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Article of the Week: A Novel Interface for the Telementoring of Robotic Surgery

Every Week the Editor-in-Chief selects an Article of the Week from the current issue of BJUI. The abstract is reproduced below and you can click on the button to read the full article, which is freely available to all readers for at least 30 days from the time of this post.

In addition to the article itself, there is an accompanying editorial written by a prominent member of the urological community. This blog is intended to provoke comment and discussion and we invite you to use the comment tools at the bottom of each post to join the conversation.

If you only have time to read one article this week, it should be this one.

A Novel Interface for the Telementoring of Robotic Surgery

Daniel H. Shin, Leonard Dalag, Raed A. Azhar, Michael Santomauro, Raj SatkunasivamCharles Metcalfe, Matthew Dunn, Andre Berger, Hooman Djaladat, Mike Nguyen, Mihir M. Desai, Monish Aron, Inderbir S. Gill and Andrew J. Hung

 

University of Southern California Institute of Urology, Catherine and Joseph Aresty Department of Urology, Keck School of Medicine, University of Southern California, Los Angeles, CA, USA

 

OBJECTIVE

To prospectively evaluate the feasibility and safety of a novel, second-generation telementoring interface (Connect; Intuitive Surgical Inc., Sunnyvale, CA, USA) for the da Vinci robot.

MATERIALS AND METHODS

Robotic surgery trainees were mentored during portions of robot-assisted prostatectomy and renal surgery cases. Cases were assigned as traditional in-room mentoring or remote mentoring using Connect. While viewing two-dimensional, real-time video of the surgical field, remote mentors delivered verbal and visual counsel, using two-way audio and telestration (drawing) capabilities. Perioperative and technical data were recorded. Trainee robotic performance was rated using a validated assessment tool by both mentors and trainees. The mentoring interface was rated using a multi-factorial Likert-based survey. The Mann–Whitney and t-tests were used to determine statistical differences.

RESULTS

We enrolled 55 mentored surgical cases (29 in-room, 26 remote). Perioperative variables of operative time and blood loss were similar between in-room and remote mentored cases. Robotic skills assessment showed no significant difference (P > 0.05). Mentors preferred remote over in-room telestration (P = 0.05); otherwise no significant difference existed in evaluation of the interfaces. Remote cases using wired (vs wireless) connections had lower latency and better data transfer (P = 0.005). Three of 18 (17%) wireless sessions were disrupted; one was converted to wired, one continued after restarting Connect, and the third was aborted. A bipolar injury to the colon occurred during one (3%) in-room mentored case; no intraoperative injuries were reported during remote sessions.

CONCLUSIONS

In a tightly controlled environment, the Connect interface allows trainee robotic surgeons to be telementored in a safe and effective manner while performing basic surgical techniques. Significant steps remain prior to widespread use of this technology.

Editorial: Robotic Networks – delivering empowerment through integration

Intuitive’s latest version of Connect for the Da Vinci Si model allows surgeons to communicate remotely via a laptop or personal computer, direct to the surgeon’s console. It has one-way video from the console to the remote mentor and bi-directional audio and telestration (drawing), replicating the successful strategy employed in many industries to develop networks, to share expertise and knowledge. The study published by Shin et al. [1] in this issue of BJUI is a technical proof of concept study and is an important first step to realising the potential of robotic networks. The study describes the application of Connect on a local area network (LAN), which is a network that interconnects computers in a limited geographical area such as a hospital, whereas a wide access network (WAN) is a computer network spanning regions, countries or even the world. The next logical advance for Connect is to study connections between different institutions, states and even internationally between countries. Connections between two UK NHS trusts have been successfully trialled, with plans for formal connections between hospitals in Sweden and the UK underway.

Minimally invasive surgery using video technologies has greatly improved opportunities for surgical learning. Telementoring has existed in various forms for >20 years and has been shown to have a positive impact on outcomes [2]. In a study by Påhlsson et al. [3], telementoring delivered by a high-volume surgeon at a tertiary hospital to a low-volume rural hospital, increased their cannulation rate in endoscopic retrograde cholangiopancreatography from 85% (one of the lowest in the country) to 99% (highest success rate).

While robotic surgery continues to evolve quickly, it remains an expensive service with required investment in surgeons’ learning curves in both established and new techniques. Maximum value is realised once the team is experienced, efficient and outcomes are optimised. Even between tertiary centres of excellence there are different skill sets. Successful collaborative approaches to training have potential to steepen learning curves. With Connect robotic trainers will have the additional option to disseminate their knowledge from a distance, without the need for mentor or mentee to travel.

Current healthcare WANs between hospitals can enable secure, quality assured connections over national and international networks. Connect will have a role in LANs [1]; however, studying telementoring across larger networks will probably define its beneficial effects on the learning curve. Connections between centres with the largest difference in skill sets are likely to show the greatest impacts.

Robotic networks are likely to exist in various forms and telementoring could be complemented by supplementary services delivered over both local and wide access networks. Future potential services over a LAN include real-time multi-disciplinary teams with direct communication from the console to the radiologists and histopathologists.

Simulators have been used in industries outside healthcare, such as the aviation industry, to measure both proficiency and technical skill learning. Although robotic surgical simulation has not yet reached a stage where it replicates all aspects of robotic surgical procedures, it currently has potential to accelerate trainees along their learning curve outside the operating room and thus contribute to patient safety. Simulators greatest future value may be aligned with the data and feedback that robotic networks will provide, replicating the roles of airport control centres and flight simulators. With better understanding of surgical learning curves and the ability to score and differentiate between performance levels [4], data collected via networks may also have a future role in regulation of surgery (Fig. 1).

image

Figure 1. Potential effect of robotic networks on identifying suboptimal technique and improving patient outcomes. (*Connect and Simulation diagrams by Intuitive Surgical).

International robotic networks will help achieve balance between the continual cycle of optimisation and standardisation of robotic surgical techniques. Standardised live surgery broadcast from home institutions [5] could support and promote both telementoring and the benefits of standardised surgical techniques [5, 6]. Standardisation is critical to developing cohesive networks with better understanding between mentors and mentees. It also aids identification of the ‘hazard’ steps in complex multistep procedures, enabling strategies to avoid the associated complications [6].

Sharing of expertise requires shared goals. In highly competitive healthcare systems where hospitals compete in attracting patients, there is inherent resistance to sharing. Connect enables interaction between mentor and mentee and once hard endpoints are identified and the beneficial effects of sharing are studied, new thinking in robotic surgery is likely. If benefits to surgical outcomes and improved safety using Connect are confirmed, both legal and reimbursement issues will probably be resolved.

In conclusion, change is driven on varying scales from local discussion, to national and international opinion and debate. While Connect will undoubtedly enhance communication between surgeons, it is the development of WANs, connecting the centres with the biggest differences in skill sets, which may deliver the greatest improvements. Collaboration via robotic networks has the potential to not only enable but to drive advancement in multiple areas of robotic surgery through the sharing of knowledge, innovations and expertise, resulting in continuous incremental improvement.

Justin Collins, Consultant Urologists, Olof AkreConsultant Urologists, Benjamin Challacombe*, Consultant Urologists, Omer Karim, Consultant Urologists and Peter Wiklund, Professor
Department of Urology, Karolinska University HospitalStockholm, Sweden, *Department of Surgery and Cancer, Kings College, Guys Hospital, London, and Department of Urology, Wexham Park Hospital, Slough, UK

 

References

 

1 Shin DH, Dalag L, Azhar Raed A et al. A novel interface for the telementoring of robotic surgery. BJU Int 2014; [Epub ahead of print]. DOI: 10.1111/bju.12985.

 

2 Challacombe B, Kandaswamy R, Dasgupta P, Mamode N. Telementoring facilitates independent hand-assisted laparoscopic living donor nephrectomy. Transplant Proc 2005;37:6136. 

 

 

4 Bonrath EM, Zevin B, Dedy NJ, Grantcharov TP. Error rating tool to identify and analyse technical errors and events in laparoscopic surgery. Br J Surg 2013;100:10808.

 

5 Collins JW, Akre O, Wiklund PN. Re: Walter Artibani, Vincenzo Ficarra, Ben J. Challacombe et al. EAU Policy on Live Surgery Events. Eur Urol 2014; 66: 8797. Eur Urol 2014; 66: e1212.

 

6 Collins JW, Tyritzis S, Nyberg T et al. Robot-assisted radical cystectomy – description of an evolved approach to radical cystectomy. Eur Urol 2013;64:65463.

 

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