A Matter of Controversy: Is Radioiodine Therapy Favorable in Differentiated Thyroid Carcinoma?

DTC HISTOPATHOLOGY, METASTATIC PATTERNS, AND TREATMENT AIMS

DTC consists of two histologic types, papillary thyroid carcinoma (PTC) and follicular thyroid carcinoma (FTC). In general, both entities are slowly growing. Prognosis is good if completely eradicated, but the metastatic patterns of these two types of carcinoma differ. FTC metastasizes predominantly to distant organs such as lungs and bones, whereas PTC shows a high incidence of lymph node metastasis, ranging from 30% to 80% of patients (2,3). Surgery has the goal of removing the tumor, and radioiodine therapy has two goals: ablation of thyroid remnants to facilitate follow-up and—more importantly—destruction of microscopic tumor tissue as an adjuvant therapy (4). DTC in pregnant women is, fortunately, rare, as pregnancy is an absolute contraindication to the use of radioiodine therapy.

TOTAL THYROIDECTOMY VERSUS LOBECTOMY

Thyroid lobectomy alone is also sufficient for minimally invasive FTC without angioinvasion (5,6) and for encapsulated follicular-patterned thyroid tumors of uncertain malignant potential according to the 4th edition of the World Health Organization classification of tumors (e.g., noninvasive follicular thyroid neoplasm with papillary-like nuclear features [NIFTP]) (7). The presence of the remaining lobe of the gland does not allow for the use of radioiodine remnant ablation. Follow-up management consists of neck ultrasonography and serial thyroglobulin measurements. For patients with an unequivocal thyroid cancer larger than 1.0 cm, we recommend a near-total or total thyroidectomy. Then, the question arises of whether radioiodine ablation may improve recurrence-free or overall survival.

METHODOLOGIC ASPECTS OF RADIOIODINE THERAPY

There are several reasons for controversy in the use of radioiodine. There is a lack of prospective randomized controlled trials, and data on clinical outcomes are taken mostly from retrospective series. To set up prospective randomized trials with radioiodine is not an easy task, requiring long-term follow-up because of the slowly growing tumor biology and the low event rate. In a review by Sawka et al., only studies with an observation period of more than 10 y showed a benefit for patients treated with radioiodine, and sample sizes required recruitment of at least 1,500 patients (8,9). There are ongoing prospective clinical trials aiming to further clarify the indication for radioiodine therapy, such as the French multicenter “Etude Stimulation Ablation” (ESTIMABL trial) (10), the British “Is Ablative Radio-Iodine Necessary for Low Risk Differentiated Thyroid Cancer Patients” (IoN trial) (11,12), and the German “I-124 PET/CT Based Remnant Radioiodine Ablation Decision Concept in Differentiated Thyroid Cancer” (CLERAD-PROBE trial) (13), which include low-risk patients. Results are expected beginning in 2020. The difficulty in planning prospective studies can be exemplified by considering the feasibility of designing a multiinstitutional prospective randomized controlled trial of prophylactic central lymph node dissection in cN0 PTC. Carling et al. calculated that a total of 5,840 patients would have to be included in such a study to achieve at least 80% statistical power. Thus, such a study was considered not readily feasible (14).

GUIDELINES OF AMERICAN THYROID ASSOCIATION (ATA) AND BRITISH THYROID ASSOCIATION

In 2015, the ATA published version 3 of the guidelines dealing with the diagnosis and treatment of DTC (6). The recurrence risk was expanded from the basic 3-tiered system of low, intermediate, and high risk for locoregional recurrence or distant metastases to a broader risk continuum that incorporates actual risk percentages from several cited studies (6,15). In version 3 of the ATA guidelines, patients with lymph node metastases can be categorized into each of the 3 risk groups rather than simply placing all patients with lymph node disease into the intermediate-risk category (6,15). Only patients who have tumors with gross extrathyroidal invasion (T4)—together with pN1 with extranodal extension and at least 3 lymph nodes involved, any lymph node larger than 3 cm, or distant metastases—are definite candidates for radioiodine therapy, whereas T1b and T2 tumors are not considered routine indications. Patients with other T categories such as T3 or T1–3 N1a or N1b are candidates in whom radioiodine therapy could be considered. The authors of the ATA guideline state that of the 191 individual recommendations, only 11 were based on high-quality evidence whereas 97 were based on low-quality evidence (6). Haugen et al. aimed to reduce what they consider excess therapy and rather want to monitor patients with a few, small lymph node metastases who are now categorized in the low-risk category (6,15). Noteworthy are considerations concerning remnant ablation, adjuvant therapy, and therapy of metastases. Patients who are considered for remnant ablation are treated with radioiodine to ablate normal thyroid tissue, and the ablation should improve the sensitivity and specificity of subsequent monitoring tools. Patients considered for adjuvant therapy are those who have undergone a complete resection of their disease and have no known residual disease but are at high risk of developing recurrent disease. Patients who receive radioiodine therapy are those who have known residual locoregional or metastatic disease and who need therapy in an attempt to eradicate or control the disease. Haugen et al. suggested that those patients who are considered for remnant ablation should be considered for only a lower administered activity of radioiodine (i.e., 1.1 GBq [30 mCi] of ¹³¹I), reserving higher administered activities for those patients receiving radioiodine for adjuvant therapy or therapy of metastases. These approaches aim to reduce the risk of potential side effects (e.g., sialadenitis, xerostomia, epiphora, or secondary malignancy) in patients with low- or intermediate-risk DTC.

The British Thyroid Association guideline (4) gave similar recommendations on the use of radioiodine in DTC patients but used the term selective use instead of may be considered. Questions remain about the precise specification of selection criteria.

POSITION OF EUROPEAN ASSOCIATION OF NUCLEAR MEDICINE AND EUROPEAN COUNTRIES

In 2016, Verburg et al. published an article on why the European Association of Nuclear Medicine declined to endorse the 2015 ATA guidelines (16). In most cases, the objections were based on differences in the interpretation of the available evidence, especially where the role of nuclear medicine is concerned. The objections start with the acceptance of incomplete resection. The ATA recommendation either to perform a bilateral near-total or total thyroidectomy or to limit the initial procedure to lobectomy for tumors larger than 1 cm but smaller than 4 cm, and with no extrathyroidal extension or clinical evidence of lymph node metastases (cN0), is a shift from previous clinical practice and would make adjuvant radioiodine therapy not feasible in the presence of a large thyroid remnant. This recommendation would result in a definite change in medical practice concerning state-of-the art follow-up examinations, because thyroglobulin would no longer have the significance it has today. For the entire population of patients with DTC exceeding 1 cm in diameter, the usefulness of postoperative ¹³¹I ablation is evident from retrospective studies (8,9). The expertise of the surgeon is an important parameter, and postoperative serum thyroglobulin may be an indicator of the completeness of thyroid tissue removal, helping to identify patients who may benefit from ¹³¹I therapy (16).

In Germany, it is recommended that patients be advised to undergo radioiodine therapy unless they have papillary thyroid microcarcinoma (PTMC) (17). Patients considered at low risk for recurrent disease (pT1b–pT2 cN0 M0; risk of recurrence, 2%–7%) are usually treated with radioiodine therapy. In our institution, 2.0 GBq of ¹³¹I are usually administered in this situation. The ATA limited its own recommendation by judging it as weak, as based on low-quality evidence, and as lacking inclusion of more aggressive variants of DTC. The results of large retrospective studies in the United States are in contrast to the ATA recommendations.

SPECIAL TUMOR ENTITIES

RISK ASSESSMENT OF RADIATION EXPOSURE

Rubino at el. reported a small risk of second malignancies for cumulated activities of more than 7.4 GBq of ¹³¹I (27). Data from the SEER Database are difficult to assess because most secondary malignancies were detected within 1 y of radioiodine therapy, making a causal relationship unlikely. It seems more likely that these patients had access to improved diagnostic facilities, explaining a higher diagnostic yield of malignancies (28). Hirsch et al. reported on 1,943 patients, of whom 1,574 (81%) were treated with radioiodine and 1,467 were followed for at least 2 y, and of these, 1,145 (78%) received a cumulative dose of more than 7.4 GBq (200 mCi) of radioiodine. In patients followed for 2 y, second malignancies were diagnosed in 9% of radioiodine-treated patients and 10.5% of non–radioiodine-treated patients (29). Data from Korea on 211,360 patients analyzed the dose-dependent risk between radioiodine and leukemia (Table 2) (30). In the group treated with activities of up to 3.7 GBq, no increase in the incidence of leukemia was observed. However, there was an increased risk in the group treated with more than 3.7 GBq (100 mCi), meaning that 1 in 2,000 patients treated with a radioiodine activity of more than 3.7 GBq may develop leukemia as a second malignancy. As a new aspect, the latency period before the statistically increased risk of leukemia was first observed (∼8 mo) is shorter than previously assumed (30).

CURRENT TREATMENT STRATEGIES

Two important prospective randomized controlled trials have compared recombinant thyroid stimulating hormone (rhTSH) with hypothyroidism and 1.1 GBq (30 mCi) versus 3.7 GBq (100 mCi) of radioiodine for ablative radioiodine therapy: the ESTIMABL trial (31) and the British study “High- Versus Low-Dose Radioiodine” (HiLo trial) (32). The authors concluded that rhTSH and hypothyroidism were equally effective and that 1.1 GBq was not inferior to 3.7 GBq. However, the trials had some drawbacks related in part to the definition of endpoints. In the ESTIMABL trial, success was defined as a stimulated thyroglobulin level of less than 1 ng/mL. The authors did not report the percentages of patients in whom a thyroglobulin level below the assay sensitivity was reached. A modern thyroglobulin assay with a lower functional sensitivity of 0.2 ng/mL was used. Only 24 of 684 patients underwent diagnostic whole-body scintigraphy, and neck uptake as high as 0.5% was accepted as success. In the HiLo trial, 1.1 GBq was 5.9% less effective than 3.7 GBq in the rhTSH group, and a second ablation was necessary in 9.5% of the 1.1-GBq group versus 4.1% in the 3.7-GBq group, indicating initial ablation failure. A stimulated thyroglobulin level of less than 2.0 ng/mL and thyroid uptake still as high as 0.1% were considered to indicate successful ablation. However, 68 of 438 patients had incomplete laboratory tests. Thus, the HiLo trial showed inferior results for the low-risk group (32).

The success of radioiodine therapy is critically dependent on the surgeon’s experience. The more total the thyroidectomy is and the lower the remnant volume, the lower is the activity of radioiodine required for successful therapy. The clinical aim is to treat patients with the lowest single dose of radioiodine activity necessary to achieve cure. However, this is a difficult aim and the above-mentioned trials used a surrogate parameter as endpoints (i.e., stimulated thyroglobulin [rhTSH]) 8 mo after radioiodine therapy. Patients treated in Poland (33), Turkey (34), and Iran (35) needed increased rates of second ablative therapies when lower initial activities of radioiodine were used. In all 3 studies, the cumulative activities of 2 ablative therapies were higher than the radioiodine dose in the standard arm (3.7 GBq of ¹³¹I). To answer questions on disease-specific and overall survival, long-term follow-up is necessary. In our institution, low-risk patients (pT1–pT2 cN0) are treated with 2.0 GBq of ¹³¹I if larger thyroid remnants do not exist before the radioiodine ablation. The concept of a 2-GBq dose of ¹³¹I was recently confirmed by retrospective data from Munich: Todica et al. demonstrated an equally high success rate with 2 GBq (90%, n = 135) versus 3.7 GBq (91%, n = 137) using a thyroglobulin threshold of 0.5 ng/mL (36).

TREATMENT RECOMMENDATIONS

Recommendations on whether to advise the use of radioiodine therapy have changed over time and vary among countries. The ATA guidelines on the use of radioiodine in the United States became increasingly restricted, whereas other countries are more open to recommending radioiodine therapy. Prospective randomized trials are lacking. In addition, because most of the tumors are slow-growing, studies with several thousands of patients and decades of follow-up would be needed (40). In the United States, about 50% of patient in stage I (pT1a–pT1b N0 M0 in patients > 45 y old and pT1–pT3 N0–N1 M0 in patients < 45 y old) receive radioiodine treatment. The most recent ATA guidelines did not include the latest and largest studies (18–20,22). Data from the National Cancer Database showed a reduced risk for the endpoint mortality even for DTC tumors between 1 and 2 cm in size. Radioiodine treatment has been found to be more important for prognosis than is the extent of resection (18,19). Other strategies, such as delayed radioiodine treatment in cases of increasing thyroglobulin level, have not found clinical acceptance yet. In intermediate-risk patients, postoperative monitoring of thyroglobulin levels alone was found to be insufficient for detection of patients with metastases (41,42). Without adjuvant radioiodine therapy, thyroglobulin production by a thyroid remnant will mask early detection of recurrent disease—a particular problem because of the decreasing use of central lymph node dissection. Microscopic nodal disease will no longer be detected or treated. For intermediate-risk patients, a significant survival advantage was found for the radioiodine treatment group (22). In multifocal PTMC, the risk for recurrence was estimated to be 4%–6% by the ATA. Shattuck et al. analyzed the patterns of X-chromosome inactivation of multiple distinct foci of well-differentiated multifocal PTC and showed that individual tumor foci in patients with multifocal PTC often arise as independent tumors (43). Thus, in viable thyroid remnants there may be an increased risk of the de novo appearance of tumor cells, which would be controlled by radioiodine treatment. Risks and side effects of radioiodine treatment exist but are neither frequent nor of impressive clinical severity. Radiation-induced inflammation of the thyroid is among the more frequent side effects and is usually easy to treat by application of cooling ice packs or nonsteroidal antiinflammatory drugs. The Korean data indicated that leukemia occurred as a side effect only when treatment activities were above 3.7 GBq, and the likelihood was only 1 in about 2,000 therapies. In low-risk patients, adjuvant radioiodine therapy is given once with 2.0 GBq of ¹³¹I. Response assessment 6–9 mo after radioiodine therapy by whole-body scintigraphy using very low activities and stimulated thyroglobulin have shown results equal to those from 3.7 GBq. Adjuvant radioiodine therapy and response assessment providing important information about the future risk of disease-specific survival should aim to routinely obviate a second ablation. Because of the difficulties with setting up prospective studies with decades of follow-up, it would be highly desirable to have a cancer registry at, minimally, a national or European level (30).