Keywords
Head And Neck Cancer - Thyroid neoplasms - Central compartment node dissection - Thyroidectomy
- Thymectomy
Thyroid cancer is a leading endocrine malignancy with differentiated thyroid cancers
accounting for 90% of cases. GLOBOCAN 2018 documented 567,233 new cases of thyroid
cancer and 41,071 deaths annually.[1] Central compartment lymph node dissection (CLND) is an integral part of surgical
management of differentiated thyroid cancers (DTC), depending upon the anticipated
risk of metastasis based on various risk factors.[2] However, CLND is associated with significant postoperative morbidity due to the
presence of many vital structures in a relatively narrow anatomical space.
There are several inconsistencies among the international guidelines regarding the
inferior limit for CLND in thyroid cancer. The American Thyroid Association (ATA)
management guidelines, published in 2015, specify CLND to target level VI station
lymph nodes.[3] However, the ATA's consensus statement on terminology defines the boundaries for
the CLND as follows: hyoid bone superiorly, the innominate artery on the right and
corresponding axial plane on the left side inferiorly, medial aspect of the carotid
sheath laterally, prevertebral fascia posteriorly, and the superficial layer of the
deep cervical fascia anteriorly ([Fig. 1]).[4] This equates CLND to incorporate both level VI and VII station lymph nodes. Furthermore,
AJCC (American Joint Committee on Cancer) 7th edition recommended the involvement
of level VII nodes to be staged as N1b, while AJCC 8th edition included level VII
metastatic nodal disease as N1a category. However, both staging guidelines consider
them regional, mandating level VII lymph node clearance.
Fig. 1 Surgical boundaries of the central compartment node dissection (dotted lines)
The thymus is anatomically located in the superior mediastinum and is encountered
during level VII lymph node dissection. Should thymectomy be done routinely as a part
of CLND to achieve good level VII clearance has not been addressed properly in the
literature. The rationale of performing thymectomy in CLND is as follows: (a) it permits
better lymph node clearance, as the thymus gland, especially its superior horns, lies
within the anatomical confines of the central compartment, and (b) it entails extirpation
of thymic metastasis if any. However, thymectomy performed as a part of CLND poses
a significantly high risk of postoperative hypocalcemia, as the upper poles of the
thymus as well as the inferior parathyroid glands share a common embryological origin
from the endoderm of III pharyngeal pouch and lie close to each other in the paratracheal
area within the domains of surgical boundaries.[5]
The present systematic review aimed to analyze the risk-benefit of the routine thymectomy
in CLND for DTC. A pooled analysis of previously conducted studies comparing morbidity
associated with bilateral versus unilateral versus no thymectomy to determine the
optimal extent of CLND was also performed.
Methods
The systematic review of the literature was conducted following the Preferred Reporting
Items for Systematic Review and Meta-Analysis Protocols (PRISMA-P) guidelines. The
protocol of this systematic review was registered in the International Prospective
Register of Systematic Reviews (PROSPERO) with the registration number CRD42020186741.
Search Strategy
A thorough literature search was conducted using the electronic databases of MEDLINE
(PubMed), Embase (Ovid), and Cochrane Library (Wiley) of the systematic review. A
complete search strategy was developed following a consensus among the coauthors in
collaboration with an external expert. The search strategy used variations in keywords—thyroid
neoplasms or tumors, thyroidectomy, and thymectomy—found in the title, abstract, or
keyword fields to retrieve articles referring to the role of thymectomy during CLND
in DTC. Filters (humans and English) were applied to refine the search, and the articles
published since the inception until July 2020 were included in the analysis. Single
case reports/editorials/commentaries were not included in the review. The abstracts
of the articles retrieved were screened for their relevance to our topic of study.
The full text of the pertinent articles was obtained and evaluated. The references
of these articles were also evaluated to look for any relevant studies. EndNote, version
8 (Clarivate Analytics) was used to facilitate the search process.
Data Extraction
Two authors (P.K. and P.K.G.) searched the electronic databases and screened all the
titles and abstracts from the selected articles. Any disagreement was resolved by
the consensus among the authors. The full texts of the selected articles were analyzed
by the three authors (P.K., P.K.G., and D.R.P.). The relevant information was extracted
using a predefined data extraction sheet. The information collected included study
location, year of publication, study design, sample size, clinicopathological details,
and treatment outcomes of the patients included in the study.
Statistical Analysis
All the relevant data was entered on the Microsoft Excel sheet and analyzed. A pooled
analysis of surgicopathological outcomes was performed using metaprop command in the
STATA software version 16.
Results
An initial database search of PubMed, Embase, and Cochrane using the stated keywords
yielded 74, 127, and 301 articles, respectively. A total of 321 articles were identified
after the removal of the duplicates. The search results were narrowed down to 26 after
screening the titles. The abstracts of these articles were reviewed and a total of
10 full-text articles were assessed for eligibility after removing all the studies
not addressing both the procedures simultaneously. After a thorough evaluation, we
found three articles[6]
[7]
[8] that fulfilled the inclusion criteria, which were included in the systematic review
([Fig. 2] PRISMA chart). There was one randomized controlled trial and two retrospective studies
addressing this issue.
Fig. 2 PRISMA chart
The studies included were heterogeneous, concerning the inclusion and exclusion criteria
and patient population. A formal assessment of the quality of the studies and publication
bias could not be undertaken due to the presence of a few studies. Three studies satisfying
the inclusion criteria were included in the present review and have been enlisted
in [Table 1]. A pooled analysis of the 347 patients included in these studies was carried out.
Among the 347 patients, 154 underwent total thyroidectomy (TT) with bilateral thymectomy,
while TT with unilateral thymectomy was performed in 166. Total thyroidectomy alone
was performed in 27 patients.
Table 1
Characteristics of the included studies in the review
|
Authors
|
Year
|
Country
|
Research design
|
Study groups
|
Sample size
|
|
Group 1
|
Group 2
|
Group 1
|
Group 2
|
|
Khatib et al[6]
|
2010
|
France
|
Retrospective review
|
TT + BT
|
TT + UT
|
45
|
93
|
|
Huang et al[7]
|
2014
|
China
|
Retrospective review
|
TT + UT
|
TT + BT
|
73
|
82
|
|
Li et al[8]
|
2019
|
China
|
Randomized controlled trial
|
TT
|
TT + BT
|
27
|
27
|
Abbreviations: BT, bilateral thymectomy; TT, total thyroidectomy; UT, unilateral thymectomy.
Demographic Details
The average age of presentation of the patients in either of the subgroups of all
the three studies was the fourth decade of life. The mean and median ages have been
enumerated in [Table 2]. All the studies reported female preponderance among the study subsets with a cumulative
female to male ratio of 3.3.
Table 2
Patient demographics and clinical characteristics reported in the included studies
|
Variable
|
Khatib et al[6]
|
Huang et al[7]
|
Li et al[8]
|
|
TT + BT
(n = 45)
|
TT + UT
(n = 93)
|
TT + UT
(n = 73)
|
TT + BT
(n = 82)
|
TT
(n = 27)
|
TT + BT
(n = 27)
|
|
(I) Demographic
|
|
Age (years)
|
46 (17–85) [a]
|
45 (6–78) [a]
|
48.1 ± 10.7 [b]
|
48.7 ± 10.4 [b]
|
45.3 ± 7.8 [b]
|
47.3 ± 11.6 [b]
|
|
Gender (M/F)
|
15/38
|
27/66
|
11/62
|
17/65
|
5/22
|
6/21
|
|
BMI (kg/m2)
|
NA
|
NA
|
NA
|
NA
|
24.6 ± 4.06
|
25.2 ± 3.19
|
|
(II) Tumor factors
|
|
Size (mm)
|
11.2 (< 1–55) [c]
|
18.1 (< 1–55) [c]
|
27.6 ± 12.3 [b]
|
25 ± 12.0 [b]
|
9.78 ± 6.4 [b]
|
8.85 ± 4.9 [b]
|
|
Histology
|
|
|
|
|
|
|
|
Papillary
|
42
|
75
|
73
|
82
|
27
|
27
|
|
Follicular
|
0
|
2
|
Nil
|
Nil
|
Nil
|
Nil
|
|
Medullary
|
3
|
17
|
Nil
|
Nil
|
Nil
|
Nil
|
|
Risk stratification (MACIS) (< 6/> 6)
|
NA
|
NA
|
7/73
|
16/82
|
NA
|
NA
|
Abbreviations: BT, bilateral thymectomy; TT, total thyroidectomy; SD, standard deviation;
UT, unilateral thymectomy.
a Median (range)
b Mean ± SD
c Average (range)
Tumor Characteristics
The average tumor size of various subgroups in the three studies analyzed has been
enumerated in [Table 2]. Variability in mean tumor size was noted among various studies; however, no statistically
significant difference was noted in the individual subgroups.
Operation Related Factors
[Table 3] displays the operative parameters and surgical outcomes reported in the included
studies. Only one study by Li et al[8] documented their mean intraoperative time, and there was no significant difference
noted when TT alone was performed versus when combined with bilateral thymectomy.
Huang et al[7] reported parathyroid autotransplantation rates of 5.1 ± 1.5 and 5.2 ± 1.3 among
the patients undergoing unilateral and bilateral thymectomy, respectively, along with
TT. However, there was no statistically significant difference between the two subgroups
(p = 0.657). Similar results with no statistically significant difference were reported
by Khatib et al[6] in their study of 138 patients. Li et al[8] reported that the rates of incidental parathyroidectomy were more common in patients
undergoing thymectomy than in those who did not (29.6% vs. 7.4%, p = 0.038).
Table 3
Operative parameters and surgical outcomes reported in the included studies
|
Variable
|
Khatib et al[6]
|
Huang et al[7]
|
Li et al[8]
|
|
TT + BT
(n = 45)
|
TT + UT
(n = 93)
|
TT + UT
(n = 73)
|
TT + BT
(n = 82)
|
TT
(n = 27)
|
TT + BT
(n = 27)
|
|
Operative duration (min) ± SD
|
NA
|
NA
|
NA
|
NA
|
129.52 ± 31.73
|
121.30 ± 33.10
|
|
Hospital stay (days)
|
NA
|
NA
|
NA
|
NA
|
6.22 ± 1.97
|
6.93 ± 2.17
|
|
Parathyroid removal/ transplant rates
|
7 (15.6%)
|
8 (8.6%)
|
5.1 ± 1.5
|
5.2 ± 1.3
|
2 (7.4%)
|
8 (29.6%)
(p = 0.038)
|
|
POD1 PTH levels
(pg/ml)
|
NA
|
NA
|
NA
|
NA
|
25.46 ± 14.72
|
11.07 ± 6.03
(p < 0.001)
|
|
Vocal fold palsy
|
|
|
|
|
|
|
|
Permanent
|
NA
|
NA
|
NA
|
NA
|
0 (0%)
|
1 (3.7%)
|
|
Transient
|
NA
|
NA
|
NA
|
NA
|
5 (18.5%)
|
3 (11.1%)
|
|
Hypoparathyroidism
|
|
|
|
|
|
|
|
Permanent
|
1 (2.2%)
|
0 (0%)
|
0 (0%)
|
3 (3.6%)
|
0 (0%)
|
4 (14.8%)
|
|
Transient
|
16 (35.5%)
|
10 (10.7%)
|
10 (13.7%)
|
43 (52.4%)
|
7 (25.9%)
|
19 (70.4%)
|
Abbreviations: TT, total thyroidectomy; UT, unilateral thymectomy; BT, bilateral thymectomy
Surgical Outcomes and Oncological Completeness
The pooled frequency of transient hypocalcemia in unilateral and bilateral thymectomy
was 12% (95%CI, 7%–17%) and 51% (95% CI 43%–59%), respectively. The pooled frequency
of permanent hypocalcemia in bilateral thymectomy was 5% (95% CI 1%–12%) ([Fig. 3A]). Li et al[8] reported that the rates of transient vocal fold palsy between the thymus preservation
and bilateral thymectomy groups were comparable (18.5% vs. 11.1%, p = 0.704). Permanent vocal cord palsy was reported in one patient in the bilateral
thymectomy group due to the violation of the recurrent laryngeal nerve. With regard
to 131I treatment, there was no significant difference in preablation serum thyroglobulin
levels between the thymus preservation and bilateral thymectomy groups (1.82 ± 2.18
vs. 1.42 ± 1.56, p = 0.775).
Fig. 3 (A) Pooled analysis of postoperative permanent hypocalcemia in patients undergoing bilateral
thymectomy during central compartment lymph node dissection (CLND) (B) Pooled analysis of thymic metastasis in patients undergoing thymectomy during CLND
Pathological Outcomes
[Table 4] displays the pathological outcomes reported in the included studies. The pooled
frequency of thymic metastasis was a mere 2% (95%CI, 0%-4%) in patients undergoing
either unilateral or bilateral thymectomy ([Fig. 3B]). Huang et al[7] reported a total of five cases of thymic metastases situated in the ipsilateral
thymus. No contralateral thymic metastases were found in either group. Likewise, Khatib
et al[6] also reported two cases of thymic metastases in the bilateral thymectomy group,
both of which were situated in the ipsilateral thymus on pathological examination.
Table 4
The pathological outcomes reported in the included studies
|
Variable
|
Khatib et al[6]
|
Huang et al[7]
|
Li et al[8]
|
|
TT + BT
(n = 45)
|
TT + UT
(n = 93)
|
TT + UT
(n = 73)
|
TT + BT
(n = 82)
|
TT
(n = 27)
|
TT + BT
(n = 27)
|
|
Lymph node metastases
|
|
|
Central compartment
|
20 (44.5%)
(all PTC)
|
53 (57%)
(PTC = 44; MC = 9)
|
NA
|
NA
|
14 (51.9%)
|
14 (51.9%)
|
|
Lateral ipsilateral
|
13 (28.9%)
(all PTC)
|
37(39.8%)
(PTC = 31; MC = 6)
|
NA
|
NA
|
NA
|
NA
|
|
Lateral contralateral
|
1 (2.2%)
(all PTC)
|
8 (8.6%)
(PTC = 6; MC = 2)
|
NA
|
NA
|
NA
|
NA
|
|
Thymic metastases
|
2 (4.4%)
|
0 (0%)
|
2 (2.7%)
|
3 (3.6%)
|
Nil
|
Nil
|
Abbreviations: BT, bilateral thymectomy; MC, medullary carcinoma; PTC, papillary thyroid
carcinoma; TT, total thyroidectomy; UT, unilateral thymectomy.
Discussion
The thymus is a specialized lymphoid organ located in the anterior superior mediastinum
associated with T-cell maturation and is critical to the adaptive immune system. The
presence of a blood thymic barrier restrains a direct contact of unwanted antigens
and tumor cells with the thymus and thereby prevents metastasis. However, on precise
analysis, structural variation in the cortex and medulla of the organ explains the
variable robustness of this barrier, which provides a possibility for metastasis.[9] The current systematic review shows that the pooled frequency of thymic metastasis
was a mere 2% in patients with DTC undergoing either unilateral or bilateral thymectomy.
Moreover, the present review also highlights that routine thymectomy (unilateral or
bilateral) does not improve lymph node yield in patients undergoing CLND. However,
a cervical extension of the thymus is frequently encountered in about two-thirds of
children and young adults as a direct continuation of mediastinal thymic tissue.[10] This cervical thymic extension may warrant selective resection in a particular patient
to achieve optimum lymph nodal clearance during CLND. A description of its extent
in the radiology report can serve as a useful guide to the surgeon contemplating CLND.
The results of our pooled analysis show that unilateral and bilateral thymectomy was
associated with high chances of transient hypocalcemia, albeit the pooled frequency
of permanent hypocalcemia was low. Lin et al[11] presented results of their retrospective cohort study including 3186 patients who
underwent thyroidectomy and reported that TT and CLND were independent risk factors
for incidental parathyroidectomy and resultant postoperative hypocalcemia. The low
rates of permanent hypoparathyroidism can be attributed to the fact that postoperative
parathyroid gland function mainly depends on the number of parathyroid glands remaining
in situ after thyroidectomy.[12] The resultant hypocalcemia serves as a trigger for the remaining parathyroid glands
to maintain the serum parathyroid hormone (PTH) values within the normal range.[13] Wide variation in the incidence of hypocalcemia across different studies may be
attributed to the surgeons' experience, surgical techniques, and the annual volume
of thyroidectomies at a particular center.
Thyroidectomy performed for carcinoma is a high-risk operation, as the posterior capsule
is radically dissected with the gland, placing the parathyroid glands as well as the
recurrent laryngeal nerve at higher risk of injury.[14] An additional thymectomy in such scenarios definitively increases the risk of transient
as well as permanent hypocalcemia in the postoperative period. However, the expertise
and experience of the operating surgeon undoubtedly remains a strong predictor of
final surgical outcomes. An association between aggressive treatment protocols and
deterioration in health-related quality of life (HRQoL) scores has been reported in
thyroid cancer survivors by various authors. The recent ATA guidelines have also emphasized
the need for developing validated patient-reported outcome measurement tools for assessing
the factors that have a bearing on the quality of life as a part of research on thyroid
cancer survivorship. Goswami et al[15] conducted an online survey of 1,743 thyroid cancer survivors, of which 98% underwent
surgery, using a patient-reported outcomes measurement information system (PROMIS)
29-item profile to evaluate their quality of life. The authors found that patient
age < 45 years, postoperative hypocalcemia, and dysphonia were among several other
factors that were associated with significantly worse HRQoL scores across various
PROMIS domains.
Therapeutic CLND for nodal metastases in DTC is well-accepted for cN1 disease. However,
controversy surrounds its role in cN0 neck, although acceptable results can be achieved
with low morbidity by an experienced thyroid surgeon.[3] There is a lack of robust data on survival outcomes with limited literature favoring
prophylactic dissection in view of improved disease-specific survival (DSS),[16] local recurrence,[17]
[18] and posttreatment Tg levels.[17]
[19] In the light of the paucity of literature on any additional survival benefit conferred
by the extensive resections in the central compartment, the question is raised as
to whether increasing the morbidity of resection by incorporating the thymus in the
resection specimen is a risk worth taking?
The main limitation of this systematic review was the limited number of studies addressing
the issue of routine thymectomy during the clearance of the central compartment in
DTC. Moreover, two of the three studies included in the review were retrospective
observational studies generating low-level evidence. One of them included 20 patients
with medullary thyroid cancer in their study.[6] The third study despite being a randomized control trial was a single institute
study with a limited sample size to evaluate the oncological completeness and a short
follow-up period to obtain convincing data on recurrence and metastasis. Lack of data
in the selected studies on the association of thymic metastases with the tumor stage,
extra thyroid extension, number of involved and sampled lymph nodes, size of the largest
involved lymph node, extranodal extension, and vascular invasion precluded establishing
any statistically significant correlation. Moreover, no meaningful correlation in
the lymph node yield following a CNLD could be calculated across various groups (TT
vs. bilateral thymectomy vs. no thymectomy) due to unavailability or scarcity of the
relevant data in the selected studies. Thus, large randomized controlled trials with
long-term follow-up are needed to generate reliable literature in this context. However,
a relatively indolent nature of the disease precludes ideal treatment research protocols
to be undertaken.
Conclusion
This systematic review elucidates that the literature on the role of thymectomy during
CLND in patients with DTC is sparse. As the thymectomy during CLND does not confer
any additional oncological benefit and is associated with a high risk of postoperative
hypocalcemia, thymic preservation must be considered by the operating surgeons, barring
the situations involving multiple metastatic nodes close to the thymus and warranting
selective thymectomy.
