Advanced search
Publication Cover
Cancer Management and Research Volume 13, 2021 - Issue
Submit an article Journal homepage
100
Views
6
CrossRef citations to date
0
Altmetric
Original Research

Risk Factors and Prediction Model for Lateral Lymph Node Metastasis of Papillary Thyroid Carcinoma in Children and Adolescents

Weili Liang1 Department of Thyroid Surgery, General Surgery, Qilu Hospital of Shandong University, Jinan, 250012, People’s Republic of ChinaORCID Iconhttps://orcid.org/0000-0002-8991-7071
ORCID Icon,
Lei Sheng1 Department of Thyroid Surgery, General Surgery, Qilu Hospital of Shandong University, Jinan, 250012, People’s Republic of China
,
Liguang Zhou2 Department of Ultrasound, Shandong Provincial Hospital Affiliated to Shandong First Medical University, Jinan, People’s Republic of China
,
Changyuan Ding1 Department of Thyroid Surgery, General Surgery, Qilu Hospital of Shandong University, Jinan, 250012, People’s Republic of China
,
Zhongyang Yao1 Department of Thyroid Surgery, General Surgery, Qilu Hospital of Shandong University, Jinan, 250012, People’s Republic of China
,
Chao Gao1 Department of Thyroid Surgery, General Surgery, Qilu Hospital of Shandong University, Jinan, 250012, People’s Republic of China
,
Qingdong Zeng1 Department of Thyroid Surgery, General Surgery, Qilu Hospital of Shandong University, Jinan, 250012, People’s Republic of China
&
Bo Chen1 Department of Thyroid Surgery, General Surgery, Qilu Hospital of Shandong University, Jinan, 250012, People’s Republic of ChinaCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0001-6917-8833
ORCID Icon show all
Pages 1551-1558 | Published online: 16 Feb 2021

Abstract

Purpose

Papillary thyroid carcinoma (PTC) in children and adolescents is prone to lateral lymph node metastasis (LNM), which is a high-risk factor for recurrence. However, few studies focused on identifying risk factors and establishing prediction models for lateral LNM of PTC in children and adolescents.

Patients and Methods

We retrospectively reviewed consecutive cases of children and adolescents with PTC undergoing thyroidectomy and cervical lymph node dissection between January 2009 and December 2019. The demographics and clinicopathologic features were collected and analyzed.

Results

A total of 102 children and adolescents with PTC were enrolled in our study; 51 of whom had lateral LNM (50%). After adjusting for other risk factors, the independent risk factors for lateral LNM were multifocality (odds ratio [OR]: 6.04; 95% confidence interval [CI]: 1.653–22.092; p=0.007), tumor size (OR: 1.752; 95% CI: 1.043–2.945; p=0.034), and the number of central LNM (OR: 1.23; 95% CI: 1.028–1.472; p=0.023). The formula of the combined predictor is: Multifocality + 0.31 × Tumor size + 0.115 × Number of central LNM. The area under the receiver operating characteristic curve of multifocality, tumor size, number of central LNM, and the combined predictor was 0.706, 0.762, 0.748, and 0.855, respectively. When the value of the combined predictor was ≥2.2744, lateral LNM could be predicted. The sensitivity and specificity of the predicted value were 82.4% and 74.5%, respectively.

Conclusion

The independent risk factors for lateral LNM in children and adolescents with PTC were multifocality, tumor size, and the number of central LNM. The prediction model can better predict the presence of lateral LNM.

Introduction

Although the incidence of thyroid nodules in children and adolescents is low, the rate of malignancy is higher compared with that recorded in adults. Papillary thyroid carcinoma (PTC) is the most common pediatric endocrine malignancy, accounting for 1% and up to 7% of all cancer cases in prepubertal children and adolescents, respectively.Citation1 Compared to adults with PTC, children and adolescents with PTC have unique clinicopathological features, such as higher rates of lymph node metastasis (LNM), extrathyroidal extension (ETE), and pulmonary metastasis, and lower mortality rate.Citation2,Citation3 Even for pediatric patients with clinically node negative (cN0) PTC, the rate of LNM was as high as 75%.Citation4

The presence, degree, and distribution of LNM have a significant impact on the recurrence rate in children and adolescents with PTC,Citation5 ranging 10–35%.Citation6,Citation7 Sugino et alCitation7 reported a 22.2% recurrence rate among 130 cases of PTC in children and adolescents, and identified the presence of clinically positive lymph node, ETE, and a number of metastatic lymph nodes ≥10 as high-risk factors for recurrence. Byeon et al further proposed that lateral LNM rather than central LNM was an independent risk factor for disease recurrence.Citation8 This finding was supported by other studies.Citation5,Citation9Citation11 Spinelli et al found that the rate of lateral compartment metastasis achieved 42.4% in children and adolescents with PTC.Citation12

Thus far, there are no randomized trials investigating the treatment approaches for pediatric PTC; historically, the therapeutic approach is extrapolated from experience with adult patients.Citation13,Citation14 The American Thyroid Association guidelines only recommend therapeutic lateral lymph node dissection (LND) in patients with cN1b. However, they do not recommend preventive lateral LND in patients with cN0 or cN1a. In other words, lateral LND was performed only in pediatric patients in whom lateral LNM was suspected by preoperative imaging examination or intraoperative lymph node exploration. The diagnostic value of preoperative imaging examination, such as ultrasound for lateral LNM, remains questionable.Citation15,Citation16 Based on an exceptional study in which all patients underwent therapeutic or prophylactic lateral LND, Ito et al reported that the sensitivity of preoperative ultrasound in the diagnosis of lateral LNM was as low as 27.3%.Citation15 Therefore, it is of great significance to investigate other methods for predicting lateral LNM, which may provide a beneficial supplement to imaging examination. The aim of this study was to identify risk factors for lateral LNM, establish a prediction model, and analyze its value.

Patients and Methods

Patients

Approval for this study was obtained from the ethics committee of Qilu Hospital of Shandong University in compliance with the tenets of the Declaration of Helsinki. Written informed consent and patient parental informed consent was obtained from all participants and their parents. Patient parental consent to review their medical records were required by the ethics committee. The data of consecutive children and adolescents with PTC undergoing surgery in our hospital between January 2009 and December 2019 were retrospectively analyzed. Children and adolescents were defined as those aged ≤21 years according to the literature.Citation13,Citation14,Citation17 All patients were diagnosed with high-resolution ultrasonography and, in most cases, disease was confirmed by fine-needle aspiration. Enhanced computed tomography was performed in each patient for a detailed preoperative evaluation of nodules and the cervical lymph nodes. All patients underwent thyroidectomy and cervical LND.

The exclusion criteria for patients were as follows: 1) lost to follow-up or with missing clinicopathological data; 2) presence of recurrent PTC; 3) presence of other pathologic types of thyroid cancer; 4) previous thyroid surgery or a history of irradiation involving the neck region; and 5) lack of lymph nodes in pathology despite undergoing LND.

Patient data were extracted from medical records and analyzed for various clinicopathologic factors, including demographics, tumor features, and postoperative pathologic details.

Surgical Procedures

Central LND was defined as a level of VI dissection, including the prelaryngeal, pretracheal, and unilateral or bilateral paratracheal lymph nodes. Lateral LND was defined as the excision of the lateral neck lymph nodes, including levels II–V; the minimum lateral LND range includes levels IIa, III, and IV.Citation18,Citation19 According to the American Thyroid Association guidelines for children with PTC, all patients underwent central LND regardless of suspected lymph nodes.Citation20 Concerning the lateral lymph nodes, if the preoperative imaging examination indicated a suspected lymph node, we performed preoperative fine needle aspiration or intraoperative biopsy to reach a definitive diagnosis. Because the sensitivity and specificity of preoperative imaging examination were highly controversial, we performed lymph node biopsy based on the intraoperative exploration when the imaging examination did not indicate suspicious lymph nodes. Only patients with suspected or confirmed metastasis to the lateral neck region underwent lateral LND.

Histopathologic Examination with Surgical Specimens

Surgical specimens were microscopically examined by at least two experienced pathologists. Histopathologic examination included the cell sub-type of the main lesion, primary tumor size (measured as the longest diameter of the largest lesion), multifocality, ETE, lymphatic vascular (LV) invasion, intrathyroidal spreading, number of central LNM, and underlying conditions of the thyroid, such as Hashimoto’s thyroiditis (HT). Multifocality was defined as having at least two lesions of PTC in a single lobe or two lobes. Intrathyroidal spreading referred to a major thyroid carcinoma with surrounding scattered small lesions, with features of heterotypic cells, psammoma bodies, and lymphatic vessel invasion.Citation19 ETE was defined as tumor extension into the adjacent tissues and subdivided into minimal and massive ETE. Capsular invasion, equal to infiltration of the thyroid capsule, is a type of minimal ETE.Citation21 Herein, minimal ETE was defined as extension of the primary tumor to the perithyroidal soft tissues or the strap muscles. Massive ETE was defined as extension of the primary tumor to the trachea, esophagus, recurrent laryngeal nerve, larynx, subcutaneous soft tissue, skin, internal jugular vein, or carotid artery.Citation22

Statistical Analysis

SPSS version 20.0 (IBM Corporation, Armonk, NY, USA) was used for data analysis, and p<0.05 denoted statistical significance. The numerical variables were firstly tested for normality. Normally distributed variables were expressed as the mean ± standard deviation and analyzed using t-tests. Non-normally distributed variables were expressed as the median with interquartile range and analyzed using the Kruskal–Wallis H-test. Categorical variables were compared using the χ2 test. Logistic regression was used for multivariate analysis. The prediction model is derived from the regression coefficient. A receiver operating characteristic (ROC) curve was plotted and the area under the curve was used to evaluate the diagnostic value of risk factors and the combined predictor. By calculating the Yoden index, the combined predictor corresponding to the maximum Yoden index was found, and its sensitivity and specificity were calculated.

Results

From January 2009 to December 2019, a total of 113 children and adolescents underwent surgery for thyroid cancer. Among them, 11 patients met the exclusion criteria and were not included in this study. The flow chart of patient selection is shown in .

Figure 1 Flow chart of patient’s selection.

Abbreviations: LND, lymph node dissection; MTC, medullary thyroid cancer.
Figure 1 Flow chart of patient’s selection.

A total of 102 children and adolescents with PTC were enrolled into our retrospective study; of those, 76 (74.5%) and 26 (25.5%) were females and males, respectively. The median age was 17 years. Of the patients, 51 had lateral LNM (50%). The baseline data of patients are shown in .

Table 1 The Baseline Data of 102 Pediatric Patients

High Risk Factors for Lateral LNM of PTC in Children and Adolescents

A univariate analysis showed that the groups of patients with and without lateral LNM were comparable in terms of sex (p=0.173), HT (p=0.336), intrathyroidal spreading (p=0.135), and LV invasion (p=0.461). There was significant difference between patients with and without lateral LNM in terms of age (p=0.001), multifocality (p<0.001), diffuse sclerosing variant (DSV)-PTC (p=0.027), ETE (p=0.011), tumor size (p<0.001), and the number of central LNM (p<0.001) ().

Table 2 Risk Factors for Lateral LNM in Children and Adolescent Patients with PTC

To exclude the influence of each variable factor, we subsequently performed a logistic regression analysis of lateral LNM. The independent risk factors for lateral LNM identified through this analysis were multifocality (odds ratio [OR]: 6.043; 95% confidence interval [CI]: 1.653–22.092; p=0.007), tumor size (OR: 1.752; 95% CI: 1.043–2.945; p=0.034), and the number of central LNM (OR: 1.23; 95% CI: 1.028–1.472; p=0.023). Age, DSV-PTC, and ETE were not independent risk factors for lateral LNM ().

Establishment and Value of the Prediction Model

According to the regression coefficient of the logistic regression analysis, the calculation formula of the prediction model is as follows:

Combined predictor = Multifocality + (0.561/1.799) × Tumor size + (0.207/1.799) × Number of central LNM = Multifocality + 0.31 × Tumor size + 0.115 × Number of central LNM.

We calculated the ROC curve of multifocality, tumor size, number of central LNM, and combined predictor (). The area under the curve of the four predictors was 0.706, 0.762, 0.748, and 0.855, respectively; the combined predictor exhibited the greatest value.

Figure 2 The ROC curve of multifocality, tumor size, number of central LNM and combined predictor. The area under the curve of the multifocality, tumor size, the number of CLNM and combined predictor was 0.706 (95% CI, 0.603–0.808), 0.762 (95% CI, 0.653–0.842), 0.748 (95% CI, 0.670–0.853) and 0.855 (95% CI, 0.782–0.928), respectively (all P<0.05).

Abbreviation: CLNM, central lymph node metastasis.
Figure 2 The ROC curve of multifocality, tumor size, number of central LNM and combined predictor. The area under the curve of the multifocality, tumor size, the number of CLNM and combined predictor was 0.706 (95% CI, 0.603–0.808), 0.762 (95% CI, 0.653–0.842), 0.748 (95% CI, 0.670–0.853) and 0.855 (95% CI, 0.782–0.928), respectively (all P<0.05).

Yoden index = sensitivity + specificity − 1

The maximum Yoden index was 0.569, and the corresponding combined predictor was 2.2744. Therefore, when the combined predictor was ≥2.2744 (calculated using the above formula), the occurrence of lateral LNM could be predicted. The sensitivity and specificity of the predicted value were 82.4% and 74.5%, respectively.

Discussion

Previous studies on the risk factors for lateral LNM have almost always targeted adults with PTC. These significant risk factors are mostly associated with tumor aggressiveness, which included central LNM, ETE, tumor multifocality, tumor size, LV invasion, etc.Citation19,Citation23,Citation24 Currently, there is limited literature on the risk factors for lateral LNM of PTC in children and adolescents. Spinelli et al proposed that infiltration of the thyroid capsule, massive ETE, distant metastasis (DM), classic subtype of PTC, and central LNM were significantly associated with lateral LNM.Citation12 Kim et al identified four tumor characteristics associated with an increased risk of LNM in pediatric PTC: larger tumor size; ETE; DM; and tumor multifocality.Citation25 In the study of children and adolescents with PTC in a post-Chernobyl exposed region, Fridman et al suggested that lateral LNM was associated with the age and sex of patients, tumor size, minimal ETE, solid architectonic, extensive desmoplasia in carcinoma, presence of psammoma bodies, extensive involvement of the thyroid, and the central lymph node ratio (LNR; number of metastatic lymph nodes/number of dissected nodes).Citation5 According to the above literature, lateral LNM in children and adolescents with PTC is also mainly associated with factors representing tumor aggressiveness and progression.

In this study, tumor size was significantly associated with lateral LNM, consistent with the results reported in other studies.Citation5,Citation25 Shi et al suggested that the OR for lateral LNM continued to increase by size relative to a 1–10 mm baseline, and multi-stratification by size could provide more precise estimates of the likelihood of LNM in adult patients prior to surgery.Citation26 The present study indicated that, as the tumor size increased by 1 cm, the risk of lateral LNM increased by 1.752-fold. The area under the ROC of the tumor size was 0.762, indicating the good accuracy of the tumor size for the prediction of lateral LNM. More importantly, the tumor size can be determined preoperatively by ultrasound, allowing doctors to closely examine the risk of lateral LNM prior to surgery.

The number of central LNM was another independent risk factor for lateral LNM of PTC in children and adolescents; this finding was supported by other studies on pediatric patients.Citation5,Citation12 Generally, central lymph node is the initial site for LNM, followed by the lateral lymph nodes. We found that, as the number of central LNM increased by 1, the risk of lateral LNM increased by 1.23-fold. The area under the ROC of the number of central LNM was 0.748. We previously analyzed risk factors for lateral LNM in adult patients with papillary thyroid microcarcinoma. Although tumor size, ETE, intrathyroidal spreading, and tumor multifocality were associated with lateral LNM, only central LNM was a significant risk factor after adjusting for other risk factors.Citation19

Some authors proposed that an increase in the number of tumors was associated with an increased risk of ETE, LV invasion, and LNM.Citation27 In pediatric patients with PTC, multifocality was also regarded as an independent risk factor for lateral LNM,Citation25 consistent with the results of the present study. We furthermore demonstrated that pediatric patients with multifocality had a 6.043-fold greater risk of lateral LNM than those without multifocality. The area under the ROC of the number of central LNM was 0.706.

Regarding other influential factors, the sex of prepubertal children is not related to pediatric and adolescent PTC. However, after puberty, females are at a 4–5-fold higher risk of developing thyroid cancer than males.Citation28 In this study, sex was not associated with lateral LNM of PTC in children and adolescents.

DSV-PTC is more frequently found in pediatric patients than adults. This type is associated with a more aggressive behavior and a less favorable outcome than conventional PTC.Citation29 Although it was significant in univariate analysis, DSV-PTC was not an independent risk factor after adjusting for other risk factors in this study. This may be because the conventional subtype of PTC also has a high rate of lateral LNM in pediatric patients.Citation12

Prepubertal children with DM are linked to poor clinical outcomes.Citation16,Citation23 The present study used a cut-off point of 15 years of age to classify the patients into prepubertal children and adolescents, according to previous literature.Citation12 However, we did not observe a higher rate of lateral LNM in prepubertal children versus adolescents.

The presence of LV invasion, which was significantly associated with LNM in adult patients, should be considered as an indicator of aggressive clinicopathological features.Citation23,Citation30 In this study, LV invasion was not an independent risk factor for lateral LNM in pediatric PTC. This result is consistent with those of studies on lateral LNM of PTC in children and adolescents.Citation12,Citation25

ETE indicates poor prognosis for adult patients with PTC. Although ETE is often observed in PTC, its association with LNM remains controversial. In general, the presence of massive ETE (an adverse pathologic feature) is predictive of LNM.Citation31 In pediatric patients with PTC, both massive ETE and infiltration of thyroid capsule were significantly associated with lateral LNM.Citation12 In our study, ETE was not an independent risk factor for lateral LNM. This finding was consistent with those of our previous research on lateral LNM in adult patients with papillary thyroid microcarcinoma.Citation19 This may be because the association of ETE with LNM was based on the tumor size.Citation32

Thus far, there have been no reports on a prediction model for lateral LNM of PTC in children and adolescents. Central LNR (number of metastatic lymph nodes/number of dissected nodes) was adopted to predict lateral LNM. This may be a useful predictor for stratifying the likelihood of recurrence in pediatric patients undergoing central or lateral LND for pathologic N1a or N1b PTC.Citation17 Fridman et al suggested that a high central LNR (eg, >0.5) was significantly associated with high risk for developing lateral LNM.Citation5 However, LNR is not a prediction model which combines all independent risk factors by regression coefficient. Furthermore, LNR is susceptible to other factors. For example, a higher LNR is required to predict the presence of lateral LNM in patients with HT, and the central LNR (HT ≥0.4; non-HT ≥0.6) was independently associated with the occurrence of lateral LNM.Citation33 From this study, it can be concluded that the predictive value of the combined predictor (determined by calculating the area under ROC curve of multifocality, tumor size, number of central LNM, and combined predictor) is greater than that of any single risk factor. We further noted that a value for the combined predictor ≥2.2744 was indicative of the occurrence of lateral LNM. The sensitivity and specificity values were 82.4% and 74.5%, respectively, demonstrating the excellent predictive value of our model.

Firstly, to our knowledge, this is the first report of a prediction model for the development of lateral LNM of PTC in children and adolescents, in which multiple variables were systematically considered to estimate an individual risk of lateral LNM. Secondly, as this was not a prospective study, the surgical team was unable to perform preventive lateral LND, which may be the premise to ensure the accuracy of this study. However, we carefully conducted intraoperative exploration in cases without the presence of a suspicious lateral lymph node in preoperative imaging examination. We adopted the incision of thyroid surgery to perform a rapid pathological examination of enlarged lymph nodes in the III and IV sub-compartments, which could ensure the accuracy of the rate of lateral LNM observed in this study. Thirdly, this investigation included a larger sample. Because PTC is rare in children and adolescents, we collected data from a thyroid cancer treatment center over a 10-year period. Finally, we performed statistical analysis of the numerical variables using the patient data. We did not group the tumor size and the number of central LNM into categorical variables as in previous studies.Citation12,Citation25 If a continuous numeric variable changed to a categorical variable through a cut-off point, the result may change as the cut-off point increases or decreases.Citation23

Despite these advantages, this study had several limitations. Firstly, as retrospective research, the presence of potential selection bias in this study was inevitable. The low annual incidence of pediatric PTC poses challenges for the design of prospective randomized trials. This has led to the extrapolation of pediatric treatment approaches based on the literature concerning adults with PTC. Secondly, unfortunately, the number of central LNM can only be identified postoperatively by histopathologic examination. The other two predictors can be preoperatively detected through low-sensitivity neck ultrasonography. However, these factors identified postoperatively may be more suitable for guiding radioactive iodine therapy and accurate follow-up for pediatric patients.Citation12

Conclusion

The independent risk factors for lateral LNM in children and adolescents with PTC were multifocality, larger tumor size, and higher numbers of central LNM. The calculation formula of the combined predictor for lateral LNM in pediatric PTC is as follows: Multifocality + 0.31 × Tumor size + 0.115 × Number of central LNM. The predictive value of these factors for lateral LNM is as follows (in descending order): the combined predictor, number of central LNM, tumor size, and multifocality. Therefore, the present model (≥2.2744) showed excellent accuracy for predicting the occurrence of lateral LNM in pediatric patients with PTC.

Abbreviations

PTC, papillary thyroid cancer; LNM, lymph node metastasis; LND, lymph node dissection; cN0, clinically node-negative; cN1, clinically node-positive; ETE, extrathyroidal extension; ROC curve, receiver operating characteristic curve; HT, Hashimoto’s thyroiditis; LV invasion, lymphatic vascular invasion; ATA, American Thyroid Association; DM, distant metastasis.

Disclosure

The authors report no conflicts of interest in this work.

References

  • Tracy ET, Roman SA. Current management of pediatric thyroid disease and differentiated thyroid cancer. Curr Opin Oncol. 2016;28(1):37–42. doi:10.1097/CCO.000000000000025026575691
  • Francis GL, Waguespack SG, Bauer AJ, et al. Management guidelines for children with thyroid nodules and differentiated thyroid cancer. Thyroid. 2015;25(7):716–759. doi:10.1089/thy.2014.046025900731
  • Dzepina D. Surgical and pathological characteristics of papillary thyroid cancer in children and adolescents. Int J Pediatr. 2012;2012:125389. doi:10.1155/2012/12538922164182
  • Ngo DQ, Ngo QX, Van Le Q. Pediatric thyroid cancer: risk factors for central lymph node metastasis in patients with cN0 papillary carcinoma. Int J Pediatr Otorhinolaryngol. 2020;133:110000. doi:10.1016/j.ijporl.2020.11000032200312
  • Fridman M, Krasko O, Lam AK. Optimizing treatment for children and adolescents with papillary thyroid carcinoma in post-Chernobyl exposed region: the roles of lymph node dissections in the central and lateral neck compartments. Eur J Surg Oncol. 2018;44(6):733–743. doi:10.1016/j.ejso.2017.12.00429397264
  • Feinmesser R, Lubin E, Segal K, Noyek A. Carcinoma of the thyroid in children–a review. J Pediatr Endocrinol Metab. 1997;10(6):561–568. doi:10.1515/jpem.1997.10.6.5619467125
  • Sugino K, Nagahama M, Kitagawa W, et al. Risk stratification of pediatric patients with differentiated thyroid cancer: is total thyroidectomy necessary for patients at any risk? Thyroid. 2020;30(4):548–556. doi:10.1089/thy.2019.023131910105
  • Byeon HK, Kim SB, Oh HS, et al. Clinical analysis of pediatric thyroid cancer: a single medical institution experience of 18 years. Ann Otol Rhinol Laryngol. 2019;128(12):1152–1157. doi:10.1177/000348941986825131375033
  • Jeon MJ, Kim YN, Sung TY, et al. Practical initial risk stratification based on lymph node metastases in pediatric and adolescent differentiated thyroid cancer. Thyroid. 2018;28(2):193–200. doi:10.1089/thy.2017.021429179646
  • Sapuppo G, Palermo F, Russo M, et al. Latero-cervical lymph node metastases (N1b) represent an additional risk factor for papillary thyroid cancer outcome. J Endocrinol Invest. 2017;40(12):1355–1363. doi:10.1007/s40618-017-0714-y28646475
  • Sung TY, Jeon MJ, Lee YH, et al. Initial and dynamic risk stratification of pediatric patients with differentiated thyroid cancer. J Clin Endocrinol Metab. 2017;102(3):793–800. doi:10.1210/jc.2016-266627809646
  • Spinelli C, Tognetti F, Strambi S, Morganti R, Massimino M, Collini P. Cervical lymph node metastases of papillary thyroid carcinoma, in the central and lateral compartments, in children and adolescents: predictive factors. World J Surg. 2018;42(8):2444–2453. doi:10.1007/s00268-018-4487-z29383423
  • Rubinstein JC, Herrick-Reynolds K, Dinauer C, et al. Recurrence and complications in pediatric and adolescent papillary thyroid cancer in a high-volume practice. J Surg Res. 2020;249:58–66. doi:10.1016/j.jss.2019.12.00231923715
  • Palaniappan R, Krishnamurthy A, Rajaraman SS, Kumar RK. Management outcomes of pediatric and adolescent papillary thyroid cancers with a brief review of literature. Indian J Cancer. 2018;55(1):105–110. doi:10.4103/ijc.IJC_486_1730147104
  • Ito Y, Tomoda C, Uruno T, et al. Ultrasonographically and anatomopathologically detectable node metastases in the lateral compartment as indicators of worse relapse-free survival in patients with papillary thyroid carcinoma. World J Surg. 2005;29(7):917–920. doi:10.1007/s00268-005-7789-x15951927
  • Dou Y, Chen Y, Hu D, Xiong W, Xiao Q, Su X. Development and validation of web-based nomograms for predicting lateral lymph node metastasis in patients with papillary thyroid carcinoma. Gland Surg. 2020;9(2):172–182. doi:10.21037/gs.2020.01.1132420240
  • Rubinstein JC, Dinauer C, Herrick-Reynolds K, Morotti R, Callender GG, Christison-Lagay ER. Lymph node ratio predicts recurrence in pediatric papillary thyroid cancer. J Pediatr Surg. 2019;54(1):129–132. doi:10.1016/j.jpedsurg.2018.10.01030361076
  • Zhou L, Gao C, Li H, Liang W, Zeng Q, Chen B. Isthmic papillary thyroid carcinoma presents a unique pattern of central lymph node metastasis. Cancer Manag Res. 2020;12:3643–3650. doi:10.2147/CMAR.S25269232547201
  • Sheng LSJ, Han B, Lv B, et al. Predicting factors for central or lateral lymph node metastasis in conventional papillary thyroid microcarcinoma. Am J Surg. 2019. doi:10.1016/j.amjsurg.2019.11.032
  • American Academy of Pediatrics. Management guidelines for children with thyroid nodules and differentiated thyroid cancer. Pediatrics. 2018;142(6). doi:10.1542/peds.2018-3063
  • Jeon YW, Ahn YE, Chung WS, Choi HJ, Suh YJ. Radioactive iodine treatment for node negative papillary thyroid cancer with capsular invasion only: results of a large retrospective study. Asia Pac J Clin Oncol. 2016;12(1):e167–73. doi:10.1111/ajco.1215924289279
  • Mete O, Rotstein L, Asa SL. Controversies in thyroid pathology: thyroid capsule invasion and extrathyroidal extension. Ann Surg Oncol. 2010;17(2):386–391. doi:10.1245/s10434-009-0832-719949881
  • So YK, Kim MJ, Kim S, Son YI. Lateral lymph node metastasis in papillary thyroid carcinoma: a systematic review and meta-analysis for prevalence, risk factors, and location. Int J Surg. 2018;50:94–103. doi:10.1016/j.ijsu.2017.12.02929329789
  • Zhan S, Luo D, Ge W, Zhang B, Wang T. Clinicopathological predictors of occult lateral neck lymph node metastasis in papillary thyroid cancer: a meta-analysis. Head Neck. 2019;41(7):2441–2449. doi:10.1002/hed.2576230938923
  • Kim J, Sun Z, Adam MA, et al. Predictors of nodal metastasis in pediatric differentiated thyroid cancer. J Pediatr Surg. 2017;52(1):120–123. doi:10.1016/j.jpedsurg.2016.10.03327836371
  • Shi RL, Qu N, Yang SW, et al. Tumor size interpretation for predicting cervical lymph node metastasis using a differentiated thyroid cancer risk model. Onco Targets Ther. 2016;9:5015–5022. doi:10.2147/OTT.S10718727574443
  • Feng JW, Qu Z, Qin AC, Pan H, Ye J, Jiang Y. Significance of multifocality in papillary thyroid carcinoma. Eur J Surg Oncol. 2020;46(10):1820–1828. doi:10.1016/j.ejso.2020.06.01532732090
  • Hogan AR, Zhuge Y, Perez EA, Koniaris LG, Lew JI, Sola JE. Pediatric thyroid carcinoma: incidence and outcomes in 1753 patients. J Surg Res. 2009;156(1):167–172. doi:10.1016/j.jss.2009.03.09819631341
  • Kim SK, Park I, Woo JW, et al. Follicular and diffuse sclerosing variant papillary thyroid carcinomas as independent predictive factors of loco-regional recurrence: a comparison study using propensity score matching. Thyroid. 2016;26(8):1077–1084. doi:10.1089/thy.2016.011327324748
  • Sezer A, Celik M, Yilmaz Bulbul B, et al. Relationship between lymphovascular invasion and clinicopathological features of papillary thyroid carcinoma. Bosn J Basic Med Sci. 2017;17(2):144–151. doi:10.17305/bjbms.2017.192428284178
  • Kim JW, Roh JL, Gong G, et al. Extent of extrathyroidal extension as a significant predictor of nodal metastasis and extranodal extension in patients with papillary thyroid carcinoma. Ann Surg Oncol. 2017;24(2):460–468. doi:10.1245/s10434-016-5594-427654105
  • Liu L, Oh C, Heo JH, et al. Clinical significance of extrathyroidal extension according to primary tumor size in papillary thyroid carcinoma. Eur J Surg Oncol. 2018;44(11):1754–1759. doi:10.1016/j.ejso.2018.05.00929934055
  • Zhu Y, Zheng K, Zhang H, et al. The clinicopathologic differences of central lymph node metastasis in predicting lateral lymph node metastasis and prognosis in papillary thyroid cancer associated with or without Hashimoto’s thyroiditis. Tumour Biol. 2016;37(6):8037–8045. doi:10.1007/s13277-015-4706-226711787
Download PDF

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.