https://doi.org/10.22190/FUMI240916061V

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Computer-Assisted Surgery (CAS) involves applying various computer-based methodologies and devices to plan, guide, and perform surgical procedures, thereby improving outcomes throughout the surgical process. This study integrates the Characteristic Product Features (CPF) methodology with Method Of anatomical Features (MAF), both developed in-house to improve CAS. It enables the creation of the human organs’ geometrical models by including different relations between Regions of Interest (RGIs) models and specific properties, like functional, materials, and topological. Enhancing existing methodologies in CAS aims to offer a more comprehensive geometrical description of human organs, leading to the development of more precise and anatomically accurate personalized geometrical models. Creating customized geometry with accurately defined features is expected to enable surgeons to prepare and execute surgical interventions better, consequently improving patient care and recovery. The demonstration of successful geometry adaptation is shown by prototyping developed models using 3D FDM printing.

computer-assisted surgery, characteristic product features, method of anatomical features.

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