Intraoperative devascularization and damage to the parathyroid glands or parathyroid removal are frequently associated with early hypocalcemia after total or near total thyroidectomy. This complication that occurs in a variable percentage of patients, from less than 5% up to 49%1,2 increases the morbidity of thyroid surgery and the length of hospital stay. Transient hypoparathyroidism can become permanent in about 10% of patients, which results in the need of vitamin D and calcium supplementation for life, regular control visits, and increased risk of long-term complications.3,4 Therefore, there has been an increasing interest in the identification of predictors of postoperative hypoparathyroidism in patients undergoing extensive thyroid gland resection.

Perioperative measurement of parathyroid hormone (PTH) levels has been explored as an early predictive marker of the development of hypocalcemia after total thyroidectomy, but significant variation exists in the timing, type of assay, and thresholds of PTH in the literature. A recent systematic review of 69 studies comprising 9163 patients showed that studies of PTH parameters used to predict hypocalcemia are extremely heterogeneous, and that a priori definition of PTH thresholds is needed to ascertain the true prognostic significance of PTH in predicting postthyroidectomy hypocalcaemia.5 Also, PTH levels can monitor parathyroid function but cannot be used to assess the viability status of individual parathyroid glands during the surgical procedure. By contrast, intravenous angiography with indocyanine green (ICG) enables intraoperative real-time assessment of blood perfusion of the parathyroid glands according to the degree of ICG fluorescence on each gland, and emerging clinical experience reported so far has shown promising results.6–13

However, ICG angiography of the parathyroids is a relatively new technique and not known widely. It is usually assumed that only one working parathyroid gland is enough to maintain normocalcemia. Quantitative scoring systems based on a black and white scale depending on the amount of ICG flowing through the gland and categorized as 0, black (nonvascularized), 1, gray/heterogeneous (partially vascularized), and 2, white (well vascularized) have been successfully used for predicting early postoperative hypocalcemia after total thyroidectomy.12,13 Galvez-Pastor et al.12 showed that in patients with the four glands identified, a 4-ICG score calculated by adding the individual viability value of the four glands (range 0–8) showed a good discrimination in terms of predicting postoperative hypocalcemia. By contrast, in a previous study of our group it was found that a single-gland ICG score of 2 in any parathyroid gland was sufficient for accurate prediction of postoperative normocalcemia.13 Therefore, the primary objective of the study was to compare the diagnostic accuracy of a single-gland ICG score of 2 with the 4-ICG sum score to predict early postoperative hypocalcemia. A secondary objective was to define a more accurate cut-off point to predict hypocalcemia based on 4-ICG sum score.

Fifty patients (17 men, 33 women) with a median age of 49.4 years (range 43.1–60.6) underwent total thyroidectomy because of thyroid cancer (n = 35), multinodular goiter (n = 13), and Graves disease (n = 2). Central neck dissection was performed in 30 patients.

The median 4-ICG sum score was 4.0 (range 2.25–5.75). ROC curve analysis showed that the 4-ICG sum score had a good discrimination for predicting postoperative hypocalcemia (AUC = 0.868, 95% confidence interval [CI] 0.746–0.991) (Fig. 2). Using the ≤2 cut-off value, the diagnostic accuracy was higher than the 4-ICG score ≤3 (84% [95% CI 70.9–92.8] vs. 72% [57.5–83.8]), but lower than the diagnostic accuracy of 92% (80.8–97.8) of the single-gland ICG score of 2. As shown in Table 1, the sensitivity (82%), specificity (95%), positive predictive value (82%), and negative predictive value (95%) were also more favorable for the single-gland ICG score of 2 than for the cut-offs ≤2 and ≤3 of the 4-ICG sum score. Also, there were statistically significant differences in specificities between the single-gland ICG score 2 and the 4-ICG cut-off ≤3 (P < 0.0197).

Fig. 2.

ROC curve of the 4-ICG sum score for predicting postoperative hypocalcemia.

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Calcium supplementation was required by 11 patients (22%) postoperatively. As shown in Table 2, the percentage of patients with hypocalcemia and a single-gland ICG score 2 were significantly lower than those with no gland scored 2 (5.1% vs. 81.8%, P < 0.001). Similarly, the need for calcium intake was significantly lower when negative vs. positive 4-ICG sum score ≤2 (8.1% vs. 61.5%, P < 0.001) as well as when negative vs. positive 4-ICG sum score ≤3 (6.9% vs. 42.9%, P = 0.004). Although both scores, the single-gland ICG score 2 and the 4-ICG sum score ≤3 coincided in the identification of 2 false negative cases, the single-gland ICG score 2 was superior to the 4-ICG sum score ≤3 in lower rate of false positives (18.2% vs. 57.1%). The comparisons of the performance of the single-gland ICG score 2 and the 4-ICG sum score in individual patients is shown in Fig. 3.

Fig. 3.

Performance of the ICG score 2 and the 4-ICG sum score in individual patients.

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This study shows that the single-gland ICG score of 2 predicts parathyroid gland function in the immediate postoperative period better than the 4 ICG sum score, potentially avoiding exhaustive identification of parathyroid glands. The present results confirmed data of our previous study13 in which identification of at least one gland with an ICG score of 2 was suggestive of postoperative normocalcemia and no need of calcium supplementation. These results can be implemented easily in routine surgical practice.

The single-gland ICG score 2 has a higher diagnostic accuracy than a sum score of the viability values assigned to each individual gland based on the optimal cut-off value (4-ICG sum score ≤3) as reported in 32 patients in the previous study of Gálvez-Pastor et al.12 The overall 4-ICG sum score ranges from 0 to 8 but in the total sum value it is difficult to ascertain the actual number of viable glands, particularly in scores from 2 to 4. However, the optimal cut-off value of ≤3 cannot be considered indicative of the presence of viable glands (e.g. possible combinations of scores 0 and 1 in the four glands). In the original study of Gálvez-Pastor et al.12 this cut-off value showed a sensitivity, specificity, positive predictive value and negative predictive value for predicting postoperative hypocalcemia of 83%, 73%, 42% and 95%, respectively. In our present series of 50 patients, values of the 4-ICG sum score ≤3 were somewhat higher, but less favorable than the diagnostic accuracy associated with the single-gland ICG score 2 (92% [80.8–97.8] vs. 72% [57.5–83.8]).

The present results are consistent with other studies that have documented the usefulness of ICG angiography for in situ evaluation of parathyroid gland perfusion and function after thyroidectomy. In the study of Jin et al.7 of 26 patients in whom glands were scored from 0 to 2 on ICG angiography, postoperative PTH levels were in the normal range in 22 patients when at least one parathyroid gland with a single-gland ICG score of 2. In the four patients with no parathyroid gland with a single-gland ICG score of 2, two of them developed transient hypoparathyroidism.7

In the study of Vidal Fortuny et al.,10 146 patients with at least one well perfused gland on ICG angiograph (ICG score 2) were randomized to the intervention group (follow‐up assessment for symptoms of hypocalcaemia, no blood tests to determine calcium or PTH levels on postoperative day 1, and no oral calcium and vitamin D supplementation) or the control group (measurement of calcium and PTH levels on postoperative days 1 and 10–15, and systematic calcium and vitamin D supplementation until the first follow‐up appointment at 10–15 days). None of these patients presented with hypoparathyroidism, including those who did not receive calcium supplementation. However, 11 (22%) of the 50 excluded patients, in whom no well perfused parathyroid gland could be identified by angiography, presented with hypoparathyroidism, which was significantly different from the findings in randomized patients (P = 0.007).

Lang et al.6 reported 70 patients undergoing intraoperative ICG angiography after total thyroidectomy and the four glands were identified. Fluorescence light intensity cut-offs of 150% and 109% were established. No patients with a greatest fluorescent light intensity >150% developed postoperative hypocalcemia while 9 (81.8%) patients with a greatest fluorescent light intensity ≤150% did. Similarly, no patients with an average fluorescent light intensity >109% developed hypocalcemia while 9 (30%) with an average fluorescent light intensity ≤109% did. In a retrospective study of 210 patients who underwent total or near total thyroidectomy, ICG angiography was more accurate to guide autotransplantation compared with visual inspection, and there was a difference of having normal postoperative PTH levels when there were at least two normal parathyroids on ICG compared to those with less than two.14

Although the authors are aware that the sample size is an important limitation of the study, in agreement with previous data6,10–13 it seems that presence of one well perfused parathyroid gland using ICG angiography is a reliable way of predicting the absence of postoperative hypocalcemia avoiding the potential trauma associated to all parathyroid gland identification. Total thyroidectomy can be performed safely without the need of systematic calcium supplementation.

This study shows that identification of single-gland ICG score of 2 has a higher diagnostic accuracy than 4-ICG sum score to predict immediate hypocalcemia after total thyroidectomy. Besides, the diagnostic accuracy in prediction of early postthyroidectomy hypocalcemia of a single-gland ICG score 2 is superior to the best cut-off point derived from the 4-ICG score obtained by adding the individual viability scores of the four parathyroids.

No funding was received for this clinical study.

P. Moreno Llorente: principal investigator, design de study, performed operations, collected and analyzed data, writing of the manuscript. A. García Barrasa, J.M, Francos Martínez, M. Alberich Prats and Mireia Pascua Solé: collected data and critically reviewed the manuscript. All authors have seen and approved the final draft.

None to be declared.