Physics-Informed Neural Networks (PINNs) for solving the forward and inverse problems of prostate biomechanics.

IF 3.5

Journal of the mechanical behavior of biomedical materials Pub Date : 2025-10-11 DOI:10.1016/j.jmbbm.2025.107225

María Ferrón-Vivó, Enrique Nadal, José Manuel Navarro-Jiménez, Santiago Gregori, María José Rupérez

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Abstract

This work introduces a novel integration of Physics-Informed Neural Networks (PINNs) with hyperelastic material modeling, employing the Neo-Hookean model to estimate the stiffness of soft tissue organs based on realistic anatomical geometries. Specifically, we propose the modeling of the prostate biomechanics as an initial application of this framework. By combining machine learning with principles of continuum mechanics, the methodology leverages finite element method (FEM) simulations and magnetic resonance imaging (MRI)-derived prostate models to address forward and inverse biomechanical problems. The PINN framework demonstrates the ability to provide accurate material property estimations, requiring limited data while overcoming challenges in data scarcity. This approach marks a significant advancement in patient-specific precision medicine, enabling improved diagnostics, personalized treatment planning, and broader applications in the biomechanical characterization of other soft tissues and organ systems.

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用于解决前列腺生物力学正反问题的物理信息神经网络（pinn）。

这项工作引入了一种新的物理信息神经网络（pinn）与超弹性材料建模的集成，采用Neo-Hookean模型来估计基于真实解剖几何的软组织器官的刚度。具体来说，我们建议将前列腺生物力学建模作为该框架的初步应用。通过将机器学习与连续介质力学原理相结合，该方法利用有限元法（FEM）模拟和磁共振成像（MRI）衍生的前列腺模型来解决正向和反向生物力学问题。PINN框架展示了提供准确的材料属性估计的能力，需要有限的数据，同时克服了数据稀缺的挑战。这种方法标志着患者特异性精准医学的重大进步，使改进的诊断、个性化的治疗计划和更广泛的应用于其他软组织和器官系统的生物力学表征。

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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Journal of the mechanical behavior of biomedical materials

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