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Journal of Robotic Surgery
Published in: Journal of Robotic Surgery 2/2016

Open Access 01-06-2016 | Original Article

Beyond 2D telestration: an evaluation of novel proctoring tools for robot-assisted minimally invasive surgery

Authors: Anthony M. Jarc, Swar H. Shah, Troy Adebar, Eric Hwang, Monish Aron, Inderbir S. Gill, Andrew J. Hung

Published in: Journal of Robotic Surgery | Issue 2/2016

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Abstract

Experienced surgeons commonly mentor trainees as they move through their initial learning curves. During robot-assisted minimally invasive surgery, several tools exist to facilitate proctored cases, such as two-dimensional telestration and a dual surgeon console. The purpose of this study was to evaluate the utility and efficiency of three, novel proctoring tools for robot-assisted minimally invasive surgery, and to compare them to existing proctoring tools. Twenty-six proctor-trainee pairs completed validated, dry-lab training exercises using standard two-dimensional telestration and three, new three-dimensional proctoring tools called ghost tools. During each exercise, proctors mentored trainees by correcting trainee technical errors. Proctors and trainees completed post-study questionnaires to compare the effectiveness of the proctoring tools. Proctors and trainees consistently rated the ghost tools as effective proctoring tools. Both proctors and trainees preferred 3DInstruments and 3DHands over standard two-dimensional telestration (proctors p < 0.001 and p = 0.03, respectively, and trainees p < 0.001 and p = 0.002, respectively). In addition, proctors preferred three-dimensional vision of the operative field (used with ghost tools) over two-dimensional vision (p < 0.001). Total mentoring time and number of instructions provided by the proctor were comparable between all proctoring tools (p > 0.05). In summary, ghost tools and three-dimensional vision were preferred over standard two-dimensional telestration and two-dimensional vision, respectively, by both proctors and trainees. Proctoring tools—such as ghost tools—have the potential to improve surgeon training by enabling new interactions between a proctor and trainee.
Literature
1.
Davis JW, Kreaden US, Gabbert J, Thomas R (2014) Learning curve assessment of robot-assisted radical prostatectomy compared with open-surgery controls from the premier perspective database. J Endourol 28(5):560–566CrossRefPubMedPubMedCentral
2.
Schreuder H, Wolswijk R, Zweemer R, Schijven M, Verheijen R (2012) Training and learning robotic surgery, time for a more structured approach: a systematic review. BJOG 119(2):137–149CrossRefPubMed
3.
Lee JY, Mucksavage P, Sundaram CP, McDougall EM (2011) Best practices for robotic surgery training and credentialing. J Urol 185(4):1191–1197CrossRefPubMed
4.
Zorn KC, Gautam G, Shalhav AL, Clayman RV, Ahlering TE, Albala DM, Lee DI, Sundaram CP, Matin SF, Castle EP (2009) Training, credentialing, proctoring and medicolegal risks of robotic urological surgery: recommendations of the society of urologic robotic surgeons. J Urol 182(3):1126–1132CrossRefPubMed
5.
6.
Shin DH, Dalag L, Gill IS, Hung AJ (2014) ConnectTM–a pilot study for the remote proctoring of robotic surgery. J Urol 191(4):e956CrossRef
7.
Lenihan J Jr, Brower M (2012) Web-connected surgery: using the internet for teaching and proctoring of live robotic surgeries. J Robot Surg 6(1):47–52CrossRef
8.
Collins J, Dasgupta P, Kirby R, Gill I (2012) Globalization of surgical expertise without losing the human touch: utilising the network, old and new. BJU Int 109(8):1129CrossRefPubMed
9.
Shin DH, Dalag L, Azhar RA, Santomauro M, Satkunasivam R, Metcalfe C, Dunn M, Berger A, Djaladat H, Nguyen M (2015) A novel interface for the telementoring of robotic surgery. BJU Int 116(2):302–8
10.
Wagner O, Hagen M, Kurmann A, Horgan S, Candinas D, Vorburger S (2012) Three-dimensional vision enhances task performance independently of the surgical method. Surg Endosc 26(10):2961–2968CrossRefPubMed
11.
Smith R, Day A, Rockall T, Ballard K, Bailey M, Jourdan I (2012) Advanced stereoscopic projection technology significantly improves novice performance of minimally invasive surgical skills. Surg Endosc 26(6):1522–1527CrossRefPubMed
12.
Hinata N, Miyake H, Kurahashi T, Ando M, Furukawa J, Ishimura T, Tanaka K, Fujisawa M (2014) Novel telementoring system for robot-assisted radical prostatectomy: impact on the learning curve. Urology 83(5):1088–1092CrossRefPubMed
13.
Blavier A, Gaudissart Q, Cadière G-B, Nyssen A-S (2006) Impact of 2D and 3D vision on performance of novice subjects using da Vinci robotic system. Acta Chir Belg 106(6):662–664CrossRefPubMed
14.
Blavier A, Gaudissart Q, Cadière G-B, Nyssen A-S (2007) Comparison of learning curves and skill transfer between classical and robotic laparoscopy according to the viewing conditions: implications for training. Am J Surg 194(1):115–121CrossRefPubMed
15.
Munz Y, Moorthy K, Dosis A, Hernandez J, Bann S, Bello F, Martin S, Darzi A, Rockall T (2004) The benfits of stereoscopic vision in robotic-assisted performance on bench models. Surg Endosc 18(4):611–616CrossRefPubMed
16.
Jourdan I, Dutson E, Garcia A, Vleugels T, Leroy J, Mutter D, Marescaux J (2004) Stereoscopic vision provides a significant advantage for precision robotic laparoscopy. Br J Surg 91(7):879–885CrossRefPubMed
17.
Byrn JC, Schluender S, Divino CM, Conrad J, Gurland B, Shlasko E, Szold A (2007) Three-dimensional imaging improves surgical performance for both novice and experienced operators using the da Vinci Robot System. Am J Surg 193(4):519–522CrossRefPubMed
18.
Jarc AM, Curet M (2014) Construct validity of nine new inanimate exercises for robotic surgeon training using a standardized setup. Surg Endosc 28(2):648–656CrossRefPubMed
19.
Jarc AM, Curet M (2014) Face, content, and construct validity of four, inanimate training exercises using the da Vinci® Si surgical system configured with Single-Site™ instrumentation. Surgical endoscopy: 1–7
20.
Siddiqui NY, Galloway ML, Geller EJ, Green IC, Hur H-C, Langston K, Pitter MC, Tarr ME, Martino MA (2014) Validity and reliability of the robotic objective structured assessment of technical skills. Obstet Gynecol 123(6):1193–1199CrossRefPubMedPubMedCentral
21.
Crusco S, Jackson T, Advincula A (2014) Comparing the da Vinci Si Single console and dual console in teaching novice surgeons suturing techniques. JSLS 18 (3)
22.
Tan GY, Goel RK, Kaouk JH, Tewari AK (2009) Technological advances in robotic-assisted laparoscopic surgery. Urol Clin North Am 36(2):237–249CrossRefPubMed
23.
Matu FO, Thøgersen M, Galsgaard B, Jensen MM, Kraus M Stereoscopic augmented reality system for supervised training on minimal invasive surgery robots. In: Proceedings of the 2014 Virtual Reality International Conference, 2014. ACM, p 33
24.
25.
Augestad KM, Bellika JG, Budrionis A, Chomutare T, Lindsetmo R-O, Patel H, Delaney C, Lindsetmo RO, Hartvigsen G, Hasvold P (2013) Surgical telementoring in knowledge translation—clinical outcomes and educational benefits a comprehensive review. Surg Innov 20(3):273–281CrossRefPubMed
26.
Gambadauro P, Torrejón R (2013) The “tele” factor in surgery today and tomorrow: implications for surgical training and education. Surg Today 43(2):115–122CrossRefPubMed
27.
28.
Ballantyne GH (2002) Robotic surgery, telerobotic surgery, telepresence, and telementoring. Surg Endosc 16(10):1389–1402CrossRefPubMed
29.
Xu S, Perez M, Yang K, Perrenot C, Felblinger J, Hubert J (2014) Determination of the latency effects on surgical performance and the acceptable latency levels in telesurgery using the dV-Trainer® simulator. Surg Endosc 28(9):2569–2576CrossRefPubMed
Metadata
Title
Beyond 2D telestration: an evaluation of novel proctoring tools for robot-assisted minimally invasive surgery
Authors
Anthony M. Jarc
Swar H. Shah
Troy Adebar
Eric Hwang
Monish Aron
Inderbir S. Gill
Andrew J. Hung
Publication date
01-06-2016
Publisher
Springer London
Published in
Journal of Robotic Surgery / Issue 2/2016
Print ISSN: 1863-2483
Electronic ISSN: 1863-2491
DOI
https://doi.org/10.1007/s11701-016-0564-1

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