Abstract
Given the fact that a large number of radiological examinations using iodine-based contrast media (ICM) are performed in everyday practice, clinicians should be aware of potential ICM-induced thyroid dysfunction (TD). ICM can induce hyperthyroidism (Hyper) or hypothyroidism (Hypo) due to supraphysiological concentrations of iodine in the contrast solution. The prevalence of ICM-induced TD varies from 1 to 15%. ICM-induced Hyper is predominantly found in regions with iodine deficiency and in patients with underlying nodular goiter or latent Graves’ disease. Patients at risk for ICM-induced Hypo include those with autoimmune thyroiditis, living in areas with sufficient iodine supply. Most cases of ICM-induced TD are mild and transient. In the absence of prospective clinical trials on the management of ICM-induced TD, an individualized approach to prevention and treatment, based on patient’s age, clinical symptoms, pre-existing thyroid diseases, coexisting morbidities and iodine intake must be advised. Treatment of ICM-induced Hyper with antithyroid drugs (in selected cases in combination with sodium perchlorate) should be considered in patients with severe or prolonged hyperthyroid symptoms or in older patients with underlying heart disease. It is debated whether preventive therapy with methimazole and/or perchlorate prior to ICM administration is justified. In ICM-induced overt Hypo, temporary levothyroxine may be considered in younger patients with symptoms of Hypo, with an underlying autoimmune thyroiditis and in women planning pregnancy. Additional clinical trials with clinically relevant endpoints are warranted to further aid in clinical decision-making in patients with ICM-induced TD.
Introduction
During the past decades, the number of radiological examinations, particularly computed tomography (CT) and vascular interventional procedures, which require iodine-based contrast media (ICM) has risen dramatically [1]. Thus clinicians must be aware of possible adverse effects (Contrast Media Safety Guidelines 10.0; http://www.esur.org/esur-guidelines/). Although certain adverse effects (e.g., contrast-induced nephropathy) have been widely studied, the effects of ICM on the thyroid gland remain poorly characterized. It is generally accepted that ICM can cause thyroid dysfunction (TD) because of supraphysiological concentrations of iodine in the contrast solution [2-5]. While the normal thyroid gland can usually adapt to an excess iodine load, individuals with an underlying thyroid disorder may develop hyperthyroidism (Hyper) or hypothyroidism (Hypo).
When it comes to radiological examinations using ICM in patients with thyroid disorders specialists from different fields of medicine are regularly faced with a dilemma. This document reviews current evidence and provides answers to questions commonly asked in clinical practice concerning the potential risk, prevention, diagnosis, and management of ICM-induced TD.
Overview of Radiographic ICM
Current radiographic (X-ray and CT) imaging uses electromagnetic radiation that penetrates the body. Contrast agents may be used with these techniques to enhance the differences seen between body tissues [6]. Among the ICM, 2 different types have to be distinguished: ionic and nonionic compounds. Ionic contrast agents with high osmolality are not in use for parenteral administration anymore, but only for oral or rectal application, which does not result in significant systemic uptake. Only nonionic iodine-based contrast agents are used for parenteral (intravenous [IV] or intra-arterial) administration in radiologic examinations. These agents are either monomeric or dimeric tri-iodinated benzene rings with an organic functional group [7]. The preference for iodine over metal ions with high atomic numbers is based on its high efficacy in absorption of X-rays, the stable binding of multiple iodine atoms to an organic molecule, and the low toxicity of ICM [8].
Physicochemical Properties
Non-ionic ICM is hydrophilic, which is a prerequisite for intravascular injection of larger quantities. Low viscosity of contrast agents is necessary for rapid administration during CT or angiography [8]. Viscosity depends on chemical structure, iodine content, and temperature of contrast agent: dimeric agents are more viscous than monomeric agents (Table 1). In general, higher iodine content and lower temperature result in higher viscosity [9].
Contrast Material Dosage
Iodine-based contrast agents are mostly administered parenterally during CT, angiography, or IV urography, and to a lesser extent orally, enterally (during endoscopic retrograde cholangiopancreatography), rectally, or intracavitary. The amount of contrast material delivered during CT ranges normally between 60 and 150 mL, depending on the indication, the scanned region, and the scan range, as well as the body weight [10-12]. Given the standard iodine concentration of 300 mg/mL then a total amount of 18–45 g of iodine is administered during contrast-enhanced CT. With catheter angiography, even higher doses of contrast may be used [7].
Prevalence of ICM-Induced TD
At present, the prevalence and clinical significance of ICM-induced TD is incompletely characterized. Recent large retrospective observational studies confirmed an association between ICM exposure and the development of TD. In a nested case-control study using data from the Partners Health-Care Research Patient Data Registry (USA), ICM exposure was associated with incident overt Hyper (oHyper) (defined as a suppressed TSH <0.1 mIU/L; odds ratio [OR], 2.50; 95% CI, 1.06–5.93) and with incident overt Hypo (oHypo) (defined as elevated serum TSH >10 mIU/L; OR, 3.05; 95% CI, 1.07–8.72) [13]. A significantly higher risk of ICM-induced TD (based on International Classification of Diseases, Ninth Revision, Clinical Modification codes) was demonstrated in Taiwan among 1 million patients in the general population over a single year time period; the adjusted hazard ratio (HR) of Hyper and Hypo compared with controls was 1.22 (95% CI, 1.04–1.44) and 2.00 (95% CI, 1.65–2.44), respectively [14]. Moreover repeated ICM exposure (>1 time of ICM per year) increased significantly the risk of thyroid disorders (HR = 3.04; 95% CI, 2.47–3.73) [15]. A subsequent study using the Taiwan’s National Health Insurance Research Database found that patients with euthyroid nodular goiter had almost 5-fold higher risk of ICM-induced TD than patients without thyroid nodule(s), including Hyper (HR 5.77, CI 2.64–12.62) and Hypo (HR 4.95, CI 2.15–11.40) [16]. A retrospective cohort study of children aged younger than 4 years in the Kaiser Permanente Northern California (USA) database revealed that the incidence density ratio for Hypo in ICM-exposed patients was 1.33 per 1000 person months (95% CI, 0.9–1.8). It was highest among children younger than 3 months old [17]. A further single-institution case-control study in the USA confirmed that ICM exposure increases the risk of incident Hypo in pediatric patients (OR, 2.60; 95% CI, 1.43–4.72) [18].
Despite convincing retrospective studies, the results of prospective observational studies in various countries examining changes in thyroid hormone levels following a single exposure to ICM are highly variable (online suppl. Table 1; see online Supplementary Materials) [19, 88-91]. The prevalence of ICM-induced Hyper ranged from 0 to 9%, being greater in countries with iodine deficiency. ICM-induced Hypo was more prevalent in countries with a high iodine intake and occurred in up to 15% of patients. These findings must be interpreted with caution due to important limitations, for example, (i) substantial heterogeneity between studies was present with respect to both groups of patients (unselected patients vs. patients without previous TD) as well as radiological examination (coronary angiography, CT, hysterosalpingography) using different ICM; (ii) most studies were of small size applying different follow-up periods; (iii) heterogeneity with respect to definition of TD; and (iv) an in-depth analysis of relevant clinical measures is generally missing.
Methodology
Given the controversies regarding the prevalence, clinical significance, prevention, and treatment of ICM-induced TD, in 2019 T.B., T.H.B., W.S., G.Z., and G.J.K. asked the European Thyroid Association (ETA) to form a task force to provide practice guidelines for the management of ICM-associated TD. Membership on the panel was based on clinical expertise, scholarly approach, representation of endocrinology, nuclear medicine, and radiology, as well as ETA membership. The proposed task force was approved by the ETA Guidelines Board and the ETA Executive Committee.
The present international guidelines concerning various TD do not address the problem of ICM exposure in detail [20-23]. Moreover, a recent survey performed in Norway suggested a need of optimization of routines regarding ICM administration to patients at risk for TD [24]. The aim of the task force was to offer an evidence-based, up-to-date, and thorough document critically encompassing and evaluating the current available scientific information worldwide.
Literature Search
Relevant published articles were identified by searching PUBMED (www.ncbi.nlm.nih.gov). Furthermore, all references were evaluated for any additional appropriate citation.
Grading
The task force rated the recommendations according to the GRADE system, which was used in the previous guidelines issued by the ETA [25-27]. The following coding system was used: (1) indicates a strong recommendation (for or against) because the benefits outweigh the risks and is associated with the phrase “we recommend”; (2) denotes a weak recommendation (for or against) in which the treatment depends on the patient’s preference because the benefits and risks were uncertain and are associated with the phrase “we suggest.” Evidence grading: ØOOO denotes very low-quality evidence; ØØOO, low; ØØØO, moderate; and ØØØØ, high quality.
Recommendations
Recommendations before Radiological Examinations Using ICM
Screening of Baseline Thyroid Function prior to ICM Exposure in the General Population
In the general population, clinically evident TD is a rare complication after ICM exposure. The number needed to harm for ICM-induced Hyper and Hypo was one in every 250 patients [14]. These results were confirmed by single-institution retrospective analyses and a recent metanalysis [19]. In the Netherlands, 7 patients with nodular goiter needed hospitalization between 1987 and 1990 due to clinically severe ICM-induced Hyper among a cohort of 24,000 CT scans [28]. More recently in Denmark, 14 patients (6% of all new cases of Hyper) had an ICM injection within 2 years before the hyperthyroid episode. During the same period, 30,000–35,000 injections of ICM were given for CT only [29].
Recommendations
1. We do not recommend baseline thyroid function testing of the general population before radiological examinations using ICM administration. 1, ØØOO
Screening of Baseline Thyroid Function in High-Risk Patients for ICM-Induced TD
It is clinically relevant to detect undiagnosed TD prior to ICM exposure. In areas of iodine deficiency, the prevalence of undiagnosed Hyper may be surprisingly high. In a large prospective study in Italy, 7.2% of patients without known thyroid disease had Hyper (predominantly subclinical Hyper [SHyper]) prior to elective coronary angiography [30]. In a second large Italian study including 1752 consecutive patients before coronary angiography [31], TD was a frequent condition involving about 40% of the population as follows: low T3 syndrome – 28%, Hypo (defined as increased serum TSH)- 10% and Hyper (decreased TSH) – 2%. Further, a retrospective study revealed that a substantial proportion of inpatients (45%) with undiagnosed thyrotoxicosis received IV ICM prior to endocrine evaluation [32]. These results suggest that an aggressive case-finding approach, based on identifying those persons most likely to have TD prior to ICM examinations might be beneficial [33].
Several risk factors have been associated with ICM-induced TD (Table 2) [3, 5, 82-87]. Although ICM-induced TD can occur in any individual, it is most commonly reported in patients with an underlying thyroid disease. The most frequently reported risk factor is nodular goiter [16]. High-risk patients for ICM-induced Hyper include those with nodular goiter containing autonomously functioning thyroid tissue and/or latent Graves’ disease. ICM-induced Hypo is predominantly found in regions with sufficient iodine supply and in patients with autoimmune thyroiditis.
Risk factors for iodine-induced thyroid dysfunction
In patients at high-risk for Hyper, diagnostically equivalent alternative imaging modalities, not requiring ICM should be considered, foremost ultrasound, or much less frequently scintigraphy, MRI, or unenhanced CT. Some centers suggest that the knowledge of an existing TD (at least serum TSH) prior to a contrast-enhanced study may be helpful, especially in the elderly with underlying cardiovascular diseases. However, the benefits of TSH screening in high-risk patients have not been demonstrated so far. Moreover, a normal baseline thyroid function does not exclude the development of TD after ICM exposure [34]. It may be explained by the fact that many patients with autonomously functioning thyroid nodules may have a normal serum TSH value [35].
Recommendations
2. Prior to ICM exposure, we suggest a thorough case-finding approach, based on identifying those persons most likely to have undiagnosed TD. 2, ØØOO
3. We suggest measurement of baseline serum TSH in high-risk patients for ICM-induced TD, especially in the elderly and subjects at risk for cardiovascular diseases. If serum TSH is abnormal, thyroid hormones (T3 and/or T4) should be measured. 2, ØOOO
Is Baseline TD a Contraindication to ICM Administration?
OHyper is generally considered to be a contraindication to radiological examinations using ICM (as stated in the drug insert) and whenever possible the search for alternative imaging modalities is recommended. In case of emergency/no alternative radiological modality is possible; treatment with antithyroid drug (ATD) should be initiated prior to radiological study using ICM (combination therapy with ATD and perchlorate may be considered in selected cases). The European Society of Urogenital Radiology questionnaire for ICM administration, which should be completed by the referring clinician, includes a question about Hyper (http://www.esur.org/esur-guidelines/). However, the effect of ICM administration in patients with untreated OHyper and in patients treated with ATD is unpredictable, and in severe cases, it may lead to life-threatening complications (online suppl. Table 2) [36-38]. On the other hand, ICM administration does not always lead to exacerbation of OHyper [30].
Patients with persistent endogenous SHyper should be diagnosed and managed according to the international/local guidelines [25]. Establishing the etiology of persistent SHyper is important in risk stratification of ICM-induced Hyper. Patients with pre-existing functional thyroid autonomy by scintigraphy using Tc-99m-pertechnetate/iodine-123 are at risk of developing OHyper, whereas patients with SHyper without thyroid autonomy have a negligible risk of ICM-induced Hyper [39]. Prior to both, elective and emergency radiological studies, an endocrinologic consultation and initiation of preventive medication may be considered.
Baseline subclinical Hypo (SHypo) and OHypo are not a contraindication to ICM administration. Patients with OHypo and SHypo should be diagnosed and managed according to the local guidelines [21, 22]. Due to possible exacerbation of Hypo, close monitoring may be advised in selected patients after ICM administration.
Recommendations
4. We do not recommend radiological examinations using ICM in patients with OHyper. Alternative imaging procedures (e.g., ultrasound, MRI, noncontrast CT) should be considered. 1, ØØOO
5. Persistent endogenous SHyper is not a contraindication to radiological examinations using ICM. Prior to elective radiological studies, we recommend to establish the etiology of SHyper. Endocrine consultation may be advised. 1, ØØØO
6. Baseline untreated SHypo and OHypo are not a contraindication to ICM administration. Due to possible exacerbation of Hypo, close monitoring after ICM is suggested in selected patients. 2, ØØOO
7. Patients on thyroid hormone replacement are not at risk for ICM-induced TD and do not require specific management. 1, ØOOO
Should High-Risk Patients for ICM-Induced Hyper Receive Prophylactic Treatment before a Radiological Examination?
The management of patients with a high risk for ICM-induced Hyper (especially patients with persistent endogenous SHyper) remains controversial [20]. After ICM administration, clinical symptoms of Hyper and/or thyroid function tests should be monitored. It is debated whether short-term pretreatment with ATDs (inhibition of thyroid hormone synthesis) and/or perchlorate (inhibition of iodine uptake) is justified to decrease the risk of incident thyrotoxicosis.
Only a few prospective studies (including only one randomized clinical trial) on efficacy of prophylactic treatment exist, most of these were performed in Germany and Austria. Short-term therapy with 60 mg of methimazole and 1 g of sodium perchlorate (24 h before and on the day of coronary angiography) led to a reduced iodine load of the thyroid when monitored by scintigraphy and urine iodine excretion 4 and 12 weeks after angiography. One of 27 (3.7%) treated patients versus 3 of 33 (9%) control patients developed Hyper [40]. These results are in line with other findings [41] that intrathyroidal iodine concentration (by means of X-ray-fluorescence-analysis) did not change in the group of volunteers on perchlorate medication after ICM administration. The protective effect of a monotherapy with either 20 mg of methimazole per day or 900 mg of perchlorate per day (starting 1 day before coronary angiography and lasting for 14 days) was studied in 51 patients with endogenous SHyper with functional thyroid autonomy [42]. Although mild OHyper occurred in both treatment and control groups (2 in the control group vs. one in each of the treated groups), the authors observed stable serum TSH, FT4, FT3 levels, normal iodine urine excretion, and normal thyroid uptake 30 days after ICM administration in the treated groups. These results were confirmed in 19 patients undergoing coronary angiography, with endogenous SHyper and functional thyroid autonomy, who were treated with perchlorate alone (900 mg/day, divided into 3 doses, for 2 weeks) or combined with methimazole (20–60 mg for 1–2 weeks). Mild Hyper was observed in 2 out of 19 patients, whereas in the remaining 17 patients, thyroid hormones (FT4 and FT3) levels decreased and TSH levels increased 28 days after coronary angiography [39].
The results of studies analyzing the prophylactic treatment prior to ICM administration in high-risk patients are shown in Figure 1. The treatment may be effective in reducing iodine load of the thyroid, stabilizing the thyroid function, and blunting/preventing ICM-induced OHyper. On the other hand, both drugs (methimazole and perchlorate) have a significant rate of side effects. Unfortunately, the prophylactic treatment does not prevent ICM-induced Hyper in all cases. Most importantly, an in-depth analysis of relevant short- and long-term clinical measures of therapeutical success besides surrogate markers (serum thyroid hormone levels, iodine urine excretion, and iodine thyroid uptake) is missing. Therefore, the final decision should be individualized with respect to pre-existing thyroid diseases, coexisting morbidities (especially cardiovascular diseases), patient’s age, iodine intake, and the need to perform radioiodine (RAI)-based studies.
The published treatment protocols vary substantially. The Austrian Thyroid Association recommends using perchlorate as preventive treatment (600 mg prior to examination and continuation with 3 × 300 mg daily for 7–14 days) in high-risk patients before emergency studies [43]. Prior to ICM exposure, a consultation in a Thyroid Clinic is advised. In many countries, the following ATD regimen is used: methimazole 20–30 mg daily, starting the day before ICM administration and continuing for 14 days [2]. A few authors suggested that a combination therapy of methimazole and perchlorate may be more effective [34, 42].
Recommendations
8. We do not recommend prophylactic treatment in all patients at high-risk for developing ICM-induced Hyper. However, patients at risk for Hyper should be monitored after ICM injection. 1, ØØOO
9. We suggest considering prophylactic treatment with methimazole and/or perchlorate before emergency radiological examinations in selected patients who are less tolerant to the effects of ICM-induced Hyper, for example, elderly with persistent endogenous SHyper and/or nodular goiter, and/or concomitant cardiovascular disease, especially in areas of iodine deficiency. 2, ØØOO
Monitoring of Patients after Radiological Examinations Using ICM
Does ICM Exposure Affect Thyroid Function Tests in Euthyroid Subjects?
The most rapid (hours to days) effect of pharmacologic doses of iodine is to inhibit organification of iodide, thereby diminishing hormone biosynthesis (Wolff-Chaikoff effect) and decreasing thyroglobulin proteolysis, thereby decreasing thyroid hormone secretion [3, 5]. The resulting small decrease in serum T4 and T3 levels causes a compensatory, transient increase in TSH concentrations [44, 45]. After the acute phase, normal thyroid hormone synthesis resumes, even with continued excess iodide exposure, a phenomenon described as the escape from the acute Wolff-Chaikoff effect. However, weeks after ICM exposure, several prospective observational studies revealed an increase or decrease in serum TSH, FT4, and FT3 levels, dependent probably on the iodine intake and pre-existing thyroid disease [46]. While these changes are within the reference and in most untreated cases, they may interfere in the proper interpretation of thyroid function tests [47].
Recommendations
10. ICM administration may cause transient changes in serum TSH, T4, and T3 levels in healthy individuals, usually within the reference values. While interpreting thyroid function tests, we suggest taking ICM exposure (within the last 1–3 months) into consideration. 2, ØØØO
Should Thyroid Function Be Monitored after ICM Administration?
There is no indication for routine monitoring for ICM-induced TD because this would not be cost-effective [13, 14]. Therefore, all patients should be informed that signs and symptoms of Hyper or Hypo may occur after ICM administration and should be advised to alert the medical team if such develop.
Routine thyroid function testing is favored by a few experts in older patients with a high risk of ICM-induced Hyper and patients with an underlying unstable cardiovascular disease. In such cases, measurement of serum TSH (and if low, T4 and T3) 3–4 weeks after ICM exposure is advised. Routine screening for ICM-induced Hypo may be also considered in selected high-risk patients, especially in women planning pregnancy after hysterosalpingography with oil-soluble ICM and in neonates [48-50].
Recommendations
11. We do not recommend routine TSH monitoring following ICM administration. 1, ØØØO
12. The exact timing of the ICM-TD is often unpredictable. We suggest advising patients to alert the medical team if they develop signs and symptoms of TD. 2, ØOOO
13. We suggest measuring thyroid function 3–4 weeks after ICM exposure in high-risk patients for ICM-induced Hyper, especially in the elderly and/or those with an underlying unstable cardiovascular disease. 2, ØØOO
When can Isotope Imaging of the Thyroid or RAI Treatment Be Performed after ICM Exposure?
The administration of ICM is known to suppress thyroidal RAI uptake, lasting for several weeks [51]. Some studies on urinary iodine secretion after ICM administration for outpatient CT scans indicate that 75% of patients’ values returned to baseline within 5–6 weeks and 90% within 11 weeks [46, 52]. A study performed in post-thyroidectomy patients requiring RAI treatment demonstrated that 1 month is sufficient for urinary iodine to return to its baseline value after the use of ICM [53]. These results may be used to guide the timing of RAI treatment as well as diagnostic scintigraphy with radioactive iodine or Tc-99m-pertechnetate following contrast exposure. The American Thyroid Association Management Guidelines for Adult Patients with Thyroid Nodules and Differentiated Thyroid Cancer (2015) state that concerns about iodine burden from IV contrast agents causing a clinically significant delay in subsequent whole-body scans or RAI treatment post-thyroidectomy is generally unfounded [54]. In doubtful situations, a spot or 24-h urinary iodine level may be checked before isotope studies. It should be remembered that oil-soluble ICM circulates for longer than other water-soluble media [48, 55, 56].
Recommendations
14. We recommend avoiding isotope imaging of the thyroid and radioactive iodine treatment for one to 2 months after ICM injection. 1, ØØØO
Diagnosis and Management of ICM-Induced Hyper
Establishing the Diagnosis and Etiology of ICM-Induced Hyper
Generally, the diagnosis of ICM-induced Hyper is based on: (i) the clinical manifestations of Hyper, (ii) laboratory findings, and (iii) history of ICM exposure. Although ICM-induced Hyper may occur up to 1 year after a radiological examination with ICM [13, 16], the majority of patients develop symptoms and/or signs of Hyper within 3–10 weeks after exposure [30]. The severity of ICM-induced Hyper is unpredictable. The majority of patients remain oligo- or asymptomatic. However, the consequences of even mild ICM-induced Hyper should not be underestimated in geriatric patients and in patients with unstable cardiovascular status; it can aggravate pre-existing cardiac diseases leading to atrial fibrillation, congestive heart failure, worsening of angina pectoris, and thromboembolism [57-59, 92-98]. Finally in rare cases, ICM exposure may lead to thyroid storm [36-38] (online suppl. Table 2).
The diagnosis of Hyper is confirmed by thyroid function tests (TSH, FT4 and TT3 or FT3). In most patients, the history of ICM exposure is apparent. In doubtful situations, checking urinary iodine concentration (spot or 24-h sampling) may be helpful to support iodine excess as the cause of Hyper and to monitor treatment.
ICM-induced Hyper is not a single etiological entity [3, 5]. It is generally accepted that ICM-induced Hyper can develop due to pre-existing areas of functional autonomy within the thyroid. Upon exposure to excess iodine, the autonomous areas produce thyroid hormone in excess and independent of autoregulatory mechanisms (the Jod-Basedow phenomenon). The most important risk factors include nodular thyroid disease (most common cause), latent Graves’ disease, and long-standing iodine deficiency. Very rarely, ICM-induced Hyper has been reported in patients without underlying thyroid disease (ICM-induced thyroiditis) [60]. Moreover, other causes of Hyper must also be considered, since Hyper may not be related to the iodine exposure. Therefore, an evaluation to determine the etiology of Hyper is important based on international/local guidelines [25, 27]. Diagnostic serological and imaging testing can include the following, depending on available expertise and resources: (i) measurement of TSH-receptor antibodies [61, 62], (ii) thyroid ultrasonography assessing nodularity, echogenicity of the parenchyma, and blood flow, and (iii) thyroid scintigraphy. The results of a RAI or 99m-pertechnetate thyroid scan (which is in other clinical settings the gold standard for differential diagnosis between hyperfunctioning thyroid tissue and thyroid cell destruction) should be interpreted here with caution because a low isotope uptake may be seen up to 2 months after ICM exposure. However, a single ICM exposure rarely reduces the uptake to <1% as it occurs in patients with destructive or painless thyroiditis [26, 63].
Recommendations
15. We recommend evaluating patients with newly diagnosed Hyper concerning possible previous radiological examinations using ICM in the last 2–3 months, because it may influence diagnosis (e.g., interpretation of thyroid scintigraphy), prognosis, and treatment. 1, ØØØO
16. We recommend that serum TSH should be measured as an initial screening in patients with a suspicion of ICM-induced Hyper. If serum TSH is low, thyroid hormones (T4 and T3) should follow. 1, ØØØØ
17. If the diagnosis of ICM-induced Hyper is not apparent based on the clinical presentation, we suggest analyzing urinary iodine concentration to support iodine excess as the cause of Hyper and to monitor treatment. 2, ØØOO
18. We recommend determining the etiology of ICM-induced Hyper. Diagnostic testing can include the following: measurement of TSH-receptor antibody, thyroid ultrasound, and/or thyroid scintigraphy. 1, ØØOO
What Is the Management of ICM-Induced Hyper?
In the absence of prospective clinical trials on the management of ICM-induced Hyper, an individualized approach to treatment must be advised, based on: (i) the clinical symptoms, etiology, and severity of Hyper and (ii) patients’ age, concomitant diseases (especially cardiovascular diseases), and clinical status. The clinical course of ICM-induced Hyper is unpredictable. It is most often mild and self-limited, but occasionally it may lead to clinically significant thyrotoxicosis lasting more than 12 months. Large toxic nodular goiter and Graves’ disease may be associated with a more severe course of disease.
Patients with oligo- or asymptomatic SHyper and OHyper should be treated according to local guidelines [23, 25]. Initial management includes close monitoring and avoidance of further excess iodine exposure. Thyroid function should be retested within 2–8 weeks to determine if the ICM-induced Hyper spontaneously resolves. The symptoms of adrenergic hyperactivity (tachycardia, palpitations, tremor, anxiety, etc.) may be improved through administration of β-blocking drugs (nonselective or cardio-selective depending on the clinical setting). Severe ICM-induced Hyper is best treated by ATD (methimazole, carbimazole, or propylthiouracil) in addition to β-blocker. The iodine-loaded thyroid gland may be less responsive to ATD; in such cases, higher doses of ATD (in rare cases up to 40–60 mg/day of methimazole or equivalent doses of propylthiouracil) and/or sodium perchlorate (in rare cases up to 4 weeks course at doses not exceeding 1 g/day) may be useful in accelerating control of Hyper [26, 63]. Patients who develop severe iodine-induced OHyper should be referred to endocrinologists because the management of this condition can be challenging. Many patients with underlying autonomous nodular thyroid disease are able to taper and discontinue ATD within 6–12 months. Urinary iodine may be monitored to assess the rate of clearance of the iodine load. After resolution of the acute episode of ICM-induced Hyper, treatment of the underlying thyroid disease, if any, should be addressed.
Recommendations
19. We recommend an individualized approach to the treatment of ICM-induced Hyper, based on: (i) clinical symptoms, etiology, and severity of Hyper and (ii) patients’ age, concomitant diseases (especially cardiovascular diseases), and clinical status. 1, ØØOO
20. In most mild cases, we recommend close monitoring, avoidance of further excess iodine exposure, and administrating β-blocking drugs. 1, ØØOO
21. In severe cases, we recommend initiation of treatment with ATD (methimazole, carbimazole, or propylthiouracil). In cases of partial response to ATD, a combination with perchlorate is helpful to control Hyper. 1 ØOOO
What Are the Recommendations for Geriatric Patients?
ICM-induced Hyper is particularly important in geriatric patients for several reasons:
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The prevalence of thyroid nodular disease increases with age, especially in regions with present or past iodine deficiency. In the elderly population, ICM-induced Hyper may be the first presentation of a previously asymptomatic multinodular goiter.
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Nowadays, elderly patients are more often exposed to radiological studies using ICM than in the past because of major technological advances and increased longevity.
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Hyper in the elderly is more likely to be undiagnosed prior and after ICM-exposure due to the nonspecific nature of the rather few symptoms particularly in the presence of cognitive impairment.
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The number of clinical signs found in the older subjects is significantly fewer than the number found in younger patients. The most common signs associated with thyrotoxicosis in older people include tachycardia, apathy, fatigue, and weight loss [64, 65].
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Geriatric patients are less tolerant to the effects of thyrotoxicosis because of underlying heart disease. Moreover, symptoms and signs of heart failure and atrial fibrillation may dominate the clinical picture [25, 57, 58, 66, 67].
Although randomized clinical trials are pending, in geriatric patients a more aggressive approach pertaining to the prevention of ICM-induced Hyper, early diagnosis and treatment, especially in areas of iodine deficiency is suggested. Furthermore and in accordance with the ETA guidelines, even mild ICM-induced SHyper should be treated in patients over 65 years, particularly in the presence of comorbidity, for example, heart disease, diabetes, renal failure, and previous stroke [25].
Recommendations
22. We recommend that even mild ICM-induced Hyper should be treated in patients older than 65 years, particularly in the presence of comorbidity. 1, ØØØO
Diagnosis and Management of ICM-Induced Hypo
Establishing the Diagnosis and Etiology of ICM-Induced Hypo
The diagnosis of ICM-induced Hypo is based upon: (i) the clinical manifestations of Hypo, (ii) laboratory findings, and (iii) history of ICM exposure. The induction of OHypo appears to be rare and the exact timing of the event is unpredictable, ranging from days to up to 2 years after ICM exposure [13, 14, 17, 18]. Because of the wide vulnerable time window (from ICM exposure to development of Hypo), general monitoring of thyroid function tests in high-risk patients for Hypo is not advisable. Therefore, all patients should be informed to alert the medical team if signs and symptoms of Hypo occur after ICM administration.
The diagnosis of SHypo and OHypo is confirmed by thyroid function tests (TSH and T4 ). The relationship between Hypo and ICM exposure may be difficult to demonstrate because the urine iodine concentration may be no longer increased.
ICM-induced Hypo is thought to result from a failure to escape the acute Wolff-Chaikoff effect [3, 5, 68]. It is predominantly found in iodine-replete regions. Although ICM-induced Hypo may occur in patients with an apparently normal thyroid gland, most frequently it develops in patients with underlying autoimmune thyroiditis. However, a wide variety of thyroid and nonthyroid diseases were associated with Hypo after ICM exposure (Table 2), and the possible etiology of Hypo should be established [21, 22]. Measurement of serum antithyroid peroxidase antibodies is the most sensitive serological test for the diagnosis of autoimmune thyroiditis.
Recommendations
23. We recommend that serum TSH should be measured as an initial screening test in patients with a suspicion of ICM-induced Hypo. If serum TSH is high, serum T4 levels should be measured. 1, ØØØØ
24. We recommend measurement of serum thyroid peroxidase antibodies if the etiology of ICM-induced Hypo is unclear. 1, ØØOO
25. We suggest evaluating patients with newly diagnosed Hypo concerning previous radiological examinations using ICM (in the last 1–2 years), since spontaneous remission might occur over time, without the need for lifelong temporary levothyroxine (LT4) treatment. 2, ØOOO
What Is the Management of ICM-Induced Hypo?
There are no prospective clinical trials on the management of ICM-induced Hypo, which is usually self-limiting [56, 68]. However, the time to recovery may vary from several weeks up to several months. Prolonged ICM-induced Hypo may be observed in patients, in whom iodine excess is not rapidly eliminated from the body (e.g. repeated exposure to excess iodine, the use of oil-soluble ICM, and renal failure). In rare cases, ICM-induced Hypo may be permanent.
Most patients do not require thyroid hormone replacement and TSH should be retested after 4–8 weeks. LT4 treatment may be considered based on individual patient factors, including: younger age, symptoms of Hypo, presence of an autoimmune thyroid disease, and comorbidities. ICM-induced Hypo in pregnant women or women planning pregnancy should be treated as all other forms of Hypo [21]. After a few months, LT4 treatment may be tapered to determine if ICM-induced Hypo has resolved. However, patients with underlying thyroid disease, who develop transient ICM-induced Hypo, are at risk for permanent Hypo in the future.
Recommendations
26. We recommend an individualized approach to the treatment of ICM-induced Hypo, based on: (i) clinical symptoms, etiology and severity of Hypo, and (ii) patients’ age, concomitant diseases, and clinical status. 1, ØØOO
27. In most cases of ICM-induced Hypo, we suggest close monitoring without thyroid hormone replacement. Temporary LT4 treatment may be considered in younger patients with symptoms of Hypo, with an underlying chronic autoimmune thyroiditis, and in women planning pregnancy. 2, ØØOO
What Are the Recommendations for the Elderly?
Old age was shown to be correlated with the risk of ICM-induced Hypo. High-risk elderly patients for ICM-induced Hypo should be carefully evaluated after radiological examination with ICM because OHypo in these patients is usually oligosymptomatic. Moreover, most common symptoms are nonspecific (e.g. tiredness, shortness of breath, depression, and cognitive changes), while the more classical Hypo-associated symptoms may be absent [69, 70]. On the other hand, elderly hypothyroid patients are also more sensitive to exogenous thyroid hormones. If needed, LT4 replacement should be started at lower doses and titrated as per response to avoid overtreatment [21, 22, 26].
Recommendations
28. Elderly patients with ICM-induced SHypo should be carefully followed, generally avoiding levothyroxine treatment. 2, ØØOO
What Are the Recommendations for Infants?
Premature infants and neonates might be particularly susceptible to the development of ICM-induced Hypo because the immature gland may not be able to fully escape from the acute Wolff-Chaikoff effect [49]. In 2015, the US Food and Drug Administration issued a safety announcement regarding 10 cases of ICM-induced Hypo in infants younger than 4 months, reported between 1969 and 2012. In all cases, the infants were either premature or had serious cardiac abnormalities. Hypo occurred within 1 month after receiving ICM. Four of the 10 infants received LT4 treatment for up to 10 months, while others improved without treatment. Based on these observations, health-care professionals were advised to use clinical judgment to determine whether testing for Hypo might be necessary after ICM exposure (https://www.fda.gov/drugs/drug-safety-and-availability/fda-drug-safety-communication-fda-advises-rare-cases-underactive-thyroid-infants-given-iodine.)
However, prevalence, severity, and duration of ICM-induced Hypo in neonates remain largely unknown. A systemic review, including eleven studies (182 neonates) attempted to determine the risk of Hypo after ICM exposure, found inconsistent results for term infants (one study did not show an increased risk, while another did find a trend towards increased TSH levels and decreased FT4 levels) [71]. In contrast, studies including premature infants found trends toward increased serum TSH, decreased T3 and FT4, and the need for LT4 treatment (8.3% of the term infants and 18.3% of the premature infants were treated for ICM-induced Hypo). Unfortunately, all studies included in the systemic review were highly affected by bias [71]. In contrast, mild, transient, neonatal Hypo was seen following exposure to iodine via caesarean section but not via exposure to contrast media [72]. Only one prospective randomized study has compared thyroid function tests in preterm neonates exposed to ICM with controls after peripherally inserted central catheter (PICC) at day 14 post PICC insertion or on day 28 of life. The results suggested that 0.3 mL of iodine-containing contrast material could be administered to extreme preterm neonates for better PICC tip visualization without causing Hypo [73].
The most frequently reported risk factors for ICM-induced Hypo (especially in preterm neonates) are: underlying congenital cardiac malformations, impaired renal function, and multiple radiological examinations [74]. Clinically, significant OHypo may occur after various radiological examinations using ICM [75-78]. In addition, there have been cases of transient fetal goiter or transient neonatal Hypo due to preconception or postnatal maternal exposure to ICM [79, 80]. However, a recent retrospective study suggested that preconception hysterosalpingography did not influence the neonatal thyroid function [50].
Although ICM-induced Hypo is likely transient and of short duration, its effects on the developing neonatal brain may be harmful. Until more evidence is available, we suggest careful monitoring of thyroid function tests in infants after maternal or neonatal ICM exposure, with a special attention to premature infants. ICM-induced Hypo in newborns should be treated according to local guidelines [81].
Recommendations
29. We suggest careful monitoring of thyroid function tests in infants after maternal or neonatal ICM exposure, with a special attention to premature infants. 2, ØØOO
Conclusions
Evidence in the field of ICM-induced TD is scarce, resulting in the majority of cases in weak recommendations predominantly based on low or very low-quality evidence, which are summarized in Table 3. Although most cases of ICM-induced Hyper are mild and transient, there is a small risk of severe thyrotoxicosis with serious cardiovascular complications, especially in elderly patients. On the other hand, the fetus and neonate may be susceptible to developing clinically significant Hypo after maternal or neonatal ICM exposure. An individualized approach to prevention and treatment of ICM-induced TD is advised, based on patient’s age, clinical symptoms of TD, pre-existing thyroid diseases, coexisting morbidities, and iodine intake. Additional clinical trials with clinically relevant endpoints are warranted to further aid in clinical decision-making in patients with ICM-induced TD.
Summary of recommendations
Acknowledgements
The task force wishes to thank the ETA Guidelines and Publications Board for their constant help and support, as well as ETA members (Professor Paolo Beck-Peccoz, Professor Bekir Cakir, Dr Oana Capraru, Professor Alicja Hubalewska-Dydejczyk, and Professor Anders Karlsson) for their thoughtful suggestions. The authors would also like to thank Dr Justyna Milczarek-Banach for her help in editing the reference list.
Conflict of Interest Statement
T.B. has received speaker honoraria from Berlin-Chemie/Menarini, Ipsen, Merck, and Novartis. He has been a consultant for Ipsen and Merck. T.H.B. has no conflicts of interest to declare. W.S. has received speaker honoraria from Siemens Healthineers and GE Healthcare. G.Z. is shareholder of Piur Imaging GmbH and ZM Sono GmbH and has received speaker honoraria from Genericon Pharma. The Johannes Gutenberg University (JGU) Medical Center, Mainz, Germany, academic institution of G.J.K. has received research-associated funding from the JGU Medical Faculty, AdvanceCor (Germany), Apitope (Belgium), Horizon (USA), Immunovant (USA), ISAR (Germany), Mediomics (USA), Merck (Germany), Novartis (USA), Quidel (USA), River Vision (USA), Roche (Switzerland), and Byondis (The Netherlands). G.J.K. consults for Immunovant, Mediomics, Merck, Novartis, and Quidel.
Funding Sources
No funding was received to support this work.
Author Contributions
All the authors contributed to the idea, gathered the information, interpreted the data, and wrote and accepted the final version of the manuscript.
Footnotes
verified
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