Deep learning based assessment of hemodynamics in the coarctation of the aorta: comparison of bidirectional recurrent and convolutional neural networks

Versnjak, Jakob; Yevtushenko, Pavlo; Kuehne, Titus; Bruening, Jan; Goubergrits, Leonid

doi:10.3389/fphys.2024.1288339

Front. Physiol.

2024

DOI: 10.3389/fphys.2024.1288339

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Deep learning based assessment of hemodynamics in the coarctation of the aorta: comparison of bidirectional recurrent and convolutional neural networks

Jakob Versnjak,

Pavlo Yevtushenko,

Titus Kuehne

et al.

Abstract: The utilization of numerical methods, such as computational fluid dynamics (CFD), has been widely established for modeling patient-specific hemodynamics based on medical imaging data. Hemodynamics assessment plays a crucial role in treatment decisions for the coarctation of the aorta (CoA), a congenital heart disease, with the pressure drop (PD) being a crucial biomarker for CoA treatment decisions. However, implementing CFD methods in the clinical environment remains challenging due to their computational cos… Show more

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Deep graph convolutional neural network for one-dimensional hepatic vascular haemodynamic prediction

Zhang,

Shi,

2024

Preprint

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Hepatic vascular hemodynamics is an important reference indicator in the diagnosis and treatment of hepatic diseases. However, Method based on Computational Fluid Dynamics(CFD) are difficult to promote in clinical applications due to their computational complexity. To this end, this study proposed a deep graph neural network model to simulate the one-dimensional hemodynamic results of hepatic vessels. By connecting residuals between edges and nodes, this framework effectively enhances network prediction accuracy and efficiently avoids over-smoothing phenomena. The graph structure constructed from the centerline and boundary conditions of the hepatic vasculature can serve as the network input, yielding velocity and pressure information corresponding to the centerline. Experimental results indicate that our proposed method achieves higher accuracy on a hepatic vasculature dataset with significant individual variations and can be extended to applications involving other blood vessels. Following training, errors in both the velocity and pressure fields are maintained below 1.5%. The trained network model can be easily deployed on low-performance devices and, compared to CFD-based methods, can output velocity and pressure along the hepatic vessel centerline at a speed three orders of magnitude faster.

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Deep graph convolutional neural network for one-dimensional hepatic vascular haemodynamic prediction

Zhang,

Shi,

2024

Preprint

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show abstract

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Deep learning based assessment of hemodynamics in the coarctation of the aorta: comparison of bidirectional recurrent and convolutional neural networks

Cited by 1 publication

References 32 publications

Deep graph convolutional neural network for one-dimensional hepatic vascular haemodynamic prediction

Deep graph convolutional neural network for one-dimensional hepatic vascular haemodynamic prediction

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