Association between Lymph Node Counts and Oncological Outcomes in Lymph Node Positive Prostate Cancer

Association between Lymph Node Counts and Oncological Outcomes in Lymph Node Positive Prostate Cancer

EUF-133; No. of Pages 8 EUROPEAN UROLOGY FOCUS XXX (2016) XXX–XXX available at www.sciencedirect.com journal homepage: www.europeanurology.com/eufocu...

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EUF-133; No. of Pages 8 EUROPEAN UROLOGY FOCUS XXX (2016) XXX–XXX

available at www.sciencedirect.com journal homepage: www.europeanurology.com/eufocus

Platinum Priority – Prostate Cancer Editorial by XXX on pp. x–y of this issue

Association between Lymph Node Counts and Oncological Outcomes in Lymph Node Positive Prostate Cancer Philipp Mandel a,b, Maximilian C. Kriegmair c, Katharina Bogdan a, Katharina Boehm b, Lars Buda¨us a, Markus Graefen a, Hartwig Huland a, Derya Tilki a,b,* a

Martini-Klinik Prostate Cancer Center, University Hospital Hamburg-Eppendorf, Hamburg, Germany;

b

Department of Urology, University Hospital

c

Hamburg-Eppendorf, Hamburg, Germany; Department of Urology, University Medical Centre Mannheim, Mannheim, Germany

Article info

Abstract

Article history: Accepted February 28, 2016

Background: While the diagnostic value of pelvic lymph node dissection (PLND) during radical prostatectomy (RP) is undisputed, its therapeutic benefit remains a matter of debate. Objective: To investigate the association between total and positive lymph node (LN) counts and oncological outcomes in pN1 patients at RP. Design, setting, and participants: The records of 706 LN-positive patients undergoing RP and PLND between 1998 and 2012 in a single center were analyzed. The median follow-up was 47.8 mo. Intervention: RP and PLND. Outcome measurements and statistical analysis: The number of harvested and positive LNs and their influence on biochemical recurrence-free survival, metastasis-free survival, and cancer-specific survival was evaluated using univariate and multivariate Cox regressions. The number of harvested LNs was used as a continuous and dichotomous variable with a cut-off of 13 LNs. Results and limitations: The mean (median) number of removed LNs was 15.0 (13) and the mean (median) number of positive LNs was 2.4 (1). In multivariate analysis, the number of removed LNs did not significantly influence oncologic outcomes (biochemical recurrence, metastasis-free survival, or cancer-specific survival). The occurrence of metastasis and cancer-specific mortality significantly increased with higher number of positive LNs. The main limitation was the retrospective nature of the study. Conclusions: While a higher number of positive LNs were significantly associated with worse oncological outcomes, the number of removed LNs was not a significant predictor. Patient summary: We found that only the number of positive lymph nodes (LNs) but not the total number of removed LNs was a factor adversely influencing oncological outcomes in LN-positive patients undergoing radical prostatectomy. # 2016 European Association of Urology. Published by Elsevier B.V. All rights reserved.

Associate Editor: James Catto Keywords: Prostate cancer Radical prostatectomy Lymph node dissection Positive lymph nodes

* Corresponding author. Martini-Klinik Prostate Cancer Center, Martinistrasse 52, 20246 Hamburg, Germany. Tel. +49 4074100; Fax: +49 4074100. E-mail address: [email protected] (D. Tilki).

1.

Introduction

Prostate cancer is the most frequent cancer among men in Europe and other developed countries and among the

leading causes of death [1,2]. For its treatment, radical prostatectomy (RP) is one of the recommended treatment options for all levels of risk. Pelvic lymph node dissection (PLND) is the most precise staging procedure for possible

http://dx.doi.org/10.1016/j.euf.2016.02.018 2405-4569/# 2016 European Association of Urology. Published by Elsevier B.V. All rights reserved.

Please cite this article in press as: Mandel P, et al. Association between Lymph Node Counts and Oncological Outcomes in Lymph Node Positive Prostate Cancer. Eur Urol Focus (2016), http://dx.doi.org/10.1016/j.euf.2016.02.018

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lymph node (LN) metastasis; however, its therapeutic benefit concerning oncologic outcome remains controversial [3–6]. According to the guidelines of the European Urological Association (EAU), whenever a PLND is indicated, an anatomically extended PLND should be performed [7]. To present, Level IB evidence from randomized controlled trials on the oncological role of PLND is lacking. The Prospective Study to Compare a Limited Versus Extended Pelvic Lymphadenectomy During Prostatectomy (NCT01555086) is currently recruiting participants. Several retrospective studies could not show that removing more LNs during RP results in improved oncological outcome in patients with pN0 [8], pN0 or pN1 [9], and pN1 [10] only. In contrast, Abdollah et al. [11] recently reported that a higher number of removed LNs is an independent predictor of a more favorable cancer-specific survival (CSS) in LN-positive patients [11]. All patients included in the study received immediate adjuvant hormonal treatment (ADT). This study was followed by a controversial discussion on potential biases and confounders involved in this type of analysis, including the Will Rogers phenomenon possibly explaining the results [12,13]. It remains questionable whether a higher number of removed LNs, regardless if these additional removed LNs harbor metastases or not, impacts oncologic outcome. The aim of the present study was to analyze the influence of the extent of PLND according to the number of removed LNs in pN1 patients at RP on biochemical recurrence (BCR), metastasis, and cancer-specific mortality (CSM) in a large single center and to add further information to the controversial ongoing discussion using a dataset of more than 700 LN-positive patients. 2.

Materials and methods

treatment was defined as immediate treatment administered within 6 mo after RP with an undetectable PSA (< 0.2 ng/ml), while salvage treatment was defined as treatment administered at a postoperative PSA 0.2 ng/ml.

2.2.

Surgical procedure and histologic evaluation

RP was performed using an open retropubic approach or robotic-assisted laparoscopic approach by high volume surgeons, as previously described [14]. Pathological outcome was assessed using the American Joint Cancer Committee 2002 staging system and tumor grading was classified using the Gleason Grading system [15]. From 2004, the template of PLND was in accordance with the EAU guidelines for anatomically extended PLND and included removal of the nodes overlying the external iliac artery and vein, the nodes within the obturator fossa located cranially and caudally to the obturator nerve, and the nodes medial and lateral to the internal iliac artery [7]. Before 2004, bilateral PLND was not uniformly performed with extended template and mainly included the region of the obturator fossa and along the external iliac artery. As the pathologic examination of LNs has changed during the study period due to advances in LN metastasis detection via the introduction of complete embedding of fat tissue, an increase in the detection of harvested LNs may have occurred. We introduced dummy variables to control for both the change in PLND template and change in pathologic examination in all multivariate regressions. To control for further unobserved time-dependent variation we included the year of surgery in all regressions.

2.3.

Statistical analyses

To check for differences in our respective subsamples Pearson’s Chi-square tests and Kruskall-Wallis tests were performed. To evaluate the association between removed lymph nodes and oncologic outcome (MFS and CSS) Kaplan-Meier curves and uniand multivariate Cox proportional hazard models adjusting for pre- and postoperative prognosticators were assessed. These prognosticators included age at surgery, preoperative PSA, pathologic Gleason score, pT-stage, surgical margin status, number of positive LNs, year of surgery,

2.1.

Patient population

neoadjuvant treatment, adjuvant ADT, salvage ADT, adjuvant RT, and salvage RT. Statistical software STATA was used (version 14 for

From our institutional Martini-Klinik database, we identified 969 out of

Windows, StataCorp LP, College Station, TX, USA). LN count was used

15 947 patients who underwent RP at our institution between January

as both, continuous and dichotomous variable. For dichotomization all

1998 and December 2012 with positive LNs in the final pathology.

cut-offs between 5 and 25 removed LNs were analyzed. As all cut-off

Information on the number of harvested LNs at PLND was missing in

values of removed LNs showed only insignificant differences on

75 men. Moreover patients who were lost to follow up within 24 mo

oncological outcomes, we presented the results at a cut-off value of

after RP were excluded (188), which left 706 patients for our analysis.

13 (median of removed LNs).

Furthermore, for analysis of BCR, patients with ADT were excluded from regressions (242 patients). All data were collected prospectively into our review board-approved database. Patients were stratified according to

3.

Results

3.1.

Patient and tumor characteristics

the number of removed LNs. Indication to perform PLND was in accordance to respective EAU guidelines applicable at the relevant time and partly based on an individual approach [7]. BCR was defined as a prostate-specific antigen (PSA) level 0.2 ng/ml and rising after RP in patients without ADT. Metastasis was confirmed with imaging. The cause of death was determined by the treating physicians, by chart review corroborated by death certificates, or by death certificates alone. After RP, patient follow up consisted of periodical PSA testing and digital rectal examination. Postoperative imaging studies to detect local recurrence or systemic spread were performed according to PSA level, patients’ preferences, and further symptoms. Adjuvant hormonal and/ or radiation therapy (RT) was recommended based on further patient and tumor characteristics and according to respective EAU guidelines applicable at the relevant time [7]. Adjuvant

Patient and tumor characteristics of the entire cohort and stratified by the number of removed LNs (high LN count [> 13] and low LN count [ 13]) are summarized in Table 1. In the entire population of LN positive patients, the mean (median) number of removed LN was 15.0 (13) and the mean (median) number of positive LN was 2.4 (1). Next to number of removed LNs and number of positive LNs, LN density (ratio of the number of metastatic LNs to the total number of LNs removed; p < 0.001) and Gleason score (p = 0.002) were significantly different between patients with a high and low LN count.

Please cite this article in press as: Mandel P, et al. Association between Lymph Node Counts and Oncological Outcomes in Lymph Node Positive Prostate Cancer. Eur Urol Focus (2016), http://dx.doi.org/10.1016/j.euf.2016.02.018

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Table 1 – Demographics and tumor characteristics stratified by number of removed lymph nodes Entire cohort (n = 706) Age (yr), mean PSA (ng/ml), mean Removed LNs Mean Median IQR Positive LNs Mean Median IQR LN density Mean Median IQR Gleason score 7 8 Pathologic stage pT2 pT3a pT3b pT4 Surgical margins Negative Positive Hormonal therapy Neoadjuvant Adjuvant Salvage Radiation therapy Adjuvant Salvage

64.5 21.0

LNs removed 13 (n = 376)

LNs removed >13 (n = 330)

64.4 19.0

15.0 13 9–19

64.6 23.3

8.6 9 6–11

p value

0.448 0.068 <0.001

22.3 20 16–26 <0.001

2.4 1 1–3

1.8 1 1–2

3.1 2 1–3

0.189 0.133 0.083–0.250

0.223 0.167 0.111–0.272

0.151 0.087 0.053–0.174

<0.001

0.002 62.6% 37.4%

68.8% 31.2%

55.6% 44.4%

6.9% 22.7% 67.3% 3.1%

6.9% 25.8% 63.6% 3.7%

7.0% 19.1% 71.5% 2.4%

49.5% 50.5%

52.8% 47.2%

45.7% 54.3%

14.0% 20.5% 33.0%

13.3% 20.7% 34.3%

14.9% 20.3% 31.5%

0.554 0.885 0.431

23.6% 32.9%

23.7% 30.3%

23.6% 35.8%

0.992 0.125

0.159

0.068

IQR = interquartile range; LN = lymph node; PSA = prostate-specific antigen.

The overall percentage of patients undergoing hormonal treatment after RP was 53.5% (20.5% adjuvant and 33.0% salvage hormonal treatment). The overall rate of RT was 56.5%, whereas patients underwent salvage RT more often (32.9%) than adjuvant RT (23.6%). 3.2.

Oncological outcome

The median follow-up was 47.8 mo (interquartile range: 27.3–68.8). Within the follow-up period 75.0%, 22.4%, and 6.2% of the patients showed BCR, metastasis, or cancerspecific death, respectively. In univariate analysis, the number of removed LNs was significantly associated with BCR (hazard ratio [HR] 1.015, p = 0.019) and occurrence of metastasis (HR 1.023, p = 0.026; Table 2). In contrast, in multivariate analysis, the number of removed LNs did not significantly influence oncologic outcomes (BCR, MFS, and CSM). When stratifying patients by LN count (> 13 vs  13), patients with 13 or less removed LNs had a significantly better BCR-free (p = 0.003) and MFS (p = 0.006), while there was no difference in CSS between both patient groups (Fig. 1A–C). In multivariate analysis this association was not significant. The number of positive LNs was significantly associated with BCR in univariate analysis (HR: 1.091, p < 0.001), but not in multivariate analysis (HR: 1.029, p = 0.194; Table 2).

Occurrence of metastasis and cancer-specific mortality significantly increased with a higher number of positive LNs in both uni- (HR: 1.157, p < 0.001 for metastasis and HR: 1.187, p < 0.001 for CSM) and multivariate (HR: 1.110, p < 0.001 for metastasis and HR: 1.137, p = 0.001 for CSM; Tables 3 and 4) analyses. Oncologic outcome stratified by the number of positive LNs is depicted in Figure 2A–C. A higher LN density was a significant factor adversely affecting BCR-free survival (HR: 2.84, p = 0.001), MFS (HR: 7.60, p < 0.001), and CSS (HR: 11.67, p < 0.001) in univariate and MFS (HR: 4.01, p = 0.001) and CSS (HR: 4.71, p = 0.014) multivariate regressions. 4.

Discussion

While the diagnostic value of a LN dissection during RP is undisputed, its therapeutic benefit still remains a matter of debate. The evidence with regards to the impact of a higher number of removed LNs during PLND on oncological outcomes in prostate cancer patients undergoing RP is limited [12,13]. Several retrospective studies have been published on the topic, which have shown conflicting results. Masterson et al. [9] reviewed 4611 patients undergoing RP and showed that an increased number of removed LNs was associated with higher BCR-free probabilities in pN0 patients, but not in the

Please cite this article in press as: Mandel P, et al. Association between Lymph Node Counts and Oncological Outcomes in Lymph Node Positive Prostate Cancer. Eur Urol Focus (2016), http://dx.doi.org/10.1016/j.euf.2016.02.018

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Table 2 – Uni- and multivariate analysis predicting oncologic outcome in patients with pN1 Biochemical recurrence Univariate analysis

Age (yr) PSA (ng/ml) Gleason score pT-stage pT2/pT3a pT3b pT4 Surgical margin Negative Positive Removed LNs Positive LNs Yr of surgery

Multivariate analysis

HR

95% CI

p value

HR

95% CI

p value

1.001 1.011 1.392

0.98–1.02 1.01–1.02 1.23-1.57

0.936 <0.001 <0.001

1.000 1.008 1.244

0.98–1.02 1.00–1.01 1.09–1.42

0.945 0.001 0.001

Ref. 1.973 1.004

1.54–2.53 0.32–3.17

<0.001 0.995

1.511 0.509

1.14–2.00 0.16–1.66

0.004 0.263

Ref. 1.721 1.015 1.091 1.048

1.36–2.18 1.00–1.03 1.05–1.13 1.01–1.09

<0.001 0.019 <0.001 0.013

1.351 1.011 1.029 0.992

1.04–1.76 1.00–1.03 0.99–1.07 0.91–1.09

0.026 0.153 0.194 0.872

CI = confidence interval; HR = hazard ratio; LN = lymph node; PSA = prostate-specific antigen; Ref. reference.

1.00

B

0.00

0.00

0.25

0.25

0.50

0.50

0.75

0.75

A

without PLND between 1988 and 1991 with a minimum follow-up of 10 yr. In line with Masterson et al. [9], the authors reported that pN0 patients with removal of at least 10 LNs had a lower CSM compared with patients without a

1.00

entire group. The median number of removed LNs was nine in this study [9]. Joslyn and Konety [16] studied the data of almost 13 000 patients from the Surveillance, Epidemiology, and End Results (SEER) database undergoing RP with or

0

50

Analysis time

150

50

0

More than 13 LNs removed

150

13 or less LNs removed

More than 13 LNs removed

0.00

0.25

0.50

0.75

C

100

Mo after surgery

1.00

13 or less LNs removed

100

0

50

100

150

Mo after surgery 13 or less LNs removed

More than 13 LNs removed

Fig. 1 – Survival stratified by number of lymph nodes (LNs) removed in (A) biochemical recurrence-free survival (= 13 vs > 13; p = 0.003), (B) metastasisfree survival (= 13 vs > 13; p = 0.006), and (C) cancer-specific survival (= 13 vs > 13; p = 0.760).

Please cite this article in press as: Mandel P, et al. Association between Lymph Node Counts and Oncological Outcomes in Lymph Node Positive Prostate Cancer. Eur Urol Focus (2016), http://dx.doi.org/10.1016/j.euf.2016.02.018

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Table 3 – Uni- and multivariate analysis predicting oncologic outcome in patients with pN1 Occurrence of metastasis Univariate analysis

Age (yr) PSA (ng/ml) Gleason score pT-stage pT2/pT3a pT3b pT4 Surgical margin Negative Positive Removed LNs Positive LNs Yr of surgery Adjuvant treatment No Yes Salvage treatment No Yes

Multivariate analysis

HR

95% CI

p value

HR

95% CI

p value

0.967 1.005 1.625

0.94–0.99 1.00–1.01 1.36–1.95

0.009 0.091 <0.001

0.972 1.000 1.475

0.95–1.00 0.99–1.01 1.20–1.82

0.040 0.932 <0.001

Ref. 2.795 6.542

1.74–4.48 2.89–14.8

<0.001 <0.001

1.959 4.459

1.17–3.27 1.82–10.9

0.010 0.001

Ref. 1.464 1.023 1.157 1.070

1.03–2.08 1.00–1.04 1.11–1.20 1.00–1.15

0.034 0.026 <0.001 0.054

1.006 0.997 1.110 1.047

0.67–1.52 0.97–1.02 1.06–1.17 0.89–1.23

0.982 0.809 <0.001 0.566

Ref. 0.801

0.55–1.16

0.238

0.587

0.37–0.92

0.021

Ref. 1.504

1.06–2.13

0.021

1.313

0.89–1.94

0.173

CI = confidence interval; HR = hazard ratio; LN = lymph node; PSA = prostate-specific antigen; Ref. reference.

PLND and therefore unknown pN status. Bivalacqua and colleagues [6] analyzed the data of 94 LN-positive patients undergoing anatomically extended or limited PLND at the time of RP and showed that extended PLND was associated with a trend toward improved BCR-free survival (p = 0.064), which was particularly seen in the group of patients with <15% positive LNs (p = 0.016). Moreover, the authors found a significant improvement in MFS in the group of patients with extended PLND (p = 0.045), while no difference was seen in CSS. The study was limited by its small sample size

and the fact that RP was performed by only two surgeons, whereby one routinely performed a limited PLND, while the second performed an extended PLND. Using a large single center dataset with more than 700 pN1 patients at RP, we could not show a significant positive effect of a higher number of LNs removed on oncological outcomes (BCR, MFS, or CSM) in uni- and multivariate analyses, neither when using the number of removed LNs as a continuous nor as a dichotomous variable. Moreover, a variation of the cut-off for high versus low

Table 4 – Uni- and multivariate analysis predicting oncologic outcome in patients with pN1 Cancer-specific mortality Univariate analysis

Age (yr) PSA (ng/ml) Gleason score pT-stage pT2/pT3a pT3b pT4 Surgical margin Negative Positive Removed LNs Positive LNs Yr of surgery Adjuvant treatment No Yes Salvage Treatment No Yes

Multivariate analysis

HR

95% CI

p value

HR

95% CI

p value

1.005 0.992 2.412

0.96–1.05 0.97–1.01 1.74–3.34

0.845 0.435 <0.001

1.004 0.987 2.133

0.95–1.06 0.97–1.01 1.42–3.20

0.872 0.211 <0.001

Ref. 4.780 19.82

1.69–13.5 5.74–68.4

0.003 <0.001

2.393 5.977

0.78–7.30 1.45–24.7

0.125 0.013

Ref. 2.239 1.019 1.187 0.998

1.20–4.19 0.98–1.06 1.12–1.26 0.89–1.11

0.012 0.325 <0.001 0.975

1.580 0.999 1.137 0.970

0.76–3.28 0.95–1.06 1.05–1.23 0.73–1.29

0.220 0.982 0.001 0.838

Ref. 0.912

0.48–1.72

0.776

0.465

0.18–1.19

0.110

Ref. 1.032

0.57–1.88

0.918

1.073

0.44–2.64

0.879

CI = confidence interval; HR = hazard ratio; LN = lymph node; PSA = prostate-specific antigen; Ref. reference.

Please cite this article in press as: Mandel P, et al. Association between Lymph Node Counts and Oncological Outcomes in Lymph Node Positive Prostate Cancer. Eur Urol Focus (2016), http://dx.doi.org/10.1016/j.euf.2016.02.018

EUF-133; No. of Pages 8 6

1.00

B

0.00

0.00

0.25

0.25

0.50

0.50

0.75

0.75

A

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EUROPEAN UROLOGY FOCUS XXX (2016) XXX–XXX

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Analysis time

150

0

50

2 positive LNs 4 or more positive LNs

150

1 positive LN 3 positive LNs

2 positive LNs 4 or more positive LNs

0.00

0.25

0.50

0.75

C

100

Mo after surgery

1.00

1 positive LN 3 positive LNs

100

0

50

100

Mo after surgery

1 positive LN 3 positive LNs

150

2 positive LNs 4 or more positive LNs

Fig. 2 – Survival stratified by number of positive lymph nodes (LNs) in (A) biochemical recurrence-free survival (1 vs 2 vs 3 vs 4+; p < 0.001), (B) metastasis-free survival (1 vs 2 vs 3 vs 4+; p < 0.001), and (C) cancer-specific survival (1 vs 2 vs 3 vs 4+; p = 0.001).

counts of removed LNs did not qualitatively alter our results. In contrast, both higher number of positive LNs and higher LN density had a negative impact on oncological outcomes. Patients with more removed LNs had adverse tumor characteristics (higher Gleason score) compared with patients with a lower LN count, which explains the significant negative impact of a higher number of removed LNs on oncological outcome seen in the univariate regressions. When controlling for tumor characteristics in multivariate analysis, this effect was not seen. Similarly, utilizing the Johns Hopkins Radical Prostatectomy Database (1982–2011), Pierorazio et al. [10] showed the number and percent of positive LNs to be an independent predictor of oncologic outcome in 505 LN positive patients who underwent RP and either extended or standard PLND. Furthermore, again conforming to our results, the number of removed LNs did not predict oncological outcomes in their patient cohort [10]. However, less than 12% had more than two positive LNs in this study compared with 26% in our patient population and results of this study are mainly derived from pre- (1982–1990) and early (1991–2000) PSA-era patients.

These results are in contrast to a recently published study by Abdollah et al. [11] who reported their data of 315 LN positive patients who underwent RP and PLND in the contemporary PSA-era from 2000 to 2012. The authors observed that the removal of a higher number of LNs during RP was associated with improvement in CSS rate. All patients included in the study received immediate ADT [13]. Therefore, the results of the present study are not directly comparable to those of Abdollah and colleagues [11]. In the present study, only 53.5% (20.5% adjuvant and 33.0% salvage hormonal treatment) received ADT, enabling us to control for this potential confounder. Moschini et al. [17] reported similar results using data from patients with pT3 and pT4 cancers with or without LN invasion. The removal of a higher number of LNs during RP in these patients was associated with higher CSS rates [17]. In another study, Abdollah et al. [18] developed a nomogram to predict CSM in LN-positive patients using a large dataset of more than 1100 patients from two tertiary centers. The results of this study were in line with our reported results. While the number of positive LNs was a significant prognosticator influencing CSM, the number of

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LNs removed had no significant influence on CSM and therefore was omitted for the nomogram. When applying our cohort to the nomogram, the predicted mean 10-yr CSS is very close to the observed one, especially in patients receiving adjuvant RT (predicted rate of approximately 93%, observed rate of 95%). In patients without adjuvant RT, however, the rate of predicted and observed 10-yr CSS differed (85% vs 73%). Besides the number of positive LNs, higher LN density, a surrogate for the extent of metastatic spread, was demonstrated to be a prognostic factor adversely influencing oncologic outcomes in the present study. As in our population number of negative nodes removed did not influence oncologic outcome, the association of LN density with oncological outcome is mainly driven by number of positive LNs. Counts of removed LNs, which may be influenced by other factors than extent such as patient characteristics, surgical, and pathologic expertise [19,20], varied from three to 67 documented removed LNs. The mean and median number as well as the range of the number of removed LNs is comparable to other studies including patients with anatomically extended PLND [6,11,18,21–23]. Patients may benefit from a removal of all positive LNs and the likelihood for a complete removal may increase with increasing LN counts. However, a more extensive PLND with a yet to be proven therapeutic advantage is associated with a higher complication rate and prolongation of operative time [24]. Currently, the effect of an extended versus limited PLND is investigated in the prospective randomized Prospective Study to Compare a Limited Versus Extended Pelvic Lymphadenectomy During Prostatectomy study (NCT01555086), which is recruiting participants at present. There are several further important limitations to our study. First and foremost are the limitations inherent to retrospective analyses. Secondly, the population in this study underwent surgery by multiple surgeons. This might have had an effect on the number of removed LNs and oncological outcome. Moreover the follow-up period of 48 mo was relatively short. Furthermore, patients with adjuvant and salvage therapy were not excluded in the present study, which may have affected our results even after controlling for additional treatment in multivariate analysis. The type and duration of hormonal treatment differed among patients and was not standardized. Additionally, the number of removed LNs may have been influenced by tumor characteristics. Finally, the study period spans 15 yr with several diagnostic and surgical changes and a variation in adjuvant treatment, which may have led to certain heterogeneity of the study group. However, we accounted for this by including the year of surgery in the multivariate analyses. Despite these limitations, this study with more than 700 pN1 patients adds important information to the ongoing debate by showing no influence of the number of removed LNs in LN-positive patients on BCR, metastasis, and CSM. Nevertheless, for a final evaluation of the therapeutic effect of a more extensive PLND, the results

7

of the above mentioned randomized trial need to be awaited. 5.

Conclusions

The number of removed LNs did not significantly influence BCR, occurrence of metastases, and CSM. A higher number of positive LNs and higher LN density were prognostic factors adversely affecting oncological outcomes in patients with LN metastases. To finally assess a possible therapeutic effect of a more extensive PLND, the results of a randomized study are awaited. Author contributions: Derya Tilki had full access to all the data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis. Study concept and design: Tilki, Mandel. Acquisition of data: Mandel, Kriegmair, Bogdan, Boehm, Buda¨us, Graefen, Huland, Tilki. Analysis and interpretation of data: Mandel, Kriegmair, Bogdan, Boehm, Buda¨us, Graefen, Huland, Tilki. Drafting of the manuscript: Mandel, Tilki. Critical revision of the manuscript for important intellectual content: Mandel, Kriegmair, Bogdan, Boehm, Buda¨us, Graefen, Huland, Tilki. Statistical analysis: Mandel. Obtaining funding: None. Administrative, technical, or material support: None. Supervision: Tilki. Other: None. Financial disclosures: Derya Tilki certifies that all conflicts of interest, including specific financial interests and relationships and affiliations relevant to the subject matter or materials discussed in the manuscript (eg, employment/affiliation, grants or funding, consultancies, honoraria, stock ownership or options, expert testimony, royalties, or patents filed, received, or pending), are the following: None. Funding/Support and role of the sponsor: None.

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