Sonographic Differentiation of Asymptomatic Diffuse Thyroid Disease from Normal Thyroid: A Prospective Study

Discussion

High-resolution thyroid sonography is a useful diagnostic tool for the evaluation of DTD. There are numerous published studies related to the diagnostic efficacy of thyroid sonography for DTD, and several sonographic characteristics have been described as potential predictors of DTD, such as thyroid inferno in Graves disease and micronodulation in HT.^1,2 Because nearly all studies related to the sonographic characteristics of DTD have been retrospectively performed, retrospective study might have a significant limitation for the accurate assessment of sonography features of the thyroid.^1–7

The present study attempted to determine the diagnostic efficacy of the use of real-time sonography for asymptomatic DTD. The sonographic diagnoses of the thyroid parenchyma were classified into 4 categories. Most cases assigned to the suggestive for DTD category as determined on thyroid sonography were confirmed as HT, chronic lymphocytic thyroiditis, and diffuse hyperplasia after thyroid surgery. Only 4 cases that were classified in the category of suggestive for DTD showed NTP on pathology. Therefore, the thyroid has a high likelihood of having asymptomatic DTD if ≥3 abnormal sonographic features, including echogenicity, echotexture, vascularity, AP diameter, and glandular margin, are identified on real-time sonography. For the category of suspicious for DTD, the incidence of DTD was not high compared with the incidence of the NTP. For the category of indeterminate, the incidence of DTD was low compared with that of NTP. In addition, most cases of asymptomatic DTD that were classified in the category of suggestive for DTD were confirmed as HT or chronic lymphocytic thyroiditis. Most cases that were classified in the category of no evidence of DTD showed the NTP on the basis of the pathologic findings after thyroid surgery.

Therefore, we believe that a combination of ≥3 sonographic features of DTD has a high sensitivity and specificity for the identification of DTD compared with the use of ≤2 sonographic features of DTD. We are also convinced that no visualization of sonographic features related to DTD on real-time thyroid sonography can rule out the existence of asymptomatic DTD. Ultimately, the present sonographic classification system showed a high efficacy and accuracy for the identification of asymptomatic DTD, except for a low positive predictive value. However, this study did not assess the combinations of sonographic features for asymptomatic DTD that were more sensitive, specific, or accurate.

There was no individual sonographic feature that showed a high sensitivity and specificity for the identification of asymptomatic DTD in the present study. Yeh et al² suggested that micronodulation is a specific sonographic sign of HT. In this study, micronodulation had high specificity but low sensitivity because of low incidence. In addition, coarse echogenicity, mildly increased vascularity, and the presence of a microlobulated margin showed high specificity but low sensitivity for the detection of asymptomatic DTD. However, several sonographic features, including marked hypoechogenicity, an AP diameter >2 cm, markedly increased vascularity, and the presence of a macrolobulated margin, showed very high specificity and very low sensitivity. Gutekunst et al⁸ reported that 5.4% of cases of HT appeared as normal findings on thyroid sonography. In this study, 11.3% (7/62) of the cases of asymptomatic DTD did not demonstrate abnormal sonographic features on real-time thyroid sonography. Therefore, asymptomatic DTD may be mistaken for the normal thyroid, though a high-resolution sonography instrument was used and an experienced radiologist performed the thyroid sonography.

In the present study, there was a high incidence of asymptomatic DTD (18.2%, 62/340). This result does not represent the general incidence of asymptomatic DTD in South Korea. Asymptomatic DTD, especially HT, is known to be significantly related to the occurrence of thyroid malignancy compared with normal thyroid.^9,10 Ohmori et al¹¹ reported that PTC with HT has a prevalence of 5.5%, which is higher than that of PTC without HT. Therefore, we suggest that the high incidence of asymptomatic DTD reflects thyroid malignancy in 310 patients (91.2%, 310/340) as the main cause of thyroid surgery.

In our study, a relatively low number of patients having asymptomatic autoimmune thyroiditis, including chronic lymphocytic thyroiditis or HT, showed positive TPOAb levels on serologic results (21/60, 35%). However, several studies have reported a high accuracy of the TPOAb with regard to the presence of subclinical hypothyroidism.^12,13 We think that further study is necessary for the evaluation of the interrelationship between asymptomatic autoimmune thyroiditis and laboratory data, including autoantibodies.

There was no case of a diffuse infiltrating malignancy in this study. The early detection of a diffuse infiltrating tumor in the thyroid is important for the improvement of patient prognosis. Some investigators have suggested that scattered microcalcifications and heterogeneous echotexture could be helpful sonographic features for the identification of the diffuse sclerosing variant of PTC.¹⁴ However, there was no case showing scattered microcalcifications on a real-time thyroid sonography in this study. Hoang et al¹⁵ reported that sonographic features suggestive of diffuse infiltrating thyroid malignancy include irregular or nodular enlargement of the thyroid gland, sparing from the infiltrative process in portions of the gland, and the presence of nodal metastases.

There are several limitations to this study. First, most of the study patients underwent thyroid surgery for the treatment of a thyroid malignancy, which can explain the high incidence of autoimmune thyroiditis. Various cases of DTD, including non-autoimmune thyroiditis, a diffuse infiltrating malignancy, or other types of DTD, were not included. Second, patients younger than 20 years of age were not included because their thyroids were not surgically confirmed. Third, we excluded 18 cases of the indeterminate category from the determination of the diagnostic index of thyroid sonography for the identification of DTD. This exclusion might have created a statistical bias. Sonographic features of the 18 cases included coarse echotexture (n = 7), AP diameter from 1 to 2 cm (n = 4), mildly increased vascularity (n = 5), and the presence of a microlobulated margin (n = 2). However, there was no case having thyroid inferno or micronodulation in the indeterminate category. Finally, the AP diameter of the thyroid was used for the assessment of glandular size because of easy acquisition. However, the accuracy of the use of the AP diameter for the determination of thyroid volume is not high. For accurate calculation of thyroid volume, several methods have been introduced for its quantification. Some investigators have suggested that 3D sonography for thyroid volumetry is useful, that volumetric sonography is better than B-mode sonography on the basis of the reference of pathologic anatomy, and that 3D volumetric quantification of the thyroid is possible with the use of semiautomated volumetric sonography.^16,17

In summary, the present sonographic classification based on real-time sonography of the thyroid is a useful tool to differentiate asymptomatic DTD from normal thyroid.