Simon Pannek, Shervin Dehghani, Michael Sommersperger, Peiyao Zhang, Peter Gehlbach, M Ali Nasseri, Iulian Iordachita, Nassir Navab
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引用次数: 0
摘要
年龄相关性黄斑变性治疗的最新进展要求精确进入视网膜下空间,强调在不造成创伤的情况下针对视网膜色素上皮(RPE)-布鲁克斯膜复合体进行微创手术。即使是技术娴熟的外科医生,手动手术过程中固有的手部震颤也会危及这些关键介入手术的安全性。这促进了旨在防止这种震颤的机器人系统的发展。这些机器人通过 FBG 传感器进行增强,FBG 传感器能感知手术器械与视网膜组织之间微小的力相互作用。为了让社会各界能够利用这些力反馈数据设计算法,本文重点讨论了提供专门数据集的必要性,该数据集将光学相干断层扫描(OCT)成像与上述力数据整合在一起。我们介绍了一个独特的数据集,该数据集整合了与 OCT B-scan 图像同步的力传感数据,该数据集来自一个复杂的装置,其中包括机器人辅助和 OCT 集成显微镜。此外,我们还提出了一个基于图像的力估算神经网络模型,以证明该数据集的适用性。
Exploring the Needle Tip Interaction Force with Retinal Tissue Deformation in Vitreoretinal Surgery.
Recent advancements in age-related macular degeneration treatments necessitate precision delivery into the subretinal space, emphasizing minimally invasive procedures targeting the retinal pigment epithelium (RPE)-Bruch's membrane complex without causing trauma. Even for skilled surgeons, the inherent hand tremors during manual surgery can jeopardize the safety of these critical interventions. This has fostered the evolution of robotic systems designed to prevent such tremors. These robots are enhanced by FBG sensors, which sense the small force interactions between the surgical instruments and retinal tissue. To enable the community to design algorithms taking advantage of such force feedback data, this paper focuses on the need to provide a specialized dataset, integrating optical coherence tomography (OCT) imaging together with the aforementioned force data. We introduce a unique dataset, integrating force sensing data synchronized with OCT B-scan images, derived from a sophisticated setup involving robotic assistance and OCT integrated microscopes. Furthermore, we present a neural network model for image-based force estimation to demonstrate the dataset's applicability.