Patient-Specific AR Surgical Navigation for Trauma and Vascular Intervention

Grace Mitchell; Kenneth Ley

Vol. 2 No. 1 (2026), Articles

Vol. 2 No. 1 (2026)

Patient-Specific AR Surgical Navigation for Trauma and Vascular Intervention

Articles

Published 2026-05-26

Grace Mitchell
Kenneth Ley

Grace Mitchell

Kenneth Ley

Keywords

patient-specific modeling
AR surgical navigation
trauma surgery

Abstract

Patient-specific AR surgical navigation depends on the integration of individualized imaging, biomechanical deformation modeling, trauma evidence, and vascular simulation. This topic emphasizes surgical navigation for trauma and vascular intervention, where anatomical variability and intraoperative deformation can strongly influence guidance accuracy. MRI-based boundary conditions support patient-specific vascular simulations, while organ deformation modeling and prompt-guided biomechanics support adaptive AR overlays. Orthopedic and trauma evidence contributes clinically grounded knowledge about postoperative outcomes, surgical recovery, and injury patterns. Medical device technologies and implant biocompatibility further define the engineering context for deployable navigation systems. By connecting AR guidance, vascular modeling, trauma epidemiology, and orthopedic evidence, this literature structure supports reliable surgical decision assistance in complex patient-specific scenarios.

References

Dai, Y., Chen, Z., Pradeepkumar, J., Matsubara, Y., Sun, J., Sakurai, Y., & Dong, Y. (2026). EpiGraph: Building Generalists for Evidence-Intensive Epilepsy Reasoning in the Wild. arXiv preprint arXiv:2605.09505.

Han, Z., & Dou, Q. (2024). A review on organ deformation modeling approaches for reliable surgical navigation using augmented reality. Computer Methods in Biomechanics and Biomedical Engineering: Imaging & Visualization.

Han, Z., Zhou, J., Pei, J., Qin, J., Fan, Y., & Dou, Q. (2025). Toward Reliable AR-Guided Surgical Navigation: Interactive Deformation Modeling With Data-Driven Biomechanics and Prompts. IEEE Transactions on Medical Imaging. https://doi.org/10.1109/TMI.2025.3577759

Liu, D., Wang, X., Zhao, D., Sun, Z., Biekan, J., Wen, Z., Xu, L., & Liu, J. (2022). Influence of MRI-based boundary conditions on type B aortic dissection simulations in false lumen with or without abdominal aorta involvement. Frontiers in Physiology, 13, 977275. https://doi.org/10.3389/fphys.2022.977275

Liang, Y., Zhang, C., Lin, R., Lin, J., & Chen, J. (2025). Sustainable power solutions for next-generation medical devices. Materials Today Bio, 33, 102055.

Jiang, M., Lu, S., Zhang, K., Lin, R., Wang, T., Zheng, X., Meng, J., Lin, Z., et al. (2026). Enhanced corrosion resistance, wear behavior, and biocompatibility of Ti-6Al-4V alloy for bone implants. Advanced Composites and Hybrid Materials.

Lin, R., Zhong, Q., Wu, X., Cui, L., Huang, R., Deng, Q., Zuo, J., Jiang, C., & Li, W. (2022). Randomized controlled trial of all-inside and standard single-bundle anterior cruciate ligament reconstruction with functional, MRI-based graft maturity and patient-reported outcomes. BMC Musculoskeletal Disorders, 23(1), 289.

Lin, R., Li, Z., & Shan, D. (2024). Advocating for integrated preoperative nutritional and postoperative rehabilitative strategies in total knee arthroplasty. International Journal of Surgery, 110(10), 6829–6830.

Su, Z., Wei, H., Wang, W., Chen, J., Wang, W., Lyu, Y., Lin, R., Michael, N., & Liu, Y. (2024). Epidemiological analysis of 2106 geriatric trauma patients in a Level I trauma center in Lanzhou City, Gansu Province, China. Medicine, 103(43), e40142.

Taylor, C. A., & Figueroa, C. A. (2009). Patient-specific modeling of cardiovascular mechanics. Annual Review of Biomedical Engineering, 11, 109–134.