 8 in group III. After one year, one additional patient in groups I and III developed hypothyroidism.

Mild cervical discomfort, localized pain and palpitations, suggesting actinic thyroiditis, were reported by 1 patient in each group between days 3 and 10. Propranolol, 80 mg/day, and nonsteroidal anti-inflammatory drugs were prescribed to those patients, with prompt and complete resolution of all symptoms.

Goiter enlargement and/or compressive symptoms with respiratory difficulty were reported at baseline by 3 participants in group I, 2 in group II and 2 in group III. Those symptoms were mild, did not cause physical limitations, and were resolved without additional interventions in all but 1 patient, who had a very large goiter at baseline (351 mL). One year after treatment, that patient from group I remained with the same complaints. After 360 days, in spite of obtaining significant TV reduction and relative improvement of the compressive symptoms, the participant still had a very large goiter (249 mL). Therefore, this patient was referred for a new treatment with 131I (without rhTSH).

One patient in group II and 1 patient in group III did not achieve significant TV reductions and remained with mild cervical discomfort, without respiratory symptoms. However, they preferred clinical observation with no additional treatment.

Before treatment, cosmetic complaints (discomfort due to esthetic issues) were reported by 5 patients in group I, 2 in group II, and 4 in group III. One year after treatment, only 1 patient in each group still had cosmetic complaints. Therefore, the overall satisfaction rate, regarding cosmetic complaints, was 86%.

Antithyroid antibodies

Titers of TSH receptor antibody were negative for all groups throughout the study. Three new patients in group I developed TPOAb on day 90 and continued positive up to day 360, different from groups II and III. The incidence of patients with positive antithyroid antibodies is shown in Table 4.

Figure 1.
Changes in plasma free T4 (A) and T3 (B) after the administration of recombinant human thyrotropin (rhTSH) or placebo and radioiodine. See Table 1 for explanation of groups. The box plot indicates the 1 ± SD with the point within each box being mean. The size of the rectangle indicates SD. *P < 0.05, compared to baseline (ANOVA).

Table 1.
Baseline characteristics of the patients studied, before administration of 131I plus rhTSH or 131I plus placebo.

Table 2.
Thyroid volume (in mL) before and after treatment with rhTSH plus 131I or placebo plus 131I.

Table 3.
Tracheal cross-sectional area before and after treatment with rhTSH plus 131I or placebo plus 131I.

Table 4.
Incidence of patients with positive titers of antithyroid antibodies before and after treatment with rhTSH plus 131I or placebo plus 131I.

Discussion

In the present study, we demonstrated that treatment with 131I did not lead to acute airway obstruction, and this was independent of the administration of rhTSH. The combination of 131I and rhTSH at 0.01 or 0.10 mg was safe, since the incidence of adverse events was similar in all groups. In addition, treatment of MNG with 131I and rhTSH led to significant TV reduction, superior to placebo, 6 and 12 months after treatment.

Our study presents data on TCA 48 h after the administration of radioiodine, preceded or not by rhTSH for the first time. We did not observe significant differences in TCA after therapy, either within or between groups. This result agrees with the findings from Fast et al. (15) and from Bonnema et al. (18). However, in discordance with the latter study, we did not observe significant individual changes in TCA. Therefore, in our study, we showed that treatment with radioiodine does not influence TCA, regardless of the use of rhTSH. This could be explained by the lack of correlation between TCA and TV, also observed by Bonnema et al. (18).

In patients with MNG, rhTSH increases RAIU and determines a more homogenous distribution of radioiodine (7,8), which allows a reduction in the activity of 131I administered (8). Treatment of MNG with 131I alone leads to decreases in TV by 30 to 40% after 12 months (2-4). Studies evaluating the effects of rhTSH as an adjuvant to fixed activities of 131I have shown more pronounced TV reductions ranging from 34% in the first 6 months (21), to 58% in the first year (22). Even with a very low dose, we have demonstrated that rhTSH was safe and effective (10). In double-blind, randomized, placebo-controlled studies that used adjusted activities of 131I, TV reductions ranged between 53 (23) and 62% (24), which were significantly greater in the groups that received rhTSH when compared to placebo.

In our study, TV reduction, compared to baseline, was significantly higher among rhTSH-treated patients, at both 6 and 12 months. Our findings agree with previous studies that evaluated goiter reduction with rhTSH and 131I. In those studies, goiter reduction was more significant in patients treated with rhTSH plus 131I compared to those treated with 131I alone. However, in terms of relative changes in TV, there was no difference between groups at the 12th month. This finding can be attributed to the relatively small and heterogeneous sample.

No significant transient increases in TSH were observed, with unexpectedly low peak levels in all groups. Had TSH been measured on day 2, higher TSH levels could have been observed. Significant peak levels of free T4 were observed only in groups II and III. This suggests that the increase in free T4 may be attributed more importantly to the actinic effect of radioiodine than to the stimulatory effect of rhTSH. Significant increases in T3 were observed in all groups, with higher levels in the groups that received rhTSH. This suggests that rhTSH leads to more pronounced changes in T3 than in free T4. The timing of the T3 peaks is explainable by the rhTSH (D3 in group I) vs the actinic effect of 131I (D10-30 in groups II and III). The changes in thyroid hormones should be interpreted with caution due to the heterogeneity regarding thyroid function at baseline. Nevertheless, the mean changes in thyroid hormones remained within normal ranges during the study in all groups.

In agreement with the results of a previous study (21), our data suggest that rhTSH does not increase the incidence of hypothyroidism when compared to placebo, probably because we used low doses of rhTSH. However, other studies obtained different results (22,24).

The incidence of thyrotoxic symptoms was equally distributed among the three groups. Those symptoms were mild and readily treatable with beta-blockers and nonsteroidal anti-inflammatory drugs. Since the incidence of symptomatic thyrotoxicosis was very low, we do not advocate the use of prophylactic beta-blockers.

The changes in TPOAb suggest that a higher dose of rhTSH may elicit a stronger, earlier and transient immunological response, in contrast with the results reported by Rubio et al. (25). In their study, the TPOAb surge after 131I occurred independently of the rhTSH dose.

We chose the highest outpatient radioactivity of 131I that is permitted by the Brazilian regulatory agencies. Patients receiving more than 1.11 GBq need to be hospitalized. By administering 1.11 GBq, the need for hospitalization was eliminated and the success rates were maximized.

Our study has some limitations. First, although this was a randomized study, our sample size provided a less-than-optimal statistical power. This could have led to the absence of difference in TV reduction at the 12th month between groups. Second, we have included some patients with relatively high RAIU, who could have been treated without the need for rhTSH. Third, we did not assess iodine intake in our patients, which could have compromised our findings if adherence to the diet was low. This confounding factor could have been eliminated by measuring urinary iodine, a procedure that was not undertaken due to logistic issues. Fourth, it is known that rhTSH leads to maximum stimulation of the expression of the Na+/I- symporter 24 to 72 h after its injection (26). Possibly, in our study, the post-rhTSH RAIU was underestimated, since the tracer activity of 131I was administered only 2 h after rhTSH. A strength of our study is the homogeneous sample investigated, consisting only of euthyroid patients. In spite of these limitations, the design of our study proved to be practical and easily applicable in a clinical setting.

In this controlled study, we observed that the use of rhTSH as an adjuvant to a fixed 1.11 GBq activity of 131I for the treatment of MNG is safe, without acute airway compression, and with mild to transient adverse effects. rhTSH enhances TV reduction 6 months and 1 year after treatment. Larger studies are needed to confirm whether the superiority of rhTSH plus 131I persists after a prolonged follow-up.

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Acknowledgments

G. Paz-Filho received consulting fees from Genzyme do Brasil. This study was partially funded by Genzyme do Brasil. Genzyme do Brasil did not have any involvement in the study design, data collection, data analysis, manuscript preparation, and/or publication decisions.

Address for correspondence: C.C. Albino, Rua Silva Jardim, 160, 87013-010 Maringá, PR, Brasil. Fax: +55-44-3028-1114. E-mail: ccalbino@uol.com.br

Received May 3, 2009. Accepted January 7, 2010. Available online January 22, 2010. Published March 12, 2010.

The Brazilian Journal of Medical and Biological Research is partially financed by

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  • Correspondence and Footnotes

  • Publication Dates

    • Publication in this collection
      09 Mar 2010
    • Date of issue
      Mar 2010

    History

    • Accepted
      07 Jan 2010
    • Received
      03 May 2009
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