Recombinant human thyrotropin is helpful in the follow-up and 131I therapy of patients with thyroid cancer: a report of the results and benefits using recombinant human thyrotropin in clinical routine.

There is no doubt that the availability of recombinant human thyrotropin (rhTSH) is one of the milestones in the management of patients with differentiated thyroid cancer (DTC). It offers the opportunity to obtain representative serum thyroglobulin (Tg) levels and diagnostic whole-body scanning (Dx WBS) with 131I under adequate TSH elevation, while the patient continues to receive thyroid hormone. But rhTSH is also used with success in the treatment of local recurrences and distant metastases. In this retrospective analysis we were able to show that our excellent clinical experiences with the use of rhTSH (rare side effects and high compliance) could also be demonstrated by sufficiently elevated TSH levels and representative stimulated Tg measurements. Since April 2001 most of the patients with thyroid cancer in our hospital have undergone diagnostic examination (205 patients underwent 319 examinations) and 131I therapy (a total of 68 treatments) with rhTSH stimulation excluding the first radioiodine ablation of remnants after initial thyroidectomy. Our results show that under rhTSH stimulation 83.5% (diagnostic group) and 88% (therapy group) of our patients with DTC obtained a TSH level of greater than 80 mU/L after two injections of rhTSH (Thyrogen, Genzyme Corp., Cambridge, MA) 0.9 mg intramuscularly 24 hours and 48 hours before the administration of 131I. Only 2.3% (diagnostic group) and 0% (therapy group) demonstrated TSH levels less than 50 mU/L. Serum Tg levels under rhTSH-stimulated conditions showed that in 81.2% the serum Tg maximum was obtained on day 5. Because of the costs associated with periodically rhTSH-assisted Tg testing and based on the data of other studies we are now testing mainly on day 5 to identify residual tumor mass and to compare these Tg levels in the follow-up. Our experience demonstrates that the administration of rhTSH is a safe, effective, and-from an economic point of view- valuable tool in the management of patients with DTC.     

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.     

Recombinant human thyrotropin-stimulated serum thyroglobulin combined with neck ultrasonography has the highest sensitivity in monitoring differentiated thyroid carcinoma

Recombinant human TSH (rhTSH)-stimulated thyroglobulin (Tg) measurement and (131)I whole body scan (WBS) have been validated as informative tests in the postsurgical follow-up of differentiated thyroid carcinoma. We report the diagnostic accuracy of Tg measurement and diagnostic WBS, alone or in combination, after rhTSH stimulation in a retrospective, consecutive series of patients undergoing follow-up for differentiated thyroid cancer. Routine procedures also include neck ultrasound in every patient and post-therapy WBS when indicated. We studied 340 consecutive patients with differentiated thyroid carcinoma, previously treated with near-total thyroidectomy and (131)I thyroid ablation, scheduled for routine diagnostic tests. At baseline on L-T(4)-suppressive therapy, 294 patients had undetectable (<1 ng/ml) serum Tg and negative anti-Tg autoantibodies (TgAb), 25 patients had undetectable serum Tg and positive TgAb, and 21 patients had detectable serum Tg and negative TgAb. These patients were tested for the presence of active disease by rhTSH stimulation. The results of our study showed that rhTSH-stimulated Tg alone had a diagnostic sensitivity of 85% for detecting active disease and a negative predictive value (NPV) of 98.2%. After adding the results of neck ultrasound, sensitivity increased to 96.3%, and the NPV to 99.5%. rhTSH-stimulated WBS had a sensitivity of only 21% and a NPV of 89%. The combination of rhTSH-stimulated Tg and WBS had a sensitivity of 92.7% and a NPV of 99%. We conclude that the rhTSH-stimulated Tg test combined with neck ultrasonography has the highest diagnostic accuracy in detecting persistent disease in the follow-up of differentiated thyroid carcinoma. A detectable level of serum Tg on L-T(4), its conversion from undetectable to detectable after rhTSH, and/or a suspicious finding at ultrasound will allow the identification of patients requiring therapeutic procedures without the need for diagnostic WBS.     

Follow-up of differentiated thyroid carcinoma

Thyroid cancer is the most common endocrine malignancy. More than 90% of primary thyroid cancers are differentiated papillary or follicular types. The treatment of differentiated thyroid carcinoma (DTC) consists of total thyroidectomy and radioactive iodine ablation therapy, followed by L-thyroxine therapy. The extent of initial surgery, the indication for radioiodine ablation therapy and the degree of TSH-suppression are all issues that are still being debated cancers are in relation to the risk of recurrence. Total thyroidectomy reduces the risk of recurrence and facilitates (131)I ablation of thyroid remnants. The aim of radioiodine ablation is to destroy any normal or neoplastic residuals of thyroid tissue. These procedures also improve the sensitivity of thyroglobulin (Tg) as a marker of disease, and increase the sensitivity of (131)I total body scan (TBS) for the detection of persistent or recurrent disease. The aim of TSH-suppressive therapy is to restore euthyroidism and to decrease serum TSH levels, in order to reduce the growth and progression of thyroid cancer. After initial treatment, the objectives of the follow-up of DTC is to maintain adequate thyroxine therapy and to detect persistent or recurrent disease through the combined use of neck ultrasound (US) and serum Tg and (131)I TBS after TSH stimulation. The follow-up protocol should be adapted to the risk of recurrence. Recent advances in the follow-up of DTC are related to the use of recombinant human TSH (rhTSH) in order to stimulate Tg production and the ultrasensitive methods for Tg measurement. Undetectable serum Tg during TSH suppressive therapy with L-T4 does not exclude persistent disease, therefore serum Tg should be measured after TSH stimulation. The results of rhTSH administration and L-thyroxine therapy withdrawal are equivalent in detecting recurrent thyroid cancer, but the use of rhTSH helps to avoid the onset of hypothyroid symptoms and the negative effects of acute hypothyroidism on cardiovascular, hepatic, renal and neurological function. In low-risk DTC patients serum Tg after TSH stimulation, together with ultrasound of the neck, should be used to monitor persistent disease, avoiding diagnostic TBS which has a poor sensitivity. These recommendations do not apply when Tg antibodies are present in the serum, in patients with persistent or recurrent disease or limited thyroid surgery. Low-risk patients may be considered to be in remission when undetectable Tg after TSH stimulation and negative US evaluation of the neck are present. On the contrary, detectable Tg after TSH stimulation is an indicator in selecting patients who are candidates for further diagnostic procedures.     

Compliance with follow-up and the informative value of diagnostic whole-body scan in patients with differentiated thyroid carcinoma given recombinant human TSH

OBJECTIVE: Protocols for monitoring patients with differentiated thyroid cancer (DTC) include measurement of serum Tg and, for most patients, whole-body scan (WBS) with low radioiodine activities ('diagnostic' WBS). Recently, recombinant human thyroid-stimulating hormone (rhTSH) has become available to provide the TSH stimulation necessary for these procedures, whilst avoiding thyroid hormone withdrawal and hypothyroid complications. In addition, the inclusion of diagnostic WBS in DTC follow-up has recently become controversial. We have assessed the compliance with withdrawal-aided monitoring and the informative value of diagnostic WBS in consecutive tertiary referral center patients. DESIGN: Forty-eight patients received rhTSH (0.9 mg) in two consecutive daily injections, with radioiodine administration 24 h, diagnostic WBS 48 h, and serum Tg testing prior to and 72 h later. METHODS: Compliance with withdrawal-aided monitoring was assessed with a questionnaire provided by the referring physician, patient record analysis, and patient interview. The informative value of diagnostic WBS was assessed by comparing findings against serum Tg measurements in light of physical and other radiological examinations. RESULTS: Forty of the forty-eight patients were female, the mean age was 43.9 years and the median follow-up from diagnosis was 4.5 years (range 1-19 years). Twenty-seven (56%) patients were compliant and 12 (25%) were non-compliant; compliance was not known in nine. Of 17 patients with clinically suspicious or significant findings on any available modality, four had uptake outside the thyroid bed on WBS but stimulated Tg <2.5 ng/ml on immunometric assay, while five had a negative WBS with serum Tg >2.5 ng/ml. CONCLUSIONS: Thyroid hormone withdrawal substantially impairs, and rhTSH administration substantially promotes, compliance with DTC monitoring. rhTSH-aided WBS is informative and should be included in the follow-up of unselected patients with DTC.     

Incidence and implications of negative serum thyroglobulin but positive I-131 whole-body scans in patients with well-differentiated thyroid cancer prepared with rhTSH or thyroid hormone withdrawal

Aims To evaluate the incidence and clinical implications of a positive whole‐body I‐131 scan but negative stimulated serum Tg/TgAb level following an ablative or diagnostic I‐131 dose in patients with well‐differentiated thyroid cancer and whether there is a difference in incidence if prepared with thyroid hormone withdrawal compared with rhTSH stimulation. Methods I‐131 scan findings, serum Tg/TgAb levels, TNM stage and method of thyroid tissue stimulation in 193 consecutive patients (138F, 55M) with well‐differentiated thyroid cancer undergoing postoperative ablative I‐131 therapy and 121 consecutive (94F, 27M) patients undergoing diagnostic I‐131 surveillance scans were retrospectively reviewed. Comparisons of proportions were performed using Chi‐square tests. Clinical, biochemical and I‐131 scan follow‐up data were obtained for each patient cohort. Results 39/193 (20·2%) postablative I‐131 and 10/121 (8·3%) diagnostic I‐131 patients had negative stimulated serum Tg/TgAb levels but positive I‐131 scans for residual thyroid tissue. Nine (4·7%) of the postablative patients had I‐131 uptake in the lateral neck suspicious for loco‐regional metastatic disease. In the postablative I‐131 group, 38/169 (22·5%) prepared with rhTSH compared to 1/24 (4·2%) prepared with thyroid hormone withdrawal were Tg/TgAb negative but I‐131 scan positive (P = 0·04). Follow‐up of 21/39 postablative I‐131 patients with negative Tg/TgAb but positive I‐131 scans confirmed a significant proportion of patients (4/21) (19·1%), remained Tg/TgAb negative/I‐131 scan positive, some of whom had higher‐risk disease at original diagnosis (2/4) (50%). Conclusions Our study confirms that in the setting of I‐131 ablation therapy or diagnostic I‐131 scanning, a significant proportion of patients (20·2% and 8·3%, respectively) have residual benign or malignant thyroid tissue on whole‐body scanning despite a negative stimulated serum Tg level. Whether such patients who would otherwise be missed as having residual thyroid tissue on serum Tg testing alone have a worse clinical outcome remains uncertain. Our findings do however suggest performing both stimulated serum Tg/TgAb levels and I‐131 scans for the follow‐up of patients with higher‐risk thyroid cancer may be important. There may also be a slightly higher incidence of this phenomenon in patients prepared with rhTSH rather than by thyroxine withdrawal.     

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.     

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.     

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.     

Effect of various doses of recombinant human thyrotropin on the thyroid radioactive iodine uptake and serum levels of thyroid hormones and thyroglobulin in normal subjects

Recombinant human TSH (rhTSH), usually given as 0.9-mg doses im on 2 successive days, increases serum thyroglobulin (Tg) and radioactive iodine uptake (RAIU) in residual thyroid tissue in patients with thyroid cancer. We previously reported that a single, relatively low dose of rhTSH (0.1 mg im) is a potent stimulator of T(4), T(3), and Tg secretion in normal subjects. The present study describes the effects of higher doses of rhTSH on thyroid hormone and Tg secretion. Six normal subjects for each dose group, having no evidence of thyroid disease, received either 0.3 or 0.9 mg rhTSH by im injection. Serum TSH, T(4), T(3), and Tg concentrations were measured at 2, 4, and 8 h and 1, 2, 3, 4, and 7 days after rhTSH administration. The peak serum TSH concentrations were 82 +/- 18 and 277 +/- 89 mU/L, respectively, for the 0.3- and 0.9-mg doses of rhTSH. Serum T(4), T(3), and Tg concentrations increased significantly in subjects receiving 0.3 and 0.9 mg rhTSH, with significant increases in T(4) and T(3) being observed before significant increases in serum TG: Peak concentrations of serum T(4), T(3), and Tg, after 0.3 mg rhTSH administration, were 100 +/- 19, 131 +/- 14, and 1035 +/- 724% above individual baselines, respectively. Similarly, peak concentrations of serum T(4), T(3), and Tg, after 0.9 mg rhTSH administration, were 102 +/- 16, 134 +/- 7, and 1890 +/- 768% above individual baselines, respectively. These data, compared with previously reported data for the responses to 0.1 mg rhTSH, indicated that 0.1, 0.3, and 0.9 mg rhTSH had similar quantitative stimulatory effects on thyroid hormone and Tg secretion, except that the T(4) response was greater in groups receiving 0.3 and 0.9 mg rhTSH than in the group receiving 0.1 mg rhTSH. We also studied the effect of rhTSH on the thyroid RAIU in the group that received 0.9 mg rhTSH. The 6- and 24-h RAIU values were significantly higher after rhTSH (pre-rhTSH, 6-h value = 12.5 +/- 1.8%; 24 h value = 23 +/- 2.7%; post-rhTSH, 6 h value = 27 +/- 4.8%; 24-h value = 41 +/- 4.2%). The stimulating effects of 0.9 mg rhTSH on the 6- and 24-h RAIUs were similar. rhTSH is a potent stimulator of T(4), T(3), and Tg secretion and the RAIU in normal subjects. Single doses greater than 0.1--0.3 mg do not seem to further enhance thyroid hormone or Tg secretion.     

Use of recombinant human thyrotropin before radioiodine therapy in patients with advanced differentiated thyroid carcinoma

The use of 131I for radioablative therapy in patients with differentiated thyroid cancer (DTC) requires a sufficient serum concentration of TSH for efficient thyroid tissue uptake of iodine. We describe the use of recombinant human TSH (rhTSH) in conjunction with ablative radioiodine therapy (RIT) in 11 patients (16 total treatments) with advanced and/or recurrent DTC (5 papillary, 6 follicular) for whom withdrawal of thyroid hormone suppression therapy (THST), the standard method to increase serum TSH, was not an option. Indications for rhTSH use in these patients included inability to tolerate withdrawal of thyroid hormones due to very poor physical condition or inability to achieve sufficient serum TSH levels after THST withdrawal. Ten patients had undergone thyroidectomy, and most (9 of 11) had received prior ablative RIT after THST withdrawal. Baseline thyroglobulin levels ranged from 25 to nearly 30,000 ng/mL, reflecting the heterogeneity of the patient population. In 7 cases (5 patients), posttherapy thyroglobulin levels assessed at a mean of 4.3 months (range, 2-10 months) after 131I therapy were decreased by at least 30% compared to pretherapy levels. In follow-up visits, an additional 3 patients showed marked clinical improvement or decreased or stabilized tumor burden in whole body scans compared to pretherapy scans. Three patients died of progressive disease within 2 months of therapy before follow-up assessments occurred. No adverse events were reported among the 8 surviving patients. The results suggest that rhTSH offers a promising alternative to THST withdrawal to allow ablative RIT after effective TSH stimulation in patients with advanced recurrent DTC who would not otherwise be able to receive this treatment. This therapeutic indication extends the clinical potential of this new agent, already demonstrated to be effective for use with 131I for diagnostic purposes.     

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.     

The effect of recombinant human tsh on the thyroid (123)i uptake in iodide treated normal subjects

Radioactive iodine therapy is often successful in the treatment of toxic or non-toxic multinodular goiter. However, when the patient has been exposed to iodine in the form of medication or radiocontrast agents prior to therapy, the thyroid radioactive iodine is often too low for successful ablation. Recently, administration of 0.9 mg of recombinant human TSH (rhTSH) has been shown to nearly double the 24-hour thyroid radioactive iodine uptake (RAIU) in euthyroid men living in the United States. In addition, 0.01 to 0.03 mg rhTSH administered 24 hours prior to (131)I in patients with a history of non-toxic multinodular goiter residing in an area of modestly low iodine intake, has also been shown to increase the 24-hour thyroid radioactive iodine uptake. We now have determined whether rhTSH administration prior to (123)I would increase the low thyroid RAIU in subjects treated with sodium iodide. Nine euthyroid men were given 15 mg iodide daily for 7 days. There was a marked increase in serum TSH values 8 and 24 hours after rhTSH administration, which induced elevated serum T4 and T3 concentrations. A 16 hour thyroid RAIU was measured at baseline, after 5 days of iodide administration, and either 8 or 32 hours after intramuscular administration of rhTSH. Administration of rhTSH 8 hours before (123)I to 4 subjects increased the 16 hour thyroid RAIU by 62% above the low post iodide thyroid RAIU. Administration of rhTSH 32 hours before (123)I administration to 5 subjects increased the 16 hour thyroid RAIU by 97% above the low iodide induced RAIU. Thus, the overall increase in the thyroid RAIU was 88% in the 9 subjects. Conclusion: Recombinant TSH moderately increased the thyroid RAIU in subjects with depressed thyroid RAIU's during iodide administration and thus may be useful in preparing patients with non-toxic or toxic goiters and low thyroid RAIU's due to excess iodine for radioactive iodine treatment. Further studies to determine the optimal protocol to enhance the effect of rhTSH will be carried out.     

Does an undetectable rhTSH‐stimulated Tg level 12 months after initial treatment of thyroid cancer indicate remission?

Objectives Routine monitoring after the initial treatment of differentiated thyroid cancer (DTC) includes periodic cervical ultrasonography (US) and measurement of serum thyroglobulin (Tg) during thyrotrophin (TSH) suppression and after recombinant human TSH (rhTSH) stimulation. The aim of our study was to evaluate the utility of repeated rhTSH‐stimulated Tg measurements in patients with DTC who have had no evidence of disease at their initial rhTSH stimulation test performed 1 year after the treatment. Material and methods A retrospective chart review of 278 patients with DTC who had repeated rhTSH stimulation testing after an initial undetectable rhTSH‐stimulated serum Tg level. Results The number of rhTSH stimulation tests performed on individual patients during the follow‐up period (3–12 years, mean 6·3) varied from two to seven. Biochemical and/or cytological evidence of potential persistent/recurrent disease based on detectable second or third rhTSH‐stimulated Tg values and US findings was observed in 11 (4%) patients. Subsequent follow‐up data revealed that in five cases, the results of the second stimulation were false positive, in one case – false negative. Combined with the negative neck US, the negative predictive value for disease‐free survival was 98% after the first undetectable rhTSH‐stimulated Tg and 100% after the second one. Conclusions In patients with DTC, the intensity of follow‐up should be adjusted to new risk estimates evolving with time. The first rhTSH‐stimulated Tg is an excellent predictor for remission, independent of clinical stage at presentation. Second negative rhTSH‐Tg stimulation is additionally reassuring and can guide less aggressive follow‐up by the measurement of nonstimulated Tg and neck US every few years.     

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.     

Administration of a single low dose of recombinant human thyrotropin significantly enhances thyroid radioiodide uptake in nontoxic nodular goiter

Radioiodine (131I) is increasingly used as treatment for volume reduction of nontoxic, nodular goiter. A high dose of 131I is often needed because of low thyroid radioiodide uptake (RAIU). We investigated whether pretreatment with a single, low dose of recombinant human TSH (rhTSH; Thyrogen, Genzyme Transgenics Corp.) enhances RAIU in 15 patients with nontoxic, nodular goiter (14 women and 1 man; aged 61+/-11 yr). Four patients were studied twice, and 1 patient was studied 3 times. RAIU was measured both under basal conditions and after pretreatment (im) with rhTSH, given either 2 h (0.01 mg; n = 7) or 24 h [0.01 mg (n = 7) or 0.03 mg (n = 7)] before 131I administration (20-40 microCi). Serum levels of TSH, free T4 (FT4), and total T3 were measured at 2, 5, 8, 24, 48, 72, 96, and 192 h after rhTSH administration. After administration of 0.01 mg rhTSH, serum TSH rose from 0.7+/-0.5 to a peaklevel of 4.4+/-1.1 mU/L (P < 0.0001), FT4 rose from 16.0+/-2.6 to 18.5+/-3.7 pmol/L (P < 0.0001), and T3 rose from 2.10+/-0.41 to 2.63 - 0.66 nmol/L (P < 0.0001). After administration of 0.03 mg rhTSH, TSH rose from 0.6+/-0.4 to 15.8+/-2.3 mU/L (P < 0.0001), FT4 rose from 15.2+/-1.5 to 21.7+/-2.9 pmol/L (P < 0.0001), and T3 rose from 1.90+/-0.43 to 3.19+/-0.61 nmol/L (P < 0.0001). Peak TSH levels were reached at 5-8 h and peak FT4 and T3 levels at 8-96 h after rhTSH administration. Administration of 0.01 mg rhTSH 2 h before 131I increased 24-h RAIU from 30+/-11% to 42+/-10% (P < 0.02), 0.01 mg rhTSH administered 24 h before 131I increased 24-h RAIU from 29+/-10% to 51+/-10% (P < 0.0001), and 0.03 mg rhTSH administered 24 h before 131I increased 24-h RAIU from 33+/-11% to 63+/-9% (P < 0.0001). After administration of 0.01 mg rhTSH 2 h before 131I, 24-h RAIU did not increase in 1 patient, whereas the increase in 24-h RAIU was less than 10% in 2 other patients. In contrast, administration of rhTSH 24 h before 131I increased 24-h RAIU by more than 10% in all 14 patients (by >20% in 10 and by >30% in 6). In conclusion, pretreatment with a single, low dose of rhTSH in patients with nontoxic, nodular goiter increased RAIU considerably. Our observations hold promise that administration of rhTSH before 131I therapy for nontoxic, nodular goiter will allow treatment with lower doses of 131I in these patients.     

Dose‐dependent acute effects of recombinant human TSH (rhTSH) on thyroid size and function: comparison of 0·1, 0·3 and 0·9 mg of rhTSH

Context Recombinant human TSH (rhTSH) is used to augment the effect of radioiodine therapy for nontoxic multinodular goitre. Reports of acute thyroid swelling and hyperthyroidism warrant safety studies evaluating whether these side‐effects are dose dependent. Objective To determine the effects on thyroid size and function of various doses of rhTSH. Design In nine healthy male volunteers, the effect of placebo, 0·1, 0·3 and 0·9 mg of rhTSH was examined in a paired design including four consecutive study rounds. Main outcome measures Main outcome measures were evaluated at baseline, 24 h, 48 h, 96 h, 7 days and 28 days after rhTSH and included: Thyroid volume (TV) estimation by planimetric ultrasound, and thyroid function by serum TSH, free T3, free T4 and Tg levels. Results Following placebo or 0·1 mg rhTSH, the TV did not change significantly from baseline at any time. At 24 and 48 h after administration of 0·3 mg rhTSH, the TV increased by 37·4 ± 12·3% (SEM) (P = 0·03) and 45·3 ± 16·1% (P = 0·05) respectively. After 0·9 mg rhTSH, the TV increased by 23·3 ± 5·8% (P = 0·008) and 35·5 ± 18·4% (P = 0·02) respectively. The increase in serum FT3, FT4 and thyroglobulin (Tg) was greater when administering 0·3 mg compared with 0·1 mg (P = 0·02) and when administering 0·9 mg compared with 0·3 mg (P = 0·02). After 0·1 mg rhTSH, the increase in FT3 and Tg was not significantly different from placebo whereas the FT4 increase was significantly higher (P = 0·02 compared with placebo). Conclusions In healthy individuals, rhTSH‐induced thyroid swelling and hyperthyroidism is rapid and dose dependent. If valid for patients with goitre, our results suggest that these adverse effects are unlikely to be of clinical significance, following doses of rhTSH of 0·1 mg or less.     

Recombinant human thyroid-stimulating hormone (Thyrogen) in thyroid cancer follow up: experience at a single institution

Background: Recombinant human thyroid‐stimulating hormone (Thyrogen^®; Genzyme Corporation, Cambridge, MA, USA) (rhTSH)‐stimulated serum thyroglobulin (Tg) (stim‐Tg) and ¹³¹I whole‐body scanning (WBS) have been reported to allow follow up of patients with thyroid cancer without the symptoms of thyroxine withdrawal and with equivalent diagnostic information to that obtained after thyroxine withdrawal. The aim of the study was to report results of rhTSH use at the Alfred Hospital, Melbourne, from 1999 to 2006 and in particular to examine the significance of detectable serum Tg after rhTSH in relation to thyroid cancer staging and to compare the sensitivity of rhTSH‐stimulated serum Tg to whole‐body ¹³¹I scanning (WBS) in the detection of residual and recurrent thyroid cancer. Methods: The study was a retrospective chart review. Results: In 90 patients, rhTSH was used for 96 diagnostic episodes and 18 doses of rhTSH were used to facilitate treatment with ¹³¹I. In stages I and II cancer (n = 42), of three patients with stim‐Tg 1–2 μg/L, none had identifiable disease, and the three patients who had stim‐Tg >2 μg/L did not experience recurrent disease during follow up. In contrast, in stages III and IV cancer (n = 43) 2 of 5 with stim‐Tg 1?2 μg/L had identifiable disease and 7 of 10 with stim‐Tg >2 μg/L had identifiable disease. In Tg‐positive, WBS‐negative disease, further imaging identified persistent/recurrent disease. Conclusion: rhTSH was effective and safe in the management of thyroid cancer follow up for diagnosis of persistent/recurrent cancer and to enable ¹³¹I treatment. In no case did rhTSH‐stimulated WBS identify the presence of disease not also identified by raised basal Tg or stim‐Tg. Therefore, in low risk cancer WBS may be omitted.     

Prediction of disease status by recombinant human TSH-stimulated serum Tg in the postsurgical follow-up of differentiated thyroid carcinoma.

Stimulation with recombinant human TSH (rhTSH) has been introduced in clinical practice as an effective alternative to thyroid hormone withdrawal for the diagnostic follow-up (Tg measurement and 131-iodine whole-body scan) of patients with differentiated thyroid cancer. The present study was specifically aimed to evaluate the utility of rhTSH-stimulated serum Tg measurements in patients with undetectable serum Tg values, on L-T(4) therapy, as the only test to differentiate patients with persistent disease from patients who are disease-free. We studied 72 consecutive patients with differentiated thyroid cancer, previously treated with near-total thyroidectomy and 131-I thyroid ablation. Admission criteria were: an undetectable (<1 ng/ml) serum Tg, on L-T(4) therapy, and negative anti-Tg antibodies. The study design consisted of a Tg-stimulation test after rhTSH, during L-T(4), followed by diagnostic WBS and serum Tg measurement off L-T(4). After rhTSH, serum Tg remained undetectable in 41 of 72 patients (56.9%). A negative rhTSH Tg test agreed with an undetectable hypo-Tg in 36 of 41 cases (87.8%), all without evidence of metastatic disease at hypo-WBS. In 5 of 41 cases (12.2%), hypo-Tg was detectable (1.1-7.8 ng/ml), in association with negative hypo-WBS or faint uptake in the thyroid bed. Serum Tg converted from undetectable to detectable after rhTSH in 31 of 72 patients (43.1%), with a peak Tg ranging between 1.2 and 23.0 ng/ml. Hypo-Tg was always detectable in these patients (100% concordance), and it was significantly higher than rhTSH-stimulated Tg (P < 0.0002). Hypo-WBS was positive in 23 of 31 patients (74.2%), showing thyroid residues in 12, cervical lymph nodes in 7, and lung metastases in 4 cases. In 8 of 31 cases, hypo-WBS was negative, despite detectable serum Tg. Thus, rhTSH-stimulated Tg was able to detect all cases of documented local or distant metastases. In conclusion, our data indicate that, in patients with undetectable basal levels of serum Tg, rhTSH-stimulated Tg represents an informative test to distinguish disease-free patients (not requiring WBS) from diseased patients (requiring further diagnostic and/or therapeutic procedures).     

The diagnostic use of the rhTSH/thyroglobulin test in differentiated thyroid cancer patients with persistent disease and low thyroglobulin levels

BACKGROUND: Serum thyroglobulin (Tg) measurement after TSH stimulation, by either thyroid hormone withdrawal or recombinant human TSH (rhTSH) administration, is the most sensitive method for early detection of patients with persistent or recurrent differentiated thyroid cancer (DTC) after total thyroidectomy and 131I ablation. The use of rhTSH is now increasing because it avoids thyroid hormone suppressive therapy (THST) withdrawal and the consequent symptoms of severe hypothyroidism. Current guidelines suggest measurement of serum Tg 4 days after starting a 2-day course of rhTSH injections, and assumes that Tg reaches maximum serum levels at that time. OBJECTIVE: The present study was carried out to evaluate the accuracy of rhTSH/thyroglobulin test in DTC patients with persistent disease and low thyroglobulin levels. PATIENTS AND MEASUREMENTS: A series of 13 DTC patients was selected because they had proven persistent disease associated with low Tg levels (< 2.0 micro g/l) under l-thyroxine treatment. In all of them, serum Tg was > 5.0 micro g/l at the last THST withdrawal. We measured serum Tg and TSH levels on days 0.5, 1, 1.5, 2, 4, 7, 10 and 15 after the first of a 2-day course of intramuscular rhTSH injections. RESULTS: Serum Tg values were variable in terms of both peak and time-course. Detectable serum Tg levels were recorded on day 4 in all patients. However, among these 13 patients, the peak Tg value was reached earlier than day 4 in three patients and later in two others. In one patient, Tg level at day 2 was higher (3.0 micro g/l) than at day 4 (1.8 micro g/l). In six of the 13 patients studied we compared Tg values after rhTSH to those subsequently obtained after THST withdrawal: in five of them Tg values were two to three times higher after the latter stimulation. Serum Tg value variability after rhTSH was partially accounted for by variability of serum TSH levels, which were inversely related to patient body surface. CONCLUSIONS: In DTC patients with persistent disease and low Tg levels, optimization of the diagnostic use of Tg measurement after rhTSH may require rhTSH dose adjustment to the patient body surface area and repeated blood sampling, in order to improve diagnostic accuracy. In these patients not even a TSH-stimulated serum Tg cut-off of 2.0 micro g/l on day 4 provides 100% accuracy, whereas a cut-off of 1.0 micro g/l seems more appropriate. Therefore, in this subset of patients, if any detectable Tg level >or= 1.0 micro g/l is found after rhTSH, re-evaluation after THST should be advised.