Shaghayegh Z Ashtiani, Mohammad Sarabian, Kaveh Laksari, Hessam Babaee
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引用次数: 0
Abstract
Blood flow reconstruction in the vasculature is important for many clinical applications. However, in clinical settings, the available data are often quite limited. For instance, transcranial Doppler ultrasound is a non-invasive clinical tool that is commonly used in clinical settings to measure blood velocity waveforms at several locations. This amount of data is grossly insufficient for training machine learning surrogate models, such as deep neural networks or Gaussian process regression. In this work, we propose a Gaussian process regression approach based on empirical kernels constructed by data generated from physics-based simulations-enabling near-real-time reconstruction of blood flow in data-poor regimes. We introduce a novel methodology to reconstruct the kernel within the vascular network. The proposed kernel encodes both spatiotemporal and vessel-to-vessel correlations, thus enabling blood flow reconstruction in vessels that lack direct measurements. We demonstrate that any prediction made with the proposed kernel satisfies the conservation of mass principle. The kernel is constructed by running stochastic one-dimensional blood flow simulations, where the stochasticity captures the epistemic uncertainties, such as lack of knowledge about boundary conditions and uncertainties in vasculature geometries. We demonstrate the performance of the model on three test cases, namely, a simple Y-shaped bifurcation, abdominal aorta and the circle of Willis in the brain.
血管中的血流重建对许多临床应用都很重要。然而,在临床环境中,可用数据往往相当有限。例如,经颅多普勒超声是一种无创临床工具,临床上常用于测量多个位置的血流速度波形。这种数据量对于训练深度神经网络或高斯过程回归等机器学习代用模型来说是远远不够的。在这项工作中,我们提出了一种基于由物理模拟生成的数据构建的经验核的高斯过程回归方法--可在数据匮乏的情况下实现近乎实时的血流重建。我们引入了一种在血管网络中重建核的新方法。提出的核编码了时空相关性和血管与血管之间的相关性,因此可以在缺乏直接测量的血管中重建血流。我们证明,使用所提出的核进行的任何预测都符合质量守恒原则。内核是通过运行随机一维血流模拟构建的,其中的随机性捕捉了认识上的不确定性,如缺乏对边界条件的了解和血管几何形状的不确定性。我们在三个测试案例中演示了该模型的性能,即简单的 Y 形分叉、腹主动脉和大脑中的威利斯圈。
期刊介绍:
J. R. Soc. Interface welcomes articles of high quality research at the interface of the physical and life sciences. It provides a high-quality forum to publish rapidly and interact across this boundary in two main ways: J. R. Soc. Interface publishes research applying chemistry, engineering, materials science, mathematics and physics to the biological and medical sciences; it also highlights discoveries in the life sciences of relevance to the physical sciences. Both sides of the interface are considered equally and it is one of the only journals to cover this exciting new territory. J. R. Soc. Interface welcomes contributions on a diverse range of topics, including but not limited to; biocomplexity, bioengineering, bioinformatics, biomaterials, biomechanics, bionanoscience, biophysics, chemical biology, computer science (as applied to the life sciences), medical physics, synthetic biology, systems biology, theoretical biology and tissue engineering.
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