Influence of body surface area on serum peak thyrotropin (TSH) levels after recombinant human TSH administration

Recombinant human TSH (rhTSH) has been proposed as an alternative method to the withdrawal of thyroid hormones in the follow-up of differentiated thyroid cancer. The aim of the present study was to evaluate the influence of several demographic and anthropometric parameters [age, body weight, height, body mass index, and body surface area (BSA)] on serum peak TSH levels after rhTSH administration. rhTSH was administered to 112 patients with differentiated thyroid carcinoma according to the conventional two-dose schedule (0.9 mg/d). Serum TSH levels were measured 24 h before and after the first administration of rhTSH, and then 24, 48, and 72 h after the second administration of rhTSH. In one severely obese patient, serum peak TSH values did not reach a valid stimulation range. Serum peak TSH levels were negatively related to body weight (r = -0.69; P < 0.0001), body mass index (r = -0.51; P < 0.0001), and BSA (r = -0.72; P < 0.0001). In a multivariate regression analysis including demographic and anthropometric variables, only BSA was independently associated to serum peak TSH concentrations (standardized beta coefficient = -0.721; P < 0.0001). In conclusion, body size seems to influence serum peak TSH levels after rhTSH administration. Future studies should evaluate the possibility of using personalized rhTSH doses, adjusted in relation to BSA.     

Ablation of thyroid residues with 30 mCi (131)I: a comparison in thyroid cancer patients prepared with recombinant human TSH or thyroid hormone withdrawal

The aim of the study was to assess whether stimulation by recombinant human TSH (rhTSH) may be used in patients with differentiated thyroid carcinoma for postsurgical ablation of thyroid remnants using a 30-mCi standard dose of (131)I during thyroid hormone therapy. The rate of ablation was prospectively compared in three groups of patients consecutively assigned to one of three treatment arms: in the first arm, patients (n = 50) were treated while hypothyroid (HYPO); in the second arm, patients (n = 42) were treated while HYPO and stimulated in addition with rhTSH (HYPO + rhTSH); in the third arm, patients (n = 70) were treated while euthyroid (EU) on thyroid hormone therapy and stimulated with rhTSH (EU + rhTSH). The outcome of thyroid ablation was assessed by conventional HYPO (131)I scan performed in HYPO state 6-10 months after ablation. Basal serum TSH was elevated in the HYPO and HYPO + rhTSH groups. In the EU + rhTSH group, basal serum TSH was 1.3 +/- 2.5 micro U/ml (range, <0.005-11.9 micro U/ml). After rhTSH, serum TSH significantly increased in the HYPO + rhTSH group and the EU + rhTSH group. Basal 24-h radioiodine thyroid bed uptake was 5.8 +/- 5.7% (range, 0.2-21%) and 5.4 +/- 5.7% (range, 0.2-26%) in the HYPO and HYPO + rhTSH groups, respectively. In the HYPO + rhTSH group, mean 24-h thyroid bed uptake rose to 9.4 +/- 9.5% (range, 0.2-46%) after rhTSH (P < 0.0001). The 24-h uptake after rhTSH in the EU + rhTSH group was 2.5 +/- 4.3% (range, 0.1-32%), significantly lower (P < 0.0001) than that found in the HYPO and HYPO + rhTSH groups. The rate of successful ablation was similar in the HYPO and HYPO + rhTSH groups (84% and 78.5%, respectively). A significantly lower rate of ablation (54%) was achieved in the EU + rhTSH group. Mean initial dose rate (the radiation dose delivered during the first hour after treatment) was significantly lower in the EU + rhTSH group (10.7 +/- 12.6 Gy/h) compared with the HYPO + rhTSH group (48.5 +/- 43 Gy/h) and the HYPO group (27.1 +/- 42.5 Gy/h). In conclusion, our study indicates that by using stimulation with rhTSH, a 30-mCi standard dose of radioiodine is not sufficient for a satisfactory thyroid ablation rate. Possible reasons for this failure may be the low 24-h radioiodine uptake, the low initial dose rate delivered to the residues, and the accelerated iodine clearance observed in EU patients. Possible alternatives for obtaining a satisfactory rate of thyroid ablation with rhTSH may consist of increasing the dose of radioiodine or using different protocols of rhTSH administration producing more prolonged thyroid cells stimulation.     

Radioiodine ablation of thyroid remnants after preparation with recombinant human thyrotropin in differentiated thyroid carcinoma: results of an international, randomized, controlled study

CONTEXT: After surgery for differentiated thyroid carcinoma, many patients are treated with radioiodine to ablate remnant thyroid tissue. This procedure has been performed with the patient in the hypothyroid state to promote endogenous TSH stimulation and is often associated with hypothyroid symptoms and impaired quality of life. OBJECTIVE AND INTERVENTION: This international, randomized, controlled, multicenter trial aimed to compare the efficacy and safety of recombinant human TSH (rhTSH) to prepare euthyroid patients on L-thyroxine therapy (euthyroid group) to ablate remnant thyroid tissue with 3.7 GBq (100 mCi) 131I, compared with that with conventional remnant ablation performed in the hypothyroid state (hypothyroid group). Quality of life was determined at the time of randomization and ablation. After the administration of the 131-I dose, the rate of radiation clearance from blood, thyroid remnant, and whole body was measured. RESULTS: The predefined primary criterion for successful ablation was "no visible uptake in the thyroid bed, or if visible, fractional uptake less than 0.1%" on neck scans performed 8 months after therapy and was satisfied in 100% of patients in both groups. A secondary criterion for ablation, an rhTSH-stimulated serum thyroglobulin concentration less than 2 ng/ml, was fulfilled by 23 of 24 (96%) euthyroid patients and 18 of 21 (86%) hypothyroid patients (P = 0.2341). Quality of life was well preserved in the euthyroid group, compared with the hypothyroid group, as demonstrated by their lower pretreatment scores on the Billewicz scale for hypothyroid signs and symptoms, 27 +/- 7 vs. 18 +/- 4 (P < 0.0001) and their significantly higher Short Form-36 Health Assessment Scale scores in five of eight categories. Euthyroid patients had a statistically significant one third lower radiation dose to the blood, compared with patients in the hypothyroid group. CONCLUSIONS: This study demonstrates comparable remnant ablation rates in patients prepared for 131I remnant ablation with 3.7 GBq by either administering rhTSH or withholding thyroid hormone. rhTSH-prepared patients maintained a higher quality of life and received less radiation exposure to the blood.     

Recombinant human TSH use in differentiated thyroid cancer

Traditionally, the immediate treatment of patients with differentiated thyroid carcinoma (DTC) after total thyroidectomy (TT) is thyroid remnant ablation (TRA) with 131I, during hypothyroidism. Late follow-up of DCT includes suppressive doses of T4, serial measurements of thyroglobulin (Tg), whole body scan (WBS) with 131I and cervical ultrasound (US). In the last years, TRA with the aid of recombinant human TSH (rhTSH) has shown not only to avoid symptoms of hypothyroidism and a lower quality of life, but also to have the same efficacy as TRA during endogenous TSH elevation. Stimulated Tg with endogenous or exogenous TSH, 9 to 12 months after the initial treatment of DTC, associated with cervical US, is able to identify low-risk patients virtually cured of their disease, in whom TSH suppression does not need to be so strict, avoiding the heart and bone complications of prolonged exogenous thyrotoxicosis. Finally, in spite of the absence of randomized studies designed to evaluate the role of rhTSH in metastatic DTC disease, results of the combined treatment of rhTSH and 131I show a clinical benefit in the majority of treated patients.     

The use of recombinant human TSH in the follow-up of differentiated thyroid cancer: experience from a large patient cohort in a single centre

BACKGROUND: Periodic evaluation of serum thyroglobulin (Tg) and whole body 131I imaging (131I-WBS) are essential in the follow-up of differentiated thyroid carcinoma (DTC); both diagnostic modalities require stimulation by high levels of TSH. Administration of recombinant human TSH (rhTSH) is an alternative to the withdrawal of thyroid hormone therapy. OBJECTIVE: The aim of this study was to report our experience in the use of rhTSH for the management of patients with DTC. PATIENTS: One hundred and four patients were enrolled in the study. A dose of 10 U of rhTSH therapy was injected intramuscularly for 2 consecutive days; 24 h after the second dose of rhTSH the patients were administered 4--5 mCi of 131I and, 48 h later, WBS was performed. RESULTS: In all patients, baseline mean serum Tg and TSH levels were 2.4 +/- 1.9 ng/ml and 0.0153 +/- 0.0232 mIU/l, respectively. Basal Tg levels were detectable in 58 out of 104 patients. After rhTSH injection, mean serum TSH levels rose to 122.67 +/- 47.36 mIU/l. Stimulated serum Tg levels increased to greater-than-or-equal 5 ng/ml and the 131I-WBS showed an uptake in 18 patients (17.4%). Among them there were three with bone metastases and one with brain metastases, who reported violent skeletal pain and a severe headache, respectively. These were caused by the growth of tumour mass of metastases induced by rhTSH administration. CONCLUSIONS: The use of rhTSH avoids the debilitating effects of hypothyroidism and its use successfully promotes iodine uptake and increases the sensitivity of serum Tg testing. The risk of causing serious side-effects recommends performing skull magnetic resonance and radionuclide bone scan in cases of suspected brain or skeletal metastases.     

Successful use of recombinant human thyrotropin in the therapy of pediatric well-differentiated thyroid cancer

Recombinant human TSH (rhTSH) is increasingly employed in stimulating radioiodine (131I) uptake in adults with well-differentiated thyroid cancer (WDTC) for diagnostic scanning, and preliminary evidence suggests that it may have a role in radioactive iodine therapy as well. However, the safety and efficacy of rhTSH in children have not been determined. We report a case of a 13-yr-old boy presenting with metastatic papillary thyroid cancer. After total thyroidectomy, his serum thyroglobulin (Tg) was 302 ng/ml (3.7-49.3) with negative antibodies. A diagnostic whole body scan (WBS) demonstrated multiple foci of uptake in the neck, thyroid bed and chest. His serum TSH only increased to 14.2 microU/ml (0.3-4.7) upon thyroid hormone withdrawal. Therefore, the patient was given 0.9 mg rhTSH every 24 h for two consecutive days and treated with 102 mCi 131I 24 h after the last rhTSH injection. Six months later, the patient was again conditioned with rhTSH and treated with an additional 150 mCi 131I. This treatment effectively reduced his tumor load with his most recent (10 months after the second ablation) serum Tg measuring 19.3 ng/ml. This case highlights the safety and effectiveness of rhTSH stimulated radioablation in pediatric WDTC, and proposes to invite controlled studies to further investigate pediatric rhTSH use, particularly in patients in whom thyroid hormone withdrawal is not a viable option.     

Serum thyrotropin (TSH) levels after recombinant human TSH injections in children and teenagers with papillary thyroid cancer

CONTEXT: In preparation for whole body radioactive iodine scanning, recombinant human TSH (rhTSH) is usually administered as 0.9-mg i.m. injections on 2 consecutive days without regard to age, body size, or other comorbid conditions. OBJECTIVE: Our objective was to determine whether the usual adult rhTSH dosing regimen would result in excessive elevations of serum TSH in children and teenagers with thyroid cancer. DESIGN/SETTING/PATIENTS/INTERVENTIONS: A retrospective review identified 53 children and teenagers with thyroid cancer who underwent whole body radioactive iodine (RAI) scanning over a 12-yr period at two major medical centers (34 after thyroid hormone withdrawal and 19 after rhTSH treatment). MAIN OUTCOME MEASURES: The dynamic time course of changes in serum TSH after rhTSH administration and/or hypothyroid withdrawal was examined. Peak TSH levels were correlated with age, weight, and body surface area. RESULTS: The mean serum TSH at the time of RAI administration was similar in patients undergoing hypothyroid preparation (188 +/- 118 mIU/liter; range, 110-452 mIU/liter) and those treated with rhTSH (134 +/- 75 mIU/liter; range, 32-290 mIU/liter; P = 0.07). Serial determinations after rhTSH injections revealed a mean serum TSH of 268 +/- 76 mU/liter (range, 87-628) at 6 h and 130 +/- 58 mU/liter (range, 67-250) at 24 h after the initial injection, and 361 +/- 78 mU/liter (range 161-524) at 6 h and 134 +/- 44 mU/liter (range, 32-290) at 24 h after the second injection. CONCLUSIONS: The mean TSH levels achieved in children after rhTSH injections are remarkably similar to values previously reported in adults despite marked differences in clinical characteristics between children and adults. These data suggest that dose adjustments are not generally required in children and teenagers undergoing rhTSH stimulation for RAI scanning or serum-stimulated thyroglobulin determinations.     

Radioiodine treatment with 30 mCi after recombinant human thyrotropin stimulation in thyroid cancer: effectiveness for postsurgical remnants ablation and possible role of iodine content in L-thyroxine in the outcome of ablation

The main steps in the management of differentiated thyroid cancer are thyroidectomy, treatment with iodine-131 ((131)I), and follow-up with whole-body scanning (WBS) and serum thyroglobulin (Tg) determination. Both (131)I treatment and follow-up require maximum stimulation of normal or pathological thyroid remnants by TSH. The use of recombinant human TSH (rhTSH) has been shown to be useful for follow-up, whereas previous reports are not univocal regarding the use of (131)I postsurgical ablation of thyroid remnants, at least when low doses (30 mCi) of (131)I are administered. A possible explanation for the diminished effectiveness of (131)I treatment after rhTSH may be the interference of iodine content of L-thyroxine (L-T4) therapy during the protocol of administration of rhTSH. We have evaluated the effectiveness of stimulation by rhTSH for radioiodine ablation of postsurgical remnants, stopping L-T4 the day before the first injection of rhTSH and restarting L-T4 the day after (131)I. The study included two groups of patients: group 1 included 16 patients with differentiated thyroid cancer (15 papillary cancers and 1 follicular cancer, stages I and II), who were treated with 30 mCi (131)I with the aid of rhTSH, using the standard protocol but stopping L-T4 as stated previously; and group 2 included 24 patients with the same features (histology and stage) of disease treated with 30 mCi in the hypothyroid state after L-T4 withdrawal. In both groups, serum TSH reached a very good stimulation level [76-210 U/liter (mean, 112 +/- 11 SE) and 38-82 U/liter (mean, 51 +/- 3 SE), respectively]. At the first WBS (after (131)I treatment), all patients showed thyroid remnants. Furthermore, two patients of the first group and three patients of the second group showed lymph node metastases. After 1 yr, all patients were studied again and underwent WBS with a tracer dose of (131)I and serum Tg measurement using rhTSH with the same protocol in both groups. The percentage of ablation (undetectable Tg and a negative WBS) was higher, although not reaching statistical significance, in patients treated with rhTSH: 81.2% in patients treated by rhTSH withdrawal and 75.0% in patients treated by L-T4 withdrawal, respectively. No patient experienced symptoms of hypothyroidism during the 4 d of L-T4 interruption, and serum T4 remained in the normal range. Urinary iodine was analyzed in both groups and compared with a control group of patients who received, for diagnostic purposes, rhTSH without stopping L-T4. In the first group, urinary iodine was 47.2 +/- 4.0 microg/liter (mean +/- SE; P = 0.21 vs. the second group, P = 0.019 vs. control group). In the second group, urinary iodine was 38.6 +/- 4.0 microg/liter (mean +/- SE; P < 0.001 vs. control group); urinary iodine in the control group was 76.4 +/- 9.3 microg/liter (mean +/- SE). Our data show that rhTSH, as administered in the protocol stated previously, allows at least the same rate of ablation of thyroid remnants when low doses (30 mCi) of (131)I are used. The possible role of interference of iodine content in L-T4 is not surprising if we consider that the amount of iodine in 30 mCi is negligible (5 microg) compared with the amount of iodine content in a daily dose of T(4) ( approximately 50 microg). The cost of rhTSH seems modest compared with the high cost of complex therapeutic regimens in other areas of oncology and in consideration of the well-being of patients and of the high level of effectiveness of the treatment.     

Thyrotropin releasing hormone (TRH) immunoreactivity and thyroid function in obesity

Circulating TRH-immunoreactive levels, the thyrotropin response to a TRH intravenous stimulation (200 micrograms) and thyroid hormone concentrations have been determined in 43 overweight subjects (body mass index 45 +/- 12 kg/m2, mean +/- s.d.) and 46 (body mass index 22 +/- 2 kg/m2) normal weight controls. The TRH levels measured by a recently developed, highly specific radioimmunoassay were similar among both groups (44 +/- 16 vs 40 +/- 12 fmol/ml, n.s.). The pattern of response of TSH to TRH was normal in the obese and no significant difference was observed between the peak TSH values of the obese and the normal group (8.3 +/- 2.8 vs 8.7 +/- 2.2 microU/ml, n.s.). No correlations were found between the degree of obesity and the concentrations of TRH, TSH and peripheral thyroid hormone levels. Three obese patients showed a delta-TSH of 18, 19 and 21 microU/ml at normal thyroid hormone concentrations as sign of latent hypothyroidism. These data indicate that in obesity: (a) the TSH response to i.v. TRH is not impaired, (b) circulating TRH-IR levels are not significantly changed and (c) the incidence of overt hypothyroidism is not increased.     

Management of differentiated thyroid carcinoma with radioiodine and recombinant human TSH

Recombinant human TSH (rhTSH) brought revolutionary change in the management of patients with differentiated thyroid cancer since it was first approved for clinical use in the United States and Europe. Follow-up management of differentiated thyroid cancer is based on the detection of recurrent or residual cancer, traditionally achieved by measurement of serum thyroglobulin level and various imaging techniques including 131I whole body scan. Previously, TSH stimulation was achieved only by induction of hypothyroidism following withdrawal of thyroid hormone. However, hypothyroidism is uncomfortable and is association with a reduction in quality of life. RhTSH can provide elevated TSH without making patients hypothyroid. In the United States and Europe, rhTSH is approved for use only in monitoring of differentiated thyroid cancer. In this article, we reviewed the role of rhTSH in the diagnosis and management of differentiated thyroid cancer.     

Pretreatment with a single,low dose of recombinant human thyrotropin allows dose reduction of radioiodine therapy in patients with nodular goiter

In patients with nodular goiter, radioiodine ((131)I) therapy results in a mean reduction in thyroid volume (TV) of approximately 40% after 1 yr. We have demonstrated that pretreatment with a single, low dose of recombinant human TSH (rhTSH) doubles 24-h radioactive iodine uptake (RAIU) in these patients. We have now studied the safety and efficacy of therapy with a reduced dose of (131)I after pretreatment with rhTSH. Twenty-two patients with nodular goiter received (131)I therapy, 24 h after im administration of 0.01 (n = 12) or 0.03 (n = 10) mg rhTSH. In preceding diagnostic studies using tracer doses of (131)I, 24-h RAIU without and with rhTSH pretreatment (either 0.01 or 0.03 mg) were compared. Therapeutic doses of (131)I were adjusted to the rhTSH-induced increases in 24-h RAIU and were aimed at 100 micro Ci/g thyroid tissue retained at 24 h. Pretreatment with rhTSH allowed dose reduction of (131)I therapy by a factor of 1.9 +/- 0.5 in the 0.01-mg and by a factor of 2.4 +/- 0.4 in the 0.03-mg rhTSH group (P < 0.05, 0.01 vs. 0.03 mg rhTSH). Before and 1 yr after therapy, TV and the smallest cross-sectional area of the tracheal lumen were measured with magnetic resonance imaging. During the year of follow-up, serum TSH, free T(4) (FT(4)), T(3), and TSH receptor antibodies were measured at regular intervals. TV before therapy was 143 +/- 54 ml in the 0.01-mg group and 103 +/- 44 ml in the 0.03-mg rhTSH group. One year after treatment, TV reduction was 35 +/- 14% (0.01 mg rhTSH) and 41 +/- 12% (0.03 mg rhTSH). In both groups, smallest cross-sectional area of the tracheal lumen increased significantly. In the 0.01-mg rhTSH group, serum FT(4) rose, after (131)I treatment, from 15.8 +/- 2.8 to 23.2 +/- 4.4 pM. In the 0.03-mg rhTSH group, serum FT(4) rose from 15.5 +/- 2.5 to 23.5 +/- 5.1 pM. Individual peak FT(4) levels, reached between 1 and 28 d after (131)I treatment, were above the normal range in 12 patients. TSH receptor antibodies were negative in all patients before therapy and became positive in 4 patients. Hyperthyroidism developed in 3 of these 4 patients between 23 and 25 wk after therapy. In conclusion, in patients with nodular goiter pretreatment with a single, low dose of rhTSH allowed approximately 50-60% reduction of the therapeutic dose of radioiodine without compromising the efficacy of TV reduction.     

Radioactive iodine lobe ablation as an alternative to completion thyroidectomy for follicular carcinoma of the thyroid.

We performed a retrospective record review of patients who received large lobar remnant ablation after surgery for well-differentiated thyroid carcinoma including 30 with papillary carcinoma, 14 with follicular carcinoma, and 6 with Hürthle cell carcinoma. We compared these 50 patients to a group of patients who underwent total or near-total thyroidectomy for well-differentiated thyroid carcinoma. The ablation group was treated with single outpatient doses of 29.9 mCi (131)I to prepare for whole-body radioiodine scanning. Subsequent serum thyrotropin (TSH) concentration during thyroid hormone withdrawal was greater than 25 microU/mL in 94% of patients. The mean TSH in this population (76 microU/mL) was not statistically different from a group of 50 patients who underwent total or near-total thyroidectomy (mean, TSH 71 microU/ml p = 0.84). Twenty-four hour radioiodine uptake post-29.9 mCi (131)I ablation was less than 1% in 80% of patients. The mean radioiodine uptake (0.8%) in the lobe ablation population was significantly lower than in patients treated with total thyroidectomy (mean, 2.4%, p < 0.001). There was minimal morbidity after 29.9 mCi (131)I ablation of large lobar remnants. Outpatient 29.9 mCi (131)I ablation is a safe, effective, and less costly alternative to completion thyroidectomy in selected patients. Although we included patients with both papillary and follicular carcinoma in our review, we recommend this method for patients with minimally invasive follicular carcinoma requiring whole body scanning, even with large postsurgical remnants in place.     

Pretreatment with recombinant human TSH changes the regional distribution of radioiodine on thyroid scintigrams of nodular goiters.

In a recent study, we demonstrated that pretreatment with a single, low dose of recombinant human TSH (rhTSH) doubles 24-h thyroid radioactive iodine uptake in patients with nodular goiter. The purpose of the present study was to investigate whether rhTSH pretreatment induces changes in the regional distribution of radioiodine as visualized on thyroid scintigrams in these patients. Anterior planar thyroid 123I scintigrams were obtained in 26 patients with a nodular goiter (23 women and 3 men; age, 62 +/- 9 yr, mean +/- SD; thyroid weight, 165 +/- 72 g) 24 h after administration of a diagnostic dose of radioiodine. All patients were studied twice: first, without rhTSH pretreatment (baseline study), and second, after an im injection of 0.01 mg (n = 10) or 0.03 mg rhTSH (n = 16), given 24 h before radioiodine administration (rhTSH study). For quantification of regional differences in radioiodine uptake, a region of interest method was used. Upon visual inspection, baseline scintigrams showed a heterogeneous uptake of radioiodine. In general, rhTSH scintigrams also showed heterogeneous radioiodine uptake. In some patients, the distribution of radioiodine in the rhTSH scintigram was considerably more homogeneous than in the baseline scintigram. In a few patients, originally "cold" areas had changed into "hot" ones, whereas originally hot areas had changed into cold ones. Quantification of regional radioiodine uptake showed that pretreatment with rhTSH caused a larger increase in radioiodine uptake in relatively cold areas and a smaller increase in radioiodine uptake in relatively hot areas, compared with the increase in radioiodine uptake in the entire thyroid. In patients with a baseline serum TSH level of 0.5 mU/liter or lower, the increase in radioiodine uptake in relatively cold areas was significantly larger than in patients with a baseline serum TSH level higher than 0.5 mU/liter. In conclusion, a single, low dose of rhTSH not only doubled 24-h radioactive iodine uptake but also caused a more homogeneous distribution of radioiodine within the thyroid gland in patients with a nodular goiter by stimulating radioiodine uptake in relatively cold areas more than in relatively hot areas. This was most marked in patients with a low baseline serum TSH level. Our data suggest that pretreatment with rhTSH may improve the efficacy of radioiodine treatment for volume reduction of nodular goiters, especially in patients with a low baseline serum TSH level.     

How the availability of recombinant human TSH has changed the management of patients who have thyroid cancer

Recombinant human TSH (rhTSH) is used in patients who have had surgery for thyroid cancer but are at low risk of recurrence. The rhTSH is used for the preparation of postoperative administration of 3.7 GBq (100 mCi) of radioiodine for thyroid-remnant ablation and for the determination of serum thyroglobulin levels during follow-up. In these two conditions, the efficiencies of levothyroxine withdrawal and rhTSH administration are similar; however, rhTSH can be administered during levothyroxine treatment, and its use avoids the hypothyroid period induced by levothyroxine withdrawal, reduces whole body exposure after radioiodine administration, avoids potential morbidity and maintains a better quality of life compared with hormone withdrawal.     

Two cases of thyroid carcinoma that were not stimulated by recombinant human thyrotropin

Recombinant human TSH (rhTSH) is being widely used to monitor patients who were previously treated for differentiated thyroid cancers for evidence of recurrence. Its value lies in the avoidance of recurrent episodes of hypothyroidism in the follow-up protocols. rhTSH is also being evaluated as a potential therapeutic adjunct that would spare patients the experience of becoming hypothyroid when undergoing thyroid remnant ablation or treatment for metastases. In some centers, rhTSH is also used to support compassionate care of patients with advanced disease who cannot safely become hypothyroid. The (131)I uptake response to rhTSH, presently an off-label application, is expected to be similar to that of endogenously raised TSH levels. The two cases presented here are cautionary tales in which (131)I uptake by metastases was present under hypothyroid conditions, but absent in one patient and present in only a portion of the lesions in the other, with rhTSH stimulation.     

Radioiodine for remnant ablation and therapy of metastatic disease

Radioiodine is considered an effective and low-risk therapy modality of advanced differentiated thyroid cancer. For patients without lymph-node or distant metastases and low stages of the primary tumor, debate is ongoing about the necessity of thyroid remnant tissue ablation in an adjuvant setting. On the basis of evidence from retrospective studies, and until results of ongoing controlled prospective randomized trials become available, (131)I ablation of remnant thyroid tissue in patients with primary tumors >1 cm is advisable. For thyroid remnant ablation, individual dosimetry is not obligatory. By contrast, the effectiveness of (131)I therapy of locally advanced and/or metastatic disease can be improved by individual dosimetry. For practical reasons, an approach delivering the maximal possible radiation dose to the tumor without exceeding a critical blood dose of approximately 2 Gy seems advantageous. The availability of recombinant human TSH (rhTSH) has improved the quality of life of patients and reduces the radiation exposure of healthy nonthyroid tissue compared with TSH stimulation through levothyroxine withdrawal. In patients with distant metastases, rhTSH stimulation is possible only in off-label use, from which especially elderly and frail patients may benefit, as they most severely suffer from hypothyroidism caused by thyroid hormone withdrawal.     

Serum vascular endothelial growth factor levels are elevated in metastatic differentiated thyroid cancer but not increased by short-term TSH stimulation

Solid tumor formation requires the development of a blood supply adequate to meet the metabolic demands of the enlarging tumor mass that cannot be sustained by simple diffusion. One principal stimulant to endothelial cell growth and migration, vascular endothelial growth factor (VEGF), is synthesized and secreted by thyroid cancer cells. Furthermore, VEGF overexpression is associated with an aggressive thyroid cancer phenotype in both animal models and clinical-pathological studies. In other malignancies, elevated serum levels of VEGF often correlate with stage of disease and other poor prognostic clinical features. Therefore, we hypothesized that serum VEGF levels would be significantly higher in patients with persistent or recurrent thyroid cancer than in those cured of the disease. Because TSH stimulates both normal and neoplastic thyroid cells, we also proposed that serum VEGF would be further increased by TSH stimulation. Sixty-nine patients with either papillary or follicular thyroid cancer, status post total thyroidectomy, and prior radioactive iodine ablation, who had undergone routine recombinant human TSH (rhTSH, Thyrogen, Genzyme Transgenics Corp., Cambridge, MA) assisted whole-body radioactive iodine scanning, were included in this study. This cohort (mean age 53 +/- 16 yr, 51% female) included 21 patients with no evidence of disease and 48 patients with local or distant metastases. Stored serum samples obtained for standard Tg determinations before and 72 h following standard rhTSH stimulation were identified and assayed for VEGF 165 (R \[amp ]\ D Systems, Minneapolis, MN). Baseline serum VEGF levels obtained at a time of TSH suppression were significantly higher in patients with known metastatic disease than in those with no evidence of disease (416 +/- 62 pg/ml vs. 185 +/- 25 pg/ml, P = 0.001). Patients with distant metastases had baseline serum VEGF levels that did not differ significantly from patients with only cervical recurrences (455 +/- 90 pg/ml in distant metastases vs. 330 +/- 44 pg/ml for local cervical recurrences). Short-term TSH stimulation, although causing a significant rise in serum Tg, resulted in no significant increase in serum VEGF measured 72 h after rhTSH injection in either the patients with known metastatic disease (416 +/- 62 pg/ml baseline vs. 419 +/- 71 pg/ml after TSH stimulation) or in cured patients (185 +/- 25 pg/ml baseline vs. 191 +/- 33 pg/ml after TSH stimulation). Subgroup analysis revealed that patients with metastatic disease arising from well differentiated primary thyroid cancers had significantly higher serum VEGF levels than patients with metastatic disease arising from poorly differentiated thyroid cancer primaries (485 +/- 74 pg/ml vs. 167 +/- 32 pg/ml, P = 0.003 by ANOVA). Poorly differentiated metastatic thyroid cancers had serum VEGF levels indistinguishable from patients cured of disease (167 +/- 32 pg/ml vs. 186 +/- 25 pg/ml). In summary, serum VEGF is significantly elevated in patients with metastatic differentiated thyroid cancer but not in those with poorly differentiated thyroid cancer metastases. No measurable increase in serum VEGF levels can be detected 72 h after short-term TSH stimulation with rhTSH. We conclude that serum VEGF may serve as a clinical useful marker of residual differentiated thyroid cancer.     

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.     

Quality of life changes and clinical outcomes in thyroid cancer patients undergoing radioiodine remnant ablation (RRA) with recombinant human TSH (rhTSH): a randomized controlled study

Background Recombinant human TSH (rhTSH) has become the modality of choice for radioiodine remnant ablation (RRA) in low‐risk thyroid cancer patients. Aims and methods The aims of the present prospective randomized study were to evaluate the impact of TSH stimulation procedure (hypothyroidism vs. rhTSH) on quality of life (QoL) of thyroid cancer patients undergoing RRA and to evaluate efficacy of both procedures. L‐T4 was initiated in both groups after thyroidectomy. After randomization, L‐T4 was discontinued in hypothyroid (hypo) group and continued in rhTSH group. A measure of 3·7 GBq of radioiodine was given to both groups. The functional assessment of chronic illness therapy‐fatigue (FACIT‐F) was administered from the early postoperative period to 9 months. Socio‐demographic parameters, anxiety and depression scales were also evaluated (CES‐D, BDI and Spielberger state‐trait questionnaires). At 9 months, patients underwent an rhTSH stimulation test, diagnostic ¹³¹I whole body scan (dxWBS) and neck ultrasonography. Results A total of 74 patients were enrolled for the study. There was a significant decrease in QoL from baseline (t0) to t1 (RRA period) in the hypothyroid group with significant differences in FACIT‐F TOI (P < 10^?3), FACT‐G total score (P = 0·005) and FACIT‐F total score (P = 0·003). By contrast, QoL was preserved in the rhTSH group. In the multivariate analysis, FACIT‐TOI changes were only affected by the modality of TSH stimulation performed for RRA. From 3 to 9 months, changes of QoL scales and subscales were no longer statistically different in both groups of patients. Based on serum rhTSH‐stimulated Tg alone (Tg < 0·8 µg/l, BRAHMS Tg Kryptor), no difference in ablation success was observed between rhTSH and hypothyroidism groups, 91·7% and 97·1%, respectively. A higher rate of persistent thyroid remnants was observed in the rhTSH arm, although in most cases uptake was < 0·1% and of no clinical significance. Conclusions rhTSH preserves QoL of patients undergoing RRA with similar rates of ablation success compared to hypothyrodism. However, there is a wide heterogeneity in the clinical impact of hypothyroidism.     

A comparison of 1850 (50 mCi) and 3700 MBq (100 mCi) 131-iodine administered doses for recombinant thyrotropin-stimulated postoperative thyroid remnant ablation in differentiated thyroid cancer

OBJECTIVE: Recently, a multicenter study in differentiated thyroid cancer (DTC) patients showed that 3700 MBq 131-iodine ((131)I) after recombinant human TSH (rhTSH) had a successful thyroid ablation rate similar to that obtained after thyroid hormone withdrawal. We investigated whether 1850 MBq (131)I had a similar successful rate to 3700 MBq in patients prepared with rhTSH. DESIGN: A total of 72 patients with DTC were randomly assigned to receive 1850 (group A, n = 36) or 3700 MBq (group B, n = 36) (131)I after rhTSH. One injection of 0.9 mg rhTSH was administered for 2 consecutive days; (131)I therapy was delivered 24 h after the last injection, followed by a posttherapy whole-body scan. Successful ablation was assessed 6-8 months later. RESULTS: Successful ablation (no visible uptake in the diagnostic whole-body scan after rhTSH stimulation) was achieved in 88.9% of group A and B patients. Basal and rhTSH-stimulated serum thyroglobulin was undetectable (<1 ng/ml) in 78.9% of group A and 66.6% of group B patients (P = 0.46). Similar rates of ablation were obtained in both groups also in patients with node metastases. CONCLUSION: Therapeutic (131)I activities of 1850 MBq are equally effective as 3700 MBq for thyroid ablation in DTC patients prepared with rhTSH, even in the presence of node metastases.