Figures
Abstract
Purposes
Robotic gastrectomy (RG), as an innovation of minimally invasive surgical method, is developing rapidly for gastric cancer. But there is still no consensus on its comparative merit in either subtotal or total gastrectomy compared with laparoscopic and open resections.
Methods
Literature searches of PubMed, Embase and Cochrane Library were performed. We combined the data of four studies for RG versus open gastrectomy (OG), and 11 studies for robotic RG versus laparoscopic gastrectomy (LG). Moreover, subgroup analyses of subtotal and total gastrectomies were performed in both RG vs. OG and RG vs. LG.
Results
Totally 12 studies involving 8493 patients met the criteria. RG, similar with LG, significantly reduced the intraoperative blood loss than OG. But the duration of surgery is longer in RG than in both OG and LG. The number of lymph nodes retrieved in RG was close to that in OG and LG (WMD = −0.78 and 95% CI, −2.15−0.59; WMD = 0.63 and 95% CI, −2.24−3.51). And RG did not increase morbidity and mortality in comparison with OG and LG (OR = 0.92 and 95% CI, 0.69−1.23; OR = 0.72 and 95% CI, 0.25−2.06) and (OR = 1.06 and 95% CI, 0.84−1.34; OR = 1.55 and 95% CI, 0.49−4.94). Moreover, subgroup analysis of subtotal and total gastrectomies in both RG vs. OG and RG vs. LG revealed that the scope of surgical dissection was not a positive factor to influence the comparative results of RG vs. OG or LG in surgery time, blood loss, hospital stay, lymph node harvest, morbidity, and mortality.
Citation: Zong L, Seto Y, Aikou S, Takahashi T (2014) Efficacy Evaluation of Subtotal and Total Gastrectomies in Robotic Surgery for Gastric Cancer Compared with that in Open and Laparoscopic Resections: A Meta-Analysis. PLoS ONE 9(7): e103312. https://doi.org/10.1371/journal.pone.0103312
Editor: Jose Luis Hernández, Clínica Universidad de Navarra, Spain
Received: March 25, 2014; Accepted: April 16, 2014; Published: July 28, 2014
Copyright: © 2014 Zong et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: The authors confirm that all data underlying the findings are fully available without restriction. The data are in Table 2 and Table 3 in the manuscript.
Funding: The authors have no funding or support to report.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Gastric cancer is the fourth most common malignancy and second leading cause of cancer death in the world [1]. Surgical resection remains the only curative treatment option and open gastrectomy with lymphadenectomy took a leading position in the treatment of gastric cancer for a long time. Kitano et al. firstly reported the laparoscopy-assisted distal gastrectomy for gastric cancer in 1994 [2]. Since then, LG has been gradually spread worldwide [3]–[5].
Minimally invasive surgery represents a developing trend for its unique characteristics. However, conventional laparoscopic surgery itself, accompanied by some limitations such as instrument movement, amplification of hand tremor, two-dimensional imaging, and ergonomic discomfort for the surgeons. Robotic surgery, an emerging technology, was invented to overcome the disadvantages of conventional laparoscopic surgery in 1997 [6]. For robotic surgery, several robotic devices have been developed, but only the Da Vinci Surgical System was widely used [7]. To date, robotic surgery has been maturely adopted in many fields of advanced surgical procedures worldwide, especially for prostate cancer [8]. In the field of gastric cancer, robotic gastrectomy (RG) has been reported to be beneficial for patients, with less injury and also with compatible short-term oncologic outcomes to open gastrectomy (OG) or laparoscopic gastrectomy (LG) [9]–[20].
However, sample size, a single institution design and different appraise system of complications limited these studies to conclude objective result. To overcome these limitations, a meta-analysis of RG vs. OG or LG for gastric cancer was performed to determine the relative merits of RG for gastric cancer.
Methods
Publication Search
Three electronic databases (PubMed, EMBASE, and Cochrane Library) were searched (last search was updated on 01 June 2013, using the search terms: robotics OR robot PLUS gastrectomy PLUS cancer OR carcinoma OR adenocarcinoma OR malignancy PLUS open OR laparoscope). Article language was limited to English. All eligible studies were retrieved, and their bibliographies were checked for other relevant publications. Review articles and bibliographies of other relevant studies identified were hand-searched to identify additional eligible studies. Only published studies with full-text articles were included. When the same patient population was included in several publications, only the most recent or complete study was used in this meta-analysis.
Inclusion Criteria
The inclusion criteria were as follows: (a) controlled studies of RG vs. LG or RG vs. OG for gastric cancer; (b) report on at least one of the outcome measures mentioned below; and (c) sufficient published data to estimate an odds ratio (OR) with 95% confidence interval (CI).
Exclusion criteria
Abstracts, letters, editorials and expert opinions, reviews without original data, case reports and studies lacking control groups were excluded. The following studies or data were also excluded: (1) they reported on gastric surgery for benign lesions and gastrointestinal stromal tumor (GIST) and did not contain a distinct group of patients with gastric cancer, (2) the outcomes and parameters of patients were not clearly reported; (3) it was impossible to extract the appropriate data from the published results; and (4) there was overlap between authors or centers in the published literature.
Quality Assessment
The methodological quality of the studies included was assessed. Jadad Scale and MINORS were usually used to assess the quality of RCTs and non-RCTs, respectively [21], [22].
Data Extraction
Information was carefully extracted from all eligible studies by two of the authors (Zong L and Seto Y), according to the inclusion criteria listed above. The following information were collected from each study: first author’s surname, publication date, district, resection extent, reconstruction method, BMI index, TNM stage, study type, and total number of patients in RG group and OG group or LG group, respectively. We did not define a minimum number of patients for inclusion in our meta-analysis.
Statistical Analysis
Odd ratios with 95% CI were used for the comparisons of dichotomous variables (e.g., morbidity, and mortality) between surgical methods according to the method of Woolf. Heterogeneity assumption was confirmed by the X2-based Q-test. A P-value greater than 0.10 for the Q-test indicated a lack of heterogeneity among the studies, therefore, the OR estimate for each study was calculated by the fixed-effects model (the Mantel-Haenszel method). Otherwise, the random-effects model (the DerSimonian and Laird method) was used. The significance of the pooled OR was determined by the Z-test and P>0.05 was considered statistically significant. Weighted mean difference (WMD) with 95% confidence intervals (95% CI) was calculated for continuous variables (e.g., operation time, and blood loss). WMD was pooled by using the inverse variance model. Sensitivity analyses were carried out to determine if modification of the inclusion criteria for this meta-analysis affected the final results. An estimate of potential publication bias was carried out using the funnel plot, in which the OR for each study was plotted against its log (OR). An asymmetric plot suggested possible publication bias. Funnel plot asymmetry was assessed using Egger’s linear regression test, a linear regression approach to measure funnel plot asymmetry on the natural logarithm scale of the OR. The significance of the intercept was determined by the t-test, as suggested by Egger (P<0.05 was considered representative of statistically significant publication bias). All statistical tests were performed with Review Manager Version 5.0 (The Cochrane Collaboration, Oxford, England).
Results
Study Characteristics
Of the 14 published pieces of literature [9]–[20], [23], 12 studies were eligible in this meta-analysis. Two studies published by the same team from the same institute within the same study interval were regarded as 1 trial, but both studies were included and shared the same study number because some separately published data was complementary [17], [23]. Hence, a total of 12 studies including 8493 patients were used in the pooled analyses. Table 1 lists the studies identified and their main characteristics. Of the 12 groups, sample size ranged from 39 to 5839 (Figure 1).
Robotic gastrectomy versus open gastrectomy
The mean operation time of RG was 68.47 minutes longer than OG, but intraoperative blood loss and hospital stay were significantly reduced by RG (WMD = 68.47 and 95% CI, 63.40−73.54; WMD = −106.63 and 95% CI, −163.13−−50.13; WMD = −2.49 and 95% CI, −3.72−−1.27). The difference of lymph node harvest between RG and OG was not statistically significant (WMD = −0.78 and 95% CI, −2.15−0.59). Moreover, Meta-analyses on morbidity and mortality indicated that there was no significant differences between RG and OG (OR = 0.92 and 95% CI, 0.69−1.23; OR = 0.72 and 95% CI, 0.25−2.06). Also, specifically for anastomotic leakage, no difference was observed between two groups (OR = 1.72 and 95% CI, 0.97−3.07). Subgroup analysis of subtotal gastrectomy, and subtotal and total gastrectomies for above parameters all showed a similar trend with the combined results (Table 2) (Figure 2).
Robotic gastrectomy versus Laparoscopic gastrectomy
Operation time was significantly longer in RG compared with LG (WMD = 57.15 and 95% CI, 42.26−72.05). Both as the minimally invasive surgery, RG did not showed a priority in intraoperative blood loss (WMD = −28.59 and 95% CI, −56.57−−0.62). As for postoperative hospital stay, there was no significant difference (WMD = −0.16 and 95% CI, −0.87−0.55). In analysis of lymph node harvest, it did not attain statistical significance between RG and LG (WMD = 0.63 and 95% CI, −2.24−3.51). Further analysis revealed that RG did not carry additional postoperative morbidity, as well as anastomotic leakage, and mortality when compared with LG (OR = 1.06 and 95% CI, 0.84−1.34; OR = 1.10 and 95% CI, 0.66−1.82; OR = 1.55 and 95% CI, 0.49−4.94) (Table 3) (Figure 3). However, Meta-analysis on another surgical outcome evaluation system with Clavien-Dindo grades also did not show significant differences in any sub-divided grade. Subgroup analysis of subtotal gastrectomy, total gastrectomy, and subtotal and total gastrectomies was also performed for above parameters and no single subgroup showed a heterogeneous result with the combined one (Table 3) (Figure 4).
Publication Bias
Begg’s funnel plot was performed to assess publication bias. The heterogeneity tests for comparing the 12 combined studies showed heterogeneity in some analyses such as operation time, blood loss and so on; however, when significant heterogeneity occurred among the studies, random-effects model was used.
Discussion
Radical gastrectomy with lymphadenectomy has been widely applied in open surgery as standard surgical treatment for gastric cancer. Although minimally invasive surgery improves quality of life, it should be ensured that this technique does not increase morbidity and mortality [24]. With the developing of technique, minimally invasive surgery has gained a revolutionized application in general surgery from last century. But for gastric cancer, minimally invasive surgery experienced a controversy focusing on morbidity and mortality for a long time. Laparoscopic gastrectomy with limited lymphadenectomy is rapidly increasing and quickly admitted in early gastric cancer because of the mass and individual screening in Japan [25]. But the data was still incomplete to support the widespread use of laparoscopic gastrectomy for advanced gastric cancer in last decade [26].
Open gastrectomy with D2 lymphadenectomy is a technically demanding operation for advanced gastric cancer compared with D1, although there is the potential for appreciable morbidity and mortality [27], [28]. Therefore, the assessment in favor of D2 lymphadenectomy makes it an integral part of laparoscopic surgery for advanced gastric cancer. Recently strong evidence from a multi-center retrospective study of laparoscopic surgery over open surgery confirmed the therapeutic role of Laparoscopic gastrectomy in advanced gastric cancer [29].
Robotic surgery, as an innovation of laparoscopic surgery, might be a simpler way to expand the indications of minimally invasive surgery for gastric cancer. However, controlled prospective studies are needed to evaluate the role of robotics in the management of gastric cancer. Some studies have demonstrated that robotic total and subtotal gastrectomies with D2-lymphadenectomy are technically feasible and safe, with acceptable surgical and oncological short-term results [15], [30]–[32]. It is particularly notable that only a few reports have examined the technical feasibility of robotic surgery for gastric cancer till 2011 [9], [14], [17]–[19], and the number of patients included in these studies was too small to generalize its application for gastric cancer [14], [17], [18]. Recently some large sized studies have been conducted to evaluate the efficacy and safety of robotic gastrectomy for gastric cancer [11], [13], [15], [19]. But single comparison and conflict results limited them to conclude persuasible conclusions. However, those examined in the present study allowed meta-analyses to be performed, providing a better view of the safety and efficacy of RG in gastric cancer. In reality, it is difficult to conduct a high-quality RCT to evaluate a new surgical intervention because of some obstacles such as learning curve effects, ethical and culture resistance, and urgent or unexpected conditions during operation in surgical treatment. For these reasons, to include non-RCTs is an appropriate strategy to extend the source of evidence [33].
In the first part of RG versus OG, our analyses highlighted the advantage of RG in minimal injury because less intraoperative blood loss and shorter postoperative hospital stay were observed. But its complication in technique correspondently brought RG significantly longer operation time than OG. Further analyses of lymph node harvest, anastomotic leakage, morbidity, and mortality between RG and OG did not show significant differences. Although no controlled study for single total gastrectomy was included in subgroup analysis, we deduced that RG was feasible and safe in either subtotal gastrectomy or total gastrectomy compared with OG by similar evidences in subtotal and total mixed group and subtotal single group.
Continually, in comparison of RG and LG, we found it was similar in surgical injury for these two methods because of no significant difference in intraoperative blood loss. The disadvantage of longer surgical duration was also observed in RG, although significant heterogeneity existed. The heterogeneity might be caused by surgeons’ experience. However, it is important to stress that surgeons had got considerable experience of LG before RG, which helped them adapt quickly to the robotic procedure. Therefore, the effect of learning curve was limited in RG. Also, higher BMI might be another important factor to increase operation time and several reports described the association between gender and BMI as increased operation time [34], [35]. But Park et al thought that this factor could be overcome by surgeon’s expertise [36]. To explore the influence of BMI to our study, we made comparisons of BMI among three groups and no significant difference was observed (data not shown). Importantly, for analyses of lymph node harvest, anastomotic leakage, morbidity, and mortality, similar results were achieved between RG and LG in either subtotal gastrectomy or total gastrectomy. We also make a pooled analyses using Clavien-Dindo (C–D) classification. Still, no significant difference was observed. What’s far more important to limit the application of RG is the higher cost compared with LG. Due to the limited published study, meta-analysis for cost evaluation was not performed. But nevertheless, recent study by Park et al showed the total cost for RG was significantly higher than LG with a difference of €3189 [16].
In summary, we found that Robotic subtotal and total gastrectomies combined with lymphadenectomy are technically feasible and safe for gastric cancer, and can produce satisfying short-term postoperative outcomes. However, a weakness of present study was lack of randomized controlled studies included and significant heterogeneity was observed in operative time, intraoperative blood loss, length of hospital stay and lymph node harvest. In addition, total and subtotal gastrectomy was pooled together in most of included studies, which limited us to make a more precise conclusion. Also, economic value and long-term survival outcome are the mandatory appraisal index. Importantly, high-quality randomized controlled studies should be conducted to evaluate the role of robotic surgery for gastric cancer in future.
Author Contributions
Conceived and designed the experiments: LZ. Performed the experiments: LZ. Analyzed the data: LZ SA. Contributed reagents/materials/analysis tools: LZ TT. Contributed to the writing of the manuscript: LZ YS. Revised the manuscript: LZ YS.
References
- 1. Hohenberger P, Gretschel S (2003) Gastric cancer. Lancet 362: 305–315.
- 2. Kitano S, Iso Y, Moriyama M, Sugimachi K (1994) Laparoscopy-assisted Billroth I gastrectomy. Surg Laparosc Endosc 4: 146–148.
- 3. National Institutes of Health Consensus Development Conference Statement on Gallstones and Laparoscopic Cholecystectomy. Am J Surg 165: 390–398.
- 4. Adachi Y, Suematsu T, Shiraishi N, Katsuta T, Morimoto A, et al. (1999) Quality of life after laparoscopy-assisted Billroth I gastrectomy. Ann Surg 229: 49–54.
- 5. Kim MC, Kim KH, Kim HH, Jung GJ (2005) Comparison of laparoscopy-assisted by conventional open distal gastrectomy and extraperigastric lymph node dissection in early gastric cancer. J Surg Oncol 91: 90–94.
- 6. Cadière GB, Himpens J, Germay O, Izizaw R, Degueldre M, et al. (2001) Feasibility of robotic laparoscopic surgery: 146 cases. World J Surg 25: 1467–1477.
- 7.
Tooher R, Pham C (2004) The da Vinci Surgical Robotics System: Technology Overview ASERNIP-S Report No. 45. Adelaide, South Australia: ASERNIP-S ISBN: 0909844658.
- 8. Atug F, Castle EP, Woods M, Davis R, Thomas R (2006) Robotics in urologic surgery: an evolving new technology. Int J Urol 13: 857–863.
- 9. Caruso S, Patriti A, Marrelli D, Ceccarelli G, Ceribelli C, et al. (2011) Open vs robot-assisted laparoscopic gastric resection with D2 lymph node dissection for adenocarcinoma: a case-control study. Int J Med Robot 7: 452–458.
- 10. Eom BW, Yoon HM, Ryu KW, Lee JH, Cho SJ, et al. (2012) Comparison of surgical performance and short-term clinical outcomes between laparoscopic and robotic surgery in distal gastric cancer. Eur J Surg Oncol 38: 57–63.
- 11. Huang KH, Lan YT, Fang WL, Chen JH, Lo SS, et al. (2012) Initial Experience of Robotic Gastrectomy and Comparison with Open and Laparoscopic Gastrectomy for Gastric Cancer. J Gastrointest Surg 16: 1303–1310.
- 12. Hyun MH, Lee CH, Kwon YJ, Cho SI, Jang YJ, et al. (2013) Robot versus laparoscopic gastrectomy for cancer by an experienced surgeon: comparisons of surgery, complications, and surgical stress. Ann Surg Oncol 20: 1258–1265.
- 13. Kang BH, Xuan Y, Hur H, Ahn CW, Cho YK, et al. (2012) Comparison of Surgical Outcomes between Robotic and Laparoscopic Gastrectomy for Gastric Cancer: The Learning Curve of Robotic Surgery. J Gastric Cancer 12: 156–163.
- 14. Kim MC, Heo GU, Jung GJ (2010) Robotic gastrectomy for gastric cancer: surgical techniques and clinical merits. Surg Endosc 24: 610–615.
- 15. Kim KM, An JY, Kim HI, Cheong JH, Hyung WJ, et al. (2012) Major early complications following open, laparoscopic and robotic gastrectomy. Br J Surg 99: 1681–1687.
- 16. Park JY, Jo MJ, Nam BH, Kim Y, Eom BW, et al. (2012) Surgical stress after robot-assisted distal gastrectomy and its economic implications. Br J Surg 99: 1554–61.
- 17. Pugliese R, Maggioni D, Sansonna F, Costanzi A, Ferrari GC, et al. (2010) Subtotal gastrectomy with D2 dissection by minimally invasive surgery for distal adenocarcinoma of the stomach: results and 5-year survival. Surg Endosc 24: 2594–2602.
- 18. Song J, Kang WH, Oh SJ, Hyung WJ, Choi SH, et al. (2009) Role of robotic gastrectomy using da Vinci system compared with laparoscopic gastrectomy: initial experience of 20 consecutive cases. Surg Endosc 23: 1204–1211.
- 19. Woo Y, Hyung WJ, Pak KH, Inaba K, Obama K, et al. (2011) Robotic gastrectomy as an oncologically sound alternative to laparoscopic resections for the treatment of early-stage gastric cancers. Arch Surg 146: 1086–1092.
- 20. Yoon HM, Kim YW, Lee JH, Ryu KW, Eom BW, et al. (2012) Robot-assisted total gastrectomy is comparable with laparoscopically assisted total gastrectomy for early gastric cancer. Surg Endosc 26: 1377–81.
- 21. Jadad AR, Moore RA, Carroll D, Jenkinson C, Reynolds DJ, et al. (1996) Assessing the quality of reports of randomized clinical trials: is blinding necessary? Control Clin Trials. 17: 1–12.
- 22. Slim K, Nini E, Forestier D, Kwiatkowski F, Panis Y, et al. (2003) Methodological index for non-randomized studies (MINORS): development and validation of a new instrument. ANZ J Surg 73: 712–716.
- 23. Pugliese R, Maggioni D, Sansonna F, Ferrari GC, Forgione A, et al. (2009) Outcomes and survival after laparoscopic gastrectomy for adenocarcinoma. Analysis on 65 patients operated on by conventional or robot-assisted minimal access procedures. Eur J Surg Oncol 35: 281–288.
- 24. Zeng YK, Yang ZL, Peng JS, Lin HS, Cai L (2012) Laparoscopy-assisted versus open distal gastrectomy for early gastric cancer: evidence from randomized and nonrandomized clinical Trials. Ann Surg 256: 39–52.
- 25. Shimizu S, Uchiyama A, Mizumoto K, Morisaki T, Nakamura K, et al. (2000) Laparoscopically assisted distal gastrectomy for early gastric cancer: is it superior to open surgery? Surg Endosc 14: 27–31.
- 26. Katsios GC, Baltogiannis G, Roukos DH (2010) Laparoscopic surgery for gastric cancer: comparative-effectiveness research and future trends. Expert Rev Anticancer Ther 10: 473–476.
- 27. Cuschieri A, Fayers P, Fielding J, Craven J, Bancewicz J, et al. (1996) Postoperative morbidity and mortality after D1 and D2 resections for gastric cancer: preliminary results of the MRC randomised controlled trial. The Surgical Cooperative Group. Lancet 347: 995–9.
- 28. Songun I, Putter H, Kranenbarg EM, Sasako M, van de Velde CJ (2010) Surgical treatment of gastric cancer: 15-year follow-up results of the randomised nationwide Dutch D1D2 trial. Lancet Oncol 11: 439–449.
- 29. Park do J, Han SU, Hyung WJ, Kim MC, Kim W, et al. (2012) Long-term outcomes after laparoscopy-assisted gastrectomy for advanced gastric cancer: a large-scale multicenter retrospective study. Surg Endosc 26: 1548–53.
- 30. Patriti A, Ceccarelli G, Bellochi R, Bartoli A, Spaziani A, et al. (2008) Robot-assisted laparoscopic total and partial gastric resection with D2 lymph node dissection for adenocarcinoma. Surg Endosc 22: 2753–60.
- 31. D’Annibale A, Pende V, Pernazza G, Monsellato I, Mazzocchi P, et al. (2011) Full robotic gastrectomy with extended (D2) lymphadenectomy for gastric cancer: surgical technique and preliminary results. J Surg Res 166: e113–20.
- 32. Uyama I, Kanaya S, Ishida Y, Inaba K, Suda K, et al. (2012) Novel integrated robotic approach for suprapancreatic D2 nodal dissection for treating gastric cancer: technique and initial experience. World J Surg 36: 331–337.
- 33. McCulloch P, Taylor I, Sasako M, Lovett B, Griffin D (2002) Randomised trials in surgery: problems and possible solutions. BMJ 324: 1448–1451.
- 34. Kim KH, Kim MC, Jung GJ, Kim HH (2006) The impact of obesity on LADG for early gastric cancer. Gastric Cancer 9: 303–307.
- 35. Lee HJ, Kim HH, Kim MC, Ryu SY, Kim W, et al. (2009) The impact of a high body mass index on laparoscopy assisted gastrectomy for gastric cancer. Surg Endosc 23: 2473–2479.
- 36. Park SS, Kim MC, Park MS, Hyung WJ (2012) Rapid adaption of robotic gastrectomy for gastric cancer by experienced laparoscopic surgeons. Surg Endosc 26: 60–67.