SURGICAL TECHNIQUES

How to teach vaginal surgery through simulation

OBG Manag. 2022 May;34(5):SS4-SS10 | doi: 10.12788.obgm.0193

References

Wright JD, Huang Y, Li AH, et al. Nationwide estimates of annual inpatient and outpatient hysterectomies performed in the United States. Obstet Gynecol. 2022;139:446-448.
Gressel GM, Potts JR 3rd, Cha S, et al. Hysterectomy route and numbers reported by graduating residents in obstetrics and gynecology training programs. Obstet Gynecol. 2020;135:268-273.
Lioce L, ed. Healthcare Simulation Dictionary. 2nd ed. Rockville, MD; Agency for Healthcare Research and Quality: 2020. AHRQ Publication No. 20-0019.
Norman G, Dore K, Grierson L. The minimal relationship between simulation fidelity and transfer of learning. Med Educ. 2012;46:636-647.
Illston JD, Ballard AC, Ellington DR, et al. Modified beef tongue model for fourth-degree laceration repair simulation. Obstet Gynecol. 2017;129:491-496.
WorldPoint website. 3B Scientific Episiotomy and Suturing Trainer. https://www.worldpoint.com/3b-episiotomy-and-suturing-sim. Accessed April 20, 2022.
Balafoutas D, Joukhadar R, Kiesel M, et al. The role of deconstructive teaching in the training of laparoscopy. JSLS. 2019;23:e2019.00020.
Ericsson KA, Harwell KW. Deliberate practice and proposed limits on the effects of practice on the acquisition of expert performance: why the original definition matters and recommendations for future research. Front Psychol. 2019;10:2396.
Smith TM, Fenner DE. Vaginal hysterectomy teaching model—an educational video. Female Pelvic Med Reconstr Surg. 2012;18:S43. Abstract.
Greer JA, Segal S, Salva CR, et al. Development and validation of simulation training for vaginal hysterectomy. J Minim Invasive Gynecol. 2014;21:74-82.
Malacarne DR, Escobar CM, Lam CJ, et al. Teaching vaginal hysterectomy via simulation: creation and validation of the objective skills assessment tool for simulated vaginal hysterectomy on a task trainer and performance among different levels of trainees. Female Pelvic Med Reconstr Surg. 2019;25:298-304.
Zoorob D, Frenn R, Moffitt M, et al. Multi-institutional validation of a vaginal hysterectomy simulation model for resident training. J Minim Invasive Gynecol. 2021;28:1490-1496.e1.
Barrier BF, Thompson AB, McCullough MW, et al. A novel and inexpensive vaginal hysterectomy simulator. Simul Healthc. 2012;7:374-379.
Burkett LS, Makin J, Ackenbom M, et al. Validation of transvaginal hysterectomy surgical model—modification of the flowerpot model to improve vesicovaginal plane simulation. J Minim Invasive Gynecol. 2021;28:1526-1530.
Escobar C, Malacarne Pape D, Ferrante KL, et al. Who should be teaching vaginal hysterectomy on a task trainer? A multicenter randomized trial of peer versus expert coaching. J Surg Simul. 2020;7:63-72.
The obstetrics and gynecology milestone project. J Grad Med Educ. 2014;6(1 suppl 1):129-143.
Nasca TJ, Philibert I, Brigham T, et al. The next GME accreditation system—rationale and benefits. N Engl J Med. 2012;366:1051-1056.
Chen CCG, Korn A, Klingele C, et al. Objective assessment of vaginal surgical skills. Am J Obstet Gynecol. 2010;203:79.e1-8.
American College of Obstetricians and Gynecologists. Surgical curriculum in obstetrics and gynecology. https://www.acog.org /education-and-events/simulations/surgical-curriculum-in-ob-gyn.
Chen CCG, Lockrow EG, DeStephano CC, et al. Establishing validity for a vaginal hysterectomy simulation model for surgical skills assessment. Obstet Gynecol. 2020;136:942-949.
Vedula SS, Hager GD. Surgical data science: the new knowledge domain. Innov Surg Sci. 2017;2:109-121.
Witthaus MW, Farooq S, Melnyk R, et al. Incorporation and validation of clinically relevant performance metrics of simulation (CRPMS) into a novel full-immersion simulation platform for nerve-sparing robot-assisted radical prostatectomy (NS-RARP) utilizing three-dimensional printing and hydrogel casting technology. BJU Int. 2020;125:322-332.
Vedula SS, Malpani A, Ahmidi N, et al. Task-level vs segment-level quantitative metrics for surgical skill assessment. J Surg Educ. 2016;73:482-489.
Maier-Hein L, Eisenmann M, Sarikaya D, et al. Surgical data science—from concepts toward clinical translation. Med Image Anal. 2022;76:102306.
Hung AJ, Chen J, Gill IS. Automated performance metrics and machine learning algorithms to measure surgeon performance and anticipate clinical outcomes in robotic surgery. JAMA Surg. 2018;153:770-771.
Altman K, Chen G, Chou B, et al. Surgical curriculum in obstetrics and gynecology: vaginal hysterectomy simulation. https://cfweb.acog. org/scog/scog008/Simulation.cfm.
DeLancey JOL. Basic Exercises: Surgical Technique. Davis + Geck; Brooklyn, NY: 1987.
Geoffrion R, Suen MW, Koenig NA, et al. Teaching vaginal surgery to junior residents: initial validation of 3 novel procedure-specific low-fidelity models. J Surg Educ. 2016;73:157-161.
Pandey VA, Wolfe JHN, Lindhal AK, et al. Validity of an exam assessment in surgical skill: EBSQ-VASC pilot study. Eur J Vasc Endovasc Surg. 2004;27:341-348.
Limbs&Things website. Knot Tying Trainer. https://limbsandthings. com/us/products/50050/50050-knot-tying-trainer. Accessed April 20, 2022.
Vaughan MH, Kim-Fine S, Hullfish KL, et al. Validation of the simulated vaginal hysterectomy trainer. J Minim Invasive Gynecol. 2018;25:1101-1106.
Braun K, Henley B, Ray C, et al. Teaching vaginal hysterectomy: low fidelity trainer provides effective simulation at low cost. Obstet Gynecol. 2017;130:44S.
Anand M, Duffy CP, Vragovic O, et al. Surgical anatomy of vaginal hysterectomy—impact of a resident-constructed simulation model. Female Pelvic Med Reconstr Surg. 2018;24:176-182.
Chen CC, Vaccaro CM. ACOG Simulation Consortium Surgical Curriculum: anterior and posterior repair. 2017. https://cfweb.acog. org/scog/.
Schmidt PC, Fairchild PS, Fenner DE, et al. The Fundamentals of Vaginal Surgery pilot study: developing, validating, and setting proficiency scores for a vaginal surgical skills simulation system. Am J Obstet Gynecol. 2021;225:558.e1-558.e11.

Low-cost vaginal hysterectomy models

Multiple low-cost vaginal hysterectomy simulation models are described. Two models developed many years ago include the ACOG SWG flowerpot model¹⁴ and the PROMPT shoulder dystocia pelvic trainer model.^10,11,14 The former model is low cost as it can be constructed from easily obtained household materials, but its downside is that it takes time and effort to obtain the materials and to assemble them. The latter model is faster to assemble but requires one to use a PROMPT pelvis for shoulder dystocia training, which has a considerable upfront cost. However, it is available in most hospitals with considerable obstetrical volume, and it allows for the most realistic perineum, which is helpful in recreating the feel of vaginal surgery, including retraction and exposure.

Many models created and described in the literature are variations of the models mentioned above, and many use commercially available low-cost bony pelvis models and polyvinyl chloride (PVC) pipes as a foundation for the soft tissue inserts to attach.^12,13,31-33 Each model varies on what it “teaches best” regarding realism—for example, teaching anatomy, working in a tight space, dissection, or clamp placement and suture ligature.

Furthermore, since vaginal hysterectomy is a high-complexity procedure in terms of skills (working in confined space, limited view, “upside-down” anatomy, and need to direct assistants for retraction and exposure), task breakdown is important for simulation learning, as it is not efficient to repeat the entire procedure until proficiency is reached. Two trainers have been described to address that need: the milk carton and the vaginal suturing trainer. The latter allows learners to practice clamp placement and pedicle ligation multiple times, including in confined space (FIGURE 2), and the former allows them to do the same in a procedural matter as the clamp placement moves caudad to cephalad during the procedure (FIGURE 3).

Native tissue pelvic floor surgery simulation

While there are few publications regarding surgical simulation models for native tissue pelvic floor surgeries, a low-cost anterior and posterior repair model was developed for the ACOG SWG Simulation Toolkit and published online in 2017, after their peer-review process. The fidelity is moderate for this low-cost model, which costs less than $5 per use. The simulation model requires a new vaginal insert for each learner, which is fast and easy to make and requires only a few components; however, the bony pelvis (for example, the flowerpot model) needs to be purchased or created. The stage of the anterior wall prolapse can be adjusted by the amount of fluid placed in the balloon, which is used to simulate the bladder. The more fluid that is placed in the “bladder,” the more severe the anterior wall prolapse appears. The vaginal caliber can be adjusted, if needed, by increasing or decreasing the size of the components to create the vagina, but the suggested sizes simulate a significantly widened vaginal caliber that would benefit from a posterior repair with perineorrhaphy. Although there is no validity evidence for this model, a skills assessment is available through the ACOG Simulation Surgical Curriculum. Of note, native tissue colpopexy repairs are also possible with this model (or another high-fidelity model, such as the Miya Model), if the sacrospinous ligaments and/or uterosacral ligaments are available on the pelvic model in use. This model’s limitations include the absence of a high-fidelity plane of dissection of the vaginal muscularis, and that no bleeding is encountered, which is the case for many low-cost models.^19,34

Fundamentals of Vaginal Surgery (FVS) basic surgical skills simulation

The FVS simulation system, consisting of a task trainer paired with 6 selected surgical tasks, was developed to teach basic skills used in vaginal surgery.³⁵ The FVS task trainer is 3D printed and has 3 main components: a base piece that allows for different surgical materials to be secured, a depth extender, and a width reducer. In addition, it has a mobile phone mount and a window into the system to enable video capture of skills exercises.

The FVS simulator is designed to enable 6 surgical tasks, including one-handed knot tying, two-handed knot tying, running suturing, plication suturing, Heaney transfixion pedicle ligation, and free pedicle ligation (FIGURE 4). In a pilot study, the FVS simulation system was deemed representative of the intended surgical field, useful for inclusion in a training program, and favored as a tool for both training and testing. Additionally, an initial proficiency score of 400 was set, which discriminated between novice and expert surgeons.³⁵

An advantage of this simulation system is that it allows learners to focus on basic skills, rather than on an entire specific procedure. Further, the system is standardized, as it is commercially manufactured; this also allows for easy assembly. The disadvantage of this model is that it cannot be modified to teach specific vaginal procedures, and it must be purchased, rather than constructed on site. Further studies are needed to create generalizable proficiency scores and to assess its use in training and testing. For more information on the FVS simulation model, visit the Arbor Simulation website (http://arborsim.com).

Surgical simulation’s important role

Surgical skills can be learned and improved in the simulation setting in a low-stakes, low-pressure environment. Simulation can enable basic skills development and then higher-level learning of complex procedures. Skill assessment is important to aid in learning (via formative assessments) and for examination or certification (summative assessments).

With decreasing vaginal surgical volumes occurring nationally, it is becoming even more important to use surgical simulation to teach and maintain vaginal surgical skills. In this article, we reviewed various different simulation models that can be used for developing vaginal surgical skills and presented the advantages, limitations, and resources relevant for each simulation model. ●

References

Wright JD, Huang Y, Li AH, et al. Nationwide estimates of annual inpatient and outpatient hysterectomies performed in the United States. Obstet Gynecol. 2022;139:446-448.
Gressel GM, Potts JR 3rd, Cha S, et al. Hysterectomy route and numbers reported by graduating residents in obstetrics and gynecology training programs. Obstet Gynecol. 2020;135:268-273.
Lioce L, ed. Healthcare Simulation Dictionary. 2nd ed. Rockville, MD; Agency for Healthcare Research and Quality: 2020. AHRQ Publication No. 20-0019.
Norman G, Dore K, Grierson L. The minimal relationship between simulation fidelity and transfer of learning. Med Educ. 2012;46:636-647.
Illston JD, Ballard AC, Ellington DR, et al. Modified beef tongue model for fourth-degree laceration repair simulation. Obstet Gynecol. 2017;129:491-496.
WorldPoint website. 3B Scientific Episiotomy and Suturing Trainer. https://www.worldpoint.com/3b-episiotomy-and-suturing-sim. Accessed April 20, 2022.
Balafoutas D, Joukhadar R, Kiesel M, et al. The role of deconstructive teaching in the training of laparoscopy. JSLS. 2019;23:e2019.00020.
Ericsson KA, Harwell KW. Deliberate practice and proposed limits on the effects of practice on the acquisition of expert performance: why the original definition matters and recommendations for future research. Front Psychol. 2019;10:2396.
Smith TM, Fenner DE. Vaginal hysterectomy teaching model—an educational video. Female Pelvic Med Reconstr Surg. 2012;18:S43. Abstract.
Greer JA, Segal S, Salva CR, et al. Development and validation of simulation training for vaginal hysterectomy. J Minim Invasive Gynecol. 2014;21:74-82.
Malacarne DR, Escobar CM, Lam CJ, et al. Teaching vaginal hysterectomy via simulation: creation and validation of the objective skills assessment tool for simulated vaginal hysterectomy on a task trainer and performance among different levels of trainees. Female Pelvic Med Reconstr Surg. 2019;25:298-304.
Zoorob D, Frenn R, Moffitt M, et al. Multi-institutional validation of a vaginal hysterectomy simulation model for resident training. J Minim Invasive Gynecol. 2021;28:1490-1496.e1.
Barrier BF, Thompson AB, McCullough MW, et al. A novel and inexpensive vaginal hysterectomy simulator. Simul Healthc. 2012;7:374-379.
Burkett LS, Makin J, Ackenbom M, et al. Validation of transvaginal hysterectomy surgical model—modification of the flowerpot model to improve vesicovaginal plane simulation. J Minim Invasive Gynecol. 2021;28:1526-1530.
Escobar C, Malacarne Pape D, Ferrante KL, et al. Who should be teaching vaginal hysterectomy on a task trainer? A multicenter randomized trial of peer versus expert coaching. J Surg Simul. 2020;7:63-72.
The obstetrics and gynecology milestone project. J Grad Med Educ. 2014;6(1 suppl 1):129-143.
Nasca TJ, Philibert I, Brigham T, et al. The next GME accreditation system—rationale and benefits. N Engl J Med. 2012;366:1051-1056.
Chen CCG, Korn A, Klingele C, et al. Objective assessment of vaginal surgical skills. Am J Obstet Gynecol. 2010;203:79.e1-8.
American College of Obstetricians and Gynecologists. Surgical curriculum in obstetrics and gynecology. https://www.acog.org /education-and-events/simulations/surgical-curriculum-in-ob-gyn.
Chen CCG, Lockrow EG, DeStephano CC, et al. Establishing validity for a vaginal hysterectomy simulation model for surgical skills assessment. Obstet Gynecol. 2020;136:942-949.
Vedula SS, Hager GD. Surgical data science: the new knowledge domain. Innov Surg Sci. 2017;2:109-121.
Witthaus MW, Farooq S, Melnyk R, et al. Incorporation and validation of clinically relevant performance metrics of simulation (CRPMS) into a novel full-immersion simulation platform for nerve-sparing robot-assisted radical prostatectomy (NS-RARP) utilizing three-dimensional printing and hydrogel casting technology. BJU Int. 2020;125:322-332.
Vedula SS, Malpani A, Ahmidi N, et al. Task-level vs segment-level quantitative metrics for surgical skill assessment. J Surg Educ. 2016;73:482-489.
Maier-Hein L, Eisenmann M, Sarikaya D, et al. Surgical data science—from concepts toward clinical translation. Med Image Anal. 2022;76:102306.
Hung AJ, Chen J, Gill IS. Automated performance metrics and machine learning algorithms to measure surgeon performance and anticipate clinical outcomes in robotic surgery. JAMA Surg. 2018;153:770-771.
Altman K, Chen G, Chou B, et al. Surgical curriculum in obstetrics and gynecology: vaginal hysterectomy simulation. https://cfweb.acog. org/scog/scog008/Simulation.cfm.
DeLancey JOL. Basic Exercises: Surgical Technique. Davis + Geck; Brooklyn, NY: 1987.
Geoffrion R, Suen MW, Koenig NA, et al. Teaching vaginal surgery to junior residents: initial validation of 3 novel procedure-specific low-fidelity models. J Surg Educ. 2016;73:157-161.
Pandey VA, Wolfe JHN, Lindhal AK, et al. Validity of an exam assessment in surgical skill: EBSQ-VASC pilot study. Eur J Vasc Endovasc Surg. 2004;27:341-348.
Limbs&Things website. Knot Tying Trainer. https://limbsandthings. com/us/products/50050/50050-knot-tying-trainer. Accessed April 20, 2022.
Vaughan MH, Kim-Fine S, Hullfish KL, et al. Validation of the simulated vaginal hysterectomy trainer. J Minim Invasive Gynecol. 2018;25:1101-1106.
Braun K, Henley B, Ray C, et al. Teaching vaginal hysterectomy: low fidelity trainer provides effective simulation at low cost. Obstet Gynecol. 2017;130:44S.
Anand M, Duffy CP, Vragovic O, et al. Surgical anatomy of vaginal hysterectomy—impact of a resident-constructed simulation model. Female Pelvic Med Reconstr Surg. 2018;24:176-182.
Chen CC, Vaccaro CM. ACOG Simulation Consortium Surgical Curriculum: anterior and posterior repair. 2017. https://cfweb.acog. org/scog/.
Schmidt PC, Fairchild PS, Fenner DE, et al. The Fundamentals of Vaginal Surgery pilot study: developing, validating, and setting proficiency scores for a vaginal surgical skills simulation system. Am J Obstet Gynecol. 2021;225:558.e1-558.e11.

How to teach vaginal surgery through simulation

References

Low-cost vaginal hysterectomy models

Native tissue pelvic floor surgery simulation

Fundamentals of Vaginal Surgery (FVS) basic surgical skills simulation

Surgical simulation’s important role

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