Feng Q, Yuan W, Li T, Tang B, Jia B, Zhou Y et al (2022) Robotic versus laparoscopic surgery for middle and low rectal cancer (REAL): short-term outcomes of a multicentre randomised controlled trial. Lancet Gastroenterol Hepatol 7(11):991–1004
Park JS, Lee SM, Choi GS, Park SY, Kim HJ, Song SH et al (2023) Comparison of laparoscopic versus robot-assisted surgery for rectal cancers: The COLRAR Randomized Controlled Trial. Ann Surg 278(1):31–38
Siddiqi N, Stefan S, Jootun R, Mykoniatis I, Flashman K, Beable R et al (2021) Robotic Complete Mesocolic Excision (CME) is a safe and feasible option for right colonic cancers: short and midterm results from a single-centre experience. Surg Endosc 35(12):6873–6881
PubMed PubMed Central Google Scholar
Harji D, Houston F, Burke J, Griffiths B, Tilney H, Miskovic D et al (2023) The current status of robotic colorectal surgery training programmes. J Robot Surg 17(2):251–263
Panteleimonitis S, Miskovic D, Bissett-Amess R, Figueiredo N, Turina M, Spinoglio G et al (2021) Short-term clinical outcomes of a European training programme for robotic colorectal surgery. Surg Endosc 35(12):6796–6806
Sian TS, Tierney GM, Park H, Lund JN, Speake WJ, Hurst NG et al (2018) Robotic colorectal surgery: previous laparoscopic colorectal experience is not essential. J Robot Surg 12(2):271–275
Aradaib M, Neary P, Hafeez A, Kalbassi R, Parvaiz A, O’Riordain D (2019) Safe adoption of robotic colorectal surgery using structured training: early Irish experience. J Robot Surg 13(5):657–662
Waters PS, Flynn J, Larach JT, Fernando D, Peacock O, Foster JD et al (2021) Fellowship training in robotic colorectal surgery within the current hospital setting: an achievable goal? ANZ J Surg 91(11):2337–2344
Soliman MK, Tammany AJ (2021) Teaching and training surgeons in robotic colorectal surgery. Clin Colon Rectal Surg 34(5):280–285
PubMed PubMed Central Google Scholar
Gauci C, Zahid A, Ravindran P, Lynch AC, Pillinger S (2024) Preceptorship in robotic colorectal surgery: experience from the Australian private sector. J Robot Surg 18(1):213
PubMed PubMed Central Google Scholar
Gleason A, Servais E, Quadri S, Manganiello M, Cheah YL, Simon CJ et al (2022) Developing basic robotic skills using virtual reality simulation and automated assessment tools: a multidisciplinary robotic virtual reality-based curriculum using the Da Vinci Skills Simulator and tracking progress with the Intuitive Learning platform. J Robot Surg 16(6):1313–1319
Younes MM, Larkins K, To G, Burke G, Heriot A, Warrier S et al (2023) What are clinically relevant performance metrics in robotic surgery? A systematic review of the literature. J Robot Surg 17(2):335–350
Goh AC, Goldfarb DW, Sander JC, Miles BJ, Dunkin BJ (2012) Global evaluative assessment of robotic skills: validation of a clinical assessment tool to measure robotic surgical skills. J Urol 187(1):247–252
Panteleimonitis S, Popeskou S, Aradaib M, Harper M, Ahmed J, Ahmad M et al (2018) Implementation of robotic rectal surgery training programme: importance of standardisation and structured training. Langenbecks Arch Surg 403(6):749–760
PubMed PubMed Central Google Scholar
Harji D, Aldajani N, Cauvin T, Chauvet A, Denost Q (2023) Parallel, component training in robotic total mesorectal excision. J Robot Surg 17(3):1049–1055
Burke JR, Fleming CA, King M, El-Sayed C, Bolton WS, Munsch C et al (2023) Utilising an accelerated Delphi process to develop consensus on the requirement and components of a pre-procedural core robotic surgery curriculum. J Robot Surg 17(4):1443–1455
PubMed PubMed Central Google Scholar
Miskovic D, Ahmed J, Bissett-Amess R, Gómez Ruiz M, Luca F, Jayne D et al (2019) European consensus on the standardization of robotic total mesorectal excision for rectal cancer. Colorectal Dis 21(3):270–276
Tou S, Gómez Ruiz M, Gallagher AG, Matzel KE (2020) European expert consensus on a structured approach to training robotic-assisted low anterior resection using performance metrics. Colorectal Dis 22(12):2232–2242
CAS PubMed PubMed Central Google Scholar
Wong SW, Crowe P (2022) Factors affecting the learning curve in robotic colorectal surgery. J Robot Surg 16(6):1249–1256
PubMed PubMed Central Google Scholar
Lai LY, Kaufman SR, Modi PK, Ellimoottil C, Oerline M, Caram MEV et al (2022) Impact of advanced practice provider integration into multispecialty group practices on outcomes following major surgery. Surg Innov 29(1):111–117
Jones BT, Ha JS, Lawrence C, Tsai LL, Yang SC (2023) A dedicated robotic bedside physician assistant significantly enhances trainee console operating time in general thoracic surgery. JTCVS Open 16:1070–1073
PubMed PubMed Central Google Scholar
Thomas A, Altaf K, Sochorova D, Gur U, Parvaiz A, Ahmed S (2021) Effective implementation and adaptation of structured robotic colorectal programme in a busy tertiary unit. J Robot Surg 15(5):731–739
Cho JS, Hahn KY, Kwak JM, Kim J, Baek SJ, Shin JW et al (2013) Virtual reality training improves da Vinci performance: a prospective trial. J Laparoendosc Adv Surg Tech A 23(12):992–998
van der Leun JA, Siem G, Meijer RP, Brinkman WM (2022) Improving robotic skills by video review. J Endourol 36(8):1126–1135
Collins D, Machairas N, Duchalais E, Landmann RG, Merchea A, Colibaseanu DT et al (2018) Participation of colon and rectal fellows in robotic rectal cancer surgery: effect on surgical outcomes. J Surg Educ 75(2):465–470
Comments (0)