Journal List > Int J Thyroidol > v.12(1) > 1126566

Yoo and Choi: Ultrasonographic Characteristics of the Hyperfunctioning Thyroid Nodule and Predictive Factors for Thyroid Stimulating Hormone Suppression

Abstract

Background and Objectives

Thyroid scan is a good tool for diagnosis of hyperfunctioning thyroid nodules (HNs), however it has been limited in use in a primary clinical practice, because of its inconvenience and low accessibility. This study aimed to analyze ultrasonographic (US) characteristics of HNs and to predict HNs by US.

Materials and Methods

We included 114 patients who exhibited results of ‘hot’ nodule in the thyroid scan from 2008 to 2017. Analysis for US characteristics included 73 patients without unclear US images and other inevitable reasons. We compared US characteristics of HNs with cold nodules that showed “cold” in the thyroid scan. Additionally, we compared US characteristics of HNs between suppressed thyroid-stimulating hormone (TSH) (<0.25 uIU/mL) or normal TSH, and analysis receiver operating characteristics (ROC) curve for prediction of suppressed TSH among HNs.

Results

The HNs showed more partially cystic nodule, isoechoic echogenicity, hypervascularity and presence of halo in the US finding than the cold nodule. In subgroup analysis of nodules with TSH suppression among HNs, the TSH suppression nodules was lager in max size and volume than the normal TSH nodules. In ROC analyses for prediction of the TSH suppression among HNs, area under receiver operating characteristics curves was 0.736 in max size, 0.761 in volume.

Conclusion

HNs showed more frequently partially cystic contents, isoechoic echogenicity, hypervascularity, and peripheral halo sign in US finding. Thyroid nodule size and volume were associated with suppressed TSH level of HNs, and optimal cutoff levels for prediction of TSH suppression among HNs were 2.6 cm and 1.13 cm3, respectively.

Introduction

Hyperfunctioning thyroid nodules (HNs) are defined as nodules that grow and produce thyroid hormone independently of thyroid-stimulating hormone (TSH).123) HNs can only be diagnosed on thyroid scan and appear as “hot spots” that can be differentiated from surrounding normal thyroid tissue.4) However, physicians in primary clinics cannot diagnose HNs easily because thyroid scans are inconvenient to perform and are limited in access.
Thyroid ultrasonography (US) is widely available, has high accessibility, poses no radiation hazards, and can clearly differentiate thyroid nodules.5) Therefore, thyroid US is most frequently used to diagnose thyroid nodules.123) If the ultrasonographic characteristics of HNs can be clarified to enable prediction of HNs, US would be useful in diagnosing and managing thyroid nodule with TSH suppression, especially in primary care settings where thyroid scan is not available. However, a few studies have accurate analyzed US characteristics of HNs.67) For this reason, it was necessary to identify the US characteristics of HNs and to analyze the characteristics of the nodule with TSH suppression.
We examined the differences in clinical and sonographical characteristics between HNs and cold nodules on thyroid scan. And the clinical and US characteristics associated with TSH suppression were analyzed, among patients with HNs. As a results, we aimed to describe the usefulness of US in the diagnosis for HNs.

Materials and Methods

Subjects

Among 114 patients with HNs who exhibited “hot” and “hyperfunction” results on thyroid scan imaging between 2008 and 2017, 73 were included in the analysis. Forty-one patients were excluded for the following reasons: no thyroid US was conducted within 3 months before or after the scan; the location of the nodule seen on the scan and the US did not agree (left/right and upper/mid/low); when multiple nodules did not have clear boundaries, or when the nodule was not clear on US; a history of thyroid surgeries; and patients taking anti-thyroid drugs or positive for anti-TSH receptor antibody. Additionally, 13 patients with multi-nodular goiter were excluded in a further analysis investigating the effect of TSH suppression, because multiple nodules can influence TSH levels (Fig. 1). As a control group, 188 patients with “cold” nodules on thyroid scan imaging were included in the analysis to compare differences in clinical and US findings. Electronic medical records and US findings were retrospectively reviewed. Institutional Review Board approval was obtained for this study (2018-04-009).

Thyroid Scan and the Definition of HN

Using a single-head gamma camera (LEM Plus, Siemens, Erlangen, Germany) equipped with a pinhole collimator, thyroid scans in the anterior view were acquired 20 min after intravenous administration of 185 MBq of Tc-99m-pertechnetate. For imaging, patients were placed in the supine position with their neck extended; marking sources for size measurements were located on both lateral sides of the neck. HNs were defined as nodules that demonstrated greater tracer uptake than the surrounding normal thyroid tissue, and could be differentiated from the thyroid parenchyma. In cases of multi-nodular goiter on scanning, representative nodules with the clearest boundary were selected and analyzed using US.

Thyroid US and Classification of Thyroid Nodules

In all cases, the sonographic images included both transverse and longitudinal real-time imaging of thyroid nodules using PACS (Picture Archiving Communications System, TechHeim, Seoul, Korea). All US images were obtained using an HDI 5000 system (Philips Medical Systems, Bothell, WA, USA) equipped with 7.5 to 12 or 8 to 15 MHz linear transducers. One endocrinologist, with 10 years' experience in thyroid US, reviewed thyroid nodule characteristics including location, size, volume (width×length×height×0.52), shape, margin, content, echogenicity, calcification, presence of halo, and vascularity according to previous recommended terminology.8) Depending on the nodule contents, the nodules were classified as solid, predominantly solid (>50% solid for a mixed nodule), predominantly cyst (>50% cyst for a mixed nodule), and pure cyst. Nodular shapes were classified as ovoid, round, TDW (when the anteroposterior diameter of the nodule was longer than its transverse diameter on a transverse or longitudinal plane), or irregular (when a nodule was neither ovoid to round nor TDW). Nodular margins were categorized as smooth, spiculated (obviously discernible, but not-smooth edge showing speculation, microlobulation), ill-defined margin (poorly demarcated margin which cannot be obviously differentiated form adjacent thyroid tissue). Echogenicity of the nodules was classified as hypoechoic (hypoechoic relative to thyroid parenchyma), isoechoic (same echogenicity as that of thyroid parenchyma), or hyperechoic (hyperechoic relative to thyroid parenchyma). Each nodule was also classified as showing microcalcification (echogenic foci of 1 mm or less), macrocalcification (when punctuate echogenic foci were larger than 1 mm in size), or rim calcification (peripheral curvilinear echogenic rim). Nodular echotexture was determined to be homogeneous or heterogeneous. Nodular vascularity was classified as none (absence of intranodular or perinodular vascularity), internal (intranodular vascularity without perinodular vascularity), peripheral (presence of circumferential vascularity at margin of nodule), or both (intranodular vascularity with perinodular vascularity) by assessed Doppler. The presence of a halo (thin or thick hypoechoic rim surrounding nodule) was also noted.8)
The malignancy risk for each thyroid nodule was classified according to the malignancy risk criteria published by the American Thyroid Association (ATA).1) When fine-needle aspiration (FNA) or surgeries were performed, the results of aspiration and the final surgical outcomes were verified.

Thyroid Function and TSH Receptor Antibody Tests

Serum TSH concentrations (reference range, 0.25–4 uIU/mL [lower detection limit, 0.03 uIU/mL]) were measured using an immunoradiometric assay (RIA-gnost rhTSH, cisbio bioassays, France). TSH suppression was defined as HNs with lower TSH levels than the low-normal reference level (TSH <0.25 mIU/mL). The serum levels of free T4 (normal range, 0.78–1.94 ng/dL) were measured using an fT4 radioimmunoassay (RIA) kit (fT4-CTX, DiaSorin S.p.A.). The serum levels of total T3 (reference range, 80–100 ng/dL) were measured using an RIA kit (T3-CTK, DiaSorin S.p.A.). TSH receptor antibody levels were determined using the B.R.A.H.M.S. TRAK human RIA kit (B.R.A.H.M.S. GmbH, Hennigsdorf/Berlin, Germany) according to manufacturer's instructions. TSH receptor antibody levels ≥1.5 IU/L were considered to indicate positive results.

Subgroup Analysis According to TSH Suppression among HNs

For subgroup analysis according to TSH suppression, two group were classified based on TSH <0.25 mIU/mL. We compared US finding, age, sex, thyroid function test between the two groups. On the assumption that TSH decreases as the size of nodule increases in HNs, receiver operating characteristic (ROC) curve analysis was performed to measure the cut-off values for the size and volume of nodules to predict TSH suppressed HNs.

Statistical Analysis

All statistical analyses were performed using SPSS version 16.0 (IBM Corporation, Chicago, IL, USA) for Windows (Microsoft Corporation, Redmond, WA, USA). The Student's t test was used for comparisons involving continuous variables, and chi-squared tests and Fisher's exact tests were performed for categorical variables. For subgroup analysis according to TSH suppression, the Student's t-test was used for comparison of continuous variable, and chi-squared test for categorical variables between groups. p<0.05 was considered to be statistically significant. ROC curve was drawn to measure the cut-off values for the size and volume of nodules to predict TSH suppressed among HNs.

Results

Comparison of Clinical Characteristics between HNs and Cold Nodules

There were no significant differences in age and female proportion between patients with HNs and those with cold nodules (Table 1). The mean TSH level was lower in patients with HNs than in those with cold nodules (0.82±0.85 uIU/mL vs. 2.15±4.94 uIU/mL, respectively; p=0.025). However, there were no differences in free T4 and total T3 levels between the groups.

Comparison of US Features between HNs and Cold Nodules

Both nodule size and volume were not different between the two groups; there were also no differences in the location of thyroid nodules (Table 1). HNs exhibited partially solid or cystic features more frequently than cold nodules (50.7% vs. 33.0%, respectively; p= 0.004). Suspicious features, including nodule shape, “irregular,” and “taller than wide” were more frequently observed in cold nodules than in HNs (17.6% vs. 5.5%, respectively; p=0.010). In particular, the “taller than wide” shape was not observed in HNs. The proportion of nodules with hypo-echogenicity (p< 0.001) and internal calcification (p=0.019) were higher in cold nodules than in HNs, with a difference that was statistically significant. Internal or peripheral hypervascularity was observed in 95.8% of HNs compared to 44.8% of cold nodules (p<0.001). Peripheral halo was observed more frequently in HNs than in cold nodules (37.0% vs. 21.3%, respectively; p=0.009). However, there were no significant differences in nodule margin and echotexture between the groups. According to the malignancy risk stratification from the ATA guideline, cold nodules exhibited a higher frequency of cases with “highly suspicious” or “intermediate suspicious” categories than HNs. In particular, there were no cases of the “highly suspicious” category in HNs.

Comparison of FNA Results or Surgery between HNs and Cold Nodules

FNA was performed in 66 of 73 HNs, and evaluated according to the Bethesda classification.9) Of the 66 HNs that underwent FNA, 6 (9.2%) were nondiagnostic or unsatisfactory, 58 (87.9%) were benign, 1 (1.5%) was atypia of undetermined significance (AUS) or follicular lesion of undetermined significance (FLUS), and 1 (1.5%) was suspicious for malignancy (Table 2). After subsequent FNA, 11 nodules underwent surgery in the authors' hospital. After surgery, 10 benign (3 follicular adenoma and 7 nodular hyperplasia) and 1 malignant (papillary thyroid carcinoma) were confirmed. One nodule was diagnosed as minimally invasive follicular carcinoma by surgery without FNA.
FNA was performed in 156 of the 188 cold nodules; of these, 14 (9.0%) were nondiagnostic or unsatisfactory, 111 (71.2%) were benign, 13 (8.3%) were AUS or FLUS, 4 (2.6%) were suspicious for malignancy, and 12 (7.7%) were malignant. The other two nodules were lymphoma and anaplastic carcinoma. After subsequent FNA, 36 nodules underwent surgery in the authors' hospital. After surgery, 23 benign and 13 malignant nodules were confirmed. The 5 subjects who were diagnosed with suspicious for malignancy or malignant in the FNA result wished to transfer to another hospital for thyroid surgery.
The number of patients with malignant thyroid nodules was 2 (2.7%) in the HN group, and 18 (9.6%) in the cold nodule group.

Comparison of Clinical and US Characteristics of HNs between Patients with Suppressed versus Normal Levels of TSH

Data from a total of 60 subjects, excluding 13 subjects with multiple nodular goiters, are shown in Table 3. According to the definition of TSH suppression (TSH <0.25 mIU/mL), 18 (30%) patients exhibited suppressed TSH levels. TSH suppressed nodules demonstrated significantly lower TSH levels, and significantly higher levels of free T4 and total T3. There were no differences in age and female proportion between the groups. TSH suppressed nodules were significantly larger (2.93±1.22 vs. 1.89±1.09 cm; p=0.002) and had a higher volume than normal nodules accompanied by normal TSH levels (9.28±9.94 vs 3.25±5.59 cm3; p=0.004) in HNs. However, there were no differences in location, content, shape, margin, echogenicity, and vascularity between HNs accompanied by suppressed or normal TSH levels.

Cut-off Values for the Size and Volume of HNs to Predict TSH Suppression

The area under the ROC curve, according to size and volume, were 0.736 (95% CI=0.664–0.879, p< 0.001) and 0.761 (95% CI=0.698–0.906, p<0.001), respectively (Fig. 2). To predict TSH suppressed HNs, the optimal cut-off value for nodule size was 2.6 cm, with sensitivity of 72.2%, specificity of 76.2%, 56.5% of positive predictive values (PPV) and 86.5 of negative predictive value (NPV). The optimal volume to predict TSH suppressed HNs was 1.13 cm3, with sensitivity of 88.9%, specificity 61.9%, 50.0% of PPV and 92.9% of NPV.

Discussion

Thyroid nodules are commonly encountered in the clinic, and US is regarded to be the most important diagnostic tool for diagnosis and management of these entities. If HNs are suspected, thyroid scans are necessary to make definitive diagnosis.123) However, thyroid scans are limited in that they cannot be easily performed in primary care settings. Our study showed that US images of HNs demonstrated higher proportions of partially cystic nodule, isoechoic echogenicity, increased vascularity, and the presence of a halo than cold nodules. Ianni et al.6) reported that HNs showed isoechoic echogenicity and the others also reported that HNs showed partially cystic contend in thyroid US.1011) Previous studies have attempted to identify HNs with other diagnostic tool, such as US-elastography12) and computed tomography (CT).13)
Guidelines recommend that patients with suppressed TSH level should be examined by thyroid scan for the differential diagnosis of HNs.2) Our results suggests the thyroid US as a tool to identify the HNs in the primary care setting, in which thyroid scan often is not available. According to our results, thyroid scan could be recommend in patients with US findings preferring to HNs, such as partially cystic, isoechoic, increased vascularity, and presence of halo.
Our study showed that HNs with suppressed TSH were significantly larger than HNs with normal TSH, corresponding to previous studies. Burch et al.14) reported that the nodule size of patients with thyrotoxicosis (3.2 cm) was greater than that of non-thyrotoxicosis patients (2.2 cm) and that six patients had experienced newly developed thyrotoxicosis during follow-up period of average 5.7 years. Additionally, a Japanese study investigating 104 patients with HNs also reported that the nodule size of patients with TSH suppression (2.4 cm) were larger than that of patients with normal TSH levels (2.3 cm).15) The close association between nodule size and degree of TSH suppression was observed well in a representative case, that a 30-year old women with a HN had showed normal TSH level for nine years, then TSH level gradually decreased as the nodule size increased (Fig. 3). We showed optimal size and volume of HNs to predict the status of suppressed TSH, using a ROC curve analysis.
In our study, according to the ATA estimated malignancy classification criteria, US images of HNs were mainly classified as “very low suspicious” or “low suspicious” categories, compared to cold nodules (75.3% and 56.9%, respectively). Interestingly, there were no HNs in high suspicion category; whereas 13.8% of cold nodules were classified into high suspicion category. Low rates of suspicious nodules in HNs are consistent with previous studies that reported very low rates of malignancy.1617) However, we found two malignancy cases (minimally invasive follicular carcinoma and papillary thyroid carcinoma) in patients with HNs. Including three patients who had incidental PTC, there were 5 (6.8%) malignancy cases in patients with HNs, corresponding to a previous study that reported malignancy rate of 6.5% of HNs.7) Because of these non-negligible proportion of malignancy of HNs, US examination might be useful in patients with HNs.
Our study has several limitations. Firstly, this study was designed as a retrospective study in a single hospital, which can lead to selection bias. Secondly, thyroid scan had low interobserver agreement rates, resulting from potential imbalance in radioiodine uptake.18) However, in our study, thyroid scan images were analyzed by one nuclear medicine specialist, which could have mitigated interobserver issues. Additionally, to mitigate this limitation, we excluded patients who have TSH receptor auto-antibodies or multi-nodular characteristics.
In conclusion, US could be a useful diagnostic for HNs in primary care settings where thyroid scan is not available. HNs are most likely to have isoechoic characteristic with mixed-type content and to show hypervascularity on US. TSH suppression is likely to be observed in large HNs larger than 2.6 cm in size or greater 1.13 cm3.

Figures and Tables

Fig. 1

Flowchart of patient enrollment in hyperfunctioning thyroid nodules.

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Fig. 2

Area under receiver operating curve (ROC) of max size and volume to predict thyroid stimulating hormone suppression in hyperfunctioning thyroid nodules were 0.736 (95% CI=0.664–0.879, p<0.001) and 0.761 (95% CI=0.698–0.906, p<0.001), respectively.

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Fig. 3

A case of hyperfunctioning thyroid nodule which showed TSH suppressed as size increased. In 2003, TSH of the patient with 1.63 cm isoechoic nodule on thyroid ultrasound (A) was 1.72 uIU/ml in the normal range. In 2012, the size was increased to 2.67 cm mixed isoechoic nodule on ultrasound (B), and the thyroid scan showed hyperfunctioning thyroid nodule (C) and TSH decreased to 0.01 uIU/ml.

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Table 1

Comparison of clinical characteristics and ultrasound findings between hyperfunctioning nodules and cold nodules

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aNodule size is the maxim width, length, height.

bVolume is calculated by multiplying width, length, height×0.52.

ATA: American Thyroid Association, SD: standard deviation, TSH: thyroid stimulating hormone

Table 2

Comparison of fine needle aspiration results or surgery between hyperfunctioning nodules and cold nodules

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AUS: atypia of undetermined significance

Table 3

Comparison of ultrasound findings between TSH suppression and normal TSH in hyperfunctioning nodules

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aNodule size is the maxim width, length, height×0.52.

bVolume is calculated by multiplying width, length, height.

NA: not available, TSH: thyroid stimulating hormone

Acknowledgments

This study was supported by research fund of Kangwon Branch of Korean Endocrine Society (2017).

Notes

Conflict of Interest The authors have nothing to disclose.

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