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Research ArticleHEAD & NECK

First-Line Use of Core Needle Biopsy for High-Yield Preliminary Diagnosis of Thyroid Nodules

H.C. Kim, Y.J. Kim, H.Y. Han, J.M. Yi, J.H. Baek, S.Y. Park, J.Y. Seo and K.W. Kim
American Journal of Neuroradiology February 2017, 38 (2) 357-363; DOI: https://doi.org/10.3174/ajnr.A5007

Abstract

BACKGROUND AND PURPOSE: Although core needle biopsy was introduced as a diagnostic alternative to fine-needle aspiration, the utility and safety of core needle biopsy for thyroid nodules in a large population has yet to be studied comprehensively. We evaluate core needle biopsy yields on a large-scale basis to investigate its potential in the preliminary diagnosis of thyroid nodules.

MATERIALS AND METHODS: Between March 2005 and December 2013, 2448 initially detected thyroid nodules from 2120 consecutive patients who underwent core needle biopsy were retrospectively evaluated. Of these, 72 thyroid nodules from 63 patients were excluded due to prior fine-needle aspiration attempts. The inconclusive and conclusive result rates, diagnostic accuracy, sensitivity, specificity, positive predictive value, negative predictive value, and unnecessary surgery rate of core needle biopsy were evaluated.

RESULTS: With core needle biopsy as the first-line method, the inconclusive result rate was 11.9% (283/2376) and the conclusive result rate was 88.1% (2093/2376). The diagnostic accuracy, sensitivity, specificity, positive predictive value, and negative predictive value of core needle biopsy for the diagnosis of malignancy were 96.7% (1160/1200), 89.7% (347/387), 100% (813/813), 100% (347/347), and 95.3% (813/853), respectively. There were no major complications and 12 minor complications.

CONCLUSIONS: We have demonstrated that first-line use of core needle biopsy may well improve diagnostic accuracy in thyroid nodules, reducing inconclusive or false-negative results and unnecessary operations. Such benefits underscore the promising role of core needle biopsy in managing thyroid nodules and optimizing related surgical decision-making.

ABBREVIATIONS:

AUS
atypia of undetermined significance
CNB
core needle biopsy
FLUS
follicular lesion of undetermined significance
FNA
fine-needle aspiration
NPV
negative predictive value
PPV
positive predictive value
US
ultrasonography

Although ultrasonography (US)-guided fine-needle aspiration (FNA) is a safe, accurate, and cost-effective method for diagnosing malignancy in thyroid nodules, there are limitations.1,2 A major drawback is the frequency of inconclusive results (ie, indeterminate or inadequate results), accounting for 25%–30% of FNA results.2,3 In such instances, even repeat FNA attempts may still be nondiagnostic (9.9%–47.8% incidence).46 Nodules with inconclusive FNA results are commonly referred for diagnostic surgery at reported rates of 22.2%–94.7%.79 Although several studies suggest that biomarkers (molecular or genetic) and clinical or sonography parameters may serve to support FNA outcomes,1012 surgical confirmation is often still required.1,2,12

Core needle biopsy (CNB) was introduced as a diagnostic alternative to FNA or tissue diagnosis. It is well-tolerated and safe and associated with a low incidence of complications.3,4,6,1316 However, its role has remained second-line, largely serving as a supplement in patients with inconclusive FNA results. However, a number of studies have reported that a diagnosis was established via CNB in up to 98% of nodules with indeterminate FNA results; and by performing CNB and repeat FNA in combination, 97% of nodules with prior inadequate FNA yields are eventually diagnosed.46,1416 Most interesting, there have been few studies to date on the use of CNB as a first-line examination for the diagnosis of thyroid nodules.1719 Consequently, the utility and safety of CNB for thyroid nodules in a large population have not yet been studied comprehensively.

This study was conducted on the premise that highly diagnostic yields are achievable via CNB, without undue or major complications. We therefore evaluated CNB yields on a large-scale basis to investigate its full potential in the preliminary diagnosis of thyroid nodules.

Materials and Methods

Study Population

This observational study was approved by the Institutional Review Board of Konyang University Hospital and Daejeon Sun Hospital, with written informed consent for data access waived. However, all patients undergoing CNB at our facility granted prior informed consent.

Between March 2005 and December 2013, 2448 thyroid nodules detected in 2120 consecutive patients at 2 institutions, Konyang University Hospital (n = 634) and Daejeon Sun Hospital (n = 1814), were subjected to ultrasound-guided CNB. Of these, 72 thyroid nodules in 63 patients were excluded on the basis of prior FNA attempts. Finally, 2376 initially detected thyroid nodules from 2057 consecutive patients (594 men and 1463 women; mean age, 50.8 ± 12.6 years, range, 11–91 years) were enrolled in this study. These enrolled thyroid nodules underwent CNB due to suspicious US findings (n = 1538), heavy calcifications (n = 296), high vascularity (n = 289), and requests of a small group of referring physicians (n = 253). The physicians of this cohort preferred the CNB rather than FNA in an attempt to avoid inconclusive FNA results.

Final diagnoses in malignant nodules were confirmed by postsurgical histopathology or other pathologic documentation (including biopsy-proved lymphoma or metastasis). Benign nodules were also confirmed by postsurgical histopathology, by sequential benign CNB or FNA outcomes (at least twice with intervals of >6 months), or by benign CNB findings with a nodule that was stable or decreased in size of after 1 year (at minimum).

Analysis of US Findings

The US images were reviewed independently by 2 radiologists (Y.J.K., and H.Y.H). The US finding of the nodules were evaluated for following features20,21: the size of thyroid nodules, composition (solid, predominantly solid, predominantly cystic, or cyst), shape (ovoid to round or irregular), orientation (parallel or nonparallel), margin (smooth, spiculated, or ill-defined), echogenicity (isoechoic, hypoechoic, markedly hypoechoic, or hyperechoic), and calcifications (none, macrocalcifications, or microcalcifications). The suspicious US findings were defined as nonparallel orientation, spiculated margin, marked hypoechogenicity, and the presence of micro- or macrocalcifications.20,21 A suspicious malignant nodule was defined if 1 of the above findings was present. If there were discrepancies in the US findings, the radiologists resolved them by consensus.

Sonography-Guided CNB Procedures

US examinations were performed by using 1 of 3 US systems: an iU22 or HDI-5000 U (Philips Healthcare, Best, the Netherlands) or a Logiq 9 ultrasound (GE Healthcare, Milwaukee, Wisconsin), each equipped with a high-frequency linear probe (7–12 MHz). All US examinations and US-guided CNBs were performed by 1 of 5 radiologists (Y.J.K., Y.S.P., D.H.O., H.Y.H., or J.M.Y.) with ≥5 years of clinical experience in performing and interpreting US images of the thyroid gland. If the nodule had a cystic portion of >50% or necrosis, the internal fluid of the nodule was aspirated at first and then US-guided CNB was performed on the remaining solid portion.

Disposable 1.1-cm excursion 18-ga double-action spring-activated needles (TSK Ace-cut; Create Medic, Yokohama, Japan) were used for CNB, following local anesthetic injection (lidocaine 1%). Before insertion, power Doppler US was used to carefully evaluate vessels along the biopsy course to avoid hemorrhage. With a freehand technique, the needle was advanced into a nodule or across its margin to obtain a tissue core, but the thyroid capsule was avoided to prevent vessel injury. Once the nodule was pierced, adjacent vessels were again evaluated to minimize injury and bleeding. We measured the distance of travel (1.1 cm) before sequential firing of the needle stylet and cutting cannula.

Tissue cores were placed in 10% buffered formalin immediately at the completion of the procedure for conventional processing. Each patient was then monitored for 10–20 minutes with firm local compression of the biopsy site.

Analysis of CNB Results

All CNB specimens were reviewed by board-certified attending staff pathologists with ≥5 years of clinical experience (S.Y.P., Y.M.K., B.K.K., and H.J.L.), though thyroid CNB diagnostic criteria were not yet standardized. For this study, the 6 categories of the Bethesda System were used to classify histopathologic CNB results.22

In the absence of any identifiable follicular elements or with scant normal follicular content, a CNB was considered nondiagnostic. Benign CNB readings were those demonstrating colloid or hyperplastic nodules and lymphocytic thyroiditis. CNB specimens containing nodules with some atypical cells not diagnostic of malignancy were interpreted as atypia (atypia of undetermined significance [AUS]) or follicular lesions of undetermined significance (FLUSs). These included cellular follicular nodules that were difficult to distinguish (follicular neoplasm versus hypercellular/hyperplastic nodule). Nodules with histologic features favoring follicular neoplasm were categorized as suggestive of follicular neoplasm or consistent with follicular neoplasm. “Suspicious for malignancy” included specimens that displayed atypia of a borderline nature. Unequivocal malignant features were needed for a diagnosis of malignancy.

Statistical Analysis

The statistical analysis relied on standard software (SPSS Version 18.0 for Windows: IBM, Armonk, New York). Rates of nondiagnostic results, malignancy, inconclusive and conclusive results, unnecessary surgery (considered malignant by CNB but confirmed as benign or viewed as a follicular neoplasm by CNB but proved to be adenomatous hyperplasia), and complications were determined. Major complications were defined as events that might result in admission to a hospital for therapy, an unplanned increase in the level of care, lengthened hospital stay, or events that might lead to substantial morbidity or disability. Other complications such as perithyroid hemorrhage or edema were considered minor complications.23

Diagnosis of malignancy included nodules with suspicious for malignancy or malignant CNB results. Inconclusive results included nondiagnostic and AUS/FLUS readings. With respect to thyroid cancer, CNB was analyzed for diagnostic accuracy, sensitivity, specificity, positive predictive value (PPV), and negative predictive value (NPV).

Subgroup analysis related to sample adequacy was performed according to the nodule size (<10 mm and ≥10 mm), location (upper/lower and mid), composition (cyst; cystic component ≥50%; and solid, cystic component <50%), and the presence and type of calcification. Subgroup analysis related to inconclusive results was also performed according to the nodule size, composition, location, and suspicious US findings. The parameters of the 2 groups were compared by using Student t tests and the χ2 or Fisher exact test. Statistical significance was set at P < .05.

Results

In all patients, CNB procedures were well-tolerated without immediate complications. The mean nodule size was 14.3 ± 9.6 mm (range, 4–93 mm), with nodules ≥10 mm accounting for 62.6% (1488/2376) of the sample. Among the 888 nodules of <10 mm, 634 nodules underwent CNB due to suspicious US findings. Two hundred fifty-four nodules with indeterminate US findings underwent CNB to decide the extent of the surgery for multiple thyroid nodules or to evaluate primary malignancy when cervical lymph nodes were diagnosed as metastatic. The mean follow-up was 27.5 ± 21.9 months. CNB results (n = 2376) and final diagnoses (n = 1200) are summarized in Table 1.

View this table:
Table 1:

Core-needle biopsy results and final diagnosis for initially detected thyroid nodulesa

Final Diagnosis

Final histopathologic diagnoses were ultimately acquired in 1200 of 2376 nodules (50.5%), all included in the outcome analyses. Of 2376 nodules, 1176 (49.5%) were neither followed adequately nor surgically removed to confirm prior CNB diagnostic assessments. Malignancies (n = 387) were diagnosed following surgical resections (n = 379) or biopsy-confirmed specific pathologic results, including metastasis (n = 7) or lymphoma (n = 1). Benign nodules (n = 813) were confirmed by an operation (193/813, 23.7%), sequential benign FNA or CNB readings (twice at least) (83/813, 10.2%), or a minimum 1-year follow-up of stable or shrinking nodules considered benign by CNB (537/813, 66.1%).

Diagnostic Utility of First-Line US-Guided CNB

Study outcomes of CNB as a first-line procedure for a preliminary diagnosis of thyroid nodules are summarized in Fig 1 and Table 2. In terms of detecting malignancy, CNB displayed a diagnostic accuracy of 96.7%, a sensitivity of 89.7%, a specificity of 100%, a PPV of 100%, and an NPV of 95.3%. The false-negative rate was 1.1% (8/742), with no false-positive results in this study. The diagnostic accuracy and NPV were significantly higher for nodules of ≥10 mm than for nodules of <10 mm. The malignancy rate was significantly higher for nodules of <10 mm (32.3%) than for nodules of ≥10 mm (12.6%). Moreover, sensitivity, specificity, and PPV did not show significant differences according to nodule size. Diagnostic accuracy was not associated with the composition and location of thyroid nodules (On-line Table 1).

Fig 1.
Fig 1.

Flow and study outcomes in study patients. Numbers are the number of thyroid nodules. FN indicates follicular neoplasm; SFN, suspicious for a follicular neoplasm.

View this table:
Table 2:

Outcome of CNB for initially detected thyroid nodules

Sample Adequacy and Conclusiveness

For CNB readings, the nondiagnostic rate was 4.9% (117/2376). Of 117 nodules, 38 contained a mix of fibromuscular tissue or normal thyroid tissue, owing to inaccurately targeted biopsies; 59 showed little or no cellular content due to cystic change or necrosis of a nodule; and 20 showed only hemorrhage. Nodule size (10 mm and ≥10 mm) and calcification did not affect the sample adequacy. The composition and location of the nodules were associated with the nondiagnostic results (Table 3).

View this table:
Table 3:

Univariate analysis for factors associated with nondiagnostic result on CNB

Inconclusive results accounted for 11.9% (283/2376), whereas 88.1% (2093/2376) generated conclusive outcomes. According to our subgroup analysis, the orientation, margin, and echogenicity of the nodules were associated with the conclusiveness of CNB results. The composition, size, and calcification of nodules were not associated with the conclusiveness of CNB results (Table 4).

View this table:
Table 4:

Univariate analysis for factors associated with conclusive and inconclusive results on CNB

Correlation of CNB Results with Surgical Findings

Of the 1200 verifiable diagnoses, 813 (67.8%) were benign and 387 (32.2%) were malignant. Five hundred seventy-two nodules (47.7%) were surgically resected; these procedures confirmed 379 as malignant and 193 as benign (On-line Table 2).

All 339 nodules considered malignant or suspicious for malignancy by CNB were confirmed as malignancies at surgery. Of the 24 nodules viewed as follicular neoplasms by CNB, 2 were adenomatous hyperplasia. Thus, unnecessary surgery was performed for only 2 nodules (2/363, 0.6%).

Motives for resecting nodules with benign CNB results were image-pathology discordance (benign by CNB but suspicious US features) (n = 21), malignancy on follow-up FNA or CNB (n = 5), coexistent nodules with a resected nodule (n = 40), and patient preference or aesthetic concerns. Of the 21 nodules with image-pathology discordance, 3 proved to be papillary carcinomas. Nodules (n = 48) interpreted as AUS/FLUS by CNB were resected to exclude papillary carcinoma. Among them, 12 (63.2%) were confirmed as malignant (11 papillary carcinomas, 1 follicular variant of papillary carcinoma) in the AUS group (n = 19) and 4 nodules (13.8%) were confirmed malignant (2 papillary carcinomas, 1 follicular carcinoma, and 1 follicular variant of papillary carcinoma) in the FLUS group (n = 29).

Complications

There were no major complications or hospitalizations associated with interventions in our patient cohort. Twelve patients developed minor complications. There was no difference according to nodule size. All minor complications were successfully managed by manual compression. No needle-tract seeding occurred in association with CNB.

Discussion

This present study validates the usefulness of CNB as a first-line option for assessing thyroid nodules, accruing a higher rate of conclusive results (88.1%) with low inconclusive (11.9%) and nondiagnostic (4.9%) rates compared with conventional FNA. The diagnostic accuracy of CNB was high (96.7%), with a PPV of 100% and no false-positive results. Moreover, the diagnostic performance of this study was consistent with that in previous studies (On-line Table 3).15,1719,24,25 The unnecessary surgery (0.6%) rate was also compatible with that in a previous study (0.5%).19 There were low rates of minor complications (0.5%) without any major complication in the course of biopsy procedures. These findings indicate that CNB is a safe and reliable method and that repeated biopsies or unnecessary operations are likely to be avoided through this approach.

For small nodules (<10 mm), the diagnostic performance and the inconclusive or nondiagnostic rate showed no significant difference compared with nodules of >10 mm in this study. These findings are similar to the results reported in previous studies,15,19 and they suggest that CNB is a reliable and effective method for evaluating small and large thyroid nodules.

US-guided FNA is safe, relatively accurate, and cost-effective, but inconclusive or false-negative results of FNA are problematic. The inconclusive results of up to 25%–30% (nondiagnostic, 5%–17%; AUS/FLUS readings, 3%–18%) and false-negative results (17%–21%) of FNA are the major drawback of this technique.2,3,2628 Recently, several studies have suggested that CNB is more useful than repeat FNA for nodules with prior nondiagnostic FNA results, especially if CNB and FNA are combined.4,5,15,24 Some sources have also indicated that CNB could be more useful for management decisions than repeat FNA in nodules with prior AUS/FLUS.4,29,30

Several studies have reported factors associated with nondiagnostic FNA results. The following factors were associated with nondiagnostic results of FNA: errors during tissue sampling (experience or skill of the operator, processing errors); interpretation errors; and the nature of the lesions, including cyst dominancy, small size, type of calcification, vascularity, and benign pathology.3133 Performing repeat FNA for a nodule with a previously nondiagnostic FNA was significantly associated with a repeat nondiagnostic result.34 Distinct from FNA, the size of nodules and the presence or type of calcification did not affect the nondiagnostic and inconclusive results of CNB. However, nodules with cystic components, which represented >50% of the nodules, showed significantly higher nondiagnostic CNB results. It is important to aspirate the internal fluid of any cystic lesion before the CNB procedure. The location of the nodule was associated with nondiagnostic results in our study. This association might be caused by the level of the operator's skill or experience. Most of the CNB procedures were performed via a craniocaudal approach, which could restrict accurate targeting when obstructed by the clavicle or mandible. Although it has been previously reported that the operator's experience does not affect the conclusive results on CNB,19 the operator's experience or skill might be a factor.

In our study, there were 8 false-negative cases (1.1%) with benign CNB results consistent with previous studies (0%–1%).4,15,24,29 This rate remains superior to the false-negative results of FNA, reported up to 17%–21%.35,36 A recent study reported that one-third of sonographically suspicious nodules with initially benign cytology were upgraded after CNB, and among them, about 32% were proved malignant.37 False-negative FNA diagnoses may be explained by the nature of the lesions, intrinsic procedural limitations, levels of operator skill/experience,38,39 and interpretation errors.40 Unlike false-negative findings on FNA, the false-negative results of CNB in our study may reflect inaccurate targeting (6 nodules confirmed malignant at follow-up CNB or FNA, 1 nodule at the posterior margin of lower isthmus, and 1 nodule in a case of lymphocytic thyroiditis) due to procedural inexperience. An advantage of CNB is less operator dependency if the biopsy device successfully penetrates the nodule.15 Our study suggested that the ability of accurate targeting of the nodule might be important to reduce false-negative and nondiagnostic results on CNB. Awareness and expertise in several approach methods (transisthmic, craniocaudal, and lateral approaches) might be necessary.41

According to the Bethesda system for reporting thyroid cytopathology, the category of AUS/FLUS is related to a FNA specimen that manifests as scenarios of nuclear atypia, architectural atypia, and an oncocytic pattern in paucicellular aspirates.42 Although this category is regarded as having inconclusive results, nodules with AUS on FNA showed a significantly higher risk of malignancy than nodules with FLUS on FNA.29 Repeat FNA has been recommended for this subcategory, but inconclusive results, including nondiagnostic and AUS/FLUS readings, occur in 20%–49.1% of nodules with prior AUS/FLUS FNA results.4,6,27 Recently, several studies have shown that CNB is more useful than repeat FNA in cases with previous AUS/FLUS results.4,29,30 Although it is possible to get larger tissue samples through CNB procedures, there was still a low rate of AUS/FLUS on CNB for thyroid nodules in this study. It might be caused by the variable heterogeneity of this group and the lack of standardized diagnostic CNB categorization. In our study, malignancy was diagnosed significantly higher in nodules with AUS on CNB (63.2%) than nodules with FLUS (13.8%). Further investigations are needed to manage AUS/FLUS on CNB.

Although CNB conducted by experienced radiologists is safe and well-tolerated, there are still safety concerns.6,13,14,43 However, we encountered no major complications. To minimize the potential for complications and patient discomfort, technical provisions are in place, including strict color Doppler US monitoring and immediate compression of biopsy sites after CNB procedures. Compared with FNA, CNB may be technically unfeasible or difficult at times (typically in small nodules at the posterior thyroid margin).15 Furthermore, CNB can be uncomfortable for the patient, requiring local anesthesia and greater experience in image-guided thyroid interventions.

Our study has several limitations. First, it was a retrospective study performed during a relatively long period. This feature may cause selection bias. This study involved multiple radiologists and pathologists performing US-guided CNB and histopathologic interpretation. Second, up to 50% of total enrolled cases do not have final results. This lack of results might be due to loss of follow-up or lack of final surgery in 1 (general hospital) of 2 participating hospitals. Finally, we did not apply the standardized diagnostic CNB categorization of a recent publication.22

Conclusions

We have demonstrated that the first-line use of CNB may improve the diagnostic accuracy in thyroid nodules, reducing nondiagnostic or inconclusive results. The high PPV and NPV of CNB for a diagnosis of malignancy could prevent repeat biopsy or unnecessary surgery. Such benefits underscore the promising role of CNB in managing thyroid nodules and optimizing related surgical decision-making.

Footnotes

  • This work was supported by the Konyang University Myunggok Research Fund of 2015.

  • Paper previously presented at: Annual Meeting of the European Congress of Radiology, March 2–6, 2016; Vienna, Austria.

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  • Received February 10, 2016.
  • Accepted after revision September 13, 2016.
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First-Line Use of Core Needle Biopsy for High-Yield Preliminary Diagnosis of Thyroid Nodules
H.C. Kim, Y.J. Kim, H.Y. Han, J.M. Yi, J.H. Baek, S.Y. Park, J.Y. Seo, K.W. Kim
American Journal of Neuroradiology Feb 2017, 38 (2) 357-363; DOI: 10.3174/ajnr.A5007
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