ORIGINAL ARTICLE Year : 2022  |  Volume : 33  |  Issue : 4  |  Page : 192-198

Complications of robotic-assisted laparoscopic radical prostatectomy: Experience Sharing from 2000 cases involving a single surgeon

Chin-Heng Lu1, Yen-Chuan Ou1, Yi-Sheng Lin1, Li-Hua Huang1, Wei-Chun Weng1, Chao-Yu Hsu1, Min-Che Tung2
1 Department of Surgery, Divisions of Urology, Tungs' Taichung Metroharbor Hospital, Taichung, Taiwan
2 Department of Surgery, Divisions of Urology, Tungs' Taichung Metroharbor Hospital, Taichung; Jenteh Junior College of Medicine, Nursing and Management, Taiwan

Date of Submission21-Dec-2020Date of Decision23-Feb-2022Date of Acceptance07-Mar-2022Date of Web Publication25-Oct-2022

Correspondence Address:
Yen-Chuan Ou
1650 Taiwan Boulevard Sect. 4, Taichung Veterans General Hospital, Taichung, Taiwan 40705
Taiwan

Source of Support: None, Conflict of Interest: None

DOI: 10.4103/UROS.UROS_173_20

Purpose: Sharing experiences of complications with robotic-assisted laparoscopic radical prostatectomy (RALP) in 2000 patients treated by a single surgeon. Materials and Methods: We retrospectively reviewed 2,000 prostate cancer patients who underwent RALP (Group I, cases 1–1,000; Group II, cases 1001–2000) from December 2005 to September 2020 to compare the complications of the first 1000 patients with those of the latter 1000. All procedures were performed by the same experienced surgeon. Perioperative surgical complications were classified using the Clavien–Dindo classification. Complications were classified as minor (Clavien–Dindo Grades I–II) and major (Clavien–Dindo Grades III–IV), respectively. There was no Grade V complication. Results: Seventy-two cases developed complications in Group I: 26 with Clavien–Dindo Grade I, 29 with Grade II, 12 with Grade III, and 4 with Grade IV. The cases that developed complications in Group II, however, were lower at 48 cases: 15 with Clavien–Dindo Grade I, 17 with Grade II, 15 with Grade III, and 1 with Grade IV. Cases with minor Clavien–Dindo Grade (I–II) complications decreased significantly from Group I to Group II, at 55–32 patients (P = 0.0416). The transfusion rate was 1.1% in Group I, which was significantly higher than that in Group II at 0.1% (P = 0.0151). Conclusion: The assessment of the two groups indicated that the surgeon's learning curve for RALP improved with significantly fewer minor Clavien–Dindo Grade (I–II) group complications after 1000 surgeries.

Keywords: Prostate cancer, robotic-assisted laparoscopic radical prostatectomy, surgical complications

How to cite this article:
Lu CH, Ou YC, Lin YS, Huang LH, Weng WC, Hsu CY, Tung MC. Complications of robotic-assisted laparoscopic radical prostatectomy: Experience Sharing from 2000 cases involving a single surgeon. Urol Sci 2022;33:192-8
How to cite this URL:
Lu CH, Ou YC, Lin YS, Huang LH, Weng WC, Hsu CY, Tung MC. Complications of robotic-assisted laparoscopic radical prostatectomy: Experience Sharing from 2000 cases involving a single surgeon. Urol Sci [serial online] 2022 [cited 2022 Dec 1];33:192-8. Available from: https://www.e-urol-sci.com/text.asp?2022/33/4/192/359676   Introduction 

One of the perioperative variables included in the pentafecta outcomes used to evaluate the quality of robotic-assisted laparoscopic radical prostatectomy (RALP) is the absence of postoperative complications. Apart from the lack of complications, the pentafecta outcomes include potency, negative surgical margins, and no biochemical recurrence.[1],[2] Patel et al.[3] classified complications in RALP using the Clavien–Dindo grading system. According to his research, RALP complications ranged from 6.1% to 26%. With experience, surgeons may be able to reduce complication rates.

Ou et al.[4] evaluated the outcomes of 200 RALP cases in 2010. After 150 RALP procedures performed by a single surgeon, there was a significant reduction in complications. Significantly lower blood loss and blood transfusion rate were noted after 50 cases. After 150 cases, there was a significant decrease in complications. In 2014, Ou et al.[5] reported a significant decrease in the positive surgical margin rate in pT3a patients after 250 cases. The complication rate fell from 9.6% to 5.6%, but this was not statistically significant (P = 0.129), and the number of cases with Clavien–Dindo Grades I/II/III/IV fell from 5/11/6/2 to 5/5/1/3 cases. In a series of 1,000 consecutive RALP cases, Ou et al.[6] reported significantly fewer blood transfusions and lower complication rates in 2016. Coelho et al.[7] reported a 9.3% complication rate in the first 300 cases in a study of 2500 single-surgeon RALP case series in 2010, which decreased to 3.3% in cases 2101–2400.

According to the above-mentioned studies, complication rates decreased with experience. In practice, only a few surgeons have had extensive experience with RALP. The goal of this study was to describe a single surgeon's learning curve in terms of the number and type of complications encountered in 2000 RALPs performed.

  Materials and Methods 

Patients

We looked back on 2000 patients with prostate cancer who had undergone RALP between December 2005 and September 2020. All procedures were carried out by the same skilled surgeon (Y. C. Ou). The Clavien–Dindo grading system was used to record and classify perioperative surgical complications.[8] As described previously by Patel et al.,[3] complications are classified as minor (Clavien–Dindo Grades I–II) and major (Clavien–Dindo Grades III–IV).[3],[9] Patients were divided into two groups: Group I, cases 1–1000 (from December 2005 to June 2015), and Group II, cases 1001–2000 (from July 2015 to September 2020).

Preoperative assessments

Preoperative evaluation included a thorough review of the patient's medical history, including the identification of comorbidities, abdominal surgical history, and medication history, particularly anticoagulation drugs, antiplatelet drugs, supplemental drugs, and herbs. Under continuous medication, the underlying diseases recorded included hypertension, diabetes, renal insufficiency, and gouty arthritis. The cardiovascular and pulmonary systems were examined. All patients had preoperative anesthetic consultations with anesthesiologists. All patients had preoperative multiparametric magnetic resonance imaging (MRI). The tumor status (including location, staging, extracapsular extension, bladder neck, Denonvillier fascia or seminal vesicle invasion, lymph node, pelvic wall or bone metastasis, and pelvic cavity) and prostate anatomical information (including narrow pelvic cavity, deep prostate, large prostate size, intravesical prostate protrusion, and apical configuration), as well as other abnormalities, were determined using MRI (including prostate abscess and calcification, large seminal vesicle cyst, vesicle stone, and bladder tumor). Based on this information, a surgical plan, including neurovascular bundle (NVB) preservation and other operative details, could be refined prior to RALP.[5]

Surgical techniques

For RALP and other robotic-assisted surgeries, a dedicated robotic team was assembled. The patient was placed in a steep Trendelenburg position of 25°–30° while under general anesthesia. Six trocar ports on a four-arm da Vinci Robotic System were used for a transperitoneal approach (Intuitive Surgical, Sunnyvale, CA, USA). [Table 1] shows the criteria for NVB preservation. NVB preservation was carried out after careful consideration of various parameters, such as the D'Amico risk classification, biopsy tumor percentage, and preoperative MRI. RALP was carried out as described previously.[4],[10],[11]

Postoperative care

The postoperative care protocol was carried out on a routine basis in accordance with the postoperative date and as described herein. Early ambulation was encouraged on the first postoperative day (POD 1). First, the patient would try to drink some water. If there was no discomfort, they were encouraged to eat a regular diet on POD 1–2. On PODs 1–3, the drainage tube would be removed. If there were no complications, the patient was discharged on PODs 2–5. The patient would visit the urology outpatient department on PODs 7–14 for evaluation and Foley catheter removal.[4] All patients were followed up on a regular basis at the outpatient department, and the surgical complication rate was assessed for at least 6 months after surgery.

The protocol was approved by the Taichung Veterans General Hospital's Institutional Review Board (IRB) (IRB Number: CE 15215B) and Tungs' Taichung Metroharbor Hospital (IRB Number: 109007). The IRB waived informed consent.

Statistical analyses

The mean and standard deviation are used to express all data. For biostatistical calculations, IBM SPSS 20.0 for Windows (Chicago, IL, USA) was used. Statistical analyses were carried out using one-way analysis of variance and the Chi-squared test, as appropriate. P < 0.05 was considered statistically significant.

  Results 

Complications occurred in 120 of the 2000 RALP cases reviewed. The perioperative surgical complications in Group I are shown in [Table 2]. In Group I, 72 cases developed complications: 26 were classified as Clavien–Dindo Grade I, 29 as Clavien–Dindo Grade II, 12 as Clavien–Dindo Grade III, and 4 as Clavien–Dindo Grade IV. In Group II, the number of cases with complications was lower at 48: there were 15 Clavien–Dindo Grade I cases, 17 Clavien–Dindo Grade II cases, 15 Clavien–Dindo Grade III cases, and 1 Clavien–Dindo Grade IV case.

[Table 3] shows that the minor Clavien–Dindo Grade (I–II) group (P = 0.0416) had a significantly lower complication rate. The transfusion rate in Group I was 1.1%, but it dropped significantly to 0.1% in Group II (P = 0.0151). Blood transfusions were the most common complication (0.6%, 12/2,000). The gastrointestinal (GI) complications observed ranged in severity from Clavien–Dindo Grades I to VI and included intraoperatively repaired intestinal tears, rectal injuries, prolonged ileus, incarcerated inguinal hernias requiring laparoscopic hernioplasty, intestinal obstructions requiring laparoscopic enterolysis, and colorectal injuries requiring transient colostomy and subsequent colostomy closure.[8] Ureteral injuries, GI bleeding, urine leakage, internal bleeding, and incisional hernia were among the other complications discovered [Table 2] and [Table 4]. The minor Clavien–Dindo Grade (I–II) group (P = 0.0416) was the only complication group with a statistically significant decrease in events. Our findings clearly show a decreasing trend in the number of complications after 1000 cases of experience.

The use of neoadjuvant hormone therapy (NHT) prior to RALP may have an impact on surgical outcomes. Hou et al.[33] studied 28 patients with high-risk prostate cancer. Following NHT, the mean operative time for RALP was longer. Patients who received NHT had the same perioperative morbidity as non-NHT patients. Anticoagulants, Chinese herbal medicine, hyperuricemia, and gouty arthritis medications were among the other preoperative medications. In our practice, anticoagulants were withheld 1 week before RALP, and Chinese herbs were withheld 3 weeks before RALP. According to Mantz et al.,[34] aspirin did not increase major thrombotic or bleeding events in at-risk patients undergoing urological surgery. Some Chinese herbal medications, on the other hand, have the potential to disrupt the coagulation cascade and increase the likelihood of bleeding. Patients who use traditional Chinese medicine may experience drug–drug interactions or other serious side effects. Cordier and Steenkamp proposed that Chinese herbal medication be stopped prior to surgery.[35],[36]

Gout attacks occurred in 4.2% of 359 patients with prostate cancer who underwent radical prostatectomy (open, laparoscopic, or robotic).[37] The incidence rate of gouty arthritis in the current study was 1.5% in the first 200 cases and decreased to 0.375% in cases 201–800. The administration of antihyperuricemic medication may have contributed to the improvement.[4]

A dedicated and experienced robotic team is critical to the success of robotic-assisted surgeries in terms of lowering complication rates and in many other factors. Preoperative preparation, patient positioning, patient safety and protection, docking, surgery instrument preparation and usage, wound treatment, and postoperative patient care are skills of a skilled robotic team at every step of RALP. A professional robotic team benefits both novices and experienced surgeons by facilitating learning and improving outcomes. The robotic team and surgeon are both growing and gaining experience at the same time.[4]

An ocular complication after RALP has been reported,[38] but it was not observed in this study. As a result of the increased intraocular pressure and other physiologic changes induced within the eye, the unusual steep Trendelenburg positioning during RALP may cause ocular complications. Kan et al. reported ocular complications, such as corneal abrasion and ischemic optic neuropathy, following RALP. Corneal abrasions frequently heal on their own without causing permanent damage, scarring, vision loss, or other complications. Ischemic optic neuropathy, on the other hand, is far more severe and can result in permanent vision loss.

Clinical decision-making should be supported by evidence from the clinical care pathway.[39] For difficult operations, such as RALP, an experienced surgeon and a surgical team require a stable clinical care pathway that includes early diagnosis, subsequent management, and a low plication rate. The most common complications identified in our study were blood transfusions and GI issues. However, as surgeon experience increased, the rate of blood transfusions decreased.

In our study, urine leaks occurred in four of the first 1000 cases, then decreased to two of the next 1000 cases. Urine leaks were one of the most common complications, with an incidence rate of 0.3%–15.4%.[3],[40] Urine leaks may be followed by vesicourethral anastomotic strictures and incontinence. There are numerous methods of vesicourethral anastomosis for urine leak prevention. Our method was posterior rhabdosphincter reconstruction, which was also used by Coelho et al.[41] They enrolled 803 RALP patients, 473 of whom received modified posterior reconstruction of the rhabdosphincter, achieving a 0.4% anastomotic leakage rate and early recovery of continence. Three hundred and thirty patients did not receive posterior reconstruction after RALP, resulting in early continence recovery in 2.1% of patients. In our practice, intraoperative normal saline bladder instillation (200 mL) was used to confirm watertight vesicourethral anastomosis. Postoperative cystography prior to Foley removal was not required in our experience.[42]

Complication reduction is the ultimate lifelong goal for all surgeons. Beginners typically have a higher complication rate. Minor complications were significantly reduced in our study after 1,000 cases of RALP. However, there was no statistically significant difference in the incidence of major (Clavien–Dindo Grades III–IV) complications between the two cohorts. We hypothesized that the reason was the accumulation of experience by the surgeon and surgical team, as well as the maturation of the clinical care pathway. Most surgeons, including beginners, were aware of the potential critical steps for major complications. Minor complications, on the other hand, necessitate more experience accumulation for prevention.

Our study found a downward trend in the complication rates of a high-volume RALP surgeon. Our findings, however, may not apply to the experiences of all surgeons in case series involving multiple surgeons, limiting the generalizability of the findings. Another limitation of our study is that the majority of the patients enrolled received the same surgical method, which was then adjusted based on individual anatomical variations or situations encountered during the operation. The Montessori technique, which involves first performing seminal vesicle dissection, dropping the bladder directly, or the Retzius space-saving radical prostatectomy are all surgical options. The Montessori technique was the most commonly performed technique in our case series. In a few cases, other methods were used. We did not weigh the pros and cons of these approaches.

Our study's strengths were in standardizing reporting using the Clavien–Dindo complication reporting system, and we met 9 of the 10 criteria defined by Martin et al.[12] Our study adds to the body of knowledge about the relationship between surgical experience and complication rates among RALP surgeons and broadens the base of comparison for future RALP research.

  Conclusion 

Our analysis of 2000 RALP cases shows that complication rates decrease with surgical experience, with significantly fewer minor Clavien–Dindo Grade (I–II) complications and blood transfusion rates. We discussed some of the solutions to problems we encountered during RALP.

Financial support and sponsorship

Nil.

Conflicts of interest

Prof. Yen-Chuan Ou, an editorial board member at Urological Science, had no role in the peer review process of or decision to publish this article. The other authors declared no conflicts of interest in writing this paper.

 

  References 
1.Moncada I, López I, Ascencios J, Krishnappa P, Subirá D. Complications of robot assisted radical prostatectomy. Arch Esp Urol 2019;72:266-76.  
    2.Ou YC, Yang CK, Kang HM, Chang KS, Wang J, Hung SW, et al. Pentafecta outcomes of 230 cases of robotic-assisted radical prostatectomy with bilateral neurovascular bundle preservation. Anticancer Res 2015;35:5007-13.  
    3.Patel VR, Abdul-Muhsin HM, Schatloff O, Coelho RF, Valero R, Ko YH, et al. Critical review of 'pentafecta' outcomes after robot-assisted laparoscopic prostatectomy in high-volume centres. BJU Int 2011;108:1007-17.  
    4.Ou YC, Yang CR, Wang J, Yang CK, Cheng CL, Patel VR, et al. The learning curve for reducing complications of robotic-assisted laparoscopic radical prostatectomy by a single surgeon. BJU Int 2011;108:420-5.  
    5.Ou YC, Yang CK, Chang KS, Wang J, Hung SW, Tung MC, et al. The surgical learning curve for robotic-assisted laparoscopic radical prostatectomy: Experience of a single surgeon with 500 cases in Taiwan, China. Asian J Androl 2014;16:728-34.  
[PUBMED]  [Full text]  6.Ou YC, Yang CK, Chang KS, Wang J, Hung SW, Tung MC, et al. Prevention and Management of Complications During Robotic-assisted Laparoscopic Radical Prostatectomy Following Comprehensive Planning: A Large Series Involving a Single Surgeon. Anticancer Res 2016;36:1991-8.  
    7.Coelho RF, Palmer KJ, Rocco B, Moniz RR, Chauhan S, Orvieto MA, et al. Early complication rates in a single-surgeon series of 2500 robotic-assisted radical prostatectomies: Report applying a standardized grading system. Eur Urol 2010;57:945-52.  
    8.Dindo D, Demartines N, Clavien PA. Classification of surgical complications: A new proposal with evaluation in a cohort of 6336 patients and results of a survey. Ann Surg 2004;240:205-13.  
    9.Patel VR, Sivaraman A, Coelho RF, Chauhan S, Palmer KJ, Orvieto MA, et al. Pentafecta: A new concept for reporting outcomes of robot-assisted laparoscopic radical prostatectomy. Eur Urol 2011;59:702-7.  
    10.Ou YC, Hung SW, Wang J, Yang CK, Cheng CL, Tewari AK. Retro-apical transection of the urethra during robot-assisted laparoscopic radical prostatectomy in an Asian population. BJU Int 2012;110:E57-63.  
    11.Ou YC, Yang CK, Wang J, Hung SW, Cheng CL, Tewari AK, et al. The trifecta outcome in 300 consecutive cases of robotic-assisted laparoscopic radical prostatectomy according to D'Amico risk criteria. Eur J Surg Oncol 2013;39:107-13.  
    12.Martin RC 2nd, Brennan MF, Jaques DP. Quality of complication reporting in the surgical literature. Ann Surg 2002;235:803-13.  
    13.Liss MA, Skarecky D, Morales B, Osann K, Eichel L, Ahlering TE. Preventing perioperative complications of robotic-assisted radical prostatectomy. Urology 2013;81:319-23.  
    14.Kočárek J. Heráček J, Čermák M, Chmelík F, Matějková M. Robotic-assisted radical prostatectomy – Results of 1500 surgeries. Rozhl Chir 2017;96:75-81.  
    15.Patel VR, Thaly R, Shah K. Robotic radical prostatectomy: Outcomes of 500 cases. BJU Int 2007;99:1109-12.  
    16.Horstmann M, Horton K, Kurz M, Padevit C, John H. Prospective comparison between the AirSeal® System valve-less Trocar and a standard Versaport™ Plus V2 Trocar in robotic-assisted radical prostatectomy. J Endourol 2013;27:579-82.  
    17.Samavedi S, Abdul-Muhsin H, Pigilam S, Sivaraman A, Patel VR. Handling difficult anastomosis. Tips and tricks in obese patients and narrow pelvis. Indian J Urol 2014;30:418-22.  
[PUBMED]  [Full text]  18.Hsu EI, Hong EK, Lepor H. Influence of body weight and prostate volume on intraoperative, perioperative, and postoperative outcomes after radical retropubic prostatectomy. Urology 2003;61:601-6.  
    19.Deliveliotis C, Protogerou V, Alargof E, Varkarakis J. Radical prostatectomy: Bladder neck preservation and puboprostatic ligament sparing – Effects on continence and positive margins. Urology 2002;60:855-8.  
    20.Walsh PC, Marschke PL. Intussusception of the reconstructed bladder neck leads to earlier continence after radical prostatectomy. Urology 2002;59:934-8.  
    21.Hoznek A, Salomon L, Rabii R, Ben Slama MR, Cicco A, Antiphon P, et al. Vesicourethral anastomosis during laparoscopic radical prostatectomy: The running suture method. J Endourol 2000;14:749-53.  
    22.Van Velthoven RF, Ahlering TE, Peltier A, Skarecky DW, Clayman RV. Technique for laparoscopic running urethrovesical anastomosis: The single knot method. Urology 2003;61:699-702.  
    23.Tewari AK, Srivastava A, Sooriakumaran P, Slevin A, Grover S, Waldman O, et al. Use of a novel absorbable barbed plastic surgical suture enables a “self-cinching” technique of vesicourethral anastomosis during robot-assisted prostatectomy and improves anastomotic times. J Endourol 2010;24:1645-50.  
    24.Chapman S, Turo R, Cross W. Vesicourethral anastomosis using V-Loc™ barbed suture during robot-assisted radical prostatectomy. Cent European J Urol 2011;64:236.  
    25.Valero R, Schatloff O, Chauhan S, HwiiKo Y, Sivaraman A, Coelho RF, et al. Bidirectional barbed suture for bladder neck reconstruction, posterior reconstruction and vesicourethral anastomosis during robot assisted radical prostatectomy. Actas Urol Esp 2012;36:69-74.  
    26.Zorn KC, Widmer H, Lattouf JB, Liberman D, Bhojani N, Trinh QD, et al. Novel method of knotless vesicourethral anastomosis during robot-assisted radical prostatectomy: Feasibility study and early outcomes in 30 patients using the interlocked barbed unidirectional V-LOC180 suture. Can Urol Assoc J 2011;5:188-94.  
    27.Finley DS, Margolis D, Raman SS, Ellingson BM, Natarajan S, Tan N, et al. Fine-tuning robot-assisted radical prostatectomy planning with MRI. Urol Oncol 2013;31:766-75.  
    28.Jeong CW, Lee S, Oh JJ, Lee BK, Lee JK, Jeong SJ, et al. Quantification of median lobe protrusion and its impact on the base surgical margin status during robot-assisted laparoscopic prostatectomy. World J Urol 2014;32:419-23.  
    29.Kordan Y, Salem S, Chang SS, Clark PE, Cookson MS, Davis R, et al. Impact of positive apical surgical margins on likelihood of biochemical recurrence after radical prostatectomy. J Urol 2009;182:2695-701.  
    30.McClure TD, Margolis DJ, Reiter RE, Sayre JW, Thomas MA, Nagarajan R, et al. Use of MR imaging to determine preservation of the neurovascular bundles at robotic-assisted laparoscopic prostatectomy. Radiology 2012;262:874-83.  
    31.Mason BM, Hakimi AA, Faleck D, Chernyak V, Rozenblitt A, Ghavamian R. The role of preoperative endo-rectal coil magnetic resonance imaging in predicting surgical difficulty for robotic prostatectomy. Urology 2010;76:1130-5.  
    32.Whang SY, Sung DJ, Lee SA, Park BJ, Kim MJ, Cho SB, et al. Preoperative detection and localization of accessory pudendal artery with contrast-enhanced MR angiography. Radiology 2012;262:903-11.  
    33.Hou CP, Lee WC, Lin YH, Chen SM, Chen CL, Chang PL, et al. Neoadjuvant hormone therapy following treatment with robotic-assisted radical prostatectomy achieved favorable in high-risk prostate cancer. Onco Targets Ther 2015;8:15-9.  
    34.Mantz J, Samama CM, Tubach F, Devereaux PJ, Collet JP, Albaladejo P, et al. Impact of preoperative maintenance or interruption of aspirin on thrombotic and bleeding events after elective non-cardiac surgery: The multicentre, randomized, blinded, placebo-controlled, STRATAGEM trial. Br J Anaesth 2011;107:899-910.  
    35.Cordier W, Steenkamp V. Herbal remedies affecting coagulation: A review. Pharm Biol 2012;50:443-52.  
    36.Gallo E, Pugi A, Lucenteforte E, Maggini V, Gori L, Mugelli A, et al. Pharmacovigilance of herb-drug interactions among preoperative patients. Altern Ther Health Med 2014;20:13-7.  
    37.Cheng WM, Lin TP, Lin CC, Huang EY, Chung HJ, Kuo JY, et al. Standardized report for early complications of radical prostatectomy. J Chin Med Assoc 2014;77:234-41.  
    38.Kan KM, Brown SE, Gainsburg DM. Ocular complications in robotic-assisted prostatectomy: A review of pathophysiology and prevention. Minerva Anestesiol 2015;81:557-66.  
    39.Kaufman MR, Baumgartner RG, Anderson LW, Smith JA, Chang SS Jr., Herrell SD, et al. The evidence-based pathway for peri-operative management of open and robotically assisted laparoscopic radical prostatectomy. BJU Int 2007;99:1103-8.  
    40.Tyritzis SI, Katafigiotis I, Constantinides CA. All you need to know about urethrovesical anastomotic urinary leakage following radical prostatectomy. J Urol 2012;188:369-76.  
    41.Coelho RF, Chauhan S, Orvieto MA, Sivaraman A, Palmer KJ, Coughlin G, et al. Influence of modified posterior reconstruction of the rhabdosphincter on early recovery of continence and anastomotic leakage rates after robot-assisted radical prostatectomy. Eur Urol 2011;59:72-80.  
    42.Chen CC, Yang CK, Hung SW, Wang J, Ou YC. Outcome of vesicourethral anastomosis after robot-assisted laparoscopic radical prostatectomy: A 6-year experience in Taiwan. J Formos Med Assoc 2015;114:959-64.