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Introduction

Endometrial cancer is one of the most prevalent malignant tumors of the female genital tract, accounting for 6% of all cases of cancer in women (1). According to the American Cancer Society, the annual incidence of endometrial cancer is increasing, with ~40,880 new cases diagnosed in the USA in 2005 (2) and ~49,560 new cases in 2013 (3). The median age of patients with endometrial cancer is 58 years, and the 5-year overall survival (OS) rate of those in the early stages of the disease is 80–85% (4). The high incidence and mortality rate highlight the necessity for optimized therapy for patients with endometrial cancer.

The guidelines of the International Federation of Gynecology and Obstetrics (FIGO), which were updated in 2009 to include a revised pathology surgical staging system (5), recommend surgical therapy involving total hysterectomy and bilateral salpingo-oophorectomy, peritoneal washing and pelvic and/or para-aortic lymphadenectomy. The guidelines of the National Comprehensive Cancer Network (NCCN) also recommend that surgical staging include pelvic and para-aortic lymphadenectomies for women with endometrial cancer (6). According to guidelines (5,6), a lymphadenectomy should be performed when myometrial invasion is >50%, or in tumors of grade 3 or a special pathological type. Despite the FIGO and NCCN recommendations, the survival benefit of lymphadenectomy in early-stage endometrial cancer has not been clearly defined, and the extent and performance of lymphadenectomy varies from surgeon to surgeon. Several retrospective studies have suggested that a therapeutic benefit is associated with lymphadenectomy in early-stage endometrial cancer (7,8); however, two large randomized control studies have failed to demonstrate a survival advantage (9,10).

Similarly, the guidelines are lacking on how to treat pelvic and para-aortic lymph node metastases. Pelvic metastases may occur in up to 10% of patients with early-stage endometrial cancer, and para-aortic metastases may occur in as many as 6% (11). Although clinicians generally agree that surgery is the best curative treatment option, they may disagree regarding the optimal procedure to use.

Lymphadenectomy is widely used to assess whether endometrial cancer has metastasized and reduces the risk of lymphatic metastasis (8). Non-systematic lymphadenectomy usually involves removing <11 lymph nodes (7). However, to try to treat and prevent metastases, physicians often perform systematic lymphadenectomy, which involves removing ≥11 lymph nodes in the same area covered by non-systematic lymphadenectomy (9,10). Systematic lymphadenectomy is significantly more invasive than the non-systematic procedure, and leaves patients with markedly lower postoperative lymph function, increasing the risk of various complications (12). Given the controversy regarding whether systematic lymphadenectomy is justified for patients with early-stage endometrial cancer, the present study aimed to examine its safety and efficacy by systematically reviewing the literature.

Materials and methods

Search strategy

The current systematic review was conducted in accordance with the recommendations of the PRISMA statement (13). PubMed (www.ncbi.nlm.nih.gov/pubmed), Embase (www.embase.com), the Cochrane Library (www.cochranelibrary.com), and the China National Knowledge Infrastructure (www.cnki.net) databases (accessed April 2014) were searched during April 2014, without language restrictions and using the following search terms: ‘Lymphadenectomy’, ‘lymph nodes dissection’, ‘endometrial cancer’, ‘endometrial carcinoma’, ‘early stage’ and ‘low risk’.

Study selection and quality assessment

Randomized control trials (RCTs) and prospective or retrospective studies (non-RCTs) directly comparing systematic lymphadenectomy and no systematic lymphadenectomy in patients with clinically localized endometrial cancer were eligible for inclusion. Studies were included if they met the following criteria: i) They involved patients with pathologically proven early-stage endometrial cancer determined to be preoperative FIGO stage I or occult stage II disease; and ii) they provided data on Kaplan-Meier analysis of OS for patients who underwent surgical resection. Studies involving patients who were diagnosed with other malignant neoplasms were excluded.

The methodological quality of included RCTs was assessed according to the guidelines in the 2008 version of the Cochrane Handbook for Systematic Reviews of Interventions (14). RCTs were considered to be high-quality if they reported on three or four of the items, which included random allocation, concealment of random allocation, blinding of persons who assess treatment effects and intention-to-treat analysis. The methodological quality of the included non-RCTs was assessed using the star scoring system based on the Newcastle-Ottawa Scale (15), which examines the method used to select patients, the comparability of the study groups, and the number of outcomes reported. Non-RCTs were considered high-quality if they received >7 out of 10 possible stars.

Outcomes

The primary outcome of the current systematic review was OS. Data on recurrence-free survival (RFS), disease-free survival (DFS) and operative mortality and morbidity were captured as a secondary outcome where available. In addition, patients were classified into risk subgroups based on criteria from the Gynecologic Oncology Group and FIGO (5).

Data extraction

Data were extracted independently by two authors. Data included author details, publication year, preoperative staging, the number of patients, patient characteristics, interventions used and conclusions, using a data extraction form. Any discrepancies in data extraction were resolved by consensus.

Data synthesis

Owing to the clinical heterogeneity among studies, meta-analysis was not performed. Instead findings from each study were synthesized and evaluated qualitatively.

Results

Description of studies

A total of 2,184 potentially eligible studies were identified and, ultimately, 13 studies involving 51,155 patients were included in the review (Fig. 1). The total population included 20,676 patients in the systematic lymphadenectomy group and 30,479 patients in the no systematic lymphadenectomy group. Two of the 13 studies were RCTs (9,10) while the remaining 11 were retrospective non-RCTs (7,8,16–24). Study recruitment periods extended from 1969 to 2008, and the studies involved centers from Italy, the USA, Germany, South Korea, Canada and China. Two studies (20,24), involving a total of 253 patients, did not report the numbers of lymph nodes dissected in the systematic lymphadenectomy and no systematic lymphadenectomy groups. All studies were in English, except for two that were in Chinese (20,24). Two studies involved only the adenocarcinoma type of endometrial cancer (22,23), whereas the other studies involved endometrial cancer of various pathological types.

Figure 1. Selection of trials for a systematic review comparing systematic lymphadenectomy vs. no systematic lymphadenectomy in patients with early-stage endometrial cancer.

A total of 1,487 patients from four studies (10,17,22,24) underwent only pelvic lymph node dissection. As expected, the recurrence rate was higher in patients exhibiting greater numbers of cancer-positive lymph nodes or a greater extent of lymph node metastasis (7–10,17,19,22,23). The median number of lymph nodes removed during systematic lymphadenectomy ranged from 11 to 30. The key characteristics of the studies are presented in Table I.

Table I. Characteristics of included studies comparing systematic and no systematic lymphadenectomy in patients with early-stage endometrial cancer.

Table I.

Characteristics of included studies comparing systematic and no systematic lymphadenectomy in patients with early-stage endometrial cancer.

Study	Year	Follow-up, months	Preoperative stagea	Number of cases, SLA / no SLA	Interventionsb	Refs.
Kilgore et al	1995	36 (mean)	Stage I or occult Stage II	204 / 192	1. Based on pelvic or minus pelvic and para-aortic lymphadenectomy	(23)
			Low risk	137 / 135	with peritoneal washing
			High risk	67 / 57	2. Standard surgery group
Gao et al	2000	60	Stage I–II	67 / 70	1. Based on lymphadenectomy	(20)
			Low risk	17 / 28	2. Standard surgery group
			High risk	23 / 31
Ceccaroni et al	2004	60	Stage I and grades 1–3	55 / 75	1. Based on pelvic lymphadenectomy	(17)
					2. Standard surgery group Peritoneal cytology (washing) in all series
Cragun et al	2005	60	Stage I or occult Stage II	246 / 263	1. Based on pelvic or pelvic and aortic lymphadenectomy	(7)
			Low risk	123 / 152	2. Hysterectomy
			High risk	123 / 111
Benedetti et al	2008	60	Stage I	264 / 250	1. Based on pelvic or pelvic and aortic lymphadenectomy	(9)
					2. Standard surgery group other than bulky lymph node
Kang et al	2009	60	Stage I and grade 1 or 2	64 / 58	1. Based on pelvic lymphadenectomy	(22)
					2. Hysterectomy and/or bilateral salpingo-oophorectomy
Kitchener et al	2009	37 (median)	Stage I	546 / 573	1. Based on pelvic lymphadenectomy and sampling of para-aortic LNs	(10)
			Low risk	282 / 330	2. Standard surgery group other than suspicious LNs
			High risk	264 / 243
Ji et al	2009	60	Stage I	40 / 76	1. Based on pelvic lymphadenectomy	(24)
					2. Standard surgery group
Bassarak et al	2010	86 (median)	Stage I	120 / 51	1. Based on pelvic and/or para-aortic LNs	(16)
			Low risk	121 (total)	2. The standard surgery group
Jeong et al	2010	35 (median)	Stage I	547 / 211	1. Based on pelvic and/or para-aortic lymphadenectomy	(21)
			Low risk	566 (total)	2. Standard surgery group other than suspicious LNs
			High risk	162 / 30
Chino et al	2011	60 (median)	Stage I	18197 / 28252	1. Based on lymphadenectomy	(18)
			Low risk	12637 / 23364
			Intermediate risk	5097 / 4628	2. Standard surgery group
			High risk	463 / 260
Zhang et al	2012	42.5 (median)	Stage I	246 / 103	1. Based on optional systematic pelvic and/or para-aortic lymphadenectomy	(8)
			Low risk	212 (total)	2. Standard surgery group and peritoneal washing cytology
			Intermediate risk	137 (total)
Dowdy et al	2012	64 (median)	Stage I	80 / 305	1. Based on optional systematic pelvic and/or para-aortic lymphadenectomy	(19)
			Low risk	80 / 305	2. Standard surgery group and peritoneal washing cytology

a Based on FIGO criteria (5).

b Interventions: ‘1’ refers to the trial arm, which was treated by standard surgery (hysterectomy and bilateral salpingo-oophorectomy) as well as pelvic lymphadenectomy or pelvic and para-aortic lymphadenectomy; ‘2’ refers to the control arm, which was treated by standard surgery only. SLA, systematic lymphadenectomy; LNs, lymph nodes.

Methodological quality

Quality assessment scores of the included studies are summarized in Tables II and III. The RCTs were considered to be high quality as they reported at least three items. Similarly, the non-RCTs were judged to be of moderate to high quality, scoring 7–9 stars.

Table II. Assessment of methodological quality of randomized controlled trials included in the current review.

Table II.

Assessment of methodological quality of randomized controlled trials included in the current review.

Study	Random allocation (description of procedure)	Concealment of random allocation	Blinding of persons who assess treatment effects	Intention-to-treat analysis
Benedetti et al (9)	+	+	+	+
Kitchener et al (10)	+	+	+	−

Table III. Assessment of methodological quality of non-randomized trials included in the current review.a

Table III.

Assessment of methodological quality of non-randomized trials included in the current review.a

	Patient selectiona			Group comparabilityb		Outcome reportingc
Study	S1	S2	S3	C1	C2	O1	O2	Starsd
Kilgore et al (23)	*	*	*	*	*	*	*	7
Gao et al (20)	*	*	*	*	*	*	*	7
Ceccaroni et al (17)	*	*	*	*	**	*	**	9
Cragun et al (7)	*	*	*	**	*	*	**	9
Kang et al (22)	*	*	*	*	**	*	*	8
Ji et al (24)	*	*	*	*	*	*	*	7
Bassarak et al (16)	*	*	*	*	*	*	*	7
Jeong et al (21)	*	*	*	*	**	*	**	9
Chino et al (18)	*	*	*	*	**	*	*	8
Zhang et al (8)	*	*	*	*	**	*	*	7
Dowdy et al (19)	*	*	*	*	**	*	**	9

a Patient selection: S1, reported inclusion criteria; S2, reported that patients underwent surgery for lymphadenectomy of ≥11 lymph nodes; S3, reported that patients underwent surgery without lymphadenectomy or with lymphadenectomy of <11 lymph nodes.

b Group comparability (if yes to all, 2 stars; if one of these characteristics was not reported, 1 star; if the two groups differed, no star): C1, age, body mass index and ethnicity; C2, tumor histological type, tumor grade, tumor stage, nodal dissection quantity.

c Outcome reporting: O1, outcomes clearly reported (1 star); O2, quality of follow-up (2 stars if >90% patients followed up for 5 years).

d Out of a maximum possible 10 stars.

Clinical characteristics

The clinical characteristics of the 13 studies comprising 51,155 patients are listed in Tables I and IV. In the absence of international standards regarding the difference between the two types of lymphadenectomy, systematic dissection was considered to involve the removal of ≥11 lymph nodes (7–10,16–19,21–23), including the dissection of iliac, obturator (17,18,20,22,24) and selective para-aortic lymph nodes (7–10,16,19,21,23). The cases that were classed as not systematic lymphadenectomy consisted of 9 cases that did not undergo lymphadenectomy (8,16–20,22–24), 3 cases that involved the removal of suspicious lymph nodes (9,10,21) and 1 case that involved the removal of <11 nodes (7). As the definitions of systematic and no systematic lymphadenectomy were different among all 13 studies, systematic vs. no systematic lymphadenectomy were defined using two criteria: Systematic dissection of lymphatic tissues vs. no lymphadenectomy other than suspicious lymph nodes or not performed; and removal of <11 vs. ≥11 lymph nodes.

Table IV. Summary of results comparing survival outcomes for systematic lymphadenectomy vs. no systematic lymphadenectomy.

Table IV.

Summary of results comparing survival outcomes for systematic lymphadenectomy vs. no systematic lymphadenectomy.

Study	Survival no. (%)	No. of lymph nodes removed	Outcomes of systematic lymphadenectomy relative to no systematic lymphadenectomy	Refs.
Kilgore et al	>11 LNs, 204 (52%); 0 LNs, 192 (48%)	11 (mean)	Significantly improved OS	(23)
Gao et al	NR	NR	Did not significantly improve OS	(20)
Ceccaroni et al	>11 LNs, 55 (42%); 0 LNs, 75 (58%)	29 (median)	Did not significantly improve OS	(17)
Cragun et al	>11 LNs, 246 (48%); <11 LNs, 263 (52%)	15 (median)	Significantly improved OS (but not in low risk group) and PFS	(7)
Benedetti et al	>11 LNs, 264 (51%); 0 LNs, 250 (49%)	30 (median)	Did not significantly improve OS and DFS	(9)
Kitchener et al	>12 LNs, 546 (49%); <2 LNs, 573 (51%)	12 (median)	Did not significantly improve OS and RFS	(10)
Kang et al	>17.5 LNs, 64 (52%); 0 LNs, 58 (48%)	18 (mean)	Did not significantly improve OS and PFS	(22)
Ji et al	NR	NR	Did not significantly improve OS	(24)
Bassarak et al	>11 LNs, 120 (71%); 0 LNs, 51 (29%)	NR	Significantly improved OS and CSS, but not PFS	(16)
Jeong et al	>11 LNs, 547 (72.1%); 0 LNs, 211 (27.9%)	25 (median)	Significantly improved OS only in high risk group	(21)
Chino et al	>11 LNs, 18,197 (32%); 0 LNs, 28,252 (68%)	11 (median)	Significantly improved OS for intermediate and high risk groups	(18)
Zhang et al	>18 LNs, 246 (70%); 0 LNs, 103 (30%)	22 (mean)	Significantly improved OS and DFS	(8)
Dowdy et al	>11 LNs, 80 (21%); 0 LNs, 305 (79%)	30 (mean)	Did not significantly improve OS, RFS or CSS	(19)

[i] LNs, lymph nodes; NR, not reported; OS, overall survival; PFS, progression-free survival; DFS, disease-free survival; RFS, recurrence-free survival; CSS, cause-specific survival.

Association of disease-related survival associated with lymphadenectomy

Three studies (7,16,22) reported data on progression-free survival (PFS), which was significantly higher for patients who underwent systematic lymphadenectomy of ≥11 lymph nodes (86%) compared with those who underwent no systematic lymphadenectomy (75%; P<0.001) (7). This difference in PFS was particularly notable among patients with intermediate- and high-risk disease. The other two retrospective studies reported similar PFS for the systematic lymphadenectomy and no systematic lymphadenectomy groups (16,22).

One study reported that DFS was significantly higher for the group who underwent the systematic procedure involving ≥11 lymph nodes (88.1%) than for the no systematic procedure (76.3%; P<0.05) patients with intermediate- and high-risk disease (8). The same study also found DFS to be similar for the systematic and no systematic procedures among patients with low-risk disease (91.2% vs. 83.7%; P>0.05). Another study identified DFS to be marginally higher following the systematic procedure for patients of mixed risk types, but this difference did not achieve statistical significance (9).

Two studies examined RFS

One study reported that systematic lymphadenectomy involving removal of ≥11 lymph nodes was associated with lower RFS compared with no systematic lymphadenectomy, regardless of patient endometrial cancer risk classification (10). Another study (19) reported similar RFS for systematic lymphadenectomy and no systematic lymphadenectomy.

Taken together, these data suggest that systematic lymphadenectomy is associated with a higher combined rate of DFS and PFS and a lower recurrence rate when compared with no systematic lymphadenectomy (Tables IV and V).

Table V. Summary of results comparing disease-related survival for SLA vs. no SLA.

Table V.

Summary of results comparing disease-related survival for SLA vs. no SLA.

Study	Survival no. (%)	Summary survival dataa	P-value	Refs.
Progression-free survival
Cragun et al	>11 LNs, 246 (48%); <11 LNs, 263 (52%)	5-year rate: 86.0% vs. 75.0%	<0.001	(7)
		Low risk: 92.0% vs. 86.0%	>0.05
		High risk: 80.0% vs. 60.0%	0.001
Kang et al	>17.5 LNs, 64 (52%); 0 LNs, 58 (48%)	5-year rate: 96.6% vs. 98.3%	0.61	(22)
Bassarak et al	>11 LNs, 120 (71%); 0 LNs, 51 (29%)	5-year rate: 89.0% vs. 87.0%	0.69	(16)
Disease-free survival
Benedetti et al	>11 LNs, 264 (51%); 0 LNs, 250 (49%)	5-year rate: 81.7% vs. 81.0%	0.68	(9)
Zhang et al	>18 LNs, 246 (70%); 0 LNs, 103 (30%)	5-year rate: 89.0% vs. 80.7%	0.02	(8)
		Low risk: 91.2% vs. 83.7%	0.09
		Intermediate risk: 88.1% vs. 76.3%	0.03
Recurrence-free survival
Kitchener et al	>12 LNs, 546 (49%); <2 LNs, 573 (51%)	NR	0.35	(10)
		Low risk: HR, 0.63 (CI, −6.28–7.53)	0.86
		Intermediate and high risk:
		HR, 0.13 (CI, −9.69–9.95)	0.98
Dowdy et al	>11 LNs, 80 (21%); 0 LNs, 305 (79 %)	5-year rate: 96.0% vs. 97.6%	0.64	(19)
Cause-specific survival
Bassarak et al	>11 LNs, 120 (71%); 0 LNs, 51 (29%)	NR	0.04	(16)
Dowdy et al	>11 LNs, 80 (21%); 0 LNs, 305 (79%)	5-year rate: 97.3% vs. 99.0%	0.32	(19)

{ label (or @symbol) needed for fn[@id='tfn8-ol-0-0-4467'] } SLA, systematic lymphadenectomy; LNs, lymph nodes. NR, not reported; HR, hazard ratio; CI, 95% confidence interval.

a Survival data are presented as systematic lymphadenectomy vs. no systematic lymphadenectomy and include all data.

Association of OS with lymphadenectomy

The 5-year OS rate, determined from 11 studies (7–9,15,16,18–23), ranged from 73.1 to 98.3% (median, 90%) in the systematic lymphadenectomy group; this was higher than the rate in the no systematic lymphadenectomy group, which ranged from 68 to 98.4% (median, 88.2%). In the majority of studies, however, the OS difference did not achieve statistical significance. Among non-RCTs, only six trials (7,8,16,17,21,23) found the difference to be significant (P<0.05), and neither of the RCTs in the current review found the difference to be significant after analyzing subgroups with different risk classifications (9,10). The number of mortalities ranged from 1 to 53 patients across all studies, while recurrence ranged from 2.4 to 13.0%.

Subsequently, OS was investigated in subgroups of patients with different risk classifications. Seven studies reported subgroup data for a total of 38,489 patients with low-risk disease and 11,696 with intermediate- to high-risk disease (7,8,10,18,20,21,23). The non-RCTs reported significantly higher OS rates for the systematic lymphadenectomy than for the no systematic lymphadenectomy procedure in patients with intermediate- and high-risk disease (P<0.05) (7,8,18,21,23), while OS rates were similar for the two procedures among patients with low-risk disease. Data from these trials indicated a trend that removal of ≥11 lymph nodes was associated with more favorable OS compared with removal of <11 lymph nodes (7,8,18,21,23). The results for OS are summarized in Tables IV and VI.

Table VI. Overall survival comparison of systematic lymphadenectomy and no systematic lymphadenectomy, with and without stratification by risk subgroup.

Table VI.

Overall survival comparison of systematic lymphadenectomy and no systematic lymphadenectomy, with and without stratification by risk subgroup.

	Number of patients			Overall survivala
Study	Total	Mortalities	Recurrences	All risk groups	Stratified by risk group	P-value	Refs.
Kilgore et al	625	NR	NR	5-year rate: 87.0% vs. 71.0%		<0.001	(23)
					Low risk: 95% vs. 83%	0.53
					High risk: 63% vs. 36%	<0.001
Gao et al	137	NR	NR	5-year rate: 73.1% vs. 82.9%		>0.05	(20)
					Low risk: 82.4% vs. 96.4%	>0.05
					High risk: 73.9% vs. 74.2%	>0.05
Ceccaroni et al	130	1	NR	5-year rate: 92.7% vs. 88.2%		0.38	(17)
Cragun et al	509	4	48	5-year rate: 88.0% vs. 79.0%		<0.001	(7)
					Low risk: 94% vs. 89%	0.45
					High risk: 82% vs. 64%	0.001
Benedetti et al	514	53	67	5-year rate: 85.9% vs. 90.0%		0.50	(9)
Kang et al	122	2	3	5-year rate: 98.3% vs. 98.4%		0.95	(22)
Kitchener et al	1119	NR	NR	NR		0.55	(10)
					Low risk: HR, 0.38 (CI, −4.89–5.64)	0.88
					High risk: HR, 0.06 (CI, −8.65–8.77)	0.99
Ji et al	116	NR	12	5-year rate: 90.0% vs. 89.5%		>0.05	(24)
Bassrak et al	171	NR	NR	5-year rate: 89.0% vs. 68.0%		<0.001	(16)
Jeong et al	758	NR	NR	5-year rate: 95.0% vs. 93.1%		0.45	(21)
					High risk: 91.6% vs. 70.6%	0.009
Chino et al	46449	NR	NR	NR			(18)
					Low risk: 93.8% vs. 92.9%	NR
					Intermediate risk: 81.2% vs. 74.9%	<0.001
					High risk: 63.5% vs. 48.2%	<0.001
Zhang et al	349	32	40	5-year rate: 92.8% vs. 81.5%		0.001	(8)
					Low risk: 93.1% vs. 84.6%	0.17
					Intermediate risk: 86.2% vs. 73.3%	0.21
Dowdy et al	385	31	11	5-year rate: 94.2% vs. 92.1%		0.72	(19)

{ label (or @symbol) needed for fn[@id='tfn10-ol-0-0-4467'] } NR, not reported; HR, hazard ratio; CI, 95% confidence interval.

a Results are reported as systematic lymphadenectomy vs. no systematic lymphadenectomy and include all data.

Complications

The complications of lymphadenectomy were most often reported to be lymphocysts and lymphedema, both of which were reported in three studies (8,9,22). In one of these studies, the two complications occurred in 35 of the 264 patients (13.2%) in the systematic lymphadenectomy group, but in only 4 of the 250 patients (1.6%) in the no systematic lymphadenectomy group (8). In the other two studies, however, the rates of these complications were similar between the two groups. Infrequent complications were directly related to surgery (e.g., wound infection and nerve or bladder injury)or the patient's medical condition (e.g., bowel obstruction, deep venous thrombus and pneumonia). No surgery-related mortalities were reported in any of the included studies. Furthermore, no long-term complications and none of the reported complications appeared to significantly affect long-term survival.

Discussion

Whether systematic or no systematic lymphadenectomy is more appropriate for patients in the early stages of endometrial cancer is controversial. Although the systematic procedure should, in principle, offer better protection against metastasis and recurrence, the current systematic review of studies involving a total of >50,000 patients from 6 countries suggests that systematic lymphadenectomy does not reliably improve survival time over no systematic lymphadenectomy when patients of all endometrial cancer risk classes are combined. In addition, the systematic procedure may be associated with higher rates of complications, including lymphedema and lymphocysts, which reduce postoperative quality of life and increase risk of mortality (12,25).

In the enrolled studies, the results were not consistent. Certain studies reported no difference in OS rates between systematic and no systematic lymphadenectomy (9,10), while other studies indicated that systematic lymphadenectomy improved OS (7,8,16,17,21,23). These results must be interpreted carefully for a number of reasons. Firstly, it is possible that only a small proportion of patients in the systematic lymphadenectomy group underwent para-aortic lymphadenectomy; in one study, for example, the proportion was only 26% (9). Secondly, it is possible that a high proportion of patients in the systematic lymphadenectomy group did not, in fact, undergo such extensive dissection; in one study, for example, 60% of the systematic lymphadenectomy group underwent dissection of <14 lymph nodes, including the pelvic lymph nodes but not the para-aortic ones (10). Furthermore, systematic and no systematic lymphadenectomy were defined differently among the included studies; six studies presented a vague definition of systematic and no systematic lymphadenectomy (9,10,16,18,20,24), while seven studies showed definite cut-off values of numbers of removed lymph nodes for defining the two types of lymphadenectomy (7,8,17,19,21–23). As previous studies have emphasized that the number of removed lymph nodes affects survival in patients with endometrial cancer (26,27), the diverse definitions of systematic lymphadenectomy may be the cause of the different efficacies of systematic lymphadenectomy for OS in patients with endometrial cancer.

The role of adjuvant radiation in early-stage endometrial cancer is also controversial. Eight of the enrolled studies, involving a total of 50,046 patients, reported the use of postoperative adjuvant radiotherapy (7,9,10,16–18,21,23). Four studies (7,16,18,23) observed that systematic lymphadenectomy in patients with grade III lesions and deep myometrial invasion and who were receiving postoperative adjuvant radiotherapy resulted in better survival than no systematic lymphadenectomy. However, four studies (9,10,17,21) reported similar survival rates when comparing patients receiving adjuvant radiotherapy. There may be potential for bias due to adjuvant radiation blunting the effect of systematic lymphadenectomy. Therefore, future investigation is required to define the role of adjuvant radiation in early-stage endometrial cancer.

Nevertheless, the current analysis does provide evidence that systematic lymphadenectomy leads to higher OS rates than the no systematic procedure specifically in patients with intermediate- or high-risk early-stage endometrial cancer. Removing ≥11 lymph nodes from these patients led to more favorable OS compared with the removal of a smaller number, regardless of the cancer status of the lymph nodes. However, no definitive guidelines are available regarding the number of lymph nodes that should be dissected. Although nodal count is indicative of the extent of lymphadenectomy, the number of nodes reported by the pathologist depends not only on anatomical variations in patients, but also on surgical expertise and the comprehensiveness of pathological analysis. Chan and Kapp (28) reported that systematic removal of all lymphatic tissue in the retroperitoneal region may be the most accurate definition of a complete lymphadenectomy. These findings suggest that systematic lymphadenectomy to remove ≥11 lymph nodes, or even a complete systematic removal of all lymphatic tissue, may be appropriate therapy for patients with intermediate- or high-risk early-stage endometrial cancer.

Metastasis of endometrial cancer to the lymph nodes worsens prognosis and increases the risk of lymphatic recurrence (29); 90% of patients who suffer such recurrence succumb to the disease (30). One study reported 5-year survival rate of 90% for patients with stage I endometrial cancer, compared to only 54% for patients with metastatic stage III disease (31).

Several studies suggest that lymph node resection is more reliable than surgery alone to determine whether endometrial cancer has metastasized and to reduce the risk of metastasis (10,11,32). Although one study reported that only 4.6% of patients with low-risk disease (stage I, grade 1) have lymph node metastases (32), other studies have reported that 98% of patients with para-aortic involvement have grossly positive pelvic nodes (11), and that 9% of stage I patients have positive pelvic lymph nodes while 6% have positive para-aortic nodes (33). Although several histopathological risk factors have been demonstrated to correlate closely with lymph node metastasis, including tumor grade, depth of myometrial invasion and the presence of 30–50% serous or clear cell histology (34), lymphadenectomy remains the most direct way to assess and reduce risk of metastasis. Previous studies reported that high-risk patients who undergo para-aortic lymphadenectomy as part of their surgical staging procedure exhibit higher survival rates than those who undergo simple surgical staging (35,36).

The current systematic review suggests that systematic lymphadenectomy should be applied carefully to patients with early-stage endometrial cancer, as it is unlikely to produce clinical benefits in a high proportion of patients. A similar story emerges from systematic reviews of lymphadenectomy to treat for other malignancies, including prostatic cancer (37) and gastric cancer (38,39). These reviews come to divergent conclusions, and the overall evidence of clinical benefit is weak. This highlights the need for more prospective, high-quality, controlled studies of the safety and efficacy of systematic lymphadenectomy, in the context not only of endometrial cancer but of other cancers as well.

While this systematic review contributes significantly to the literature by examining a large number of patients in several countries and ethnic groups, its findings are nevertheless subject to several limitations. Firstly, only two of the included trials are RCTs, while the remaining 11 are retrospective non-RCTs. Secondly, patient selection, techniques used to dissect lymph nodes and perform surgery, and postoperative care and follow-up varied substantially across the included studies, which weakens the strength of the conclusions. Thirdly, a previous meta-analysis (40) has shown that, in one of the included trials (26), which accounts for 12,333 of the patients in the population included the present study, body mass index varies significantly between the systematic and no systematic lymphadenectomy groups and that controlling for this leads to a significantly higher OS rate for the systematic lymphadenectomy group than for the no systematic lymphadenectomy group. This highlights the requirement for future studies to control for all possible confounders when examining the clinical effects of systematic lymphadenectomy.

In conclusion, the available evidence suggests that systematic lymphadenectomy may improve OS in patients with intermediate- or high-risk early-stage endometrial cancer, particularly when ≥11 lymph nodes are removed; however, this may not be the case in patients with low-risk disease. In addition, systematic lymphadenectomy may be associated with higher rates of lymphocysts and lymphedema. These findings argue that the use of systematic lymphadenectomy in carefully selected patients may improve endometrial cancer staging, choice of adjuvant therapy and prognosis prediction.

Acknowledgements

This work was supported by the National Natural Science Foundation of China (project no. 81060219).

References