Beginner Surgeon's Initial Experience with Distal Subtotal Gastrectomy for Gastric Cancer Using a Minimally Invasive Approach

Yung Hun You; Yoo Min Kim; Dae Ho Ahn

doi:10.5230/jgc.2015.15.4.270

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You, Kim, and Ahn: Beginner Surgeon's Initial Experience with Distal Subtotal Gastrectomy for Gastric Cancer Using a Minimally Invasive Approach

Original Article

Journal of Gastric Cancer 2015; 15(4): 270-277.

Published online: 31 December 2015

DOI: https://doi.org/10.5230/jgc.2015.15.4.270

Beginner Surgeon's Initial Experience with Distal Subtotal Gastrectomy for Gastric Cancer Using a Minimally Invasive Approach

Yung Hun You, Yoo Min Kim, Dae Ho Ahn

Department of Surgery, CHA Bundang Medical Center, CHA University, Seongnam, Korea.

Correspondence to: Yoo Min Kim. Department of Surgery, CHA Bundang Medical Center, CHA University, 59 Yatap-ro, Bundang-gu, Seongnam 13496, Korea. Tel: +82-31-780-1870, Fax: +82-31-780-5259, aug-79@cha.ac.kr

Received 2 November 2015 Revised 15 December 2015 Accepted 15 December 2015

(open-access):

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted noncommercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Purpose

Minimally invasive gastrectomy (MIG), including laparoscopic distal subtotal gastrectomy (LDG) and robotic distal subtotal gastrectomy (RDG), is performed for gastric cancer, and requires a learning period. However, there are few reports regarding MIG by a beginner surgeon trained in MIG for gastric cancer during surgical residency and fellowship. The aim of this study was to report our initial experience with MIG, LDG, and RDG by a trained beginner surgeon.

Materials and Methods

Between January 2014 and February 2015, a total of 36 patients (20 LDGs and 16 RDGs) underwent MIG by a beginner surgeon during the learning period, and 13 underwent open distal subtotal gastrectomy (ODG) by an experienced surgeon in Bundang CHA Medical Center. Demographic characteristics, operative findings, and short-term outcomes were evaluated for the groups.

Results

MIG was safely performed without open conversion in all patients and there was no mortality in either group. There was no significant difference between the groups in demographic factors except for body mass index. There were significant differences in extent of lymph node dissection (LND) (D2 LND: ODG 8.3% vs. MIG 55.6%, P=0.004) and mean operative time (ODG 178.8 minutes vs. MIG 254.7 minutes, P<0.001). The serial changes in postoperative hemoglobin level (P=0.464) and white blood cell count (P=0.644) did not show significant differences between the groups. There were no significant differences in morbidity.

Conclusions

This study showed that the operative and short-term outcomes of MIG for gastric cancer by a trained beginner surgeon were comparable with those of ODG performed by an experienced surgeon.

Keywords: Minimally invasive surgical procedures, Stomach neoplasms, Laparoscopy, Robotics, Beginner surgeon

Introduction

For the treatment of gastric cancer, minimally invasive gastrectomy (MIG) is technically feasible and safe, especially for early gastric cancer.1 2 Recently, excellent postoperative short-term outcomes of laparoscopic gastrectomy and robotic gastrectomy have been reported in prospective, multicenter studies. In addition, acceptable oncologic outcomes of laparoscopic gastrectomy for gastric cancer in a retrospective, multicenter study have been confirmed.3 4 Thus, MIG (laparoscopic or robotic) is now regarded as one of the standard treatments for early gastric cancer,5 6 7 8 and is being performed in more institutions.

Laparoscopic gastrectomy has a steep learning curve. While the procedure can be performed successfully in the early learning period, it is known that robotic gastrectomy can more easily be learned by surgeons with experience in laparoscopic gastrectomy.9 However, these were well-trained gastric surgeons who were thoroughly familiar with open gastrectomy. To date, there has been no report of surgical outcomes of MIG performed by surgeons with minimal open counterpart experience as an operator. Although some urologic surgeons reported that previous experience with open surgery had little effect on the performance of minimally invasive surgical procedures,10 there has been no report on the effect of experience with open gastrectomy on performing MIG.

Therefore, we present our initial experience with minimally invasive, laparoscopic, or robotic distal subtotal gastrectomy (RDG) by a single, trained beginner surgeon, report the results of the evaluation of the short-term outcomes, compared with those for open distal subtotal gastrectomy (ODG) by an experienced surgeon.

Materials and Methods

1. Patients

We retrospectively reviewed a database of gastric cancer patients treated since January 2014 at CHA Bundang Medical Center, CHA University, Gyeonggi-do, Korea. Robotic or laparoscopic distal gastrectomy was offered to patients with histologically proven gastric adenocarcinoma not involving the serosal layer or extraperigastric lymph nodes on preoperative evaluation. All tumors were staged with preoperative endoscopy, endoscopic ultrasound, and abdominopelvic computed tomography (CT). Laparoscopic and robotic gastrectomies were first performed in April 2014; a total of 36 patients underwent laparoscopic or RDG in Bundang CHA Medical Center between April 2014 and February 2015 by a beginner surgeon in the early learning period. Of the 36 cases, 20 laparoscopic distal subtotal gastrectomies (LDGs) and 16 RDGs were performed. An experienced surgeon performed 13 ODGs in CHA Bundang Medical Center for the same indications as for MIG from January 2014 to February 2015. During a training period of 3 years, the beginner surgeon had experienced more than 200 ODGs, 200 LDGs, and 100 RDGs as a first assistant. The experienced surgeon has performed more than a thousand ODGs for gastric cancer over 20 years. We compared demographic characteristics, operative findings, and postoperative short-term outcomes of 20 LDGs and 16 RDGs by the beginner surgeon with those of 13 ODGs by the experienced surgeon. After receiving a detailed explanation, all patients selected the type of surgery by themselves and all gave proper informed consent before surgery. Because this was a retrospective analysis, signed informed consent for the study was waived by the institutional review board.

2. Variables

The demographic characteristics and operative findings, including age, sex, American Society of Anesthesiologists (ASA) score, body mass index (BMI), previous abdominal surgery, extent of lymph node dissection (LND), presence of combined resection, operative time, and tumor classification, were evaluated. Variables associated with postoperative short-term outcomes, such as postoperative changes in hemoglobin, white blood cell (WBC) count, length of hospital stay, time to first soft diet, and postoperative complications were reviewed. The participants in this study had undergone gastrectomy for gastric cancer; thus, we evaluated the number of retrieved lymph nodes, with more than 15 for early gastric cancer and 25 for advanced gastric cancer, to assess the oncologic quality of lymphadenectomy by the beginner surgeon. We serially evaluated the level of serum hemoglobin (Hb) in the perioperative period to estimate intraoperative blood loss, because the methods for measuring intraoperative blood loss differed between ODG and MIG groups in our institution. The serial WBC counts in the postoperative period were reviewed as inflammatory markers. The level of serum Hb and the WBC count were checked preoperatively, immediate postoperatively, and on postoperative day (POD) #1, POD #3, and POD #5. Postoperative complications according to the Clavien-Dindo classification were also evaluated to compare short-term outcomes.11

3. Surgical methods

The extent of gastric wall resection (total or distal subtotal gastrectomy) was determined according to the location of the tumor and the extent of LND; D1+ or D2 was performed according to the Japanese gastric cancer treatment guidelines.5 The surgical techniques for the robotic and laparoscopic gastrectomies with LND are similar in detail, as previously reported.12 13 14 15 Reconstructions were performed with gastroduodenostomy, gastrojejunostomy with or without Braun anastomosis, or Rouxen-Y gastrojejunostomy, based on the tumor location for distal subtotal gastrectomy. The da Vinci Si System (Intuitive Surgical Inc., Sunnyvale, CA, USA) was used in all robotic gastrectomies

1) Laparoscopic distal subtotal gastrectomy

The patient was placed in reverse Trendelenburg position and 5 ports (3, 12-mm and 2, 5-mm ports) were inserted into the upper abdomen. After trocar insertions, liver traction was performed using the sling method with gauze and Prolene 2-0.16

After mobilization of the stomach and dissection of lymph nodes, distal gastrectomy was performed by applying 2, 60-mm Endo linear staplers through the 12-mm port in the left abdomen, and reconstruction was done intracorporeally with Endo linear staplers. Intracorporeal gastroduodenostomy was performed, similar to so-called delta-shaped anastomosis, as reported by Kanaya et al.17 When the last 45-mm stapler was fired to close the common entry hole, the previously stapled duodenal stump was also included and removed to secure the blood supply to the duodenum. Intracorporeal gastrojejunostomy was performed in a side-to-side, anisoperistaltic, and antecolic fashion, using Endo linear staplers. The common entry hole was closed intracorporeally by a hand-sewn method, with 2 layers of continuous running suture and absorbable barbed suture. Fullthickness running suture was used for the first layer and seromuscular running suture was used from the opposite start point using the same suture material without tying. For intracorporeal Roux-en-Y gastrojejunostomy, the proximal jejunum was divided 25 cm from the ligament of Treitz using a 45-mm Endo linear stapler. Intracorporeal gastrojejunostomy was performed in a side-to-side, isoperistaltic, and antecolic fashion using 60-mm Endo linear staplers 7 cm distal from the jejunal transection line. A side-to-side jejunostomy was performed 25 to 30 cm distal from the gastrojejunostomy site using a 45-mm Endo linear stapler. The common holes were closed intracorporeally by a hand-sewn method as described above. In all cases, Petersen's defect was repaired with a purse-string suture.

2) Robotic distal subtotal gastrectomy

After port insertion (2, 12-mm and 3, 8-mm ports), the surgical cart can be docked on the patient. The instrumentation and settings consist of a 30° down endoscope, Maryland bipolar forceps in the 1st arm, ultrasonic shears in the 2nd arm, and Cadiere forceps in the 3rd arm. The surgery begins with liver retraction; detailed procedures and intracorporeal reconstruction are the same as described above for LDG, except for gastrojejunostomy. When performing gastrojejunostomy, the 8-mm port for the 2nd robotic arm is changed to a 12-mm port for stapling. After gastrojejunostomy, an 8-mm robotic cannula is inserted into the 12-mm port, trocar-in-trocar fashion, to proceed after gastrojejunostomy.

4. Statistical analysis

All statistical analyses were conducted with the IBM SPSS software ver. 20 (IBM Co., Armonk, NY, USA). The variables compared among operations were tested with Student's t-test or analysis of variance for continuous variables and the chi-square test or Fisher's exact test for categorical variables as appropriate. The Mann-Whitney U-test was used for continuous variables, unless the data satisfied the normality criteria. For longitudinal outcomes, such as WBC counts, a linear mixed model was applied, and the outcomes at each time point were compared by independent t-tests. The accepted level of statistical significance was a P-value less than 0.05.

Results

The demographic characteristics of the enrolled patients in ODG and MIG groups are summarized in Table 1. Although LDG and RDG groups were significantly older or younger than the ODG group (67.1±12.2, 57.7±10.5 vs. 61.8±10.4, respectively, P<0.001), the mean age of the MIG group was not significantly different from the ODG group (P=0.780). The ODG group had a higher BMI (P=0.043); there were no differences in gender and previous abdominal operations between the ODG and MIG groups. The proportion of ASA scores in the ODG group was not different from the MIG group (P=0.498), but there were significantly more patients without a comorbidity (ASA=1) in the RDG group than in the ODG and LDG groups (P=0.023).

The operative findings and the pathologic results are summarized in Table 2. There was no significant difference between ODG and MIG groups for tumor location, tumor size, and resection margin. The mean of total retrieved lymph nodes was 41.6 in ODG and 41.8 in MIG and was not significantly different between the groups (P=0.963), even though the MIG group had a higher proportion of D2 LND than the ODG group (P=0.004). For patients who underwent D1+ LND, total retrieved lymph nodes in MIG were 34.5 on average, and more than 15 lymph nodes were retrieved in all MIG patients. For patients who underwent D2 LND, total retrieved lymph nodes in MIG were 47.7 on average, and more than 25 lymph nodes were retrieved in all MIG patients. There were no differences in reconstruction afterdistal gastrectomy, combined operations, and TNM stage between the groups. Combined operations were performed in one patient (transperitoneal hernia repair) in ODG, 2 patients (cholecystectomy for asymptomatic multiple gallbladder stones) in LDG, and one patient (robotic segmentectomy of S2 of the liver for hepatocellular adenoma) in RDG.

The operative short-term outcomes are summarized in Table 3. The mean operative time for MIG was about one and one half hours longer than that for ODG (254.7±51.5 minutes vs. 178.8 ±52.7 minutes, P<0.001), and the difference was statistically significant. There were 3 cases in the MIG group that took over 300 min, including 2 LDGs and 1 RDG. One case was an RDG with full robotic segmentectomy of the liver for hepatocellular adenoma and another was an LDG with previous abdominal surgical history and combined cholecystectomy for asymptomatic gallbladder stones. The other case was an LDG with active intestinal tuberculosis and there were several nodules on the omentum fixed to the mesentery in the ileocecal area. In this case, we took biopsies, evaluated the frozen results, and performed a total omentectomy. There was no intraoperative or postoperative transfusion in either group. The postoperative Hb levels were significantly different over time for individual patients as well as between groups. As shown in Fig. 1, the curves for Hb level in ODG and MIG are almost parallel and do not cross; there was no statistical difference over time for individual patients or between groups (P=0.464). This finding was also observed in comparisons of ODG, LDG, and RDG groups (P=0.741). The postoperative WBC counts were significantly different over time for individual patients (P<0.001, Fig 1.). However, the curves for both groups were similar and did not cross; thus, the changes in WBC counts in the perioperative period were not statistically significant between groups (P=0.644) over time, compared with the changes in individual patients, as shown in Fig. 1. The changes in WBC counts over time in the perioperative period were not significantly different in comparisons of ODG, LDG, and RDG groups (P=0.780). There was no significant difference in time to soft diet and hospital stay between the groups. Postoperative complications greater than grade III did not developed in either group; there was no significant difference between ODG and MIG groups (P=0.527), and there was no postoperative mortality within 30 days after surgery in either group. Two LDG patients were readmitted within 6 months after surgery due to delayed gastric emptying and dumping syndrome with severe postprandial diarrhea.

Discussion

In our study, we simultaneously started performing laparoscopic gastrectomy and robotic gastrectomy for gastric cancer; these were performed successfully in terms of operative time, total retrieved lymph nodes, postoperative changes in Hb level and WBC counts, and postoperative morbidity.

Complete LND of the perigastric and extraperigastric area during gastrectomy for gastric cancer must be meticulous around the major vessels, which is stressful in a conventional laparoscopic environment. Thus, it has been suggested that performance of at least 50 cases is needed to overcome the learning curve for laparoscopic gastrectomy with only limited LND; surgeons must acquire experience from far more than 50 cases to be proficient in performing laparoscopic gastrectomy with D2 LND.18 Accordingly, surgeons at low-volume hospitals, where gastric cancer surgery is not frequently performed, may have difficulty in becoming proficient in laparoscopic gastrectomy.

Meanwhile, robotic surgical systems provide ambidextrous tremor-filtered bidirectional dissection around complex vascular structures that is more thorough and precise, reducing the possibility of injury to vessels or the pancreas.12 Moreover, the use of wristed instruments via robotic arms aids in the approach to and traction of the stomach and pancreas, as well as proper and stable exposure of the peripancreatic area; in addition, these procedures are performed on a stable camera platform. Thus, robotic gastrectomy exhibits a shorter learning curve than that for laparoscopic gastrectomy,19 and with its mechanical superiority has been adopted as an alternative approach for gastrectomy in gastric cancer. However, robotic gastrectomy is expensive and the robot is not always available, unlike laparoscopic equipment, especially at low-volume centers. Some investigators showed that experience with laparoscopic surgery could affect the learning process for robotic gastrectomy; an experienced laparoscopic surgeon requires fewer cases of robotic gastrectomy to reach a steady state.9

In our institution, 60 to 80 cases of gastrectomy for gastric cancer are performed annually; these were insufficient to overcome the learning curves of MIG including LDG and RDG, eve n though our institution is not a low-volume center by definition. In our initial experience, LDG and RDG can be performed safely for gastric cancer, although cases in each group in our study were too few to evaluate the learning curve; in addition, the follow-up period was insufficient to estimate long-term results. Even though the number of cases was small, surgical outcomes after robotic gastrectomy were acceptable in the initial period compared to laparoscopic gastrectomy. In order to overcome the learning curve in a shorter time, a surgeon should be trained by surgical teams and review videos of surgical procedures. A surgeon should also have experience as a first assistant in moreh atn 100 cases of laparoscopic and robotic gastrectomy, even though the experience was not as an operator.20 21 With these measures, we successfully performed MIG; we retrieved a mean number of 39.9 lymph nodes in LDG and 44.3 in RDG, similar to the 39.9 retrieved in open gastrectomy, and the more than 31.5 retrieved in laparoscopic gastrectomy in a large-scale, case-control and case-matched Korean multicenter study.3 In a meta-analysis of laparoscopic distal gastrectomies with D2 LND, a mean total of 28 to 49 lymph nodes were reportedly retrieved,22 which was comparable with our results, because our study included D1+ and D2 LND.

We observed no Clavien-Dindo grade III and IV postoperative complications after LDG and RDG. Although we should be aware of biases regarding the clinicopathological differences between this study and published data, our complication rates (15.0% in LDG and 12.5% in RDG) were acceptable when compared with published data.3 22 However, the most notable finding of this study was the operative time for the MIG group, which was about one and one half hours longer on average. In spite of this, there was no significant difference in intraoperative blood loss, postoperative decrease in the level of Hb, or postoperative inflammatory response as shown by changes in WBC counts. Moreover, postoperative progress assessed by days to diet start, hospital stay, and complications was not significantly different between the groups; thus, a longer operative time for MIG is within acceptable limits.

In conclusion, we report our initial experience with MIG for gastric cancer compared with operations by an experienced surgeon in the same institution. The operative and short-term outcomes with MIG performed by a beginner surgeon were acceptable during the early learning period.

Figures and Tables

Fig. 1

Mean hemoglobin level (A, B) and white blood cell count (C, D) after gastrectomy. Preop = preoperative; POD = postoperative day; ODG = open distal subtotal gastrectomy; MIG = minimally invasive gastrectomy; LDG = laparoscopic distal subtotal gastrectomy; RDG = robotic distal subtotal gastrectomy; WBC = white blood cell. ^*P-value for over time within subject; ^†P-value between or among the groups; ^‡P-value between or among the groups considering time effect within the patients.

Table 1

Demographic characteristics

Values are presented as mean±standard deviation (range) or number (%). ODG = open distal subtotal gastrectomy; LDG = laparoscopic distal subtotal gastrectomy; RDG = robotic distal subtotal gastrectomy; MIG = minimally invasive gastrectomy; ASA = American Society of Anesthesiologists. ^*P-value among three groups (ODG, LDG, RDG); ^†P-value between ODG and MIG.

Table 2

Operative findings and pathologic outcomes

Values are presented as number (%) or mean±standard deviation (range). ODG = open distal subtotal gastrectomy; LDG = laparoscopic distal subtotal gastrectomy; RDG = robotic distal subtotal gastrectomy; MIG = minimally invasive gastrectomy; LND = lymph node dissection. ^*P-value among three groups (ODG, LDG, RDG); ^†P-value between ODG and MIG; ^‡Roux-en-Y gastrojejunostomy; ^§Transperitoneal hernia repair; ^∥Laparoscopic cholecystectomy; ^¶Robotic segmentectomy of S2, liver.

Table 3

Postoperative short-term outcomes

Values are presented as mean±standard deviation (range), mean±standard deviation only, median (range), number (%), or number only. ODG = open distal subtotal gastrectomy, LDG = laparoscopic distal subtotal gastrectomy; RDG = robotic distal subtotal gastrectomy; MIG = minimally invasive gastrectomy; POD = postoperative day. ^*P-value among three groups (ODG, LDG, RDG); ^†P-value between ODG and MIG; ^‡P-value estimated by Linear mixed model; ^‡Clavien-Dindo classification of surgical complications; ^§Delayed gastric emptying and stasis.

Notes

^{Conflicts of Interest} No potential conflict of interest relevant to this article was reported.

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