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Updates in Surgery
Published in: Updates in Surgery 3/2021

01-06-2021 | Nephrectomy | Original Article

Transitioning to robotic partial nephrectomy with a team-based proctorship achieves the desired improved outcomes over open and laparoscopic partial nephrectomy

Authors: Asrif Chowdhury, Lincoln Guan Lim Tan, Edmund Chiong, Koon Ho Rha, Ho Yee Tiong

Published in: Updates in Surgery | Issue 3/2021

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Abstract

Proctoring may facilitate a safe transition to robotic-assisted partial nephrectomy (RAPN) for centres performing open (OPN) and laparoscopic partial nephrectomies (LPN). This study compared the 5-year outcomes of RAPN, initiated with a team-based proctorship, with OPN and LPN. Following an observation course at the proctor’s institution and a 3-surgeon performance of proctored RAPN in August 2014, a review of 90 RAPN, 29 LPN and 43 OPN consecutively performed by the same team from 2013 to 2019 at National University Hospital, Singapore was conducted. Peri-operative data, functional and oncological outcomes were compared amongst the three groups. Most cases were performed robotically after 2015 with comparable baseline characteristics in all groups. Median RENAL Nephrometry Score was not significantly different between RAPN (8 [IQR 6, 9]) and OPN (9 [IQR 7, 10]) (P = 0.12) but was significantly lower for LPN (7 [IQR 5, 8]) compared to RAPN (P = 0.002). RAPN achieved the lowest blood loss (226 ml vs.348 ml and 263 ml for OPN and LPN respectively, P = 0.02), transfusion rate (3% vs.21% and 17% respectively, P = 0.003) and median length of stay after surgery (4 vs.6 and 5 days respectively, P = 0.001). Complication rates, warm ischemic times were similar between the three approaches with no differences in 1-year and long-term renal function. The rate of positive surgical margin was 8%, 8% and 3% for RAPN, LPN and OPN, respectively (P = 0.76), with a single recurrence in each arm. Despite modest hospital volume, a team-based proctorship facilitated the transition to the Da Vinci robotic platform to perform partial nephrectomies of equivalent complexities as open surgery, achieving improved perioperative outcomes, while maintaining oncological and kidney functional results.
Literature
1.
Aboumarzouk OM, Stein RJ, Eyraud R et al (2012) Robotic versus laparoscopic partial nephrectomy: a systematic review and meta-analysis. Eur Urol 62(6):1023–1033CrossRef
2.
Tsai SH, Tseng PT, Sherer BA et al (2019) Open versus robotic partial nephrectomy: systematic review and meta-analysis of contemporary studies. Int J Med Robot Comput Assist Surg MRCAS 15(1):e1963CrossRef
3.
Choi JE, You JH, Kim DK, Rha KH, Lee SH (2015) Comparison of perioperative outcomes between robotic and laparoscopic partial nephrectomy: a systematic review and meta-analysis. Eur Urol 67(5):891–901CrossRef
4.
Xia L, Pulido JE, Chelluri RR et al (2018) Hospital volume and outcomes of robot-assisted partial nephrectomy. BJU Int 121(6):900–907CrossRef
5.
Zorn KC, Gautam G, Shalhav AL et al (2009) Training, credentialing, proctoring and medicolegal risks of robotic urological surgery: recommendations of the society of urologic robotic surgeons. J Urol 182(3):1126–1132CrossRef
6.
Haseebuddin M, Benway BM, Cabello JM, Bhayani SB (2010) Robot-assisted partial nephrectomy: evaluation of learning curve for an experienced renal surgeon. J Endourol 24(1):57–61CrossRef
7.
Hanzly M, Frederick A, Creighton T et al (2015) Learning curves for robot-assisted and laparoscopic partial nephrectomy. J Endourol 29(3):297–303CrossRef
8.
Komninos C, Shin TY, Tuliao P et al (2014) R-LESS partial nephrectomy trifecta outcome is inferior to multiport robotic partial nephrectomy: comparative analysis. Eur Urol 66(3):512–517CrossRef
9.
Kutikov A, Uzzo RG (2009) The R.E.N.A.L nephrometry score: a comprehensive standardized system for quantitating renal tumor size, location and depth. J Urol 182(3):844–853CrossRef
10.
Dindo D, Demartines N, Clavien PA (2004) Classification of surgical complications: a new proposal with evaluation in a cohort of 6336 patients and results of a survey. Ann Surg 240(2):205–213CrossRef
11.
Levey AS, Stevens LA, Schmid CH et al (2009) A new equation to estimate glomerular filtration rate. Ann Intern Med 150(9):604–612CrossRef
12.
Levey AS, Coresh J, Balk E et al (2003) National Kidney Foundation practice guidelines for chronic kidney disease: evaluation, classification, and stratification. Ann Intern Med 139(2):137–147CrossRef
13.
Buffi N, Lista G, Larcher A et al (2012) Margin, ischemia, and complications (MIC) score in partial nephrectomy: a new system for evaluating achievement of optimal outcomes in nephron-sparing surgery. Eur Urol 62(4):617–618CrossRef
14.
Campbell SC, Novick AC, Belldegrun A et al (2009) Guideline for management of the clinical T1 renal mass. J Urol 182(4):1271–1279CrossRef
15.
Bertolo R, Garisto J, Dagenais J et al (2019) Transperitoneal robot-assisted partial nephrectomy with minimum follow-up of 5 years: oncological and functional outcomes from a single institution. Eur Urol Oncol 2(2):207–213CrossRef
16.
Lista G, Buffi NM, Lughezzani G et al (2015) Margin, ischemia, and complications system to report perioperative outcomes of robotic partial nephrectomy: a European Multicenter Observational Study (EMOS project). Urology 85(3):589–595CrossRef
17.
Parekh DJ, Weinberg JM, Ercole B et al (2013) Tolerance of the human kidney to isolated controlled ischemia. J Am Soc Nephrol 24(3):506–517CrossRef
18.
Nahar B, Bhat A, Parekh DJ (2019) Does every minute of renal ischemia still count in 2019? unlocking the chains of a flawed thought process over 5 decades. Eur Urol Focus 5(6):939–942CrossRef
19.
Goonewardene SS, Brown M, Challacombe B (2017) Robotic partial nephrectomy and early unclamping: an evolving paradigm. J Robot Surg 11(1):93–94CrossRef
20.
Mottrie AM (2012) Editorial Comment on: margin, ischemia, and complications (MIC) score in partial nephrectomy: a new system for evaluating achievement of optimal outcomes in nephron-sparing surgery. Eur Urol 62(4):617–619CrossRef
21.
Bahler CD, Monn MF, Flack CK, Gramm AR, Gardner TA, Sundaram CP (2018) Assessing cost of robotic utilization in partial nephrectomy with increasing utilization. J Endourol 32(8):710–716CrossRef
22.
Tidman J (2018) Renal cell carcinoma: controversies in care. Eur Urol Today Congr News 23:1–2
23.
Larcher A, De Naeyer G, Turri F et al (2019) The ERUS Curriculum for robot-assisted partial nephrectomy: structure definition and pilot clinical validation. Eur Urol 75(6):1023–1031CrossRef
24.
Gamboa AJ, Santos RT, Sargent ER et al (2009) Long-term impact of a robot assisted laparoscopic prostatectomy mini fellowship training program on postgraduate urological practice patterns. J Urol 181(2):778–782CrossRef
25.
Mason MD, Herndon CDA, Herbst KW et al (2014) Proctor environment facilitates faculty training in pediatric robotic-assisted laparoscopic pyeloplasty. J Robot Surg 8(4):365–369CrossRef
Metadata
Title
Transitioning to robotic partial nephrectomy with a team-based proctorship achieves the desired improved outcomes over open and laparoscopic partial nephrectomy
Authors
Asrif Chowdhury
Lincoln Guan Lim Tan
Edmund Chiong
Koon Ho Rha
Ho Yee Tiong
Publication date
01-06-2021
Publisher
Springer International Publishing
Published in
Updates in Surgery / Issue 3/2021
Print ISSN: 2038-131X
Electronic ISSN: 2038-3312
DOI
https://doi.org/10.1007/s13304-021-01028-0

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