Advancing Urology Training: An In-Depth Evaluation of a 3D-Printed Ileal Conduit Simulation Model

Abstract

Introduction:

Conduitoscopy is a technically demanding procedure with limited opportunities for structured training. We evaluated the educational impact of a 3D-printed ileal conduit simulator on knowledge acquisition and perceived learning among urology trainees and fully qualified urologists (FQU).

Methods:

We conducted a prospective, single-group study during a national urology training course in 2024. Participants included U.K.-based resident doctors in year 3 and year 7, as well as FQU; participation was voluntary. Knowledge acquisition was assessed with a five-item multiple-choice questionnaire (MCQ) administered before and after training, while educational experience was evaluated post-training using the Michigan Standard Simulation Experience Scale (MiSSES), covering key educational sections. Comparisons of MCQ scores were analyzed using Welch’s t-test, and group differences in survey responses were assessed using Fisher’s exact test. Free-text comments were also collected and thematically analyzed to capture participants’ perceptions and suggestions.

Results:

Fifty-three participants completed the study (36 resident doctors in year 3 [RDY3], 9 in year 7 [RDY7], and 8 FQU). Agreement rates were high across all MiSSES sections, with 100% endorsing teaching quality and overall ratings. MCQ scores improved significantly after training (mean 2.55 vs 3.23, p < 0.001; Cohen’s d = 0.71). Comparison between RDY3 and the combined RDY7 + FQU group showed a significant difference in self-efficacy (p = 0.003), while no statistically significant differences were observed in fidelity, educational value, or teaching quality.

Conclusion:

The 3D-printed ileal conduit simulator is an effective tool for conduitoscopy training, improving theoretical knowledge and receiving strong endorsement across key educational sections. Participant feedback highlighted its realism and educational value, alongside suggestions for minor refinements. These findings support its integration into structured endourology urology training programs.

Keywords

ureteroscopy conduitoscopy skills training urology

Get full access to this article

View all access options for this article.

References

1. Ahmed

, Jawad

, Abboudi

, et al. Effectiveness of simulation-based training in urology: A systematic review. J Urol 2015;193(6):1706–1715.

2. Cook

, Hatala

, Brydges

, et al. Technology-enhanced simulation for health professions education: A systematic review and meta-analysis. JAMA. 2011;306(9):978–988.

3. Gallagher

, Ritter

, Champion

, et al. Virtual reality simulation for the operating room: Proficiency-based training as a paradigm shift in surgical skills training. Ann Surg. 2005;241(2):364–372.

4. Matsumoto

, Hamstra

, Radomski

, Cusimano

. The effect of bench model fidelity on endourological skills: A randomized controlled study. J Urol 2002;167(3):1243–1247.

5. Ritchie

, Pacilli

, Nataraja

. Simulation-based education in urology – an update. J Surg Educ 2023;80(1):1–10.

6. Ebbing

, Meling

, Rørvik

, Røe

, Gilboe

, Alme

, et al. Training with 3D-printed models improves urological skills and self-assurance: A randomized controlled trial. J Urol 2022;208(3):677–684.

7. Checcucci

, Autorino

, Amparore

, Pecoraro

, Piazzolla

, Manfredi

, et al. 3D technologies in urology: A review of the literature. Minerva Urol Nephrol 2021;73(4):442–457.

8. Biyani

, Kozan

, Ferrie

, et al. Creation of a novel ex vivo 3D-printed ileal conduit task trainer for teaching conduitoscopy skills. Urology. 2024;192:173–180.

9. Seagull

, Rooney

. Filling a void: Developing a standard subjective assessment tool for surgical simulation through focused review of current practices. Surgery. 2014;156(3):718–722.

10.

10. Brydges

, Hatala

, Zendejas

, et al. Linking simulation-based educational assessments and patient-related outcomes: A systematic review and meta-analysis. Acad Med. 2015;90(2):246–256.

11.

11. Kim

, Kim

, Park

, et al. Effectiveness of a newly-developed training module using 3D printing navigation for flexible ureteroscopy. Int Braz J Urol 2022;48(5):770–778.

12.

12. Kwon

, Kim

, Park

, et al. Validation of a 3D-printed simulator for training in endoscopic injection of bulking agent. Surg Endosc 2024;38(3):11081–11090.

13.

13. Matsumoto

, Al-Mousawi

, Knoll

, et al. A review of simulation platforms in urology: Current state and future directions. Curr Opin Urol 2023;33(1):1–7.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.28 MB

155.06 MB

0.00 MB

155.06 MB