射频联合131I治疗失分化甲状腺癌的临床研究

Objective:The aim of this study was to explore clinical efficiency of radio frequency combined with 131I therapy for dedifferentiated thyroid carcinoma. Methods:All patients have been treated by radiofrequency connected with 131I in 29 cases of dedifferentiated thyroid carcinoma which performed radionuclide imaging and Ig array of blood serum before and after therapy, respectively. Results:There were 4 (4/29) positive cases of radionuclide imaging before treatment and 19 (19/29)cases 2 weeks after therapy, 25 (25/29) cases of overall efficacy and 15 (15/29) curative cases. Conclusion:Radiofrequency connected with 131I improve clinical efficacy of 131I treatment for dedifferentiated thyroid cancer of thyroid in view of higher absorbing 131I of thyroid cancerous cell.     

Therapeutic concepts of proteinuria and intra-glomerular hypertension

Leukemia has rarely been reported as a late complication of 131I therapy, occurring mostly after cumulative doses of 800 mCi. We observed two cases of acute myeloid leukemia (AML) after 131I therapy for hyperthyroidism and thyroid carcinoma, respectively. The first patient was a 45-year-old woman treated with a single dose of 27 mCi 131I for hyperthyroidism. She developed AML (FAB M2) 14 months after receiving 131I; the second patient was a 44-year-old man affected by refractory thyroid carcinoma who received a total dose of 1 Ci 131I plus radiotherapy and developed AML (FAB M6) 8 years after the first exposure to 131I. Although it is a very rare event, the occurrence of leukemia after 131I treatment should be kept in mind, considering the widespread use of 131I, particularly in the treatment of hyperthyroidism, and the unfavorable outcome of secondary leukemia.     

Long-term effect of 131I therapy of multinodular non-toxic goiter

The aim of this study was to investigate the long term effect of 131I treatment on thyroid function and size in patients with non-toxic multinodular goitre. The subjects were 69 consecutive patients with multinodular non-toxic goitre selected for 131I treatment and followed for a minimum of 12 months. Outcome measures were standard thyroid function variables and ultrasonically determined thyroid volume before and after treatment. Fifty-nine patients were treated with a single dose of 131I, 12 with two doses, and one with four doses. In 45 patients treated with one dose who remained euthyroid the median thyroid volume was reduced from 73 (interquartile range 50-106) ml to 29 (interquartile range 23-48) ml at 24 months. The median reduction was 40 (22-48) ml, half of which occurred within three months. Patients treated with two doses as well as those developing hypo- or hyper-thyroidism also had a significant reduction in thyroid volume. Eleven patients developed hypothyroidism (cumulative five year risk 22%). Side effects were few. In conclusion we find that 131I treatment of multinodular non-toxic goitre is an attractive alternative to surgery.     

Can radioactive iodine be used in the treatment of diffuse non-toxic goiter?

Traditional treatment modalities of diffuse nontoxic goitre are thyroid hormone suppression or surgery. When treating nodular nontoxic goitre with 131I treatment, a reduction in thyroid volume to about 50% is seen. In the present study we evaluated the effect of 131I treatment in 21 patients treated for a diffuse nontoxic goitre and followed by evaluation of thyroid volume measured by ultrasound. Thyroid volume declined in all patients from median of 66 ml (range 27-160 ml) to 21 ml (9-108 ml) over a year, a reduction of 62%. Three patients developed hypothyroidism in the follow-up period (14%), one of these had a temporary hyperthyroid fase. In conclusion, 131I treatment of diffuse nontoxic goitre reduces thyroid volume by approximately 60% within 12 months. Hypothyroidism developed in 14% during a limited follow-up period.     

Effectiveness of preoperative radioactive iodine (131I) therapy for locally advanced papillary thyroid cancer: a case report

We report here the effectiveness of preoperative radioactive iodine-131 (131I) therapy for locally advanced thyroid cancer. A 57-year-old woman demonstrated a hard neck tumor that markedly invaded the surrounding organs. The cytological diagnosis of the tumor using fine-needle aspiration biopsy was papillary carcinoma. Because curative resection of the tumor appeared difficult at her first visit, 131I therapy was performed prior to surgery and was more useful than expected. After 3 131I treatments, the tumor size was greatly reduced, and the patient underwent a curative operation. Histopathological diagnosis was well differentiated papillary carcinoma, pT4 and pN1b. The postoperative clinical course was uneventful. There have been no definitive reports using 131I as preoperative treatment for inoperable thyroid cancer. We suggest that 131I therapy may also be beneficial as neoadjuvant therapy for locally advanced thyroid carcinoma.     

The correlation of the vasopressin- and oxytocin-producing activities of different nuclei in the hypothalamo-hypophyseal neurosecretory system]

Radioiodine long has proven to be a safe and effective treatment for thyroid disease. Nonetheless, persisting concerns regarding radiogenic stochastic risks (e.g., carcinogenesis) to patients, their families, and the general public have led regulators to establish criteria for release of 131I-containing patients from medical confinement, with limits ranging from as low as 2 mCi in some parts of Europe to as high as 30 mCi in the United States. To optimize clinical efficacy and cost-effectiveness of 131I therapy, such regulations should be based on logical dosimetric considerations. The thyroidal absorbed dose, proportional to maximum uptake and effective half-life and inversely proportional to mass, is typically approximately 1,500 rad/mCi of 131I administered to a euthyroid adult (based on a thyroid maximum uptake of 25%, effective half-life equivalent to the physical half-life of 131I (8.04 days), and mass of 20 g). As thyroid uptake increases from 0% to 100%, extrathyroidal absorbed doses range from a minimum of 0.15 to 0.5 rad/mCi for breast and gonads to a maximum of 1.5 to 2 rad/mCi for stomach and salivary glands; the absorbed doses of the urinary bladder wall, in contrast, decrease with increasing thyroid uptake, from 2 to 0.6 rad/mCi. In hyperthyroid patients (approximately 15%) with a small iodine pool (so-called small patients), the short effective half-life of radioiodine in the thyroid and high serum concentrations of long-lived protein-bound 131I result in a standard 7,000-rad absorbed dose for treatment of Graves' disease requiring an administered activity of 28 mCi of 131I and yielding a prohibitively high blood absorbed dose of 150 rad. Importantly, once the fetal thyroid begins to function and accumulate radioiodine at a gestational age of 10-12 weeks, fetal thyroid absorbed doses as large as 5,000 rad/mCi of 131I administered to the mother can result. Thus, pregnancy is an absolute contraindication to administration of 131I because of the risk of radiogenic cretinism. Based on actual measurements of thyroid activity and of external absorbed dose, the total thyroid and mean extrathyroidal absorbed doses to adult family members from immediately released 131I-treated patients are approximately 0.01 and approximately 0.02 rad/mCi administered, respectively, yielding an effective dose of approximately 0.02 rem/mCi. A maximum permissible effective dose of 0.5 rem for adults therefore is consistent with a release criterion of 30 mCi of retained 131I. Lower-activity release criteria therefore may be unnecessarily restrictive.     

Changes in thyroid volume in response to radioactive iodine for Graves' hyperthyroidism correlated with activity of thyroid-stimulating antibody and treatment outcome

This study investigated 1) the relationship between thyroid volume and thyroid function in radioactive iodine (RAI) treatment for Graves' disease, and 2) the activity of thyroid-related Ig in serum on the responsiveness of thyroid tissue to RAI. The changes in thyroid volume per megabecquerel (MBq) of 131I retained in thyroid tissue was calculated by ultrasonography as a quantitative indicator of the effect of RAI on thyroid volume. Of the 52 patients treated with 131I (3.7 MBq retained/g thyroid tissue), 26 patients showed thyrotoxicosis, 20 patients became euthyroid, and 6 patients developed hypothyroidism 6 months after therapy. The change in thyroid volume per MBq 131I was lower (P < 0.01) in the hyperthyroid patients than in the euthyroid or hypothyroid patients. The activity of thyroid-stimulating antibody in serum immediately before the therapy was greater (P < 0.01) in the hyperthyroid patients than in the euthyroid patients and was greater (P < 0.05) in the euthyroid patients than in the hypothyroid patients; it was inversely correlated with the changes in thyroid volume per MBq 131I (r = -0.667; P < 0.01). Accurate measurement of changes in thyroid volume during the course of RAI treatment provides evidence of the responsiveness of Graves' disease thyroid tissue to RAI, which is related to the outcome of thyroid function. Thyroid-stimulating antibody determination may be useful in deciding the appropriate dose of RAI to obtain euthyroidism instead of hyperthyroidism.     

Outcome of pregnancy after radioactive iodine treatment for well differentiated thyroid carcinomas

This study sought to determine the outcome of pregnancy in female patients with differentiated thyroid carcinoma who became pregnant after radioactive iodide treatment. A total of 779 female thyroid cancer patients were treated at Chang Gung Medical Center in Linkou between January 1977 and December 1995. The medical records of these patients were reviewed retrospectively. Thirty-seven of these patients had well differentiated thyroid carcinoma receiving 131I treatment and conceived at a mean age of 27.97 +/- 3.49 year-old. A total of 58 pregnancy episodes were recorded during this study period. Among these 37 patients, 3 episodes of artificial abortion, 8 episodes of spontaneous abortion and 2 threatened abortions were observed. These patients delivered a total of 47 babies including 3 premature babies. Seven of these patients conceived within 6 months after the last administration of 131I, including 2 cases within 1 month, 4 cases within 4 months, and 1 patient within 5 months. Of these 7 patients, only one patient who conceived within 6 months after the last administration of 131I (14.3%) had a spontaneous abortion. The present results suggest that previous administration of 131I in female patients with well differentiated thyroid cancer does not result in demonstrable adverse effects in subsequent pregnancies. However, further studies involving long-term follow-up of children delivered by mothers who became pregnant within 6 months after the last administration of 131I is needed to further elucidate the possible chronic effects and sequelae of 131I therapy on subsequent pregnancies.     

131 iodine: medical use. Carcinogenic and genetic effects

131 radioiodine is used for treating patients with thyrotoxicosis and differentiated thyroid carcinoma. Its therapeutic effect is related to the radiation dose delivered to the thyroid tissue. The radiation dose is related to its radioactive concentration (ratio between the radioactive uptake and the mass of functional tissue) and its effective half-life. Follow-up studies of patients exposed to 131I did not demonstrate any tumorigenic effect of 131I on the thyroid gland in adults, but do exclude such an effect in children. The dose delivered to other tissues is relatively low, and significant risk of cancer and leukemia has been found only in patients exposed to high cumulative activities of 131I (> 15 GBq). No genetic effect has been found in the studies of the outcome of pregnancies in women exposed to 131I for thyroid carcinoma. These data indicate that there is no scientific reason to avoid the use of 131I even in young patients when therapeutic benefits can be obtained.     

Urinary bladder organ culture with a continuous nutrient system]

From the differences in radiation profiles between 131I and 125I isotopes of iodine it would be expected that they would show different effects on thyroid function. The differences should lead to lower rates of thyroid gland destruction with 125I and hence less post-irradiation hypothyroidism. This difference in biological effect has been demonstrated in rats by indirect assessment of thyroid function. In this report the long-term effects of a range of similar doses of 131I and 125I were compared, in male and female rats, by direct assessment of thyroid function. Seventeen months after receiving 25 and 125 muCi of 131I, male and female rats showed significant elevation of serum TSH concentration and a reduction in 3 h radioiodine uptake. Rats receiving 1 and 5 muCi of 131I and all doses of 125I showed no significant changes in thyroid function. These findings confirm the previously reported differences in effect between the 131I and 125I isotopes of iodine in the rat.     

Interleukin 1alpha and interleukin 6 promote the in vitro growth of both normal and neoplastic human cervical epithelial cells

We report here on a patient who was diagnosed with follicular carcinoma in 1985, and who was treated with total thyroidectomy. Two years later, when metastasis was found in his neck lesion, lung, pelvis and right femur, the patient received 131I treatment. Six years after receiving 131I treatment, the patient presented with hyperthyroidism. Whole-body scan with 131I revealed functioning metastasis in his right femur and pelvis. There was no hot spot in the neck region, confirming that no thyroid tissue remained. Blood panels revealed an increase in both TSH binding inhibitory immunoglobulin (TBII. 36.2%; normal. -10 approximately 10%) and thyroid stimulating antibody (TSAb, 176%; normal, less than 145%). Treatment with antithyroid drugs, dexamethasone and radioisotope therapy rapidly resolved his hyperthyroidism. Thyrotoxicosis and positive TRAb occurred in the absence of thyroid tissue, and many years after the completion of R1 therapy. The overproduction of thyroid hormone can therefore only be attributed to some mechanism of activity in the metastatic tumor tissue.     

Foetal rat pancreatic transplantation: posttransplantation development of foetal pancreatic iso- and allografts and suppression of rejection with mycophenolate mofetil (MMF) and cyclosporine based immunesuppression

CONTEXT: High-dose iodine 131 is the treatment of choice in the United States for most adults with hyperthyroid disease. Although there is little evidence to link therapeutic (131)I to the development of cancer, its extensive medical use indicates the need for additional evaluation. OBJECTIVE: To evaluate cancer mortality among hyperthyroid patients, particularly after (131)I treatment. DESIGN: A retrospective cohort study. SETTING: Twenty-five clinics in the United States and 1 clinic in England. PATIENTS: A total of 35 593 hyperthyroid patients treated between 1946 and 1964 in the original Cooperative Thyrotoxicosis Therapy Follow-up Study; 91 % had Graves disease, 79% were female, and 65% were treated with (131)I. MAIN OUTCOME MEASURE: Standardized cancer mortality ratios (SMRs) after 3 treatment modalities for hyperthyroidism. RESULTS: Of the study cohort, 50.5% had died by the end of follow-up in December 1990. The total number of cancer deaths was close to that expected based on mortality rates in the general population (2950 vs 2857.6), but there was a small excess of mortality from cancers of the lung, breast, kidney, and thyroid, and a deficit of deaths from cancers of the uterus and the prostate gland. Patients with toxic nodular goiter had an SMR of 1.16 (95% confidence interval [CI], 1.03-1.30). More than 1 year after treatment, an increased risk of cancer mortality was seen among patients treated exclusively with antithyroid drugs (SMR, 1.31; 95% CI, 1.06-1.60). Radioactive iodine was not linked to total cancer deaths (SMR, 1.02; 95% CI, 0.98-1.07) or to any specific cancer with the exception of thyroid cancer (SMR, 3.94; 95% CI, 2.52-5.86). CONCLUSIONS: Neither hyperthyroidism nor (131)I treatment resulted in a significantly increased risk of total cancer mortality. While there was an elevated risk of thyroid cancer mortality following (131)I treatment, in absolute terms the excess number of deaths was small, and the underlying thyroid disease appeared to play a role. Overall, (131)I appears to be a safe therapy for hyperthyroidism.     

Transient hypothyroidism after iodine-131 therapy for Grave's disease

We studied 355 patients with Grave's disease to characterize transient hypothyroidism and its prognostic value following 131I therapy. METHODS: The patients received therapeutic 131I treatment as follows: 333 received a dose < 10 mCi (6.6 +/- 1.9 mCi) and 22 received a dose > 10 mCi (12.8 +/- 2.9 mCi). Diagnosis of transient hypothyroidism was based on low T4, regardless of TSH within the first year after 131I followed by recovery of T4 and normal TSH. RESULTS: After administration of < 10 mCi 131I, 40 patients developed transient hypothyroidism during the first year; transient hypothyroidism was symptomatic in 15. There was no transient hypothyroidism after high doses (> 10 mCi) of 131I. Iodine-131 uptake > 70% at 2 hr before treatment was a risk factor for developing transient hypothyroidism (Odds ratio 2.8, 95% confidence interval 0.9-9.4). At diagnosis of transient hypothyroidism, basal TSH levels were high (51%), normal (35%) or low (14%); therefore, the transient hypothyroidism was not centralized. If hypothyroidism developed during the first 6 mo after basal TSH > 45 mU/liter ruled out transient hypothyroidism. CONCLUSION: The development of transient hypothyroidism and its hormonal pattern did not influence long-term thyroid function. Since no prognostic factors reliably predicted transient hypothyroidism before 131I or at the time of diagnosis, if hypothyroidism appears within the first months after 131I, the reevaluation of thyroid function later is warranted to avoid unnecessary chronic replacement therapy.     

Changes in radioiodine turnover in patients with autonomous thyroid adenoma treated with percutaneous ethanol injection

In 24 patients with autonomous thyroid adenoma, we studied the hormonal pattern (free thyroxine, free triiodothyronine and thyroid stimulating hormone) and markers of radioiodine turnover before and after nodule ablation with percutaneous ethanol injection. METHODS: The hormonal pattern was studied before treatment and at various intervals after nodule ablation. Changes in radioiodine turnover were studied measuring 131I protein-bound iodine and the biologic half-life of radioiodine in the thyroid (calculated from thyroid uptake at 24 and 48 hr) before and after ethanol treatment. RESULTS: The hormonal pattern was normalized by treatment in all patients and remained normal for the follow-up period. Before treatment, protein-bound 131I was elevated in all patients but 4; after treatment, it normalized in 15 patients with the disappearance of the adenoma on scintigraphy. In the remaining 9 patients with only partial nodule destruction on scintigraphy, protein-bound 131I remained elevated although markedly reduced. Biologic half-life was shortened in 18 of 24 patients before treatment; after treatment, it was normal in 18 of 24 patients (13 of 15 with complete nodule ablation and 5 of 9 with partial ablation). CONCLUSION: Ethanol treatment normalized the hormonal pattern in all patients. Measures of radioiodine turnover were better markers of residual disease in that they normalized in almost all patients with complete nodule ablation, whereas they remained abnormal in a high proportion of patients with incomplete ablation. Thyroid hormones remained normal over a follow-up period of 3-7 yr in all patients.     

Screening for microalbuminuria by RIA in 131I-treated thyroid cancer patients

Thyroid cancer patients are treated with up to 9.9 GBq of 131I to ablate remnant thyroid tissue and/or any functioning metastases that may be present. Radioiodine therapy is repeated as often as required. However, only a small fraction of the 131I is taken up by remnant thyroid and metastases, the remainder being eliminated by the kidneys, which are therefore subject to irradiation. External radiation therapy to the kidneys is known to lead to nephritis and albuminuria. The study included 113 patients treated with one to four doses of 131I (1.1-9.9 GBq each dose) and followed up 1 month to more than 8 years later. Spot samples of urine were collected and microalbuminuria measured by in-house radioimmunoassay. Twelve patients had elevated levels (normal range up to 34 micrograms ml-1), but their clinical history revealed such predisposing factors as diabetes and/or hypertension and proteinuria before therapy commenced. The remaining patients had normoalbuminuria. Grouping the patients based on the total dose of 131I administered resulted in a median microalbuminuria of 2.4-12.9 micrograms ml-1. Hence, this study showed that the dose of 131I normally used in treating thyroid cancer does not increase microalbuminuria to any significant extent.     

Leukaemias and cancers following iodine-131 administration for thyroid cancer

We studied 1771 patients treated for a thyroid cancer in two institutions. None of these patients had been treated with external radiotherapy and 1497 had received (131)I. The average (131)I cumulative activity administered was 7.2 GBq, and the estimated average dose was 0.34 Sv to the bone marrow and 0.80 Sv to the whole body. After a mean follow-up of 10 years, no case of leukaemia was observed, compared with 2.5 expected according to the coefficients derived from Japanese atomic bomb survivors (P = 0.1). A total of 80 patients developed a solid second malignant neoplasm (SMN), among whom 13 developed a colorectal cancer. The risk of colorectal cancer was found to be related to the total activity of (131)I administered 5 years or more before its diagnosis (excess relative risk = 0.5 per GBq, P = 0.02). These findings were probably caused by the accumulation of (131)I in the colon lumen. Hence, in the absence of laxative treatment, the dose to the colon as a result of (131)I administered for the treatment of thyroid cancer could be higher than expected from calculation of the International Commission on Radiological Protection (ICRP). When digestive tract cancers were excluded, the overall excess relative risk of second cancer per estimated effective sievert received to the whole body was -0.2 (P = 0.6).     

Chernobyl accident: reconstruction of thyroid dose for inhabitants of the Republic of Belarus

The Chernobyl accident in April 1986 resulted in widespread contamination of the environment with radioactive materials, including (131)I and other radioiodines. This environmental contamination led to substantial radiation doses in the thyroids of many inhabitants of the Republic of Belarus. The reconstruction of thyroid doses received by Belarussians is based primarily on exposure rates measured against the neck of more than 200,000 people in the more contaminated territories; these measurements were carried out within a few weeks after the accident and before the decay of (131)I to negligible levels. Preliminary estimates of thyroid dose have been divided into 3 classes: Class 1 ("measured" doses), Class 2 (doses "derived by affinity"), and Class 3 ("empirically-derived" doses). Class 1 doses are estimated directly from the measured thyroidal (131)I content of the person considered, plus information on lifestyle and dietary habits. Such estimates are available for about 130,000 individuals from the contaminated areas of the Gomel and Mogilev Oblasts and from the city of Minsk. Maximum individual doses are estimated to range up to about 60 Gy. For every village with a sufficient number of residents with Class 1 doses, individual thyroid dose distributions are determined for several age groups and levels of milk consumption. These data are used to derive Class 2 thyroid dose estimates for unmeasured inhabitants of these villages. For any village where the number of residents with Class 1 thyroid doses is small or equal to zero, individual thyroid doses of Class 3 are derived from the relationship obtained between the mean adult thyroid dose and the deposition density of (131)I or 137Cs in villages with Class 2 thyroid doses presenting characteristics similar to those of the village considered. In order to improve the reliability of the Class 3 thyroid doses, an extensive program of measurement of (129)I in soils is envisaged.     

Thymic uptake of iodine-131 in the anterior mediastinum

Two thyroidectomized patients with a history of differentiated thyroid carcinoma are presented who had nonmetastatic mediastinal 131I uptake following therapeutic doses of 131I. Chest CT scans in both patients demonstrated an anterior mediastinal mass. Surgical excision in one patient and a percutaneous CT-guided fine needle aspiration biopsy in the other disclosed normal thymus tissue. Iodine-131 uptake in the anterior mediastinum in patients thyroidectomized for follicular or papillary thyroid carcinoma may represent the thymus.     

Combination of radioiodine (131I) and probe-guided surgery for persistent or recurrent thyroid carcinoma

To improve the completeness of surgical excision of persistent or recurrent differentiated thyroid carcinoma, the following protocol was used for the treatment of 54 patients with functioning lymph node metastases: administration of 3.7 gigabecquerels (100 mCi) 131I; total body scintigraphy (TBS) on day 4; surgery on day 5, using an intraoperative probe (Gammed 2, Eurorad); and postoperative TBS with the remaining 131I activity on day 7. The 54 patients (35 women and 19 men presenting 47 papillary carcinomas, 2 well differentiated follicular carcinomas, and 5 poorly differentiated follicular carcinomas) had already undergone surgery for differentiated thyroid carcinoma: total thyroidectomy (51 patients) or lobectomy with isthmusectomy (3 patients), with lymph node dissection in 33. One to 7 131I treatments were performed before inclusion. Preoperative 131I-TBS with a high dose of 131I allowed accurate localization of previously suspected neoplastic foci and detection of yet unknown foci in 56%; it was the most sensitive tool for localizing neoplastic foci. The use of an intraoperative probe was considered decisive in 20 patients, as neoplastic foci were found inside sclerosis due to previous surgery (n = 9), at unusual sites behind vessels or in the mediastinum (n = 10), or both (n = 1). In 26 patients, it facilitated the preoperative detection of foci with 131I uptake already depicted at preoperative 131I-TBS. In all 46 patients, the completeness of excision was demonstrated by both the probe and the postoperative 131I-TBS and was confirmed during follow-up. Of note, lymph node metastases undetected by 131I-TBS or by the probe were found in 14 patients at histological examination. This clearly shows that en block dissection is the only recommended procedure. In four patients, no neoplastic foci were found and in four patients, uptake was either due to the thymus (in two) or to the salivary glands (in two).     

Determination of factors affecting the therapeutic outcome of radioiodine therapy in patients with Graves' disease

AIM: Of this study was to determine whether success of radioiodine therapy (RIT) in Graves' disease depends on thyroid volume, function, thyroideal receptor antibodies (TRAK), thyreostasis, therapeutic dosage, 131I uptake, or effective half-life. METHOD: 78 patients received an average of 626 +/- 251 MBq of iodine-131 orally for thyroid ablation. 60 were assessed for successful therapy 3 months after RIT. RESULTS: In patients showing hyperthyreosis or a TRAK value > 11 U/l at the beginning of RIT, a significantly lower therapeutic dosage and effective iodine half-life were found than in non-hyperthyreotic patients or patients with TRAK < or = 11 U/l. Patients with a thyroid volume < or = 25 ml showed a significantly lower 131I uptake, but a significantly higher relative uptake (131I uptake/ volume) than patients with a thyroid volume > 25 ml. All failures were treated thyreostatically during RIT and showed a significantly lower therapeutic iodine dosage and relative uptake, as well as a significantly higher thyroid volume than patients with a successful therapy. RIT caused a thyroid volume reduction of 44%, with therapy failures showing a significantly lower volume reduction. Patients who received a therapeutic dosage of < or = 250 Gy showed significantly worse results than did those who had received > 250 Gy. Only one case of therapy failure received a dosage > 250 Gy, while 50% of failures received dosages > 200 Gy but < 250 Gy. Multivariate analyses (MANOVA, factor analyses) showed thyreostasis as the decisive negative factor for a successful course of therapy. CONCLUSIONS: Since most treatment failures occurred in patients under thyreostatic medication we recommend raising the target dosage to 250 Gy for these cases.