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Main Authors: Gueziri, Houssem-Eddine, Uthamacumaran, Abicumaran, Safih, Widad, Almansouri, Abdulrahman, Hamdan, Nour Abou, Correa, Jose A., Léger, Étienne, Collins, D. Louis, Del Maestro, Rolando F.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.14879
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author Gueziri, Houssem-Eddine
Uthamacumaran, Abicumaran
Safih, Widad
Almansouri, Abdulrahman
Hamdan, Nour Abou
Correa, Jose A.
Léger, Étienne
Collins, D. Louis
Del Maestro, Rolando F.
author_facet Gueziri, Houssem-Eddine
Uthamacumaran, Abicumaran
Safih, Widad
Almansouri, Abdulrahman
Hamdan, Nour Abou
Correa, Jose A.
Léger, Étienne
Collins, D. Louis
Del Maestro, Rolando F.
contents Background. Bimanual psychomotor proficiency is fundamental to neurosurgical procedures, yet it remains difficult for trainees to acquire and for educators to objectively evaluate performance. In this study, we investigate the feasibility of a neurosurgical simulation platform that integrates an anatomically realistic brain model with surgical instrument tracking to support training and objective assessment of bimanual tasks in the context of subpial corticectomy. Methods. We developed and evaluated a neurosurgical simulation platform based on an ex-vivo calf brain model and a multi-camera tracking system capable of simultaneously capturing the motion of surgical instruments in both hands, including collection of real-time instrument trajectories and synchronized video recordings. These enabled extraction of motion-based, time-based, and bimanual coordination metrics. We conducted a case series involving 47 participants across four training levels: medical students, junior residents, senior residents, and neurosurgeons. Results. The tracking system successfully captured instrument motion during 81% of the periods when instruments were actively used throughout the simulation procedure. Several extracted metrics were able to significantly differentiate between levels of surgical expertise. In particular, instrument usage duration and custom-defined bimanual coordination metrics such as instrument tip separation distance and simultaneous usage time, show potential as features to identify participant expertise levels with different instruments. Conclusions. We demonstrated the feasibility of tracking surgical instruments during complex bimanual tasks in an ex-vivo brain simulation platform. The metrics developed provide a foundation for objective performance assessment and highlight the potential of motion analysis to improve neurosurgical training and evaluation.
format Preprint
id arxiv_https___arxiv_org_abs_2511_14879
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A High-Fidelity Neurosurgical Training Platform for Bimanual Procedures: A Feasibility Study
Gueziri, Houssem-Eddine
Uthamacumaran, Abicumaran
Safih, Widad
Almansouri, Abdulrahman
Hamdan, Nour Abou
Correa, Jose A.
Léger, Étienne
Collins, D. Louis
Del Maestro, Rolando F.
Computational Engineering, Finance, and Science
Background. Bimanual psychomotor proficiency is fundamental to neurosurgical procedures, yet it remains difficult for trainees to acquire and for educators to objectively evaluate performance. In this study, we investigate the feasibility of a neurosurgical simulation platform that integrates an anatomically realistic brain model with surgical instrument tracking to support training and objective assessment of bimanual tasks in the context of subpial corticectomy. Methods. We developed and evaluated a neurosurgical simulation platform based on an ex-vivo calf brain model and a multi-camera tracking system capable of simultaneously capturing the motion of surgical instruments in both hands, including collection of real-time instrument trajectories and synchronized video recordings. These enabled extraction of motion-based, time-based, and bimanual coordination metrics. We conducted a case series involving 47 participants across four training levels: medical students, junior residents, senior residents, and neurosurgeons. Results. The tracking system successfully captured instrument motion during 81% of the periods when instruments were actively used throughout the simulation procedure. Several extracted metrics were able to significantly differentiate between levels of surgical expertise. In particular, instrument usage duration and custom-defined bimanual coordination metrics such as instrument tip separation distance and simultaneous usage time, show potential as features to identify participant expertise levels with different instruments. Conclusions. We demonstrated the feasibility of tracking surgical instruments during complex bimanual tasks in an ex-vivo brain simulation platform. The metrics developed provide a foundation for objective performance assessment and highlight the potential of motion analysis to improve neurosurgical training and evaluation.
title A High-Fidelity Neurosurgical Training Platform for Bimanual Procedures: A Feasibility Study
topic Computational Engineering, Finance, and Science
url https://arxiv.org/abs/2511.14879