lNTRODUCTlON

Papillary thyroid carcinoma (PTC) is the most common pathological type of thyroid malignant tumor,and its incidence is increasing every year[1-3]. Most patients with PTC have a good prognosis, but cervical lymph node metastasis (LNM) may still occur in the early stage[4]. The LNM rate of PTC has been reported to be 20%-90%, which may be related to the different stages of the disease, occult LNM and different lymph node dissections (LNDs) in the first operation[4-7]. At present, many scholars recommend cervical LND for PTC with clinically involved neck nodes (cN1-PTC), but there is great controversy about clinically node-negative PTC (cN0-PTC) LND, and most scholars favor central LND(CLND) on at least one side[8,9]. Studies have reported a high rate of occult LNM in cN0-PTC patients for whom prophylactic lateral LND (LLND) is not recommended. This occurs in the central area and the lateral area mainly due to the low accuracy of the preoperative diagnosis of cN0 tumors[10,11]. A study by Kim

[12] showed that the accuracy of ultrasonography in the diagnosis of lateral LNM (LLNM)of PTC was 51% and that the accuracy of computed tomography was 62%[13,14]. Intraoperative freezing is helpful for the diagnosis of LNM in the central area of cN0-PTC and changes the surgical method of total thyroidectomy in many cN0-PTC patients[15,16]. Previous studies have suggested that central LNM (CLNM) has a predictive effect on cervical LLNM, which is helpful to guide LLND[9,11,17], but the relationship between the subgroup of CLNM and ipsilateral LLNM is not yet clear. The purpose of this research was to analyze the relationship between LNM in subgroups of central and ipsilateral lateral areas in unilateral cN0-PTC and to provide a basis for prophylactic LLND.

MATERlALS AND METHODS

Data were collected for 1089 PTC patients who underwent surgical treatment at the Department of Endocrine and Breast Surgery of the First Hospital of Chongqing Medical University. The criteria for inclusion were as follows: (1) Having complete medical records that fully provided the clinical and pathological features of the patient; (2) Meeting the cN0 criteria based on the clinical diagnostic criteria of cervical lymph nodes proposed by Kouvaraki

[18] , which are that the clinical examination did not touch the enlarged lymph nodes or that the maximum diameter of the enlarged lymph nodes was ＜2 cm and that the enlarged lymph nodes were texturally soft; and the imaging examination showed no enlarged lymph nodes or enlarged lymph nodes with a maximum diameter ＜ 1 cm or enlarged lymph nodes with a maximum diameter of 1-2 cm but an aspect ratio ＞ 2 and having a regular shape, clear boundary of dermis and medulla, no fine calcification of sand particles, central liquefaction necrosis,peripheral enhancement and disappearance of adjacent fat space; (3) The operations were performed by the same operator using the method of total thyroidectomy + CLND + LLND; (4) The tumor was confined to one side of the glandular lobe; and (5) The resected lymph nodes of the patients with PTC confirmed by postoperative pathological examination were strictly zoned and examined, and the pathological examination report data were complete (Figure 1).

Our univariate and multivariate analyses indicated that the risk of ipsilateral level-III LNM and level-III LNM increased with primary tumor size, ETE and CLNM subgroup. The optimal scaling regression models showed that pretracheal and ipsilateral paratracheal LNM were associated with ipsilateral level-III LNM and ipsilateral level-IV LNM, which indicated that under other conditions, with the increase in positive numbers of pretracheal and ipsilateral paratracheal LNMs, the possibility of ipsilateral level-III LNM and ipsilateral level-IV LNM were obvious. According to the importance of the model, the sum important influencing factor of pretracheal and ipsilateral paratracheal LNM that affected ipsilateral level-III LNM was 75.9%; that is, approximately 75.9% of ipsilateral level-III LNM was determined by the above two factors. Similarly, approximately 68.8% of ipsilateral level-IV LNM was determined by pretracheal and ipsilateral paratracheal LNM, and approximately 47.2% of ipsilateral level-IV LNM was determined by ipsilateral paratracheal LNM. This may be related to the lymphatic drainage of the thyroid. Some studies have suggested that the lymphatic vessels accompanying the inferior thyroid artery mainly collect the middle and lower parts of the thyroid gland into the lateral lymph node through the pretracheal and ipsilateral paratracheal lymph nodes and finally into the internal jugular vein[23,25-27]. This study indicated that the probability of ipsilateral level-III LNM and ipsilateral level-IV LNM also increased with primary tumor size, which was consistent with a previous study. Feng

[31] suggested that a tumor size ＞ 1 cm was associated with a 3.474-fold increased risk of LLNM. Ma

[32] showed that a greater tumor size was significantly associated with LNM. In this study, it was found that dissection of the lymph node at levels III and IV of the affected side of unilateral cN0-PTC patients must be considered when the tumor diameter is ＞ 2 cm with pretracheal or ipsilateral paratracheal LNM.

Regarding neck LND, all of the patients with unilateral cN0-PTC were first treated with unilateral lobectomy plus ipsilateral CLND. The specimens of the central lymph node subgroups of the affected side were strictly divided and frozen during the operation. All the specimens were diagnosed by two pathologists with more than 10 years of work experience, with each lymph node reported separately by area. If intraoperative freezing indicated CLNM and the tumor was located in the upper part of the thyroid gland, then ipsilateral LLND was performed (levels II, III and IV).

“探索光合作用”是北師大版《生物學(xué)》七年級(jí)上冊(cè)第五章第一節(jié)的內(nèi)容，教學(xué)重點(diǎn)是通過(guò)探索光合作用的原料、產(chǎn)物、條件和場(chǎng)所的實(shí)驗(yàn)活動(dòng)來(lái)獲得事實(shí)性知識(shí)，從而幫助學(xué)生理解光合作用這一抽象的重要上位概念。教學(xué)難點(diǎn)是有效完成驗(yàn)證綠葉在光下合成淀粉、驗(yàn)證植物進(jìn)行光合作用需要葉綠素活動(dòng)以及檢驗(yàn)光合作用釋放氧氣和檢驗(yàn)光合作用需要二氧化碳演示活動(dòng)。鑒于活動(dòng)內(nèi)容多，《生物學(xué)·教師教學(xué)用書》建議用3課時(shí)來(lái)完。

Statistical analysis

SPSS 22.0 software was used for the statistical analysis. In the univariate analysis, the measurement data were analyzed by an independent sample

test, and the count data were analyzed by the chi-square test(Pearson correlation analysis) with a test level of

＜ 0.05. Variables with statistical significance in the univariate analysis were subjected to optimal scaling regression analysis.

RESULTS

A total of 126 patients (32.5%) had level-III LNM, and a univariate analysis showed that there was statistical significance in the primary tumor size (

= 0.002), ETE (

= 0.025), CLNM (

＜ 0.001),prelaryngeal LNM (

＜ 0.001), pretracheal LNM (

＜ 0.001), and paratracheal LNM (

＜ 0.001). Optimal scaling regression analysis showed that the regression models were statistically significant (adjusted Rsquared = 0.144, F = 9.108,

＜ 0.001). Primary tumor size, pretracheal LNM, and paratracheal LNM were significantly associated with ipsilateral level-III LNM. Their importance levels were 0.120, 0.408 and 0.351, respectively. The total importance level of pretracheal LNM and paratracheal LNM was 0.759(Table 4).

好在今年6月，王述金的弟弟王述銀帶領(lǐng)沮水巫音樂(lè)班從武漢表演回來(lái)，他激動(dòng)地告訴我，哥哥生前的愿望要實(shí)現(xiàn)了。

Patients were not required to give informed consent to the study because the analysis used anonymous clinical data that were obtained after each patient agreed to treatment by written consent.

A total of 181 patients (46.6%) had ipsilateral LLNM, and the univariate analysis showed that there was statistical significance in the sex (

= 0.048), primary tumor size (

＜ 0.001), tumor location (

=0.029), ETE (

= 0.002), CLNM (

＜ 0.001), prelaryngeal LNM (

＜ 0.001), pretracheal LNM (

＜ 0.001),and paratracheal LNM (

＜ 0.001). Optimal scaling regression analysis showed that the regression models were statistically significant (adjusted R-squared = 0.223, F = 13.317,

＜ 0.001). Primary tumor size, tumor location, prelaryngeal LNM, pretracheal LNM, and paratracheal LNM were significantly associated with ipsilateral LLNM. Their importance levels were 0.104, 0.055, 0.168, 0.260 and 0.362,respectively. The total importance levels of prelaryngeal LNM, pretracheal LNM, and paratracheal LNM was 0.790 (Table 2).

A total of 77 patients (26.8%) had level-II LNM, and a univariate analysis showed that there was statistical significance in the sex (

= 0.006), primary tumor size (

= 0.002), tumor location (

= 0.002),ETE (

= 0.034) multifocality (

= 0.003), prelaryngeal LNM (

＜ 0.001), and paratracheal LNM (

＜0.001). Optimal scaling regression analysis showed that the regression models were statistically significant (adjusted R-squared = 0.119, F = 7.563,

＜ 0.001). Sex, primary tumor size, tumor location,ETE, and prelaryngeal LNM were significantly associated with ipsilateral level-II LNM. Their importance levels were 0.122, 0.213, 0.172, 0.110 and 0.227, respectively (Table 3).

Of 1089 PTC patients, 388 unilateral cN0-PTC patients were enrolled in this study; 653 were evaluated as cN0 before the operation, 193 were pathologically confirmed to be cN0, and 460 had pathologically involved neck nodes (pN1) after the operation. The rate of meeting the cN0 criterion was 30.0%(Figure 1).

A total of 104 patients (32.5%) had level- IV LNM, and a univariate analysis showed that there was statistical significance in the primary tumor size (

＜ 0.001) , ETE (

= 0.002), CLNM (

＜ 0.001),prelaryngeal LNM (

＜ 0.001), and pretracheal LNM (

＜ 0.001), and paratracheal LNM (

＜ 0.001).Optimal scaling regression analysis showed that the regression models were statistically significant(adjusted R-squared = 0.150, F =10.773,

＜ 0.001). Primary tumor size, ETE, pretracheal LNM, and paratracheal LNM were significantly associated with ipsilateral level-IV LNM. Their importance levels were 0.164, 0.146, 0.216 and 0.472, respectively. The total importance level of pretracheal LNM and paratracheal LNM was 0.688 (Table 5).

DlSCUSSlON

To date, whether LND should be performed in cN0-PTC patients is still controversial[10]. Most scholarssupport prophylactic CLND, while prophylactic LLND is controversial[8]. Some articles argue that prophylactic LLND is beneficial for accurate postoperative staging and reduces the chances of local recurrence and distant metastasis, while others disapprove of prophylactic LLND[16]. Since cervical LLNM does not affect the overall survival of PTC patients and prophylactic LLND is extensive anddifficult, the incidence of chylous leakage, pain, cervical dysfunction, edema, sensory abnormalities and other surgical complications has increased[21]. At present, the cN0 criterion for preoperative evaluation of the lymph node condition in PTC patients is not very accurate. In this study, the coincidence rate of cN0 was only 30.0%, which is low, similar to results in previous studies. Therefore, exploring the regularity of PTC LNM to determine the range of LND is helpful for identifying and addressing occult metastasis and for reducing local recurrence and distant metastasis.

Some scholars have suggested that lymphatic metastasis of thyroid carcinoma is usually predictable,occurring first to the central area of the affected side and then to the lateral lymph node, and that leaping metastasis is rare[11,22,23]. Lim

[24] studied 246 patients with PTC with metastasis in the central area and found that CLNM was an independent risk factor for LLNM (OR = 38.82,

＜ 0.001).Liu

[22] reported that CLNM was a predictor of LLNM in 966 patients who underwent total thyroidectomy + CLND + selective LLND. Isaacs

[23] suggested that LNM in the prelaryngeal subgroup of the central area of the affected side had predictive value for the LLNM. The results of this study reveal that there is LNM in the central area and that the rate of LLNM is 46.6%. CLNM was positively associated with the risk of LLNM (

＜ 0.001). Prelaryngeal, pretracheal and ipsilateral paratracheal LNM had a substantial influence on ipsilateral LLNM. According to the optimal scaling regression models, prelaryngeal, pretracheal and ipsilateral paratracheal LNM were positively correlated with ipsilateral LLNM and with a relatively high importance level, which suggests that the subgroup of the central area of the affected side is the main factor affecting ipsilateral LLNM. The subgroup of the central LNM accounted for 84.3% of the factors affecting LLNM; these results indicated that under other conditions, with an increase in the number of positive LNMs, the possibility of LNM was obvious, with approximately 84.3% of LLNM determined by the CLNM subgroup, which is consistent with the above results. Thus, the CLNM subgroup has predictive value for LNM on the affected side. LLND should be considered when intraoperative freezing indicates LNM in a subgroup of the central area.

This study first investigated the relationship between LNM in subgroups of the central area and ipsilateral LLNM. The optimal scaling regression models showed that prelaryngeal LNM was associated with ipsilateral level-II LNM, and with a relatively high importance level, which suggests that prelaryngeal LNM is a main factor affecting ipsilateral level-II LNM, indicating that under other conditions, with an increase in positive numbers of prelaryngeal LNMs, the possibility of ipsilateral level-II LNM was obvious, and prelaryngeal LNM was the most important influencing factor of ipsilateral level-II LNM. According to the importance of the model, approximately 22.7% of ipsilateral level-II LNM was determined by prelaryngeal LNM, which may be related to the following factors.Anatomically, the prelaryngeal lymph nodes are located between the thyroid cartilage and hyoid bone to drain the lymph of the thyroid and larynx, which is close to the location of lymph nodes in level II.Some scholars have suggested that the lymphatic vessels accompanying the superior thyroid artery mainly collect the drained lymph from the upper part of the thyroid gland into the venous system through the lateral lymph node[23,25-27]. Our research indicated that the probability of ipsilateral level-II LNM also increased with primary tumor size and tumor location, and the importance level was relatively high. The optimal scaling regression models showed that given a tumor in the upper third of the thyroid with a larger diameter and the increase in positive numbers of prelaryngeal LNMs, the possibility of ipsilateral level-II LNM was obvious. Many studies have shown that the location of a PTC affects the probability of LLNM. Hunt

[28] suggested that tumors involving the superior aspect of the thyroid lobe were more likely to be associated with metastasis to the lateral cervical lymph nodes (

＜ 0.01), and 76.9% of patients with lateral cervical lymph node disease had involvement of the superior aspect of the lobe. Kwak

[29] suggested that a tumor in the upper third of the thyroid was associated with a 4.7-fold increased risk of LLNM. Dou

[30] suggested that a tumor on the upper third of the thyroid could be used to assist in the evaluation of LLNM in PTC patients. In this study, dissection of the lymph node at level II of the affected side of unilateral cN0-PTC patients with prelaryngeal LNM must be considered.

自1932年始，蔣介石發(fā)表了大量關(guān)于革命哲學(xué)的演講及著述，如1932年5月發(fā)表的《自述研究革命哲學(xué)經(jīng)過(guò)的階段》、1934年6月發(fā)表的《十年來(lái)革命經(jīng)過(guò)之回顧》、1935年9月發(fā)表的《國(guó)父遺教概要》等。蔣介石關(guān)于革命哲學(xué)的闡述，內(nèi)容大致包含兩個(gè)方面，一是在黨內(nèi)強(qiáng)調(diào)其是繼承總理遺教的正宗，從而爭(zhēng)奪黨內(nèi)正統(tǒng)，樹(shù)立個(gè)人權(quán)威;二是打壓異黨，確立國(guó)民黨在意識(shí)形態(tài)領(lǐng)域的主導(dǎo)性和排他性地位，在清理中共在意識(shí)形態(tài)領(lǐng)域影響的同時(shí)，也極力壓制自由主義對(duì)國(guó)民黨的異議。這一時(shí)期，蔣介石對(duì)黨義的闡釋和宣導(dǎo)大致有兩個(gè)方向:一是側(cè)重于內(nèi)部的政訓(xùn)，統(tǒng)一黨內(nèi)意識(shí)形態(tài);二是推動(dòng)國(guó)民黨意識(shí)形態(tài)的國(guó)家化，開(kāi)展針對(duì)全民的意識(shí)形態(tài)教育。

The lymph node zoning criteria were as follows. As recommended by the American Academy of Otolaryngology–Head and Neck Surgery Foundation in 1991, cervical lymph nodes were divided into 6 levels: Level I, submandibular area and submental area; Level II, superior jugular vein lymphatic chain group; Level III, middle jugular vein lymphatic chain group; Level IV, inferior jugular vein lymphatic chain group; level V, posterior trigonometric area; and Level VI, anterior jugular area. In 2002, the American Joint Committee on Cancer updated the zoning by adding the anterior superior mediastinal lymph nodes as level VII. In clinical work, central lymph nodes are classified as level VI, and lateral lymph nodes of the neck are classified as levels II-V[19]. Central lymph nodes (level VI) are divided into four subgroups, namely, prelaryngeal, pretracheal, ipsilateral paratracheal and contralateral paratracheal, as recommended by the American Academy of Otolaryngology–Head and Neck Surgery Foundation in 2009[20]. The range of prelaryngeal LND is the area below the hyoid bone and above the cricoid cartilage, that of pretracheal LND is the tracheal surface up to the thyroid gland and down to the innominate artery, and that of paratracheal LND is the area from the internal carotid artery to the paratracheal area.

In summary, lymphatic metastasis of PTC is traceable. Prelaryngeal LNM is related to LNM in ipsilateral level-II LNM and pretracheal and ipsilateral paratracheal LNM to LNM in ipsilateral level-III and level-IV LNM; these findings reveal the lymphatic drainage pathway around the thyroid gland,provide a basis for regional dissection and accurate dissection of lateral lymph nodes of unilateral cN0-PTC patients and help determine the extent of LLND. However, further in-depth studies are needed to prove these findings in consideration of the small sample size of this study, lack of basic research support and insufficient follow-up testing.

CONCLUSlON

For unilateral cN0-PTC patients, an understanding of LNM in each subgroup of the central area is helpful to determine the range of prophylactic lateral cervical LND. For unilateral cN0-PTC patients with a tumor diameter ＞ 2 cm and pretracheal or ipsilateral paratracheal LNM, LND at ipsilateral level III and level IV can be considered. When there is a tumor in the upper third of the thyroid with prelaryngeal LNM, LND at level II, level III and level IV can be considered.

ARTlCLE HlGHLlGHTS

FOOTNOTES

Zhou J and Li DΧ contributed equally to this work; Zhou J, Su ΧL and Gao H designed the research study; Zhou J, Li DΧ and Gao H performed the research; Su ΧL and Gao H contributed new analytic tools;Zhou J and Li DΧ analyzed the data and wrote the manuscript; all authors have read and approve the final manuscript.

3.3.2 海馬CA3區(qū)病理檢測(cè)結(jié)果 光鏡下觀察小鼠海馬CA3區(qū)神經(jīng)元，神經(jīng)元呈橢圓狀，神經(jīng)元胞體飽滿，胞質(zhì)豐富，細(xì)胞核大而圓，邊緣結(jié)構(gòu)清晰。與對(duì)照組比較，乳腺癌組細(xì)胞有一定程度的萎縮；抑郁癥組和BCRD組細(xì)胞有空泡樣和核深染改變，且細(xì)胞間隙增寬，細(xì)胞排列散亂，胞漿濃縮，細(xì)胞核體積變小或者消失。綜合海馬DG和CA3區(qū)病理結(jié)果，提示BCRD小鼠海馬存在海馬損傷。結(jié)果見(jiàn)圖4。

This study was reviewed and approved by the Ethics Committee of the First Affiliated Hospital of Chongqing Medical University. The research content and process of the project followed the international and national ethical requirements for biomedical research.

組建村必須要在農(nóng)戶自愿的基礎(chǔ)上，堅(jiān)持“試點(diǎn)先行、逐步鋪開(kāi)”原則，在盈余分配上宜采取“利益共享、風(fēng)險(xiǎn)共擔(dān)、按股分紅”的方式，盡量規(guī)避因方便組建而采取“保底分紅”的分配方式，將虧損風(fēng)險(xiǎn)轉(zhuǎn)嫁到合作社。

The female to male ratio of the 388 unilateral cN0-PTC patients enrolled in this study was 2.22:1; the average age of the patients was 43.5 ± 13.6 years old. The mean tumor size was 14.2 ± 8.9 mm.Hashimoto’s thyroid (HT) was present in 80 patients (20.6%), tumors involving the superior aspect of the thyroid lobe were present in 102 patients (26.3%), extrathyroid extension (ETE) was present in 136 patients (35.1%), and multiple lesions were present in 48 patients (12.4%). The metastasis rate of LLNM was 46.6% in the 388 patients with unilateral cN0-PTC. The LNM rate was 19.8% for level II, 32.5% for level III and 26.8% for level IV lymph nodes of the affected side in patients with unilateral cN0-PTC. The LNM rate was 24.5% in prelaryngeal LNM, 48.7% in pretracheal LNM and 57.0% in ipsilateral paratracheal LNM of the affected side in patients with unilateral cN0-PTC (Table 1).

All authors have no potential conflicts of interest to disclose.

No additional data are available.

This article is an open-access article that was selected by an in-house editor and fully peer-reviewed by external reviewers. It is distributed in accordance with the Creative Commons Attribution NonCommercial (CC BYNC 4.0) license, which permits others to distribute, remix, adapt, build upon this work non-commercially, and license their derivative works on different terms, provided the original work is properly cited and the use is noncommercial. See: https://creativecommons.org/Licenses/by-nc/4.0/

China

從價(jià)值觀角度去告訴員工什么該做，什么不該做，團(tuán)隊(duì)的用人標(biāo)準(zhǔn)和工作模式是什么樣的，培養(yǎng)團(tuán)隊(duì)成員的目標(biāo)感，遇到價(jià)值觀不符的要及時(shí)遏制，并給予警告，不要讓其存任何僥幸心理去鉆制度的漏洞，提前告知防范于未然。

Jing Zhou 0000-0002-5133-740Χ; Da-Χue Li 0000-0002-2701-1370; Han Gao 0000-0001-8578-2037; Χin-Liang Su 0000-0001-5792-1406.

Fan JR

A

Fan JR

1 Haugen BR, Alexander EK, Bible KC, Doherty GM, Mandel SJ, Nikiforov YE, Pacini F, Randolph GW, Sawka AM,Schlumberger M, Schuff KG, Sherman SI, Sosa JA, Steward DL, Tuttle RM, Wartofsky L. 2015 American Thyroid Association Management Guidelines for Adult Patients with Thyroid Nodules and Differentiated Thyroid Cancer: The American Thyroid Association Guidelines Task Force on Thyroid Nodules and Differentiated Thyroid Cancer.

2016 ; 26 : 1 -133 [PMID: 26462967 DOI: 10 .1089 /thy.2015 .0020 ]

2 Deng Y, Li H, Wang M, Li N, Tian T, Wu Y, Χu P, Yang S, Zhai Z, Zhou L, Hao Q, Song D, Jin T, Lyu J, Dai Z. Global Burden of Thyroid Cancer From 1990 to 2017 . JAMA Netw Open 2020 ; 3 : e208759 [PMID: 32589231 DOI:10 .1001 /jamanetworkopen.2020 .8759 ]

3 Bray F, Ferlay J, Soerjomataram I, Siegel RL, Torre LA, Jemal A. Global cancer statistics 2018 : GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. CA Cancer J Clin 2018 ; 68 : 394 -424 [PMID: 30207593 DOI: 10 .3322 /caac.21492 ]

4 Zhao H, Huang T, Li H. Risk factors for skip metastasis and lateral lymph node metastasis of papillary thyroid cancer.

2019 ; 166 : 55 -60 [PMID: 30876667 DOI: 10 .1016 /j.surg.2019 .01 .025 ]

5 Yang Z, Heng Y, Lin J, Lu C, Yu D, Tao L, Cai W. Nomogram for Predicting Central Lymph Node Metastasis in Papillary Thyroid Cancer: A Retrospective Cohort Study of Two Clinical Centers.

2020 ; 52 : 1010 -1018 [PMID:32599980 DOI: 10 .4143 /crt.2020 .254 ]

6 Liu H, Li Y, Mao Y. Local lymph node recurrence after central neck dissection in papillary thyroid cancers: A meta analysis.

2019 ; 136 : 481 -487 [PMID: 31196800 DOI:10 .1016 /j.anorl.2018 .07 .010 ]

7 Huang H, Wu L, Liu W, Liu J, Liu Y, Χu Z. Long-term outcomes of patients with papillary thyroid cancer who did not undergo prophylactic central neck dissection.

2020 ; 16 : 1077 -1081 [PMID: 33004750 DOI:10 .4103 /jcrt.JCRT_620 _19 ]

8 Wang Y, Guan Q, Χiang J. Nomogram for predicting central lymph node metastasis in papillary thyroid microcarcinoma:A retrospective cohort study of 8668 patients. Int J Surg 2018 ; 55 : 98 -102 [PMID: 29803769 DOI:10 .1016 /j.ijsu.2018 .05 .023 ]

9 Hu D, Zhou J, He W, Peng J, Cao Y, Ren H, Mao Y, Dou Y, Χiong W, Χiao Q, Su Χ. Risk factors of lateral lymph node metastasis in cN0 papillary thyroid carcinoma. World J Surg Oncol 2018 ; 16 : 30 [PMID: 29439716 DOI:10 .1186 /s12957 -018 -1336 -3 ]

10 Lee YC, Na SY, Park GC, Han JH, Kim SW, Eun YG. Occult lymph node metastasis and risk of regional recurrence in papillary thyroid cancer after bilateral prophylactic central neck dissection: A multi-institutional study.

2017 ; 161 :465 -471 [PMID: 27574773 DOI: 10 .1016 /j.surg.2016 .07 .031 ]

11 Eltelety AM, Terris DJ. Neck Dissection in the Surgical Treatment of Thyroid Cancer.

2019 ; 48 : 143 -151 [PMID: 30717898 DOI: 10 .1016 /j.ecl.2018 .11 .004 ]

12 Kim E, Park JS, Son KR, Kim JH, Jeon SJ, Na DG. Preoperative diagnosis of cervical metastatic lymph nodes in papillary thyroid carcinoma: comparison of ultrasound, computed tomography, and combined ultrasound with computed tomography.

2008 ; 18 : 411 -418 [PMID: 18358074 DOI: 10 .1089 /thy.2007 .0269 ]

13 Suh CH, Baek JH, Choi YJ, Lee JH. Performance of CT in the Preoperative Diagnosis of Cervical Lymph Node Metastasis in Patients with Papillary Thyroid Cancer: A Systematic Review and Meta-Analysis.

2017 ; 38 :154 -161 [PMID: 27789450 DOI: 10 .3174 /ajnr.A4967 ]

14 Zhao H, Li H. Meta-analysis of ultrasound for cervical lymph nodes in papillary thyroid cancer: Diagnosis of central and lateral compartment nodal metastases.

2019 ; 112 : 14 -21 [PMID: 30777203 DOI: 10 .1016 /j.ejrad.2019 .01 .006 ]

15 Raffaelli M, De Crea C, Sessa L, Giustacchini P, Bellantone R, Lombardi CP. Can intraoperative frozen section influence the extension of central neck dissection in cN0 papillary thyroid carcinoma? Langenbecks Arch Surg 2013 ; 398 : 383 -388 [PMID: 23207498 DOI: 10 .1007 /s00423 -012 -1036 -3 ]

16 Lee CW, Gong G, Roh JL. Intraoperative diagnosis of central compartment lymph node metastasis predicts recurrence of patients with papillary thyroid carcinoma and clinically node-negative lateral neck and may guide extent of initial surgery.

2015 ; 39 : 194 -202 [PMID: 25234198 DOI: 10 .1007 /s00268 -014 -2800 -z]

17 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.

2019 ; 41 : 2441 -2449 [PMID: 30938923 DOI: 10 .1002 /hed.25762 ]

18 Kouvaraki MA, Shapiro SE, Fornage BD, Edeiken-Monro BS, Sherman SI, Vassilopoulou-Sellin R, Lee JE, Evans DB.Role of preoperative ultrasonography in the surgical management of patients with thyroid cancer.

2003 ; 134 : 946 -54 ; discussion 954 [PMID: 14668727 DOI: 10 .1016 /s0039 -6060 (03 )00424 -0 ]

19 Robbins KT, Clayman G, Levine PA, Medina J, Sessions R, Shaha A, Som P, Wolf GT; American Head and Neck Society; American Academy of Otolaryngology--Head and Neck Surgery. Neck dissection classification update: revisions proposed by the American Head and Neck Society and the American Academy of Otolaryngology-Head and Neck Surgery.

2002 ; 128 : 751 -758 [PMID: 12117328 DOI: 10 .1001 /archotol.128 .7 .751 ]

20 American Thyroid Association Surgery Working Group; American Association of Endocrine Surgeons; American Academy of Otolaryngology-Head and Neck Surgery; American Head and Neck Society, Carty SE, Cooper DS, Doherty GM, Duh QY, Kloos RT, Mandel SJ, Randolph GW, Stack BC Jr, Steward DL, Terris DJ, Thompson GB, Tufano RP,Tuttle RM, Udelsman R. Consensus statement on the terminology and classification of central neck dissection for thyroid cancer.

2009 ; 19 : 1153 -1158 [PMID: 19860578 DOI: 10 .1089 /thy.2009 .0159 ]

21 Jo YJ, Choi HR, Park SH, Jeong YJ. Extent of thyroid surgery for clinically node-negative papillary thyroid carcinoma with confirmed nodal metastases after prophylactic central neck dissection: a 15 -year experience in a single center.

2020 ; 99 : 197 -204 [PMID: 33029478 DOI: 10 .4174 /astr.2020 .99 .4 .197 ]

22 Liu C, Χiao C, Chen J, Li Χ, Feng Z, Gao Q, Liu Z. Risk factor analysis for predicting cervical lymph node metastasis in papillary thyroid carcinoma: a study of 966 patients. BMC Cancer 2019 ; 19 : 622 [PMID: 31238891 DOI:10 .1186 /s12885 -019 -5835 -6 ]

23 Isaacs JD, McMullen TP, Sidhu SB, Sywak MS, Robinson BG, Delbridge LW. Predictive value of the Delphian and level VI nodes in papillary thyroid cancer.

2010 ; 80 : 834 -838 [PMID: 20969694 DOI:10 .1111 /j.1445 -2197 .2010 .05334 .x]

24 Lim YC, Liu L, Chang JW, Koo BS. Lateral lymph node recurrence after total thyroidectomy and central neck dissection in patients with papillary thyroid cancer without clinical evidence of lateral neck metastasis.

2016 ; 62 : 109 -113 [PMID: 27865362 DOI: 10 .1016 /j.oraloncology.2016 .10 .010 ]

25 Fisch UP, Sigel ME. Cervical lymphatic system as visualized by lymphography. Ann Otol Rhinol Laryngol 1964 ; 73 : 870 -882 [PMID: 14239533 ]

26 Andrade M, Jacomo A. Anatomy of the human lymphatic system. Cancer Treat Res 2007 ; 135 : 55 -77 [PMID: 17953408 DOI: 10 .1007 /978 -0 -387 -69219 -7 _5 ]

27 Zhu J, Huang R, Yu P, Hu D, Ren H, Huang C, Su Χ. Clinical implications of Delphian lymph node metastasis in papillary thyroid carcinoma.

2021 ; 10 : 73 -82 [PMID: 33633964 DOI: 10 .21037 /gs-20 -521 ]

28 Hunt JP, Buchmann LO, Wang L, Abraham D. An analysis of factors predicting lateral cervical nodal metastases in papillary carcinoma of the thyroid.

2011 ; 137 : 1141 -1145 [PMID: 22106241 DOI:10 .1001 /archoto.2011 .174 ]

29 Kwak JY, Kim EK, Kim MJ, Son EJ, Chung WY, Park CS, Nam KH. Papillary microcarcinoma of the thyroid: predicting factors of lateral neck node metastasis.

2009 ; 16 : 1348 -1355 [PMID: 19224278 DOI:10 .1245 /s10434 -009 -0384 -x]

30 Dou Y, Hu D, Chen Y, Χiong W, Χiao Q, Su Χ. PTC located in the upper pole is more prone to lateral lymph node metastasis and skip metastasis.

2020 ; 18 : 188 [PMID: 32723382 DOI: 10 .1186 /s12957 -020 -01965 -x]

31 Feng JW, Yang ΧH, Wu BQ, Sun DL, Jiang Y, Qu Z. Predictive factors for central lymph node and lateral cervical lymph node metastases in papillary thyroid carcinoma.

2019 ; 21 : 1482 -1491 [PMID: 30879178 DOI:10 .1007 /s12094 -019 -02076 -0 ]

32 Ma B, Wang Y, Yang S, Ji Q. Predictive factors for central lymph node metastasis in patients with cN0 papillary thyroid carcinoma: A systematic review and meta-analysis.

2016 ; 28 : 153 -161 [PMID: 26944586 DOI:10 .1016 /j.ijsu.2016 .02 .093 ]