Primary hyperparathyroidism has an increasing prevalence nowadays, as a consequence of routine measurements of the blood calcium levels [
Imaging studies are represented by ultrasonographic (US) techniques, scintigraphy, and, rarely, computed tomography or magnetic resonance imaging. Among these, scintigraphy is considered the best, but requires a specialized center of nuclear medicine and implies an exposure to radiations [
US is a good technique for the detection of parathyroid adenomas localized in the cervical region. In some cases, due to their location adjacent to the thyroid tissue and other cervical structures, parathyroid adenomas might be mistaken for thyroid nodules or lymph nodes.
US elastography is a noninvasive method for evaluating the mechanical characteristics of the tissues, such as elasticity and stiffness [
2D-shear wave elastography (2D-SWE) uses tracking of shear wave propagation through a structure in order to evaluate the elasticity and stiffness of the tissue. The method was described in detail for the first time by Bercoff et al. in 2004 [
This method was used during the past years to explore the breasts, liver, thyroid, and kidneys [
The purpose of this study was to use 2D-SWE for the evaluation of parathyroid benign lesions (adenomas or hyperplasia) in order to establish if this can offer valuable pieces of information on the preoperative localization of the adenoma.
This was a cross-sectional study that included patients with hyperparathyroidism and healthy controls. Approval from the Local Ethics Committee and informed consent from all the patients and controls were obtained, before performing any study-related procedure. The research followed the Code of Ethics of the World Medical Association (Declaration of Helsinki).
The patients with hyperparathyroidism were enrolled from different outpatient or inpatient services, and 2D-SWE was offered to them after conventional US evaluation. The controls were recruited from the students and the staff of the hospital. They had a negative history for thyroid disorders and presented normal thyroid at physical and US examination.
A total number of 35 patients with hyperparathyroidism were evaluated by conventional B-mode US and by 2D-SWE. Cases with unidentified parathyroid lesion and those not submitted to surgery were excluded from the study. The remaining 22 patients formed the “parathyroid” group that included 20 patients with primary and 2 with tertiary hyperparathyroidism. The diagnosis of primary hyperparathyroidism was established in the presence of hypercalcemia with increased parathormone (PTH). The parathyroid adenoma was detected by US, and at least one supplementary imaging method (either Tc-sestamibi parathyroid scintigraphy or magnetic resonance imaging) was used for confirmation. The diagnosis of tertiary hyperparathyroidism was based on the presence of hypercalcemia, together with increased PTH, in patients known with chronic kidney failure. All the patients underwent surgery, and the pathological results confirmed the diagnosis of parathyroid adenoma or hyperplasia in the structures removed.
Conventional B-mode US examination and 2D-SWE were performed with the same device—Aixplorer system (SuperSonic Imagine, France), using a high-resolution linear transducer of 15-4 MHz. B-mode US was performed first, in order to detect the pathological parathyroid and to measure the adenomatous/hyperplastic gland.
2D-SWE was performed in each of the cases, the image being displayed together with the grayscale US picture. After placing a box (frame) over the parathyroid adenoma captured in a longitudinal section, a colored image appeared, revealing blue and red areas on an elastogram. Dark-blue areas correspond to soft tissues, whereas red areas correspond to stiff tissues. With the aid of the device’s software, a circular region of interest was placed inside the parathyroid elastogram, and the diameter of the circle was increased as much as possible, between 2 and 8 mm, taking care not to overpass the limits of the analyzed parathyroid gland (Figure
US and 2D-SWE evaluation of the parathyroid adenoma.
We compared the EI of the abnormal parathyroid glands with that of the normal thyroid parenchyma, because normal parathyroid glands are small and cannot be evaluated by US in the majority of the subjects, despite the use of high-resolution devices.
For each parathyroid gland, three measurements were performed and the mean values for each of the three elastographic parameters depicted by the device (SWE-Mean, SWE-Max, and SWE-SD) were calculated.
For the healthy subjects from the control group, the thyroid was explored and three measurements were performed in the right thyroid lobe (RTL) and three in the left thyroid lobe (LTL). The mean value of the three determinations, for each lobe and parameter, was calculated.
All the measurements were performed by two endocrinologists (MV and IG) with more than 10 years of experience in thyroid and parathyroid US and two years of experience in using the Aixplorer device.
The results were collected in a Microsoft Excel file. The statistical analysis was performed with the aid of two programs, SPSS v17 and EpiInfo v7. Descriptive statistics have been performed on both groups of subjects. The significance of the differences between groups was assessed with the Mann–Whitney test or the chi-square test. The diagnostic performance of 2D-SWE was evaluated using receiver operating characteristic curves. This analysis was performed for SWE-Mean, and the value that provided the maximum sum of sensitivity and specificity was considered the cutoff. Sensitivity and specificity were calculated according to the standard methods. The threshold for the statistical significance for
In total, 65 subjects were evaluated by 2D-SWE. From these, 22 patients (33.8%) were diagnosed with hyperparathyroidism (20 with primary hyperparathyroidism and 2 with tertiary hyperparathyroidism) and 43 (66.2%) were healthy controls (with normal thyroid parenchyma at US). The baseline characteristics of the cases included in the study are summarized in Table
Baseline characteristics of the studied cases.
Parameter | Study group | Controls |
|
---|---|---|---|
Numbera | 22 | 43 | — |
F/Ma | 19/3 | 30/13 | — |
Age (years)b | 53.7 ± 13.6 | 48.3 ± 11.3 | 0.887 |
Weight (kg)b | 73.7 ± 18.6 | 66.3 ± 17.5 | 0.166 |
TV (ml)b | — | 9.3 ± 3.3 | — |
Calcemia (NV: 8.2–10.4 mg/dl)b | 10.8 ± 1.5 | — | — |
PTH (NV: 10–55 pg/ml)b | 411.5 ± 594.1 | — | — |
Maximum diameter of PT adenoma in US (mm)b | 14.3 ± 6.4 | — | — |
F: females; M: males; TV: thyroid volume; NV: normal values; PTH: parathormone; PT: parathyroid; avalues expressed as numbers; bvalues expressed as mean ± standard deviation.
All the patients with hyperparathyroidism were submitted to surgery, and the pathological results indicated adenoma in 21 patients and hyperplasia in one case.
The mean values of EI in parathyroid adenomas and in normal thyroid parenchyma, as well as the differences between the groups, are shown in Table
Mean values of 2D-SWE parameters for parathyroid and thyroid tissue, in the two groups of subjects.
Samples/variables | SWE-Mean (kPa) | SWE-Max (kPa) | SWE-SD (kPa) |
---|---|---|---|
Control group | |||
RTLa | 19.6 ± 6.6 | 33.4 ± 9.5 | 4.1 ± 1.4 |
LTLa | 19.5 ± 6.8 | 33.2 ± 11.2 | 4.4 ± 1.7 |
|
0.92 | 0.91 | 0.29 |
Mean RTL-LTLa | 19.5 ± 7.6 | 33.4 ± 9.5 | 4.3 ± 1.5 |
Study groupa | 10.2 ± 4.9 | 22.9 ± 10.6 | 4.8 ± 2.5 |
|
<0.001 | <0.001 | 0.233 |
|
<0.001 | <0.001 | 0.396 |
SWE: shear wave elastography; RTL: right thyroid lobe; LTL: left thyroid lobe; mean: mean value; max: maximum value; SD: standard deviation; avalues expressed as mean ± standard deviation.
The thyroid parenchyma has higher EI than the parathyroid pathological tissue, for all the parameters analyzed: SWE-Mean (Figure
Distribution of SWE-mean for EI in healthy thyroid parenchyma and in parathyroid adenomas. SWE-Mean = mean value of the elasticity index.
The best cutoff value for predicting parathyroid pathology by SWE-Mean was calculated, and the value obtained was 12.5 kPa (AUC = 0.949;
AUC for the prediction of parathyroid pathology using 2D-SWE.
Elastography is a method that provides noninvasive diagnostic information regarding the elasticity of different tissues. 2D-SWE is a relatively new elastographic technique, with very good reproducibility. A correlation coefficient ranging from 0.97 to 0.98 for interobserver variability, and between 0.78 and 0.85 for intraobserver variability, was found by some authors [
Only few preliminary studies have used elastography in patients with parathyroid adenomas or hyperplasia, but the results are promising [
In our study, we analyzed the 2D-SWE characteristics of pathologically confirmed parathyroid adenomas from patients with hyperparathyroidism, in order to determine the values for the EI in abnormal parathyroid glands. We presume that knowing the EI for a specific structure would help to identify it. To the best of our knowledge, this is the first study that quantifies parameters provided by 2D-SWE with Aixplorer system in pathologically confirmed parathyroid adenomas.
Because parathyroid adenomas are usually located in the proximity of the thyroid, we utilized for comparison normal thyroid parenchyma. Our experience regarding macroscopic examination of adenomatous and hyperplasic parathyroid after surgical removal, as well as the results from two previous studies, indicates that parathyroid lesions have a soft appearance [
The values of the EI in the two thyroid lobes in healthy subjects are similar [
We suggest that, for predicting parathyroid adenomas, the cutoff value for SWE-Mean should be set at 12.5 kPa. This provides the maximum sum of sensitivity and specificity for the measurement and a minimum probability for having false results. Subjects with a SWE-Mean value smaller than 12.5 kPa have, with a very high probability, a parathyroid adenoma and need no additional imagistic tests to localize it. These values are very useful when elastography is used to confirm that the nodule detected by US represents a pathological parathyroid gland.
In clinical practice, parathyroid adenomas need to be differentiated by other neck lesions, such as thyroid nodules and lymph nodes. Two studies, using Virtual Touch Imaging Quantification, performed a direct comparison between parathyroid and thyroid lesions, but their results are not concordant. Chandramohan et al. [
Sometimes, it may be quite challenging to differentiate parathyroid adenomas from cervical lymph nodes. Two recent studies, using a different elastographic technique [
Considering all these data, one can state that parathyroid adenomas are softer than thyroid nodules and lymphadenopathies by 2D-SWE with the Aixplorer system.
The technique proved to have a good feasibility, so it can be offered after routine US examination in the cases where a parathyroid adenoma is suspected.
There are several limitations of our study. First, the number of cases with hyperparathyroidism is low. However, all of them were treated by surgery, so that there is confirmation provided by the pathologic exam for all the parathyroid lesions. Second, the selection of the subjects with normal thyroid was based only on a negative history for thyroid disorders, normal physical exam (performed by an experienced endocrinologist), and normal thyroid US examination. No hormonal or immunological measurements were performed. Nevertheless, we considered these criteria sufficient to exclude, with a high probability, any thyroid pathology. Third, because normal parathyroid tissue cannot be evaluated in the majority of the subjects, the values for EI in parathyroid adenomas were compared with those of normal thyroid tissue. We do not consider that this last limitation constituted an important bias, because our intention was to establish a cutoff value for EI that could be used as a threshold when analyzing parathyroid adenomas and to distinguish these pathological parathyroid glands from the nearby normal thyroid parenchyma.
The work performed by us has several strengths, as well. To the best of our knowledge, this is the first study that used this elastographic method to investigate the parathyroid glands. In addition, due to the fact that the parathyroids were surgically removed, they could be evaluated by the pathologist, providing the confirmation that all the analyzed lesions represent parathyroid tissue. Finally, a standard protocol was used in all cases by two investigators with a lot of experience in using 2D-SWE.
Further studies are needed in order to compare the different parameters that can be measured by 2D-SWE for different parathyroid lesions with those obtained in thyroid nodules and/or cervical lymph nodes.
To conclude, in this study, we intended to quantify the values of EI measured by 2D-SWE, in order to provide a tool to identify preoperatively the presence of a parathyroid lesion, when other imagistic methods are not available. 2D-SWE can conveniently be performed in routine clinical practice, after US examination, in patients with parathyroid adenomas. The values of different EI measured by 2D-SWE in parathyroid adenomas are significantly lower than those of the normal thyroid parenchyma, indicating the existence of a soft tissue. By using this elastographic technique, a value less than 12.5 kPa for mean EI could be used to confirm that the lesion/nodule is a parathyroid adenoma.
Ioan Sporea has received financial support (congress travel grants or speaker fees) from Philips, Siemens, and General Electric. The rest of the authors declare that there is no conflict of interest regarding the publication of this article.