Subscribe to RSS
DOI: 10.1055/s-0036-1582263
Is There Bias against Simulation in Microsurgery Training?
Publication History
08 January 2016
23 February 2016
Publication Date:
13 April 2016 (online)
Abstract
Background While other surgical specialties have embraced virtual reality simulation for training and recertification, microsurgery has lagged. This study aims to assess the opinions of microsurgeons on the role of simulation in microsurgery assessment and training.
Methods We surveyed faculty members of the American Society of Reconstructive Microsurgery to ascertain opinions on their use of simulation in training and opinions about the utility of simulation for skills acquisition, teaching, and skills assessment. The 21-question survey was disseminated online to 675 members.
Results Eighty-nine members completed the survey for a 13.2% response rate. Few microsurgeons have experience with high-fidelity simulation, and opinions on its utility are internally inconsistent. Although 84% of respondents could not identify a reason why simulation would not be useful, only 24% believed simulation is a useful measure of clinical performance. Nearly three-fourths of respondents were skeptical that simulation would improve their skills. Ninety-four percent had no experience with simulator-based assessment.
Conclusion Simulation has been shown to improve skills acquisition in microsurgery, but our survey suggests that unfamiliarity may foster bias against the technology. Failure to incorporate simulation may adversely affect training and may put surgeons at a disadvantage should these technologies be adopted for recertification by regulatory agencies.
-
References
- 1 Sauer MV, Zeffer KB, Bustillo MC, Buster JE. Sterilization reversals performed by fellows in training: what success rates can we reasonably expect?. Microsurgery 1987; 8 (3) 125-127
- 2 Balasundaram I, Aggarwal R, Darzi LA. Development of a training curriculum for microsurgery. Br J Oral Maxillofac Surg 2010; 48 (8) 598-606
- 3 Ahmed K, Khan RS, Darzi A, Athanasiou T, Hanna GB. Recertification: what do specialists think about skill assessment?. Surgeon 2013; 11 (3) 120-124
- 4 Vassiliou MC, Feldman LS. Objective assessment, selection, and certification in surgery. Surg Oncol 2011; 20 (3) 140-145
- 5 Nicholas RS, Madada-Nyakauru RN, Irri RA, Myers SR, Ghanem AM. Research priorities in light of current trends in microsurgical training: revalidation, simulation, cross-training, and standardisation. Arch Plast Surg 2014; 41 (3) 218-224
- 6 Leclère FM, Trelles M, Lewbart GA, Vögelin E. Is there good simulation basic training for end-to-side vascular microanastomoses?. Aesthetic Plast Surg 2013; 37 (2) 454-458
- 7 Kamath JB, Kamath SJ. A custom-made latex conduit for simulation of microvascular repair. Plast Reconstr Surg 2007; 119 (5) 1634-1635
- 8 Prunières GJC, Taleb C, Hendriks S , et al. Use of the Konnyaku Shirataki noodle as a low fidelity simulation training model for microvascular surgery in the operating theatre. Chir Main 2014; 33 (2) 106-111
- 9 Nugent E, Joyce C, Perez-Abadia G , et al. Factors influencing microsurgical skill acquisition during a dedicated training course. Microsurgery 2012; 32 (8) 649-656
- 10 Atkins JL, Kalu PU, Lannon DA, Green CJ, Butler PE. Training in microsurgical skills: Does course-based learning deliver?. Microsurgery 2005; 25 (6) 481-485
- 11 Grober ED, Hamstra SJ, Wanzel KR , et al. Laboratory based training in urological microsurgery with bench model simulators: a randomized controlled trial evaluating the durability of technical skill. J Urol 2004; 172 (1) 378-381
- 12 Moulton CA, Dubrowski A, Macrae H, Graham B, Grober E, Reznick R. Teaching surgical skills: what kind of practice makes perfect?: a randomized, controlled trial. Ann Surg 2006; 244 (3) 400-409
- 13 Studinger R, Bradford M, Jackson I. Microsurgical training: is it adequate for the operating room?. Eur J Plast Surg 2005; 28 (2) 91-93
- 14 Price J, Naik V, Boodhwani M, Brandys T, Hendry P, Lam BK. A randomized evaluation of simulation training on performance of vascular anastomosis on a high-fidelity in vivo model: the role of deliberate practice. J Thorac Cardiovasc Surg 2011; 142 (3) 496-503
- 15 Sturm LP, Windsor JA, Cosman PH, Cregan P, Hewett PJ, Maddern GJ. A systematic review of skills transfer after surgical simulation training. Ann Surg 2008; 248 (2) 166-179
- 16 Kazemi H, Rappel JK, Poston T, Hai Lim B, Burdet E, Leong Teo C. Assessing suturing techniques using a virtual reality surgical simulator. Microsurgery 2010; 30 (6) 479-486
- 17 Reznick RK, MacRae H. Teaching surgical skills—changes in the wind. N Engl J Med 2006; 355 (25) 2664-2669
- 18 Starkes JL, Payk I, Hodges NJ. Developing a standardized test for the assessment of suturing skill in novice microsurgeons. Microsurgery 1998; 18 (1) 19-22
- 19 Selber JC, Chang EI, Liu J , et al. Tracking the learning curve in microsurgical skill acquisition. Plast Reconstr Surg 2012; 130 (4) 550e-557e
- 20 Ramachandran S, Ghanem AM, Myers SR. Assessment of microsurgery competency-where are we now?. Microsurgery 2013; 33 (5) 406-415
- 21 Ver Halen JP, Chen A, Jeffers L, Basu CB ; ASPS Young Plastic Surgeons' Steering Committee. Young Plastic Surgeons Forum member survey: Part II. Advocacy in plastic surgery: opinions toward the ASPS and PlastyPAC. Plast Reconstr Surg 2014; 134 (2) 353-360