Is experience with extracorporeal urinary diversion following robotic assisted radical cystectomy necessary before transitioning to intracorporeal urinary diversion?

Efforts to minimise the high morbidity following open radical cystectomy have led to the development of robotic assisted radical cystectomy (RARC) (1). Since first reported in 2003, the uptake of RARC has increased in recent years despite the lack of solid evidence to suggest a perioperative benefit (2,3). The recently published RAZOR study which randomised patients to open cystectomy or RARC with extracorporeal urinary diversion (eRARC) reported that 90 days complications rates between the two treatment arms were comparable and while hospital length of stay (LOS) was lower favouring the RARC arm (6 vs. 7 days, P=0.02), this is not clinically meaningful (4). Reassuringly, 2-year progression free survival for the two treatment arms were similar (4).

In the recent issue of World J Urol, Tan et al. report their experience of transitioning from eRARC to RARC with intracorporeal urinary diversion (iRARC) in their robotic cystectomy programme (5). While they commenced their RARC programme in 2004, they started performing iRARC in October 2016. In their study which analysed patients treated between April 2015 to October 2017, a total of 127 RARC with ileal conduit (68 eRARC and 59 iRARC) were performed. They report that iRARC treated patients had a significantly lower operating time (330 vs. 375 min, P=0.019), lower blood loss (300 vs. 425 mL, P>0.035), and lower 30-day overall complications (48.4% vs. 71.4%, P=0.008) compared to eRARC. Subsequently, their operating time continued to improve when comparing their first 29 cases to next 30 cases (300 vs. 360 min, P=0.004).

We congratulate Tan et al. for their study which suggests that iRARC can be safely performed and a transition from eRARC can be done without any subsequent increase in patient morbidity and mortality (5). We note that they have diligently collected 90-day complications data which are higher than other reported series (6). We acknowledge that reported case series often suffers from retrospective and publication bias. Indeed, in our early experience, we reported a similar 90-day major complication rate (20.9%) but lower overall complication rate (71.7%) (7,8). Using randomised data as a bench mark, the RARC arm of RAZOR report an overall complication rate of 69% and a major complication rate of 22% at 90 days (4).

The results of Tan et al. suggest that their institution may still be in their learning curve given the increase of overall and major complications from 64% to 79% and 17% to 30% between their two iRARC cohorts (5). While there are no reports suggesting the number of cases required to overcome the learning curve, the Pasadena consensus suggest that a minimum of 100 cases are required before one is considered a very experienced surgeon (9).

We question the requirement for a step wise transition from eRARC to iRARC in contemporary practice. We appreciate the cautious approach adopted by the authors and that most robotic cystectomy historically may feel more comfortable with a step wise approach where eRARC is performed before iRARC is attempted. However, at our institution, we made the transition from open cystectomy directly to iRARC. Subsequently, six of our trainees have gone through our programme and can now successfully perform RARC with intracorporeal ileal conduit diversion without previous eRARC experience. We believe the combination of robotic simulators and good mentorship has made this possible. Future trainees are likely to naturally make the transition without the need for eRARC experience.

Nevertheless, we share the same view that iRARC may be beneficial compared to eRARC despite limited evidence (10,11). Reports of early oncological outcomes between open cystectomy and iRARC suggest they are comparable (12). It is worth pointing out that randomised data from RAZOR was comparing open cystectomy to eRARC (4). Many have argued the logic of using a minimal invasive approach to perform the cystectomy only to convert to a laparotomy to perform urinary diversion (6,13). We believe minimising the need of the laparotomy incision will minimise the need for opiate based analgesia which contributes to ileus, the main reason for prolonged hospital LOS (8). Other advantages include lower blood loss due to pneumoperitoneum, loss of insensible fluid and reduced bowel handling. In addition, although unproven, an intracorporeal urinary diversion may reduce uretero-ileal stricture rates by reducing tension during suturing and allowing to use of shorter ureter length minimising the risk of devascularization the distal ureter.

However, an added benefit from iRARC is the ability to draw from the benefits from an enhance recovery after surgery (ERAS) programme to truly maximise perioperative benefits (14). We have shown that early mobilisation and reduced opiate used which is enabled by iRARC allows for reduction in both hospital LOS and complication rate without increasing readmission rates (14,15). We believe, ERAS itself maybe more advantageous compared to a minimal invasive approach but in combination, they may be synergistic.

While iRARC may be advantageous, centralisation of services remains crucial in improving outcomes following radical cystectomy. There is a clear volume relationship with cystectomy outcomes and may explain the disparity of care as well as variation in cost associated with radical cystectomy (16-18). Efforts towards centralisation of services should be encouraged and evidence suggest that ‘failure to rescue’ rates are lower in high volume centers following complex surgery (19).

In summary, the study by Tan et al. should give confidence to other programmes still performing eRARC to transition to iRARC (1). The publication of the RAZOR trial which does not show a clear benefit for eRARC over open cystectomy should encourage institutions to perform iRARC. While we acknowledge that data supporting the use of iRARC is limited, and our institution is leading a phase III prospective multi-center randomised study comparing open cystectomy to iRARC (iROC trial, ClinicalTrials.gov: NCT03049410) which would hopefully provide evidence on perioperative outcomes comparing iRARC to open cystectomy.

Acknowledgements

None.

Footnote

Conflicts of Interest: JD Kelly is a Co-chief investigator for the iROC trial. WS Tan has no conflicts of interest to declare.

References

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