Diagnostic accuracy of a new fluoroenzyme immunoassay for the detection of TSH receptor autoantibodies in Graves’ disease

The thyrotropin receptor (TSHR), expressed on the cell surface of thyrocytes, initiates the major signals that direct thyroid cell growth and hormone synthesis/secretion [1]. In addition, it is now well-established that TSHR is expressed in a variety of extra-thyroidal cells, including fibroblasts, adipocytes and bone cells, where it is known to modulate target cell function [2, 3]. The TSHR is a target autoantigen in Graves’ disease (GD) [4‐6], where TSHR autoantibodies (TRAbs) induce thyroid growth and hyperthyroidism and represent an important diagnostic hallmark. TRAbs are also detected in a small portion of patients with Hashimoto’s thyroiditis (HT) [5].

Three varieties of TRAb are recognized: stimulating (S-TRAbs), blocking (B-TRAbs), and “neutral” (neutral TRAbs) autoantibodies. Some authors report that S-TRAbs preferentially recognize the N-terminal region, while B-TRAbs are more biased toward the C-terminal region of the ectodomain of the TSHR [7, 8]. Neutral TRAbs are reported to be directed against the cleavage region of the TSHR and are able to induce apoptosis in thyrocytes [9]. However, experimental evidence, including the analysis of the crystal structure of the TSHR extracellular domain bound to stimulating or blocking human monoclonal autoantibodies, show that TRAbs bind extensively across the leucine rich repeats of the TSHR extracellular domain, regardless of biological activity [10]. TRAbs without stimulating activity can be enriched from normal individuals [11].

In the last 50 years, bioassay (BA) and immunoassay (IMA) methods have been used to detect autoantibodies against the TSHR. BAs measure functional activity of TRAbs, (S-TRAbs, B-TRAbs), while IMAs measure the binding of autoantibodies to the receptor (total TRAbs, T-TRAbs) and are not able to differentiate S-TRAbs from B-TRAbs [12]. Since S-TRAbs are highly correlated with GD activity, BAs result as the optimal method for TRAb detection in GD. They are, however, cumbersome, time-consuming and in need of optimization and standardization [13], thus it remains restricted to a limited number of specialized laboratories. On the contrary, second and third generation IMAs are suitable for clinical practice and show high analytical and clinical accuracy [14, 15], even if they do not allow to distinguish between the different kinds of TRAbs found in patients with AITDs. However, recently, an assay using chimeric TSHR putatively detecting S-TRAbs, based on the putative structure of the extracellular domain of the TSHR and its interaction with TSHR antibodies [1], has been developed [16].

The aim of this study was to evaluate the diagnostic accuracy of a new third generation automatic fluorescence enzyme immunoassay (FEIA) for TRAb measurement in GD, in comparison with the current two IMAs.

According to the ROC curve analysis, the optimal threshold to maximize sensitivity and specificity of the ELiA™ anti-TSH-R assay was 3.8 IU/L (Fig. 1), slightly higher than that suggested by the manufacturer. Using this cut-off, the sensitivity for untreated GD was 94.7% and the specificity 99.6%. The percentage of TRAb positivity in all patient groups is shown in Fig. 2, and the median and range (minimum–maximum) values of the TRAbs for each group are reported in Table 1. A statistically significant difference (p < 0.0001) was shown between the TRAb levels of NC and those of the GD and GD/GO groups. Values of TRAbs of the treated GD group were significantly lower than those of the untreated GD and GD/GO groups (p < 0.01).

Using the TRAK™ and the TSI™ assay, the sensitivity and specificity were 100 and 98.2%, and 100 and 98.2%, respectively. The overall agreement, evaluated using a 2 × 2 classification table, between ELiA^™ and TRAK^™ was 97.9% (CI 95%: 96.1–99.0) [positive agreement: 95.3% (CI 95%: 92.2–99.5), negative agreement 98.7% (CI 95%: 97.8–99.5)]; Cohen k: 0.940 (CI 95%: 0.90–0.98). The overall agreement between ELiA™ and TSI™ was 98.5% (CI 95%: 92.0–98.0) [positive agreement: 96.3% (CI 95%: 93.6–99.0), negative agreement: 99.1% (98.4–99.8)]; Cohen k: 0.954 (CI 95%: 0.92–0.98).

Spearman’s coefficient and Passing-Bablok regression showed a satisfactory correlation between EliA^™ and TRAK^™ (Fig. 3a) [rho: 0.925; 95% CI: 0.883–0.953. Intercept: − 0.875 (95% CI: − 2.411 to 0.194); slope: 1.086 (95% CI: 0.941 to 1.248)], and between ELiA^™ and TSI^™ (Fig. 3b) [rho: 0.947; 95% CI: 0.912 0.969. intercept: 1.085 (95% CI: 0.665 to 2.116); slope 1.315 (95% CI:1.116 to 1.700)].

Bland–Altman analysis between ELiA™ and TRAK pointed out a bias of − 0.3 IU/L (95% CI: − 10 to +9.4) (Fig. 4a), and between ELiA^™ and TSI^™, a bias of 4.2 IU/L (95% CI: − 13.8 to +22.1) (Fig. 4b), showing an acceptable agreement.

TRAb detection is widely accepted as a routine test for diagnosing and monitoring GD and for differential diagnosis of the various forms of hyperthyroidism [20]. In this study, we evaluated the diagnostic accuracy of the new fully automated third generation assay (ELiA^™-TSH-R assay) for the measurement of TRAbs in comparison with the two current IMAs.

The diagnostic sensitivity of ELiA^™-TSH-R assay for GD resulted high, though slightly lower than those of the TRAK^™ and TSI^™ Immulite assays. In all probability, this is associated to the lower analytical sensitivity of the ELiA^™-TSH-R assay, as shown by the high cut-off (3.8 IU/L). However, the three patients negative with ELiA^™-TSH-R assay resulted low positive with the other two assays. On the contrary, the specificity of ELiA^™-TSH-R assay (99.6%) was slightly higher than those of TRAK^™ and TSI™ Immulite assays (98.2%). In the control population, only one patient with systemic lupus erythematosus (SLE) showed a low titer of TRAbs (4.4 IU/L). It is not surprising, since SLE is the autoimmune disease associated with the largest number of autoantibodies [21]. Thyroid antibodies, in particular, are frequently associated with this autoimmune disease and are predictive markers of thyroid disorders (hypothyroidism and hyperthyroidism), present in SLE with a high prevalence [22]. No patients with HT showed positivity for TRAbs with the ELiA^™-TSH-R assay, whereas three cases resulted positive with the other two methods. In the case of TSI^™ Immulite, putatively measuring only S-TRAbs, this result was unexpected, but confirmed the findings of other studies [15, 22]. The absence of TRAbs in HT with the ELiA^™-TSH-R assay was also surprising, since previous studies using second and third generation assays detected TRAbs in 5–20% of HT patients [14, 24‐26], putatively B-TRAbs or neutral TRAbs. We cannot discriminate whether this represents a higher specificity of the method (i.e., no/low detection of B-TRAbs or neutral TRAbs) or a lower sensitivity, since positive samples obtained with the other two methods were not tested with a BA.

As expected, patients undergoing anti-thyroid drug treatment for 1–12 months showed lower TRAb values, with 24% resulting as negative. The majority of negative patients (7/8) were in clinical remission or euthyroid while on long-term low dose anti-thyroid drugs, confirming the usefulness of TRAb measurement for following disease activity and treatment effects [7, 23].

Correlation and agreement between ELiA^™-TSH-R assay and the other methods were good, even if it was higher with the TRAK^™ assay, notwithstanding the latter is calibrated against the first international standard (NIBSC code 90/672). This is likely due to the different designs of the TSI^™ Immulite assays, as previously described.

In conclusion, the diagnostic performance of the fully automated 3rd generation ELiA^™-TSH-R assay is at least comparable to that of some current TRAb assays, with a trend toward a higher specificity. As a consequence, it may be adopted into clinical practice for the differential diagnosis of hyperthyroidism (including patients with unusual GD/GO), to screen for transient hyperthyroidism, and to monitor disease activity and treatment effects.