Automated Volumetric Milling Area Planning for Acoustic Neuroma Surgery via Evolutionary Multi-Objective Optimization

• Published in: Sensors (Basel, Switzerland) Vol. 25; no. 2; p. 448
• Main Authors: Yang, Sheng, Li, Haowei, Zhang, Peihai, Yan, Wenqing, Zhao, Zhe, Ding, Hui, Wang, Guangzhi
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 14.01.2025; MDPI
• Subjects: Acoustics; Algorithms; Automation; bone milling; Brain cancer; Cochlear implants; Humans; Methods; multi-objective optimization; Neuroma, Acoustic - diagnostic imaging; Neuroma, Acoustic - surgery; Optimization; Planning; Surgeons; Surgery; Surgery, Computer-Assisted - methods; Surgical apparatus & instruments; Tomography, X-Ray Computed - methods; volumetric area parameterization; volumetric surgical planning; multi-objective optimization; bone milling; volumetric area parameterization; volumetric surgical planning
• ISSN: 1424-8220; 1424-8220
• DOI: 10.3390/s25020448

Mastoidectomy is critical in acoustic neuroma surgery, where precise planning of the bone milling area is essential for surgical navigation. The complexity of representing the irregular volumetric area and the presence of high-risk structures (e.g., blood vessels and nerves) complicate this task. In order to determine the bone area to mill using preoperative CT images automatically, we propose an automated planning method using evolutionary multi-objective optimization for safer and more efficient milling plans. High-resolution segmentation of the adjacent risk structures is performed on preoperative CT images with a template-based approach. The maximum milling area is defined based on constraints from the risk structures and tool dimensions. Deformation fields are used to simplify the volumetric area into limited continuous parameters suitable for optimization. Finally, a multi-objective optimization algorithm is used to achieve a Pareto-optimal design. Compared with manual planning on six volumes, our method reduced the potential damage to the scala vestibuli by 29.8%, improved the milling boundary smoothness by 78.3%, and increased target accessibility by 26.4%. Assessment by surgeons confirmed the clinical feasibility of the generated plans. In summary, this study presents a parameterization approach to irregular volumetric regions, enabling automated milling area planning through optimization techniques that ensure safety and feasibility. This method is also adaptable to various volumetric planning scenarios.