A Probabilistic Neural Twin for Treatment Planning in Peripheral Pulmonary Artery Stenosis

arXiv - CS - Numerical Analysis Pub Date : 2023-12-01 DOI:arxiv-2312.00854

John D. Lee, Jakob Richter, Martin R. Pfaller, Jason M. Szafron, Karthik Menon, Andrea Zanoni, Michael R. Ma, Jeffrey A. Feinstein, Jacqueline Kreutzer, Alison L. Marsden, Daniele E. Schiavazzi

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Abstract

The substantial computational cost of high-fidelity models in numerical hemodynamics has, so far, relegated their use mainly to offline treatment planning. New breakthroughs in data-driven architectures and optimization techniques for fast surrogate modeling provide an exciting opportunity to overcome these limitations, enabling the use of such technology for time-critical decisions. We discuss an application to the repair of multiple stenosis in peripheral pulmonary artery disease through either transcatheter pulmonary artery rehabilitation or surgery, where it is of interest to achieve desired pressures and flows at specific locations in the pulmonary artery tree, while minimizing the risk for the patient. Since different degrees of success can be achieved in practice during treatment, we formulate the problem in probability, and solve it through a sample-based approach. We propose a new offline-online pipeline for probabilsitic real-time treatment planning which combines offline assimilation of boundary conditions, model reduction, and training dataset generation with online estimation of marginal probabilities, possibly conditioned on the degree of augmentation observed in already repaired lesions. Moreover, we propose a new approach for the parametrization of arbitrarily shaped vascular repairs through iterative corrections of a zero-dimensional approximant. We demonstrate this pipeline for a diseased model of the pulmonary artery tree available through the Vascular Model Repository.

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肺动脉周围动脉狭窄治疗计划的概率神经孪生

到目前为止，数值血流动力学中高保真模型的大量计算成本已将其主要用于离线治疗计划。数据驱动架构和快速代理建模优化技术的新突破为克服这些限制提供了令人兴奋的机会，使此类技术能够用于时间关键型决策。我们讨论了通过经导管肺动脉康复或手术修复肺动脉周围病变多发狭窄的应用，在肺动脉树的特定位置实现所需的压力和流量，同时最大限度地降低患者的风险。由于在实际治疗过程中可以实现不同程度的成功，我们制定了问题的非概率，并通过基于样本的方法来解决它。我们提出了一种新的离线-在线管道，用于概率实时治疗计划，它结合了边界条件的离线同化、模型约简和训练数据集生成以及边缘概率的在线估计，可能取决于在已经修复的病变中观察到的增强程度。此外，我们还提出了一种通过零维近似迭代修正的任意形状血管修复参数化的新方法。我们通过血管模型库展示了肺动脉树病变模型的管道。

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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arXiv - CS - Numerical Analysis

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