In silico simulation: a key enabling technology for next-generation intelligent surgical systems

IF 5 Q1 ENGINEERING, BIOMEDICAL
Benjamin Killeen, Sue Min Cho, M. Armand, Russell H. Taylor, M. Unberath
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引用次数: 0

Abstract

To mitigate the challenges of operating through narrow incisions under image guidance, there is a desire to develop intelligent systems that assist decision making and spatial reasoning in minimally invasive surgery (MIS). In this context, machine learning-based systems for interventional image analysis are receiving considerable attention because of their flexibility and the opportunity to provide immediate, informative feedback to clinicians. It is further believed that learning-based image analysis may eventually form the foundation for semi- or fully automated delivery of surgical treatments. A significant bottleneck in developing such systems is the availability of annotated images with sufficient variability to train generalizable models, particularly the most recently favored deep convolutional neural networks or transformer architectures. A popular alternative to acquiring and manually annotating data from the clinical practice is the simulation of these data from human-based models. Simulation has many advantages, including the avoidance of ethical issues, precisely controlled environments, and the scalability of data collection. Here, we survey recent work that relies on in silico training of learning-based MIS systems, in which data are generated via computational simulation. For each imaging modality, we review available simulation tools in terms of compute requirements, image quality, and usability, as well as their applications for training intelligent systems. We further discuss open challenges for simulation-based development of MIS systems, such as the need for integrated imaging and physical modeling for non-optical modalities, as well as generative patient models not dependent on underlying computed tomography, MRI, or other patient data. In conclusion, as the capabilities of in silico training mature, with respect to sim-to-real transfer, computational efficiency, and degree of control, they are contributing toward the next generation of intelligent surgical systems.
硅片模拟:下一代智能手术系统的关键使能技术
为了减轻在图像引导下通过狭窄切口进行手术的挑战,人们希望开发智能系统,帮助微创手术(MIS)中的决策和空间推理。在这种情况下,用于介入图像分析的基于机器学习的系统由于其灵活性和向临床医生提供即时、信息反馈的机会而受到相当大的关注。人们进一步认为,基于学习的图像分析可能最终形成手术治疗的半自动或全自动交付的基础。开发此类系统的一个重要瓶颈是具有足够可变性的注释图像的可用性,以训练可推广模型,特别是最近最受欢迎的深度卷积神经网络或转换器架构。从临床实践中获取和手动注释数据的一种流行的替代方案是从基于人体的模型中模拟这些数据。模拟具有许多优点,包括避免道德问题、精确控制的环境以及数据收集的可扩展性。在这里,我们调查了最近依赖于基于学习的MIS系统的计算机训练的工作,其中数据是通过计算模拟生成的。对于每种成像模式,我们从计算需求、图像质量和可用性方面回顾了可用的模拟工具,以及它们在训练智能系统方面的应用。我们进一步讨论了MIS系统基于模拟开发的开放挑战,例如对非光学模态的集成成像和物理建模的需求,以及不依赖于底层计算机断层扫描、MRI或其他患者数据的生成患者模型。总之,随着计算机训练能力的成熟,在模拟到真实的转移、计算效率和控制程度方面,它们正在为下一代智能手术系统做出贡献。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
9.40
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