Image Processing Framework for Accuracy Measurements in Real-Time Endovascular Simulation
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Publicerad
Författare
Typ
Examensarbete för masterexamen
Master's Thesis
Master's Thesis
Modellbyggare
Tidskriftstitel
ISSN
Volymtitel
Utgivare
Sammanfattning
Training surgeons to navigate catheters and guidewires through blood vessels is
challenging, and simulators are increasingly used to practice these procedures safely.
However, no standard method currently exists to objectively measure how realistically
a simulator reproduces the behavior of real surgical instruments. This thesis
presents an image-based framework for the quantitative comparison of physical and
simulated catheter configurations, combining camera-based image acquisition, centerline
extraction, geometric alignment, and shape comparison metrics.
Physical experiments were performed by imaging catheters and guidewires both on
flat surfaces and inside a vascular phantom (Physical SIM). The same instrument
configurations were then reproduced in the Mentice simulator (VIST), allowing a
direct comparison between the physical and virtual setups. The framework was further
extended with an automated optimization module that searches for simulator
stiffness parameters that best reproduce the observed physical catheter behavior
using Bayesian optimization.
Validation experiments demonstrated high accuracy in catheter length estimation,
achieving a mean absolute error of 0.117 cm and a coefficient of determination exceeding
R2 > 0.99. It also remained consistent regardless of the catheter shape. The
alignment procedure showed that the extracted centerlines converge to a close geometric
correspondence after registration. Optimization experiments further showed
that simulator stiffness parameters could be tuned to reproduce physical catheter
configurations with high geometric similarity, although discrepancies remained for
certain catheter-guidewire combinations. A direct comparison between the physical
and virtual environments was additionally limited by fundamental differences in
anatomy representation.
The results demonstrate that the proposed framework enables quantitative and repeatable
evaluation of endovascular simulator realism. Among the evaluated metrics,
RMS error and curvature analysis were found to be the most informative: RMS error
for localizing spatial deviations along the catheter shaft, and curvature analysis for
capturing mechanical differences in instrument bending behavior. The framework
provides a foundation for future validation and calibration of catheter mechanics in
anatomically realistic simulation environments.
Beskrivning
Ämne/nyckelord
endovascular, simulation, catheter, guidewire, validation, centerline, alignment, optimization, curvature, phantom
