Quality assessment of robot assisted thoracic surgical resection of non-small cell lung cancer: nodal upstaging and mediastinal recurrence
Introduction
Surgical resection remains the standard treatment of early stage non-small cell lung cancer (NSCLC) (1-3). Minimally invasive approaches such as multi-and uniportal video assisted thoracoscopic surgery (VATS) and 3–4 arm robot assisted thoracic surgery (RATS) are alternatives to thoracotomy. VATS is widely established in The Netherlands, but the application of robotic thoracic surgery has been rather stagnant, mainly due to financial issues and the new technical challenge that accompanies it (4-12).
After executing a vast experience in VATS, the technique of preference in lung surgery has shifted towards RATS at the Isala Hospital. This resulted from the benefits, such as the high-definition 3-dimensional view, the surgeon-operated camera, the increased freedom of intrathoracic movement, the scaled-down motion and the hand-related tremor filtration (13-15).
These features of RATS technology enable precise hilar and mediastinal lymph node dissection (MLND), which is a major prognostic factor in NSCLC (16). Even in case of preoperative invasive mediastinal staging, it is recommended that ≥3 ipsilateral MLN (N2) stations should be dissected, in addition to regional LN (N1) stations (17).
Although there is an ongoing debate on the “best” minimally invasive technique regarding MLND or sampling there is agreement that all thoracic surgical units should have access or expertise to either VATS or RATS. Thoracotomy in early stage lung cancer should to be avoided. Either way, the ultimate goal ought to be the pursuit of radical resection along with the most precise staging possible.
The hypothesis of this study is that the surgical accuracy facilitated by a robotic platform, results, not only in a higher yield of lymph nodes, but also a more precise and complete lymph node dissection. Therefore, the specific objective of this single center study was to assess the quality of RATS lymph node dissection, expressed by the surrogate markers of pathological upstaging and mediastinal recurrence.
We present the following article in accordance with the STROBE reporting checklist (available at http://dx.doi.org/10.21037/jtd-20-2267).
Methods
Key element of the study design is a single institutional retrospective cohort study of patients with NSCLC operated on by RATS. The setting is the Department of Cardiothoracic Surgery at the Isala Hospital in Zwolle The Netherlands. This is a tertiary non-academic hospital. The database of the Department of Cardiothoracic Surgery and Intensive Care of the Isala Hospital was used for data collection. Patients who were operated on between November 2011 and May 2016 were selected for eligibility. Follow-up data were collected from the same database. For this retrospective human study the Medical Ethical Research Board was consulted. It concluded that no ethical approval was required as all data were collected from the same database for which the patients had given their consent. The study was conducted in accordance with the Declaration of Helsinki (as revised in 2013).
The eligibility criteria were patients with histologically proven NSCLC, who underwent anatomic resection by means of RATS. We excluded patients with a history of concurrent malignant disease or other previous primary neoplasms (N=25), patients with small cell lung cancer (SCLC) (N=1), patients in whom the operation was converted to thoracotomy, before LN dissection was carried out (N=23), and a variety of other pathology (N=48). Of the initially selected 227 patients, 130 remained to be analyzed for this study (Figure 1). For the postoperative follow-up of the patients CT scanning was used. Unfortunately, intervals for performing the CT scan were not predefined. Patients were included until May 2016 in order to achieve a long-term follow-up.
Outcomes were defined as nodal upstaging and mediastinal recurrence. Nodal upstaging was assessed by comparing the cTNM to the pTNM. Preoperative staging was based on integrated fluor-18-deoxyglucose positron emission tomography (FDG-PET) and computed tomographic (CT) scans, and endoscopic ultrasonography and/or endobronchial (EUS/EBUS), and mediastinoscopy (18,19). Lymph nodes were considered clinically positive when the short-axis diameter was ≥1 cm on CT or when SUVmax ≥2.5 on PET scan. Routinely, all lymph node stations were examined by EBUS in case of hilar involvement and centrally located tumors. Mediastinoscopy was only performed when during EUS/EBUS no representative lymphatic tissue could be retrieved in patients with high suspicion of mediastinal metastatic disease. Upstaging was defined as a higher pTNM than cTNM classification. Downstaging was defined as a lower pTNM than the cTNM as described preoperatively. Unforeseen N2 disease (cN0/N1-to-pN2) is defined as patients with N0 or N1 in whom postoperative histological mediastinal involvement (N2) was determined.
Mediastinal recurrence was defined as pathologically proven or strong suggestion of imaging of tumor recurrence on follow-up CT within MLN stations.
Data were collected on localization of primary tumor (peripheral/central), lymph node stations dissected (IASLC location, cTNM and pTNM, stage, number of unforeseen N2 nodes and mediastinal recurrence), as well as the rate of conversion to thoracotomy prior to lymph node dissection.
Statistical analysis
All data were analyzed retrospectively. Data management and analysis was performed using SPSS version 23 for Windows (IBM Corporation, Armonk, NY, USA). Continuous variables were presented as mean ± standard deviation (SD). Mean, standard error of the mean, and range were used for age and LN stations. Categorical data were expressed as count (%). The rate of nodal upstaging/downstaging and the rate of mediastinal recurrence on CT are expressed as count (%). P values ≤0.05 were considered statistically significant.
The surgical technique that was used was the 4-arm complete portal robotic lobectomy: CPRL-4, together with CO2 insufflation (20). The robotic platform that was used is the Intuitive Surgical Da Vinci® Si, (Intuitive Surgical Inc., Sunnyvale, California, USA). According to the Cancer and Leukemia Group B (CALGB) 39802-consensus report for VATS lobectomy we adhered in all cases to the use of non-rib spreading incisions, with the largest incision no greater than 8 cm (21). Lymph node dissection was carried out for stations 2, 4, 7, 8, 9, 10 and 11 on the right side, and 5, 6, 7, 8, 9, 10, 11 on the left side, according the International Association for the Study of Lung Cancer (IASLC) (22). All stations were dissected en bloc with the surrounding fatty tissue.
Although all surgical procedures were performed by one surgeon and the surgical technique is therefore reproducible, we are aware that the preoperative staging, by means of EUS/EBUS or mediastinoscopy, might be a potential source of bias.
Postoperative pathologic staging was determined by examination of intraoperative dissected lymph node stations. Clinical and pathological staging was determined according to the IASLC proposal (22).
Postoperative follow-up data were obtained from 116 (89.2%) of patients. In the majority follow-up was ascertained by means of a CT or PET-CT. The data of the 14 patients who were lost to follow-up, were sought for extensively, yet unfortunately could not be retrieved from the archives of referring hospitals. They were not included in the analysis.
Results
Between November 2011 and May 2016, 227 patients underwent RATS at the Isala Hospital in Zwolle, The Netherlands. All were examined for eligibility. As shown in Figure 1, 130 patients met the inclusion criteria. These 130 patients were included in the study.
Table 1 gives an overview of the patient characteristics. The rationale to include stage IV patients is that these are patients with oligometastatic disease, for whom was decided to surgically remove the primary NSCLC and administer radiotherapy for the metastasis.
Full table
Table 2 shows the type of resection and the resected specimen.
Full table
The anatomic locations of the tumors and the type of resection as well as the amount of obtained lymph nodes are summarized in Tables 2 and 3.
Full table
After robotic MLND the operation was converted to thoracotomy in 3.1%.
As is shown in Table 4, the clinical stage did not alter postoperatively in 69 patients (53.1%).
Full table
There was upstaging in 36.1% of patients, either by tumor size (T) or by nodal status (N).
Nodal upstaging was found in 26 patients (20%) of which, 9.2% upstaging from cN0-pN1, 4.6% cN0-pN2 (skip N2) and 6.2% from cN1 to pN2, which explains the 10.8% unforeseen N2 disease. To correlate this finding with the pre-operative staging, the medical records were revisited. In 8 of the 14 upstaged patients, pre-operative EUS/EBUS was performed as planned. In 1 patient, the procedure was aborted due to technical difficulties. In the seven completed EUS/EBUS procedures, there was an adequate yield of lymphatic tissue.
Four patients did not undergo a preoperative EUS/EBUS and the staging of the mediastinum was based entirely on imaging by means of CT and PET CT scan. Lastly, one of the fourteen upstaged patients, underwent a (false negative) mediastinoscopy.
Nodal downstaging was found in 4 patients (3.1%), which can be explained by a successful neoadjuvant chemoradiation therapy (Table 4).
Median postoperative follow-up period of 116 patients (89.2%) was 54 months, range 1.5–102 months. In seven patients (5.4%) mediastinal recurrence was detected.
Discussion
The present retrospective single center study reports on unforeseen N2 disease and mediastinal recurrence as parameters of quality of robot assisted anatomical resection for NSCLC. Nodal upstaging from cN0/N1 to pN2 was found in 10.8% with a skip N2 metastasis rate of 4.6% of the 130 investigated patients. Mediastinal recurrence during a median follow-up of 54 months was found in 5.4% of the patients. Both parameters are considered to be surrogate markers for the quality of RATS MLND.
For the accuracy of staging NSCLC, only little evidence is provided to support the superiority of MLND over lymph node sampling. However, although not supported by randomized controlled trials, retrospective cohort studies comparing MLND with lymph node sampling in stage I disease, suggest a survival benefit after MLND (23). This is not surprising, as a more thorough exploration of mediastinal nodes will more frequently result in detection of stage migration to higher levels.
The question rises if the superior operating features of RATS are distinctive enough to show better result when compared with VATS. The rate of unforeseen N2 disease and mediastinal recurrence rate might be regarded as reflections of a technique’s superiority in mediastinal lymph node examination.
First, the unforeseen N2 rate of 10.8% with RATS in our study is comparable to studies composed of similar cohorts (stages I-IV) reporting rates of 8.4% up to 10.7% (24,25). Lower rates of unforeseen N2 disease of 4.3% and 6% are reported with RATS in stage I disease (26,27). When comparing unforeseen N2-rates of VATS with thoracotomy most studies reports differences in favor of thoracotomy. Rates range from 1.8–4.9% in VATS to 5.0–11.5% in thoracotomy (28-31). Robotic surgery, yielded more lymph nodes compared to thoracotomy in clinical stage I disease without influencing survival (32). Unforeseen N2 rates are not mentioned in this report.
Secondly, the local recurrence rate of 5.4% as observed with RATS in our report is in line with results reported in former studies. A locoregional recurrence rate (hilar and mediastinal recurrence) with VATS for clinical stage I and II disease is demonstrated in 8 patients out of a series of 248 procedures (3.2%) (33,34). A similar defined local recurrence rate of 9.4% is reported in a series of 1012 VATS procedures for stages I-III (35).
Limitations of the study
The sample size of this study is small. The inclusion for analysis was halted in May 2016, in order to accomplish a long-term follow-up. Due to the retrospective design of this study, we have a number of missing follow-up data. Follow-up is complete for 89.2%, which might have resulted in an underrated mediastinal recurrence rate. Furthermore, there was no standardization concerning the preoperative lymph node staging, this has currently improved. In this study the clinical staging was determined by variations in technical skills of the pulmonologists who perform the EUS/EBUS. Mediastinoscopy should be performed more frequently, and an insufficient yield of lymphatic tissue during EUS/EBUS should not be accepted.
Another limitation might be the fact that we analyzed patients in various stages of NSCLC. It is to be expected that the higher stages of the disease will result more frequently and/or faster in mediastinal and locoregional recurrence.
We have included both pneumonectomy and segmentectomy patients. Although theoretically the biologic behavior of large or centrally located tumors requiring pneumonectomy is different from small peripheral tumors for which segmentectomy is sufficient, we focus in this manuscript on the feasibility and accuracy of lymph node dissection. As the lymph node dissection was performed in the same standardized fashion in every resection, we decided to include all types of resections.
As future perspective, we suggest studies that are designed to ascertain the correlation between surgical nodal upstaging, mediastinal recurrence and thus survival. A more accurate and standardized preoperative mediastinal staging and follow-up by means of CT scanning in all patients at preset intervals is desirable.
Conclusions
In this retrospective study, RATS lymph node dissection in patients undergoing lung resection for NSCLC stages I–IV resulted in 10.8% unforeseen N2 disease rate, and 5.4% mediastinal recurrence at a median follow-up time of 54 months (mean 42.8 months, range, 1.5–102 months). Regarding the advocated advantages of VATS and RATS concerning unexpected N2 disease and local recurrence after MLND, it will be difficult to prove superiority for one of the techniques. However, the presented results support earlier reports on the accuracy of RATS.
Superiority of RATS might be sought in other fields, such as expansion of the indications for minimally invasive surgical approach.
Acknowledgments
The authors would like to thank R.M. Brohet, for the statistical analysis of the data, and cardiothoracic surgeons Dr. G.J. Brandon Bravo Bruinsma and Dr. S. Siddiqi for their feedback and critical reading of this manuscript.
Funding: None.
Footnote
Reporting Checklist: The authors have completed the STROBE reporting checklist. Available at http://dx.doi.org/10.21037/jtd-20-2267
Data Sharing Statement: Available at http://dx.doi.org/10.21037/jtd-20-2267
Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at http://dx.doi.org/10.21037/jtd-20-2267). GMS reports that she is proctor for Intuitive Surgical Inc. The other authors have no conflicts of interest to declare.
Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved. For this retrospective human study, the Medical Ethical Research Board was consulted. It concluded that no ethical approval was required as all data were collected from the same database for which the patients had given their consent. The study was conducted in accordance with the Declaration of Helsinki (as revised in 2013).
Open Access Statement: This is an Open Access article distributed in accordance with the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License (CC BY-NC-ND 4.0), which permits the non-commercial replication and distribution of the article with the strict proviso that no changes or edits are made and the original work is properly cited (including links to both the formal publication through the relevant DOI and the license). See: https://creativecommons.org/licenses/by-nc-nd/4.0/.
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